RELAY CATALOG 2 LABINAL POWER SYSTEMS TF300-9E SENSING & CONTROLS RELAY CATALOG Table of Contents 3 4 4 5-8 9-20 Table of Contents Fast Information Finder Part Number to Page Index Capabilities and Featured Products Labinal Power Systems Capabilities Featured Products Article (High Volt DC / Next Generation Contactors / Power Distribution Boxes) Remote Controlled Circuit Breakers Remote Controlled Circuit Breakers Remote Power Controllers 21-30 Power Relays Gasket Sealed - 100 to 1000A Gasket Sealed - 25 to 400A, Type II and Type III 31-37 Hermetically Sealed Power Relays Hermetically Sealed - 12 to 50A Hermetically Sealed - 100 to 400A Terminal Covers 38-41 Lightweight Relays Hermetically Sealed Environmentally Sealed 42-43 Generator Contactors Custom Flat Packs 44-46 46 Capabilities and Featured Products Reference Military to Labinal Power Systems Part Number Index Remote Controlled Circuit Breakers Power Relays Hermetically Sealed Power Relays Lightweight Relays Generator Contactors Custom Flat Packs Reference LABINAL POWER SYSTEMS TF300-9E 3 FAST INFORMATION FINDER Find Information Fast Part Number to Page Index * Labinal Power Systems Part Have an Labinal Power Systems part number and need more information? Use the part number to page index on this page to get the exact page of the full product listing. No. 496041H6042H6046H9565H SM15 SM100DSM150DSM200DSM400DSM1000DSM100H1 SM135B2 SM400H SM600BA5 - 100 SM600BA125 - 200 SM601BA10 - 60 * Have a Military part number and need applicable Labinal Power Systems part number? Use the Military part number Index in the back of this catalog. * Need additional information not contained in this catalog? For technical questions, application assistance, or the name of your local authorized distributor, call 1-800955- 7354. 4 LABINAL POWER SYSTEMS TF300-9E Page No. 36 25 31 25 25 40 21 21 21 21 21 38 42 34 10 19 10 CAPABILITIES Market Trends Aircraft and commercial offhighway vehicle Original Equipment Manufacturers (OEMs) are continuously pursuing efficiencies associated with the design and manufacture of vehicle platforms. Additionally, the OEMs are working on increasing the functionality of system components while reducing operating and life cycle costs. These activities are leading to the migration of engineering and system design activities to Tier 1 system integrators and their supply partners such as Labinal Power Systems. This supplier team will be required to design, develop, and manufacture performance rated products such as relays, "smart" contactors, high voltage DC contactors, and power distribution junction boxes that minimize cost, reduce weight, and limit product dimensions in order to support accomplishing OEM objectives. What Problem Does Labinal Power Systems Solve? Aircraft OEMs discovered that outsourcing power distribution management requirements to Tier 1-system integrators and their vendor base is an effective alternative that mitigates risk and leverages the subsystem and component manufacturer expertise. The success of such outsourcing efforts benefits the OEM and leads to more reliance on qualified Tier 1-System Integrators for electrical systems. To compliment this OEM strategy, Labinal Power Systems formed the ES&C product divison, which combines the product pedigree of illuminated pushbutton switches, cockpit displays and keyboards, NVIS products, pilot controls, and a variety of MILqualified aerospace switches, relays, contactors, and circuit breakers, to broaden the product portfolio and support execution of a subsystem strategy. Labinal Power Systems' objective is to be the leading candidate for the supply of aerospace power distribution components and subsystems. The Labinal Power Systems Solution Labinal Power Systems is an attractive partner in the design and development of integrated relay and contactor components and subsystem power junction boxes. Our development process employs sound methodology to identify, assess, and manage program risk. The components of this approach include Phase-Gate Reviews, Project Management, and Six Sigma for Design and Development. This process in conjunction with Labinal Power Systems' extensive Product Portfolio and Capabilities enable the Aerospace Group's ES&C division to be a single source supplier for power protection, distribution, and switching components. The system integrators have the option of sourcing pedigree relays and contactors for their power distribution box designs or subcontracting the entire power distribution subsystem to Labinal Power Systems. Phase-Gate Reviews This process organizes product development activities from the idea through product launch into a series of phases. The activities within each phase are multifunctional, and are designed to provide information that progressively reduces risk. Consistent application of the process promotes successful on-time product development, as well as competitive pricing and high quality levels. Project Management Product development projects involve the iterative planning, execution and control of project team activities in order to meet the competing demands of scope, timing, cost, risk and quality. Project management methodology affords the application of knowledge, skills, tools and techniques to meet these requirements. Six Sigma for Design and Development Six Sigma for Design and Development is a methodology using normal Six Sigma tools, but applies them early in the design process. This methodology instills the product development process with the same Six Sigma process rigor found in Labinal Power Systems manufacturing to create successful products in a competitive marketplace. Product Portfolio Labinal Power Systems' complete product portfolio allows flexibility to partner with customers having a variety of relay and contactor subsystem and component needs. Labinal Power Systems' engineers design additional value into traditional power distribution components and subsystems through electronics, while balancing customer concerns for size, weight, cost, and performance. Labinal Power Systems' Power Distribution Boxes are a prime example of value-added engineering. Proven relay, contactor, and circuit breaker products are packaged into a single line replaceable assembly that offers the user a customized power module that significantly reduces overall system weight, improves system level reliability, and maintainability. The Labinal Power Systems product portfolio is recognized in the aerospace industry as MIL qualified for performance rated power distribution products. Labinal Power Systems' experience in designing relays and contactors to MIL Spec requirements such as MILPRF-83383, MIL-R-6106/9, /10, /11, and MIL-R-6101/48 ensures the customer of relays and contactors that will operate in the most challenging environments and in accordance with the strictest performance requirements. These same component design considerations are incorporated into Labinal Power Systems' latest designs such as High Voltage DC Contactors and also in subsystem designs such as a Power Distribution Box (PDB). These products are highlighted in the Featured Products Article on page 7-8. LABINAL POWER SYSTEMS TF300-9E 5 CAPABILITIES The product portfolio includes: * Smart Contactors with cur rent sensing protection, Ground Fault Interrupt technology, or Arc Fault Circuit Interrupt technology. * 28 Vdc Contactors (50 to 1000 amperes). * 270 Vdc Contactors (25 to 350 amperes). * 115/230 Vac 400 Hertz Contactors (30 to 430 amperes). * 750 Vdc Contactors (100 to 600 amperes). * Power Distribution Junction Boxes. * A variety of aerospace switches (rocker, toggle, pushbutton and limit) *P ilot Controls including customized flap controls, landing gear controls, throttle controls, trim controls (for mechanical pitch, roll and yaw), and fire emergency controls. *D isplays, readable in both direct sunlight and at night, including the popular Series 900 fiber optic displays, as well as displays with surface mount devices and programmable electronic arrays. *K eyboards that are sunlight and night light readable and suited for virtually any application, including flight management panels, handheld data communications panels, shipboard computer control panels, fire system control panels, ground support equipment, and radar and telemetry control panels. Labinal Power Systems Aerospace keyboards also incorporate logic boards, photo sensors, rotary and toggle switches, and annunciators, and have features such as micro-processor interfacing and programmable logic control. 6 LABINAL POWER SYSTEMS *N VIS products such as cockpit controls, displays and keyboards, and illuminated push button switches that conform to MIL and NVIS specifications and any unique customer needs. * Illuminated Pushbutton switches with a multitude of options ranging from sunlight readable, NVIS-compatible, incandescent and LED lighting to various mounting and termination options for flexible installation and retrofit applications. *E lectro-mechanical thermal circuit breakers (0.5 to 300 amperes) - single phase or three phase thermally actuated devices offered in conventional design or with integrated Arc Fault Circuit Interrupt technology. *R emote Control Circuit Breakers (5 to 125 amperes) - single phase or three-phase devices sold separately or as a subsystem when combined with a necessary indicator control unit (0.5 ampere circuit breaker). *E lectromechanical Remote Power Controllers (125 to 200 amperes) - single-phase devices sold separately or as a subsystem when combined with a necessary indicator control unit (0.5 ampere circuit breaker). Labinal Power Systems Capabilities * Proven excellence in component and subsystem design, development, testing, qualification, and production for both military and commercial aerospace applications. * A manufacturing organization that emphasizes customer satisfaction by focusing on cost, quality, and delivery of the product portfolio. TF300-9E * Altitude / temperature testing chamber simulating altitude to 80,000 feet and temperatures from -65C to 125C. * Test capabilities of 115/200 Vac 400 Hz to 3600 amps, 28 Vdc to 10,000 amps, 270/350/475 Vdc to 1,500 amps. *E nvironmental tests for Sand and Dust, Shock, and Vibration. *L atest CAD/CAM finite element analysis and stereolithographic techniques, and PRO-E design. *M odel Shop flexibility to respond to design changes and rapid turn around of prototypes. The Labinal Power Systems Difference There are a number of relay and contactor suppliers in the aerospace market. However, few possess the vertical integration needed to engineer and manufacture to both MIL Spec and OEM customer specifications to ensure consistency of quality operation in components and subsystems. Labinal Power Systems affords its customers the following difference: *S trong brand recognition, customer loyalty, and demonstrated market presence for over 80 years * Ability to leverage the company's size, financial strength, and scope to drive superior results. Labinal Power Systems has the ability to leverage the engineering resources of a multi-billion dollar company. * An extensive product portfolio that complements integrated subsystem design competency. * A flat organizational structure that allows for the optimal blend of best value technical approach and test support within budget and schedule constraints. *D edicated program managers that understand and communicate the "voice of the customer". Design software that promotes concurrent engineering and the exchange of customer data. *C o-located engineering, manufacturing, and development resources promote robust product development and product support. Labinal Power Systems' unique product portfolio, its ability to design and manufacture components and subsystems, and customer centric strategy mitigates the risk associated with new aircraft electrical power distribution systems. Labinal Power Systems is an ideal candidate to consider for engineering and manufacturing collaboration on all future commercial, General Aviation, and military programs. FEATURED PRODUCTS Changing Aerospace Industry In today's consolidating aerospace industry, Tier 1-System Integrators and Airframe Manufacturers desire more value from their component suppliers. A qualified supplier must not only have an extensive product portfolio, but must also display proven subsystem capabilities. These abilities include the capacity to design, manufacture, and test customized power distribution assemblies that consolidate multiple functions in a single package. Over the past decade, Labinal Power Systems acknowledged this fact, and has focused its attention on developing these value-add competencies to become a recognized leader in integrated power distribution systems. Specifically, Labinal Power Systems has stayed at the forefront of product / technology development through the development of the following components and subassemblies: High-Voltage DC (HVDC) Contactors, NextGeneration Alternating Current (AC) Contactors, and Power Distribution Boxes. High-Voltage DC Contactors As electrical power systems of 270Vdc and greater become the application standard for high performance aircraft, the requirements for switching and protection components become increasingly demanding. DC switching has always posed greater design challenges versus AC applications. With AC, the current naturally passes through zero each half cycle resulting in quick arc extinction after contact separation. Conventional 28Vdc switching can also be accomplished using single or double break contact sets. In this case, the inherent arc voltage generated by the anode and cathode of the arcing contact sets is capable of opposing and interrupting the current flow. The low voltage device counts little on the arc voltage generated in the actual arc column to drive the current to zero. Once the system voltage is increased beyond the 48Vdc rating, the interruption scheme becomes more challenging. Although the arc voltage generated by the arc column is generally small compared to the anode and cathode voltages, it will increase as the open contact gap widens. The actual arc voltage generated is a function of contact materials, the gas or atmosphere in the contact region, application current, and contact gap. Unfortunately, there is zero crossover to facilitate interruption, and the design must rely on open gap or arc stretching to match the system voltage. Therefore, with a single or double break contact set, the ability to interrupt 270Vdc quickly becomes size impractical without a more involved interruption scheme. Labinal Power Systems Technical Approach The technology chosen for use within the Labinal Power Systems line of 270Vdc contactors is splitting the arc into multiple series arcs under the influence of a constant magnetic field. This is accomplished by driving the arc column into a set of metallic plates housed within an insulated arc chute assembly. The multiple plates then provide the significant anode and cathode contribution to the arc voltage required for interruption. The plates also help to cool the arc column, causing the arc to exist at a higher potential and be stabilized in a predictable location in the plate. By placing multiple plates within the arc chute, the arc voltage generated during interruption can be increased resulting in less volume required by the arc chute. With the use of permanent magnets for controlling the arc column, the interruption is consistent even at low levels of application current. This results in extended low-level contact life. This Labinal Power Systems design allows for smaller device size and the ability to the mount the products in a compact power distribution subsystem. Benefits of Labinal Power Systems HVDC Technology The Aerospace Group's ES&C division has long been involved in programs addressing requirements for High Voltage Direct Current (HVDC) applications. Few competitors rival Labinal Power Systems' knowledge and experience in this technology over the past two decades. The proven air break technology used by the Labinal Power Systems HVDC contactor line provides the following benefits that competitive HVDC product offerings (hermetic) do not provide: *L abinal Power Systems was the first contactor manufacturer to complete product design and flight safety tests for 270Vdc aero space devices. *H ermetic sealing material adds unnecessary device weight. Hermetic sealing material degrades over time compromising the controlled atmosphere within the arc chamber, potentially leading to device failures. Labinal Power Systems devices have no requirement for a seal. * Hermetic sealed devices are classified by an allowable leakage rate, suggesting they are inherently unstable over time and susceptible to "dormant" failures. The Labinal Power Systems design increases reliability because the splitter plates eliminate single point of failure (inability to interrupt) associated with failed hermetic devices. * Load Polarity - Labinal Power Systems' devices are bi-directional without restriction. Labinal Power Systems devices reliably switch small current loads as well as high current loads. *E lectrical Life - Labinal Power Systems end of life characterized by contact voltage drop. * Labinal Power Systems' design is robust and operates well in harsh environments as demonstrated by past program performance and application of commercialized product. * Labinal Power Systems' device is a "Qualified" technology per MIL-R-6106 standard for all contactors. * Labinal Power Systems' device packaging easily tailored for application footprint. * Increased capability to dissipate energy for switching inductive loads. * Consistent and controlled switching transients due to ramped build up of arc voltage upon interruption. * Line Replaceable Unit packaging minimizes maintenance time. LABINAL POWER SYSTEMS TF300-9E 7 FEATURED PRODUCTS The Labinal Power Systems design does not require a hermetic seal, providing several advantages in application. In military applications, the use of splitter plate technology allows the device to function reliably throughout the life of the airframe while being subjected to harsh combat field environments and flight profiles that involve extreme levels of vibration and shock that can compromise competitors' hermetic seal product designs. The loss of a hermetic seal causes device failure as it relies on the sealed atmosphere within the device to interrupt high voltage. A failure of this nature could cause mission cancellation, mission abort, or even loss of aircraft. If installed in commercial aircraft applications, hermetically sealed devices would require periodic maintenance crew checks to prevent the risk of "dormant" failures associated with this design. The Labinal Power Systems design reduces/eliminates the need for maintenance involvement and better supports Air Carrier objectives for maintenance-free devices. Combining ongoing research with current product development, Labinal Power Systems continually strives to be a premier supplier of HighVoltage DC components and subsystems. Contactors, and Advanced Generator Contactors. "Smart" Contactors Labinal Power Systems is currently developing 175/60 amp packages for galleys, pumps, and primary load distribution. These contactors use the latest technologies, and can include current sensors for overcurrent protection and/or AFCI sensing. Internal / centralized electronics control are also features of these devices. Labinal Power Systems is continually looking for lower weight / size product solutions; a prime example being the 60 amp "Smart" contactor that is currently no bigger than an Labinal Power Systems 3-phase motor circuit protection device. 28Vdc Lightweight Contactors Labinal Power Systems is also developing a new 28Vdc, 50-400 Amp contactor family whose focus is on the reduction of weight and cost. Bolt-on designs combine power terminations and mechanical mounting, and contain captive hardware for all mounting fasteners. Both Single Pole Single Throw and Single Pole Double Throw configurations are available with features such as SubD or sealed in-line connectors. Advanced Generator Contactors Next Generation Contactors Labinal Power Systems has extensive experience in the research, design, and development of various AC Contactor product lines, including "Smart" contactors with integrated current sensing and Arc Fault Circuit interrupt (AFCI) technology, 28Vdc Lightweight 8 LABINAL POWER SYSTEMS Based upon Labinal Power Systems' existing SM15 product line, a new AC Generator contactor line of products is emerging. These contactors have automatic control connector TF300-9E mating and either Three Pole Single Throw or Three Pole Double Throw main contacts. Labinal Power Systems offers 115 VAC or 230 VAC (350-800Hz) generator contactors that are bolt-on designs with SubD connectors and rated at either 260 amps or 430 amps. They are currently one of the smallest and lightest AC contactors in the aerospace generator relay market, accommodate Variable Frequency and double voltage aircraft architectures, and are suitable for either stand-alone applications or power distribution boxes. Power Distribution Boxes Labinal Power Systems' proven component expertise and packaging capabilities have allowed ES&C to become a subsystem supplier in both the commercial jet and military aircraft markets. An example of these competencies is evident in the development of ED&C Power Distribution Boxes. A Power Distribution Box provides the next generation of AC and DC power distribution and protection, whereby conventional relays, contactors, and circuit protection devices are incorporated into a densely packaged, single line replaceable assembly. Benefits of this type of bundled packaging include weight reduction, reduced maintenance labor time due to the line replaceable nature of these boxes, minimal program risk since commercially off the shelf components are incorporated as often as possible into the design, significantly lower on-aircraft test time since they are tested to the customer acceptance testing standards prior to shipment, and reduced overall aircraft build time since Power Distribution Boxes support a centralized power distribution architecture. Power Distribution Boxes (PDBs) are typically designed and manufactured for each of the main generators onboard an aircraft in order to provide power to various bus lines and aircraft systems, while other, separate Battery/ External PDBs can provide switching power to a standby power bus and several components such as overhead panels, service lights, and the emergency locator transmitter. Labinal Power Systems has supplied customers with AC Power Distribution Boxes with features that direct outputs to high current loads, serve as power feeders to lower current circuit breakers, or act as current transformers to monitor all outputs. DC Power Distribution Boxes contain such features as Transformer Rectifier Units and Battery Contactors that direct outputs to high current loads, and incorporate Hall Effect sensors to monitor outputs. All Power Distribution Boxes can incorporate customized current carrying bus structures, and provide spare electrical power generation capacity to support future electrical systems growth/capacity. REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) Three Phase * 115/200 VAC 400 Hz * Three Phase Only Single Pole * 28 VDC * 115/200 VAC 400 Hz Qualified Qualified to demanding performance parameters of MIL- PRF - 83383 standard. Use as a Relay, Circuit Breaker, Or Both RCCBs combine the best attributes of a circuit breaker and a relay. Automatically protects the wires and the load device during circuit/load breakdown, but allows the flight deck control of the load during normal operation. Weight and Cost Savings In distributed-load applications, RCCBs are a more efficient power distribution solution promoting cost and weight savings through the elimination of long runs of heavy cables associated with the conventional relay - flight deck circuit protector method. Control of the RCCB requires only one #22 AWG control wire from the ICU on the flight deck to the RCCB. Cockpit Space Savings An RCCB system removes the presence of large circuit breakers from the cockpit while permitting remote On/Off operation from the flight deck. Combine Labinal Power Systems RCCB with Indicator Control Unit (ICU) model #1500-052-05. PERFORMANCE DATA Rupture Levels 3600 A (115 VAC or 28VDC for 1 Pole and 115VAC for 3 Pole) Endurance (Resistive & Inductive (Motor) Endurance (Motor) Endurance (Lamp) Dielectric Strength Insulation Resistance Thermal Temperature Range 50,000 Cycles 5-50A: 50,000 cycles; 60-100A: 25,000 cycles 5-25A: 50,000 cycles; 35-50A: 25,000 cycles; 60-100A: no rating 1500V, 60 Hz, MIL-STD-202, method 301, 0.5 MA max 100 mega ohm min, MIL-STD-202, method 302 -54C to 71C (-65F to 160F). MIL-STD-202, Method 107 Vibration 10G's to 2000 Hz. Exceeds MIL-STD-202, Method 204, Condition C, 10 microseconds max. chatter Shock25G's. MIL-STD-202, Method 213, 10 microseconds max. chatter Altitude50,000 ft. EMI Requirements MIL-STD-461, Requirements CS114 and RE102 over the frequency range of 14 kHz to 400 MHz and RE102 limits for Aircraft and Space Systems. EMI/RFI Susceptibility MIL-STD-461, Class 1D and Generation Moisture Resistance MIL-STD-202, method 106 Salt Spray Resistance MIL-STD-202, method 101, Condition B Sand and Dust Resistance MIL-STD-202, method 110, Condition A Fungus Resistance MIL-HDBK-454, Guideline 4 Explosion Proof MIL-STD-202, method 109 Weight (Single Pole) 5-25A: 318 grams (0.703 lbs.); 35-50A: 325 grams (0.719 lbs.); 60- 100A: 332 grams (0.734 lbs.) Weight (w/ Auxiliary Contacts) 5-25A: 332 grams (0.734 lbs.); 35-50A: 339 grams (0.750 lbs.); 60- 100A: 346 grams (0.766 lbs.) 2.0 lbs. max. Weight (Three Phase) OVERLOAD CALIBRATION DATA @ 25C Specification Table Must Hold Must Trip MIN MAX @ +71C MIN MAX @ -54C MIN MAX Test Time Parameters 115% % for 1 Hour 115% 115% 138% 150% % Within 1 Hour 138% LABINAL POWER SYSTEMS TF300-9E 9 REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) Engineering Data Single Pole Single Throw (Double Break Contacts) Rated Contact Load (Amperes) 28 Vdc Catalog Number SM600BA5A1 SM600BA5N1 SM600BA10A1 SM600BA10N1 SM600BA15A1 SM600BA15N1 SM600BA20A1 SM600BA20N1 SM600BA25A1 SM600BA25N1 SM600BA35A1 SM600BA35N1 SM600BA40A1 SM600BA40N1 SM600BA50A1 SM600BA50N1 SM600BA60A1 SM600BA60N1 SM600BA75A1 SM600BA75N1 SM600BA100A1 SM600BA100N1 115/200 V 400 Hz Res. Ind. Motor Lamp Res. 5 5 5 5 5 Ind. Motor Lamp 5 5 5 10 10 10 10 10 10 10 10 15 15 15 15 15 15 15 15 20 20 20 20 20 20 20 20 25 25 25 25 25 25 25 25 35 35 35 35 35 35 35 35 40 40 40 40 40 40 40 40 50 50 50 50 50 50 50 50 60 60 60 -- 60 60 60 -- 75 75 75 -- 75 75 75 -- 100 100 100 -- 100 100 100 -- Three Pole Single Throw (Double Break Contacts) Rated Contact Load (Amperes) Catalog Number 115/200 V 400 Hz Res. Ind. Motor Lamp MIL-PRF-83383 Part Number SM601BA10A1 10 10 10 10 SM601BA15A1 15 15 15 15 M83383/04-03 SM601BA20A1 20 20 20 20 SM601BA25A1 25 25 25 25 SM601BA35A1 35 35 35 35 M83383/04-07 SM601BA40A1 40 40 40 40 M83383/04-08 SM601BA50A1 50 50 50 50 SM601BA60A1 60 60 60 60 M83383/04-05 M83383/04-10 j Contact factory on alternate amperage, trip times, control configurations, grounding, auxiliary switches, and mounting systems. 10 LABINAL POWER SYSTEMS TF300-9E MIL-PRF-83383 Part Number Maximum Weight Oz/gm M83383/02-01 11.75/332 M83383/01-02 M83383/02-03 M83383/01-03 M83383/02-04 M83383/01-04 M83383/02-05 M83383/01-05 M83383/02-06 M83383/01-06 M83383/02-07 M83383/01-07 M83383/02-08 M83383/01-08 M83383/02-09 M83383/01-09 M8338/02-10 M83383/01-10 M83383/02-11 M83383/01-11 11.25/318 11.75/332 11.25/318 11.75/332 11.25/318 11.75/332 11.25/318 11.75/332 11.25/318 12.00/339 11.50/325 12.00/339 11.50/325 12.00/339 11.50/325 12.25/346 11.75/332 12.25/346 11.75/332 M83383/02-13 M83383/01-13 12.25/346 11.75/332 REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) ORDERING INFORMATION Three Pole Single Throw (Double Break Contacts) Single Pole Single Throw (Double Break Contacts) Standard AMPERE RATING 5 7.5 10 15 20 25 35 40 50 60 75 80 100 MS P/N M83383/01-01 * * * * M83383/01-03 M83383/01-04 M83383/01-05 M83383/01-06 M83383/01-07 M83383/01-08 M83383/01-09 M83383/01-10 M83383/01-11 M83383/01-13 w/ Auxiliary Contacts Labinal Power Systems P/N SM600BA5N1 ** SM600BA10N1 SM600BA15N1 SM600BA20N1 SM600BA25N1 SM600BA35N1 SM600BA40N1 SM600BA50N1 SM600BA60N1 SM600BA75N1 ** SM600BA100N1 MS P/N M83383/02-01 M83383/02-03 M83383/02-04 M83383/02-05 M83383/02-06 M83383/02-07 M83383/02-08 M83383/02-09 M83383/02-10 M83383/02-11 M83383/02-13 w/ Auxiliary Contacts Labinal Power Systems P/N ** ** SM601BA10A1 SM601BA15A1 SM601BA20A1 SM601BA25A1 SM601BA35A1 SM601BA40A1 SM601BA50A1 SM601BA60A1 MS P/N Labinal Power Systems P/N SM600BA5A1 ** SM600BA10A1 SM600BA15A1 SM600BA20A1 SM600BA25A1 SM600BA35A1 SM600BA40A1 SM600BA50A1 SM600BA60A1 SM600BA75A1 ** SM600BA100A1 M83383/04-03 M83383/04-05 M83383/04-07 M83383/04-08 M83383/04-10 All Ampere Ratings equal to Rated Contact Loads (Resistive, Inductive, Motor, and Lamp) except as noted. * No Lamp Load Rating ** Contact Factory Note: Contact factory on alternate amperage, trip times, control configuations, grounding, auxilary switches, mounting systems, etc. SINGLE POLE TRIPLE POLE OVERLOAD CALIBRATION DATA OVERLOAD CALIBRATION DATA Ratings Percent Ambient Temperature Tripping Time Rated Current Degrees C. 5 All 115% 138% 115% 150% 25C & 71C -54C No Trip 1 Hour Max.* No Trip 1 Hour Max.* Ratings Percent Ambient Temperature Tripping Time Rated Current Degrees C. 5 All 115% 138% 115% 150% 25C & 71C -54C No Trip 1 Hour Max.* No Trip 1 Hour Max.* * Must trip in one hour. * Must trip in one hour. OVERLOAD CALIBRATION DATA -- SINGLE POLE OVERLOAD CALIBRATION DATA -- THREE POLE AMPERE RATING 200% Trip Times -54C to +71C 400% Trip Times -54C to +71C 1000% Trip Times -54C to +71C MAX MIN MAX MIN MIN MAX AMPERES SECONDS SECONDS SECONDS SECONDS SECONDS SECONDS 6.4 7 40 5 0.3 1.2 1.2 6.8 11 40 7.5 0.33 2.4 1.1 8.5 12 42 10 0.42 2.8 1.05 8.3 13 45 15 0.35 1.7 1.2 7.6 14 46 20 0.4 2.9 1.15 8.7 15 50 25 0.4 2.6 1.3 8.3 16 55 35 0.35 2.8 1.3 9.2 16 55 40 0.36 2.9 1.3 10 13 55 50 0.4 2.9 1.25 13 13 60 60 0.26 2.6 1.8 13 13 60 75 0.26 2.5 1.8 12.5 14 60 80 0.3 2.7 2 13 17 63 100 0.38 3.5 1.9 200% Trip Times -54C to +71C 1000% Trip Times 400% Trip Times -54C to +71C -54C to +71C MAX MIN MIN MIN MAX MAX AMPERES SECONDS SECONDS SECONDS SECONDS SECONDS SECONDS 11 2.8 0.42 12 1.3 80 10 10 1.7 0.35 13 1.2 80 15 9.6 2.9 0.4 14 1.15 80 20 10 2.6 0.4 15 1.3 80 25 11 2.8 0.35 16 1.3 80 35 10 2.6 0.36 16 1.3 80 40 10 2.9 0.4 13 1.25 80 50 16 2.4 0.26 13 1.8 80 60 AMPERE RATING TRIP CURVE Contact business unit for trip curve. LABINAL POWER SYSTEMS TF300-9E 11 REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) Engineering Data Application Note Distributed Load Concept With RCCB Without RCCB 1/2 AMP C8 SWITCH SWITCH 1/2 AMP B U S S C8 100 AMPS 100 AMPS C8 100 AMPS RCCB L O A D RELAY B U S S MS22073-1/2 OR MS26574-1/2 L O A D FLIGHT DECK FLIGHT DECK Typical Wiring Diagrams Integrated Wire Termination Module (MIL-STD-1549) LOAD 3 LINE A1 A2 4 5A 5B 6 S3 S1 S2 Auxiliary Contacts When Applicable To Indicator/ Control Unit Circuit Breaker Internal Connection Type MS220731/2 OR MS26574Backup Control Power (when used) 1/2 115 V 400 Hz or 28 Vdc (Must be same AC Phase as the "Line" Power) Contacts and Coil Circuits Only LINE LOAD LINE LOAD LINE 3 4 5A 5B S3 S1 S2 To Indicator/ Control Unit Circuit Breaker Type MS220731/2 OR MS265741/2 Wiring for Multiple Line Protection 3 4 5A 5B 6 S2 S1 S3 A2 LOAD 3 4 5A 5B 6 3 4 5A 5B 6 Backup Control Power (when used) 28 Vdc Contacts and Coil Circuits Only A1 S1 S3 A2 B2 A1 C2 C1 B1 Intermittent Duty Coils Current Cut-Off Controlled Electronically Single Pole NOTE: Terminals 5A and 5B internally grounded to the mounting leg (s). Integrated Wire Termination (IWT) module accepts pin contacts P/N M39029/1-100 or -101. Use with insertion/extraction tool M81969/14-02. LABINAL POWER SYSTEMS TF300-9E Auxiliary Contacts S2 Intermittent Duty Coils Current CutOff Controlled Electronically 12 Auxiliary Contacts Internal Connection Three Pole REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) -- 1 POLE AND 3 POLE Engineering Data Approximate Dimensions - 1 Pole Typical Placement of Rating on Top Plane LOAD A2 .688/ 17.48 .172/4.37 DIA. 2 MTG. HOLES LINE A1 R. 20 5.08 50 Mtg. Flanges Main Contact Mate As Shown Position Indicator Red: Closed; Green: Open 1.200 30.48 2.940 74.68 3.250 82.55 2.250 57.15 .350 8.89 1.530 38.86 .42 10.67 .07 1.778 .056 1.42 .500 - .610 12.70 - 15.24 .180 4.57 Name Plate 4.26 108.20 Options * Special application auxiliary switches * Unique grounding * Power sources * Other current ratings * Control via systems other than I/CU *Low level auxiliary contacts available *Data Bus/Interface capability available * Electronically held coil * Moisture resistant sealing 3.42 86.87 .084 2.13 Three Pole LINE A1 3.69 93.73 2.03 51.56 3.29 83.57 .77 19.56 2.526 64.16 .05 1.27 .130 3.30 50 2.940 74.68 .07 1.78 .350 8.89 1.50 38.86 LINE C1 LOAD C2 2.526 64.16 2.28 57.91 LINE B1 LOAD B2 LOAD A2 Main Contact Position Indicator Red: Closed; Green: Open 4.26 108.20 Location of NamePlate 3.43 87.12 3.250 82.55 Coil Operate Current/Set And Trip Time RCCB Circuits 1 Pole 3 Pole MAX. Set Time Most Adverse 71C & Nominal Voltage & Condition - MIN. Nominal Voltage 71C. Voltage Room Temp. Ambient *I/CU. Trip Current Nominal 71C & -54C & Room Temp. Nominal Nominal Nominal Voltage Voltage Voltage Nominal System Voltage I/CU Set Current @ Nom Voltage (Mulliamp) Set Coil Current @ Nom Voltage Pulse 28 Vdc (18 volts MIN.) 115 Vac 400 Hz (104 V. MIN. 28 Vdc (18 volts MIN.) 115 Vac 400 Hz (104 V. MIN.) 2 3.0 AMP MAX 20 Millisec 35 Millisec 1.4 AMP 1.9 AMP 1.6 AMP 2 10 AMP MAX 15 Millisec 30 Millisec 6.8 AMP ** 6.3 AMP ** 2 7.0 AMP MAX 13.0 AMP MAX 20 Millisec 35 Millisec 1.5 AMP 15 Millisec 30 Millisec 4.3 AMP ** 2 * MAX. I/CU. Line Impedance 7.5 ** Average Half-Wave Rectified DC Current -54C & Nominal Voltage MAX. Standby Current Milliamp 0.9 AMP *** 2.1 AMP 10 8.6 AMP ** 6.1 AMP ** 7.0 AMP ** 10 2.0 AMP 1.7 AMP 2.2 AMP 10 3.3 AMP ** 4.5 AMP ** 0.9 AMP *** 4.0 AMP ** 3.1 AMP ** 10 Current Decreases w/Time so that I2t ***Absolute Min. Value from -54 to +71C LABINAL POWER SYSTEMS TF300-9E 13 REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) -- 1 POLE AND 3 POLE Engineering Data Description The Remote Control Circuit Breakers (RCCB) concept, as load controllers in distributedload applications, provides for a more efficient power distribution system with less line loss at a lower cost and with less weight than the conventional relay-flight deck circuit protector method. Designed to meet the requirements of MIL-PRF-83383, the RCCB's capability and advantages include: * Fusible link fail safe * Remote on/off operation from the flight deck * Visual indicators for open (green) and closed (red) on top surface * Substantial reduction in weight and size * Most direct route from power source to load * Single wire control line from I/CU to RCCB * Double-break power contact assembly *Indication of trip or set by position of the 1/2 ampere circuit breaker on the flight deck * Elimination of long runs of heavy and costly cables * Magnetically latched coils (low power consumption) * Use as a relay or circuit breaker or both * Flanges mate for in-line or side-by-side mounting *1PST for DC or single phase AC *3PST for three phase AC only Application The Remote Control Circuit Breaker (RCCB) is a combination relay and circuit breaker which can be released or set by applying a release or set coil current electronically controlled 14 LABINAL POWER SYSTEMS by a command from the Indicator/Control Unit (I/CU) (a 1/2 ampere fast trip, thermal circuit breaker). With power available to terminal #4 and/or terminal A1 (28 Vdc or 115 V 400 Hz) on 1PST RCCB: to terminal #4 (28 Vdc) and/ or both terminals B1 and C1 (115 V 400 Hz) on 3PST RCCB, the RCCB will assume the state requested/indicated by the I/CU. If power is removed from terminal #4 and A1 on 1PST or from terminal #4 and both B1 and C1 on 3PST, the RCCB will remain in the state it was in prior to power removal. When power is reapplied to the terminals, the RCCB will assume the state indicated by the I/CU. With the RCCB closed, an overload or fault current on any line or lines will cause the RCCB to trip and in turn will cause a controlled overload of the I/CU, causing it to trip also. A fault or overload on any power contact will cause the RCCB to trip open within the time limits specified regardless of the availability of coil power. To reclose the RCCB, the I/CU line (line 3 to ground) must be opened by the I/CU or series switch and reconnected to ground. Other Performance Parameters For MILPRF-83383 * Coordination. An overload applied to two devices in series with a 2 to 1 current rating will result in only the lower rated device opening. * Rupture capability to 3600A (115 Vac rms or 28 Vdc for SM600BA and 115 Vac rms for SM601BA series) * Dielectric. 1500 V, 60 Hz, MIL-STD-202, Test Method 301, 0.5 MA maximum TF300-9E * Explosion-proof. MILSTD-202, Test Method 109 * Thermal Temperature Range. -54C to 71C (-65F to 160F). MIL-STD-202, Test Method 107 * Insulation Resistance. MILSTD-202, Test Method 302, 100 Megohms minimum * Aircraft Electrical Power. MILSTD-704 * Vibration. 10 g's to 2000 Hz. MIL-STD-202, Test Method 204. Condition C (-54C, 25C, and 71C). Maximum duration of contact transfer to uncommanded state: 10x10-6 seconds. * Shock. 25 g's. MIL-TD-202, Test Method 213. Maximum duration of contact transfer to uncommanded state: 10x10-6 seconds. * Altitude. 50,000 feet * EMI, MIL-STD-461, Class 1D * Moisture Resistance. MILSTD-202, Test Method 106 * Fungus Resistance. MIL-STD454, Guideline 4 * Sand and Dust Resistance. MIL-STD-202, Test Method 110, Test Condition A * Salt Spray Resistance. MILSTD-202, Test Method 101, Test Condition B REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) Single Pole Design Concept * 28 VDC * 115/200 VAC 400 Hz Introduction Three Phase * 115/200 VAC 400 Hz * Three Phase Only Qualified Meets MIL-PRF-83383 Weight and Cost Savings Saves fuel by eliminating long runs of heavy, costly cables Space Savings Keeps larger breakers out of cockpit RCCB System for Remote Operation To form an RCCB system enabling remote On/Off operation from the flight deck, combine the Labinal Power Systems RCCB with Indicator Control Unit (ICU) model #1500-053-05 on pg. 13. Single Wire from Flight Deck Control of the RCCB requires only one #22 AWG control wire from the ICU on the flight deck to the RCCB. Use as a Relay, Circuit Breaker, or Both Combines the best attributes of a circuit breaker and a relay. Automatically protects the wires and the load device during circuit/load breakdown, but allows the flight deck control of the load during normal operation. Part of the weight of the modern jet aircraft comes from the electrical wires and power control systems needed to distribute the electrical energy. As these aircraft increase their passenger carrying capability, the electrical power management system becomes more complex and could become heavier. Wire runs of more than 300 feet from the flight deck circuit breakers to the load become common. Utilization of Labinal Power Systems' Remote Controlled Circuit Breakers (RCCB) close to the load or power source will eliminate much of these long, heavy, and expensive wire/ cable. Control of the RCCB requires only one #22 AWG control wire from the flight deck to the RCCB. Weight reduction, directly from wire use and indirectly from (generator) line heat loss, and installation and maintenance cost reductions becomes significant. The RCCB combines the best attributes of a circuit breaker and a relay. The RCCB automatically protects the wires and the load device during circuit/load breakdown, but allows flight deck control of the load during normal operation. Operation The RCCB is basically a relay and a circuit breaker and allows the utilization of each identity singularly or in combination, depending upon the application. All of the RCCB's capabilities apply in either application. It can be employed as a relay located adjacent to its load and remotely operated much like relays are today through control wiring and a switching device in the flight deck. LOAD-L1 LOAD-L2 BI-METAL J K E-PIVOT N G-PIVOT I LATCH BAR STATIONARY CONTACTS H-LATCH C M MOVEABLE CONTACT BRIDGE L-LEVER D ARMATURE S1 S2 B TRIP (OPEN) COIL SET (CLOSED) COIL A T1 T2 PERMANENT MAGNET DOUBLE THROW TOGGLE SWITCH SET POSITION TRIP POSITION LOAD-L2 Figure BI-METAL 1 LOAD-L1 Single Pole RCCB magnet itself. Its path now, K however, is through the right leg STATIONARY of the electro-magnet. The flux Motor Operation CONTACTS MOVEABLE generated by the electro-magnet N G-PIVOT H-LATCH increases in magnitude as CONTACT Figure 1 depicts a simplified L-LEVER I power is applied, and as the BRIDGE flux presentation of the RCCB. LATCH C builds up in the path through M BAR D Figure 2 describes the "motor", the right leg of the electrowhich when "energized", will B ARMATURE S magnet, the flux tending to latch TRIP result in typical armature SET the(OPEN) armature in the left leg of A transfer operation. (CLOSED) COIL the electro-magnet becomes N COIL B T1 T2 The magnetic circuit SET utilizes very TRIP small in comparison. The A (OPEN) then "transfers" and a permanent as a armature S1 S2 magnet (CLOSED) COIL fulcrum and latch forPERMANENT the rocking MAGNETseals at the pole face of COIL T1 the T2 armature and uses electroright leg of the electro-magnet. S1 S2(coils) at each end of magnets The cutthroat contact B in series MAGNET the armature strokePERMANENT for transfer with coil T1 -T2 is opened by purpose. In the set position mechanical actuation due to DOUBLE (Figure 2), the flux generated byTHROW the armature movement. In TOGGLE SWITCH the permanent magnet follows Figure 2, a "dotted extension" a patch from the top of the of the armature represents permanent magnet through the SET TRIP the mechanical actuator of the armature, through thePOSITION left leg of POSITION cutthroat contacts. In actual the electro-magnet and back to design, this is accomplished the permanent magnet. more conveniently through only When the coil T1 -T2 is one armature extension and energized, the flux generated an appropriate actuator which is such that it "flows" through drives both contacts B and A. the permanent magnet in the same direction as the flux generated by the permanent J E-PIVOT It can also be utilized as a circuit breaker and mounted adjacent to the load, the power source, or even the flight deck. S A S1 S2 SET (CLOSED) COIL N TRIP (OPEN) COIL B T1 T2 PERMANENT MAGNET Figure 2 LABINAL POWER SYSTEMS TF300-9E 15 REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) -- DESIGN CONCEPT BI-METAL The opening of contact B occurs in the last several thousandths of an inch travel of the armature movement. After coil opening, the armature movement continues (until it seats i.e. seals), due in some degree to the inertia of the armature, but mostly due to the magnetomotive force of the permanent magnet in conjunction with the decreasing air gap at the right pole face. The device now is again in a stable position, but the armature has transferred and the following conditions exist: Contact A is closed and contact B is open, and the armature is sealed and latched at the right leg of the electro-magnet. To transfer the armature to its original position, energizing the coil S1-S 2 allows the process described above to occur in the opposite direction. There are a number of advantages to this design approach of the "motor." 1.The coils open upon transfer of the armature; hence, the actual "on time" or duty cycle approximately equals the operate time of the relay. Accordingly, the coil can be driven hard without fear of burnout. The "hot coil" with the low timer constant results, in turn, in fast operate times. 2.Using intermittent duty coils (smaller coils with less copper) results in less weight and smaller sizes. 3.Power is conserved. This is important for two reasons. If a relay is to use power, it must be available. In some of the present day and future vehicles, power remains an expensive commodity, and elimination of coil power drawing (10-35 watts) in power devices can add up 16 LABINAL POWER SYSTEMS J especially when vehicles sophistication requires use of a significant number of these devices. Also, it must be remembered that power utilized by relay coils generate heat which must be dissipated. The necessary elimination of this heat, in turn, requires the use of additional energy from the main power source. A S2 LOAD-L1 K LOAD-L1 K MOVEABLE K CONTACT BRIDGE MOVEABLE E-PIVOT H-LATCH N E-PIVOT H-LATCH M C N STATIONARY CONTACTS STATIONARY CONTACTS L-LEVER STATIONARY CONTACTS D L-LEVER H-LATCH C ARMATURE M U1 U2 CONTACT MOVEABLE BRIDGE CONTACT BRIDGE L-LEVER D C ARMATURE SET S (CLOSED) ARMATURE COIL SET S BUCKING (CLOSED) N SET COIL COIL S (CLOSED) BUCKING N COIL COIL PERMANENT MAGNET BUCKING N COIL M S2 S1 LOAD-L2 N A U2 U1 A U2 U1 S1 S2 S1 LOAD-L1 E-PIVOT LOAD-L2 BI-METAL J I G-PIVOT LATCH BAR I G-PIVOT LATCH I BAR LATCH BAR 4.As indicated, the cutthroat contacts are opened by the armature mechanically during the last several thousandths of an inch travel of armature movement. Note: In actual RCCB, the cutthroat contacts function is replaced by electronic control of coil on time. TRIP (OPEN) COIL TRIP BUCKING (OPEN) TRIP COIL COIL (OPEN) BUCKING COIL COIL BUCKING COIL D B T2 T1 B V1 V1 B V1 T1 V1 V1 T1 T2 T2 V1 PERMANENT MAGNET PERMANENT MAGNET Figure LOAD-L2 BI-METAL J J G-PIVOT To examine the RCCB operation as a relay, refer to Figure 3 and 4. The device is shown in the set position in Figure 3 and in the tripped position in Figure 4. The circuit path is from L2, through the bimetal to one of the stationary contacts. L1 is connected directly to the other stationary contact. S1 S1 S2 U2 U1 S1 U2 LOAD-L1 E-PIVOT H-LATCH C E-PIVOT N H-LATCH C N H-LATCH ARMATURE C M M M ARMATURE SET ARMATURE S (CLOSED) COIL SET S BUCKING (CLOSED) N SET COIL COIL S (CLOSED) BUCKING N COIL COIL PERMANENT MAGNET BUCKING N COIL STATIONARY CONTACTS L-LEVER STATIONARY CONTACTS L-LEVER K K MOVEABLE CONTACT BRIDGE MOVEABLE CONTACT MOVEABLE BRIDGE CONTACT BRIDGE D L-LEVER D TRIP (OPEN) D COIL TRIP BUCKING (OPEN) TRIP COIL COIL (OPEN) BUCKING COIL COIL BUCKING COIL PERMANENT MAGNET Figure PERMANENT MAGNET The movable bridge closes the circuit by bridging between the two stationary contacts. LOAD-L1 K STATIONARY CONTACTS N U1 A U2 U1 A S2 LOAD-L1 E-PIVOT LOAD-L2 BI-METAL A S2 3 LOAD-L2 BI-METAL J I G-PIVOT LATCH BAR I G-PIVOT LATCH I BAR LATCH BAR RCCB Operation As A Relay As can be seen, movement of the armature about its fulcrum will determine the position of the contacts. When coil S1-S 2 has been energized such that the armature seals on the left-hand pole face (Figure 3), the mechanical linkage system closes the contacts. Conversely, when coil T1-T 2 has been energized, such that the armature seals on the righthand pole face (Figure 4), the relay contacts will open due to the spring forces exerted by compression spring K. J G-PIVOT BI-METAL LOAD-L2 B V1 B T2 T1 T2 V1 T1 V1 B V1 V1 T2 T1 V1 4 LOAD-L2 BI-METAL BI-METAL J BI-METAL J G-PIVOT J I G-PIVOT LATCH BAR I G-PIVOT LATCH I BAR LATCH BAR M LOAD-L2 LINE-L1 LOAD-L2 E-PIVOT LINE-L1 N E-PIVOT H-LATCH N E-PIVOT H-LATCH N H-LATCH STATIONARY L-LEVER CONTACTS STATIONARY CONTACTS L-LEVER M M A A S1 S2 S1 S2 S1 S2 A D ARMATURE ARMATURE SET ARMATURE (CLOSED) LINE-L1 K STATIONARY CONTACTS K K CONTACT MOVEABLE BRIDGE CONTACT BRIDGE L-LEVER D S S COIL SET N (CLOSED) S SET COIL N (CLOSED) PERMANENT MAGNET COIL N D TRIP (OPEN) COIL TRIP (OPEN) TRIP COIL (OPEN) COIL Figure 5 PERMANENT MAGNET MOVEABLE CONTACT BRIDGE MOVEABLE B B T1B T2 T1 T2 T1 T2 Note: there is an "upward force" directed on the lever L through the linkage tying into the armature PERMANENT MAGNET at point D. During operation as a relay, point C (interface between lever L and latch bar I) is "fixed" in place, and the lever L actually rotates about point C when moving the contact structure from the opening to the closed, and from the closed to the open position. TF300-9E REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) -- DESIGN CONCEPT Note that the coil U1-U2 is connected in parallel with T1-T2. It is wound on the left-hand core of the electro-magnet such that when energized along with T1-T2, the force it generates will be in a direction opposing the latching force generated in that core by the permanent magnet. bar I counter-clockwise around its pivot point G. This allows the main lever L to rotate clockwise around point D (where it is engaged with the armature) due to the "contact return" spring (compression spring) force K acting upon the moveable contact bridge. The utilization of a permanent magnet and intermittent duty coils, in conjunction with cutthroat contacts, allows a considerable reduction in copper and iron from that normally required in electro-magnets for continuous duty operation. Note that when this overload occurs, the armature is not transferred to the "off" (tripped) position, but instead remains in the latched position normally associated with the "on" (set) position of the device. RCCB Operation as a Circuit Breaker To examine the operation of the device as a breaker, refer to Figures 3, 4, and 5. In Figure 3, the device is shown in the closed contact position (presumably) carrying rated current. Should an overload occur, currents greater than rated currents now "flow" through the device "entering" through L2, passing through the bimetal, through the connection of the bimetal to one stationary contact, through the bridging moveable contact structure, to the other stationary contact, and "out" through L1. Depending upon the size of the overload, the bimetal will begin to deflect as shown in Figure 5 until the actuating end of the bimetal engages latch H at point J. Motion and force due to the deflection of the bimetal moves latch H such that it rotates in a counter-clockwise direction around its pivot point E. When latch H has moved an adequate distance, the upward force of lever L, applied at point C to latch bar I, will rotate latch To "reset" the device after the fault or overload clears could be readily accomplished by energizing the "trip" coil (T1T2) through a toggle or pushbutton switch (see Figure 1) located in the flight deck. The armature would then transfer and seal on the right-hand core of the electro-magnet, which is the "open" position shown in Figure 4. At that time, springs M and N (tension springs) would reposition latch bar I and latch H to the position shown in Figure 4, providing that the bimetal has now cooled sufficiently and returned to its original position as shown in Figure 4. At this stage, the RCCB is still in an "open position" i.e. (the contacts are open), but as outlined above, the fault or overload has been cleared through action and operation of the device through bimetallic activity, i.e. "Circuit Breaker" operation. OB 1O AC 2.5 MILLISECONDS 1.0 RECTIFIED AC 1.25 MILLISECONDS OFF TIME OB OC 2O AC 2O RECTIFIED AC APPROXIMATELY 0.4 MILLISECONDS OFF TIME Figure 6 To re-close the contacts, it is now only necessary to energize coils S1-S2 and re-establish a mechanism position similar to that shown in Figure 3. If the fault of overload condition is still in existence, the device would again trip through bimetallic activity as just described. LABINAL POWER SYSTEMS TF300-9E 17 REMOTE CONTROLLED CIRCUIT BREAKER (RCCB) -- DESIGN CONCEPT Three Pole RCCB phases. The "off" time between current pulses during coil energization is approximately 0.4 milliseconds. In comparison, the "off" time for single-phase power is approximately 1.25 milliseconds. See Figure 6. The design principles employed in the 3-pole RCCB have followed many of the same paths utilized in the 1-pole RCCB. Differences other than the obvious, such as size, weight, shape, etc., are explained below. The timing circuit establishes a coil "on" time longer than the actual transfer time of the armature. The operation of the 3-pole RCCB is identical to the 1-pole. Motor Operation The principles of motor operation and construction of the three pole devices are similar to those employed in the single pole RCCB. In the 3-pole device, the AC operating power is drawn from two of the three Control Circuit Refer to Figure 7. There is one minor difference in operating principles and parameters from OB OC the single pole devices. The difference is the addition of a power junction area in the electronics. (see Figure 7). The 3-pole RCCB is designed for use in 3-phase circuits and is a 400 Hz AC load controller. The power junction is designed to use AC power only. DC operate (coil) power may be used even though AC loads are to be controlled. This connection is made at terminal 4 of the IWTS connector. In Figure 7, two separate power junctions are shown: one for AC and one for DC. In the event both AC and DC are connected to the RCCB, only AC would be utilized by the Set Coil POWER JUNCTION The other differences between 1-phase and 3-phase control circuitry, i.e. timer addition, is directly related as described in the above Motor Operation section. EMERGENCY (BACK-UP) POWER 28Vdc LINE POWER 115 V 400 Hz * logic circuit. Should AC power be lost, the DC connection would automatically take over the control function. DC TRIP COIL LOGIC POWER SUPPLY SET SWITCH (FET) 1/CU (1/2 AMP C.B.) LOGIC TIMER Figure 7 *Indicates In 3 Phase Electronics 18 LABINAL POWER SYSTEMS TF300-9E TRIP SWITCH (FET) REMOTE POWER CONTROLLERS -- WITH ELECTRONIC CURRENT SENSING PERFORMANCE DATA Single Pole * 28 VDC Electronic Current Sensing The electronic over current sensing of these devices offer several advantages over the bi-metal sensing RCCB. Trip current levels can be closely controlled, for better protection of sensitive loads, trip times are faster, and both can be customized for specific applications. Other advantages included less heat buildup, and higher current capabilities in the same small package. Use as a Relay, Circuit Breaker, Or Both RPCs, like RCCBs, combine the best attributes of a circuit breaker and a relay. Automatically protects the wires and the load device during circuit/load breakdown, but allows the flight deck control of the load during normal operation. Rupture Levels 2500 A (28VDC) Endurance (Resistive) 50,000 Cycles Endurance (Inductive and Motor) 25,000 cycles Endurance (Lamp) No Rating Mechanical Life 100,000 cycles Dielectric Strength Sea Level - VRMS .2-3 seconds: Coil to Case - 1250 initial. 1,000 After Life, All other Points 1,800 Initial, 1350 After Life 50,000 ft - VRMS 1 Minute: Coil to Case 500 Initial & After Life. All other Points 700 Initial & After Life Insulation Resistance 1100 Megaohms initial, 50 Megohms after Life, MIL-STD-202, method 302, test condition B Thermal Temperature Range -55C to 85C (-67F to 185F). Vibration Sinusoidal 5 to 10 Hz: 0.08 DA; 10 TO 55 Hz: 0.06 DA; 55 to 2000 Hz: 10G's Shock 50G's. (1/2 sine, 10-12 ms) Altitude 50,000 ft. Maximum EMI Requirements MIL-STD-461, Requirements CS114 and RE102 over the frequency range of 14 kHz to 400 MHz and RE102 limits for Aircraft and Space Systems Moisture Resistance MIL-STD-202, method 106 Salt Spray Resistance MIL-STD-202, method 101, Condition B Sand and Dust Resistance MIL-STD-202, method 110, Condition A Fungus Resistance MIL-HDBK-454, Guideline 4 Explosion Proof MIL-STD-202, method 109 Weight (Standard) 425.017 grams (0.937 lbs.) OVERLOAD DATA Weight and Cost Savings In distributed-load applications, RPCs are a more efficient power distribution solution promoting cost and weight savings through the elimination of long runs of heavy cables associated with the conventional relay - flight deck circuit protector method. Control of the RPC requires only one #22 AWG control wire from the ICU (model #1500-053-05) on the flight deck to the RPC. % Rated Current 100% 125% 200% 400% Trip in Seconds -55C to +85C No Trip 45 Sec. Trip 0.22 Sec. Trip 0.095 Sec. Trip ORDERING INFORMATION Single Pole Single Throw (Double Break Contacts) AMPERE Labinal Power RATING Systems P/N 125 150 175 200 SM600BA125A1 SM600BA150A1 SM600BA175A1 SM600BA200A1 Rated Contact Load (Amperes) 28 VDC Res. 125 150 175 200 Ind. Motor Min. 125 125 5 150 150 5 150 175 5 150 175 5 Notes: * One auxiliary contact included on each unit * Contact Business Unit on Alternate Amperages, Trip Times, Control Configurations, Grounding, Auxiliary Switches, Mounting Systems, etc. LABINAL POWER SYSTEMS TF300-9E 19 REMOTE POWER CONTROLLER (RPC) Engineering Data Approximate Dimensions - 1 Pole Integrated Wire Module Typical Placement of Rating on Top Plane LOAD A2 .688/ 17.48 LINE A1 .172/4.37 DIA. 2 MTG. HOLES 125 .256/6.50 2.940 74.68 3.250 82.55 .150 3.81 Position Indicator Red: Closed Green: Open 2.250 57.15 Barrier Black Nylon Per MIL-M20693A Type I. General Purpose .350 8.89 1.530 38.86 1.200 30.48 .42 10.67 .07 1.778 .056 1.42 .05/1.27 Terminal Pad .6 DIA. .180 4.57 Name Plate 4.26 108.20 3.42 86.87 R.06 1.52 Typical Wiring Diagram Approximate Dimensions Auxiliary Contacts S2 S1 S3 A2 A1 LOAD A2 3 To Indicator / Control Unit Circuit Breaker Type MS22073 - 1/2 Or MS26574 - 1/2 LINE A1 A2 A2 A2 3 28 VDC Back Up Power 4 Over Current Detector 5A 5B Module: Integrated wire termination. Terminals will accept PIN contact per M39029/1 - 101. Use insertion/extraction tool M81969/14 - 02. 5A 3 4 5B COIL OPERATE CURRENT/SET AND TRIP TIME Set Coil Current @Nom Voltage Pulse Nominal Voltage @ Room Temp Most Adverse Condition-Min. Voltage 71C Ambient 71C and Nominal Voltage -54C and Nominal Voltage Room Temp and Nominal Voltage Max. Standby Current (milliamp) 28 VDC (18 volts Min) 3.7 Amp 20 Millisec 35 Millisec 1.76 Amp 1.25 Amp 1.89 Amp 30 2 * MAX I/CU. LINE IMPEDANCE 7.5 Ohms 20 *I/CU. Trip Current Nominal MAX. Set Time Nominal I/C Set System Current @ Voltage Nom. Voltage (milliamp) LABINAL POWER SYSTEMS TF300-9E CURRENT DECREASES W/TIME SO THAT I2t >= 2 S3 S2 S1 POWER RELAYS -- GASKET SEALED - 100 AMPS TO 1,000 AMPS Typical Characteristics Part Number Rated Contact Load Rupture Current 28 Vdc Contact Rating Intermittent Power Specifications * Design to meet the general requirements of MIL-R-6106 Type II continuous Duty Unsealed * Contacts are covered & gasketed * Double break contacts * All units are thermal breaker compatible at rated relay resistive load * Some models available with auxiliary circuits * Gold-plated auxiliary contacts for low-level applications available * Auxiliary contacts ratings: 28 Vdc: 5 amps resistive 3 amps inductive 2.5 amps lamp Ratings Per MIL-R-6106: 28 Vdc SM100D2 SM100D3 SM150D1 SM150D2 SM150D3 SM150D4 SM150D5l Res. Ind. Motor Intermediate 100 100 150n 150n 150n 150n 80 80 50 50 50 50 50 100 100 100 100 100 100 -- 100 100 150j 150j 150j 150j 150j 200 200 200 400 400 400 -- 4 4 15 15 15 15 15 20 20 20 40 40 40 50 150 200 200 200 400 400 400 1000 SM200D1 SM200D2 SM200D3 SM400D1 SM400D2 SM400D3 SM1000D11r 1000 1000 1200 1200 1200 1200 1200 2000 2000 2000 4000 4000 4000 6000 15 Minute 5 Minute 1 Minute Max.o Inrush 130 130 195 195 195 195 195 260 260 260 520 520 520 1200 150 150 225 225 225 225 225 300 300 300 600 600 600 1500 200 200 300 300 300 300 300 400 400 400 800 800 800 2000 600 600 900 900 900 900 900 1200 1200 1200 2400 2400 2400 2500s j 600 Amp make, 200 Amp break kDuty cycle: 1 minute on, 1 minute off; 1 minute on, 20 minutes off lMaximum vibration 2000 Hz 2 g's mDuty cycle: 1.5 minutes on, 3 minutes off nWill carry 200 Amps at 20% on duty cycle per minute *Salt spray, humidity, accelera tion, sand & dust, intermediate current * Vibration: 5 to 10 Hz -.08 DA 10 to 55 Hz -.05 DA 55 to 500 Hz -2.0 g's * Shock: 25 g's (6-9 MS 1/2 sine wave) * Life: (-55 to 71C) 50,000 cycles electrical at full rated load 100,000 cycles mechanical tested at 25% rated load * Altitude: 50,000 feet oMaximum inrush provided coil voltage as noted is maintained pOperate time at 28 Vdc & 25 deg. C. qContact bounce is average of 5 conse cutive ratings. rAvailable in normal closed circuit. s 1 sec. on, 60 sec. off Circuit Diagrams A1 A1 A1 X1 A2 X1 A2 A2 A1 X1 13 X2 X2 12 #1 X2 #1 #1 #1 Typical Characteristics (Figures 1 through 8) (For additional details, contact your local Labinal Power Systems Technical Sales Representative) 11 X1 A1 A1 A2 A2 A2 13 23 13 12 2322 12 11 11 X1 23 2221 22 21 X1 21 X2 B1 A2 A1 A2 B1 B1 A1 11A1 23 12 11 22 1111 21 12 X112 11 #2 X2 X2 #2 #2 #2 * Power Contact Voltage Drop: Initial 0.15 V After Life Test: 0.175 V * Insulation Resistance: Initial 200 Meg ohm. * After Life Test: 100 Meg ohm A2 A2 22 21 X2 Dielectric Withstanding Voltage: 23 22 21 X1 X1 A2 23 X211 X2 A2 #3 #3 50,000#3Feet 60 Seconds Initial & After Life Test: 500 V 2.5 Seconds Sea Level Initial: 1250 V After Life Test: 1000 V Power Contacts: 650 V #3 LABINAL POWER SYSTEMS TF300-9E 21 POWER RELAYS -- GASKET SEALED - 100 AMPS TO 1,000 AMPS Contact Transfer Milliseconds, Max. Coil Data Op.o Time Rel. Time Contact Bounceq Poles & Throw Weight Lbs./gm Circuit Dia. Dimension Fig. Res. (OHMS) Max. Volts Pick Up Max VoltsDrop Out Duty Cycle Mounting Auxiliary Termination Part Number 35 35 40 40 15 15 40 25 25 25 40 40 20 60 15 15 15 15 12 12 15 10 10 18 15 15 15 30 6 6 5 5 5 5 5 2.5 2.5 5 10 10 10 3 SPST/NO SPST/NO SPST/NO SPST/NO SPDT SPDT SPDT SPST/NO SPST/NO SPST/NO SPST/NO SPST/NO SPST/NO SPST/NO 0.6/272 0.6/272 0.95/430 0.95/430 1.25/567 1.25/567 1.25/567 1.3/588 1.3/588 1.3/588 2.6/1177 2.6/1177 2.6/1177 4/1810 1 1 2 2 3 3 3 2 2 2 2 2 2 1 1 2 3 3 4 4 4 5 6 6 7 8 8 9 94.2 94.2 82.7 82.7 6.6 6.6 60 66 66 10 60 60 10 38 18 18 16.5 16.5 6.5 6.5 18 18 18 7.5 18 18 7.0 18 7 to 1.5 7 to 1.5 1 to 7 1 to 7 0.2 to 3 0.2 to 3 0.6 to 8.5 1.5 to 7 1.5 to 7 0.5 to 3 1.5 to 7 1.5 to 7 0.5 to 3 1 to 7 Cont Cont Cont Cont Interk Interk Cont Cont Cont Interm Cont Cont Interm Cont Side Top B B B B B Side B B Side B B Side -- -- Screw IWTS Screw IWTS Screw Lug Lug Lug Lug Lug Lug -- SM100D2 SM100D3 SM150D1 SM150D2 SM150D3 SM150D4 SM150D5 SM200D1 SM200D2 SM200D3 SM400D1 SM400D2 SM400D3 SM1000D11 j600 Amp make, 200 Amp break kDuty cycle: 1 minute on, 1 minute off; 1 minute on, 20 minutes off lMaximum vibration 2000 Hz 2 g's mDuty cycle: 1.5 minutes on, 3 minutes off nWill carry 200 Amps at 20% on duty cycle per minute oMaximum inrush provided coil voltage as noted is maintained pOperate time at 28 Vdc & 25 deg. C. qContact bounce is average of 5 consecutive ratings. rAvailable in normal closed circuit. Dimensions (See next page for other dimension figures) Figure 9 Insulation Resistance: Initial: 100 Meg ohms After Life Test: 50 Meg ohms Dielectric Withstanding Voltage: (2.5 Seconds Sea Level) Initial: 1250 V After Life Test: 1000 V Unit Shown Without Auxiliary Contacts Life at 1000 Amps limited to 10,000 cycles. Life at 50 Amps is 50,000 cycles minimum. Rupture life is 20 cycles at 6000 Amps. This unit is available with inverted terminals, bottom mounting, available with normally closed power contacts, and DPDT auxiliary circuits. 22 LABINAL POWER SYSTEMS TF300-9E POWER RELAYS -- GASKET SEALED - 100 AMPS TO 1,000 AMPS Dimension Figures Figure 1 Figure 2 .219 (5.56) DIA. (2) MOUNTING HOLES 2.22 (56.3) .625 (15.87) .219 (5.56) DIA. MOUNTING HOLES .250 (6.35)-28 UNF-3A 2 Power Term 2.22 (56.38) 2.188 (55.5) X2 1.312 (33.3) 2.64 (67) 2.68 (68) Unit Shown Without Auxiliary Contacts Unit Shown Without Auxiliary Contacts 1.72 (43.69) .986 (25.0) 2.68 (68.0) X1 .625 (15.8) 2.75 (69.85) .422 (10,7) .937 (23.8) 2.68 (68) 1.875 (47.62) .250 (6.35)-28 UNF-3A 2 POWER TERM SM100D3 SM100D2 Figure 4 .203 (5.15) .005 DIA. 4 MOUNTING HOLES .250 (6.35)-28 UNF-2A 4 POWER TERMINALS 2.19 (55.6) (47.5) 187 MTG 2.75 2.75 (69.8) B2 A2 #6-32 UNC-2A 2 COIL TERMINALS #6-32 UNC-2A 6 AUX. TERMINALS 2.25 .75 (19) SM150D1 X2 X2 A2 #6-32 UNC-2A 2 COIL TERMINALS (57.1) X1 B3 A1 X1 A1 (69.8) X1 1.87 MTG (47.5) #6-32 UNC-2A 6 AUX. TERMINALS 2.25 (57.1) SM150D3 SM150D5 .75 (19) .75 4.50 (114.3) (114.3) (19) 4.50 .203 (5.15) .005 DIA. 4 MOUNTING HOLES X2 1.87 MTG #6-32 UNC-2A (47.5) 2 COIL TERM 187 MTG (47.5) .250 (6.35)-28 UNF-2A 2 POWER TERMINALS 2.19 (55.6) Figure 3 2.25 2.25 (57.1) (57.1) WILL ACCEPT TERMINAL-PIN CONNECTION (DEUTSCH PART NO. 1841-1-5620) SM150D2 1.72 (43.6) 2.385 (60.55) WILL EXCEPT TERMINAL-PIN CONNECTION (DEUTSCH PART NO 1841-1-5620) SM150D2 SM150D4 SM150D4 LABINAL POWER SYSTEMS TF300-9E 23 POWER RELAYS -- GASKET SEALED - 100 AMPS TO 1,000 AMPS Dimension Figures Figure 5 Figure 6 2.00 (50.8) 2 X STUD, THD .500-20 UNF-2A POWER TERMINAL .916 (23) 2.438 MAX. 1.219MAX. .500 MIN. .475 4.45 (113.03) MAX. 3.25 (82.55) 3.85 (97.8) .781 (19.8) .125 (1.13) .266 2 MTG. HOLES (6.75) .984 (25) .058 DIA. TERMINALS TO FIT "AMP" LUG PT 61276-2 2 X STUD, THD .138-32 UNC-2A 3.000 (76.20) 2.395 (60.8) 5.500 MAX. (139.70) 4.312 (109.47) .375 (9.5)- UNF-2A A1 A2 X1 X2 3.5 (68.9) 1.89 (48.01) 3.65 (92.7) MAX. #6-32 UNC-2A COIL TERMINALS A1 A2 X1 X2 4.500 (76) SM200D2 SM200D3 SM200D1 Figure 8 Figure 7 .500 (12.7)-20 UNF-2A POWER TERMINAL 2 X STUD, THD .500-20 UNF-2A POWER TERMINAL 2 X STUD, THD .138-32 UNC-2A .058 DIA. TERMINALS TO FIT "AMP" LUG PT 61276-2 .058 (1.47) DIA. TERMINALS TO FIT "AMP" LUG PT 61276-2 .266 (6.76) DIA. 2 HOLES FOR MTG X1 A2 1.89 (48.01) 3.53 (89.66) MAX. 5.500 MAX. (139.70) 2.25 (57.15) 4.312 (109.47) A2 5.50 MAX. (139.70) A1 X2 SM400D1 LABINAL POWER SYSTEMS TF300-9E 4.45 (113.03) MAX. .266 2 HOLES FOR (6.76) MOUNTING .062 (1.575) X2 4.31 (109.47) 24 .475 3.25 (82.55) 4.38 MAX (61.93) 3.000 (76.20) A1 1.219 MAX. 1.06 (26.9) 3.92 (99.57) 1.28 (32) MAX .81 (20.57) #6-32 UNC-2A COIL TERMINAL 2.438 MAX. .500 MIN. 1.000 .125 2.406 (61.11) 1.05 (26.67) TYP. 2.25 (57.15) 4.00 (101.6) .266 2 HOLES FOR (6.76) MOUNTING .062 (1.575) .058 (1.47) DIA. TERMINALS TO FIT "AMP" LUG PT. NO. 61276-2 X1 SM400D2 SM400D3 POWER RELAYS -- CONTINUOUS DUTY, TYPE II, UNSEALED INTERMITTENT DUTY, TYPE III, UNSEALED General Specifications * Designed to MIL-R-6106 - Type II Unsealed Continuous Duty - Type III Unsealed Intermittent Duty - Covered/Gasketed Contact Area - Twin-break Silver Alloy Contacts * Meets Explosion, Humidit, Salt, Spray, Sand, and Dust requirements. * Altitude: 50,000 feet * Shock: 25 g's 1/2 Sine 6 to 9 milliseconds - Maximum contact opening: 2 milliseconds * Acceleration: 10 g's * Vibration Limits: - 5 to 10 Hz: 0.8 in DA - 10 to 55 Hz: 0.6 in DA - 55 to 2000 Hz: 2 g's * Temperature Range: -55C to 71C * Insulation Resistance: - 100 megohm minimum initially - 50 megohm minimum after tests * Dielectric: - 1250 Vac minimum initially - 1000 Vac minimum after tests * Life: - Electrical Operations: 50,000 cycles - Mechanical Operations at 25% of Rated Resistive Load: 100,000 cycles * Minimum Current: 10% of Rated DC Resistive Load * Intermittent Duty Ratings: - % of Rated Resistive - Time On in Minutes - Cooling time is required between successive over load applications. Cat N. 6041H217 *SPST rated 400 Amp resistive and motor at 28 Vdc continuous duty with top mounting. * MS24185-D1 - 2.6 Lbs/ 1179gm Cat N. 6041H202 *SPST rated 200 Amp resistive and motor at 28 Vdc continuous duty with side mounting. * MS24171-D2 - 1.25 Lbs/ 567gm Cat N. 6041H209 *2 PST rated 100 Amp resistive at 28 Vdc and 75 amperes 115/200 V 400 Hz intermittent duty with top mounting. * AN-3392-1 - 1.5 Lbs/ 680 gm Cat N. 6041H201 *SPST rated 50 Amp resistive, inductive and motor at 28 Vdc continuous duty with side mounting. * MS24166-D2 - 0.5 Lbs/ 225 gm Intermittent Duty Ratings Minutes 15 5 1 Inrush 130% 150% 200% 600% Rupture Time Per MIL-R-6106 (Coil Voltage must be maintained at rated value) Cat N. 9565H2 *3 PST rated 25 Amp resistive, inductive and motor at 28 Vdc and 115/200 V 400 Hz continuous duty cycle with base mounting. * MS24192-D1 - 1.1 Lbs/ 499 gm * Options: - Other Coil Voltage - Alternate Mountings * MIL-STD-461 applies to AC operated coils. * See drawing for additional applicable details. Reversing and Dynamic Braking Relay Special Service Use Mechanical Interlock/Type Service Part Number Reversing Transfer Dynamic Braking 9565H29 X X -- 6046H39 X -- X 6046H46 X X -- 6046H53 X X -- Cat N. 6046H39 * Control of split field series motors. * SPST see circuit diagram 6 for details. * Rated 28 Vdc 50 Amp N.O., 25 Amp N.C * 2.9 Lbs./1315 gm LABINAL POWER SYSTEMS TF300-9E 25 POWER RELAYS -- C ONTINUOUS DUTY, TYPE II, UNSEALED INTERMITTENT DUTY, TYPE III, UNSEALED Labinal Power Systems Part Number Government Part Number 9565H2 9565H29 9565H95 6041H53k MS24192-D2 MS24152-D1 -- -- 25 25 25 25 25 25 50/25 50/25 25 25 25 50/25 25 25 25 25/25 25 25 25 -- 25 25 25 -- 20 20 20 20 15 15 15 15 6041H220k MS24187-D1 50/25 50/25 50/25 25/25 -- -- 20 15 6041H230 MS24187-D2 50/25 50/25 50/25 25/25 -- -- 20 15 -- 50/25 50/25 MS24166-D2 50 50 -- 50 50 MS24166-D1 50 50 MS24193-D1 50 50 MS24178-D1 55 40 -- 100 80 -- 100 80 -- 100 80 AN3362-1 100 80 MS25031-D1B 100 80 -- 100 75 MS24171-D2 200 100 -- 200 100 -- 200 100 MS24172-D2 200 100 -- 200 100 MS24171-D1 200 100 MS24172-D1 200 100 MS25032-D1 200 100 MS24185-D2 400 100 MS24185-D1 400 100 MS24179-D1 400 100 MS24179-D2 400 100 50/25 50 50 50 50 40 80 80 80 80 80 75 200 200 200 200 200 200 200 150 400 400 400 400 -- -- -- -- 50 55 -- -- -- 75 75 100 -- -- -- -- -- -- -- 150 -- -- -- -- -- -- -- -- 50 -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 50 35 -- -- -- 65 65 75 -- -- -- -- -- -- -- 100 -- -- -- -- -- 20 20 20 20 -- -- 10 15 10 15 -- 6 6 6 5 N.O./10 N.C. 5 N.O./10 N.C. 5 N.O./10 N.C. -- 5 5 5 4 -- 35 10 3.5 22 25 -- 40 25 40 25 25 40 40 40 20 20 15 10 -- 15 18 15 10 10 15 15 15 15 15 4 50 -- 5 5 5 5 5 5 5 5 5 5 6046H39k 6041H201 6041H149 6041H200 9565H94 6041H219 6041H80 6041H144 6041H11 6041H209 6046H53 9565H13 6041H202 6041H105 6041H123 6041H203 6041H212 6041H215 6041H216 6046H46 6041H205 6041H217 6041H218 6041H206 Continuous Power Contacts, Ratings RES. 28VDC IND. MOTOR 115/200 VAC 400 Hz. RES. IND. MOTOR Contacts Operate Milliseconds, Maximum Contact Bounce OP. REL TIME TIME Coil will exceed 95 C temperature rise when left on continuously in 25 ambient, but will not be damaged. At maximum ambient temperture of 71C, the duty cycle should be limited to 15 minutes "on" time per half hour to obtain maximum coil life. Continuous and intermittent duty ratings shown are for N.O. pole rated at 1/2 the listed continuous DC duty ratings. N.C. pole on 6041H53 and H220 limited to 15 g's shock. Time on 1 1/2 minutes at 29 Vdc. Minimum time off is 3 minutes. MS Part Number Summary 6041H209 MS24179-D1 6041H218 MS24152-D1* 9565H29* MS24185-D2 6041H205 MS24166-D1 6041H200 MS24187-D1 6041H220 MS24166-D2 6041H201 MS24187-D2 6041H230 MS24171-D1 6041H215 MS24192-D1 9565H2 MS24171-D2 6041H202 MS24193-D1 9565H94 MS24172-D1 6041H216 MS25031-D1B 6046H53 MS24172-D2 6041H203 MS24185-D1 6041H217 MS24178-D1 6041H219 MS25032-1 6046H46 26 LABINAL POWER SYSTEMS TF300-9E Poles & Throwm Weight Lbs./GMS Circuit Dia./ Dim. Figure 3PST 3PDT 3PST SPDT 1.1/498 2/909.09 1.06/482.95 .54/245.45 10 / 11 16 / 11 10 / 11 4/2 SPDT .54/245.45 4/2 Resistance (OHMS) 10% Pickup/ Sealed Volts Pickupn Volts Dropouto Duty Cycle Mounting Coil Voltage Nominal 18 18 70 8.2 1.5 to 7 1.5 to 7 8 to 38 0.8 to 4.8 CONT CONT CONT CONT BASE BASE BASE TOP 28 dc 28 dc 120 dc 12 dc 94.2 18 1.5 to 9 CONT TOP 28 dc CONT TOP 29 dc CONT CONT CONT CONT Notej CONT CONT CONT Notej CONT CONT CONT CONT CONT INTERl CONT CONT INTERl CONT CONT CONT INTERl INTERl TOP SIDE SIDE TOP BASE TOP SIDE SIDE TOP TOP TOP BASE SIDE SIDE SIDE SIDE SIDE TOP TOP TOP SIDE TOP TOP SIDE 28 dc 28 dc 12 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc 12 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc 28 dc / 60 22 / 92 / 1160 16.9 SPDT .54/245.45 4 /2 94.2 18 1.5 to 9 SPDT SPST SPST SPST 3PST DPST SPST SPST SPST DPST DPDT 3PST SPST SPST SPST SPST SPST SPST SPST DPDT SPST SPST SPST SPST 2.9/1318.18 .50/225 .56/254.55 .50/225 1.51/685 .75/340.91 1.4/636.36 1.4/636.36 1.4/636.36 1.5/685 3.5/1590.91 2.5/1136.36 1.25/568.18 1.25/868.18 1.3/590.91 1.23/560 1.3/590.91 1.33/604.55 1.33/604.55 5.5/2500.00 2.6/1181.82 2.6/1181.82 2.6/1181.82 2.6/1181.82 6/7 1/4 1/4 1/4 10 / 11 2/2 1/3 1/3 1/1 2/2 9/7 12 / 11 1/5 1/5 1/5 1/5 1/5 1/1 1/1 8/7 1/5 1/1 1/1 1/5 26 94.2 16.9 94.2 13.5 / 71.5 66 66.3 66.3 66.3 43 43 9 / 53 66 10 (+15/-10) 66 10 (+15/-10) 66 66 10(+15/-10) 41 60 60 10 10 18 18 8.2 18 18 18 18 18 18 20 18 18 18 9 18 7.5 18 18 7.5 18 18 18 7 7 7 1.5 to 7 0.8 to 4.8 1.5 to 7 1.5 to 7 1.5 to 7 1.5 to 7 1.5 to 7 1.5 to 7 1.5 to 7 1.5 to 7 1.5 to 7 1.5 to 7 3.5 1.5 to 7 0.5 to 3.0 1.5 to 7 1.5 to 7 0.5 to 3.0 1.5 to 7 1.5 to 7 1.5 to 7 0.5 to 3.0 0.5 to 3.0 All continuous duty resistive and motor load ratings and all intermittent duty ratings for all 3 pole relays listed under 28 Vdc apply for 120 Vdc systems with all 3 poles of the relay connected in the series. Pick-up voltage below values shown may cause relay to rapidly cycle on and off (chatter). Relay must drop-out at voltage value or less and may drop-out at any voltage below the higher voltage noted. Conversion Part Number AN3362-1* *Inactive for new design Coil Data AN Part Number Use MS Part Number Labinal Power Systems Part Number 3343-1 -- 9565H13 3350-1 MS24166-D2 6041H201 3362-1 -- 6041H209 3370-1 MS24171-D2 6041H202 3371-1 MS24172-D2 6041H203 3380-1 MS24185-D2 6041H205 -- MS25030-D1B 6041H51 3381-2 MS24179-D1 6041H218 POWER RELAYS -- CONTINUOUS DUTY, TYPE II, UNSEALED INTERMITTENT DUTY, TYPE III, UNSEALED Approximate Dimensions and Weights Dimensions in Inches Catalog Number Ampere Ratings Figure Number Wide A High B Deep C 6041H11 6041H53 6041H80 6041H105 6041H123 6041H144 6041H149 6041H200 6041H201 6041H202 6041H203 6041H205 6041H206 6041H209 6041H212 6041H215 6041H216 6041H217 6041H218 6041H219 6041H220 6046H39 6046H46 6046H53 9565H2 9565H13 9565H29 9565H94 9565H95 100 50/25 100 200 200 100 50 50 50 200 200 400 400 100 200 200 200 400 400 55 50/25 50/25 200 100 25 100 25 50 25 1 2 3 5 6 3 4 2 4 5 5 5 5 2 5 1 1 1 1 2 2 7 7 7 11 11 12 11 11 3.27 2.63 2.91 4.406 4.5 3.33 2.75 2.75 2.75 4.41 4.5 5.5 5.5 3.469 4.48 4.406 4.406 5.5 5.5 2.922 2.812 4.82 7.688 6.688 3.063 3.812 4.75 3.625 3.063 3.13 3.14 3 3.28 3.575 3 2.5 2.625 2.5 3.28 3.313 3.92 3.92 3.406 3.313 3.75 3.75 4.5 4.5 2.844 3.13 3.45 4.125 3.75 2.75 3.546 2.75 3.188 2.75 2.08 2.062 2.08 1.99 2 2 2.125 2.125 2.125 1.99 2 2.438 2.438 2.656 2.466 2 2 2 2 2.031 2.062 2.25 3.468 2.656 2.75 3.28 4.125 3.312 2.75 Mounting D Hole F E -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 1.395 2.01 1.76 2.125 2.688 2.468 2.75 2.135 2.75 0.27 2.2 0.214 2.26 0.276 2.395 0.276 2.395 0.276 2.26 0.276 1.875 0.229 2.188 0.219 1.875 0.229 2.395 0.276 2.395 0.276 2.406 0.276 2.406 0.276 2.948 0.276 3.717 0.27 3.01 0.276 3.01 0.276 3.01 0.276 3.01 0.276 2.385 0.223 2.2 0.214 4.301 0.228 6.895 0.266 6.02 0.266 2.49 0.229 3.102 0.225 4.187 0.218 2.322 0.219 2.494 0.229 Dimensions in Millimeters Net Stud G Power Coil Dimensions in Millimeters Weight Lbs. .250-28 UNF .138-32 UNC .190-32 UNF-2A .138-32 UNC-2A .250-32 UNC .138-32 UNC-2A .375-24 UNF-2A .138-32 UNC-2A .375-24 UNF-2A .138-32 UNC-2A .250-28 UNF .138-32 UNC .190-32 UNC-2A .138-32 UNC-2A .191-32 UNC-2A .138-32 UNC-2A .190-32 UNC-2A .138-32 UNC-2A .375-24 UNF-2A .138-32 UNC-2A .375-24 UNF-2A .138-32 UNC-2A .500-20 UNF-2A .138-32 UNC-2A .500-20 UNF-2A .138-32 UNC-2A .250-28 UNF-2B .138-32 UNC-2B .375-24 UNF-2A .138-32 UNC-2A .375-24 UNF-2A .138-32 UNC-2A .375-24 UNF-2A .138-32 UNC-2A .500-20 UNF-2A .138-32 UNC-2A .500-20 UNF-2A .138-32 UNC-2A .190-32 UNC-2B .138-32 UNC-2B .190-32 UNF-2A .137-32 UNC-2A .190-32 .138-32 UNC .375-24 UNF .138-32 UNC .250-28 UNF .138-32 UNC .190-32 UNF-2B .138-32 UNC-2B .250-28 UNF-2B .164-32 UNC-2B .190-32 UNF-2B .164-32 UNC-2B .190-32 UNF-2B .164-32 UNC-2B .190-32 UNF-2B .164-32 UNC-2B 1.4 0.54 1.4 1.25 1.3 1.4 0.562 0.5 0.5 1.25 1.23 2.6 2.6 1.5 1.3 1.33 1.33 2.6 2.6 0.75 0.54 2.9 5.5 3.5 1.062 2.5 2.25 1.5 1.06 Wide A High B 83.06 66.8 73.91 111.92 112.01 84.58 69.85 69.85 69.85 112.01 114.3 139.7 139.7 88.11 113.79 111.91 111.91 139.7 139.7 74.22 71.42 122.43 195.28 169.88 77.8 96.82 120.65 92.08 77.8 79.5 79076 76.2 83.31 90.81 76.2 63.5 66.68 63.5 83.31 84.15 99.57 99.57 86.51 84.15 95.25 95.25 114.3 114.3 72.24 79.5 87.63 104.78 95.25 69.85 90.07 69.85 80.98 69.85 Deep C D Mounting E Hole F Weight Grams 52.83 52.37 52.83 50.55 50.8 50.8 53.98 53.98 53.98 50.55 50.8 61.93 61.93 67.46 62.64 50.8 50.8 50.8 50.8 51.59 52.37 57.15 88.09 67.46 69.85 83.31 104.78 84.12 69.85 -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 35.43 51.05 44.7 53.98 68.28 62.69 69.85 54.23 69.85 55.88 57.4 60.83 62.83 57.4 47.63 55.58 47.63 60.83 60.83 61.11 61.11 74.88 94.41 76.45 76.45 76.45 76.45 60.58 55.88 109.25 175.13 152.91 63.25 78.79 106.35 58.98 63.35 6.86 5.44 7.01 7.01 7.01 7.01 5.82 5.56 5.82 7.01 7.01 7.01 7.01 7.01 6.86 7.01 7.01 7.01 7.01 5.66 5.44 5.79 6.76 6.76 5.82 5.72 5.54 5.56 5.82 636.36 245.45 636.36 568.18 590.91 636.36 255.68 225 225 568.18 560 1181.82 1181.82 681.82 590.91 604.55 604.55 1181.82 1181.82 340.91 245.45 1318.18 2500 1590.91 482.95 1136.36 1022.73 681.82 481.82 Note: All coils and auxiliary terminals are 6-32, except for Catalog Number 9565 relays which have 8-32 coil terminals. Dimensions are approximate and should not be used for construction purposes. A4 A4 A3 X2 X2 A1 C Dimension Figures A4 A4 X2 X2 A1 G. DIA. TERM. STUDS C B DIA. G TERM. STUD DIA. F MTG. HOLES A3 G. DIA. TERM. STUDS B E F DIA MTG. HOLES C E A A B Figure 2 Figure 1 F DIA MTG. HOLES E A LABINAL POWER SYSTEMS TF300-9E 27 POWER RELAYS -- CONTINUOUS DUTY, TYPE II, UNSEALED INTERMITTENT DUTY, TYPE III, UNSEALED Dimension Figures (cont.) A X1 X2 G DIA. TERM. STUDS B G DIA. TERM. STUDS B B C A2 A1 F DIA. MTG. HOLES F DIA. MTG. HOLES F DIA. MTG. HOLES E F G DIA. TERM. STUDS F DIA. MTG. HOLES E E B B B C DIA. TERM. STUDS A E A A Figure 3 Figure 4 Figure 5 Figure 6 B G DIA. TERM STUDS F DIA. MTG.HOLES E D C A Figure 7 28 LABINAL POWER SYSTEMS Figure 11 TF300-9E Figure 12 POWER RELAYS -- CONTINUOUS DUTY, TYPE II, UNSEALED INTERMITTENT DUTY, TYPE III, UNSEALED B1 B2 B1 B2 A3 A4 A1 Typical Wiring Diagrams A2 A1 A2 A1 A2 A1 A2 X1 B1 X1 B2 B1 X1 B2 A3 X1 A4 A1 X2 A2 A1 X2 A2 A1 X2 A2 A1 X2 A2 X1 X1 X1 X1 X2 X2 X2 X2 Diagram 1 B1 B2 D1 D2 A1 A2 C1 B1 X1 B2 A1 X2 A2 Diagram 2 B2 B4 C2 A1 A2 A4 A3 D1 X3 D2 B1 X1 B2 B4 Y1 A3 C1 X4 C2 A1 X2 A2 A4 Y2 A3 X1 X3 X1 Y1 X2 X4 X2 Y2 A2 4 Diagram A1 Diagram 3 B1 A3 B1 B2 A1 C1 A2 C2 B1 X1 B2 C1 X2 C2 X1 X2 Diagram 9 Diagram 8 A2 B2 C2 A1 L1 T2 L1 T2 L1 L1 T2 T2 L1 X1 T2 L1 X2 T2 B1 A2 X2 Y2 C1 X1 X2 T1 A3 L1 B3 L2 B2 C2 A1 C1 B1 Diagram 10 Y2 L11 L12 T1 A3 C3 L1 L3 B3 L2 C3 L3 Y1 X1 Y1 X1 T2 T3 T2 T3 L11 L13 X2 L12 X1 L13 X2 X12 X1 X1 Diagram 12 X1 Diagram 16 Diagram 18 X12 X2 LABINAL POWER SYSTEMS TF300-9E 29 POWER RELAYS -- CONTINUOUS DUTY, TYPE II, UNSEALED INTERMITTENT DUTY, TYPE III, UNSEALED P/N 6046H39 Typical Operation: All items shown within dotted lines are part of the relay. All other parts external to dotted lines, including switches connected to C1 & C2 customer supplied. Internal Mechanical Interlocks Prevents the opposite contacts from transferring when either one of the coils is energized and the respective contacts are closed. Reversing Operation Closing either external start/stop switch at C1 or C2 will cause the motor to turn in either direction. Dynamic Braking Operation Internal switch provides for dynamic braking current flow through the motor shunt-fields series (SF) 1 and 2. Switch S is mechanically closed when either coil is energized and maintains that position until the alternate coil is energized. Switch S is shown in the last position commanded by external start/stop switch at C1. L1+ L2C1 C3 3 1 D S S.F.2 4 2 C2 Dia. No. 6 6046H39 30 LABINAL POWER SYSTEMS TF300-9E S.F.1 ARM (Items shown outside dotted line are customer supplied) POWER RELAYS -- HERMETICALLY SEALED - 12 AMPS TO 50 AMPS Characteristics: * Ambient Temperature Class: - B -70C to 125C - D -70C to 71C * Hermetically sealed/ MIL-PRF-6106 * Twin Break Silver Alloy Main Contacts * Electrical Life: 50,000 cycles (sea level to 80,000 feet) * Mechanical Life: 100,000 cycles * Acceleration: 15 g's * Shock: 25 g's * Vibration Levels (Typical): 5 - 10 CPS .08 DA 10 - 55 CPS 55 - 200CPS .06 DA 10 g's 250 - 500 CPS 500 - 1500 CPS 5 g's 3 g's Typical Configurations Catalog Number Continuous Ampere Contact Rating Poles and Throw 6042H110-2 12 3PST Operating Coil Voltage Number Auxj Contacts Dimension Drawing Figure Number Wiring Diagram Figure Number Government Type Number Temp Class/ Note 1 2 8 MS24143-D3 Bk -- 2 6 MS24143-D1 B 1 2 8 MS24143-D2 Bp 115 Vac 60 or 400 Hertz -- 2 6 MS24143-A3 D Built In Rectifiers 1 2 8 MS24143-A4 D -- 1 9 MS24140-D1 B 1 1 10 MS24140-D2 B 6042H145-2 -- 2 6 MS24376-D1 B 6042H146-2 1 2 8 MS24376-D2 B 115 Vac 60 or 400 Hertz -- 2 6 MS24376-A1 Bs 1 2 8 MS24376-A2 Bs 1 2 8 MS24376-A4 Bs Built In Rectifiers -- 2 6 MS24376-A3 Bs 28 Vdc 6042H141-2 6042H142-2 6042H290-2 25 3PST 6042H291-2 6042H155-2 SPST 6042H156-2 6042H147-2 6042H148-2 6042H285-2 50 3PST 6042H288-2 Cat. No. 6042H285 3PST, 50 Amp w/Auxiliary 28 Vdc Cat. No. 6042H155 SPST, 50 Amp Cat. No. 6042H46 SPST, 50 Amp w/Auxiliary LABINAL POWER SYSTEMS TF300-9E 31 POWER RELAYS -- HERMETICALLY SEALED - 12 AMPS TO 50 AMPS Ratings Power Contact Ratings Continuous Duty o 28 Vdc 115/200 Vac 400 Hz Amperes Max. Coil Power Amperes Res. Ind. Motor Res. Ind. Motor 12 12 6 12 12 6 0.6 25 0.6 0.6 25 25 25 50 Coil Data 50 25 25 Amps 0.225 50m 50m 50m 0.50 0.50 50 50 50 0.6 0.6 50 50 50 0.225 50 Volts Max. Volts Pick Up at Amb. Temp. Catalog Number Volts Hold Drop Out 29 dc 18 dc 7 dc 1.5 dc 124 ac 90 ac 40 acr 10 ac 29 dc 18 dc 7 dc 1.5 dc 124 ac 90 ac 40 ac 10 ac 6042H110-2 6042H141-2 6042H142-2 6042H290-2 6042H291-2 6042H155-2 6042H156-2 6042H145-2 6042H146-2 6042H147-2 6042H148-2 6042H285-2 6042H288-2 Auxiliary Switch: SPDT rated 28 Vdc and 115 V 400 Hz, 5 Amp Res. & Ind. & 0.75 Amp Lamp Rated 100,000 operations electrical and mechanical life; Auxiliary switch rated 1,25 Amp Res. & 0.75 Amp Ind. These Ratings for 115 V 400 Hz only See MS Sheets for details Intermittent duty ratings for general applications. (See chart below) Ratings for 50/60 Hz only @ 115/200 Vac 400 Hz only Temperature Class D for 60 Hz AC Operation Intermittent Duty Ratings Continuous 15 Minutes 5 Minutes 1 Minute Max. Inrush 100% 130% 150% 200% 600% In general, these power relays can withstand the above intermittent duty overcurrent. Options: Internal Coil Suppression 32 LABINAL POWER SYSTEMS TF300-9E POWER RELAYS -- HERMETICALLY SEALED - 100 AMPS TO 400 AMPS Typical Configurations Catalog Number Continuous Ampere Contact Rating 6042H159-2 6042H160-2 6042H166-2 6042H161-2 6042H162-2 Dimension Wiring Poles Operating Number Drawing Diagram Government Temp j and Coil Aux. Figure Figure Type Class/ Throw Voltage Contacts Number Number Number Note SPST 28 Vdc 100 3PST 6042H286-2 6042H289-2 115 Vac 6042H151-2 6042H152-2 6042H167-2 6042H153-2 6042H154-2 SM400H2-2 SM400H3-2 200 SPST 28 Vdc 300 400 -- 1 -- 1 1 1 9 10 9 -- 2 1 2 -- Power Contact Ratings -- Continuous Dutyo 28 Vdc 115/200 Vac 400 Hz Amperes Amperes Res. Ind. Motor Res. 100m 100m 100m B B D B 100 100 100 100 100 100 100 100 100 6 MS24141-D1 MS24141-D2 MS24182-D1 MS24168-D1 100 100 100 100m 8 MS24168-D2 B 100 100 100 100 2 8 MS24168-A4 D 100 100 100 100 1 2 6 MS24168-A3 D 100 100 100 100 -- 9 MS24142-D1 B 200 100 200 -- 1 1 10 MS24142-D2 B 200 100 1 1 9 MS24183-D1 D 200 100 -- 1 9 D 300 1 -- 1 10 MS24184-D1 -- D 1 1 9 10 -- -- D D 1 Ind. -- -- -- 50q Coil Data Max. Time In Seconds Motor Operate Release Amps 75m 75m 75m 0.025 0.025 0.02 0.5 0.5 0.5 Max. Volts Pickup @ Volts Amb Temp. 29 dc 18 dc 29 dc 18 dc 29 dc 18 dc 29 dc 18 dc Volts Max. Coil Power Hold 7 dc 7 dc 7 dc 7 dc Drop Out 1.5 dc 1.5 dc 1.5 dc 1.5 dc 100m 0.06 0.01 0.01 0.01 0.015 50q 50q 100 0.06 0.025 0.6 29 dc 7 dc 1.5 dc 100 0.06 0.11 0.25 10 ac 100 0.06 0.08 0.25 200 50q -- 120 ac 90 ac 40 ac 120 ac 90 ac 40 ac 150 0.015 0.6 29 dc 18 dc 7 dc 1.5 dc 200 200 -- 150 0.035 0.035 0.015 0.6 29 dc 18 dc 7 dc 1.5 dc 200 200 -- 150 0.03 0.01 0.5 29 dc 18 dc 7 dc 1.5 dc 100 250 300 -- 150 0.035 0.015 0.6 29 dc 18 dc 7 dc 1.5 dc 300 100 250 300 -- 150 0.6 29 dc 18 dc 7 dc 1.5 dc 400 100 250 400 -- 150 0.035 0.015 0.6 29 dc 18 dc 7 dc 1.5 dc 400 100 250 400 -- 150 0.035 0.015 0.6 29 dc 18 dc 7 dc 1.5 dc 0.6 18 dc 10 ac Auxiliary switch: SPDT rated 28 Vdc and 115 V 400 Hz, 5 Amp Res. & Ind. & 0.75 Amp Lamp. Rated 100,000 operations electrical and mechanical life. Auxiliary switch rated 1.25 Amp Res. & 0.75 Amp Ind. Rated 50 g shock. These ratings for 115 V 400 Hz only. See MS Sheets for details. Intermittent duty ratings for general applications (see chart below). Ratings for 50/60 Hz only @ 115/200 Vac. Cat. No. 6042H286 3 PST, 100 Amp Characteristics: * Electrical Life: 50,000 cycles (sea level to 80,000 feet) * Mechanical Life: 100,000 cycles * Acceleration: 15 g's * Shock: 25 g's * Ambient Temperature Class: - B -70C to 125C - D -70C to 71C * Hermetically sealed/ MILPRF-6106 Cat. No. 6042H151 SPST, 200 Amp * Twin Break Silver Alloy Main Contacts * Vibration Levels (Typical): 5-10 CPS .08 DA 250-500 CPS 5 g's 10-5 CPS .06 DA 55-200CPS 10 g's Cat. No. 6042H153 SPST, 300 Amp Intermittent Duty Ratings: Continuous 15 Minutes 5 Minutes 1 Minute Max. Inrush 100% 130% 150% 200% 600% In general, these power relays can withstand the above intermittent duty overcurrent. 500-1500 CPS 3 g's Options: Internal Coil Suppression LABINAL POWER SYSTEMS TF300-9E 33 POWER RELAYS -- HERMETICALLY SEALED Approximate Dimensions and Weights Catalog Number 6042H110-2 6042H141-2 6042H142-2 6042H145-2 6042H146-2 6042H147-2 6042H148-2 6042H151-2 6042H152-2 6042H153-2 6042H154-2 6042H155-2 6042H156-2 6042H159-2 6042H160-2 6042H161-2 6042H162-2 6042H166-2 6042H167-2 6042H285-2 6042H286-2 6042H288-2 6042H289-2 6042H290-2 6042H291-2 SM400H2-2 SM400H3-2 Ampere Dimensions Rating in Inches Wide A 12 2 3.305 25 2 3.305 25 2 3.305 50 2 3.305 50 2 3.305 50 2 3.305 50 2 3.305 200 1 3.640 200 1 3.640 300 1 3.640 300 1 3.640 50 1 2.700 50 1 2.700 100 1 3.640 100 1 3.640 100 2 4.250 100 2 4.250 100 1 3.640 200 1 3.672 50 2 3.305 100 2 4.235 50 2 3.305 100 2 4.235 25 2 3.305 25 2 3.305 400 1 3.640 400 1 3.640 Dimensions in Inches High Deep Mounting B C D E 4.485 3.700 3.250 2.687 3.250 3.700 3.250 2.687 4.513 3.700 3.250 2.687 3.200 3.700 3.250 2.687 4.485 3.700 3.250 2.687 3.200 3.700 3.250 2.687 4.485 3.700 3.250 2.687 3.700 3.315 -- 3.000 4.972 3.315 -- 3.000 3.700 3.315 -- 3.000 4.973 3.315 -- 3.000 2.665 2.835 -- 2.188 3.947 2.835 -- 2.188 3.250 2.925 -- 3.000 4.532 2.925 -- 3.000 4.280 4.220 3.697 3.510 5.615 4.220 3.697 3.510 3.063 2.925 -- 3.000 3.282 2.957 -- 3.000 4.485 3.700 3.250 2.687 5.553 4.218 3.697 3.510 3.200 3.700 3.250 2.687 4.280 4.218 3.697 3.510 3.250 3.700 3.250 2.687 4.513 3.700 3.250 2.687 3.700 3.315 -- 3.000 4.973 3.315 -- 3.000 Net Term. Stud Dia. G Hole F 0.218 0.218 0.218 0.218 0.218 0.218 0.218 0.266 0.266 0.266 0.266 0.218 0.218 0.266 0.266 0.218 0.218 0.266 0.266 0.218 0.218 0.218 0.218 0.218 0.218 0.266 0.266 Power .190-32 UNF-2B .190-32 UNF-2B .190-32 UNF-2B .190-32 UNF-2B .190-32 UNF-2B .19O-32 UNF-2B .190-32 UNF-2B .375-24 UNF-2B .375-24 UNF-2B .375-24 UNF-2B .375-24 UNF-2B .190-32 UNF-2B .190-32 UNF-2B .250-28 UNF-2B .250-28 UNF-2B .250-28 UNF-2B .250-28 UNF-2B .250-28 UNF-2B .375-24 UNF-2B .190-32 UNF-2B .250-28 UNF-2B .190-32 UNF-2B .250-28 UNF-2B .190-32 UNF-2B .190-32 UNF-2B .375-24 UNF-2B .375-24 UNF-2B Coil .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B .138-32 UNC-2B Weight Lbs. 1.60 1.50 1.60 1.60 1.70 1.70 1.82 2.30 2.50 2.40 2.50 0.90 1.10 1.40 1.60 3.30 3.45 1.10 1.70 1.90 3.70 1.80 3.60 1.70 1.90 2.40 2.50 NOTE: All coils and auxiliary terminals are 6-32. Dimensions are approximate and should not be used for construction purposes. Figure 1 34 LABINAL POWER SYSTEMS Figure 2 TF300-9E Wide A 83.95 83.95 83.95 83.95 83.95 83.95 83.95 92.46 92.46 92.46 92.46 68.58 68.58 92.46 92.46 107.95 107.95 92.46 93.27 83.95 107.57 83.95 107.57 83.95 83.95 92.46 92.46 Dimensions in Millimeters High Deep Mounting B C D E 113.92 93.98 82.55 68.25 82.55 93.98 82.55 68.25 114.63 93.98 82.55 68.25 81.28 93.98 82.55 68.25 113.92 93.98 82.55 68.25 81.28 93.98 82.55 68.25 113.92 93.98 82.55 68.25 93.98 84.20 -- 76.20 126.29 84.20 -- 76.20 93.98 84.20 -- 76.20 126.31 84.20 -- 76.20 67.69 72.01 -- 55.58 100.25 72.01 -- 55.58 82.55 74.30 -- 76.20 115.11 74.30 -- 76.20 107.57 107.19 93.90 89.15 142.62 107.19 93.90 89.15 77.80 74.30 -- 76.20 83.36 75.11 -- 76.20 113.92 93.98 82.55 68.25 141.05 107.14 93.90 89.15 81.28 93.98 82.55 68.25 108.71 107.14 93.90 89.15 82.55 93.98 82.55 68.25 114.63 93.98 82.55 68.25 93.98 84.20 -- 76.20 126.31 84.20 -- 76.20 Hole F 5.54 5.54 5.54 5.54 5.54 5.54 5.54 6.76 6.76 6.76 6.76 5.54 5.54 6.76 6.76 5.54 5.54 6.76 6.76 5.54 5.54 5.54 5.54 5.54 5.54 6.76 6.76 Weight Grams 727.27 681.82 727.27 727.27 771.11 771.11 825.54 1043.26 1133.98 1088.62 1133.98 408.23 498.95 635.03 727.27 1496.86 1568.18 498.95 771.11 861.83 1678.29 816.47 1636.36 771.11 861.83 1088.62 1133.98 POWER RELAYS -- HERMETICALLY SEALED Typical Wiring Diagrams NO X2 X2 L3 L3 T3 L2 T2 L1 T1 L2 L1 X1 X2 L3 L2 L1 NO NONC X2 NC X1 NC X1 L3 X1 X2 L2 X2 L1 T3 L3 T3 T2 T2 L2 T1 T1 L1 Dia. No. 1 T3 X1 NO NO NC NC X2 NC X1 T3 X1 L3 X1 X1 T3 X2 T2 X2 L2 X2 X2 T2 L3 T1L3 L2 A1 T2 L2 T2 L1 B1 T1 L1 T1 X2 NC X1 X1 X2 X2 X1 13 X1 T3 11X2 11 12 13 13 14 A1 X2 11 13 X1 C1 Dia. No. 2 13 11 1211 12 13 1413 14 13 A1 12 X1 12 14 14 B1 A2 X2 X2 L2 A1 T2 A1 A1 A2 B1 A1 C1 A2 A2 B2 A2 L1 B1 T1 B1 B1 B2 C1 B1 B2 B2 C2 B2 C1 C1 C2 C1 C2 C1 C2 X1 A2 11 12 13 14 X1 X2 B2 X2 A1 C2A1 B1 C1 C2 Dia. No. 7 T2 T1 A2 A1T1 A1 B1 B1 C1 C1 B2 C2 12 Dia. No. 6 14 B1 X1 12 12 14 X2 14 A1 X1 X1 A2 B1 X2 X2 B2 C1 A2 A2 B2 B2 A1 C2 C1 X2 X2 11 B2 C1 C2 A1 C2 11 12 13 14 13 12 13 14 X1 X1 X2 X2 11 12 13 14 11 A1 11 12 X2 X1 12 13 14 14 11 X1 A2 X1 13 X2 X2 A1 X1 Dia. No. 9 A1 A1 X2 A1 X2 A2 Dia. No. 10 B1 A2 A1 C1 X2 11 X1 B1 A1 A2 Dia. No. 8 X1 A2 C2 X1 X1 A1 T3 11 11 11 X2 L3 L1 T3 NO NC X1 NC NO X1 NO NO NC (See Selection Table for Diagram No. Reference) X1 X1 NO A2 11 13 A1 12 12 13 14 B1 A2 A1 CA2 A1 C1 CA2 CA2 B1 CB2 B1 CB2 CB2 C1 C1 LABINAL POWER SYSTEMS CC2 14 CC2 CC2 TF300-9E 35 POWER RELAYS -- TERMINAL COVERS FOR HERMETICALLY SEALED POWER RELAYS Specifications * Molded of unbreakable nylon * Ambient temperature ranges: -70C to 125C * Secured by coil terminal hardware * Part number molded into cover * Positive protection between power stubs Part No. 49-2665 MS27242-1 Part No. 49-2672 MS27243-5 Part No. 49-2661 MS27243-1 36 LABINAL POWER SYSTEMS TF300-9E Part No. 49-2667 MS27243-3 Part No. 49-2670 MS27243-4 POWER RELAYS -- TERMINAL COVERS FOR HERMETICALLY SEALED POWER RELAYS Approximate Dimensions and Weights Terminal Covers Application Labinal Power Systems Relays Relay MS Numbers Terminal Cover Part Number MS27243 6042H110-2 MS24143-D3 49-2661 -1 26042H141-2 MS24143-D1 49-2661 -1 6042H142-2 MS24143-D2 49-2661 -1 6042H145-2 MS24376-D1 49-2661 -1 6042H146-2 MS24376-D2 49-2661 -1 6042H147-2 MS24376-A1 49-2661 -1 6042H148-2 MS24376-A2 49-2661 -1 6042H151-2 MS24142-D1 49-2672 -5 6042H152-2 MS24142-D2 49-2672 -5 6042H153-2 MS24184-D1 49-2672 -5 6042H154-2 MS24184-D2 49-2672 -5 6042H155-2 MS24140-D1 49-2667 -3 6042H156-2 MS24140-D2 49-2667 -3 6042H159-2 MS24141-D1 49-2665 -2 6042H160-2 MS24141-D2 49-2665 -2 6042H161-2 MS24168-D1 49-2670 -4 6042H162-2 MS24168-D2 49-2670 -4 6042H166-2 MS24182-D1 49-2667 -3 6042H167-2 MS24183-D1 49-2665 -2 6042H286-2 MS24168-A4 49-2670 -4 6042H288-2 MS24376-A3 49-2661 -1 6042H289-2 MS24168-A3 49-2670 -4 6042H290-2 MS24143-A3 49-2661 -1 6042H291-2 MS24143-A4 49-2661 -1 SM400H2-2 -- 49-2672 -5 SM400H3-2 -- 49-2672 -5 Part Number Figure Number 49-2661 Dimensions in In./Mill. C Ship Wt. Lbs./ gm A B 1 2.32/58.93 0.75/19.05 2.94/74.68 .025/11.31 49-2665 1 2.56/65.02 1.17/29.72 2.12/53.85 .026/11.77 49-2667 1 2.66/67.56 1.11/28.19 2.05/52.07 .027/12.22 49-2670 1 2.75/69.85 1.06/26.92 3.81/96.77 .044/19.91 49-2672 1 3.00/76.20 1.17/29.72 2.50/63.50 .030/13.57 NOTE: Dimensions are approximate and should not be used for construction purposes. Figure 1 Figure 2 LABINAL POWER SYSTEMS TF300-9E 37 POWER RELAYS -- HERMETICALLY SEALED LIGHT-WEIGHT - SM100H1 Engineering Data * MIL-R-6106 Type I - Hermetically Sealed - Continuous Duty * Weight - 11.3 oz. (320 grams) * Seal - 1x10-6 STD CC/SEC Max * Altitude: 80,000 Feet * Double Break Contacts Vibration Random 15 Minutes Each Plane M6106/48-001 Frequency (Hz) Level (g^2/Hz) 10 - 125 0.037 125 - 250 +4 dB 250 - 1000 0.1 1000 - 2000 -3 dB Vibration Random 15 Minutes Each Plane M6106/48-002j Frequency (Hz) Level (g^2/Hz) 15 - 50 0.012 120 - 200 0.364 250 - 400 0.194 600 - 1000 0.060 1300 - 2000 0.097 jTest to be performed with 5 ampere load on main contact. Selection Table (4) #8 (.164) - 32UNJC-3A SCREW CAPTIVE, HEX HEAD (4) RETAINING RING, CRIMP-ON STYLE * SM100H1 * M6106/48-001 * SM100H15 * M6106/48-002 400 Application Notes 300 AMPERES The curve shows a typical motor/generator requirement. The SM100H1 can withstand up to 400 Amps for several seconds during motor start - dropping to 100 Amps within 5 seconds. The SM100H1 can withstand the generator output up to 200 Amp for several minutes - dropping to 100 Amps within 3.5 minutes. These cycles can be repeated once every 90 seconds. The SM100H1 will meet applications requiring a reliable and robust contactor. DC - Motor start (seconds) Normally twice per flight 200 100 Battery charge (minutes) Normally twice per flight 0 38 LABINAL POWER SYSTEMS TF300-9E 5 10 SECONDS / MINUTES 15 POWER RELAYS -- HERMETICALLY SEALED LIGHT-WEIGHT - SM100H1 2.000 50.80 2.430 61.72 .170 4.31 2.000 50.80 2.430 61.72 .656 16.66 .250-28 UNF-2A 2.90 77.66 * Meets MIL-R-6106/48 Type I Hermetically Sealed Continuous Duty * Power Contacts SPST: - 28 Vdc - Load Ratings: Resistive: 100 Amps Inductive: 100 Amps (10,000 cycles) Motor: 50 Amps -001; 25 amps -002 Lamp: 50 Amps (25,000 cycles) Minimum: 10 Amps Overload: 800 Amps (See application curve) Rupture: 1000 Amps - Contact Voltage Drop: Initial 0.100 V After Test - 0.150 V * Life: - Electrical: 50,000 cycles - Mechanical: 100,000 cycles * Auxiliary Contacts SPDT Form "Z": - Voltage: 28 Vdc - Resistive: 5 Amps - Inductive: 5 Amps (10,000 cycles) - Lamp: 1 Amp (25,000 cycles) - Minimum: 2 MA at 28 Vdc. - Contact Voltage Drop: Maximum: 5 MV +/- 100 MA and 6V * Current above 125 MA negates minimum current capability. * Operating Temperature: -55C to 125C * Shock: 1/2 Sine 50 g's 6-9 MS: - Contact Opening: 2 millisec. max. * Insulation Resistance Minimum: - Initial: 100 Megohms - After Test: 50 Megohms * Vibration: Sinusoidal (-001 only) - 5 to 10 Hz 0.08 DA - 10 to 55 Hz 0.05 DA - 55 to 2000 Hz 10 g's * Vibration (Gun Fire) 15 minutes each plane: - 0.0375 g/Hz for 10 to 125 Hz - 4DB/Octave inc 125 to 250 Hz - 0.1 g/Hz for 250 to 1000 Hz - 3DB/Octave decrease 1000 to 2000 Hz * Dielectric Strength Sea Level 2-5 sec. Voltage=VRMS 60 Hz: - All points: 1250 V Initial, 1000 V After Tests * Dielectric Strength Altitude 1 min. 60 Hz: - Coil & contacts: 500 V Initial & After Test - All other points: 500 V Initial & After Test Dimensions 2.016 51.21 Engineering Data .090 22.86 Schematic INTERNAL COIL SUPRESSOR A1 A2 X2 X1 13 11 AUXILIARY CONTACTS 14 12 Coil Data * Duty Cycle: Continuous * Maximum Voltage: 30 Vdc * Pick up: 18 Vdc (15 Vdc at 25C) *Hold-in: Unit must drop out at 1.5 Vdc & below and can drop out at any voltage below 7 Vdc. *Operate Time: 30 MS maximum Release Time: 20 MS maximum *Contact Bounce: 3 MS maximum main and auxiliary contacts. * Coil Resistance: @-25C; 100 Ohms minimum (- 002); 90 Ohms Minimum (-001). * Coil Suppression: 0.42 V max. Peak Inverse Voltage. LABINAL POWER SYSTEMS TF300-9E 39 POWER RELAYS -- ENVIRONMENTALLY SEALED LIGHTWEIGHT - SM15 SERIES Power Contact Ratings (Continuous Duty) Engineering Data * Meets MIL-R-6106 Type IV * Weight: 10.5 ounces (284 g) * Altitude: -Rated: 50,000 feet -Extended: 80,000 feet with encapsulated terminals * Ratings: -Voltage: 115/200 V, 400 Hz, 3AE -Load Ratings: Resistive: 60 Amps Inductive: 60 Amps Motor: 40 Amps Minimum Current: 4 Amps Rupture: 400 Amps * Environmental Seal: MIL-STD202, METHOD 112 Test Condition C Procedure IV * Seal: 6 x 10-4 STD CC/SEC * Economizer Coil: 30 Vdc -Inrush: 1.25 Amps (20 milliseconds max) -Steady State: 0.25 Amps * Resistive * Inductive * Motor * Minimum Current * Rupture * Contact Drop - Initial - After Life Test * Contact Bounce 115/200 Vac 400 Hz 60 A. 60 A. 40 A. 4 A. 400 A. 28 Vdc 20 A. 10 A. .... .... .... 0.150 V Max. 0.175 V. Max. 2 Milliseconds .... .... DC ratings are maximum overload capability. By wiring two poles in series, 28 Vdc rating can be increased to the same as the full AC ratings. Options * * * * AC operated coils Encapsulated terminals Internal coil suppression Suitable for synchronized power supplied transfer Selection Table Poles and Throw-Circuit Number of Auxiliary Contacts 1 P.D.T. Government Type Number M6106 Catalog Number 3 P.S.T.-N.O. -- 1 /10-001 /10-002 SM15AWD1 SM15AXD1 3 P.S.T.-N.C. -- 1 /11-001 /11-002 SM15BWD1 SM15BXD1 3 P.D.T. -- 1 /9-001 /9-002 SM15CWD1 SM15CXD1 3 P.S.T.-N.O. -- 10-005* SM15AWD3 * Unit supplied with internal coil suppression. 45 V max. peak inverse voltage. Typical Wiring Digrams X1 (+) X2 (-) X1 (+) X2 (-) A3 A2 B3 B2 C3 C2 3 P.S.T. - N.C. Auxiliary Contact 40 LABINAL POWER SYSTEMS X1 (+) X2 (-) 11 13 12 A3 A3 B3 B3 C3 C3 3 P.S.T. - N.C. Auxiliary Contact TF300-9E A1 A3 B1 B3 C1 C3 X1 (+) X2 (-) A2 B2 C2 3 P.D.T. Without Auxiliary Contact A1 A3 B1 B3 C1 C3 X1 (+) X2 (-) 11 13 12 A2 B2 A1 A2 B1 B2 C1 C2 C2 3 P.DT. With Auxiliary Contact 3 P.S.T. N.O. Without Auxiliary Contact With Internal Coil Suppression POWER RELAYS -- ENVIRONMENTALLY SEALED LIGHTWEIGHT - SM15 SERIES C1 11 12 13 2.313 (50.75) B1 A2 A3 B3 2.40 (60.96) .240 R. (6.096) C3 Top View - SM15AWD1 3 PST N.O. Contacts. Without Auxiliary Contacts A1 B1 C1 A2 B2 C2 X2 2.313 (58.75) X1 1.375 (34.93) .240 R. (6.096) Side View UPPER AND LOWER BARRIERS Power Terminals .190-32 UNF-2A .475 (12.07) NAMEPLATE 3.032 (77.01) SM15CXDI 3PDT and Auxiliary Contacts 2.500 (63.50) * 28 Vdc: Inrush 1.25 Amps (20 MS Max); Steady State 0.25 Amps * Pick-up: 17 Vdc. Hold in: 7.0 Vdc Drop-out: 1.5 Vdc Unit must drop out at 1.5 Vdc and below and can drop out at any voltage below 7 Vdc. * Operate Time: 25 MS. Release Time: 25 MS * Contact Bounce: 2 MS maximum main and auxiliary contacts A1 .60 (5.24) 2.125 (53.98) Coil Data .148 DIA. (3.76) 4 MTG. HOLES 1.06 (26.92) * Meets MIL-R-6106/9, /10, /11 Type IV Environmentally Sealed - Continuous Duty Operation * Power Contacts 400 Hz: - Voltage: 115 V Single Phase 115 V/ 200 V Three Phase - Load Ratings per Pole: Resistive: 60 Amps Inductive: 60 Amps Motor: 40 Amps Minimum Current: 4 Amps Overload: 320 Amps Rupture: 400 Amps - Electrical Life at Rated Loads: 100,000 operations (50,000 motor) - Mechanical Life at 15 Amps: 200,000 operations * Auxiliary Contacts 115 V 400 Hz/ 28 Vdc: - Resistive: 3 Amps - Inductive: 1.5 Amps - Mechanical: 0.5 Amps * Operating Temperature: -55C to 71C * Shock: 1/2 Sine, 25 g's 6 to 9 MS - Contact Opening: 1 millisecond maximum * Acceleration: 15 g's * Insulation Resistance Minimum - Initial: 200 Megohms - After Test: 100 Megohms * Vibration: - 5 to 10 Hz 0.08" DA - 10 to 55 Hz 0.06" DA - 55 to 400 Hz 10 g's - 400 to 800 Hz 8 g's - 800 to 2000 Hz 8 g's (-55C to 25C) 7 g's at 71 * Dielectric Strength Sea Level 2-5 sec. 60 Hz: - Coil & Auxiliary Contacts: 1250 V Initial, 1000 V After Test, Across open power contacts: 1250 V Initial 625 V After Life. - All Other Points: 1800 V Initial, 1350 V After Test * Dielectric Strength Altitude 1 minute 60 Hz: - Coil & Auxiliary Contacts: 500 V Initial & After Test - All Other Points: 700 V Initial & After Test Top View - SM15CXD1 3PDT and Auxiliary Contacts 1.890 (48.01) Specifications Dimensions Drawings 1.900 (48.26) Engineering Data CIRCUIT PLATE LABINAL POWER SYSTEMS TF300-9E 41 GENERATOR CONTACTORS -- 40 KVA 135 AMPERES CONTACTORS - SM135B2 Approximate Dimensions 42 LABINAL POWER SYSTEMS TF300-9E GENERATOR CONTACTORS -- 40 KVA 135 AMPERES CONTACTORS SM135B2 POWER RELAY - 115/200 V 400 HZ Engineering Data Electrical Characteristics Specifications * Designed to MIL-R-6106/42 * All moving parts, contacts, and magnet coil gasket sealed & vented * Operable at altitudes to 50,000 feet * Operating Temperature: -55C to +71C * Altitude: 50,000 ft. Max. * Vibration: - Per MIL-E-5400 - Curve IV, 5-2000 Hz * Shock: 30 g's, Half Sine, 11 MS Duration * Acceleration: 6 g's * Maximum weight: 3.15 Lbs/ 1425.31 gm * Overload Current: 1080 Amps Insulation Resistance (Initial): After Life or Environmental Tests: 200 Megohms 100 Megohms Rupture Current (Main) 1350 amp * Rupture Current: 1350 Amps Duty Rating Continuous Contact Voltage Drop (Initial): MAIN 0.175 V max. - .150 V avg After Life Test 0.200 V max. - .175 V avg Contact Voltage Drop (Initial) AUX 0.400 V max. - .300 V avg After Life Test 0.450 V max. - .400 V avg At 5 Amps Overload Current (Main) 1080 amp Coil Suppression to meet requirements of MIL-E-6051D(1) Dielectric Strength Application Notes Mechanically interlocked contact circuits prevent inadvertent operation of the alternate contact circuits. These units are suitable for load transfer typically from ground support to on-board power. Test Voltage Vrms Description At Sea Level (2-5 Sec.) Initial At Altitude (60 Sec.) After Life 28 Vdc 115 Vac 28 Vdc 115 Vac 28 Vdc Coil to Case 1250 -- 1000 -- 500 115 Vac -- Aux. Contacts 1250 1500 1000 1125 500 500 All Other Points NA 1800 NA 1350 NA 700 Operating Characteristics Coil Data Nominal Max * Volts Volt 28DC Amp In Rush 30 5 ** Drop-Out Voltage Pick-Up Volts At 25C Cont. 1 Hi Temp 15DC Time Milliseconds Max. Count Cur. 18DC Coil Voltage 22.5 DC Bounce Time at 28 Vdc 18 Vdc 23 Vdc 30 Vdc Operate Release Transfer Main Aux. 50 35 10 2 4 7+0/-6 * Pick-Up: Coil will operate at the voltages shown and higher. ** Drop-Out: Coil will drop out at 1 Vdc and may drop out at any voltage from 7 Vdc and below. Rated Contact Load -- (Amps per pole) Case Grounded Type of Load Life Operating Cycles X103 N.O. N.C. N.O. N.C. 400 Hz 60 Hz 400 Hz 60 Hz 400 Hz 60 Hz 400 Hz 60 Hz Resistive 50 120* -- 5 5 135 -- 5 -- 135 -- 5 -- Inductive 50 -- -- 3 3 135 -- 3 -- 135 -- 3 -- Motor 50 -- -- -- -- 80 -- -- -- 80 -- -- -- Lamp -- -- -- 2 2 -- -- 2 -- -- -- 2 -- Transfer Load 10 -- -- -- -- 135 -- -- -- 135 -- -- -- 100 -- -- 1.25 1.25 33.75 -- 1.25 -- 33.75 -- 1.25 -- 50 13.5 13.5 Mech. Life Reduced Amps Interm. Current 28 Vdc 115 Vac 1 Phase 400 Hz Main Aux. Main 115/200 Vac 3 Phase 400 Hz Aux. Main Aux. Per MIL-R-6106 * Room Ambient conditions 100,000 operations. LABINAL POWER SYSTEMS TF300-9E 43 FLAT PACKS -- CUSTOM CAPABILITY Engineering Data * Construction: Gasket Sealed (vented) MIL -R - 6106 Type III, except as noted * Ratings: - Main Contacts Configuration: SPST N.O. Voltage (Nominal): 28 Vdc Current Resistive: 400 Amp (Terminal Temperature Rise 85C above 71C Ambient) Inductive: 100 Amps Motorload: 400 Amps Overload: 2,000 Amps Custom Motor Current: See Graph 20,000 cycles (Min.) Motor Current test to be run 5 cycles per hour maximum with 90 seconds off time between cycles * Life: Electrical: 50,000 Cycles Minimum Mechanical: 100,000 Cycles - Weight: (Max.): 2.25 Lbs/ 1020.58 gm * Environmental Data Ambient Temp: -55C to +71C Altitude: 50,000 Feet Maximum - Vibration: 5 to 14 Hz 0.2" Double Amplitude 14 to 33 Hz 2 g 33 to 52 Hz 0.036" Double Amplitude 52 to 500 Hz 5 g (peak) - Acceleration: 12 g Maximum (Steady State Load) - Shock: G-Level: 25 g's Duration: 6 to 9 Milliseconds - Max. Duration Contact 2 Milliseconds Opening * Coil Data: - Duty Cycle: Continuous, Economizing - Nom. Operating - Voltage: 28 Vdc - Pick-Up Voltage: 18 Vdc Max. at 25C - Drop-Out Voltage: 0.75-3.50 Vdc at 25C - Hold Voltage: 9 Vdc - Operating Time: 35 Milliseconds Maximum - Inrush Current: 3.0 Amps Max for 50 Milliseconds Max. at 25C - Hold Current: 1.2 Amps Max. at 25C * Auxiliary Contacts: - Voltage: 28 Vdc or 115 V, 400 Hz - Current: 5 Amp Resistive Options * Low Level Auxiliary Contacts * Auxiliary Terminal Size and Length 44 LABINAL POWER SYSTEMS Electronic Control will add coil turns to compensate for low battery voltage during starter operation. TF300-9E FLAT PACKS -- CUSTOM CAPABILITY Typical Configurations -- 400 Amp 4.56 115.82 1.25 31.75 .88 22.35 .1.75 44.45 .1.28 32.51 2.56 65.02 RECOMMENDED INSTALLATION TORQUE 90 in-lbs MAX. A2 HIGH VOLTAGE TEST SHORT +X1 TO -X2 BEF0RE -X2 COIL A1 CAUTION .266 DIA. 6.76 2 MTG. HOLES 14 ELECTRONIC CONTROL 13 12 12 11 RECOMMENDED INSTALLATION TORQUE 19 in-lbs MAX -X2 A2 14 11 +X1 +X1 A1 13 1.13 28.70 2.00 50.80 NAMEPLATE 4.06 103.12 4.56 115.82 3.13 79.50 .78 19.81 1.25 31.75 A2 .88 22.35 .1.75 44.45 .1.28 32.51 COIL A1 HIGH VOLTAGE TEST ELECTRONIC CONTROL -X2 -X2 SHORT +X1 TO -X2 BEF0RE .266 DIA. 6.76 2 MTG. HOLES +X1 RECOMMENDED INSTALLATION TORQUE 90 in-lbs MAX. IND A2 RECOMMENDED INSTALLATION TORQUE 19 in-lbs MAX A1 CAUTION 2.56 65.02 +X1 IND SUPPLIES 28 Vdc POWER FROM MOVEABLE CONTACTS NAMEPLATE 4.06 103.12 (2) .375-24UNF-2A 6 X #10(.190)-32UNF-2A .75 19.05 4.56 115.82 .88 22.35 .1.75 44.45 .1.28 32.51 2.56 65.02 COIL RECOMMENDED INSTALLATION TORQUE 90 in-lbs MAX. 3.42 86.87 A1 13 A2 14 24 VENT LOCATION 5.15 130.81 -X2 .06 1.52 SHORT +X1 TO -X2 BEF0RE HIGH VOLTAGE TEST .266 DIA. 6.76 2 MTG. HOLES 12 ELECTRONIC CONTROL CAUTION 12 11 +X1 -X2 A2 14 11 RECOMMENDED INSTALLATION TORQUE 19 in-lbs MAX MADE IN U.S.A. A1 13 23 +X1 NAMEPLATE 400 AMP S.P.-S.T. 28 VDC RELAY 28 VDC COIL NO. SM400D78 GR835AAR FSCM 81640 1.25 31.75 .50 12.70 1.13 28.70 2.00 50.80 NAMEPLATE 4.06 103.12 LABINAL POWER SYSTEMS TF300-9E 45 QUALIFIED PRODUCTS UNDER MILITARY SPECIFICATION -- MIL-PRF-6106 AND MIL-PRF-83383 MIL P/N Cross Reference MIL P/N M6106/9-001 Labinal Power Systems P/N Page MIL P/N Labinal Power Systems P/N Page MIL P/N SM15CWD1 36 M83383/02-06 SM600BA25A1 3 MS24166-D1 Labinal Power Systems P/N 6041H200 Page MIL P/N Labinal Power Systems P/N Page 19 MS24376-A2 6042H148 24/26 M6106/9-002 SM15CXD1 36 M83383/02-07 SM600BA35A1 3 MS24166-D2 6041H201 19 MS24376-A3 6042H288 24/26 M6106/10-001 SM15AWD1 36 M83383/02-08 SM600BA40A1 3 MS24168-A3 6042H289 24/26 MS24376-A4 6042H285 24/26 M6106/10-002 SM15AXD1 36 M83383/02-09 SM600BA50A1 3 MS24168-A4 6042H286 24/26 MS24376-D1 6042H145 24/26 M6106/10-005 SM15AWD3 36 M83383/02-10 SM600BA60A1 3 MS24168-D1 6042H161 24/26 MS24376-D2 6042H146 24/26 M6106/11-001 SM15BWD1 36 M83383/02-11 SM600BA75A1 3 MS24168-D2 6042H162 24/26 MS25030-D1B 6046H51 19 M6106/11-002 SM15BXD1 36 M83383/02-13 SM600BA100A1 3 MS24171-D1 6041H215 19 MS25031-D1B 6046H53 19 M6106/48-001 SM100H1 32 M83383/04-03 SM601BA10A1 3 MS24171-D2 6041H202 19 MS25032-D1 6046H46 19 M6106/48-002 SM100H15 32 M83383/04-04 SM601BA15A1 3 MS24172-D1 6041H216 19 MS27242-1 6042H181 24/26 24/26 M83383/01-01 SM600BA5N1 3 M83383/04-05 SM601BA20A1 3 MS24172-D2 6041H203 19 MS27242-2 6042H182 M83383/01-03 SM600BA10N1 3 M83383/04-07 SM601BA35A1 3 MS24178-D1 6041H219 19 MS27243-1 49-2661 23 M83383/01-04 SM600BA15N1 3 M83383/04-08 SM601BA40A1 3 MS24179-D1 6041H218 19 MS27243-2 49-2665 23 M83383/01-05 SM600BA20N1 3 M83383/04-10 SM601BA60A1 3 MS24179-D2 6041H206 19 MS27243-3 49-2667 23 M83383/01-06 SM600BA25N1 3 MS24140-D1 6042H155 24/26 MS24182-D1 6042H166 19 MS27243-4 49-2670 23 M83383/01-07 SM600BA35N1 3 MS24140-D2 6042H156 24/26 MS24183-D1 6042H167 19 MS27243-5 49-2672 23 M83383/01-08 SM600BA40N1 3 MS24141-D1 6042H159 24/26 MS24184-D1 6042H153 19 MS27243-6 49-3179 23 M83383/01-09 SM600BA50N1 3 MS24141-D2 6042H160 24/26 MS24184-D2 6042H154 19 MS27997-D1 6042H91 24/26 M83383/01-10 SM600BA60N1 3 MS24142-D1 6042H151 24/26 MS24185-D1 6041H217 19 MS27997-D2 6042H92 24/26 M83383/01-11 SM600BA75N1 3 MS24142-D2 6042H152 24/26 MS24185-D2 6041H205 19 AN3362 6041H209 19 M83383/01-13 SM600BA100N1 3 MS24143-A3 6042H290 24/26 MS24187-D1 6041H220 19 AN3372-1 6041H204 19 M83383/02-01 SM600BA5A1 3 MS24143-A4 6042H291 24/26 MS24187-D2 6041H230 19 M83383/02-03 SM600BA10A1 3 MS24143-D1 6042H141 24/26 MS24192-D1 9565H2 19 M83383/02-04 SM600BA15A1 3 MS24143-D2 6042H142 24/26 MS24193-D1 9565H94 19 M83383/02-05 SM600BA20A1 3 MS24143-D3 6042H110 24/26 MS24376-A1 6042H147 24/26 46 LABINAL POWER SYSTEMS TF300-9E ELECTRICAL SENSING & CONTROLS Product Application Information and Warranty Disclaimer It is buyer's responsibility to determine the suitability of the particular device for its application, and Labinal Power Systems Aerospace LLC. makes no warranties, and assumes no liability as to the suitability of sufficiency for buyer's application of the device. Ratings and switch performance are valid only on devices which have not been subjected to unauthorized modifications or misapplications. Dimensional drawings are available upon request. Notice The use of Labinal Power Systems Aerospace LLC. devices should be in accordance with the provisions of the National Electric Code, U.L. and/ or other local, military or industry standards that are pertinent to the particular end use. Installation or use not in accordance with these codes and standards could be hazardous to personnel and/or equipment. Export Controls Compliance Reminder to our catalog customers, product in this catalog, if exported, is subject to United States Export Control regulations. Labinal Power Systems Aerospace encourages our customers to understand the regulations and ensure compliance, including obtaining written U.S. government authorizations when applicable. Government Cage Code The Government Cage Code for products manufactured by Labinal Power Systems Aerospace Sensing & Controls are 81640, 76374, 96182, 99145 and 27878. Need additional information not contained in this catalog? For technical questions, application assistance, or the name of your local authorized distributor, call 1-800-9557354. LABINAL POWER SYSTEMS TF300-9E 47 Local contact (Sarasota, FL): LABINAL POWER SYSTEMS 2250 Whitfield Avenue Sarasota, FL 34243 USA Tel. 1-800-955-7354 * Fax 941-751-7173 LABINAL POWER SYSTEMS Headquarters : 36 rue Raymond Grimaud 31700 BLAGNAC - FRANCE Tel. +33 (0)5 34 60 00 00 - Fax +33 (0)5 34 60 01 99 www.labinal-power.com