Automation Controls Catalog 1 Form A 5A slim power relay complies with IEC61010 reinforced insulation FEATURES Protective construction: Sealed type (RTIII) 1. High density mounting 5mm(W) 20mm(L) 12.5mm(H) 2. Low operating power Rated operating power: 110mW 3. Complies with IEC61010 reinforced insulation standards 4. Long insulation distance * Clearance: 5.29mm Creepage distance: 5.35mm (Between contact and coil) * 3,000 V dielectric strength and 6,000V surge breakdown voltage 5. Complies with standard for hazardous location (ANSI/ISA 12.12.01) PA-N RELAYS TYPICAL APPLICATIONS 1. Output relays for programmable controllers and temperature controllers 2. Industrial equipment, office equipment 3. Measuring devices and test equipment ORDERING INFORMATION APAN 3 1 Contact arrangement 3: 1 Form A Bifurcated Terminals and rated operating power 1: PC board terminal110mW Rated coil voltage DC 03: 3V, 4H: 4.5V, 05: 5V, 06: 6V 09: 9V, 12: 12V, 18: 18V, 24: 24V TYPES Contact arrangement 1 Form A Rated coil voltage Part No. 3 V DC APAN3103 4.5 V DC APAN314H 5 V DC APAN3105 6 V DC APAN3106 9 V DC APAN3109 12 V DC APAN3112 18 V DC APAN3118 24 V DC APAN3124 Standard packing Carton (Tube) Outer carton 25 piecies 1,000 piecies * Terminal sockets available. 2019.04 industrial.panasonic.com/ac/e/ 1 c Panasonic Corporation 2019 ASCTB368E 201904 PA-N (APAN3) RATING 1.Coil data *Operating characteristics such as `Operate voltage' and `Release voltage' are influenced by mounting conditions, ambient temperature, etc.Therefore, please use the relay within 5% of rated coil voltage. *`Initial' means the condition of products at the time of delivery. Rated coil voltage Operate voltage (at 20C) Release voltage (at 20C) Rated operating current [10%] (at 20C) Coil resistance [10%] (at 20C) 3 V DC 36.7 mA 82 4.5 V DC 24.4 mA 184 22.0 mA 227 18.3 mA 327 12.2 mA 736 5 V DC 70%V or less of rated voltage* (Initial) 6 V DC 9 V DC 12 V DC 5%V or more of rated voltage* (Initial) 9.2 mA 1,309 18 V DC 6.1 mA 2,945 24 V DC 4.6 mA 5,236 Rated operating power Max. allowable voltage (at 20C) 110 mW 120%V of rated voltage Note: *Pulse drive (JIS C 5442) 2.Specifications Item Contact arrangement Contact data Contact resistance (initial) Max. 30 m (by voltage drop 6 V DC 1A) Contact material AgNi type + Au Contact rating (resistive) 5 A 250 V AC, 5 A 30 V DC Max. switching power (resistive) 1,250 VA, 150 W Max. switching voltage 250 V (AC), 110 V (DC) (0.4 A) Max. switching current 5 A (AC, DC) Min. switching capacity (reference value)*1 100 A 100 mV DC Insulation resistance (initial) Dielectric strength (initial) Surge breakdown voltage (initial)*2 Time characteristics (initial) Shock resistance Vibration resistance Specifications 1 Form A (bifurcated) Min. 1,000M (at 500V DC) Measurement at same location as "Breakdown voltage" section. Between open contacts 1,000 Vrms for 1min. (detection current: 10mA.) Between contact and coil 3,000 Vrms for 1min. (detection current: 10mA.) Between contacts and coil 6,000 V Operate time Max. 10 ms (at rated coil voltage at 20C, without bounce) Release time Max. 5 ms (at rated coil voltage at 20C, without bounce, without diode) Functional Min. 147 m/s2 (half-wave pulse of sine wave: 11 ms; detection time: 10 s.) Destructive Min. 980 m/s2 (half-wave pulse of sine wave: 6 ms.) Functional 10 to 55 Hz (at double amplitude of 2.5 mm, detection time: 10 s.) Destructive 10 to 55 Hz (at double amplitude of 3.5 mm) Expected life Mechanical Min. 2x107 (at 180 times/min.) Conditions Condition for usage, transport and storage*3 Ambient temperature: -40C to +90C Humidity: 5 to 85% R.H. (not freezing and condensing at low temperature) Approx. 3 g Unit weight Notes: *1. This value can change due to the switching frequency, environmental conditions, and desired reliability level, therefore it is recommended to check this with the actual load. *2. Wave is standard shock voltage of 1.2x50s according to JEC-212-1981 *3. The upper limit of the ambient temperature is the maximum temperature that can satisfy the coil temperature rise value. Refer to Usage, transport and storage conditions in NOTES. 3.Expected electrical life Conditions: Resistive load, at 20 times/min. Type 1 Form A Switching capacity Number of operations 3 A 250 V AC Min. 105 3 A 30 V DC Min. 105 5 A 250 V AC Min. 5x104 (at 6 times/min, ON:OFF = 1 s:9 s) 5 A 30 V AC Min. 5x104 Panasonic Corporation Electromechanical Control Business Division industrial.panasonic.com/ac/e/ 2 c Panasonic Corporation 2019 ASCTB368E 201904 PA-N (APAN3) REFERENCE DATA 1. Max. switching capacity 2. Life curve 3. Coil temperature rise Tested sample: APAN3124, 6 pcs. Measured portion: Inside the coil Ambient temperature: 20C, 90C (No contact current) 10 DC resistive load 1 0.4 35 30V DC resistive load 100 50 40 30 20 Temperature rise (C) No. of operations (x10 4) Contact current (A) 5 40 250V AC resistive load AC resistive load 250V AC (cos = 0.4) 30V DC (L/R = 7ms) 10 5 30 25 20C 5A 20C 3A 20C 0A 20 15 90C 0A 10 5 0.1 1 10 100 1 0.1 1,000 Contact voltage (V) 5 10 Drop-out voltage 10 Pick-up voltage 0 60 80 100 Ambient temperature (C) m/s2 130 140 150 Deenergized condition Energized condition 800 600 400 7.0 6.0 0 Max. Ave. Min. 4.0 3.0 Release time 0 70 80 90 100 Z 200 Operate time 5.0 1.0 30 120 Y 1,000 8.0 2.0 20 DIMENSIONS (mm) 110 Tested sample: APAN3124, 6 pcs. 9.0 20 40 100 6. Malfunctional shock 10.0 30 20 0 90 Coil applied voltage (%V) Tested sample: APAN3124, 20 pcs. Measured direction: Upright Operate & release time (ms) Rate of change (%) 3 5. Operate & release time Tested sample: APAN3124, 6 pcs. 10 1 Contact current (A) 4. Ambient temperature characteristics 60 40 20 0.5 ' Z' Y' Z' Max. Ave. Min. 110 120 Coil applied voltage (%V) Z Y Y' ' 130 CAD The CAD data of the products with a "CAD" mark can be downloaded from our Website. External dimensions CAD PC board pattern (Bottom view) 1dia. 1dia. 1.2dia. 1.2dia. 1.2 8.8 1.3 6 4.8 2.9 3.5 12.5Max.12.8 0.3 0.5 5 2.54 2.54 Tolerance 0.1 0.5 10.16 20 5.08 0.8 1.1 1.2 0.25 Schematic (Bottom view) General tolerance 0.3 Panasonic Corporation Electromechanical Control Business Division industrial.panasonic.com/ac/e/ 10.16 5.08 3 1 2 c Panasonic Corporation 2019 5 6 ASCTB368E 201904 PA-N (APAN3) SAFETY STANDARDS UL/C-UL (Recognized) File No. E43149 TUV (Certified) Contact ratings Cycles Temp. 5 A 250 V AC resistive 5 A 250 V AC resistive 5 A 30 V DC general use 5 A 30V DC, 3 A 250 V AC general use 3 A 250 V AC resistive 3 A 30 V DC general use B300, R300 pilot duty 5x104 104 5x104 104 105 105 6x103 40C 90C 40C 90C 40C 40C 40C File No. Contact ratings B18 03 13461 368 5 A 250 V AC (cos =1.0) 5 A 250 V AC (cos =1.0) 5 A 30 V DC (0 ms) 5 A 30 V DC (0 ms) 3 A 250 V AC (cos =1.0) 3 A 30 V DC (0 ms) Cycles Temp. 5x104 104 5x104 104 105 105 40C 90C 40C 90C 40C 40C E479891 Class I, division 2, groups A, B, C, D hazardous location (ANSI/ISA 12.12.01-2015, CAN/CSA C22.2 No.213-15) Insulation distance (between contact and coil) * UL/C-UL: Clearance distance: 5.29 mm , Creepage distance: 5.35 mm . * TUV: Clearance distance: 5.29 mm , Creepage distance: 5.35 mm . NOTES 1. For cautions for use, please read "GENERAL APPLICATION GUIDELINES". 2. If it includes ripple, the ripple factor should be less than 5%. 3. Specification values for pick-up and drop-out voltages are for the relay mounting with its terminals below. Tested sample: APAN3124, 6 pcs. Ambient temperature: 20C Measured direction: 6 direction 4. When mounting the relays within 1 mm please notice the condition below. 1) Mount the relays in the same direction. Within 1mm Tested sample: APAN3124, 6 pcs. Ambient temperature: 20C Measured direction: 6 directions 100 2) Coil terminals (Terminal No. 1 & 2) polarity should be arranged in the same direction. 90 Voltage (%V) 80 70 Pick-up voltage Max. 60 Ave. Min. 50 40 30 20 Drop-out voltage Max. Ave. Min. 10 0 Top Mounting direction Bottom Please refer to "the latest product specifications" when designing your product. *Requests to customers: https://industrial.panasonic.com/ac/e/salespolicies/ Panasonic Corporation Electromechanical Control Business Division industrial.panasonic.com/ac/e/ 4 c Panasonic Corporation 2019 ASCTB368E 201904 PA-N RELAYS TERMINAL SOCKETS ACCESSORIES TYPES Product name Standard type terminal socket Self clinching type terminal socket Standard type terminal socket Self clinching type terminal socket DIMENSIONS (mm inch) CAD The CAD data of the products with a "CAD" mark can be downloaded from our Website. Standard type terminal socket External dimensions CAD 1 Part No. PA1a-PS PA1a-PS-H 2 3 4 5 Self clinching type terminal socket External dimensions CAD 5+0.2 -0.6 .197+.008 -.024 6 1 2 22.60.6 .890.024 4 .157 0.5 .020 2.54 .100 6.35 .250 3 4 5 5+0.2 -0.6 .197+.008 -.024 6 22.60.6 .890.024 0.8 .031 3.81 .150 90.6 .354.024 90.6 .354.024 5.30.6 .209.024 5.30.6 .209.024 (0.3) (.012) 5.08 .200 3.9 10.25 .154 .039.010 1.23 .048 0.25 .010 1.23 .048 0.8 .031 0.5 .020 2.54 .100 6.35 .250 3.81 .150 (0.3) (.012) 5.08 .200 General tolerance:0.3 .012 General tolerance:0.3 .012 PC board pattern (Bottom view) PC board pattern (Bottom view) 1.0 dia. .039 dia. 1.0 dia. .039 dia. 2.54 .100 10.16 .400 1.2 dia. .047 dia. 1.2 dia. .047 dia. 1.30.15 .051.006 0.80.25 dia. 1.20.05 dia. .031.010 dia. .047.002 dia. 0.80.25 dia. 1.20.05 dia. .031.010 dia. .047.002 dia. 5.08 .200 2.54 .100 Tolerance: 0.1 .004 10.16 .400 5.08 .200 Tolerance: 0.1 .004 INSTALLING AND REMOVING Installing and removing the relay 1) Firmly insert the relay into the socket with the terminals going in the direction of the blade receptacles. 2) The relay can be easily removed using the removal key (APA801). (1) Insert the removal key into the socket slots. (2) Pull the removal key up to remove the relay. Panasonic Corporation Electromechanical Control Business Division industrial.panasonic.com/ac/e/ 5 (3) Slide the removal key off of the relay. (c) Panasonic Corporation 2019 ASCTB373E 201903 GUIDELINES FOR POWER RELAYS AND HIGH-CAPACITY DC CUT OFF RELAYS USAGE For cautions for use, please read "GUIDELINES FOR RELAY USAGE". https://industrial.panasonic.com/ac/e/control/relay/cautions_use/index.jsp Precautions for Coil Input Long term current carrying A circuit that will be carrying a current continuously for long periods without relay switching operation. (circuits for emergency lamps, alarm devices and error inspection that, for example, revert only during malfunction and output warnings with form B contacts) Continuous, long-term current to the coil will facilitate deterioration of coil insulation and characteristics due to heating of the coil itself. For circuits such as these, please use a magnetic-hold type latching relay. If you need to use a single stable relay, use a sealed type relay that is not easily affected by ambient conditions and make a failsafe circuit design that considers the possibility of contact failure or disconnection. DC Coil operating power Steady state DC current should be applied to the coil. The wave form should be rectangular. If it includes ripple, the ripple factor should be less than 5%. However, please check with the actual circuit since the electrical characteristics may vary. The rated coil voltage should be applied to the coil and the set/reset pulse time of latching type relay differs for each relays, please refer to the relay's individual specifications. Maximum allowable voltage and temperature rise Proper usage requires that the rated coil voltage be impressed on the coil. Note, however, that if a voltage greater than or equal to the maximum continuous voltage is impressed on the coil, the coil may burn or its layers short due to the temperature rise. Furthermore, do not exceed the usable ambient temperature range listed in the catalog. Operate voltage change due to coil temperature rise (Hot start) In DC relays, after continuous passage of current in the coil, if the current is turned OFF, then immediately turned ON again, due to the temperature rise in the coil, the pick-up voltage will become somewhat higher. Also, it will be the same as using it in a higher temperature atmosphere. The resistance/temperature relationship for copper wire is about 0.4% for 1C, and with this ratio the coil resistance increases. That is, in order to operate of the relay, it is necessary that the voltage be higher than the pick-up voltage and the pick-up voltage rises in accordance with the increase in the resistance value. However, for some polarized relays, this rate of change is considerably smaller. Coil connection When connecting coils of polarized relays, please check coil polarity (+,-) at the internal connection diagram (Schematic). If any wrong connection is made, it may cause unexpected malfunction, like abnormal heat, fire and so on, and circuit do not work. Avoid impressing voltages to the set coil and reset coil at the same time. Ambient Environment Dew condensation Usage, Transport, and Storage Conditions Condensation occurs when the ambient temperature drops suddenly from a high temperature and humidity, or the relay is suddenly transferred from a low ambient temperature to a high temperature and humidity. Condensation causes the failures like insulation deterioration, wire disconnection and rust etc. Panasonic Corporation does not guarantee the failures caused by condensation. The heat conduction by the equipment may accelerate the cooling of device itself, and the condensation may occur. Please conduct product evaluations in the worst condition of the actual usage. (Special attention should be paid when high temperature heating parts are close to the device. Also please consider the condensation may occur inside of the device.) During usage, storage, or transportation, avoid locations subjected to direct sunlight and maintain normal temperature, humidity and pressure conditions. Temperature/Humidity/Pressure When transporting or storing relays while they are tube packaged, there are cases the temperature may differ from the allowable range. In this case be sure to check the individual specifications. Also allowable humidity level is influenced by temperature, please check charts shown below and use relays within mentioned conditions. (Allowable temperature values differ for each relays, please refer to the relay's individual specifications.) Icing Condensation or other moisture may freeze on relays when the temperature become lower than 0C.This icing causes the sticking of movable portion, the operation delay and the contact conduction failure etc. Panasonic Corporation does not guarantee the failures caused by the icing. The heat conduction by the equipment may accelerate the cooling of relay itself and the icing may occur. Please conduct product evaluations in the worst condition of the actual usage. Low temperature and low humidity The plastic becomes brittle if the switch is exposed to a low temperature, low humidity environment for long periods of time. High temperature and high humidity Storage for extended periods of time (including transportation periods) at high temperature or high humidity levels or in atmospheres with organic gases or sulfide gases may cause a sulfide film or oxide film to form on the surfaces of the contacts and/or it may interfere with the functions. Check out the atmosphere in which the units are to be stored and transported. 1) Temperature: The tolerance temperature range differs for each relays, please refer to the relay's individual specifications 2) Humidity: 5 to 85 % RH 3) Pressure: 86 to 106 kPa Humidity, %R.H. 85 Allowable range (Avoid icing when used at temperatures lower than 0 C) 5 -40 (Avoid condensation when used at temperatures higher than 0 C) 0 Ambient temperature, C 85 Panasonic Corporation Electromechanical Control Business Division industrial.panasonic.com/ac/e/ 6 c Panasonic Corporation 2019 ASCTB412E 201903 GUIDELINES FOR POWER RELAYS AND HIGH-CAPACITY DC CUT OFF RELAYS USAGE Package In terms of the packing format used, make every effort to keep the effects of moisture, organic gases and sulfide gases to the absolute minimum. Silicon When a source of silicone substances (silicone rubber, silicone oil, silicone coating materials and silicone filling materials etc.) is used around the relay, the silicone gas (low molecular siloxane etc.) may be produced. This silicone gas may penetrate into the inside of the relay. When the relay is kept and used in this condition, silicone compound may adhere to the relay contacts which may cause the contact failure. Do not use any sources of silicone gas around the relay (Including plastic seal types). NOx Generation When relay is used in an atmosphere high in humidity to switch a load which easily produces an arc, the NOx created by the arc and the water absorbed from outside the relay combine to produce nitric acid. This corrodes the internal metal parts and adversely affects operation. Avoid use at an ambient humidity of 85%RH or higher (at 20C). If use at high humidity is unavoidable, please contact our sales representative. Others Cleaning 1) Although the environmentally sealed type relay (plastic sealed type, etc.) can be cleaned, avoid immersing the relay into cold liquid (such as cleaning solvent) immediately after soldering. Doing so may deteriorate the sealing performance. 2) Cleaning with the boiling method is recommended(The temperature of cleaning liquid should be 40C or lower ). Avoid ultrasonic cleaning on relays. Use of ultrasonic cleaning may cause breaks in the coil or slight sticking of the contacts due to ultrasonic energy. Please refer to "the latest product specifications" when designing your product. *Requests to customers: https://industrial.panasonic.com/ac/e/salespolicies/ Panasonic Corporation Electromechanical Control Business Division industrial.panasonic.com/ac/e/ 7 c Panasonic Corporation 2019 ASCTB412E 201903 Please contact .......... Panasonic Corporation Electromechanical Control Business Division 1006, Oaza kadoma, kadoma-shi, Osaka 571-8506, japan industral.panasonic.com/ac/e/ (c)Panasonic Corporation 2019 ASCTB368E-1 201904 Specifications are subject to change without notice.