RFV RFV -Pole Force Guided Relays/SJ Series Relay Sockets Key features: -pole force guided relay to reduce cost and installation space. Force guided contact mechanism (EN00 Type A TÜV approved). Reinforced insulation between coil and contact and contacts of different poles. Mechanical shows contact status. Two terminal styles - socket mounting and PC board mounting. RTIII degree of protection, LED, diode models available. Can be used with SJ series relay socket. Applicable s Mark Certification Applicable Marking Certification Organization/ File Number UL09--a UL/Recogntion File No. E99 CSA C. No. EN00 EN0- CSA File No. LR TÜV SÜD EU Low Voltage Directive -pole Contact Configuration SPST-NO + SPST-NC Terminal Style Plug-in PC Board LED Indicator w/diode Part Numbers Degree of Protection (Note) Flux-tight (RTII) Sealed (RTIII) Rated Coil Voltage Part No. V DC RFS-ABLD-D out RFS-AB-D RFS-ABD-D V DC RFS-ABLD-D RFS-ABLDK-D out out RFS-AB-D V DC RFS-ABLD-D RFS-ABLDK-D V DC RFV-AB-D RFV-AB-D RFV-ABK-D V DC RFV-ABD-D RFV-ABDK-D RFV-ABLDK-D out V DC RFV-AB-D DPDT out V DC RFV-C-D 9 www.idec.com 090
RFV Part Number Structure RF S - AB - LD-K D Series Name No of poles : -pole Terminal Construction S : Plug-in V : PC Board Contact Arrangement A B : Form X C : DPDT Coil Ratings Rated Voltage (V) Rated Current (ma) ±% (at 0 C) Coil Resistance ±0% (at 0 C) Rated Coil Voltage D : V DC D : V DC D : V DC Options Blank : L : LED D : diode (Note ) D : diode of reverse polarity coil (Note ) LD : LED & diode (Note ) LD : LED & diode of reverse polarity coil (Note ) Degree of Protection Blank : RTII K : RTIII out LED LED out LED LED V DC 0 0 V DC 9 0 0 V DC. 00 00 Note : diode: terminal, terminal + Note : diode of reverse polarity coil: terminal +, terminal Note : Used interpreting part numbers. Not all variations are possible. Operating Characteristics (against rated values at 0 C) Minimum Pickup Voltage Note: Maximum continuous applied voltage is the maximum voltage that can be applied to relay coils. s Ratings UL Rating Resistive CSA Rating Resistive Voltage NO NC NO NC V AC A A A A 0V DC A A A A Sockets Style No. of Poles Part Number Screw Terminal Fingersafe Screw Terminal PC Board Mount Sockets SJS-0BW SJS-0LW SJS- Dropout Voltage Maximum Continuous Applied Voltage Consumption % maximum 0% minimum 0% Approx. 0.W TÜV Rating Resistive Voltage NO NC 0VAC A A V DC A A Certification for Sockets Applicable UL0 CSA C. No. EN0999- (Note ) EN0- (Note ) Note : Finger-safe screw terminal only. Note : PC board terminal only. Marking Certification Organization/ File Number UL Recognition File No. E CSA File No. LR9 EC Low Voltage Directive 090 00--IDEC () USA & Canada 9
RFV Specifications Contact Configuration Contact Resistance (initial value) Contact Material Rated Load (resistive load) Allowable Switching (resistive load) Allowable Switching Voltage Allowable Switching Current Minimum Applicable Load Model RFS (Plug-in Terminal) -pole RFV (PC board terminal) -pole SPST-NO + SPST-NC, DPDT 00 mω maximum AgNi+Au-Clad NO contact: 0V AC, A/V DC, A NC contact: 0V AC, A/V DC, A NO contact: 0VA/W, NC contact: 0VA/W 0V AC, V DC A V DC, ma Consumption (approx.) Approx. 0.W Insulation Resistance Dielectric Strength Operating Time (at 0 C) Response Time (at 0 C) Release Time (at 0 C) Vibration Resistance Shock Resistance Electrical Life Mechanical Life Between contact and coil Between contacts of the same pole Between contacts of different poles Operating Extremes Damage Limits Operating Temperature Operating Humidity Storage Temperature 000 MΩ minimum (00V DC megger, same measurement positions as the dielectric strength) 000V AC, minute 000V AC, minute 00V AC, minute ms maximum (at the rated coil voltage, excluding contact bounce time) ms max. (at the rated coil voltage, without diode) 0ms max. (at the rated coil voltage, with diode) 0ms max. (at the rated coil voltage, excluding contact bounce time, without diode) ms max. (at the rated coil voltage, excluding contact bounce time, with diode) NO contact: 0 to Hz, amplitude 0.mm NC contact:0 to Hz, amplitude 0.mm 0 to Hz, amplitude 0.mm Operating Extremes No Contact 00 m/s, NC contact: 0 m/s Damage Limits 000 m/s Operating Frequency (rated load) Weight (approx.). Measured using V DC,A voltage drop method.. Failure rate level P (reference value) NO contact: 00,000 operations minimum (operating frequency,00 per hour) at 0V A resistive load or A inductive load (power factor 0.) 00,000 operations minimum (operating frequency,00 per hour) at V A resistive load or A inductive load (time constant ms) NC contact: 00,000 operations minimum (operating frequency,00 per hour) at 0V AC, A resistive load or A inductive load (power factor 0.) 00,000 operations minimum (operating frequency,00 per hour) at V DC, A resistive load or A inductive load (time constant ms) 0 million operations minimum (operating frequency 0,00 operations per hour) Single mounting: 0 to +0 C (no freezing) Collective mounting: 0 to + C (no freezing) to %RH (no condensation) 0 to + C (no freezing) 00 operations per hour 0 to +0 C (no freezing)=== g (without LED/diode), 0g (with LED/with diode/with LED & diode). Response time is the time until NO contact opens, after the coil voltage is turned off. 9 www.idec.com 090
RFV Socket Specifications Part Number SJS-0B/-0L SJS- Mounting DIN Rail PC Board Rated Current Rated Insulation Voltage Dielectric Strength Between contact and coil Between contacts of the same pole Between contacts of the different pole 000V AC, minute A 0V AC/DC 000V AC, minute 000V AC, minute 000V AC, minute Screw Terminal Style M slotted Phillips screw - Applicable Wire mm - Recommended Screw Tightening Torque 0. to.0 N m - Terminal Strength Wire tensile strength: 0N min. - Vibration Resistance Damage limits: 90 m/s Resonance: 0 to Hz, amplitude 0. mm Shock Resistance 000 m/s Operating Temperature Operating Humidity Storage Temperature Storage Humidity Degree of Protection (Scre Terminal) 0 to +0 C (no freezing) to % RH (no condensation) to + C (no freezing) to % RH (no condensation) SJS-0L: IP0 (IEC 09) - Weight (approx.) 0g.g. When using at 0 to C, reduce the switching current by 0.A/ C. Removable Marking Plate Jumper Replacement Release Lever (with integrated marking plate) Applicable Crimping Terminals Specifications.9 max..0 max..9 max.. min..0 max. ø. min.. min.. to. Note: Ring tongue terminals cannot be used on SJS-0L. Description/Shape Material Part No. Ordering No. Package Quantity Remarks Plastic (white) SJ9Z-PW SJ9Z-PWPN0 0 0... 0. Marking area:.. mm For sockets SJ9Z-JF SJ9Z-JFPN0 Terminal centers:.mm Nickel-coated For sockets Rated current: A brass with SJ9Z-JF SJ9Z-JFPN0 Ensure that the total current to the For sockets polypropylene SJ9Z-JF SJ9Z-JFPN0 jumper does not exceed the maximum coating For 0 sockets SJ9Z-JF0 SJ9Z-JF0PN0 current. Plastic (gray) SJ9Z-CM SJ9Z-CMPN0.... When not using marking plate 090 00--IDEC () USA & Canada 99
RFV Dimensions (mm) RFS (plug-in terminal) (without LED/diode) RFV (PC board terminal) (without LED/diode) PC Board Terminal type Mounting Hole Layout (Bottom View) 0.. 0. (.) (.) (.) (.)..9 LED/diode:. LED/diode:. LED/diode LED/diode Diode LED Diode LED Mechanical Indicator RFV (DPDT) 0 0 () 0 () Mechanical Indicator.. (.)(.) 0. 0 () 0 ().. 9. (.) (.) 0. 0.. 0. 0. 0... 0. *.. (.).. (.)(.) (.) ø -ø.. h o ho le s les RFV (SPST-NO + SPST-NC) ø -ø.. ho ho les les RFV Socket Dimensions SJS-0L SJS-0B 9. 9. ø.. 0. 9 (Top View) SJS- SJS-... 0.9. Marking Plate (integrated with release lever) (Top View) Marking Plate (integrated with release lever) 90 0.. 0..0..0. ø. 9.... M Terminal Screws. M Terminal Screws.0 www.idec.com 090
RFV RF -AB- RF* -ABLD- RF -ABLD- coil LED LED ++diode diode of of reverse reverse polarity polarity coil LED LED ( ) RF* -CLD- coil LED LED ++diode diode of of reverse reverse polarity polarity coil LED LED (+ ) RF* -ABD- RF* -ABD- LED LED reverse polarity coil coil diode diodeofof reverse polarity diode diode RF* -CL- RF* -CD- RF* -CD- LED LEDl reverse polarity coil diode LED of diode diode ( ) ( ) RF* -ABL- RF -CLD- RF *-C- Internal Connection (View from Bottom) Relays with diode have polarity. Take polarity into consideration when wiring. When using DPDT model as a force guided relay, use in SPST-NO + SPST-NC wiring (EN00). 090 00--IDEC () USA & Canada 9
Operating Instructions Driving Circuit for Relays. To ensure correct relay operation, apply rated voltage to the relay coil.. Input voltage for the DC coil: A complete DC voltage is best for the coil power to make sure of stable relay operation. When using a power supply containing a ripple voltage, suppress the ripple factor within %. When power is supplied through a rectification circuit, the relay operating characteristics, such as pickup voltage and dropout voltage, depend on the ripple factor. Connect a smoothing capacitor for better operating characteristics as shown below. Smoothing Capacitor + R Relay Operating Instructions Protection for Relay Contacts Pulsation Emin Emax Emean DC Ripple Factor (%) Emax Emin Emean 00% Emax = Maximum of pulsating current Emin = Minimum of pulsating current Emean = DC mean value. Leakage current while relay is off: When driving an element at the same time as the relay operation, special consideration is needed for the circuit design. As shown in the incorrect circuit below, leakage current (Io) flows through the relay coil while the relay is off. Leakage current causes coil release failure or adversely affects the vibration resistance and shock resistance. Design a circuit as shown in the correct example. Incorrect Correct R Io TE. Surge suppression for transistor driving circuits: When the relay coil is turned off, a high-voltage pulse is generated, causing a transistor to deteriorate and sometimes to break. Be sure to connect a diode to suppress the back electromotive force. Then, the coil release time becomes slightly longer. To shorten the coil release time, connect a Zener diode between the collector and emitter of the transistor. Select a Zener diode with a Zener voltage slightly higher than the power voltage. Back emf suppressing diode + R Relay R. The contact ratings show maximum values. Make sure that these values are not exceeded. When an inrush current flows through the load, the contact may become welded. If this is the case, connect a contact protection circuit, such as a current limiting resistor.. Contact protection circuit: When switching an inductive load, arcing causes carbides to form on the contacts, resulting in increased contact resistance. In consideration of contact reliability, contact life, and noise suppression, use of a surge absorbing circuit is recommended. Note that the release time of the load becomes slightly longer. Check the operation using the actual load. Incorrect use of a contact protection circuit will adversely affect switching characteristics. Four typical examples of contact protection circuits are shown in the following table: RC Diode Varistor + C D Varistor R Ind. Load Ind. Load Ind. Load This protection circuit can be used when the load impedance is smaller than the RC impedance in an AC load power circuit. R: Resistor of approximately the same resistance value as the load C:0. to µf This protection circuit can be used for both AC and DC load power circuits. R: Resistor of approximately the same resistance value as the load C: 0. to µf This protection circuit can be used for DC load power circuits. Use a diode with the following ratings. Reverse withstand voltage: voltage of the load circuit x 0 Forward current: More than the load current This protection circuit can be used for both AC and DC load power circuits. For a best result, when using a power voltage of to V AC/DC, connect a varistor across the load. When using a power voltage of 00 to 0V AC/DC, connect a varistor across the contacts.. Do not use a contact protection circuit as shown below: C Load This protection circuit is very effective in arc suppression when opening the contacts. But, the capacitor is charged while the contacts are opened. When the contacts are closed, the capacitor is discharged through the contacts, increasing the possibility of contact welding. C Load This protection circuit is very effective in arc suppression when opening the contacts. But, when the contacts are closed, a current flows to charge the capacitor, causing contact welding. Generally, switching a DC inductive load is more difficult than switching a DC resistive load. Using an appropriate arc suppressor, however, will improve the switching characteristics of a DC inductive load. Soldering. When soldering the relay terminals, use a soldering iron of 0 to 0W, and quickly complete soldering (within approximately seconds).. Use a non-corrosive rosin flux. 9 www.idec.com 090