Slim compact safety relay SF RELAYS Slim type Max..9 Max..9 Max.. Max..99 Max.. Max.. mm inch FEATURES Forcibly guide contact structure (EN Class A TÜV recognized) Slim profile (mm inch) Compact size with slim profile relay reduces substrate size. [-pole type] (L) (W) (H). (L). (W).9 (H) [-pole type] (L) (W) (H).99 (L). (W).9 (H) Built-in LED indication type available Built-in LED eliminates need for design and mounting of separate LED circuit. This cuts costs and saves labor. Fast response time is achieved ( ms or less) Circuit is quickly opened to ensure safety. High shock resistance (Functional: Min. m/s ) Improved anti-shock properties meaning that the relay can be safely used in high shock and vibration environments such as in machine tools and other factory equipment. PC board sockets also available ( and -poles) Lineup also includes DIN terminal socket with finger protect construction ( and -poles) TYPICAL APPLICATIONS Machine tools Robots Safety PLCs Circuits with stringent safety standard requirements such as those in motor vehicle production equipment. SPECIFICATIONS Contact Contact arrangement Initial contact resistance, max. (By voltage drop V DC A) Contact material Rating (resistive load) Expected life (min. operations) Item poles poles Nominal switching capacity Max. switching power Max. switching voltage Max. switching current Min. switching capacity (Reference value) # m Gold-flashed AgSnO type A V AC, A V DC, VA, W V AC, V DC A (Reduce by. A/ C for temperatures to C.) ma V DC Mechanical (at times/min.) Electrical V AC A resistive load: (at times/min.) V DC A resistive load: (at times/min.) V AC A resistive load: (at times/min.) V DC A resistive load: (at times/min.) [AC ] V AC A inductive load: (at times/min., cos =.) [DC ] V DC A inductive load: (at times/min., L/R = ms) # 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.
Coil poles poles Nominal operating power mw mw Characteristics (at C F) Max. operating speed Initial insulation resistance* Initial breakdown voltage* Item Outline of performance [Socket for PC board/din terminal socket] Remarks * Measurement at same location as Initial breakdown voltage section * Detection current: ma * Excluding contact bounce time * Response time is the time after the coil voltage turns off until the time when a contact turns off. * Half-wave pulse of sine wave: ms; detection time: s * Half-wave pulse of sine wave: ms * Detection time: s * Refer to NOTES on page 9,. Usage, transport and storage conditions. ORDERING INFORMATION Between open contacts Between contact sets poles poles, Vrms for min.: -/9-, Vrms for min.: -/- -/- -/9- times/min. (at nominal voltage) Min., M at V DC, Vrms for min., Vrms for min.: -/- 9-/- -/-, Vrms for min.: -/- -/- -/9- -/9-, Vrms for min. Between contact and coil Operate time (at nominal voltage) Max. ms* Response time* (without diode) (at nominal voltage) Release time (without diode) (at nominal voltage) Shock resistance Vibration resistance Functional* Destructive Conditions for operation, transport and Ambient temp. storage* (Not freezing and condensing at low temperature) Humidity Max. ms* Max. ms* Functional* Min. m/s Destructive* Min., m/s to Hz at double amplitude of. mm to Hz at double amplitude of. mm C to + C F to + F to % R.H. Unit weight Approx. g Approx.. oz Approx. g Approx.. oz Max. carrying current Initial breakdown voltage Initial insulation resistance* A (Reduce by. A/ C for temperatures to C.) Between each terminal:, Vrms for min. (Detection current: ma) Min., M at V DC Ex. SF S Product name Slim type Contact arrangement : : : : : Operation indication Nil: Without LED indication L: Coil voltage DC,,,, V Note: Standard packing: Carton pcs. Case pcs. (Accessories: Carton pcs. Case pcs.) Please inquire about other coil voltages.
TYPES. Relay poles poles Contact arrangement Nominal voltage Without LED indication Part No. Part No. V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV V DC -DCV -L-DCV. Accessories Type No. of poles Part No. PC board sockets poles -PS poles -PS DIN terminal socket poles -SFD poles -SFD
COIL DATA (at C F) Contact arrangement poles poles Nominal voltage, V DC Pick-up voltage, V DC (max.) (initial) Drop-out voltage, V DC (min.) (initial) Nominal operating current, ma ( %) Coil resistance ( %) Nominal operating power, mw Note: The nominal operating current of the LED indication type increases approximately ma because of the light emitting diode display. Max. allowable voltage, V DC 9.... 9 9....,..,...,. Approx. 9.... 9 9....,..,...,. 9...... 9.......,...,. 9...... 9.... Approx....,...,. 9...... 9.......,...,.
DIMENSIONS mm inch CAD Data Data from our Web site. Download CAD. poles (, FormA/ Form B) CAD Data Max. Max.. PC board pattern (Bottom view) Max. Max... Max. Max..9.. -.. dia. (.) (.).9....9. Tolerance:.....9.... General tolerance:.. Schematic (Bottom view) 9 9 Standard ( FormA/ Form B) 9 ( FormA/ Form B) 9 ( FormA/ Form B) ( FormA/ Form B). poles (, FormA/ Form B, ) CAD Data Max. Max..99 PC board pattern (Bottom view) Max. Max.... -.. dia..9 (.) (.).. Max. Max..9....9......9 Tolerance:.... General tolerance:.. Schematic (Bottom view) 9 9 9 Standard () ( FormA/ Form B) () 9 9 9 () ( FormA/ Form B) ()
. PC board sockets ( poles) mm inch..99..9 PC board pattern (Bottom view) 9.9......9 -.. dia. (For M screw).... (.9) (.).9 -.. dia... Tolerance:.. Schematic (Bottom view) () () (.) (.)..9....9.... General tolerance:.. Standard 9 (When FormA/ Form B mounted) 9 (When FormA/ Form B mounted) 9 (When FormA/ Form B mounted) 9 (When FormA/ Form B mounted). PC board sockets ( poles)....9 PC board pattern (Bottom view) 9.9..9....9 -.. dia. (For M screw).... (.9) (.).9.. -.. dia. Tolerance:.. Schematic (Bottom view) () () (.) (.)..9....9.... General tolerance:.. Standard 9 9 9 (When mounted) (When FormA/ Form B mounted) (When mounted) 9 9 9 (When mounted) (When FormA/ Form B mounted) (When mounted)
. DIN terminal socket ( poles) mm inch R..9.. M. screw Mounting hole dimensions -M. or dia. hole -M. or. dia. hole.±..±..±. dia..±. dia...9.±..±. - hole... +.. +. *. *..9.9 Tolerance:.. Schematic (Top view) 9..9.... General tolerance:.. * Reference value (when using DIN rail ATA) Note: Round terminals cannot be used with DIN terminal sockets.. DIN terminal socket ( poles) R..9.. M. screw Mounting hole dimensions -M. or dia. hole -M. or. dia. hole.±..±..±. dia..±. dia...9.±..±.. +.. +. - hole.. Tolerance:.. *. *..9.9 Schematic (Top view)..9.. 9.. 9 General tolerance:.. * Reference value (when using DIN rail ATA) Note: Round terminals cannot be used with DIN terminal sockets.
REFERENCE DATA. Operate/response/release time Sample: -DCV () Quantity: n = (a contacts:, b contacts: ) No. of contacts 9 Time, ms Operate time Release time Response time. Coil temperature rise Sample: -DCV () Quantity: n = Measured portion: Inside the coil Ambient temperature: Room temperature ( C. F), C F, C F Temperature rise, C 9 Coil applied voltage, %V. Malfunctional shock Sample: -DCV () Quantity: n = X m/s Z X X' Energized condition Y Deenergized condition m/s A Room temperature m/s A Room temperature Z' A C A C A C m/s.a C Y' Y Y' Z' Z m/s m/s X'. Max, switching capacity ( type) Contact current, A DC resistive load.... AC resistive load. Contact voltage, V Other contact gaps when contacts are welded Sample: -DCV () The table below shows the state of the other contacts. In case of form NO contact weld the coil applied voltage is V. In case of form NC contact weld the coil applied voltage is nominal. State of other contacts - (NC) - (NC) - (NO) 9- (NO) - (NO) - (NO) - (NC) >. >. >. >. - (NC) >. >. >. >. Welded contact No. - (NO) >. >. 9- (NO) >. >. - (NO) >. >. - (NO) >. >. >.: contact gap is kept at min.. mm.inch Empty cells: either ON or OFF Note: Contact gaps are shown at the initial state. If the contact transfer is caused by load switching, it is necessary to check the actual loading. SAFETY STANDARDS Certification authority File No. UL/C-UL E9* A V AC, A V DC TÜV B A V AC (cos =.), A V DC (ms), AC: A V AC (cos =.), DC: A V DC (L/R ms) * CSA standard: Certified by C-UL
NOTES. Coil operating power Pure 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 %. However, check it with the actual circuit since the characteristics may be slightly different.. Coil connection When connecting coils, refer to the wiring diagram to prevent misoperation or malfunction.. Cleaning This relay is not sealed, therefore, immersion may cause failure. Be careful that flux does not overflow onto the PC board or penetrate inside the relay.. Soldering When using automatic soldering, the following conditions are recommended ) Preheating: C F, within s max (PC board solder surface). ) Soldering: C C F F, within s max.. Attach directly to the chassis or use a DIN rail. () When attaching directly to chassis Use a M. screw, spring washer, and hex nut. For the mounting pitch, refer to the dimensions. () When installing on a DIN rail Use a mm. inch wide DIN rail (DIN). Install and remove as shown in the figures below. <When installing> DIN rail <When removing> Push Pull Screwdriver ) Refer to the figure below for applicable wire-pressed terminals. (You cannot use round type wirepressed terminals.). mm max. mm min.. inch max.. inch min.. Other ) If the relay has been dropped, the appearance and characteristics should always be checked before use. ) The switching lifetime is defined under the standard test condition specified in the JIS* C -99 standard (temperature to C 9 to 9 F, humidity to %). Check this with the actual product as it is affected by the coil driving circuit, load type, activation frequency, activation phase, ambient conditions and other factors. Also, be especially careful with loads such as those listed below. () When used for AC load-operation and the operating phase is synchronous. Rocking and fusing can easily occur due to contact shifting. () During high frequency on/off operation with certain loads, arcing may occur at the contacts. This can cause fusion to Oxygen and Nitrogen gas in the air creating Nitric Acid (HNO) which can cause corrosion to the contacts. Please see the following countermeasure examples:.incorporate an arc-extinguishing circuit..lower the operating frequency.lower the ambient humidity ) For secure operations, nominal coil voltage should be applied. In addition, please note that pick-up and drop-out voltage will vary according to the ambient temperature and operating conditions. ) Heat, smoke, and/or fire may occur if the relay is used outside the allowable ranges for the coil ratings, contact ratings, operating cycle lifetime, and other specifications. Therefore, do not use the relay if these ratings are exceeded. Also, make sure that the relay is wired correctly. ) Incorrect wiring may cause false operation or generate heat or flames. ) Check the ambient conditions when storing or transporting the relays and devices containing the relays. Freezing or condensation may occur in the relay causing damage. Avoid exposing the relays to heavy loads, or strong shock and vibration.. Usage, transport and storage conditions ) Ambient temperature, humidity, and atmospheric pressure during usage, transport, and storage of the relay: () Temperature: to + C to + F (When the temperature is to C, reduce the A max. switching current by. A/ C.) () Humidity: to % RH (Avoid freezing and condensation.) The humidity range varies with the temperature. Use within the range indicated in the graph below. (Avoid freezing when used at temperatures lower than C F) - - Tolerance range Humidity, %R.H. (Avoid condensation when used at temperatures higher than C F) + + + Temperature, C F () Atmospheric pressure: to kpa Temperature and humidity range for usage, transport, and storage ) Condensation Condensation forms when there is a sudden change in temperature under high temperature and high humidity conditions. Condensation will cause deterioration of the relay insulation. ) Freezing Condensation or other moisture may freeze on the relay when the temperatures is lower than C F. This causes problems such as sticking of movable parts or operational time lags. ) At low temperature, low humidity environments, the plastic becomes brittle. Please note corrections.. Please connect DC coil types with LED and built-in diode correctly by verifying the coil polarity ( + and ). Connecting with reverse polarity will cause the LED not to light and damage the built-in diode due to its specification. For Cautions for Use, see Relay Technical Information. 9