MOS FET Relay GVM SSR for Switching Analog Signals, with an Insulation Value of. kvac between Input and Output Terminals Switching minute analog signals. Linear voltage and characteristics. Switching AC and. Ultra-highly sensitive and subminiature SSR assuring long life. Low ON-resistance. Low leakage between output terminals when they are open. Surface-mounting-type models are also available. Ordering Information Model Number Legend: GVM -. Voltage X: A load voltage of 0 V or 0 VAC (peak value) : A load voltage of 00 V or 00 VAC (peak value). Terminal None: PCB terminals F: Surface-mounting terminals Contact form Terminals voltage (peak value) Model SPST-NO PCB terminals 0 VAC GVM-X 00 VAC GVM- Surface-mounting terminals 0 VAC GVM-XF 00 VAC GVM-F
GVM GVM Specifications Absolute Maximum Ratings (Ta = C) Item GVM-X/-XF GVM-/-F Conditions Input LED forward 0 ma --- Repetitive peak LED forward Excessive peak LED forward LED reverse voltage V --- Output Output dielectric strength 0 to 0 V 00 to 00 V 0 ma Duty: 0% max.; pulse width: 00 ms max. 00 ma Duty: % max.; pulse width: 0. ms max. or AC peak value; AC connection (see note ) 0 to 0 V 0 to 00 V ; parallel connection (see note ) Continuous load 00 ma 0 ma AC connection (see note ) 0 ma 00 ma parallel connection (see note ) Peak load. A.0 A Pulse width: 00 ms max. per shot Output permissible loss mw mw/ C 0 C Dielectric strength between I/O terminals,00 VAC min Ambient temperature Operating: 0 C to 8 C Storage: C to C Max. soldering temperature and time 0 C s Characteristics (Ta = C) With no icing and condensation Item GVM-X/-XF GVM-/-F Conditions ON-resistance 0.7 Ω max. 0.0 Ω max. AC connection I F = 0 ma, I O = 00/0 ma (see note ) 0.8 Ω max.. Ω max. parallel connection I F = 0 ma, I 0 = 0/00 ma (see note ) Current leakage when the relay is open.0 µa V F = 0.8 V, V 0 = 0/00 V LED forward. V min.,.8 V max. I F = 0 ma Capacity between input and output terminals Approx..0 pf MHz Insulation resistance between input and output,000 MΩ min. 00 V Operate time. ms max. 0.9 ms max. I F = 0 ma (see note ) Release time 0. ms max. I F = 0 ma (see note ) Note:. AC Connection AC/. 0% 0% Input Output Operating time 0% 90% Release time. Parallel Connection
GVM GVM Engineering Data Reference Data Current vs. Ambient Temperature Characteristics Distribution of ON-resistance (AC Connection) GVM-X GVM- (A) GVM-X GVM-XF GVM- GVM-F Ambient temperature ( C) Distribution of ON-resistance ( Parallel Connection) GVM-X GVM- Operating Time vs. LED Forward Current Operating time (ms) GVM- GVM-X LED forward (ma)
GVM GVM Distribution of Operating Time GVM- GVM-X Distribution of Release Time GVM- GVM-X Output Voltage vs. Current Characteristics GVM-X Operating time (ms) Release time (µs) Voltage between output terminals (V) ON-resistance vs. Ambient Temperature GVM-X GVM- GVM- ON-resistance ( Ω ) ON-resistance ( Ω ) Current between output terminals (ma) Ambient temperature ( C) Ambient temperature ( C)
GVM GVM Dimensions Note: All units are in millimeters unless otherwise indicated. GVM-X GVM-. max. 9.9 max. Terminal Arrangement/ Internal Connections (Top View). PCB Dimensions (Bottom View). - 0.8 dia. hole (0.) Indicates the position of pin 7.. max..9 min. (0.) (0.) (0.) 0. min. 0. max..78 max... GVM-XF GVM-F 9.9 max. Terminal Arrangement/ Internal Connections (Top View) Actual Mounting Pad Dimensions (Recommended Value, Top View). max... Indicates the position of pin 9.±0. 7.±0. 8.8 0..8 0.8 0. 0 0. max..78 max... 0... Note: Mounting pad dimensions shown are a top view. Precautions Recommended Operating Conditions Use the GVM under the following conditions so that the relay will operate accurately. Item Min. Type Max. Operating LED forward ma 0 ma 0 ma Releasing LED forward 0 V --- 0.8 V
GVM GVM Typical Relay Driving Circuit Examples C-MOS CMOS V cc R V F Protection from Spike Voltage on the Output Terminals If a spike voltage exceeding the absolute maximum rated value is generated between the output terminals, insert a C-R snubber or clamping diode in parallel to the load as shown in the following circuit diagram to limit the spike voltage. VIN V OL/OH Spike Voltage Protection Circuit Example Transistor V cc 0 to 00 kω R V F V IN V OL/OH Use the following formula to obtain the LED limiting resistance value to assure that the relay operates accurately. R = V CC V OL V F (ON) to 0 ma Unused Terminals Terminal is connected to the internal circuit. Do not connect anything to terminal externally. Relay Holding Force for Automatic Mounting A relay must not be imposed with a force exceeding 00 gf (.9 N) in the A or B direction shown in the following illustration when the relay is mounted automatically, otherwise the characteristics of the relay may change. Use the following formula to obtain the LED forward voltage value to assure that the relay releases accurately. V F (OFF) = V CC V OH < 0.8 V A B Protection from Surge Voltage on the Input Terminals If any reversed surge voltage is imposed on the input terminals, insert a diode in parallel to the input terminals as shown in the following circuit diagram and do not impose a reversed voltage value of V or more. Surge Voltage Protection Circuit Example Connection Do not short-circuit the input and output terminals while the relay is operating or the relay may malfunction.
GVM GVM AC Connection or AC or Single Connection Parallel Connection Destruction of MOS FET by Static Electricity Handle the relay with utmost care in order to avoid the destruction of the relay by static electricity. ALL DIMENSIONS SHOWN ARE IN MILLIMETERS. To convert millimeters into inches, multiply by 0.097. To convert grams into ounces, multiply by 0.07. Cat. No. J90-E- OMRON Corporation Relay Division 8th Fl., Crystal Tower Bldg. --7, Shiromi, Chuo-ku, Osaka 0 Japan Phone: 0-99- Fax: 0-99- In the interest of product improvement, specifications are subject to change without notice. Printed in Japan 079-M (09) a 7