ZSJ series DC power-off delay relayDetailed product description：

ZSJ series DC power-off delay relay uses:

The ZSJ series static DC power-off delay relay is used in DC operated relay protection and automation circuits as a time element for instantaneous action after DC power on and delayed return after power-off.

ZSJ series DC power-off delay relay model name:

There are three types of ZSJ series relays according to their structure:
The ZSJ-1 relay adopts an upward protruding fixed structure for the housing structure, and its external dimensions and installation hole dimensions are shown in Figure 1 of the general structural system;  
The ZSJ-2 relay adopts a protruding plug-in structure for the housing structure, and its external dimensions and installation hole dimensions are shown in Figure 3 of the general structural system;  
The ZSJ-3 relay adopts a Xuji embedded plug-in structure for its housing structure, and its external dimensions and installation hole dimensions are shown in Figure 7 of the general structural system.

Working Principle:
The principle block diagram of the relay is shown in Figure 1. As shown in the figure, the relay consists of a crystal oscillator, a frequency divider, a counter, a setting switch, a driving circuit, and a power supply circuit. When the rated voltage is applied to the relay, the internal instantaneous relay and two delay execution relays perform instantaneous actions, switch contacts, and disconnect the power circuit from the timing circuit. Therefore, the timing circuit is in a power-off state to improve the anti-interference performance of the relay. When the input voltage significantly decreases or completely disappears, the instantaneous relay returns instantly. (Two delay execution relays are still in action), and the contacts also instantly return, connecting the energy storage power supply to the timing circuit. The crystal oscillates to generate clock pulses, which are divided into 10ms. The counter counts the timing pulses, and when the counted number of pulses matches the preset value of the setting switch, it drives the execution relay to return, completing the function of power-off delay return.



Usage:
The relay panel diagram is shown in Figure 2. The upper three digit switch in the diagram sets the delay return time t1 of relay K1, and the lower three digit switch sets the delay return time t2 of relay K2. Multiplying the three digit switch by 0.01S is the time setting value. For example, if the three digit setting is 580, the time setting value is 580 × 0.01S=5.8S. The setting values of t1 and t2 can be equal or not equal.

Main technical parameters:
6.1 Rated voltage: DC 220V, 110V, 48V, 24V.
6.2 Ensure that the voltage required for reliable energizing of relay contacts is not greater than 70% of the rated voltage.
6.3 Ensure that the reliable power-off return voltage of the relay is not less than 10% of the rated voltage.
6.4 The delay error of relay power-off delay return under rated voltage shall not exceed 0.1% of the setting value+10ms within the setting range
6.5 The variation of relay power-off delay under rated voltage shall not exceed 0.1% of the rated value+10ms. Variation refers to the difference between the maximum and minimum values of the relay measured five times at the same time setting point.
6.6 The two delayed return contacts can be independently set, with a time setting range of 0.02-9.99s, and the delay setting values can be different or the same.
6.7 The power consumed by the relay at rated voltage shall not exceed 4W.
6.8 Relays are allowed to withstand 110% of rated voltage for a long time.
The contact breaking capacity of the 6.9 relay in a DC inductive circuit with a time constant T=5 ± 0.75ms and a voltage not exceeding 250V and a current not exceeding 1A is 30W.
6.10 The effective voltage between each circuit of the relay and the exposed non charged metal parts should be able to withstand 2KV, and the input circuit and contacts should be able to withstand 1kV, 50HZ AC voltage. After a 1-minute experiment, there should be no insulation breakdown or flashover phenomenon.
6.11 The relay can reliably operate within the temperature range of -10 ℃ to 40 ℃.
6.12 Relay has a mechanical lifespan of 10 ^ 5 times and an electrical lifespan of 10 ^ 4 times.
6.13 Relay weight: approximately 0.5kg.

Wiring diagram behind the relay:
The wiring terminal diagram of the relay is shown in Figure 3. The contacts in the diagram are the state after the relay loses power. When the rated DC voltage is applied, the instantaneous contact K3, the contact K1 with a delay time of t1, and the contact K2 with a delay time of t2 all act simultaneously. At this time, the contact state is opposite to that shown in Figure 3. When the applied voltage suddenly loses power (voltage), the instantaneous contact K3 immediately returns, and the delayed contact K1 returns after a delay of t1 after power failure. Similarly, the delayed contact K2 returns after a delay of t2 after power failure. The contact state after return is shown in Figure 3.



Ordering instructions:
7.1 Relay model and name;
7.2 Rated voltage;
7.3 Order quantity.

ZSJ series DC power-off delay relay（No image available）