SU1633143A1 - Method for preventing hazardous sparking in multichannel system - Google Patents

Abstract

The invention relates to electrical engineering, in particular to multichannel systems with parallel connection of channels with different levels of supply voltage, having a common point. The purpose of the invention is to increase the intrinsically safe power of the multichannel system. The source 1 with a lower voltage and the source 2 - with a higher voltage are connected to the common wire by one terminal. A voltage control unit 3 is connected between the common wire and the second output of source 2. Parallel to source 1, a disconnecting unit 4 is connected. Sources 1 and 2 are connected to load 5 via sparking contacts 6. When the voltage goes above the threshold value of block 3, a signal is sent to disconnect unit 4. At this, the voltage on the spark-forming contacts is limited by the voltage low voltage channel. 2 Il. Yo

Description

ABOUT

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The invention relates to electrical engineering, in particular to multichannel systems with parallel connection of channels with different levels of supply voltage having a common point.

The purpose of the invention is to increase the spark-safe power of a multi-channel system.

Figure 1 shows a two-channel system; 2, a multichannel system.

When commutating the common wire, the discharge voltage increases. When the discharge voltage exceeds the channel voltage with a lower level, a signal is emitted that acts on the device shutting off the channel with a higher voltage level. Consequently, the discharge voltage is limited by the voltage of the channel with a low voltage level. Limiting the maximum voltage to a discharge allows an increase in the intrinsically safe power of the multichannel system. It is not necessary to disconnect all channels with a higher voltage. To ensure the intrinsic safety, it is sufficient to disconnect only those channels, the connection of one of which together with the channel on which the voltage is controlled, leads to a violation of intrinsic safety when switching in the common wire. Channels that are connected to the one on which the voltage is monitored, do not lead to intrinsic safety violation, can be not disconnected.

The system consists of a high voltage source 1, a low voltage source 2, a voltage control unit 3, a disconnecting unit A, a load 5, and spark-forming contacts 6. Sources 1 and 2 have a common point that is connected by common wire to the load 5. The second poles of the power supply sources 1 and 2 are connected to each load 5. Parallel to the low-voltage source 2, the voltage control unit 3 is connected, and the power source 1 is the disconnecting unit 4. The voltage control unit 3 is connected to the disconnecting unit 4.

The tripping voltage of the block, 3 voltage control is chosen slightly higher than the voltage of channel 2, but lower than the voltage of channel 1, i.e. above the voltage of the channel on which the voltage is monitored (to eliminate false alarms), but lower than the voltage of the higher channel).

The system works as follows.

The load 5 is powered from sources 2 and 1. When the voltage on the spark-forming contacts 6 reaches the threshold value of the voltage of the control unit 3, a signal is given to the tripping unit 4.

In this case, the power source 1 is short-circuited, and consequently, its energy is not supplied to the spark-forming contacts 6. The discharge stops. Reducing the maximum discharge voltage allows the system to increase the intrinsically safe power.

An example implementation of the method in a multi-channel intrinsically safe system is shown in figure 2. In this device, the voltage control unit contains a series of parallel-connected circuits consisting of a separating diode and a zener diode and connected to each channel, except for the channel with the maximum voltage. The stabilization voltage of each of the zener diodes is chosen greater than the voltage of the channel to which it is connected, but less than the voltage of the next channel with a higher voltage. The common point of these chains is connected to the input of the disconnecting device. The disconnecting device contains a thyristor, the anode of which is connected through dividing diodes to all channels except the channel with the minimum voltage. When shorting any two channels, the zener diode opens with a lower stabilization voltage, and the current flowing through it opens the thyristor. When the thyristor is opened, all channels, except the channel with the minimum voltage, are short-circuited.

Experimental studies of the method have shown that with a voltage of 12 and 24 V channels, the total intrinsically safe power reaches 20 watts.

Claims (1)

Invention Formula The method of ensuring the intrinsic safety of a multichannel system, which consists in comparing the measured output voltage in each channel with a reference signal and when the output voltage in the channel exceeds the reference signal, giving a signal to turn off the channel, in order to increase the intrinsically safe power a multichannel system, a signal to disconnect a channel with a large measured voltage is applied if in other channels with a lower voltage the measured voltage is greater than the specified one.