RU13728U1 - DEVICE FOR CONTROL OF INSULATION AND PROTECTION OF MOBILE ELECTRIC INSTALLATIONS - Google Patents

Description

The alleged invention relates to instrumentation and can be used to protect a person from electric shock and to monitor the state of insulation of electrical installations on pneumatic wheels, mainly city trolley buses,

operated in networks with both insulated and grounded negative poles.

A device for measuring leakage currents and protective shutdown of a trolley bus 1.

The main elements of the device are a measuring unit and a sensitive element, made in the form of a leakage current indicator. In addition, the device includes a block for providing dead-time pauses, a program control circuit, switched switches and a trip control circuit. The measurement unit is connected via current switches to the power circuits of the trolley bus, and through a model resistor to its housing. To measure leakage currents, a current-free pause mode is created with the trolleybus disconnected from the supply network for the duration of the measurements. In this case, the electronic components of the device are powered from an operational source connected to the on-board battery.

A significant disadvantage of the known device is the indirect measurement of leakage current. Its value is determined depending on the measured value of the insulation resistance of the trolleybus housing, which introduces significant errors in the indication of the leakage current indicator. At the same time, a large overload and shutdown of the trolley bus is allowed at permissible leakage currents.

The device is fire hazard, since it is connected directly to the 600V power network and significantly increases the energy consumption of the trolley bus due to the need to create dead-time pauses in the power network for making measurements.

A device for monitoring the insulation and protection of mobile electrical installations, which contains similar to the claimed nonequilibrium bridge, in the diagonal of which is included a sensing element. One pair of shoulders of the bridge is the insulation resistance of the poles of the power supply network of the installation relative to the housing, the second insulation resistance of the poles of the network relative to the ground 2, chapter 3.

This technical solution is the closest to the claimed in terms of essential features and is selected as a prototype.

The sensitive element of the prototype is a low-current relay that responds to leakage currents that exceed the permissible value. At the same time, a warning light or sound signal is given to the trolley bus driver.

The device operates as follows: if the insulation of the trolley bus is damaged, the leakage current passing through the diagonal of the bridge increases. When its value reaches ZmA, the relay contacts close and an alarm occurs. After the alarm is triggered, the trolley bus driver must independently decide on the possibility of further operation of the electrical installation.

The main disadvantages of the prototype are the inability to differentially respond to different values of leakage currents, to automatically turn off the trolley when currents appear that are dangerous to human life, and turn off the device itself to avoid damage when the contact wire is shorted to the electrical installation case.

The use of a low-current relay as a sensitive element with low gain at the contacts and their inevitable vibration during movement causes false signals, which can lead to unjustified shutdowns of the electrical installation by the driver. In addition, the prototype does not provide for the possibility of control checks of the insulation status on the route and to control the presence of contact between the movable electrodes and the road surface.

The basis of the invention is the task of improving the device for monitoring insulation and protecting mobile electrical installations through the use of a new sensor circuit with galvanic isolation of the measurement circuits from the supply voltage circuit of electronic components.

The problem is solved in that in a device for monitoring the insulation and protection of mobile electrical installations, containing a nonequilibrium bridge, one pair of shoulders of which are the insulation resistance of the poles of the power supply network of the electrical installation relative to the housing, the second is the insulation resistance of the network poles relative to the ground and a sensitive element included in the diagonal of the bridge , according to the invention, a galvanic isolation unit for the measurement circuits from the supply voltage circuit of the electronic components is introduced, the sensitive element is made a multi-stage voltage divider outputs are connected to respective inputs of the comparator. At the same time, the galvanic isolation unit of the measurement circuits from the supply voltage circuit of the electronic components contains a transformer converter

DC current into an alternating current, the output of which is connected to the input of the rectifier, combined by its output with the input of the blocking filter, the output of which is connected to the input of the stabilizer. In addition, the device is equipped with a high-pass filter, the output of which is connected to the input of the voltage divider, and a DC amplifier connected between the voltage divider and the comparison unit. The device also comprises a process signaling unit and a numerical indication unit connected in series, wherein the input of the process signaling unit is combined with the first output of the comparison unit; an alarm block and a power supply shutdown unit for electrical installations, the inputs of which are connected to the second output of the comparison unit, and a device shutdown unit connected by its input to the third output of the comparison unit.

The use of a voltage divider as part of the sensitive element of the alleged invention makes it possible to obtain several independent voltage values proportional to the leakage currents.

Each value corresponds to a certain current level characterizing the state of isolation of the trolley bus. The obtained values are sent to the comparison unit, where they are processed and compared with the reference values. Depending on the result of the comparison, a decision is made about the possibility of further operation of the electrical installation. If the insulation damage is insignificant, and the leakage current does not pose a danger to human life, the process alarm unit is activated, informing the trolley bus driver about the deterioration of the insulation condition. This condition may be acceptable, for example, if it is caused by short-term increases in the supply voltage.

A further increase in the leakage current triggers the alarm unit and ensures that the trolley bus is automatically turned off.

In case of significant damage to the insulation, a short circuit inside the device itself or a short circuit of one of the poles of the network to the electrical installation enclosure, information from the comparison unit enters the device’s shutdown unit, which turns it off.

The presence of galvanic isolation of the measurement circuits from the supply voltage circuit of electronic components eliminates the influence of leakage currents of the on-board 24V system on the value of the measured currents and eliminates errors in the operation of the comparison unit, DC amplifier, alarm and shutdown units.

The use of a high-pass filter eliminates the possibility of false positives due to the presence of high-frequency interference in the DC network; DC amplifier provides accuracy and stability of the device, contributes to the expansion of its functionality.

Figure 1 presents the connection diagram of the insulation monitoring device, figure 2 is an equivalent circuit.

The device is connected between the body of the trolleybus K and the movable electrodes / E and E2. The use of movable electrodes allows continuous monitoring of leakage currents between the electrical installation casing and the road surface D.P., as well as the presence of contact between the moving electrodes and the road surface in the control sections of K.U. R and Rnep are the tire resistance and the transition resistance between the road surface and the ground, respectively.

Insulation resistance of the poles of the power supply network of the electrical installation relative to the housing. R out.k. and insulation resistance of the poles of the network relative to the ground R%, Rc form the shoulders of the nonequilibrium bridge, the diagonal of which includes an element CH.E. Possible grounding of the negative pole of the network is indicated by switch P.

Control plot K.U. Designed for control checks of the state of isolation of the trolleybus on the route.

Functional diagram of a specific embodiment of the claimed device is shown in Fig.Z. The control and protection device for mobile electrical installations contains a high-pass filter 1, the inputs of which are connected to the movable electrodes E and Et and the trolleybus housing K. The output of the filter 1 is connected to the input of the voltage divider 2, connected through the DC amplifier 3 to the inputs of the comparison unit 4. The first output of the block Comparison 4 is combined with the input of the process signaling unit 5, the output of which is connected to the block of numerical indication 6, intended to fix the number of process signaling operations. The second output of the comparison unit 4 is connected to the inputs of the alarm unit 7 and the power supply unit of the electrical installation 8. The third output of the comparison unit 4 is connected to the input of the device’s power-off unit 9. The power supply circuits of the electronic components are connected to the galvanic isolation unit 10 of the measurement circuits from the supply voltage circuit.

The device also has a button for checking the measurement scheme and alarm. There is no button for checking the galvanic connection of the moving electrodes with the pavement 12.

Functional diagram of the galvanic isolation unit 10 is made in figure 4. Block 10 consists of a transformer DC / AC converter 13, the output of which is connected to the input of the rectifier 14. The output of the rectifier 14 is combined with the input of the blocking filter 15, which is connected to the input of the stabilizer 16. From the stabilizer 16, the supply voltage is supplied to the electronic components of the insulation control device .

A high-pass filter is an RC link containing a non-polar capacitor, for example, type K76P and a wire resistor that can withstand a load of 25-50W. The voltage divider is built on any widespread resistors, for example, such as MLT. The DC amplifier is made in the form of an emitter follower on transistors of "" -conductivity, for example, type KT315, KT3102. The comparator uses the K554CAZ type comparator. Technological and emergency alarms are based on LEDs of the type UI1TMO-43. The block of numerical indication consists of a binary-decimal counter of the K155 series, a decoder of the KR5144D1 type and a seven-segment indicator of the LSIPMO-43 type. The power supply unit of the electrical installation is made using a transistor optocoupler type AOT110 and powerful transistor switches, switching electromagnets. As keys, transistors of the KT827 type can be used. The device shutdown unit can be implemented using a relay with a switching current of at least 10 ohms. The galvanic isolation block includes a converter made on; 7i / 7-transistors, for example, type KT814, a transformer made on the basis of ferrite cups, a rectifier based on any high-frequency diodes with direct current from 50 mA. The blocking filter - capacitive based on a capacitor type K50-35; the stabilizer is built on a standard zener diode with a stabilization voltage of Yun-12V and a stabilization current of at least 15mA.

The movable electrodes are made in the form of chains of wear-resistant hardened steel, and the control section is a grounded metal sheet.

A device for monitoring insulation and protecting mobile electrical installations works as follows; The potential difference between the trolleybus housing and the movable electrodes is fed to the input of a high-pass filter 1, which protects the device from false positives under the influence of high-frequency components and short-term pulses in a DC network of a supply voltage of 600V. The potential difference from the output of the filter 1 is fed to the voltage divider 2. The voltage divider 2 generates voltage values proportional to the leakage currents. Next, the signals are fed to a current amplifier 3, amplified and fed to a comparison unit 4, where the operation of comparing the acquired knowledge with reference values is performed. Visually, the values of the leakage currents can be controlled using the current indicator connected to the amplifier 3 or the comparison unit 4. When the leakage current reaches the ZmA value, the process alarm unit 5 is triggered, a light-sound signal and an impulse are sent to the numeric display unit 6. At the value of the leakage current 15 mA, the alarm unit 7 and the power-off unit of the trolley bus 8 are triggered. A further increase in current causes the device to turn off the unit 9.

The device was tested on a trolleybus type UMZ-T1 in a trolleybus fleet.

Changes in the insulation resistance of the trolleybus were made by connecting additional Kdop resistances. between the positive pole of the network and the chassis. The 600V power supply was made with a grounded negative pole. When connecting the Kdop 220kOhm, the leakage current between the case and the ground was 3, Ohm, while the red leakage lamp lit up and the audible alarm of the process alarm unit worked. A similar pattern was observed when connecting Kdop.197kOhm and a leakage current of 3.4 mA.

The connection of + 600V voltage to the trolley bus case caused the lamps to leak, leakage, an alarm signal from the alarm unit and automatic disconnection of the device from the 600V network. In this case, the leakage current was more than 15mA.

The device can be used in stationary conditions of a trolleybus fleet to control leakage currents. At the same time, it is not necessary to permanently connect it to the trolley bus body, and stationary grounding can be used instead of moving electrodes.

The test results showed the operability of the device and reliability in operation.

Sources of information:

1. Patent of the Russian Federation No. 2017300, publ. 07/30/94, MKI NO2PZ / 16.

2.D.K. Tomlyanovich, V.I. Chubukov. Protection of power supply devices for trolley buses. Moscow, Transport, 1980.

Claims (7)

1. A device for monitoring the insulation and protection of mobile electrical installations, comprising a nonequilibrium bridge, one pair of shoulders of which is the insulation resistance of the poles of the power supply network of the electrical system relative to the housing, the second is the insulation resistance of the network poles relative to the ground, and a sensitive element included in the diagonal of the bridge, characterized in that it is equipped with a galvanic isolation unit for the measurement circuits from the supply voltage circuit of electronic components, and the sensitive element includes a multi-stage divider conjugation, the outputs of which are connected to respective inputs of the comparator.  2. The device according to claim 1, characterized in that the galvanic isolation unit of the measurement circuits from the supply voltage circuit of the electronic components contains a transformer DC / AC converter, the output of which is connected to the input of the rectifier, combined by its output with the input of the blocking filter, the output of which is connected to stabilizer input.  3. The device according to claim 1, characterized in that it is equipped with a high-pass filter, the output of which is connected to the input of the voltage divider.  4. The device according to claim 1, characterized in that a DC amplifier is connected between the voltage divider and the comparison unit.  5. The device according to claim 1, characterized in that a process signaling unit and a numerical display unit are connected in series thereto, while the input of the process signaling unit is combined with the first output of the comparison unit.  6. The device according to claim 1, characterized in that an alarm unit and a power supply disconnecting unit of the electrical installation are introduced into it, the inputs of which are connected to the second output of the comparison unit. 7. The device according to claim 1, characterized in that the input of the device shutdown unit is connected to the third output of the comparison unit.