RU2538036C2 - Measuring instrument switch to test quality of power supply circuits in electrical systems during their assembly - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is related to the area of process systems and may be used to test power supply circuits of an electrical system. The invention concept is as follows: the device contains three input circuits (for connection to supply buses and the system frame) and four output circuits to connect measuring instruments (ohmmeter and megohmmeter), a switch for three positions and four directions, a diode and two low-ohmic resistors R1 and R2 with different rated values of resistance and essentially less equivalent resistance of Rh load to the supply buses (R1≠2)<Rh and electrical couplings between the device components, which ensure safe testing of power supply circuits of the electrical system in process of its assembly.

EFFECT: increase in production rate, exclusion of effect of interference and errors of the measuring instrument connection on reliability of the assembled electrical system, provision of reliable and authentic control and error or defect detection in the assembled electrical system, including fault-to-frame identification for any power supply buses of the assembled electrical system.

2 cl, 1 dwg

Description

The switch of the measuring device for monitoring the quality of the power circuits of the electrical systems of the product during their assembly (hereinafter referred to as the switch of the measuring device) refers to the technological equipment and can be used in the assembly and technological preparation of the electrical systems of various products before their first inclusion for tuning or electrical testing.

Any electrical system of the product (and the product as a whole) is subjected to mandatory control operations during the assembly process, which include measuring the resistance between the power rails and the insulation resistance of each power rail with respect to the body of the product with both measuring device polarities (ohmmeter and megger) and, based on the totality of measurement results , - a subsequent assessment of the suitability for continuing the assembly or for its first inclusion to check the operability (functioning). Six measurements are foreseen taking into account measurements when the polarity of the measuring voltage is changed. Such checks are repeated each time after connecting another cable or device to the electrical system of the product. During the assembly of any electrical system of the product, dozens of such measurements are required. This delays the assembly process of the electrical system and the product as a whole.

A close analogue of the proposed switch of the measuring device can be performed by analogy with the switch from [1]. Connecting the measuring device using such a switch can be performed alternately to de-energized power buses and to the body of the product as the electrical system of the product is assembled, while monitoring the load resistance between the power buses, the absence of breakage of the power bus or short circuit between them, as well as the resistance of galvanic connections between each of the power rails and the product case at both polarities of the measuring voltage.

When using measuring instruments in the ohmmeter and megger modes in the process of quality control of the power circuits of the product’s electrical systems during assembly, the capacitors of the product’s electrical system associated with the power rails and the product’s case are recharged with a change in voltage polarity, which is unacceptable for electrolytic capacitors, in in particular for capacitors installed between power rails. In addition, the process of measuring the insulation resistance between the power rails and the body of the product due to the slow recharging of the mentioned capacitors at low measuring currents takes a relatively long time.

Moreover, when checking the resistance between power buses using a low-voltage ohmmeter and checking the insulation resistance of the power circuits relative to the product case using a high-voltage megohmmeter, in the event of an error when they are connected, the probability of damage to the low-voltage component base of the product increases significantly.

These circumstances make up the complex of disadvantages of such a device when using it.

As a prototype for execution in relation to the proposed device, you can take the switch circuit according to [2], containing three input circuits, two output circuits and a multi-position switch.

However, the switch of the measuring device, made on the basis of the prototype circuit, has all of the above disadvantages. In addition, in an electrical system with long power circuits and long measuring circuits, during the assembly process, interference always occurs due to electrostatic effects or due to spurious connections of the power circuits of measuring instruments with industrial networks, which can affect the measurement results, the quality of electrolytic capacitors, connected between the power buses of the devices of the assembled electrical system, and to another, especially low-voltage, elemental base, which reduces the reliability of the equipment, ovliyat on the life of the product as a whole and even lead to failure.

The objective of the invention is to reduce the number of control measurements, and, as a result, increase the control performance, eliminate the influence of interference on the connection circuits of the measuring device on the reliability of the assembled electrical system of the product, as well as increase the objectivity and reliability of the control, identify errors and defects in the assembled electrical system of the product.

This problem is solved by the fact that in the switchboard of measuring instruments for monitoring the quality of the power supply circuits of electrical systems of the product during assembly, it contains three input circuits, two output circuits, a switch, two low-resistance resistors R1 and R2, a diode, a third and fourth output circuit are introduced, with this switch is applied in four directions with contact groups in three positions, while the first input circuit is designed to connect to the product’s “plus” power bus and is connected to the movable contact of the first contact group the second input circuit is designed to connect to the power bus "minus" of the product and is connected to the movable contact of the second contact group of the switch, the third input circuit is designed to connect to the housing of the product and is connected to the movable contact of the third contact group of the switch, the first output circuit is designed to connect the first output of the first measuring device (ohmmeter) and is connected to the middle fixed contact of the first contact group of the switch, the second output circuit is designed for I connect the second terminal of the first measuring device (ohmmeter) and connected to the middle fixed contact of the second contact group, the first and third fixed contacts of the first contact group are connected to one terminal of the first low-resistance resistor R1, the first and third fixed contacts of the second contact group are connected to one terminal of the second low-resistance resistor R2, other terminals of said low-resistance resistors are connected to the movable contact of the fourth contact group, the first fixed contact of the fourth contact group is connected to the third fixed contact of the third contact group and to the third output circuit, designed to connect the first output of the second measuring device (megger), the first fixed contact of the third contact group is connected to the third fixed contact of the fourth contact group and to the fourth output circuit, intended for connecting the second output of the second measuring device (megger), the cathode of the diode is connected to the first output circuit, the anode of the diode is connected to the second output circuit.

In addition, low-resistance resistors R1 and R2 are used with different resistance ratings and each of them is less than the equivalent load resistance R _N on the power bus of the product’s electrical system (R1 ≠ R2) <R _N. In this case, the resistance of one of the resistors can be reduced to zero.

The technical result of the proposed invention is achieved when it is used due to the fact that, firstly, for an objective control of the state of the power circuits of the assembled electrical system of the product, only three operations are required instead of six, which provides increased productivity. Secondly, in the initial state of the relay, the measuring device (ohmmeter) is connected to the power buses of the assembled electrical system of the product and monitors the resistance between them during the connection of cables and devices to the assembled electrical system of the product, which makes it possible to detect a defect at the time of its manifestation and does not allow accumulate static electricity on the terminals of the measuring device. Thirdly, the insulation resistance of the supply lines relative to the body of the product is checked for compliance with the design documentation when the supply lines are connected to each other through low-impedance resistances with one and the other polarity connecting the measuring voltage to the supply lines relative to the unit, which eliminates the appearance of voltage of any polarity between the buses power during this check. In addition, maintaining the reliability of the assembled electrical system provides a diode that protects the supply bus from contact with them direct, alternating or pulsed voltage containing a component of reverse polarity. This diode does not affect the results of other measurements and at the same time allows you to check the correctness of the wiring of the power cable of the electrical system before connecting devices to them.

In addition, the measuring device (ohmmeter), being connected to the power circuits of the assembled electrical system of the product through this switch during measurements, repeatedly and accurately switches between the same power circuits and the body of the product using the same switch. This eliminates any error in its connection, which can have a harmful effect on the elements of the assembled electrical system of the product, at the same time, the measurements themselves are reliable, are objective in nature and allow you to identify any defect in the power circuits during the assembly of the electrical system of the product - short circuit, open circuit, unacceptable communication with the body of the product, deviation from the requirements of technical documentation. Analysis of the result of measuring the short-circuit resistance of any power bus to the product body will unambiguously tell which of the power buses is closed to the product body.

Figure 1 shows a diagram of the proposed switch measuring instruments for controlling the quality of power circuits of electrical systems of the product during assembly.

In figure 1, the following notation:

XP1, XP2 and XP3-input circuits of the device, provided, if necessary, with connectors for connecting to power circuits and to the body of the assembled electrical system of the product;

XS1, XS2 and XS3, XS4 - device output circuits or conditional connectors (sockets) for connecting measuring instruments - an ohmmeter and a megger;

SA - four-way switch SA.1, SA.2, SA.3 and SA.4 and three positions,

1, 2, 3 - fixed contacts of each direction SA.1, SA.2, SA.3 and SA.4 switch SA,

2 ′ - movable contacts of the SA switch of each direction,

R1, R2 - low resistance resistors,

VD - diode.

The device is made as follows.

The first input circuit XP1 is designed to connect to the “plus” power bus of the product and is connected to the movable contact 2 ′ of the first contact group SA.1, the second input circuit XP2 is designed to connect to the “minus” power bus of the product and is connected to the movable contact 2 ′ of the second contact group SA.2, the third input circuit ХРЗ is designed to connect to the product body and is connected to the movable contact 2 ′ of the third contact group SA.3, the first output circuit XS1 is designed to connect the first output of the first measuring device and with it is connected to the fixed contact 2 ′ of the first contact group SA.1, the second output circuit XS2 is used to connect the second output of the first measuring device and is connected to the fixed contact 2 ′ of the second contact group, the first 1 and third 3 fixed contacts of the first contact group SA.1 are connected with one terminal of the first low-resistance resistor R1, the first 1 and third 3 fixed contacts of the second contact group SA.2 are connected to one terminal of the second low-resistance resistor R2, the other terminals of the low-resistance resistors R1 and R2 are connected to the other contact 2 ′ of the fourth contact group SA.4, the first fixed contact 1 of the fourth contact group SA.4 and the third fixed contact 3 of the third contact group SA.3 are connected to the third output circuit XS3, designed to connect the first output of the second measuring device, the third fixed pin 3 of the fourth contact group SA.4 and the first fixed contact 1 of the third contact group SA.3 are connected to the fourth output circuit XS4, designed to connect the second output of the second measuring device, the cathode of the diode VD is connected to the first output circuit, the anode of the VD diode is connected to the second output circuit.

In addition, low-resistance resistors R1 and R2 can be used with different resistance ratings and each of them is less than the equivalent load resistance Rн on the supply busbars of the product’s electrical system (R1 ≠ R2) <Rн. In this case, the resistance of one of the resistors R1 or R2 can be reduced to zero.

When preparing the device for work with the electrical system of the product during its assembly, the first input circuit XP1 of the device is connected to the plus bus of the assembled electrical system of the product, the second input circuit XP2 is connected to the negative bus, the third input circuit XP3 to the body of the product (not shown in the diagram of FIG. 1). The input of the first measuring device (ohmmeter) having a positive potential in the resistance measurement mode is connected to the first output circuit XS1 of the device, and the second input of this device having a negative potential is connected to the second output circuit XS2. The inputs of the second measuring device (megger) are connected to the third XS3 and the fourth XS4 output circuits. This is the initial state of the equipment, ready to conduct control measurements in the process of assembling the electrical system of the product and preparing it for the first inclusion.

Depending on the features of the product’s electrical system being assembled, instead of an ohmmeter, a universal measuring device can be used that can (if necessary) measure capacitance of capacitors connected to power buses during the assembly of the product’s electrical system, or complex resistance between power circuits, etc.

During measurements, an ohmmeter is switched with one switch to check the resistance between the power buses and a megohmmeter to check the insulation resistance between the combined power buses and the product body.

The proposed device works, being connected to a product assembled, but not connected to a power source, together with a low-voltage (1-5) V ohmmeter and high-voltage (up to 100 V and more) megger, as follows.

In the initial (average) state of the switch SA according to Fig. 1, an ohmmeter connected to the power buses of the assembled electrical system of the product through normally closed contacts of 2′-2 contact groups SA.1 and SA.2 will show the current value of the load resistance between the power buses, for example a cliff. If the value of this resistance during the assembly of the electrical system of the product is within acceptable limits for this product at this stage of assembly, you can check the insulation resistance of the power bus relative to the housing of the product. If not, then you need to find and eliminate the cause of the discrepancy.

To check the insulation resistance between the power supply busbars of the product’s electrical system (together with the elements connected between these power buses, for example, executive bodies, secondary power supplies, etc.) and the product housing for compliance with the requirements of the design documentation, it is enough to install the SA switch alternately in the extreme provisions. At the same time, in one position of the switch SA (the upper one in Fig. 1), through the NC contacts 2 ′ and 1 of the contact groups SA.1 and SA.2, the power buses are interconnected via two series-connected low-resistance resistors R1 and R2, the midpoint of these resistors through pins 2 ′ and 1 of the SA.4 pin group are connected to the positive terminal of the megohmmeter connected to the third output circuit XS3 of the device, and the negative pin of the megohmmeter connected to the fourth output circuit XS4 of the device is connected to the body of the product through the pins 2 ′ and 1 of the group ontacts SA.3. In this position of the SA switch, the insulation resistance between the combined power rails and the product casing is checked at a positive potential of the measuring voltage on the power rails of the product’s electrical system.

When the switch SA is set to another extreme position (lower in FIG. 1), by analogy, the insulation resistance between the combined power rails and the product casing is checked at a negative potential of the measuring voltage on the power rails.

If the insulation resistance between the case and the power rails is normal, you can proceed to connect the next cable or device to the system being assembled, after which the measurements are repeated. And so on, until the completion of the assembly of the electrical system of the product.

If the insulation resistance between the power rails and the product casing is not normal, analysis of the remark and elimination of its cause is required. After eliminating the reason for the remark, the assembly of the electrical system of the product can be continued.

A short circuit of any power bus of the assembled electrical system of the product to the product body can be identified by the value of the measured resistance between the product body and the common resistance point R1 and R2. Moreover, in the event of a short circuit in any power bus to the product body, the megohmmeter connected to the output circuits of XS3 and XS4 should be replaced with an ohmmeter. For example, we take R1 = 10 Ohms and R2 = 20 Ohms, although the values of these resistances may be different, but should be significantly less than the equivalent load resistance Rn of devices connected to the power buses of the assembled electrical system of the product. In this case, when the minus bus is shorted to the chassis of the product, the ohmmeter connected to the third and fourth output circuits instead of the megger will show a resistance of not more than 20 Ohms, and if the plus circuit is shorted to the plus chassis, not more than 10 Ohms. An analysis of the measurement result will definitely tell which of the power buses is closed to the body of the product. When designing the proposed device as a whole, the ratio (R1 ≠ R2) <Rн should be taken into account so that the load resistance Rh (actually the “third resistance”, supplementing the resistances R1 and R2 to the closed triangle R1-R2-Rн-R1) does not complicate the analysis of the results measurements.

After eliminating the reason for the remark, the assembly of the electrical system of the product can be continued.

In addition, this device, being connected to the product’s electrical system that is being assembled, but not connected to a power source, provides verification of the circuits of the product’s power cables already installed on the product before connecting devices to them (if such a technological sequence of assembly of a particular electrical system is provided products). To do this, it is enough to leave the SA switch in its original position and check with an ohmmeter the resistance between the power circuits directly on the contacts of all the remote connectors of the power cables, taking into account the one-way conductivity of the VD diode connected to the product power buses. In this case, any errors in the wiring of the power cable circuits are detected, including breaks, short circuits and incorrect connections.

After completing the assembly of the product’s electrical system and with positive results of checking the status of the power buses and the electrical connections of these buses to the product’s chassis, the SA switch is set to its initial state, measuring devices are disconnected from the output circuits XS1-XS4 of the device (or the device as a whole is disconnected from the assembled electrical system of the product ) After that, the power supply voltage can be applied to the power supply busbars of the product’s electrical system and verification of its operability can be started.

The proposed set of features in the device considered by the author for performing such measurements was not met to solve the problem, and does not follow explicitly from the prior art, which allows us to conclude that the technical solution meets the criteria of "novelty" and "inventive step".

Note. The order of the functional purpose of the switch positions may be different, for example, the initial position may be, for example, the first. For this, the connections of the input and output circuits of the device with the contacts of the switch in figure 1 should be accordingly changed. From this, the novelty and performance of the proposed device when it is used will not change.

For the practical implementation of the proposed switch of measuring instruments, switches of the ZP4N type [1] can be used, and resistors and a diode of any type.

This switch of the measuring device can be made in the form of an independent device or introduced into the composition of the measuring stand or into the electrical system of the product as its component. In the latter case, the device can be used both in the assembly process, and during the operation of the product during the modernization, routine and repair work.

Currently, the proposed device is under development.

LITERATURE

1. Dubinsky G.N., Levin L.G. Adjustment of devices for electrical monitoring of voltages above 1000 V. - M.: SOLON-press, 2005; p.298, fig. 13.

2. Kulikov G.V., Khabarov B.P. Repair of measuring instruments. - M .: "SOLON-R", 2000; p. 58, fig. 3.3.

3. Thomas R.K. Switching devices. Reference manual. Radio Library, issue 1045. 1982 (Switches PG2 or PG3 type 6P2N, 3P4N and others.)

Claims (2)

1. The switch of measuring instruments for monitoring the quality of the power circuits of electrical systems of the product during their assembly, containing three input circuits, two output circuits and a switch, characterized in that two low-resistance resistors R1 and R2, a diode, a third and fourth output circuit are introduced into it, the switch is applied in four directions with contact groups in three positions, while the first input circuit is designed to connect to the product plus bus and is connected to the movable contact of the first contact group, the second input circuit is designed to connect to the negative bus of the product and is connected to the movable contact of the second contact group, the third input circuit is to connect to the product housing and connected to the movable contact of the third contact group, the first output circuit is to connect the first output of the measuring device and connected to the middle fixed contact of the first contact group, the second output circuit is designed to connect the second output of the measuring device and is connected to the middle fixed contact of the second contact group, the first and third fixed contacts of the first contact group are connected to one terminal of the first low resistance resistor R1, the first and third fixed contacts of the second contact group are connected to one terminal of the second low resistance resistor R2, the other terminals of the mentioned low resistance resistors are connected to the movable contact of the fourth contact group , the first fixed contact of the fourth contact group is connected to the third fixed contact of the third contact group and to the third output circuit, To connect the first output of the second measuring device, the first fixed contact of the third contact group is connected to the third fixed contact of the fourth contact group and to the fourth output circuit, designed to connect the second output of the second measuring device, the diode cathode is connected to the first output circuit, the diode anode is connected to second output circuit. 2. The switch of measuring instruments for monitoring the quality of the power circuits of the electrical systems of the product during assembly according to claim 1, characterized in that the low-resistance resistors R1 and R2 are made with different ratings in terms of resistance to each other and both in resistance are less than the equivalent load resistance Rн on the power bus (R1 ≠ R2) <Rн, while the resistance of one of the resistors can be reduced to zero.