RU2544357C2 - Switchboard of measurement instrument for control of quality of power supply circuits of electric systems of product during their assembly - Google Patents

Abstract

FIELD: instrumentation.

SUBSTANCE: device comprises three inlet circuits for connection to power supply buses and to the product body, and two outlet circuits for connection of a measurement instrument, two groups of electromagnetic relays, a diode and two low-resistance resistors R1 and R2, which are correspondingly connected to each other. At the same time the specified resistors may be made with different par values by resistance and be substantially less than equivalent resistance of load Rl on power supply buses.

EFFECT: increased efficiency due to reduced number of control measurements, elimination of impact from noise and errors of connection of a measurement instrument for reliability of an assembled electrical system of a product, provision of objective nature and validity of control and detection of errors or defects in an assembled electrical system of a product.

2 cl, 1 dwg

Description

The switch of the measuring device for controlling 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 technological equipment with automated control and can be used in the process of its assembly and technological preparation of the electrical systems of the products before first switching on for configuration 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 between each power rail and the product casing for both polarities of the measuring device and, based on the totality of the measurement results, the subsequent assessment of suitability for the continuation of the assembly or its first inclusion to verify 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 is nothing but a multiplexer, for example, a pyramidal one [1], made on electromagnetic relays (hereinafter referred to as the relay) and having two directions for six measurements (in [1] there is a diagram of one direction indicated by BS, the second direction is similar, the inputs of the measuring device are connected to them). Connecting the measuring device using such a switch can be performed alternately to de-energized power buses and to the product body 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 between each from power rails and the product body at both polarities of the measuring voltage. When switching from monitoring one circuit to another, you have to switch (one to turn on, others to turn off) up to three electromagnetic relays at once, and this requires three control inputs.

When using the measuring device in ohmmeter mode during the 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 body of the product are recharged with a change in voltage polarity, which is unacceptable for electrolytic capacitors, in particular - for capacitors installed between power rails. In addition, the process of measuring high-ohmic resistances 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.

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

As a prototype for the functional purpose and execution, the above-mentioned switch circuit may be adopted, made on the basis of [1], containing three input circuits, two output circuits, electromagnetic relays containing contacts and control windings, and control inputs associated with control windings.

However, this switch of the measuring device has a set of listed disadvantages. In addition, in an electrical system that has long power circuits and long measuring circuits during the assembly process, there is always interference due to electrostatic effects or due to spurious connections of the power circuits of measuring instruments with industrial networks, and interference from the EMF of self-induction of relay control windings, which can affect both on the measurement results and on the quality of electrolytic capacitors connected between the power buses of the devices of the assembled electrical system, and to another, especially low-voltage new, elemental base, which reduces the reliability of the equipment, can affect 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 switch of the measuring device for monitoring the quality of the power circuits of the electrical systems of the product during assembly, it contains three input circuits, two output circuits, electromagnetic relays containing contacts and control windings, and control inputs associated with control windings two low-resistance resistors R1 and R2 and a diode, a relay are combined into two independent groups having four groups of contacts, while the first input circuit is designed to connect to the “plus” power bus of the product and is connected the first changeover contact of the first contact group, the second input circuit is designed to connect to the power supply bus "minus" of the product and is connected to the second changeover contact of the first contact group, the third input circuit is designed to connect to the housing of the product and is connected to the third changeover contacts of the first and second contact group , the first output circuit is designed to connect the first output of the measuring device and is connected to the first normally closed contact of the second contact group, the second output the circuit is designed to connect the second output of the measuring device and is connected to the second normally closed contact of the second contact group, the first normally closed contact of the first contact group is connected to the first changeover contact of the second contact group, the second normally closed contact of the first contact group is connected to the second changeover contact of the second contact group , the first normally open contacts of the first and second contact groups are connected to one terminal of the first resistor R1, the second is normal o the open contacts of the first and second contact groups are connected to one terminal of the second resistor R2, the other terminals of the mentioned resistors are connected to the fourth changeover contacts of the first and second contact groups, the third normally open contact of the second contact group and the fourth normally open contact of the first contact group are connected to the first output circuit, the third normally open contact of the first contact group and the fourth normally open contact of the second contact group are connected to the second single chain, the diode cathode connected to the first output circuit, the diode anode connected to the second output circuit.

In addition, the low-resistance resistors R1 and R2 are made with different resistance values and each of them is significantly less than the equivalent load resistance Rн on the power bus of the product’s electrical system (R1 ≠ R2) <Rн. 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 objective monitoring of the state of the power circuits of the assembled electrical system of the product, only three measurement operations are required instead of six, which provides an increase in 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 to accumulate static electricity at the terminals of the measuring device. Thirdly, the galvanic connections of the power lines with the product housing are checked for compliance with the design documentation when the power lines are connected to each other through low-impedance resistances with one and the other polarity connecting the measuring voltage to the power lines relative to the product body, which eliminates the appearance of voltage of any polarity between the tires 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 product body using the same switch by applying only two voltage pulses (two commands) into two groups of windings of electromagnetic relays. 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 make it possible to determine the occurrence of any defect in the power circuits during the assembly of the electrical system of the product - short circuit, open circuit, Inadmissible communication with the product body, 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 device for controlling the quality of power circuits of electrical systems of the product during assembly.

Figure 1 adopted the following notation.

ХР1, XP2, ХР3 - input circuits of the device, provided, if necessary, with connectors for connection to power circuits and to the body of the assembled electrical system;

XS1, XS2 - output circuits of a device for connecting a measuring device, for example an ohmmeter;

K1, K2 - the first and second groups of electromagnetic relays that switch independently (or two relays with four groups of contacts each), while:

K1: 1-K1: 4 and K2: 1-K2: 4 - contacts of the first and second groups of contacts (or contacts of two relays with four groups of contacts each), in which contact 1 is normally closed with changeover contact 2, and contact 3 is normal open with changeover contact 2,

K1: 0, K2: 0 - control windings of the first and second groups of electromagnetic relays (or two relays with four groups of contacts each), intended for connection to an automated test station (AIS);

R1, R2 - low resistance resistors,

VD - diode.

The device of figure 1 is made as follows.

The first input circuit XP1 is designed to connect to the product’s “plus” power bus and is connected to the first changeover contact 2 of the first K1: 1 contact group, the second input circuit XP2 is designed to connect to the product’s “minus” power bus and is connected to the second changeover contact 2 of the first contact group K1: 2, the third input circuit XP3 is designed to connect to the product body and is connected to the third changeover contacts 2 of the first and second contact groups K 1: 3 and K2: 3, the first output circuit XS1 is designed to connect the first pin ode of the measuring device and connected to the first normally closed contact 1 of the second contact group K2: 1, the second output circuit XS2 is used to connect the second output of the measuring device and connected to the second normally closed contact 1 of the second contact group K2: 2, the first normally closed contact 1 of the first contact group K1: 1 is connected to the first changeover contact 2 of the second contact group K2: 1, the second normally closed contact 1 of the first contact group K 1: 2 is connected to the second changeover contact 2 of the second contact group K2: 2, the first normally open contacts 3 of the first K 1: 1 and second K2: 1 contact groups are connected to one terminal of the first resistor R1, the second normally open contacts 3 of the first K1: 2 and second K2: 2 contact groups are connected to one the output of the second resistor R2, the other outputs of the mentioned resistors R1 and R2 are connected to the fourth movable contacts 2 of the first and second contact groups K 1: 4 and K2: 4, the third normally open contact 3 of the second contact group K2: 3 and the fourth normally open contact 3 of the first contact group K1: 4 s connected to the first output circuit, the third normally open contact 3 of the first contact group K 1: 3 and the fourth normally open contact 3 of the second contact group K2: 4 are connected to the second output circuit, the cathode of the diode VD 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 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 operation with the electrical system of the product, the first input circuit ХР1 of the device is connected to the plus power bus of the assembled electrical system of the product, the second input circuit ХР2 is connected to the power bus "minus", the third input circuit ХР3 is connected to the body of the product (in the diagram of FIG. .1 not shown). The input of the 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 control windings K1: 0 and K2: 0 are connected to the AIS for supply to them as measurements of control voltages from the AIS are carried out. This is the initial state of the equipment, ready to conduct control measurements in the process of assembling the electrical system and preparing it for the first inclusion.

When using the device together or as part of an AIS, measuring instruments of the AIS itself can be used. Moreover, depending on the features of the product’s electrical system being assembled, instead of an ohmmeter (if necessary), a universal measuring device can be used, capable of measuring capacitors connected to power buses during the assembly of the product’s electrical system, or the complex resistance between power circuits, etc.

The proposed device works, being connected to the assembled, but not connected to the power source of the electrical system of the product, as follows.

All measurements are made in three steps (in three "steps"):

1. In the initial state of the relay K1 and K2 (figure 1) an ohmmeter connected to the "clean" power buses of the assembled electrical system of the product (it is advisable to connect the first device to them) through normally closed contacts (terminals 2-1) K1: 1 and K2: 1 (to the plus bus) and K1: 2 and K2: 2 (to the minus bus) should show an open circuit on any scale. If any technological device, for example, an indicator, is already connected between the power buses of this system, then the ohmmeter should show its resistance on the scale selected by the ohmmeter (or manually). If the measured value of this resistance does not correspond to the calculated one, it is necessary to analyze the remarks and eliminate the cause of the non-compliance.

2. When switching contacts K1: 1-K1: 4 of the first relay group (when a corresponding command is sent to the windings K1: 0 from the AIS side), normally closed contacts K1: 1 and K1: 2 (terminals 1-2) open and disconnect the measuring the device (ohmmeter) from the power supply buses of the system being assembled, and the normally open contacts K1: 1 and K1: 2 (terminals 2-3) are closed and series-connected low-resistance resistors R1 and R2 are connected to these buses. The midpoint of these resistors is connected through contact K1: 4 (terminals 2-3) to the first output circuit XS1 and then to one output of the measuring device (ohmmeter), and the other terminal of the measuring device through another output circuit XS2 and contact K 1: 3 ( conclusions 2-3) is connected to the third input circuit XP.3 and then to the body of the product. In this mode, the ohmmeter measures the resistance of galvanic couplings between the body of the product and the power rails, closed to each other through two series-connected low-resistance resistors. In this case, the "minus" of the measuring voltage is connected to the product body, and the "plus" of the measuring voltage is connected via low-impedance resistors R1 and R2 to both power supply buses of the product’s electrical system at the same time.

3. When switching contacts K2: 1-K2: 4 of the second group at the same time (when applying the appropriate command to the windings K2: 0 from the AIS side), normally closed contacts K2: 1 and K2: 2 (terminals 1-2) open and turn off the measuring device from the power supply buses of the assembled system, and normally open contacts K2: 1 and K2: 2 (pins 2-3) are closed and series-connected low-resistance resistors R1 and R2 are connected to these buses. The midpoint of these resistors is connected via pin K2: 4 (pins 2-3) to one output circuit and then to one pin of the measuring device, and the other pin of the meter through another output circuit and pin K2: 3 (pins 2-3) to the third input circuit and then to the body of the product under test. In this mode, the ohmmeter also measures the resistance of galvanic couplings between the body of the product and the power rails, closed to each other through two series-connected resistors R1 and R2, but with a different polarity of the measuring voltage.

If the resistance between the chassis and the power rails, measured in steps 2 and 3, is normal, you can proceed to connect the next cable or device to the system being assembled, after connecting which the measurements are repeated in steps 1-3. In this case, the measurement in step 1 is carried out continuously as soon as the relay contact groups return to their original state. And so on, until the assembly of the electrical control system of the product.

If the resistance between the power rails and the product casing, measured in steps 2 or 3, 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 can be continued.

A short circuit of any power bus of the assembled electrical system of the product to the product body can be easily identified by the value of the measured resistance between the product body and the common resistance point R1 and R2. For example, we take R1 = 10 Ohms and R2 = 20 Ohms, although the ratings of these resistances may be different, but should be several times 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, with a short circuit to the chassis of the product bus “minus” an ohmmeter will show a resistance of not more than 20 Ohms, and with a short circuit to the chassis of the bus “plus” - no more than 10 Ohms. When designing the proposed device as a whole, the ratio (R1 ≠ R2) <Rн should be taken into account so that the load resistance Rн (actually the “third resistance”, supplementing the resistances R1 and R2 to a 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 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 power cables of the electrical system already laid on the product before connecting devices to them (if such a technological sequence of assembly of a specific electrical system of the product is provided ) To do this, it is enough to set the relay groups K1 and K2 to their initial state (do not apply voltage to the control windings K1: 0 and K2: 0) and check with an ohmmeter the resistance between the power circuits directly on the contacts of all remote connectors of the power cables, taking into account the one-way conductivity of the VD diode connected to the product power rails. In this case, any errors in the wiring of the power cable circuits are detected, including breaks, short circuits and incorrect connections.

After 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 body, both groups of contacts of the electromagnetic relays are set to their initial state (the voltage is removed from the windings K1: 0 and K2: 0 of the electromagnetic relays K1 and K2), the measuring device, or the device as a whole, must be disconnected from the assembled electrical system of the product. After that, a supply voltage can be applied to the assembled electrical system of the product and verification of its operability can be started.

Additionally, the device allows you to check the operability of the measuring device: if both groups of relay contacts are turned on (apply voltage to the control windings K1: 0 and K2: 0), then the circuits XS1 and XS2 for connecting the measuring device will be closed through two pairs of series-connected contacts K1: 3-K2: 3 and K1: 4-K2: 4 and an ohmmeter will indicate a short circuit. Such a check does not affect anything, does not take any measurements on the product, but provides a technological check of the operability of the measuring device itself: it starts the automatic selection of the measurement scale in the measuring device and is safe for the equipment of the electrical system of the product.

After 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 body, both groups of contacts of the electromagnetic relays are set to their initial state (the voltage is removed from the windings K1: 0 and K2: 0 of the electromagnetic relays K1 and K2), measuring devices, or the device as a whole, are disconnected from the assembled electrical system of the product. After that, a supply voltage can be applied to the assembled electrical system of the product 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".

For the practical implementation of the proposed switch, two groups of electromagnetic relays can be used, four relays in each relay group with one changeover contact each, or one electromagnetic relay with four changeover contacts in each, etc.

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

Currently, the proposed device is at the development stage.

LITERATURE

1. V.M. Shlyandin and K.N. Chernetsov. Automation of control of electric circuits. Ed. "Energy", Moscow, Leningrad, 1966, p. 39, Fig. 13.

Claims (2)

1. The switch of the measuring device for controlling the quality of the power circuits of the electrical systems of the product during assembly, containing three input circuits, two output circuits, electromagnetic relays containing contacts and control windings, and control inputs associated with control windings, characterized in that a diode and two low-resistance resistors R1 and R2 are introduced, electromagnetic relays are combined into two groups, the control circuits of each group of electromagnetic relays are interconnected and connected to the control inputs of electromagnetic relays, In this case, the first input circuit is designed to connect to the power supply bus “plus” of the product and is connected to the first changeover contact of the first contact group, the second input circuit is designed to connect to the power supply bus “plus” of the product and is connected to the second changeover contact of the first contact group, the third input the circuit is designed to connect to the product body and is connected to the third changeover contacts of the first and second contact group, the first output circuit is designed to connect the first output of the measuring the instrument and is connected to the first normally closed contact of the second contact group, the second output circuit is for connecting the second output of the measuring device and connected to the second normally closed contact of the second contact group, the first normally closed contact of the first contact group is connected to the first changeover contact of the second contact group, the second normally closed contact of the first contact group is connected to the second changeover contact of the second contact group, the first normally open contact the strokes of the first and second contact groups are connected to one terminal of the first resistor, the second normally open contacts of the first and second contact groups are connected to one terminal of the second resistor, the other terminals of these resistors are connected to the fourth changeover contacts of the first and second contact groups, the third normally open contact of the second contact groups and the fourth normally open contact of the first contact group are connected to the first output circuit, the third normally open contact of the first contact groups and the fourth normally open contact of the second contact group are connected to the second output circuit, the cathode of the diode is connected to the first output circuit, the anode of the diode is connected to the second output circuit. 2. The switch of the measuring device for controlling 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 used with different ratings in terms of resistance to each other and both in terms of resistance are significantly less than the equivalent load resistance Rн on tires power supply (R1 ≠ R2) <Rн, while the resistance of one of the resistors can be reduced to zero.