RU129281U1 - SOFTWARE AND HARDWARE COMPLEX OF AUTOMATED FUNCTIONAL CONTROL OF ELECTRICAL INSTALLATION STRUCTURES - Google Patents

Abstract

A software and hardware complex for automated functional control of electrical installation structures, containing a workstation, a connector block, a switching unit with the corresponding channels and a connecting board, a transition unit and a measuring unit, characterized in that a computer is used as a workstation and an external power supply unit with automatic a switch and an insulation breakdown control device and an internal power supply unit, in addition, the switching unit is equipped with a microprocessor controller with a control system and a programmable current and voltage source, and the measuring unit is equipped with a voltmeter, while the first input-output of the workstation is connected to the input-output of the microprocessor controller the switching unit, the second input-output of the workstation is connected to the digital input of the voltmeter of the measuring unit through the transition unit, the analog inputs of the voltmeter are connected to the measuring outputs of the board of the connecting switching unit, the calibration output of this board is so It is connected with the connector block, and its inputs - with the outputs of the internal power supply unit; in addition, the first output of the external power supply unit is connected to the input of the internal power supply unit, and its second output is connected to the power supply input of the voltmeter.

Description

The utility model relates to radio electronics and computer engineering and can be used to control the installation of harnesses, blocks, devices and complexes that use volumetric or printed wiring.

A device for monitoring electrical installation according to the USSR Author's Certificate No. 723590, M. Cl. ² G06F 15/46, 1978, publ. Bull. No. 11, 1980

The prototype device comprises a communication unit with a monitored object, a RAM block, a model state encryption block, a mounting model generation block, a recorder, a result decryption block, a control block, a program input block and an error output block.

Device prototype works as follows.

The communication unit with the monitored object supplies a single potential to the first contact of the mounted circuit and fixes all the numbers of contacts connected to this circuit at each installation step. The sequence of contact numbers is recorded in the corresponding area of the RAM block, then the information through the encryption block of the model state goes to the block for creating the mounting model, where the real mounting model is formed. The program input unit transmits information about the reference installation to the control unit, which gives instructions to read the RAM block, then the information enters the model state encryption unit and then to the installation model formation unit to form a real installation model for the circuits specified by the control unit. Using the recorder, the control unit analyzes the conformity of the real installation to the standard. If there is no connection in the actual installation, available in the reference, the information enters the error output unit. If the actual installation contains unnecessary communication, then after fixing the fact of such an error, the model contacts are switched off sequentially with the help of the recorder until the electrical connection between the two unconnected circuits in the standard installation disappears.

The prototype device provides localization of errors in installation, but has drawbacks.

The disadvantages of the prototype device are the significant verification time and the high complexity of localization in the installation of an extra connection between two long chains, each of which can consist of tens or hundreds of connections. When correcting such errors in installation, it is necessary to use connection tables, wiring drawings, or other documentation, and the time to correct such an error may exceed several times the verification time of the controlled product. The localization of excess communication, for example, a short circuit between the power bus and the ground bus, each of which has several hundred connection points, has to be done by dividing the circuit into parts, while controlling in which part of the circuit the circuit is preserved. The impossibility of long-term storage of the generated installation model, the output of results to the printing device, and the inability to verify various models and installation topologies. The impossibility of measuring the voltage level at the reciprocal end of the circuit (conductor) and comparing it with the filed, i.e. measuring the voltage drop in the circuit, which, in turn, does not allow to identify poor-quality contacts, for example due to cold soldering. The prototype device does not provide control efficiency, requires restarting after each operation and does not provide a visual representation of the geometry of the circuit. In addition, there is no protection against short circuit and overload of circuits and protection against electric shock to personnel during current leakage, i.e. during breakdown of insulation.

The problem to be solved is to increase speed and expand functionality by providing long-term storage of the generated installation model, outputting results to a printing device and the ability to test various models and installation topologies, the ability to measure the resistance of the circuits of the tested product, adjusted for the resistance of the connecting (technological) bundles, voltage drops chains and identification of poor-quality contacts, as well as increased safety of work - protection against short circuit and overload by the introduction of a circuit breaker and from damage in case of current leakage by the introduction of an insulation breakdown monitoring device

The essence of the claimed utility model consists in the fact that in the software and hardware complex of automated functional control of electrical installation structures containing a workstation (in the prototype there is a RAM unit, a control unit, a program input unit and an error output unit), connection and switching blocks with switching channels (in the prototype - a communication unit with a controlled object) and transitional and measuring units (in the prototype - a block encrypting the state of the model, the block forming the installation model and the decryption block results), a computer was used as a workstation, to which connecting boards are connected, while their number can be increased if necessary, which makes it possible to simultaneously monitor several electrical installation structures, i.e. improve performance, in addition, the use of computers allows you to store information on an unlimited number of different models and installation topologies, which can be loaded into RAM without using a reference sample, which also increases the speed of operation; an external power supply unit for the distribution of mains voltage 220 V, 50 Hz has been introduced for the components of the complex with a circuit breaker for protection against short circuit and overload and a device for monitoring breakdown of insulation for protection working with the complex personnel, from electric shock as a result of a possible breakdown of the insulation of the 220 V electric circuit to the case, and the internal power supply unit for generating +5 V, + 12 V and +48 V power supply to the switching unit, the switching unit is equipped with a microprocessor controller with a control system and programmable a source of current and voltage, designed to ensure the electrical modes of the tested products, and the measuring unit is equipped with a voltmeter designed to measure the voltage drop in the circuits of the tested products and in Identification of poor-quality contacts, the value of these parameters in the form of a digital code from the output of the RS232 serial port is fed to the input of the workstation for further analysis, and then back to the RS232 voltmeter port to control its operation mode, the voltmeter inputs being connected to the switching unit, while the transition unit It is structurally included in the power supply unit for connecting the voltmeter of the measuring unit with the workstation and matching their signals with the measuring unit.

Description of the construction of the complex

The complex is designed as a dashboard rack (cabinet) with the following components located in it on the floors:

1 - workstation

2 - block connector

3 - switching unit,

4 - block transition,

5 - measuring unit,

6 - external power supply,

7 - circuit breaker,

8 - control device breakdown isolation

9 - internal power supply,

10 - voltmeter.

Each block is made in the form of a separate finished construct, the electrical blocks are interconnected by cable connections and bundles, while the components of the same name are interchangeable.

The set of mounting parts also includes electrical harnesses used to connect the complex to the tested product.

Description of the device and the operation of the complex in accordance with the functional diagram

Workstation 1 is a personal computer with a printer and monitor * (* ⁾ not shown in the diagram) and is intended for generating control signals, analyzing measurement results, displaying and printing them, providing an interface with the user through software, and also for storing information for an unlimited number of different models and installation topologies.

The connector block 2 with sockets - analogues of the tested products is intended for self-testing (functional testing) and calibration of the complex to introduce corrections for the resistance of the connecting (technological) harnesses * when measuring the resistance of the circuits of the tested product * and connected to the connection board ** (** ⁾ not shown on the diagram) switching unit 3.

Switching unit 3 consists of switching channels K 1 ... K N **, a special channel SK **, a microprocessor controller MK ** and a connection board **. The switching channels ** are controlled by the MK ** controller, which, along with the control system *, includes a programmable current and voltage source PITN *, which ensures the electrical modes of the tested products *. The mentioned switching channels ** provide communication and switching of the electric circuits of the voltmeter 10 of the measuring unit 5, a programmable current and voltage source ** with the circuits of the tested products **, as well as with the workstation 1.

The transitional unit 4, for communication of the voltmeter 10 with the workstation 1 and matching their signals with the measuring unit 5, the transitional unit 4 is structurally included in the internal power supply unit 9.

Measuring unit 5 together with a voltmeter 10 (for example, a universal digital voltmeter B7 - 65/5) are designed to measure the controlled parameters of the tested products **. The values of these parameters in the form of a digital code from the output of the RS232 serial port are input to the workstation 1 for further analysis, and then back to the RS232 port of the voltmeter 10 to control its operation mode, while the inputs of the voltmeter 10 are connected to switching unit 3.

The external power supply unit 6 is designed to distribute the mains voltage of 220 V, 50 Hz to the components of the complex, for protection against short circuit and overload, the circuit breaker 7 and an insulation breakdown monitoring device 8 are installed in the unit for protection against electric shock from personnel as a result of a possible breakdown of the insulation of the electric circuit 220 V to the housing *.

The internal power supply 9 is designed to generate voltages +5 V, +12 V and +48 V power supply switching unit 3.

When assembling the complex, the first input-output of station 1 is connected to the input-output of the microprocessor controller ** of the switching unit 3, the second input-output of station 1 is connected to the digital input of the voltmeter 10 of measuring unit 5 through the transition unit 4, the analog inputs of the voltmeter 10 are connected to the measuring outputs connecting board ** of switching unit 3, the calibration output of this board is connected to the connector block 2, and its inputs are connected to the outputs of the internal power supply unit 9, the first output of the external power supply unit 6 is connected to the input of the internal unit power supply, and its second output is with the power input of the voltmeter 10.

The connection of the tested (controlled) products * with the complex is carried out by means of external harnesses * included in the set of assembly parts of the complex, while the composition of the connected harnesses depends on the specific product.

When working with the complex, connect the connectors of the switching unit 3 to the connectors of the connector block 2 using the cables * included in the kit of the latter. Then they connect the external power supply unit 6 to the 220 V, 50 Hz network and turn on the internal power supply unit 9 and workstation 1, load the operating system and start the self-test program, while the circuit breaker 7 provides protection against short circuit and overload, and the insulation breakdown monitoring device 8 - protection against electric shock as a result of a possible breakdown of the insulation of the 220 V electric circuit to the housing * of the complex. The complex is calibrated, including measuring the resistance of the connecting (technological) harnesses * to introduce corrections when measuring the resistance of the circuits of the tested product *. After passing the self-test and calibration of the complex, disconnect the connector block 2 and connect the controlled mounting structure * (harness, block, device or complex). In the storage device * of the workstation 1, select the necessary reference program - the sample, assign one of the switching channels ** and start the monitoring program, observe the result on the monitor * of the workstation 1 and, if necessary, print the received data on the printer *.

If there is no necessary reference program in the database, the program is launched and the structure being checked is written as a reference and its identifier is assigned to it.

The program of the complex allows you to produce:

- viewing tasks for testing the product, with the possibility of issuing to a printing device (printer);

- input passport data on the tested product;

- verification of the functioning of the complex;

- manual control of electrical circuits, with the ability to change the measuring range;

- the formation of a test report of the mounting structures of the tested product, with the subsequent issuance of test results to a printing device (printer).

The complex is designed to test the wiring of various electrical products, including the following checks:

- conformity of the installation of the product to the wiring drawing, control of messages of electrical circuits);

- disunity of electrically unconnected electrical circuits of the product among themselves (control of disunity of electrical circuits);

- insulation resistance of the electrical circuits of the product, relative to the housing, and between electrically unconnected circuits;

- the correct functioning of the product when a nominal supply voltage (27 ± 0.5) V is applied to it and the voltage of the power sources changes from 24 to 32 V;

- current consumed by the product.

Technical data of the complex:

- the maximum number of control points is 832;

- tolerance control when measuring resistance δ: ± 1%;

- tolerance control when measuring voltage δ: ± 1%;

- tolerance control when measuring current δ: ± 1%;

- primary power supply voltage 220 V, frequency 50 Hz;

- the current consumed by the complex along the circuit 220 V, 50 Hz, not more than 2.5 A;

- the complex functions normally for 16 hours when a supply voltage and control signals are applied to it;

- the complex saves the parameters when the voltage of the power supply 220 V, 50 Hz varies from 198 to 242 V;

- the mass of the complex (75 ± 7.5) kg;

- the designated life and storage of the complex is 5 years.

The technical result from the use of a utility model is to increase performance, security and functionality.

The specified technical result is achieved by a combination of distinctive features, namely the use of a computer as a workstation, the introduction of an external power supply unit with a circuit breaker and an insulation breakdown control device and an internal power supply unit, as well as supplying the switching unit with a microprocessor controller with a control system and a programmable current and voltage source , and the measuring unit with a voltmeter.

The presented description and diagram of the claimed complex allows, using existing materials and unified purchased component parts, to manufacture it industrially and use it to control the installation of harnesses, blocks, devices and complexes that use volumetric or printed wiring.

Claims (1)

A hardware-software complex of automated functional control of electrical installation structures containing a workstation, a connector block, a switching unit with corresponding channels and a connecting board, a transitional unit and a measuring unit, characterized in that a computer is used as a workstation and an external power supply unit with automatic switch and isolation breakdown control device and internal power supply, in addition, the switching unit is equipped with a microprocessor controller with a system board and a programmable current and voltage source, and the measuring unit with a voltmeter, while the first input-output of the workstation is connected to the input-output of the microprocessor controller of the switching unit, the second input-output of the workstation is connected to the digital input of the voltmeter of the measuring unit through the transition block, analog the voltmeter inputs are connected to the measuring outputs of the board of the connecting switching unit, the calibration output of this board is connected to the connector block, and its inputs to the outputs of the internal pi block anija, moreover, the first external power supply output is connected to the input of the internal power supply, and its second output - to the input of the voltmeter supply.

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