RU108857U1 - VOLTAGE REGULATOR INSPECTION STAND - Google Patents

Abstract

 A voltage regulator test stand comprising a power supply unit connected to a control unit, a control unit and an indication unit that are connected to a switching unit, a load resistor unit that contains a set of resistors that simulate the actual load of the voltage regulator, to which an analog-to-digital converter is also connected signal having a data input-output adapter connected to a personal computer, and a place for connecting the studied objects, characterized in that in the stand are additionally connected a unit simulating a feedback signal for a charge current of a battery, a unit for generating a feedback signal for a voltage of a charge of a battery, and a unit simulating a feedback signal for a voltage at an output, set so that the switching unit is connected to the investigated voltage regulator, and the analog-to-digital converter additionally contains a block of dividers and is connected to the tested voltage regulator.

Description

The utility model relates to electrical engineering, namely to bench equipment that checks and adjusts the voltage regulator of electric rolling stock, and can be used to test the performance of the sample presented for different types of tests, as well as to carry out adjustment work in the conditions of the manufacturer and repair locomotive depots.

The prototype is a stand for checking the power panel, containing a power supply connected to the switching and indicating device, short circuit protection, an analog signal converter, a panel with terminals for connecting the objects under study, a block of load resistors, a block of measuring devices: voltage and current, showing the received information on the displays of digital switchboards, small-sized switching units, designed to connect the control elements of the stand with the data input-output adapter, which the queue is connected to a personal computer, which serves to register and process the information received, as well as to control the operation of the stand in automatic mode using software (RF Patent for utility model No. 77448).

The disadvantages of the stand are: the impossibility of checking the operability of the voltage regulator PH5, a significant investment of time for assembling the test circuit and checking the parameters of the tested samples of equipment, which leads to an increase in labor intensity, etc.

The objective of the utility model is to check the operability of the PH5 voltage regulator, reduce the complexity and accelerate the process of setting up and checking new or already in use on an electric locomotive or failed PH5 voltage regulators.

The problem is solved in that the proposed stand contains a power supply connected to the control unit, the control unit and the display unit, which are connected to the switching unit. The above blocks, in turn, are connected to a block simulating a feedback signal on the battery charge current, and also to a block generating a feedback signal on the battery charge voltage and a block simulating a feedback signal on the output voltage. In addition, the stand has a block of load resistors and an analog-to-digital signal converter, which has a divider block and an input / output data adapter, a personal computer and a multi-pole outlet for connecting a voltage regulator. The stand includes an indicator panel designed to determine the integrity of circuits and elements of the voltage regulator being checked.

The difference from the prototype is that a unit simulating a feedback signal for the battery charge current, a unit for generating a feedback signal for the battery charge voltage and a block simulating a signal are additionally connected to the power supply, control, monitoring, display and switching units; feedback on the output voltage, and the analog-to-digital Converter additionally contains a block of dividers. The place for connecting the studied objects is made in the form of a multi-pole outlet.

EFFECT: reduced labor intensity, accelerated adjustment process and increased labor productivity when checking the operability of a failed PH5 sample.

It should be noted that the test stand for the voltage regulator is capable of checking the electrical parameters of the sample not only in manual mode, but also in automatic mode, by means of an analog-to-digital adapter and a personal computer with special software installed. If necessary, the results can be saved on any storage medium as a text file or printed.

Figure 1 presents a diagram of a structural bench test voltage regulator (SP RN5).

Figure 2 presents the diagram of the power supply, control, monitoring and display stand.

Figure 3 presents the circuit block switching stand.

Figure 4 presents a block diagram simulating a feedback signal on the charge current of the battery.

Figure 5 presents a block diagram of the formation of a feedback signal for the voltage of the charge of the battery.

Figure 6 presents a block diagram simulating a feedback signal on the output voltage.

Figure 7 presents a block diagram of the load resistors of the stand.

On Fig presents a block diagram of an analog-to-digital Converter stand.

Figure 9 presents a table of checking the performance of the voltage regulator.

The test stand of the voltage regulator, depicted in the form of a structural diagram (Figure 1), contains a power supply 1 having a short circuit protection in the form of a circuit breaker connected to a control unit 2, a control unit 3 and an indication unit 4. These units that perform the power function , control, monitoring and indication, connected to a switching unit 5, a unit simulating a feedback signal on the charge current of the battery 6, a unit for generating a feedback signal on the charge voltage of the battery 7, the unit simulating a feedback signal on the voltage at the output 9. The switching unit 5, in turn, is connected to the blocks 6, 7, 9 and the studied voltage regulator 8. The block of load resistors 10 performs the function of simulating the load of the studied voltage regulator 8. The analog-digital block a converter 11, comprising a block of dividers 12, as well as an input / output data adapter 13 that converts information from analog to digital, for subsequent processing and control of the stand in automatic mode using a personal computer 14, in turn, is connected to the switching unit 5 and the investigated voltage regulator 8.

The power supply unit (Figure 2), in turn, contains: an automatic switch 15 with indication 16, necessary for supplying mains power to the stand circuit and performing the function of protecting against short circuit currents; electromagnetic starter 17, designed to supply and remove the mains voltage directly in the SP RN-5 circuit using the buttons of the combined post 18 with backlight 19. Fan 20 serves to cool the load resistors. Using the buttons 21 and 22, the relay 23 and 24, the motor 25, the autotransformer 26, the supply voltage specified by the program and test procedure PH5 is set. Transformer 27 is an isolator. Diodes 28-31, resistors 32-33 provide a pulsating voltage supply voltage regulator. Thyristor 34 is used to simulate the thyristors of a power rectifier. The zener diode 35 is designed to open the thyristor 34. The winding 7-8 of the transformer 27, the voltage regulator 36 is used to power the indicator panel 37, which is designed to troubleshoot. A voltmeter 38 is used to control the test voltage. The terminals of stand 39, 40, 41 are used to connect the oscilloscope. Intermediate relays 42-47 and buttons 48-53 controlling electric motors 54-56 mounted on the axis of the movable contacts of resistors 74 (figure 4), 76 (figure 5), 82 (figure 6) to adjust the value of the variable resistance, which simulates the test signal regulator voltage 8. Using buttons 48-53, the value of the test voltage is changed. The LEDs 57-62 indicate the extreme left or rightmost position of the resistors 74, 76, 82. To limit the motors 54-56 and send a signal to the extreme position indicators 57-62, the limit switches of the motors 63-68 are used. The switch 69 transfers the stand from the manual control mode verification (position "Manual") to automatic (position "Automatic").

The switching unit (Figure 3) consists of a switch 70, which serves to connect the terminals of the stand 40 and 41 to the monitored circuits of the voltage regulator under test, and small-sized switching blocks 71-73, which participate in the verification of the voltage regulator in automatic mode.

The block simulating the feedback signal on the charge current of the battery (Figure 4), consists of a winding 5-6 of the transformer 27 and resistors 74, 75.

The block for generating a feedback signal for the voltage of the battery (Figure 5) consists of resistors 76-78, diode 79, capacitor 80.

The block simulating the feedback signal on the output voltage (Figure 6) consists of resistors 81-83.

The block of load resistors (Figure 7) contains a set of resistors 84-86, simulating the real load of the voltage regulator 8.

In the "Automatic" test mode, the voltage regulator 8 is registered using the analog-to-digital converter unit (Figure 8), which consists of a divider board 12, which in turn consists of zener diodes 87 and 88 and resistors 89-92, and an input adapter -data output 13. Communication of the output of the input-output data adapter 13 with the corresponding connector of a personal or laptop computer 14 is carried out using a USB cable (included in the adapter 13 kit). The connector of the stand 93 is used to connect the test sample voltage regulator RN-5 using a connecting cable.

The stand works as follows:

To test the performance and commissioning, the studied voltage regulator is connected to the test stand by means of a connecting cable. Then the stand is connected by a network cable to the AC voltage network (220 ± 22) V of frequency (50.0 ± 0.5) Hz and the supply voltage is supplied to the circuit breaker 15 with indication 16 and the supply voltage is supplied to the input circuit of the stand circuit.

An electromagnetic starter 17 is designed to supply and remove mains voltage directly in the SP RN-5 circuit using the buttons of the combined post 18 with backlight 19.

The supply voltage is supplied to the fan 20, which serves to cool the load resistors.

From the transformer 27 (conclusions 3-4), using the buttons 21 and 22 of the relay 23 and 24, the motor 25, the autotransformer 26, the supply voltage specified by the program and test procedure RN-5 is set. Diodes 28-31, resistors 32-33 provide a pulsating voltage supply voltage regulator (75 ± 5) V, control by voltmeter 38. Thyristor 34 is used to simulate the thyristors of a power rectifier. Zener diode 35 is designed to open the thyristor 34.

The feedback signal on the charge current of the battery is generated using a transformer 27 (pins 5-6), an intermediate relay 42, 43 and buttons 48, 49, a gear motor 54 mounted on the axis of the movable contact of the resistor 74, resistor 75.

A feedback signal on the voltage of the battery is generated using an intermediate relay 44, 45 and buttons 50, 51, a gear motor 55 mounted on the axis of the movable contact of the resistor 76, resistors 77, 78, diode 79, and capacitor 80.

A feedback signal on the output voltage is generated using the intermediate relay 46, 47 and buttons 52, 53 of the gear motor 56 mounted on the axis of the movable contact of the resistor 82, resistors 81 and 83.

From the transformer 27 (conclusions 7-8) through the voltage stabilizer 36, voltage is supplied to the indicator panel 37, designed to determine the integrity of the circuits and elements of the tested voltage regulator.

In the "Manual" mode, the voltage regulator 8 is registered using a two-channel oscilloscope (the option is not included in the stand) connected to the terminals of the stand 39, 40, 41. The switch 70 is used to connect the terminals of the stand 40, 41 to the monitored circuits of the tested regulator. Next, the check of the voltage regulator is carried out according to the table (figure 9).

Using the switch 69 carry out the transfer of the stand from the manual control control mode (position "Manual") to automatic (position "Automatic").

In the "Automatic" test mode, the voltage regulator parameters are registered using the analog-to-digital converter unit 11, which consists of a data input-output adapter 13 and a divider unit 12, which in turn contains zener diodes 87, 88, and resistors 89-92.

The connection of the output of the data input-output adapter 13 with the corresponding connector of the personal computer 14 is carried out using a USB cable (included in the adapter kit).

When the switch 69 is in the "Automatic" position, the controls of the SP RN-5 stand are disconnected from the standard electrical circuit. Next, the control of the test mode occurs through the input and output circuits of the switching blocks 71, 72, 73. Automated reading of information about the state of the monitored parameters for recording and storing in the memory of the computer 14 is carried out through the data input-output adapter 13. The service program, in accordance with the statement of work , issues a conclusion on the operability of the voltage regulator in the form of a protocol - in the form of a text file. Subsequently, it can be stored on any type of storage medium, including a “hard” magnetic computer drive.

The positive effect of the utility model is manifested in the fact that the proposed technical solution will speed up the setup process and increase productivity when checking the operability of a failed PH5 sample using one single apparatus - a stand. It should be noted that the stand is capable of checking the electrical parameters of the voltage regulator not only in manual mode, but also in automatic mode, using an analog-to-digital adapter and a personal computer with special software installed. At the same time, the stand is equipped in such a way that it can be moved and placed in any convenient place, even in an electric locomotive, excluding the dismantling of the voltage regulator from the power cabinet of the electric locomotive.

Claims (1)

A voltage regulator test stand comprising a power supply unit connected to a control unit, a control unit and an indication unit that are connected to a switching unit, a load resistor unit that contains a set of resistors that simulate the actual load of the voltage regulator, to which an analog-to-digital converter is also connected signal having a data input-output adapter connected to a personal computer, and a place for connecting the studied objects, characterized in that in the stand are additionally connected a unit simulating a feedback signal for a charge current of a battery, a unit for generating a feedback signal for a voltage of a charge of a battery, and a unit simulating a feedback signal for a voltage at an output, set so that the switching unit is connected to the investigated voltage regulator, and the analog-to-digital converter additionally contains a block of dividers and is connected to the tested voltage regulator.