RU107607U1 - LOAD UNIT - Google Patents

Abstract

1. A load block containing voltage and load converters, characterized in that it contains indicators of currents and voltages of the secondary power supply module, indicators of the status of loads, control buttons, a microcontroller, a generator, a polarity inverter, an interface circuit, a load switch, and current indicators and voltage and load status indicators with their inputs, and the control buttons for their outputs are connected to the first and second outputs and the first input of the microcontroller, which is connected to the generator with its second input, and with the polarity inverter by its third output, the input of which is connected to the power bus and the input of the first voltage converter, the output of which is connected to the inputs of the second and third voltage converters, and the outputs of the second and third voltage converters are connected to the third and fourth inputs of the microcontroller, respectively, the output of the third voltage converter is connected to the input of the interface circuit, two inputs of which are connected to the outputs of the tested product, and the output is connected to the input of the microcontroller, the output of which is connected to the input of the load switch, the outputs of which are connected to the inputs of the loads. ! 2. Load block according to claim 1, characterized in that a pulse voltage converter from 24 V to 7 V is used as the first voltage converter. ! 3. Load block according to claim 1, characterized in that linear voltage converters from 7 V to 5 V are used as the second and third voltage converters. ! 4. Load block according to claim 1, characterized in that a clock generator is used as a generator.

Description

The utility model relates to the field of electronic equipment, is designed to test the health of the secondary power supply modules (hereinafter - MVIP) and can be used in technological means of debugging and monitoring power supplies.

A device for monitoring and signaling about malfunctions of at least two power sources (see RF patent No. 687441, IPC 2 G05F 1/58, publ. 09/25/1979, according to the application No. 2471935 / 24-07 of 03/28/1977 for the invention “Device for monitoring and signaling about malfunctions of at least two secondary power sources”, patent holder of the Kiev Order of the Red Banner of Labor, factory of computer and control machines). The known device contains two overvoltage sensors, two undervoltage sensors, two AND-NOT summing logic circuits, two display units, an actuator, a memory element, a power supply, an electronic interlock, two terminals, two monitored channels. In general, the maximum number of channels is determined by the number of inputs of the logic circuits of the display units and the actuator. If the required number of monitored channels is greater than the number of inputs of the logical circuits of the NAND displays and the inputs of the actuating element, the device can be made according to a “tree diagram” with the introduction of additional logic elements, which, in turn, will complicate the circuit and, as consequence, to complicate the design of the device. The device operates in four modes: in the "on" mode of the device, in the "tracking" mode, i.e. when the rated voltages are set at the output of controlled secondary power supplies (hereinafter - VIP), in the "accident" mode, when the output voltage of one sensor and the VIP is out of range, and in the "address storage" mode of the emergency VIP.

Signs of an analogue that coincide with the features of the claimed technical solution are as follows: two display units.

Reasons that impede the achievement of the claimed technical result are: the complexity of the design (circuit design), the inability to connect various loads to the tested power source, the inability to change the polarity of the power supply of the tested power source.

A known control system for power sources (see RF patent No. 1262455, IPC 4 G05B 23/02, published on 10/07/1986 by application No. 3868164 of 03/15/1985 for the invention of "Power supply control system", patent holder I am M-5343). The known device contains a programmer, a voltage switch, a load current regulator, a store of tuning elements, a scoreboard, a data logger, three analog-to-digital converters, moreover, the programmer, in turn, contains a control computer, an input device, an operator console, a matching device, a device mode selection, decryption unit, control code registers, transformer, switch, optothyristors, switch control unit, NAND elements. The system operates in two modes: “Control” and “Settings”. In the “Control” mode, the system provides automatic control of the electrical parameters of the tested power source, namely: output voltage level, output voltage ripple, stabilization coefficient when the mains voltage changes by + 10%, stabilization coefficient when the load current changes from 0 to maximum, operability after short circuit, operation threshold of the current protection circuit, operation thresholds of the voltage protection circuit. In the “Setup” mode, the system provides automatic control of the same parameters and performs additional operations: automatic setting of the output voltage level using the control element, automatic selection of the two resistors in the voltage protection circuit with the output of the values of the selected resistors on the display. The duration of one cycle of work in the "Control" mode is 30 s, and the duration of one cycle of work in the "Setup" mode is 70 s. System control is carried out by monitoring a known-good power source in both operating modes.

Signs of an analogue that coincide with the features of the claimed technical solution are as follows: a load current regulator, the functions of which in the inventive device are performed by a switch of loads and loads, the first and second analog-to-digital converters (ADCs), the functions of which in the claimed utility model are performed by the microcontroller ADC (MK) , an input device, the functions of which in the inventive device are performed by control buttons, an operator console, the functions of which are also performed by control buttons, a display board, the functions of which are performed by current indicators s and voltages of the secondary power supply module and load status indicators. The reasons that impede the achievement of the claimed technical result are: the complexity of the design (circuit design) due to the large number of elements, the inability to change the polarity of the power supply of the tested power source, the inability to simultaneously control two channels of the tested power source.

A device for controlling a power source is known (see USSR author's certificate No. 1515117, IPC 4 G01R 19/165, published on October 15, 1989, by application No. 4258379 of June 5, 1987 for the invention “Device for monitoring a power source”, patent holders Production Association “Kazavtotranstekhnika”, Institute for Advanced Studies of Executive Officers and Automotive Industry Specialists). The known device contains three comparators, a load current sensor, two controlled generators, an OR element, an NAND element and an indicator. The device allows using one LED to control three voltage levels (less, normal, more) and two current levels (normal, more).

Signs of an analogue that coincide with the features of the claimed technical solution are the load current sensor, the functions of which can be performed by one of the components of the switch of loads and the indicator.

The reasons hindering the achievement of the claimed technical result are the lack of the ability to display currents and voltages at the outputs of the tested product, the inability to connect various loads to the tested power source, the inability to change the polarity of the power supply of the tested power source.

The closest technical solution to the claimed object is a device for monitoring VIP (see RF patent No. 2127015, IPC 6 Н02Н 3/24, G01R 19/165, publ. 02/27/1999, application No. 96124036/09 of 12.20.1996 g for the invention “Device for controlling a secondary power source”, patent holder of the Open Joint-Stock Company “Russian Railways”). The known device contains the first and second power sources connected to the supply voltage buses, a load connected in parallel with the output of the second power source, a comparator, the input of which is connected to the input of the first power source, the first threshold element, the output of which is connected to the input of the first Executive unit, the comparator is powered from the first power source, the AND element, the second actuating unit and the OR element, the output of which is the output of the device, are connected in series The first and second power supplies are connected to the inputs of the first and second threshold elements, the output of the second threshold element is connected to another input of the AND element, and the output of the first actuating unit is connected to the first input of the OR element, while the second threshold element and AND element are powered from the first power source, and the first threshold element is powered from the second power source.

Signs of the closest analogue, coinciding with the signs of the proposed technical solution: the first and second actuating units (their functions are performed by the MC), the load.

The reasons that impede the achievement of the claimed technical result are: the lack of the ability to display currents and voltages at the outputs of the tested product, the inability to change the polarity of the power supply of the tested power source.

The problem to which the claimed technical solution is directed is to increase the speed and expand the functionality of the device.

The technical result provided by the implementation of the proposed technical solution is to reduce the time of monitoring, debugging and testing due to the simultaneous monitoring and indication of voltages and currents through two channels of the tested power source and expanding the functionality of the device by providing the possibility of inverting the polarity of power of the tested product, and is achieved the fact that the load block containing voltage and load converters includes: current and voltage indicators MVIP, indicator load state tori, a microcontroller, a generator, a polarity inverter, a pairing circuit, a load commutator, control buttons, and MVIP current and voltage indicators and load status indicators with their inputs, and control buttons of their outputs connected to the first and second outputs and the first MK input, which, respectively, is connected to a generator by its second input, and a polarity inverter by a third output. The third input of the MC is connected to the output of the linear voltage converter. The linear voltage converter with its input is connected to the output of the voltage converter, the input of which is connected to the power source and the second input of the polarity inverter, as well as to the input of the linear voltage converter. The fourth input of the MC is connected to the output of the linear voltage converter and to the first input of the interface circuit, the output of which is connected to the fifth input of the MK. The fourth output of the MC is connected to the first input of the load switch, the outputs of which are connected to the inputs of the loads, the outputs of which are connected to power sources and the second and third inputs of the interface circuit.

The essence of the utility model is illustrated by the drawings, in which Fig. 1 shows an example of the implementation of the load block at the structural level, Fig. 2 - an example of the implementation at the level of the electrical circuit diagram, in which the groups of electric radio products (hereinafter - ERI) corresponding to the nodes of the load block shown on figure 1. In Fig. 1 and Fig. 2, the following designations are adopted: 1 - indicators of currents and voltages of MVIP, 2 - indicators of the state of loads, 3 - control buttons, 4 - MK, 5 - generator, 6 - polarity inverter, 7 - second voltage converter 7 V at 5 V, 8 - the first voltage converter 24 V to 7 V, 9 - the third voltage converter 7 V to 5 V, 10 - interface circuit, 11 - switch loads, 12 - loads.

In figure 1 and figure 2, the nodes and blocks of the device are interconnected as follows.

Indicators of currents and voltages MVIP 1 and indicators of the state of loads 2 with their inputs, and control buttons 3 with their outputs, are connected to the first and second outputs and the first input of MK 4, which, respectively, is connected with its second input to the generator 5, and the third output to the polarity inverter 6. The third input MK 4 is connected to the output of the linear voltage converter 7. The linear voltage converter 7 is connected by its input to the output of the pulse voltage converter 8, the input of which is connected to the power source and the second input polarity inverter 6, as well as with the input of the linear voltage converter 9. The fourth input of MK 4 is connected to the output of the linear voltage converter 9 and with the first input of the interface circuit 10, the output of which is connected to the fifth input of MK 4. The fourth output of MK 4 is connected to the input of the switch loads 11, the outputs of which are connected to the inputs of the loads 12, the outputs of which are connected to power sources and to the second and third inputs of the interface circuit 10.

The device operates as follows.

The converter 8 of the voltage 24 V to 7 V pulse type, made on the basis of the chip DA4 type LM2675M-ADJ / NOPB (see figure 2), converts the primary supply voltage of 24 V into an intermediate value of 7 V, supplied to the second and third voltage converters 7 V to 5 V, for example, of linear type. Linear converters 7, 9 of voltage 7 V to 5 V, made on the basis of microcircuits, the conversion of intermediate voltage 7 V to voltage 5 V, necessary to power the internal circuits of the load block. One of the voltages is used to power digital circuits, and the second is used for analog circuits of the load block. The polarity inverter 6 is made on the basis of relay K1 of type O-1462037-9 (see figure 2) and is designed to implement the function of generating an inverse supply voltage of the tested MVIP and is controlled by MK 4. Loads 12 include a set of resistors (R11, R12, R16 , R17, R19-R24) of various ratings, for example, 2.7 Ohms (R11, R16, R19, R21), 100 Ohms (R17, R22), 300 Ohms (R12, R20, R24) and 3.9 Ohms (R23 ) (see figure 2, position 12), which can alternately connect to the outputs of the tested MVIP using the load switch 11, forming 4 loads from the calculation of 2 loads on each of the two channels and ensuring that load ki from 0 to 1 A. The load switch 11 includes a set of field effect transistors VT4-VT7 type IRF7413A and VT8-VT9 type IRL3705N (see figure 2) and is controlled by MK 4 (see above). The interface circuit 10 is based on a DA5 type AD8608AR chip (see FIG. 2) and is designed to match the output voltage levels of the tested MVIP with the input signal range of the analog-to-digital converter MK 4. Current and voltage indicators MVIP 1 include a set of transistors VT11- VT18 type IRLML6402 and VT19-VT30 type IRLML2402 (see figure 2), are based on built-in seven-segment LED indicators of type SA05-11SRWA. Indicators of currents and voltages of MVIP 1 and state of loads 2 are intended for visual display of values of currents and voltages at the outputs of the tested MVIP. The load condition indicators 2 are made on single VD3-VD11 LEDs of the L934ID type and are intended for visual monitoring of the load connected to the output of the tested MVIP. The control buttons 3 are made on buttons of the type TS-A4PS-130 (see Fig. 2), designed to generate commands for connecting various loads to the outputs of the tested MVIP and commands for generating the inversion of polarity. The generator 5 is made on the basis of the DD1 chip type SG-8002JF4M-PHM (see figure 2), is designed to generate the clock pulses necessary for the operation of MK 4. MK 4 is made on the basis of the DD2 chip type MB90F497GPFM (see figure 2), It is intended for storage and execution of a control program. MK 4 provides the collection of information from the control buttons 3, the calculation of the values of the output currents and voltages of the MVIP, the display of information on indicators 1 and 2, the management of the load switch circuits 11 and the inverter polarity 6.

To the power inputs of 5 V and 9 V, the MVIP is connected, which is subject to verification.

The first MK4 output is intended for generating control signals of the current and voltage indicators MVIP 1. The second MK 4 output is for generating control signals of the load status indicators 2. The first MK 4 input is for inputting the status signals of the control buttons 3. The second MK 4 input is for connecting a signal generator 5. The fourth output of MK 4 5V-1, 5V-2, 9V-1, 9V-2 is designed to generate control signals of the switch loads 11 to the gates of transistors VT4, VT5, VT6, VT7, respectively (figure 2, item 11.1) first exit comm load tator 11 is used to switch loads 12 in the 5 V channel, the second output of load switch 11 (9V_VIP) is used to switch loads 12 in the 9 V channel (see Fig. 2, pos. 11.2), the first input of loads 12 (5V_1) is intended for connecting / disconnecting the resistance of the loads 12 to the circuit of the 5 V channel (with the output of the transistor VT4 to the circuit of resistors R21 and R16 and with the output of VT5 to the resistors R17 and R22), the second input of the loads 12 (9V_1) is designed to connect / disconnect the resistance of the loads of 12 to the circuit channel 9 V, the third input of loads 12 (9V_VIP) is designed to connect The output 9 of the test MVIP (9V in 9V_VIP), the fourth input loads 12 (5V_VIP) for connecting the output of the test MVIP 5V (5V in 5V_VIP). The fifth input of MK 4 is designed to input analog signals coming from the outputs of the interface circuit 10, the first input of the interface circuit 10 is used to connect the 5 V power needed to power the elements of the interface circuit 10, the second input of the interface circuit 10 is designed to input voltages and currents from loads channel 9 V, the third input of the interface circuit 10 is designed to input voltages and currents from the loads of the channel 5 V. The third input MK 4 is designed to connect 5 V power to the digital part of the microcontroller 4. The fourth input is designed to power supply of the built-in ADC MK4. The third output MK 4 is designed to generate a control signal of the inverter polarity 6, the input of the inverter polarity 6 is used to connect an external power source (18-30V), the output of the inverter polarity 6 is designed to supply voltage to the tested MVIP.

Claims (4)

1. The load block, containing voltage and load converters, characterized in that it includes indicators of currents and voltages of the secondary power supply module, indicators of the state of loads, control buttons, microcontroller, generator, polarity inverter, interface circuit, load switch, and current indicators and voltages and indicators of the state of loads with their inputs, and control buttons for their outputs are connected to the first and second outputs and the first input of the microcontroller, which is connected with its second input n with a generator, and the third output with a polarity inverter, the input of which is connected to the power bus and the input of the first voltage converter, the output of which is connected to the inputs of the second and third voltage converters, and the outputs of the second and third voltage converters are connected respectively to the third and fourth inputs of the microcontroller , the output of the third voltage converter is connected to the input of the interface circuit, the two inputs of which are connected to the outputs of the tested product, and the output is connected to the input of the microcontrol a unit, the output of which is connected to the input of the load switch, the outputs of which are connected to the inputs of the loads. 2. The load block according to claim 1, characterized in that the pulse voltage converter from 24 V to 7 V is used as the first voltage converter. 3. The load block according to claim 1, characterized in that linear voltage converters from 7 V to 5 V are used as the second and third voltage converters. 4. The load block according to claim 1, characterized in that a clock generator is used as a generator.