JP6335404B1 - Power supply inspection device for relay - Google Patents

Abstract

An object of the present invention is to improve the possibility of finding a power supply device for a relay that may cause the relay to malfunction. A relay power supply inspection device includes a power terminal, a range determination unit, an operation determination relay, a relay connection circuit, a multiple condition determination unit, and a determination result output unit. Is provided. The range determination unit 28 is connected to the power supply terminal 20. The range determination unit 28 determines whether or not the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range. When the current flowing from the relay power supply device 12 passes through the operation determination relay, the relay connection circuit 26 can conduct the current. The multiple-type condition determination unit 30 determines whether or not the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range and the relay connection circuit 26 can be conducted. The determination result output unit 32 outputs information indicating the determination result of the multiple-type condition determination unit 30. [Selection] Figure 1

Description

  The present invention relates to a power supply inspection device for a relay.

  Patent Document 1 discloses a power supply monitoring circuit. The power supply monitoring circuit includes a voltage comparator, a pair of resistance elements, and a constant voltage source. The pair of resistance elements are connected in series between the power source and the place grounded. The voltage between the power supply potential and the ground potential is divided by the resistance ratio of each resistance element. The potential extracted from between the resistance elements is supplied to the voltage comparator as a monitoring potential. The constant voltage source is constituted by a known constant voltage circuit and generates a potential described below. The potential is a potential that always maintains a constant potential difference with respect to the ground potential regardless of fluctuations in the power supply potential. This potential is supplied to the voltage comparator as a reference potential. This power supply monitoring circuit is used to monitor the power supply voltage of the computer.

  The power supply monitoring circuit disclosed in Patent Document 1 detects a decrease in power supply potential. As a result, the circuit operation of the computer can be stopped before the power supply potential drops to such an extent that data cannot be correctly determined. As a result, a computer including a power monitoring circuit can be less likely to malfunction than a computer not including a power monitoring circuit.

  It is not only computers that are prone to malfunction when the power supply potential is lowered. The relay is also likely to malfunction when the power supply potential is lowered. When the power supply monitoring circuit disclosed in Patent Document 1 is connected to the relay power supply device, a relay power supply device in which the relay may malfunction may be found.

JP 2000-88896 A

  However, the power supply monitoring circuit disclosed in Patent Document 1 has a problem that it is insufficient for finding a relay power supply device in which the relay may malfunction.

  The present invention solves such problems. An object of the present invention is to provide a relay power supply inspection device that improves the possibility of finding a relay power supply device in which the relay may malfunction.

  The relay power supply inspection device of the present invention will be described with reference to the drawings. Note that the use of the reference numerals in the figure in this column is intended to assist understanding of the contents of the invention, and is not intended to limit the contents to the illustrated range.

  In order to solve the above-described problems, according to an aspect of the present invention, the relay power supply inspection device 10 includes a power supply terminal 20 and a range determination unit 28. The power supply terminal 20 is a terminal to which the relay power supply device 12 is connected. The relay power supply device 12 is used to supply power to the relay. The range determination unit 28 is connected to the power supply terminal 20. The range determination unit 28 determines whether or not the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range. The relay power inspection apparatus 10 further includes an operation determination relay 70, a relay connection circuit 26, a multiple-type condition determination unit 30, and a determination result output unit 32. The operation determination relay 70 is connected to the power supply terminal 20. The operation determination relay 70 passes the current flowing from the relay power supply device 12. The relay connection circuit 26 is connected to the operation determination relay 70. In the relay connection circuit 26, when the current flowing from the relay power supply device 12 passes through the operation determination relay 70, the current can be conducted. The multiple-type condition determination unit 30 determines whether or not the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range and the relay connection circuit 26 can be conducted. The multiple-type condition determination unit 30 is connected to the range determination unit 28 and the relay connection circuit 26. The determination result output unit 32 outputs information indicating the determination result of the multiple-type condition determination unit 30.

  When a current flows from the relay power supply device 12 to the operation determination relay 70, the relay connection circuit 26 becomes conductive. The multiple-type condition determination unit 30 determines whether or not the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range and the relay connection circuit 26 can be conducted. Thereby, not only whether or not the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range, but also the relay is connected to the relay power supply device 12 and connected to the relay from the relay power supply device 12. When power is supplied, it is determined whether or not the device operates correctly. As a result, the possibility that the relay power supply device 12 in which the relay may malfunction may be found.

  Further, the range determination unit 28 described above includes an upper limit power supply unit 82, a voltage upper limit determination element 120, a lower limit power supply unit 86, a voltage lower limit determination element 126, and a voltage condition determination element 134. Is desirable. The upper limit power supply unit 82 supplies power whose ground voltage is an upper limit value within a predetermined range. The voltage upper limit determination element 120 is connected to the upper limit power supply unit 82 and the power supply terminal 20. The voltage upper limit determining element 120 determines whether or not the ground voltage of the power supplied by the upper limit power supply unit 82 is higher than the ground voltage of the current flowing from the relay power supply device 12 via the power terminal 20. The lower limit power supply unit 86 supplies power whose ground voltage is a lower limit value within a predetermined range. The voltage lower limit determination element 126 is connected to the lower limit power supply unit 86 and the power supply terminal 20. The voltage lower limit determination element 126 determines whether or not the ground voltage of the power supplied by the lower limit power supply unit 86 is lower than the ground voltage of the current flowing from the relay power supply device 12 via the power terminal 20. The voltage condition determination element 134 determines whether or not two requirements described below are both satisfied. The first requirement is that the ground voltage of the power supplied by the upper limit power supply unit 82 is higher than the ground voltage of the current flowing from the relay power supply device 12 via the power terminal 20. The second requirement is that the ground voltage of the power supplied by the lower limit power supply unit 86 is lower than the ground voltage of the current flowing from the relay power supply device 12 via the power terminal 20. Voltage condition determination element 134 is connected to voltage upper limit determination element 120 and voltage lower limit determination element 126.

  The range determination unit 28 includes an upper limit power supply unit 82, a voltage upper limit determination element 120, a lower limit power supply unit 86, a voltage lower limit determination element 126, and a voltage condition determination element 134. Thereby, the range determination unit 28 does not simply determine whether or not the voltage of the relay power supply device 12 falls below a predetermined lower limit value, but the current flowing from the relay power supply device 12 via the power supply terminal 20 is not determined. It can be determined whether the ground voltage is between a predetermined upper limit value and a lower limit value.

  Alternatively, the upper limit power supply unit 82 described above preferably includes an excess power supply unit 90 and an upper limit side step-down unit 92. The excess power supply unit 90 supplies power whose ground voltage exceeds the upper limit value in a predetermined range. The upper limit voltage step-down unit 92 is connected to the excess power supply unit 90. The upper limit side step-down unit 92 steps down the ground voltage of the power supplied by the excess power supply unit 90 to an upper limit value within a predetermined range.

  The upper limit power supply unit 82 includes an excess power supply unit 90 and an upper limit side step-down unit 92. The upper limit voltage step-down unit 92 steps down the power supplied by the excess power supply unit 90. Once power with a high ground voltage is supplied and the voltage is lowered, it is possible to prevent a shortage of power in the range determination unit 28 due to energy loss caused by transformation.

  The relay power supply inspection device according to the present invention improves the possibility of finding a relay power supply device that may cause a malfunction of the relay.

It is a conceptual diagram by which the structure of the power supply inspection apparatus for relays concerning one Embodiment of this invention is shown. It is a conceptual diagram by which the structure of the power consumption part and operation | movement judgment part concerning one Embodiment of this invention is shown. It is a conceptual diagram by which the one part structure of the range judgment part concerning one Embodiment of this invention is shown. It is a conceptual diagram which shows the structure of the remaining part of the range judgment part concerning one Embodiment of this invention, a relay connection electric circuit, and multiple types of condition judgment part.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

[Description of configuration]
Hereinafter, an embodiment of the present invention will be described. FIG. 1 is a conceptual diagram showing a configuration of a relay power supply inspection apparatus 10 according to the present embodiment. Based on FIG. 1, the structure of the power inspection apparatus 10 for relays concerning this embodiment is demonstrated.

  The relay power supply inspection device 10 according to the present embodiment is a device for inspecting the relay power supply device 12. The relay power supply device 12 is used to supply power to a relay (not shown). The relay power supply inspection device 10 according to the present embodiment includes a power supply terminal 20, a power consuming unit 22, an operation determining unit 24, a relay connecting circuit 26, a range determining unit 28, and a plurality of condition determining unit 30. The determination result output terminal 32, the first grounding electrode 34, and the second grounding electrode 36 are provided.

  The power supply terminal 20 is a terminal to which the relay power supply device 12 is connected. The power consumption unit 22 is connected between the power supply terminal 20 and the range determination unit 28. A part of the current flowing from the relay power supply device 12 to the range determination unit 28 is branched by the power consumption unit 22. The power consuming unit 22 consumes power due to the branched current.

  The operation determination unit 24 determines whether or not a relay (current relay that the relay power supply device 12 is scheduled to supply power) whose current flowing from the relay power supply device 12 is not illustrated can be operated. The relay connection circuit 26 is connected to the operation determination unit 24.

  The range determination unit 28 is connected to the power supply terminal 20 via the power consumption unit 22. The range determination unit 28 determines whether the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range. The specific contents of this determination in this embodiment will be described later.

  The multiple-type condition determination unit 30 is connected to the relay connection electric circuit 26 and the range determination unit 28. The multiple-type condition determination unit 30 determines whether or not the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range and the relay connection circuit 26 can be conducted. The determination result output terminal 32 outputs the signal.

  The first grounding electrode 34 and the second grounding electrode 36 ground a predetermined portion of the relay power supply inspection device 10 according to the present embodiment. It will be described later which part of the relay power supply inspection device 10 is grounded in the present embodiment.

  FIG. 2 is a conceptual diagram showing the configuration of the power consuming unit 22 and the operation determining unit 24 according to the present embodiment. Based on FIG. 2, the structure of the power consumption part 22 and the operation | movement judgment part 24 concerning this embodiment is demonstrated.

  The power consumption unit 22 according to the present embodiment includes a first resistor 50, a second resistor 52, and a third resistor 54.

  One end of the first resistor 50 is connected to an electric wire branched from the electric wire connecting the power supply terminal 20 and the range determination unit 28. The other end of the first resistor 50 is connected to the first ground electrode 34.

  One end of the second resistor 52 is connected to an electric wire branched from the electric wire connecting the power supply terminal 20 and the range determination unit 28. The other end of the second resistor 52 is connected to the first ground electrode 34. The second resistor 52 is connected in parallel with the first resistor 50.

  One end of the third resistor 54 is connected to an electric wire branched from the electric wire connecting the power supply terminal 20 and the range determination unit 28. The other end of the third resistor 54 is connected to the first ground electrode 34. The third resistor 54 is connected in parallel with the first resistor 50 and the second resistor 52.

  The first resistor 50, the second resistor 52, and the third resistor 54 consume part of the power supplied from the relay power supply device 12 to the range determination unit 28. In this way, the range determination unit 28 is made to determine whether or not the ground voltage of the current flowing from the relay power supply device 12 under load is within a predetermined range.

  The operation determination unit 24 according to the present embodiment includes an operation determination relay 70 and an operation determination rectifier element 72.

  One of the terminals of the operation determination relay 70 is connected to an electric wire branched from the electric wire connecting the power supply terminal 20 and the range determination unit 28. The other terminal of the operation determination relay 70 is connected to the first ground electrode 34. As a result, part of the current flowing from the relay power supply device 12 passes through the operation determination relay 70. The operation determination relay 70 is connected in parallel to the first resistor 50, the second resistor 52, and the third resistor 54. The other two terminals of the operation determination relay 70 are connected to the relay connection circuit 26 and the range determination unit 28.

  In the case of the present embodiment, when the following three requirements are satisfied, the operation determination relay 70 closes the relay connection circuit 26. The first of the three requirements is a requirement that the current flowing from the power supply terminal 20 flows in a predetermined direction. The second requirement is a requirement that the current value of the current is a current value that can operate the operation determination relay 70. The third requirement is that the voltage value of the current is a voltage value that can operate the operation determination relay 70. When the operation determination relay 70 closes the relay connection circuit 26, the relay connection circuit 26 becomes conductive. Accordingly, the operation determination relay 70 generates an electrical signal indicating “true” and outputs this signal to the relay connection circuit 26.

  The operation determination rectifier 72 adjusts the direction of the current flowing through the operation determination relay 70. The operation determining rectifying element 72 according to the present embodiment is realized by, for example, a known rectifying diode.

  FIG. 3 is a conceptual diagram illustrating a partial configuration of the range determination unit 28 according to the present embodiment. Based on FIG. 3, a partial configuration of the range determination unit 28 according to the present embodiment will be described.

  The range determination unit 28 according to the present embodiment includes a drive power supply terminal 80, an upper limit power supply unit 82, a signal generation unit converter 84, and a lower limit power supply unit 86.

  The drive power supply terminal 80 is connected to a power supply (not shown). This power supply supplies power for driving the range determination unit 28.

  The upper limit power supply unit 82 is connected to the drive power supply terminal 80. The upper limit power supply unit 82 supplies power whose ground voltage is an upper limit value within a predetermined range. A specific configuration of the upper limit power supply unit 82 will be described later.

  The signal generator converter 84 is connected to the drive power supply terminal 80 and grounded by the first ground electrode 34. The signal generation unit converter 84 converts the voltage of the power supplied from the drive power supply terminal 80 into a predetermined voltage. In the present embodiment, the signal generation unit converter 84 steps down the power supplied from the drive power supply terminal 80.

  The lower limit power supply unit 86 is connected to the drive power supply terminal 80 and grounded by the first ground electrode 34. In the case of the present embodiment, the lower limit power supply unit 86 sequentially steps down the power supplied from the drive power supply terminal 80 using two known resistors. Thereby, the lower limit power supply unit 86 according to the present embodiment constitutes a kind of voltage divider. By appropriately selecting the resistance value of each resistor constituting the lower limit power supply unit 86 in advance, the lower limit power supply unit 86 supplies power whose ground voltage is the lower limit value of the “predetermined range” described above. Can supply.

  The upper limit power supply unit 82 includes an excess power supply converter 90 and an upper limit side step-down unit 92.

  The excess power supply converter 90 is grounded by the second ground electrode 36. The excess power supply converter 90 converts the ground voltage of the power supplied from the drive power supply terminal 80 into a predetermined ground voltage. In the present embodiment, the excess power supply converter 90 boosts the power supplied from the drive power supply terminal 80.

  The upper limit voltage step-down unit 92 is connected to the excess power supply converter 90 and is grounded by the first ground electrode 34. The upper limit voltage step-down unit 92 sequentially steps down the voltage boosted by the excess power supply converter 90 using four known resistors. As a result, the upper limit side step-down unit 92 according to the present embodiment constitutes a kind of voltage divider. By appropriately selecting the resistance values of the individual resistors constituting the upper limit side step-down unit 92 in advance, the upper limit side step-down unit 92 is able to supply power whose ground voltage is the upper limit value of the “predetermined range” described above. Can supply. As is clear from these descriptions, in the upper limit power supply unit 82 according to the present embodiment, the ground voltage is an upper limit value within a predetermined range by the step-up by the excess power supply converter 90 and the step-down by the upper-end side step-down unit 92. Is supplying power. Thereby, compared with the case where the voltage of the power supplied from the drive power supply terminal 80 is directly boosted so as to be equal to the upper limit value of the power ground voltage supplied by the relay power supply device 12, the ground voltage can be set with higher accuracy. It becomes possible.

  In the present embodiment, the excess power supply converter 90 and the signal generation unit converter 84 are realized by a known converter. Therefore, detailed description thereof will not be repeated here. In the present embodiment, the upper limit voltage step-down unit 92 is realized by a known resistor connected in series. Therefore, detailed description thereof will not be repeated here.

  FIG. 4 is a conceptual diagram showing the configuration of the remaining part of the range determination unit 28 according to the present embodiment, the relay connection electric circuit 26, and the multiple types of condition determination unit 30. Based on FIG. 4, the structure of the remaining part of the range determination part 28 concerning this embodiment, the relay connection electric circuit 26, and the multiple types condition determination part 30 is demonstrated.

  The range determination unit 28 according to the present embodiment includes the following elements in addition to the drive power supply terminal 80, the upper limit power supply unit 82, the signal generation unit converter 84, and the lower limit power supply unit 86. ing. These elements include a voltage upper limit determination comparator 120, an upper limit side signal step-down resistor 122, a voltage upper limit determination photocoupler 124, a voltage lower limit determination comparator 126, a lower limit side signal step-down resistor 128, A voltage lower limit determining photocoupler 130, an upper limit potential side photocoupler step-down resistor 132, a voltage condition determining AND circuit 134, and a ground voltage side grounding step-down resistor 136.

  The voltage upper limit comparator 120 is a ground voltage at a location in the middle of the upper limit voltage step-down unit 92 (in this embodiment, the ground voltage at this location is the upper limit value of the “predetermined range” described above). And the ground voltage in the section from the power supply terminal 20 to the voltage upper limit determination comparator 120 is compared. The voltage upper limit comparator 120 outputs a signal corresponding to the comparison result. In the case of this embodiment, the voltage upper limit comparator 120 is configured such that the ground voltage at the above-described portion of the upper limit voltage step-down unit 92 is equal to or higher than the ground voltage in the section from the power supply terminal 20 to the voltage upper limit comparator 120. For example, a signal indicating “true” is output. In the case of this embodiment, the voltage upper limit comparator 120 is configured such that the ground voltage at the above-described portion of the upper limit voltage step-down unit 92 is less than the ground voltage in the section from the power supply terminal 20 to the voltage upper limit comparator 120. For example, a signal indicating “false” is output.

  The upper limit side signal step-down resistor 122 reduces the ground voltage of the signal output from the voltage upper limit determination comparator 120 with respect to the first ground electrode 34.

  The voltage upper limit determination photocoupler 124 changes the electrical signal output from the voltage upper limit determination comparator 120 into an optical signal and further converts it into an electrical signal. In the present embodiment, if the electrical signal output from the voltage upper limit comparator 120 is a signal indicating “true”, the voltage upper limit determination photocoupler 124 outputs an electrical signal indicating “true”. In the present embodiment, if the electrical signal output from the voltage upper limit comparator 120 is a signal indicating “false”, the voltage upper limit photocoupler 124 outputs an electrical signal indicating “false”.

  The voltage lower limit judgment comparator 126 is configured such that the ground voltage in the section from the power supply terminal 20 to the voltage lower limit judgment comparator 126 and the ground voltage in the middle of the lower limit power supply unit 86 (in this embodiment, this place The ground voltage is a lower limit value of the “predetermined range” described above). The voltage lower limit comparator 126 outputs a signal corresponding to the comparison result. In the case of the present embodiment, the voltage lower limit judgment comparator 126 is such that the ground voltage at a location in the middle of the lower limit power supply unit 86 is equal to or lower than the ground voltage in the section from the power supply terminal 20 to the voltage lower limit judgment comparator 126. , A signal indicating “true” is output. In the case of this embodiment, the voltage lower limit determination comparator 126 is configured such that the ground voltage at a position in the middle of the lower limit power supply unit 86 exceeds the ground voltage in the section from the power supply terminal 20 to the voltage lower limit determination comparator 126. For example, a signal indicating “false” is output.

  The lower limit side signal step-down resistor 128 decreases the ground voltage of the signal output from the voltage lower limit determination comparator 126 with respect to the first ground electrode 34.

  The voltage lower limit determination photocoupler 130 changes the electrical signal output from the voltage lower limit determination comparator 126 into an optical signal, and further converts it into an electrical signal. In the present embodiment, if the electrical signal output by the voltage lower limit determination comparator 126 is a signal indicating “true”, the voltage lower limit determination photocoupler 130 outputs an electrical signal indicating “true”. In the case of this embodiment, if the electrical signal output from the voltage lower limit determination comparator 126 is a signal indicating “false”, the voltage lower limit determination photocoupler 130 outputs an electrical signal indicating “false”.

  The upper limit potential side photocoupler step-down resistor 132 sets a voltage between the voltage upper limit determination photocoupler 124 and the first ground electrode 34.

  In the case of the present embodiment, the voltage condition determining AND circuit 134 is “true” when both the signal output from the voltage upper limit determining photocoupler 124 and the signal output from the voltage lower limit determining photocoupler 130 are “true”. A signal indicating “true” is output. In the present embodiment, the AND circuit 134 for determining the voltage condition determines that at least one of the signal output from the voltage upper limit determination photocoupler 124 and the signal output from the voltage lower limit determination photocoupler 130 is “false”. For example, a signal indicating “false” is output.

  The ground voltage side ground step-down resistor 136 sets a voltage between the voltage lower limit determination photocoupler 130, the voltage condition determination logical product circuit 134 and the first ground electrode 34.

  Based on FIG. 4, the structure of the relay connection electric circuit 26 concerning this embodiment is demonstrated. One end of the relay connection circuit 26 according to the present embodiment is connected to the operation determination relay 70 and is installed on the first ground electrode 34. The relay connection circuit 26 according to this embodiment includes an operation determining step-down resistor 150. The operation determining step-down resistor 150 lowers the voltage of the signal output from the operation determining relay 70. The operation determining step-down resistor 150 is a known resistor.

  Based on FIG. 4, the configuration of the multiple-type condition determination unit 30 according to the present embodiment will be described. The multiple-type condition determination unit 30 according to the present embodiment includes a continuity determination signal generation photocoupler 170, an operation determination setting resistor 172, a multiple-type condition determination logical product circuit 174, and a test result determination step-down resistor. 176 and a result signal generating photocoupler 178.

  The continuity determination signal generating photocoupler 170 temporarily converts the electrical signal output from the operation determination relay 70 into an optical signal and further into an electrical signal. In the present embodiment, if the electrical signal output from the operation determination relay 70 is a signal indicating “true”, the continuity determination signal generating photocoupler 170 outputs an electrical signal indicating “true”. In the case of this embodiment, unless the electrical signal output from the operation determination relay 70 is a signal indicating “true”, the continuity determination signal generation photocoupler 170 does not output a signal.

  The operation determination setting resistor 172 sets a voltage between the continuity determination signal generating photocoupler 170, the multiple condition determination AND circuit 174, and the first ground electrode 34.

  In the case of this embodiment, the multi-condition determining AND circuit 174 indicates that both the signal output from the voltage condition determining AND circuit 134 and the signal output from the continuity determining signal generating photocoupler 170 are “true”. If so, a signal indicating "true" is output. In the case of the present embodiment, the multiple condition determination logical product circuit 174 indicates that at least one of the signal output from the voltage condition determination logical product circuit 134 and the signal output from the continuity determination signal generation photocoupler 170 is “true”. If “” is not indicated, a signal indicating “false” is output.

  The test result judgment step-down resistor 176 lowers the ground voltage of the signal output from the multiple-type condition judgment logical product circuit 174 with respect to the first ground electrode 34.

  The result signal generating photocoupler 178 temporarily changes the electrical signal output from the multiple condition judgment logical product circuit 174 into an optical signal, and further converts it into an electrical signal. In the case of the present embodiment, the result signal generating photocoupler 178 outputs a signal indicating “true” if the signal output from the multiple condition determining AND circuit 174 indicates “true”. In the case of the present embodiment, the result signal generating photocoupler 178 outputs a signal indicating “false” if the signal output from the multiple condition determining AND circuit 174 indicates “false”.

  An upper limit side signal step-down resistor 122, a lower limit side signal step-down resistor 128, an upper limit potential side photocoupler step-down resistor 132, a ground voltage side ground step-down resistor 136, an operation determination setting resistor 172, The test result judgment step-down resistor 176 is constituted by a known resistor. These resistors have different resistance values. This allows these resistors to provide a voltage depending on where they are located. By providing a voltage, these serve to set the ground voltage of the wiring connected to one end thereof to a predetermined value. Since the configuration of these resistors themselves is well known, detailed description thereof will not be repeated.

  The voltage upper limit determination photocoupler 124, the voltage lower limit determination photocoupler 130, the continuity determination signal generation photocoupler 170, and the result signal generation photocoupler 178 are configured by well-known photocouplers. These photocouplers transmit signals from the input side to the output side while electrically insulating the input side and the output side. Since the configurations of these photocouplers themselves are well known, detailed description thereof will not be repeated.

  The voltage upper limit determination comparator 120 and the voltage lower limit determination comparator 126 are configured by known comparators. The voltage condition determining logical product circuit 134 and the multiple-type condition determining logical product circuit 174 are configured by well-known logical product circuits. Since the structures of these comparators and logical product circuits are well known, detailed description thereof will not be repeated.

[Description of operation]
Based on FIG. 1 thru | or FIG. 4, operation | movement of the power supply test | inspection apparatus 10 for relays concerning this embodiment is demonstrated.

(When a normal relay power supply is connected)
First, the operator supplies power to the excess power supply converter 90, the signal generation unit converter 84, and the lower limit power supply unit 86 via the drive power supply terminal 80. The excess power supply converter 90 and the signal generation unit converter 84 of the upper limit power supply unit 82 convert the ground voltage of the supplied power into different predetermined voltages. The power whose voltage has been converted by the excess power supply converter 90 is supplied to the upper limit voltage step-down unit 92. The upper limit voltage step-down unit 92 sets a voltage between the excess power supply converter 90 and the voltage upper limit determination comparator 120. The power whose voltage has been converted by the signal generation unit converter 84 is supplied to the voltage upper limit determination photocoupler 124, the voltage lower limit determination photocoupler 130, and the continuity determination signal generation photocoupler 170. When power is supplied via the drive power supply terminal 80, the lower limit power supply unit 86 sets a voltage between the drive power supply terminal 80 and the voltage lower limit determination comparator 126.

  Next, the worker connects the relay power supply device 12 to be inspected to the power supply terminal 20. Next, the worker supplies power from the relay power supply device 12 to the relay power supply inspection device 10 according to the present embodiment via the power supply terminal 20. The power supplied from the relay power supply device 12 is supplied to the range determination unit 28 via the power supply terminal 20 and the power consumption unit 22. On the way, a part of the power is supplied to the first resistor 50, the second resistor 52, and the third resistor 54 of the power consuming unit 22. The electric power supplied to the first resistor 50, the second resistor 52, and the third resistor 54 is consumed as heat. Further, a part of the power different from that supplied to the power consumption unit 22 is supplied to the operation determination relay 70. The electric power supplied to the operation determination relay 70 operates it. As a result, the relay connection circuit 26 can be conducted. Along with this, a signal indicating “true” is input to the photocoupler 170 for generating the continuity determination signal. Of the power supplied from the power supply device 12 for the relay, the remaining power except for the power supplied to the first resistor 50, the second resistor 52, the third resistor 54, and the operation determination relay 70 is the voltage upper limit. The voltage is supplied to the determination comparator 120 and the voltage lower limit determination comparator 126.

  The voltage upper limit comparator 120 outputs signals according to the levels of these voltages. In this case, since the normal relay power supply device 12 is connected, the voltage upper limit comparator 120 outputs a signal indicating “true”. The signal is input to the voltage upper limit determination photocoupler 124. When the signal is input, the voltage upper limit determination photocoupler 124 outputs a signal indicating “true”. The signal output from the voltage upper limit determination photocoupler 124 is input to the voltage condition determination logical product circuit 134.

  In parallel with this, the voltage lower limit judgment comparator 126 includes a ground voltage in a section from the power supply terminal 20 to the voltage lower limit judgment comparator 126 and a ground voltage in the middle of the lower limit power supply unit 86 (“predetermined range”). ) Is supplied. The voltage lower limit comparator 126 outputs a signal corresponding to the level of these voltages. In this case, since the normal relay power supply device 12 is connected, the voltage lower limit determination comparator 126 outputs a signal indicating “true”. The signal is input to the voltage lower limit determination photocoupler 130. When the signal is input, the voltage lower limit determination photocoupler 130 outputs a signal indicating “true”. The signal output from the voltage lower limit determining photocoupler 130 is also input to the voltage condition determining AND circuit 134. In this case, both the signal output from the voltage upper limit determination photocoupler 124 and the signal output from the voltage lower limit determination photocoupler 130 are signals indicating “true”. As a result, the voltage condition determining AND circuit 134 outputs a signal indicating “true”. The signal is input to the AND circuit 174 for determining multiple types of conditions.

  In parallel with the operations of the voltage upper limit judgment comparator 120 and the voltage lower limit judgment comparator 126, as described above, a signal indicating “true” is input to the continuity determination signal generation photocoupler 170. When a signal indicating “true” is input, the continuity determination signal generating photocoupler 170 outputs a signal indicating “true”. The signal output from the continuity determination signal generation photocoupler 170 is input to the multiple condition determination logical product circuit 174.

  The signal output from the voltage condition determining AND circuit 134 and the signal output from the continuity determining signal generating photocoupler 170 are input to the multiple-type condition determining AND circuit 174. Both of these signals are signals indicating “true”. As a result, the multiple-condition determining AND circuit 174 outputs a signal indicating “true”. The signal is input to the result signal generating photocoupler 178 via the test result determining step-down resistor 176. The result signal generating photocoupler 178 outputs a signal indicating “true”. The signal is output to the outside of the relay power supply inspection apparatus 10 according to the present embodiment via the determination result output terminal 32. In the signal, the voltage of the power supplied from the relay power supply device 12 is between a predetermined upper limit value and lower limit value, and the operation determination relay 70 is determined by the power supplied from the relay power supply device 12. Indicates that it works properly.

(When a power supply device for a relay with a small amount of power that can be supplied when multiple relays are connected is connected)
First, the operator supplies power to the excess power supply converter 90, the signal generation unit converter 84, and the lower limit power supply unit 86 via the drive power supply terminal 80. Thereby, similarly to the case where the normal relay power supply device 12 is connected, power is supplied to the relay power supply inspection device 10 according to the present embodiment. Next, the worker connects the relay power supply device 12 to the power supply terminal 20. Next, the worker supplies power from the relay power supply device 12 to the relay power supply inspection device 10 according to the present embodiment via the power supply terminal 20.

  The power supplied from the relay power supply device 12 is supplied to the range determination unit 28 via the power supply terminal 20 and the power consumption unit 22. The relay power supply device 12 has a small amount of power that can be supplied when a plurality of relays are connected. Therefore, when a part of the power is consumed as heat by the first resistor 50, the second resistor 52, and the third resistor 54 of the power consuming unit 22, the power supplied to the operation determination relay 70 is This is so small that it cannot be driven. Since the power is small, the operation determination relay 70 does not operate. Since the operation determination relay 70 does not operate, the relay connection circuit 26 remains in a non-conductive state. Accordingly, a signal indicating “true” is not input to the photocoupler 170 for generating the continuity determination signal.

  Of the power supplied from the power supply device 12 for the relay, the remaining power except for the power supplied to the first resistor 50, the second resistor 52, the third resistor 54, and the operation determination relay 70 is the voltage upper limit. The voltage is supplied to the determination comparator 120 and the voltage lower limit determination comparator 126.

  The voltage upper limit comparator 120 outputs a signal corresponding to the voltage level of the power supplied thereto. In this case, the voltage upper limit comparator 120 outputs a signal indicating “true”. The signal is input to the voltage upper limit determination photocoupler 124. When the signal is input, the voltage upper limit determination photocoupler 124 outputs a signal. The signal output from the voltage upper limit determination photocoupler 124 is input to the voltage condition determination logical product circuit 134.

  In parallel with this, the voltage lower limit judgment comparator 126 also outputs a signal corresponding to the voltage level of the power supplied thereto. In this case, the voltage lower limit comparator 126 outputs a signal indicating “false”. The signal is input to the voltage lower limit determination photocoupler 130. When the signal is input, the voltage lower limit determination photocoupler 130 outputs the signal. The signal output from the voltage lower limit determining photocoupler 130 is also input to the voltage condition determining AND circuit 134. In this case, the signal output from the voltage upper limit determination photocoupler 124 indicates “true”, and the signal output from the voltage lower limit determination photocoupler 130 indicates “false”. As a result, the voltage condition determining AND circuit 134 outputs a signal indicating “false”. The signal is input to the AND circuit 174 for determining multiple types of conditions.

  As described above, in this case, a signal indicating “true” is not input to the continuity determination signal generating photocoupler 170. Therefore, the continuity determination signal generating photocoupler 170 does not output a signal.

  The signal output from the voltage condition determining AND circuit 134 is input to the multi-condition determining AND circuit 174, and the signal output from the continuity determining signal generating photocoupler 170 is not input. The signal output from the voltage condition determining AND circuit 134 is “false”. As a result, the multi-condition determining AND circuit 174 outputs a signal indicating “false”. The signal is input to the result signal generating photocoupler 178 via the test result determining step-down resistor 176. The result signal generation photocoupler 178 outputs a signal indicating “false”. The signal is output to the outside of the relay power supply inspection apparatus 10 according to the present embodiment via the determination result output terminal 32. The signal indicates that the operation determination relay 70 does not operate normally depending on the power supplied from the relay power supply device 12.

(When a relay power supply unit is connected that has too much power to be supplied)
First, the operator supplies power to the excess power supply converter 90, the signal generation unit converter 84, and the lower limit power supply unit 86 via the drive power supply terminal 80. Next, the worker connects the relay power supply device 12 to the power supply terminal 20. Next, the worker supplies power from the relay power supply device 12 to the relay power supply inspection device 10 according to the present embodiment via the power supply terminal 20.

  The power supplied from the relay power supply device 12 is supplied to the range determination unit 28 via the power supply terminal 20 and the power consumption unit 22. On the way, a part of the power is supplied to the first resistor 50, the second resistor 52, and the third resistor 54 of the power consuming unit 22. A part of the power different from that supplied to the power consuming unit 22 is supplied to the operation determination relay 70. The electric power supplied to the operation determination relay 70 operates it. As a result, a signal indicating “true” is input to the photocoupler 170 for generating the continuity determination signal.

  Of the power supplied from the relay power supply device 12, the remaining power except for the power supplied to the first resistor 50, the second resistor 52, the third resistor 54, and the operation determination relay 70 is voltage comparison. The voltage upper limit determination comparator 120 and the voltage lower limit determination comparator 126 of the unit 42 are supplied.

  The voltage upper limit comparator 120 outputs a signal corresponding to the voltage level of the power supplied thereto. In this case, since the voltage of the supplied power is too large, the voltage upper limit determination comparator 120 outputs a signal indicating “false”. The signal is input to the voltage upper limit determination photocoupler 124. When the signal is input, the voltage upper limit determination photocoupler 124 outputs a signal. The signal output from the voltage upper limit determination photocoupler 124 is input to the voltage condition determination logical product circuit 134.

  In parallel with this, the voltage lower limit judgment comparator 126 also outputs a signal corresponding to the voltage level of the power supplied thereto. In this case, the voltage lower limit determination comparator 126 outputs a signal indicating “true”. The signal is input to the voltage lower limit determination photocoupler 130. When the signal is input, the voltage lower limit determination photocoupler 130 outputs the signal. The signal output from the voltage lower limit determining photocoupler 130 is also input to the voltage condition determining AND circuit 134. In this case, the signal output from the voltage upper limit determination photocoupler 124 is “false”. The signal output from the voltage lower limit determination photocoupler 130 is “true”. As a result, the voltage condition determining AND circuit 134 outputs a signal indicating “false”. The signal is input to the AND circuit 174 for determining multiple types of conditions.

  In parallel with the operations of the voltage upper limit judgment comparator 120 and the voltage lower limit judgment comparator 126, as described above, a signal indicating “true” is input to the continuity determination signal generation photocoupler 170. When the signal is input, the continuity determination signal generating photocoupler 170 outputs the signal. The signal output from the continuity determination signal generation photocoupler 170 is input to the multiple condition determination logical product circuit 174.

  The signal output from the voltage condition determining AND circuit 134 and the signal output from the continuity determining signal generating photocoupler 170 are input to the multiple-type condition determining AND circuit 174. The signal output from the voltage condition determining AND circuit 134 is “false”. The signal output from the continuity determination signal generating photocoupler 170 is “true”. As a result, the multi-condition determining AND circuit 174 outputs a signal indicating “false”. The signal is input to the result signal generating photocoupler 178 via the test result determining step-down resistor 176. The result signal generation photocoupler 178 outputs a signal indicating “false”. The signal is output to the outside of the relay power supply inspection apparatus 10 according to the present embodiment through the determination result output terminal 32. The signal indicates that the operation determination relay 70 does not operate normally depending on the power supplied from the relay power supply device 12.

[Description of effects]
In the relay power supply inspection device 10 according to the present embodiment, when a current flows from the relay power supply device 12 to the operation determination relay 70, the relay connection circuit 26 becomes conductive. The multiple-type condition determination unit 30 determines whether or not the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range and the relay connection circuit 26 can be conducted. Thereby, the relay power supply inspection device 10 according to the present embodiment determines whether or not the relay power supply device 12 operates correctly when the relay is connected to the relay power supply device 12 and power is supplied to the relay from the relay power supply device 12. Will be performed. The relay power supply inspection device 10 according to the present embodiment does not merely determine whether or not the ground voltage of the current flowing from the relay power supply device 12 is within a predetermined range. As a result, the possibility that the relay power supply device 12 in which the relay may malfunction may be found.

  The embodiments disclosed herein are illustrative in all respects. The scope of the present invention is not limited based on the above-described embodiment. Of course, various design changes may be made without departing from the spirit of the present invention.

  For example, the configuration of the upper limit power supply unit 82 is not limited to that described above. The configuration of the range determination unit 28 is not limited to that described above.

DESCRIPTION OF SYMBOLS 10 ... Relay power supply inspection device 12 ... Relay power supply device 20 ... Power supply terminal 22 ... Power consumption part 24 ... Operation judgment part 26 ... Relay connection electric circuit 28 ... Range judgment part 30 ... Plural kind condition judgment part 32 ... Determination result output Terminal 34... First ground electrode 36... Second ground electrode 42... Voltage comparison unit 50... First resistor 52... Second resistor 54 ... Third resistor 70 ... Operation judgment relay 72 ... Operation judgment rectifier 80 Terminal 82 for driving power supply Upper limit power supply unit 84 Converter for signal generation unit 86 Lower limit power supply unit 90 Converter for excess power supply 92 Upper limit side voltage step-down unit 120 Voltage comparator for upper limit judgment 122 Upper limit side signal Step-down resistor 124 ... Photo upper limit judgment photocoupler 126 ... Voltage lower limit judgment comparator 128 ... Lower limit side signal step-down resistor 130 ... Voltage lower limit judgment photo coupler 132 ... Upper limit potential side photo coupler Voltage resistor 134 ... AND circuit for voltage condition determination 136 ... Ground voltage side step-down resistor 150 ... Operation determination step-down resistor 170 ... Conduction determination signal generating photocoupler 172 ... Operation determination setting resistor 174 ... Plurality Specified condition judging AND circuit 176 ... Inspection result judging step-down resistor 178 ... Result signal generating photocoupler

Claims (3)

A power supply terminal for connecting a power supply device for a relay used to supply power to the relay; and
A relay power supply inspection device comprising a range determination unit that determines whether or not a ground voltage of a current flowing from the relay power supply device connected to the power supply terminal is within a predetermined range,
An operation determining relay connected to the power terminal and through which a current flowing from the relay power supply device passes;
A relay connection circuit that is connected to the operation determination relay, and that allows current to flow when the current flowing from the relay power supply device passes through the operation determination relay;
Connected to the range determination unit and the relay connection circuit for determining whether the ground voltage of the current flowing from the power supply device for the relay is within the predetermined range and the relay connection circuit can be conducted A plurality of types of condition judging unit,
A relay power supply inspection apparatus, further comprising: a determination result output unit that outputs information indicating a determination result of the plurality of types of condition determination unit. The range determination unit
An upper limit power supply unit that supplies power whose ground voltage is an upper limit value of the predetermined range;
The ground voltage of the power supplied by the upper limit power supply unit from the ground voltage of the current that is connected to the upper limit power supply unit and the power supply terminal and flows from the relay power supply device via the power supply terminal is A voltage upper limit judging element for judging whether or not it is high,
A lower limit power supply unit that supplies power whose ground voltage is a lower limit value of the predetermined range;
The ground voltage of the power supplied by the lower limit power supply unit from the ground voltage of the current that is connected to the lower limit power supply unit and the power supply terminal and flows from the relay power supply device through the power supply terminal is A voltage lower limit determination element for determining whether or not the voltage is low;
The ground voltage of the power supplied by the upper limit power supply unit is higher than the ground voltage of the current flowing from the power supply device for the relay through the power terminal, and the relay is connected through the power terminal. Connected to the voltage upper limit determination element and the voltage lower limit determination element for determining whether or not the ground voltage of the power supplied by the lower limit power supply unit is lower than the ground voltage of the current flowing from the power supply device. The relay power supply inspection device according to claim 1, further comprising a voltage condition determination element. The upper limit power supply unit is
An excess power supply unit that supplies power whose ground voltage exceeds the upper limit of the predetermined range;
An upper limit step-down unit that is connected to the excess power supply unit and steps down the ground voltage of the power supplied by the excess power supply unit to an upper limit value of the predetermined range. The power inspection apparatus for relays according to 2.

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