JP7270485B2 - judgment system - Google Patents

Description

The present invention relates to a decision system.

A plurality of air conditioners are installed in a building or the like. A plurality of air conditioners and branch breakers are connected via connection lines. Here, a technology related to connection line diagnosis has been proposed (see Patent Literature 1).

JP 2016-95271 A

By the way, there are cases where it is desired to diagnose a connection line between an electrical device such as an air conditioner that is farthest from the branch breaker and the branch breaker. However, there is a problem that it is not known which electrical device is the furthest electrical device. For example, a method of specifying the farthest electrical equipment from the construction drawing can be considered. However, construction drawings may not be properly updated from the time of construction. Therefore, construction drawings cannot be trusted. Therefore, there is a problem that it is not known which electrical device is the farthest electrical device.

An object of the present invention is to detect the furthest electrical device from the branch breaker.

A determination system is provided according to one aspect of the present invention. A determination system includes a branch breaker, and a plurality of electrical devices connected to a plurality of second connection lines respectively connected to a plurality of locations on a first connection line connected to the branch breaker. , the electrical device furthest from the branch breaker is determined from among the plurality of electrical devices. The determination system includes a determination device connected to the first connection line connected to the branch breaker, and a plurality of switching devices connected to the plurality of second connection lines connected to the plurality of electrical devices. including. Each of the plurality of switchgears is a device that opens or short-circuits the ends of two electric wires included in a second connection line to which the device itself is connected among the plurality of second connection lines. be. The determination device applies a voltage to the first connection line and the plurality of second connection lines, and causes the ends of the plurality of switchgears to transition from the open state to the shorted state at different times. and measuring a plurality of resistance values between the determination device and each of the plurality of switchgears when the plurality of switchgears are shifted to the short-circuited state, and determining the plurality of resistance values is used to determine the electrical device furthest from the branch breaker among the plurality of electrical devices.

ADVANTAGE OF THE INVENTION According to this invention, the electrical equipment furthest from a branch breaker can be detected.

1 is a diagram showing an air conditioning control system according to Embodiment 1; FIG. 1 is a diagram showing a determination system according to Embodiment 1; FIG. 1 is a functional block diagram showing the configuration of a determination device according to Embodiment 1; FIG. 2 is a functional block diagram (Part 1) showing the configuration of a communication control unit according to Embodiment 1; FIG. 2 is a functional block diagram (Part 2) showing the configuration of a communication control unit according to Embodiment 1; FIG. 1 is a functional block diagram (Part 1) showing the configuration of a switchgear according to Embodiment 1; FIG. 2 is a functional block diagram (part 2) showing the configuration of the switchgear according to Embodiment 1; FIG. (A) to (C) are diagrams showing specific examples of setting contents. 4 is a diagram showing a specific example of a format of information transmitted to the switchgear according to Embodiment 1; FIG. 4 is a diagram showing an example of a relationship table according to Embodiment 1; FIG. FIG. 10 is a functional block diagram showing the configuration of a determination device according to Embodiment 2; (A) to (C) are diagrams showing specific examples of waveforms.

Embodiments will be described below with reference to the drawings. The following embodiments are merely examples, and various modifications are possible within the scope of the present invention.

Embodiment 1.
FIG. 1 is a diagram showing an air conditioning control system according to Embodiment 1. FIG. The air conditioning control system includes air conditioners 200 , 200 a and 200 b and a branch breaker 300 . Air conditioners 200, 200a, and 200b are indoor units. An air conditioner is also called an electric device.

Air conditioners 200, 200a, 200b and branch breaker 300 are connected via connection lines 11-16. Here, the connection lines 11 to 13 are also referred to as first connection lines. The connection lines 14-16 are also referred to as second connection lines. The connection relationship will be explained in detail. The connection lines 14-16 are connected to a plurality of points on the connection lines 11-13, respectively. In FIG. 1, the points are represented by contacts 1-3. Air conditioners 200, 200a, and 200b are connected to connection lines 14-16, respectively. Note that the connection line includes two electric wires. A connecting line is also called a cable.
Electricity output from a branch breaker 300 is supplied to the air conditioners 200, 200a, 200b via connection lines 11-16.

Here, there is a case where it is desired to diagnose the connecting line between the branch breaker 300 and the air conditioner 200b farthest from the branch breaker 300 . The reason is that if the connection lines 11 to 14 between the air conditioner 200b and the branch breaker 300 are diagnosed, the four connection lines can be diagnosed all at once. However, it may not be known which air conditioner among the air conditioners 200 , 200 a and 200 b is the farthest from the branch breaker 300 . Therefore, a method for detecting air conditioner 200b will be described.

FIG. 2 is a diagram showing a determination system according to Embodiment 1. FIG. The determination system includes a determination device 100 and opening/closing devices 400, 400a, and 400b.
The determination device 100 connects with the connection line 11 connected to the branch breaker 300 . Switching device 400 connects to connection line 15 connected to air conditioner 200 . The opening/closing device 400a is connected to the connection line 16 connected to the air conditioner 200a. The opening/closing device 400b connects to the connection line 14 connected to the air conditioner 200b.

The switchgear 400 opens or shorts the ends of the two wires included in the connection line 15 to which it is connected. The switching device 400a opens or shorts the ends of the two wires included in the connection line 16 to which it is connected. The switching device 400b opens or shorts the ends of the two wires included in the connection line 14 to which it is connected.

Here, an outline of the processing executed by the determination device 100 will be described. The determination device 100 applies a voltage to the connection lines 11-16. The determination device 100 controls the switchgears 400, 400a, and 400b so that the ends of the switchgears 400, 400a, and 400b shift from the open state to the short-circuit state at different times. The determination device 100 measures a plurality of resistance values between the determination device 100 and each of the switchgears 400, 400a, and 400b when the switching devices 400, 400a, and 400b are shifted to the short circuit state. The determination device 100 determines the air conditioner 200b that is farthest from the branch breaker 300 from among the air conditioners 200, 200a, and 200b using a plurality of resistance values.

Next, the functions of the determination device 100 will be described in detail.
FIG. 3 is a functional block diagram showing the configuration of the determination device according to Embodiment 1. FIG. The determination device 100 has an input section 110 , a communication control section 120 , a resistance measurement section 130 , a calculation section 140 , a determination section 150 , an output section 160 and a storage section 170 .

A part or all of the input unit 110 , the communication control unit 120 , the resistance measurement unit 130 , the calculation unit 140 , the determination unit 150 and the output unit 160 may be realized by the processor included in the determination device 100 . Some or all of the input unit 110, the communication control unit 120, the resistance measurement unit 130, the calculation unit 140, the determination unit 150, and the output unit 160 may be implemented as modules of a program executed by a processor included in the determination device 100. good.

The storage unit 170 may be realized as a storage area secured in a volatile storage device or a nonvolatile storage device included in the determination device 100 .
Identifiers of the opening/closing devices 400, 400a, and 400b are input to the input unit 110 by the user's operation. Identifiers are also called addresses. Addresses will be explained later.

Next, the communication control section 120 will be explained.
4 is a functional block diagram (part 1) showing the configuration of the communication control unit according to the first embodiment; FIG. The communication control unit 120 has a control unit 121, a resistor 122, and the like. The communication control unit 120 may be configured as follows.

5 is a functional block diagram (part 2) showing the configuration of the communication control unit according to the first embodiment; FIG. The communication control unit 120 similarly has a control unit 121, a resistor 122, and the like.
The communication control unit 120 communicates with the opening/closing devices 400, 400a, and 400b. Detailed functions of the communication control unit 120 will be described later.

Returning to FIG. 3, the resistance measuring section 130 will be described.
The resistance measurement unit 130 applies a voltage to the connection line and measures the insulation resistance value and the conduction resistance value. Note that the insulation resistance value is the resistance value when the switching devices 400, 400a, and 400b open the ends of the two electric wires included in the connection line. For example, the insulation resistance value corresponding to the switchgear 400b is the resistance value between the determination device 100 and the switchgear 400b when the ends of the two wires included in the connection line 14 are open. In addition, the terminal is also referred to as the first terminal. The conduction resistance value is the resistance value when the switchgear 400, 400a, 400b short-circuits the ends of two electric wires included in the connection line. For example, the conduction resistance value corresponding to the switchgear 400b is the resistance value between the determination device 100 and the switchgear 400b when the ends of the two wires included in the connection line 14 are short-circuited.

The calculator 140 calculates the distance using the conduction resistance value. A calculation method will be described later.
The determining unit 150 determines the air conditioner 200b that is farthest from the branch breaker 300 from among the air conditioners 200, 200a, and 200b. Further, the determination unit 150 determines whether or not the connection lines 11 to 14 can be used continuously.

The output unit 160 outputs the determination result of the determination unit 150 . For example, the output unit 160 outputs the determination result to a display of the determination device 100 or a display of another device. Note that the other device is a device connected to the determination device 100 . Illustration of the other device is omitted.
Information stored in the storage unit 170 will be described later.

Next, the opening/closing devices 400, 400a and 400b will be described. Here, the functions of the switching device 400 are the same as the functions of the switching devices 400a and 400b. Therefore, functions of the opening/closing device 400 will be described. A description of the functions of the opening/closing devices 400a and 400b is omitted.

FIG. 6 is a functional block diagram (part 1) showing the configuration of the switchgear according to the first embodiment. Here, when the communication control unit 120 has the configuration shown in FIG. 4, the configuration of the opening/closing device 400 becomes the configuration shown in FIG.
The switchgear 400 has a battery 410 , an address switch 420 , a relay 430 , a relay drive circuit 440 , a timer circuit 450 and a communication section 460 .

The battery 410 supplies power to the switchgear 400 through the power switch 411 . The address switch 420 can be realized by a DIP switch or the like. The address switch 420 sets the address of the switchgear 400 .
The relay 430 opens or shorts the ends of the two wires of the connection line 15 . Here, the relay 430 normally opens the end of the wire. That is, relay 430 is normally open. Note that the initial state of the relay 430 is a short-circuit state. This is because if the initial state is the open state, the switching device 400 cannot receive the electric signal transmitted by the determination device 100 .

Relay drive circuit 440 is an electric circuit for driving relay 430 .
The timer circuit 450 is an electric circuit that sets the time for the relay 430 to open or short-circuit the ends of the two wires of the connection line 15 .
The communication unit 460 receives information transmitted by the determination device 100 .

Here, the opening/closing device 400 may be configured as follows.
7 is a functional block diagram (part 2) showing the configuration of the switchgear according to Embodiment 1. FIG. When the communication control unit 120 has the configuration shown in FIG. 5, the opening/closing device 400 has the configuration shown in FIG.

Next, a flow until air conditioner 200b is detected will be described.
The address switch 420 sets the address of the switchgear 400 . Similarly, the address switches of the switching devices 400a, 400b set the addresses of the switching devices 400a, 400b. It is assumed that the addresses set for each of the switchgears 400, 400a, and 400b do not overlap.

The user operates the input unit 110 to input addresses of the switching devices 400, 400a, and 400b. Thereby, the determination device 100 can store the addresses of the switching devices 400, 400a, and 400b.

The communication control unit 120 sets an open state time, a short circuit state time, a first waiting time, and a second waiting time for each of the switchgears 400, 400a, and 400b. The first waiting time is the time to wait before starting the operation of the open state and the short state. The second waiting time is the waiting time after completing the operation of the open state and the short state. Here, each of the times of the open state and short-circuit state is set in advance. For example, each of the open and short circuit times is 1 second.

Here, a specific example of setting contents will be described.
8A to 8C are diagrams showing specific examples of setting contents. "Open" in FIG. 8 indicates an open state. "Closed" in FIG. 8 indicates a short circuit state. FIG. 8A shows the contents to be set in the opening/closing device 400. FIG. For example, the first waiting time set in the switchgear 400 is 0 seconds.

FIG. 8B shows the contents to be set in the opening/closing device 400a. For example, the first waiting time set in the switchgear 400a is two seconds.
FIG. 8C shows the contents to be set in the opening/closing device 400b. For example, the second waiting time set in the switching device 400b is 0 second.

Here, the first waiting time and the second waiting time are also the open state time.
Note that the total value of the first waiting time and the second waiting time is calculated by Equation (1).

Total value = time of open state and short circuit state x (number of switchgear - 1) (1)

The first waiting time is calculated by Equation (2).

First waiting time=time of open state and short-circuit state×(order−1) (2)

The second waiting time is calculated by Equation (3).

Second waiting time = total value - first waiting time (3)

The communication control unit 120 transmits information including setting contents to the opening/closing devices 400, 400a, and 400b. A specific example of the information will now be described.

FIG. 9 is a diagram showing a specific example of the format of information transmitted to the switchgear according to the first embodiment. For example, FIG. 9 shows information sent to the switchgear 400 . The information includes addresses and commands. The address contains a START BIT and a STOP BIT. The addresses in FIG. 9 indicate the addresses of the switchgear 400 . The command indicates the content to be set in the switchgear 400 . That is, the open state time, the short-circuit state time, the first waiting time, and the second waiting time set in the switchgear 400 are registered in the command. Note that the address may be considered as a header. A command may be thought of as a payload.

In this manner, the communication control unit 120 transmits information including setting contents to the opening/closing devices 400, 400a, and 400b. The communication units of the switching devices 400, 400a, and 400b receive information including setting contents. The opening/closing devices 400, 400a, and 400b operate according to the setting contents. For example, the timer circuit 450 sets the time for the relay 430 to open or short-circuit the ends of the two wires of the connection line 15 according to the setting contents. Relay drive circuit 440 controls relay 430 to open or short circuit according to the time set by timer circuit 450 . As a result, the opening/closing devices 400, 400a, and 400b operate as shown in FIG.

The resistance measurement unit 130 calculates a plurality of insulation resistance values between the determination device 100 and each of the switching devices 400, 400a, and 400b. That is, the calculation unit 140 calculates the insulation resistance value between the determination device 100 and the switchgear 400, the insulation resistance value between the determination device 100 and the switchgear 400a, the insulation resistance value between the determination device 100 and the switchgear 400b. Calculate the value.

The resistance measurement unit 130 calculates a plurality of conduction resistance values between the determination device 100 and each of the switching devices 400, 400a, 400b. That is, the calculation unit 140 calculates the conduction resistance value between the determination device 100 and the switchgear 400, the conduction resistance value between the determination device 100 and the switchgear 400a, the conduction resistance value between the determination device 100 and the switchgear 400b. Calculate the value.
The resistance measurement unit 130 registers the measured insulation resistance value and conduction resistance value in the relationship table. The relationship table will now be described.

10 is a diagram showing an example of a relationship table according to Embodiment 1. FIG. A relationship table 171 is stored in the storage unit 170 . The relationship table 171 has items of switchgear name, switchgear address, conduction resistance, insulation resistance, and distance.

The names of the switching devices 400, 400a, and 400b are registered in the item of the switching device name. The addresses of the switching devices 400, 400a, and 400b are registered in the item of address of the switching device. The conduction resistance value measured by the resistance measurement unit 130 is registered in the conduction resistance item. An insulation resistance value measured by the resistance measurement unit 130 is registered in the item of insulation resistance. The distance calculated by the calculator 140 is registered in the item of distance.

Next, calculation of the distance will be described.
The calculator 140 calculates the distance using Equation (4). Note that Z is the conduction resistance value. Rc is the resistance value per unit length.

The calculator 140 calculates a plurality of distances between the determination device 100 and each of the switchgears 400, 400a, and 400b using Equation (4). That is, the calculation unit 140 calculates the distance between the determination device 100 and the switching device 400, the distance between the determination device 100 and the switching device 400a, and the distance between the determination device 100 and the switching device 400b. The calculation unit 140 registers the calculated multiple distances in the relationship table 171 .
Further, the calculator 140 may calculate the distance using Equation (5). In addition, for example, other resistance values are resistance values due to terminals of the switchgear.

The determination unit 150 detects that the distance between the determination device 100 and the opening/closing device 400b is the longest among the plurality of distances registered in the relationship table 171 . The determination unit 150 determines that the air conditioner 200 b to which the connection line 14 connected to the switching device 400 b is connected is the air conditioner that is farthest from the branch breaker 300 . Here, the opening/closing device 400b is also referred to as a first opening/closing device.

Further, the determination unit 150 may detect the air conditioner 200b by the following method. The determination unit 150 detects the largest conduction resistance value among the plurality of conduction resistance values registered in the relationship table 171 . For example, the largest conduction resistance value is the resistance value between the switching device 400 b and the branch breaker 300 . The determination unit 150 detects the switching device 400b corresponding to the detected conduction resistance value. The determination unit 150 determines that the air conditioner 200 b to which the connection line 14 connected to the switching device 400 b is connected is the air conditioner that is farthest from the branch breaker 300 .
Thereby, the determination device 100 can detect the air conditioner 200b.

After ending the short-circuit state in each of the switchgears 400, 400a, and 400b, the communication control unit 120 transmits a command to the switchgears 400, 400a, and 400b to execute the open state in the switchgears 400, 400a, and 400b. . As a result, the opening/closing devices 400, 400a, and 400b open the ends of the connection lines.

The determination unit 150 determines whether or not the connection lines 11 to 14 can continue to be used using the first threshold and the second threshold. Specifically, if the insulation resistance value corresponding to the switchgear 400b is equal to or greater than the first threshold and the conduction resistance value corresponding to the switchgear 400b is equal to or less than the second threshold, the determination unit 150 14 is determined to be usable continuously. Note that, for example, the first threshold is 0.2 MΩ. The second threshold is a resistance value based on the distance corresponding to the switching device 400b and the resistance value per unit length.
The determination unit 150 stores the determination result in the storage unit 170 . The output unit 160 outputs the determination result.

Next, when the resistance measurement unit 130 is measuring the resistance value, there is a case where a defect is detected in the connection line. The processing of the determination device 100 when a defect is detected will be described.
When the resistance measurement unit 130 measures a resistance value close to a short circuit, the output unit 160 outputs that there is a short circuit connection line. The communication control unit 120 also transmits a command to the switching devices 400, 400a, and 400b to cause the switching devices 400, 400a, and 400b to enter the open state. Then, the resistance measurement unit 130 ends the measurement process.

Moreover, when the connection line is broken, the resistance measurement unit 130 detects that a short circuit state does not occur at the set time. For example, if the resistance value does not change at the time when the switchgear 400 becomes short-circuited, the resistance measurement unit 130 detects that the switchgear 400 is not short-circuited. The output unit 160 outputs that disconnection has occurred between the connection lines 11 and 15 . Then, the resistance measurement unit 130 ends the measurement process.

Next, the recovery timing of the opening/closing devices 400, 400a, and 400b will be described. In the opening/closing devices 400, 400a, and 400b, the terminals of the connection lines are in an open state. Therefore, when normal operation is performed between air conditioners 200, 200a, 200b and branch breaker 300, switching devices 400, 400a, 400b do not adversely affect normal operation. Therefore, the switchgears 400, 400a, and 400b may be left as they are until the equipment renewal work. The switchgears 400, 400a, and 400b are recovered during facility renewal work. In this way, the determination device 100 causes the switchgears 400, 400a, and 400b to enter the open state after the measurement process of the resistance measurement unit 130 is completed, so that the switchgears 400, 400a, and 400b do not need to be recovered immediately. done.

Switching devices other than the switching device farthest from the branch breaker 300 may be recovered immediately. That is, the opening/closing devices 400 and 400a may be collected.
The switchgear 400, 400a, 400b may be left for periodic diagnostics.

According to Embodiment 1, determination device 100 can detect the air conditioner furthest from branch breaker 300 from among air conditioners 200, 200a, and 200b by using the conduction resistance value.

A case of diagnosing the connection line between the air conditioner 200b and the branch breaker 300 has been described above. However, the determination device 100 may diagnose the connection line between the air conditioner 200 and the branch breaker 300 and the connection line between the air conditioner 200 a and the branch breaker 300 . The diagnostic method will be described in detail below.

The determination unit 150 determines whether or not the connection lines 11 and 15 can continue to be used using the first threshold and the second threshold. Specifically, if the insulation resistance corresponding to the switchgear 400 is equal to or greater than the first threshold and the conduction resistance value corresponding to the switchgear 400 is equal to or less than the second threshold, the determination unit 150 15 can be used continuously. Note that, for example, the first threshold is 0.2 MΩ. The second threshold is a resistance value based on the distance corresponding to the switching device 400 and the resistance value per unit length.

The determination unit 150 determines whether or not the connection lines 11, 12 and 16 can continue to be used using the first threshold and the second threshold. Specifically, if the insulation resistance corresponding to the switching device 400a is equal to or greater than the first threshold and the conduction resistance value corresponding to the switching device 400a is equal to or less than the second threshold, the determination unit 150 12 and 16 can be continuously used. Note that, for example, the first threshold is 0.2 MΩ. The second threshold is a resistance value based on the distance corresponding to the switching device 400a and the resistance value per unit length.
Thus, the determination device 100 can determine whether or not the connection lines 11 to 16 can be used continuously.

Embodiment 2.
Next, Embodiment 2 will be described. Embodiment 2 will mainly describe matters that are different from Embodiment 1, and will omit description of matters that are common to Embodiment 1. FIG. Embodiment 2 refers to FIGS. 1-10.

In the first embodiment, the case of calculating the distance using the conduction resistance value has been described. Here, connection failure may occur. For example, if the connection line 15 is incompletely connected to the contact 1 . In addition, connection failure may be expressed as contact failure of the insertion portion. When a connection failure occurs, the impedance increases, so the conduction resistance value increases. As the conduction resistance value increases, the distance also increases. In this way, there is a possibility that an accurate distance cannot be measured by calculating the distance using the conduction resistance value. Therefore, in the second embodiment, a case of using a TDR (Time Domain Reflectometry) method will be described.

Here, the TDR method is a method in which a voltage pulse with a fast rise is applied to the sample, and the internal structure of the sample is grasped from the time change of the voltage applied to the sample. In Embodiment 2, the sample is a connecting line. A voltage pulse with a fast rising edge is generated by a TDR measuring section, which will be described later.

FIG. 11 is a functional block diagram showing the configuration of the determination device according to the second embodiment. 11 that are the same as those shown in FIG. 3 are given the same reference numerals as those shown in FIG.
The determination device 100 a has a calculation unit 140 a , a measurement switching unit 180 and a TDR measurement unit 190 . A part or all of the calculation unit 140a, the measurement switching unit 180, and the TDR measurement unit 190 may be implemented by a processor included in the determination device 100a. Part or all of the calculation unit 140a, the measurement switching unit 180, and the TDR measurement unit 190 may be implemented as modules of a program executed by a processor included in the determination device 100a.

The function of the calculator 140a will be described later.
When the resistance measurement unit 130 executes, the measurement switching unit 180 executes control for the resistance measurement unit 130 to acquire an electrical signal. Moreover, when the TDR measurement unit 190 executes, the measurement switching unit 180 executes control for the TDR measurement unit 190 to acquire an electric signal.

The resistance measurement unit 130 executes measurement processing when the TDR measurement unit 190 is not executing. The TDR measurement unit 190 executes measurement processing when the resistance measurement unit 130 is not executing. The TDR measuring unit 190 controls the switchgears 400, 400a, and 400b so that the ends of the switchgears 400, 400a, and 400b shift from the open state to the short-circuit state at different times. Thereby, for example, the opening/closing devices 400, 400a, and 400b operate as shown in FIG. The TDR measurement unit 190 applies voltage pulses to the connection lines 11 to 16 when the switchgears 400, 400a, 400b are open or short-circuited. The TDR measurement unit 190 measures reflected waves.

Next, waveforms measured by the TDR method will be described.
First, reflection of an electrical signal occurs at locations where there is a difference in impedance. Specifically, negative reflection occurs where the characteristic impedance drops. Positive reflection occurs where the characteristic impedance rises.

12A to 12C are diagrams showing specific examples of waveforms. 12A to 12C show graphs. The vertical axis of the graph indicates voltage. The horizontal axis of the graph indicates time. In FIG. 12, it is assumed that the connection line 15 is incompletely connected to the contact 1 .

FIG. 12A shows the waveform of the reflected wave measured by the TDR measurement unit 190 when the switchgear 400 is in the open state. The time when the TDR measurement unit 190 starts detecting the reflected wave of the voltage pulse is time T1. The time when the voltage pulse reaches the end of the connection line 15 is time T2. For example, the voltage value between time T1 and time T2 is also called the first voltage value. Note that the voltage pulse is also called a first voltage pulse.

Also, FIG. 12A shows an ellipse 21 representing the relationship between the voltage and the time when the voltage pulse reaches the location of the poor connection. The time when the voltage pulse reaches the point of connection failure is after time T1. Since the switching device 400 opens the end of the connection line 15, positive reflection occurs after time T2.

FIG. 12B shows the waveform of the reflected wave measured by the TDR measurement unit 190 when the switchgear 400 is in a short circuit state. The time when the TDR measurement unit 190 starts detecting the reflected wave of the voltage pulse is time T3. The time when the voltage pulse reaches the end of the connection line 15 is time T4. For example, the voltage value between time T3 and time T4 is also called a second voltage value. Note that the voltage pulse is also referred to as a second voltage pulse.

In addition, FIG. 12B shows an ellipse 22 representing the relationship between the voltage and the time when the voltage pulse reaches the connection failure point. The time when the voltage pulse reaches the point of connection failure is after time T3. Since the switchgear 400 short-circuits the end of the connection line 15, negative reflection occurs after time T4.

FIG. 12(C) shows a waveform based on the difference between the waveform of FIG. 12(A) and the waveform of FIG. 12(B). An ellipse 23 indicates that the influence of the poor connection has been removed.
If there is no difference between the first voltage value and the second voltage value, the determination device 100a performs the following processing. The calculator 140a calculates the distance from the branch breaker 300 to the switchgear 400 using Equation (6). Note that the dielectric constant is the dielectric constant of the connection lines including the connection lines 11-16. The dielectric constant varies depending on the type of connection line. Also, T2 in Equation (6) may be changed to T4. T1 in equation (6) may be changed to T3.

Similarly, the TDR measurement unit 190 measures the waveform of the reflected wave when the switchgears 400a and 400b are in the open state. The TDR measurement unit 190 measures the waveform of the reflected wave when the switching devices 400a and 400b are short-circuited. Then, the TDR measurement unit 190 calculates the difference between the waveform of the reflected wave when the switchgears 400a and 400b are in the open state and the waveform of the reflected wave when the switchgears 400a and 400b are in the short-circuited state. do. When there is no voltage difference between the time when the detection of the reflected wave of the voltage pulse is started and the time when the voltage pulse reaches the end of the connection line, the calculation unit 140a starts detecting the reflected wave of the voltage pulse. Using the time, the time the voltage pulse reaches the end of the connection line, and equation (6), the distance is calculated.

Thus, the determination device 100a calculates the distance for each opening/closing device.
The calculator 140 a registers the calculated distance in the relationship table 171 .
The determination unit 150 refers to the relationship table 171 and detects the opening/closing device 400b corresponding to the longest distance. The air conditioner 200 b to which the connection line 14 connected to the switching device 400 b was connected is the air conditioner farthest from the branch breaker 300 .
Thereby, the determination device 100a can identify the air conditioner 200b.

According to Embodiment 2, the determination device 100a calculates the distance using the TDR method. Thereby, the determination device 100 a can determine the air conditioner that is farthest from the branch breaker 300 .

The features of the embodiments described above can be combined as appropriate.

11,12,13,14,15,16 connection line, 21,22,23 ellipse, 100,100a determination device, 110 input section, 120 communication control section, 121 control section, 122 resistance, 130 resistance measurement section, 140, 140a calculation unit 150 determination unit 160 output unit 170 storage unit 171 relationship table 180 measurement switching unit 190 TDR measurement unit 200,200a,200b air conditioner 300 branch breaker 400,400a,400b switching device , 410 battery, 411 power switch, 420 address switch, 430 relay, 440 relay drive circuit, 450 timer circuit, 460 communication unit.

Claims (7)

In a system including a branch breaker and a plurality of electrical devices connected to a plurality of second connection lines respectively connected to a plurality of locations on a first connection line connected to the branch breaker , a determination system for determining an electrical device farthest from the branch breaker from among the plurality of electrical devices,
a determination device connected to the first connection line connected to the branch breaker;
a plurality of switchgears connected to the plurality of second connection lines connected to the plurality of electrical devices;
including
Each of the plurality of switchgears is a device that opens or short-circuits the ends of two electric wires included in a second connection line to which the device itself is connected among the plurality of second connection lines. can be,
The determination device applies a voltage to the first connection line and the plurality of second connection lines, and causes the ends of the plurality of switchgears to transition from the open state to the shorted state at different times. and measuring a plurality of resistance values between the determination device and each of the plurality of switchgears when the plurality of switchgears are shifted to the short-circuited state, and determining the plurality of resistance values determining the electrical device furthest from the branch breaker among the plurality of electrical devices using
judgment system. The determination device detects that a resistance value between a first switching device of the plurality of switching devices and the branch breaker is the highest among the plurality of resistance values, determining that the electrical device to which the second connection line connected to is connected is the electrical device farthest from the branch breaker;
The determination system according to claim 1. The determination device calculates a plurality of distances between the determination device and each of the plurality of switching devices using the resistance value per unit length and the plurality of resistance values, and calculates the plurality of opening and closing devices. detecting that the distance between a first switchgear of devices and the branch breaker is the longest among the plurality of distances, and the second connection line connected to the first switchgear is determining that the connected electric device is the farthest electric device from the branch breaker;
The determination system according to claim 1. The determination device is configured to perform the determination device and the first terminal when the first end, which is the end of the two electric wires included in the second connection line connected to the first switchgear, is in the open state. The resistance value between the determination device and the first switchgear when the resistance value between the one switchgear is equal to or greater than a first threshold and the first terminal is in the short-circuited state If it is equal to or less than the second threshold, it is determined that the connection line between the determination device and the first switchgear can be continuously used.
The determination system according to claim 2 or 3. In a system including a branch breaker and a plurality of electrical devices connected to a plurality of second connection lines respectively connected to a plurality of locations on a first connection line connected to the branch breaker , a determination system for determining an electrical device farthest from the branch breaker from among the plurality of electrical devices,
a determination device connected to the first connection line connected to the branch breaker;
a plurality of switchgears connected to the plurality of second connection lines connected to the plurality of electrical devices;
including
Each of the plurality of switchgears is a device that opens or short-circuits the ends of two electric wires included in a second connection line to which the device itself is connected among the plurality of second connection lines. can be,
The determination device is
Each of the plurality of switchgears performs control for shifting the terminal from the open state to the shorted state at different times, and each of the switchgears is controlled to shift the terminal from the open state to the short-circuited state. a time at which a first voltage pulse is applied to one connection line and the plurality of second connection lines and detection of a reflected wave of the first voltage pulse is started; A first voltage value is measured between the arrival time and the second voltage pulse is applied to the first connection line and the plurality of second connection lines in the short-circuit state, and the second voltage pulse is applied to the second connection line. measuring a second voltage value between the time when the detection of the reflected wave of the second voltage pulse is started and the time when the second voltage pulse reaches the end, and measuring the first voltage value and the first voltage pulse; 2, the time at which detection of the reflected wave of the first voltage pulse or the second voltage pulse is started in the open state or the short-circuited state, the first Calculating the distance using the time when the voltage pulse or the second voltage pulse reaches the end, the speed of light, and the dielectric constant of the connection lines including the first connection line and the plurality of second connection lines. death,
Using the calculated distance, determining the electrical device furthest from the branch breaker from among the plurality of electrical devices;
judgment system. The determination device outputs a determination result,
The determination system according to any one of claims 1 to 5. The plurality of electrical devices are a plurality of air conditioners,
A determination system according to any one of claims 1 to 6.

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