JP5656914B2 - Measuring device, measuring method and program - Google Patents

Description

  The present invention relates to a measuring device, a measuring method, and a program.

  There is a power monitoring system described in Patent Document 1 that measures the power consumption of a measurement target device at each predetermined timing and displays the fluctuation of the power consumption of the measurement target device.

  When a predetermined operation on the terminal device is performed by the user, the power monitoring system displays, for example, a change in power consumption of the air conditioner on the display screen of the terminal device. Specifically, the power monitoring system uses power consumption for a certain period (for example, today, this month, or this year) including the operation time of the terminal device in the air conditioner and consumption for a certain period in the past (for example, yesterday, last month, or last year). The amount of power is displayed on the display screen of the terminal device. By this display, the user can grasp the fluctuation of the power consumption of the air conditioner.

Japanese Patent Laid-Open No. 2008-202985

  The power monitoring system described in Patent Document 1 only displays the power consumption of the air conditioner for two different periods. Therefore, when this power monitoring system is applied to an air conditioner system installed in a building or the like, the following problems arise. That is, with the maintenance of the air conditioner system, for example, an operator changes the program of the computer that controls the operation of the air conditioner of the air conditioner, and then cleans the air conditioner. Specifically, when another worker grasps which factor causes how much power consumption changes, another confirmer confirms the contents of the changes made by the previous worker before grasping. And the timing of changes must be confirmed. Therefore, there is a problem that the work until grasping the factor of fluctuation of the power consumption is complicated.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a measuring device, a measuring method, and a program that make it easy to grasp the cause of fluctuations in power consumption.

In order to achieve the above object, the measurement generation unit of the measurement apparatus according to the present invention measures the power consumption of the measurement target device at each predetermined timing, and associates the measured power consumption with the measurement timing. Is generated. When a change in the state of the measurement target device that affects power consumption occurs and information indicating the content of the change is input, the acquisition unit acquires information indicating the content of the input change. The correspondence generation unit generates information in which the information indicating the content of the change acquired by the acquisition unit is associated with the input timing. The storage unit composed of the nonvolatile memory includes information in which the measurement timing generated by the measurement generation unit is associated with the power consumption amount, and information indicating the input timing generated by the correspondence generation unit and the content of the change. Is stored in the associated information. The output unit outputs the information stored in the storage unit to the external device in response to a request from the external device. The information indicating the content of the change is information indicating the content of the change caused by the maintenance of the measurement target device.

  According to the present invention, it is possible to easily grasp the factor of fluctuation in power consumption.

It is a connection diagram of the electric power measurement system which concerns on Embodiment 1 of this invention. It is a block diagram of a power measuring device. It is a block diagram of a controller. It is a figure of the screen displayed on the display part. It is a connection diagram of the electric power measurement system which concerns on Embodiment 2 of this invention. 6 is a block diagram of a power measuring device according to a second embodiment. FIG.

(Embodiment 1)
Hereinafter, as shown in FIG. 1, the power measurement system 100 according to Embodiment 1 of the present invention mediates an air conditioner 2 connected to the power line 4 through the lead-in line 7 and an operation by the user of the air conditioner 2. And a controller 6 that performs.

  The air conditioner 2 includes air conditioners 2a and 2b. The air conditioners 2a and 2b are part of an air conditioner system, for example, an outdoor unit of an air conditioner installed indoors. The air conditioners 2a and 2b are connected to a power line 4 connected to a three-phase three-wire type three-phase AC power source via a lead-in line 7. Specifically, the air conditioners 2a and 2b are connected to the power line 4a connected to the R phase of the three-phase AC power supply via the lead-in line 7a, and are connected to the power line 4b connected to the S-phase of the three-phase AC power supply. The power line 4c connected to the T phase of the three-phase AC power supply is connected to the power line 4c via the lead-in line 7c. The air conditioners 2a and 2b operate using a three-phase AC power source supplied by the lead-in wires 7a to 7c.

  A control board 5 built in each of the air conditioners 2a and 2b is connected to the lead-in wires 7a to 7c. Each control board 5 has a computer that controls the operation of each of the air conditioners 2a and 2b by controlling the current from the three-phase AC power supplied to each of the air conditioners 2a and 2b. A control transmission line 3 connected to the controller 6 is connected to each control board 5. An operation signal output from the controller 6 is input to each control board 5 by the control transmission line 3. In accordance with this operation signal, the computer of the control board 5 operates the air conditioners 2a and 2b. The control transmission line 3 is applied with a DC voltage for supplying power to equipment connected to the control transmission line 3.

  The controller 6 is connected to the control board 5 of the air conditioners 2a and 2b via the control transmission line 3. The controller 6 has, for example, a keyboard that mediates user operations. When the controller 6 accepts an operation by the user, the controller 6 generates an operation signal corresponding to the operation, and outputs the operation signal to the control board 5 of the air conditioners 2a and 2b.

  Here, in addition to the transition of the power consumption of the air conditioners 2a and 2b, the controller 6 changes the event that occurred in the air conditioners 2a and 2b (change in the state of the measurement target device that affects the power consumption, specifically, For example, the content of the change in state caused by maintenance such as cleaning of the air conditioner 2a or replacement of the compressor built in the air conditioner 2b) is displayed together with the event occurrence date and time. Therefore, the user can confirm how much the power consumption of the air conditioners 2a and 2b has changed due to which event.

  The power measuring device 1 is connected to the lead-in wires 7a to 7c connected to the air conditioners 2a and 2b via the voltage conducting wire 11, respectively. In addition, the power measuring device 1 is connected to the lead-in wires 7a and 7c connected to the air conditioners 2a and 2b via the current conducting wires 12, respectively.

  The power measuring device 1 measures the voltage applied to the lead-in wires 7a to 7c via the voltage conducting wire 11 at every predetermined timing (for example, every 0.1 ms). Thereby, the power measuring device 1 measures the line voltage (voltage between the R phase and the S phase) V_RS applied between the lead-in wire 7a and the lead-in wire 7b, and also draws in the lead-in wire 7b and the lead-in wire 7b. The line voltage (voltage between S phase and T phase) V_ST applied between the line 7c is measured.

  In addition, the power measuring device 1 has a current (current consumption) that flows from the lead-in wire 7a into the air conditioner 2a (or the air conditioner 2b) at a predetermined timing (for example, every 0.1 ms) via the current conducting wire 12. While measuring IR, the electric current (current consumption) IT which flows into the air conditioner 2a (or air conditioner 2b) from the lead-in wire 7c is measured.

  Then, the power measuring apparatus 1 calculates the sum of the product of the current consumption IR and the line voltage V_RS for one cycle of the three-phase AC power supply (for example, one cycle of the line voltage V_RS) and the current consumption IT And the line voltage V_ST, the sum of one cycle of the three-phase AC power supply (for example, one cycle of the line voltage V_ST) is obtained, and these sums are added. Thereafter, the power measuring device 1 calculates the instantaneous power of each of the air conditioners 2a and 2b by dividing the added value by the number of samplings in one cycle of the three-phase AC power supply. And the electric power measuring apparatus 1 measures each power consumption of air conditioner 2a, 2b by integrating | accumulating the calculated | required instantaneous electric power for a predetermined period.

  As shown in FIG. 2, the power measuring device 1 includes a power supply unit 13, a voltage unit 14, a current unit 15, an analog-digital conversion unit (hereinafter referred to as “A / D conversion unit”) 16, An arithmetic control unit 17, an event input unit 18, a storage unit 19, a timer unit 20, an insulation circuit 21, a communication unit 22, and a power feeding unit 23 are provided.

  The power supply unit 13 generates DC power using AC power supplied from a three-phase AC power supply, and supplies the generated DC power to the units 14 to 20. In the power supply unit 13, one of the two input terminals is connected to the voltage conducting wire 11a, and the other input terminal of the two input terminals is connected to the voltage conducting wire 11b. By connecting the input terminals, the power supply unit 13 rectifies the input line voltage V_RS using, for example, a diode, and generates DC power by stepping down the voltage using, for example, a DC-DC converter.

  In the voltage section 14, the voltage lead 11a is connected to the lead-in wire 7a, the voltage lead 11b is connected to the lead-in wire 7b, and the voltage lead 11c is connected to the lead-in wire 7c. The voltage unit 14 has two output terminals connected to the input terminal of the A / D conversion unit 16.

  The voltage unit 14 measures the voltage V_R applied to the lead-in line 7a, the voltage V_S applied to the lead-in line 7b, and the voltage V_T applied to the lead-in line 7c, and the line voltage is determined from the measured voltage V_R and voltage V_S. V_RS is obtained, and line voltage V_ST is obtained from the measured voltage V_S and voltage V_T. The voltage unit 14 divides the obtained line voltage V_RS and the line voltage V_ST to step down the line voltage V_RS and the line voltage V_ST to a voltage value that can be input to the A / D conversion unit 16. Thereafter, the voltage unit 14 outputs the stepped down line voltage V_RS and the line voltage V_ST to the A / D conversion unit 16.

  In the current section 15, the current conducting wire 12a is connected to a current transformer surrounding the lead-in wire 7a, and the current conducting wire 12c is connected to the current transformer surrounding the lead-in wire 7c. The current unit 15 has two output terminals connected to the input terminal of the A / D conversion unit 16. The current transformer is an annular current transformer having a primary conductor and a secondary conductor.

  The current unit 15 indirectly measures the current IR flowing through the lead-in wire 7a by measuring the voltage generated in the current transformer according to the current flowing through the lead-in wire 7a through the current conducting wire 12a. The current unit 15 indirectly measures the current IT flowing through the lead-in wire 7c by measuring the voltage generated in the current transformer according to the current flowing through the lead-in wire 7c through the current conducting wire 12c. Then, the current unit 15 steps down the measured voltage to a voltage value that can be input to the A / D conversion unit 16 by dividing the measured voltage. Thereafter, the current unit 15 outputs the stepped down voltage to the A / D conversion unit 16.

  The A / D converter 16 is, for example, a ΔΣ A / D converter that uses ΔΣ (delta sigma) modulation. The A / D conversion unit 16 has four input terminals connected to the voltage unit 14 and the current unit 15. Specifically, the A / D conversion unit 16 has two input terminals connected to the output terminal of the voltage unit 14, and the remaining two input terminals connected to the output terminal of the current unit 15. The A / D conversion unit 16 has four output terminals connected to the input terminal of the arithmetic control unit 17.

  The A / D conversion unit 16 outputs the divided line voltage V_RS (instantaneous value) and line voltage V_ST (instantaneous value) output from the voltage unit 14 and the divided voltage output from the current unit 15 ( The instantaneous value of the voltage generated according to the current flowing through the lead-in wires 7a and 7c) is converted from an analog value to a digital value and output to the arithmetic control unit 17.

  The instantaneous value of the line voltage V_RS, the instantaneous value of the line voltage V_ST, the instantaneous value of the voltage generated according to the current flowing through the lead-in line 7a, and the instantaneous value of the voltage generated according to the current flowing through the lead-in line 7c are as follows. The sampling for converting the analog value into the digital value by the A / D conversion unit 16 is controlled by a trigger signal output from the arithmetic control unit 17 to the A / D conversion unit 16. Since the voltage generated according to the current flowing through the lead-in lines 7a and 7c becomes a leading phase with respect to the line voltages V_RS and V_ST due to the influence of the current transformer of the current transformer, the leading phase is corrected. In this case, the A / D converter 16 samples the instantaneous value of the voltage generated according to the current flowing through the lead-in lines 7a and 7c by the amount corresponding to the advance phase, and calculates the instantaneous value of the line voltage V_RS and the line voltage. What is necessary is just to make it faster than the sampling of the instantaneous value of V_ST. Specifically, each value after sampling (which becomes a digital signal) is the instantaneous value of the line voltage V_RS, the instantaneous value of the line voltage V_ST, and the instantaneous value of the voltage generated according to the current flowing through the lead-in line 7a. The instantaneous value of the voltage generated according to the current flowing through the lead-in line 7c is output from the A / D conversion unit 16 and stored in a RAM (Random Access Memory) of the arithmetic control unit 17.

  The arithmetic control unit 17 includes a central processing unit (CPU), a read only memory (ROM), and a RAM (all not shown), and six input terminals include an A / D conversion unit 16, an event input unit 18, and a time count. Connected to the unit 20. Specifically, the arithmetic control unit 17 has four input terminals connected to the A / D conversion unit 16, another one input terminal connected to the event input unit 18, and the remaining one input terminal serving as a time measuring unit. 20 is connected. Further, the arithmetic control unit 17 has one input / output terminal connected to the storage unit 19 and the other input terminal connected to the insulation circuit 21.

  The arithmetic control unit 17 draws the instantaneous value of the line voltage V_RS, the current IR flowing through the lead-in line 7a, and the instantaneous value of the line voltage V_ST, which is output from the A / D conversion unit 16 and stored in the RAM (not shown). The power consumption of the air conditioner 2a (or air conditioner 2b) is obtained from the current IT flowing through the line 7c.

  Specifically, the arithmetic control unit 17 obtains the power consumption of the air conditioner 2a (or air conditioner 2b) as follows. First, the arithmetic control unit 17 calculates the lead-in wire 7a from the instantaneous value of the voltage generated according to the current flowing through the lead-in wires 7a and 7c, which is output from the A / D converter 16 and stored in the RAM (not shown). And the current IT flowing in the lead-in line 7c are obtained. Specifically, the arithmetic control unit 17 converts a conversion coefficient stored in advance in a ROM (not shown) (an instantaneous value of a voltage generated according to the current flowing through the lead-in wires 7a and 7c into a current value). ) Is used to convert the instantaneous value of the voltage generated according to the current flowing through the lead-in line 7a and the instantaneous value of the voltage generated according to the current flowing through the lead-in line 7c into a current value. The current IR flowing through 7a and the current IT flowing through lead-in line 7c are obtained.

  Next, the arithmetic control unit 17 multiplies the current IR flowing through the lead-in line 7a and the instantaneous value of the line voltage V_RS at the same time (same sample timing). Then, the arithmetic control unit 17 obtains the sum of this multiplication value for one cycle of the three-phase AC power supply (for example, one cycle of the line voltage V_RS). In addition, the arithmetic control unit 17 multiplies the current IT flowing through the lead-in line 7c and the instantaneous value of the line voltage V_ST at the same time (same sample timing). Then, the arithmetic control unit 17 obtains the sum of this multiplication value for one cycle of the three-phase AC power supply (for example, one cycle of the line voltage V_ST). Thereafter, the arithmetic control unit 17 adds these sums, and divides the added value by the number of samplings of one cycle of the three-phase AC power supply, thereby instantaneous power of the air conditioner 2a (or air conditioner 2b). Ask for. And the calculation control part 17 measures the power consumption of the air conditioner 2a (or air conditioner 2b) by integrating | accumulating the calculated | required instantaneous electric power for a predetermined period. When the power consumption is measured, the arithmetic control unit 17 acquires the date and time when the power consumption is measured from the time measuring unit 20, and associates the acquired date and time with the obtained power consumption and the name of the air conditioner. The associated information (generated information) is stored in the storage unit 19. The arithmetic control unit 17 performs the above-described processing every time one minute elapses, for example.

  The arithmetic control unit 17 periodically transmits information stored in the storage unit 19 (information in which the measured power consumption, the date and time when the power consumption is measured, and the name of the air conditioner are associated) from the controller 6. In response to the requested command, it is transmitted to the controller 6. When the controller 6 receives the information in which the power consumption, the date and time when the power consumption is measured, and the name of the air conditioner are received, the controller 6 stores the information.

  In addition, the arithmetic control unit 17 performs an event such as cleaning of the air conditioner 2a (or air conditioner 2b) or replacement of a compressor built in the air conditioner 2a (or air conditioner 2b). When the user inputs information indicating the content of the event that has occurred in the air conditioner 2a (or air conditioner 2b) based on the occurrence (information indicating the content of the change) via the event input unit 18, The information indicating the contents of the event is associated with the date and time (input timing) and the name of the air conditioner being timed by the timekeeping unit 20. The arithmetic control unit 17 stores the associated information (generated information) in the storage unit 19 and transmits it to the controller 6 via the communication unit 22. When the controller 6 receives the information in which the event content is associated with the input date / time and the name of the air conditioner, the controller 6 stores the information.

  The controller 6 receives and stores the information (information indicating the contents of the event, the date and time of input and the name of the air conditioner, the date and time when the power consumption and the power consumption are measured, and the like. The information indicating the contents of the event and the power consumption amount are associated with each other according to the date and time (timing), and are displayed on the display of the controller 6. Thereby, the user can confirm how much the power consumption of the air conditioners 2a and 2b has changed due to which event.

  The event input unit 18 is connected to the input terminal of the calculation control unit 17. The event input unit 18 is a keyboard, for example. While an event occurs in the air conditioner 2a (or air conditioner 2b) and the information indicating the content of the event that has occurred is input by the user, the event input unit 18 receives (acquires) the input information.

  In addition, when the event which may generate | occur | produce in the air conditioner 2a (or air conditioner 2b) is limited beforehand, you may make the event input part 18 into the pushbutton type switch matched with the content of the event. . In this case, when the button is pressed, the arithmetic control unit 17 specifies the content of the event corresponding to the pressed button from the correspondence table (the table in which the button and the content of the event are associated) stored in the ROM. . Then, the arithmetic control unit 17 associates the information indicating the content of the identified event with the date and time when the button was pressed (input date and time) and the name of the air conditioner, and the associated information (generated information) The data is stored in the storage unit 19 and transmitted to the controller 6 via the communication unit 22.

  The storage unit 19 is connected to the input terminal of the calculation control unit 17. The storage unit 19 is, for example, a flash memory. The storage unit 19 stores the information indicating the contents of the event input by the user using the event input unit 18, the information in which the input date / time and the name of the air conditioner are associated, the power consumption amount, and the power consumption amount. Information in which the measured date and time and the name of the air conditioner are associated is stored.

  The timer unit 20 is connected to the input terminal of the arithmetic control unit 17. The timer unit 20 has a calendar function and a function of measuring time.

  The insulation circuit 21 connected to the input / output terminal of the arithmetic control unit 17 is connected to the input / output terminal of the communication unit 22. The insulating circuit 21 is a circuit for insulating the communication unit 22 from the power supply supplied from the power supply unit 13 (in other words, insulating from the three-phase AC power supply). The insulating circuit 21 is a photocoupler, for example.

  The communication unit 22 is configured by, for example, a communication driver. The communication unit 22 is connected to the insulation circuit 21 and to the control transmission line 3. An operation signal transmitted from the controller 6 and transmitted through the control transmission line 3 is transmitted to the communication unit 22 and the insulating circuit 21 and input to the arithmetic control unit 17. Signals and information transmitted through the control transmission line 3 correspond to a data format (a format including a transmission destination address, a transmission source address, a command, an operand, and the like) determined by a protocol on the control transmission line 3. Yes. For this reason, when an operation signal is input to the calculation control unit 17, the calculation control unit 17 refers to the field of the transmission destination address, and if the transmission destination address is an address assigned to the own device, a command or the like is issued. Reference the stored field. On the other hand, when the transmission destination address is not an address assigned to the own device, the arithmetic control unit 17 discards the operation signal.

  The address of the own device is stored in the ROM of the arithmetic control unit 17. When the power measuring device 1 is turned on, the arithmetic control unit 17 reads the address stored in the ROM, thereby recognizing the address assigned to the own device.

  Also, information transmitted by the arithmetic control unit 17, specifically, information indicating the contents of the event input by the user using the event input unit 18, the date and time of input, and the name of the air conditioner are associated with each other. And the information on which the date and time of measuring the power consumption and the power consumption and the name of the air conditioner are associated with each other is transmitted through the insulation circuit 21 and the communication unit 22 and transmitted through the control transmission line 3. Received by the controller 6. At the time of information transmission, the arithmetic control unit 17 executes access control such as CSMA / CD (Carrier Sense Multiple Access with Collision Detection) according to the protocol on the control transmission line 3.

  The power feeding unit 23 is connected to the communication unit 22 and to the control transmission line 3. The power feeding unit 23 is configured by, for example, a DC-DC converter or the like. The power feeding unit 23 generates DC power that serves as an operation power source for the communication unit 22 from the DC voltage applied to the control transmission line 3, and supplies the generated DC power to the communication unit 22. The communication unit 22 is operated by DC power supplied from the power supply unit 23.

  As shown in FIG. 3, the controller 6 that is connected to the power measuring device 1 via the control transmission line 3 and mediates the operation by the user of the air conditioner 2 includes a power supply unit 31, an input unit 32, and a storage unit 33. A timing unit 34, a calculation control unit 35, a display unit 36, an insulation circuit 37, a communication unit 38, and a power feeding unit 39.

  The power supply unit 31 generates DC power using, for example, AC power supplied from a commercial power supply, and supplies the generated DC power to the units 32 to 36. The power supply unit 31 includes, for example, a rectifier diode and a DC-DC converter.

  The input unit 32 is connected to the input terminal of the calculation control unit 35. The input unit 32 is, for example, a keyboard. An instruction to change the operation of the air conditioner 2a (or air conditioner 2b) by the operation of the input unit 32 by the user (for example, a change to an energy saving operation that realizes a power consumption smaller than the current power consumption, 2a (or an instruction to change the computer program of the control board 5 that controls the operation of the air conditioner 2b) and the like. When this instruction is given, the arithmetic control unit 35 prompts the user to input a screen prompting the user to input information indicating the content of the instruction, that is, information indicating the content of the event (information indicating the content of the change). The screen is displayed on the display unit 36. And while the information which shows the content of the event which generate | occur | produced is input by the user, the input part 32 receives the input information (acquires). When the reception is completed, the arithmetic control unit 35 associates the information indicating the content of the input event with the date and time (input timing) and the name of the air conditioner that are timed by the time measuring unit 34. (Generated information) is stored in the storage unit 33.

  The storage unit 33 is connected to the input terminal of the calculation control unit 35. The storage unit 33 is, for example, a flash memory. The storage unit 33 stores information indicating the content of the event input by the user using the input unit 32, information on the input date and time, and the name of the air conditioner. Moreover, the memory | storage part 33 shows the content of the event transmitted by the information transmitted from the electric power measurement apparatus 1 provided in each of the air conditioners 2a and 2b, specifically, the user using the event input part 18. Information in which information, the input date / time and the name of the air conditioner are associated, and information in which the power consumption and the amount of power consumption are measured and the name of the air conditioner are associated are stored.

  The timer unit 34 is connected to the input terminal of the calculation control unit 35. The timer unit 34 has a calendar function and a function of measuring time.

  The arithmetic control unit 35 has two input terminals connected to the input unit 32 and the time measuring unit 34, two input / output terminals connected to the storage unit 33 and the insulation circuit 37, respectively, and one output terminal The display unit 36 is connected.

  When the operation of the air conditioner 2a (or air conditioner 2b) by the user is accepted by the input unit 32, the arithmetic control unit 35 generates an operation signal corresponding to the operation, and the operation signal is transmitted to the insulation circuit 37 and the communication unit. Then, the data is output to the control board 5 of the air conditioners 2a and 2b.

  Moreover, the arithmetic control part 35 transmits a request command to the electric power measurement apparatus 1 provided in each of the air conditioners 2a and 2b via the insulation circuit 37 and the communication part 38, for example every 5 minutes. When each power measuring device 1 receives this request command, among the information stored in the storage unit 19 of the power measuring device 1, the power consumption, the date and time when the power consumption is measured, and the name of the air conditioner are associated with each other. The received information is transmitted to the controller 6. When the calculation control unit 35 receives this information, the calculation control unit 35 stores the received information in the storage unit 33.

  The arithmetic control unit 35 also includes information indicating the content of an event that has occurred in the air conditioner 2a (or the air conditioner 2b) among the information stored in the storage unit 19 of the power measuring device 1, the date and time of input, and the air conditioner's When the information associated with the name is received from the power measurement device 1, this information is stored in the storage unit 33.

  Further, the operation control unit 35 is instructed by the user to change the operation of the air conditioner 2a (or the air conditioner 2b) by the user's operation, and information indicating the contents of the event (information indicating the contents of the change). When input by the user, the information indicating the contents of the input event is associated with the date and time (input timing) and the name of the air conditioner being timed by the time measuring unit 34, and the associated information is stored in the storage unit. 33.

  In addition, when an instruction to display information stored in the storage unit 33 is given by the user via the input unit 32, the arithmetic control unit 35 reads the information stored in the storage unit 33 and displays the read information on the screen. To display on the display unit 36.

  Specifically, the arithmetic control unit 35 indicates the amount of power consumption measured by the power measuring device 1, information indicating the content of the event transmitted from the power measuring device 1, and the content of the event input by the input unit 32. Information is read out, and the information is associated according to the date and time (each timing). Then, the arithmetic control unit 35 processes each associated information into a screen and displays it on the display unit 36.

  For example, as shown in FIG. 4, the screen displayed on the display unit 36 represents the transition of the power consumption of the air conditioner 2a and the transition of the power consumption of the air conditioner 2b.

  Here, information indicating that the operation of the air conditioner 2a has been changed to the energy saving operation at 10:35 on the 20th is displayed on the screen of the display unit 36, and further, the air conditioner at 14:10 on the 20th. Information indicating that 2a has been washed is displayed. On the other hand, regarding the air conditioner 2b, the fact that some event has occurred is not displayed on the screen of the display unit 36.

  The screen of the display unit 36 allows the user to reduce the power consumption of the air conditioner 2a by about 1 kW · h, for example, by changing to an energy saving operation, or by cleaning the air conditioner 2a. It can be understood that the amount is reduced by about 0.5 kW · h.

  Thus, the controller 6 associates the information indicating the contents of the event that has occurred in the air conditioner 2a with the power consumption of the air conditioner 2a according to the date and time. And the controller 6 displays the information which shows the content of the event which generate | occur | produced in the air conditioner 2a with transition of the power consumption of the air conditioner 2a. Therefore, the user can confirm how much the power consumption of the air conditioner 2a (or air conditioner 2b) has changed due to which event.

  The display unit 36 illustrated in FIG. 3 is, for example, a liquid crystal display. As described above, the display unit 36 displays, for example, the screen shown in FIG.

  The insulation circuit 37 is connected to the calculation control unit 35 and to the communication unit 38. The insulation circuit 37 is a circuit for insulating the communication unit 38 from the DC power output from the power supply unit 31. The insulating circuit 37 is a photocoupler, for example.

  The communication unit 38 is connected to the insulation circuit 37 and to the control transmission line 3. The communication unit 38 is configured by, for example, a communication driver. The communication unit 38 operates with DC power supplied from the power supply unit 39.

  The power feeding unit 39 is connected to the communication unit 38 and to the control transmission line 3. The power supply unit 39 is configured by, for example, a DC-DC converter or the like. The power feeding unit 39 generates DC power that serves as an operation power source for the communication unit 38 from the DC voltage applied to the control transmission line 3, and outputs the generated DC power to the communication unit 38.

  As described above, the power measuring apparatus 1 according to the first embodiment adds the information indicating the transition of the power consumption of the air conditioners 2a and 2b to the information indicating the contents of the event that has occurred in the air conditioners 2a and 2b. It transmits to the controller 6 with the information shown. Thereby, the controller 6 can display information indicating the contents of the event on the display unit 36 in association with the transition of the power consumption. Therefore, the user can confirm how much the power consumption of the air conditioner 2a (or air conditioner 2b) has changed due to which event. In this way, the power measuring device 1 makes it easy to grasp the factors of fluctuations in the power consumption of the air conditioners 2a and 2b.

(Embodiment 2)
Next, the electric power measurement system 200 which concerns on Embodiment 2 of this invention is demonstrated with reference to FIG. 5 and FIG. The power measurement system 200 uses the air conditioner 2a (without using the air conditioner 2b), changes the power measurement device 1 to the power measurement device 40, and newly provides a display device 50. Therefore, in FIGS. 5 and 6, only the power measurement device 40 and the display device 50 will be described. Further, in the power measuring device 40, the same number is assigned to the same configuration as the power measuring device 1. Therefore, the description of the same configuration as the power measuring device 1 is omitted.

  As shown in FIG. 5, the power measurement system 200 includes an air conditioner 2 a connected to the power line 4 through the lead-in line 7, a controller 6 that mediates an operation by the user of the air conditioner 2 a, and a display device 50. Have.

  The power measuring device 40 built in the air conditioner 2 a is connected to the display device 50 via a USB (Universal Serial Bus) cable 51. As a result, the power measuring device 40 can communicate with the display device 50.

  As shown in FIG. 6, the power measuring device 40 has the same configuration as the power measuring device 1 of the first embodiment, and includes a power supply unit 13, a voltage unit 14, a current unit 15, and an A / D conversion unit. 16, an event input unit 18, a storage unit 19, a timer unit 20, and an insulating circuit 21. The power measuring device 40 includes an arithmetic control unit 61 and a communication unit 62 that are different from the power measuring device 1. The power measuring device 40 does not include the supply unit 23 included in the power measuring device 1.

  The calculation control unit 61 is the same connection as the calculation control unit 17 of the power measuring device 1.

  The arithmetic control unit 61 measures the power consumption of the air conditioner 2a as in the arithmetic control unit 17 of the power measuring device 1, and uses the measured power consumption as the date and time of measuring the power consumption and the name of the air conditioner. The data are stored in the storage unit 19 in association with each other. And the arithmetic control part 61 is the information memorize | stored in the memory | storage part 19 similarly to the arithmetic control part 17 of the electric power measurement apparatus 1 (information which matched the date and time which measured the power consumption and the power consumption, and the name of an air conditioner). ) Is transmitted to the display device 50 in response to the request command transmitted from the display device 50.

  Moreover, the calculation control part 61 is the same as the calculation control part 17 of the electric power measurement apparatus 1, When the input of the information which shows the content of the event which generate | occur | produced in the air conditioner 2a is performed by the user via the event input part 18, Information indicating the content of the input event is stored in the storage unit 19 in association with the date and time of the timekeeping unit 20 and the name of the air conditioner. At this time, unlike the calculation control unit 17 of the power measuring device 1, the calculation control unit 61 does not transmit the associated information to the display device 50. For this reason, the calculation control unit 61 transmits information stored in the storage unit 19 (information indicating the content of the event, the date and time of input of the content, and the name of the air conditioner) from the display device 50. In response to the request command, it is transmitted to the display device 50.

  Further, the calculation control unit 61 performs the following operation different from that of the calculation control unit 17 of the power measuring device 1. That is, the arithmetic control unit 61 generates an event in the air conditioner 2a when a change in the operation of the air conditioner 2a is instructed by the user via the input unit 32 (see FIG. 3), and information indicating the contents of the event When the names of the air conditioners are transmitted from the display device 50, they are received. Then, the arithmetic control unit 61 associates the information indicating the content of the received event and the name of the air conditioner with the date and time (input timing) being timed by the time measuring unit 20, and stores the associated information in the storage unit 19. To remember. The calculation control unit 61 sends a request transmitted from the display device 50 to the information stored in the storage unit 19 (information indicating the contents of the received event, the input date and time, and the name of the air conditioner). It transmits to the display apparatus 50 according to a command.

  The communication unit 62 is an interface for USB communication. The communication unit 62 is connected to the insulation circuit 21 and to the USB cable 51. The communication unit 62 operates with DC power applied to the USB cable 51. The communication unit 62 receives a request command transmitted from the display device 50 and transmits information stored in the storage unit 19.

  The display device 50 is, for example, a personal computer. The display device 50 has, for example, a keyboard as an input device, has, for example, a liquid crystal display as a monitor, and further has, for example, a hard disk drive as a storage device. The display device 50 transmits the information stored in the storage unit 19 to the display device 50 when an instruction to display the information stored in the storage unit 19 of the power measurement device 40 is given by the user via the keyboard. A request command to be requested is transmitted to the power measuring device 40 via the USB cable 51.

  When receiving the request command, the power measurement device 40 reads information stored in the storage unit 19 and transmits the read information to the display device 50 via the USB cable 51. Specifically, the power measurement device 40 associates the following information from the storage unit 19, that is, the power consumption measured by the power measurement device 40, the date and time when the power consumption was measured, and the name of the air conditioner. Information indicating the content of the event input by the event input unit 18, information indicating the input date and time and the name of the air conditioner, information indicating the content of the received event, input date and time, and air conditioning Information associated with the name of the machine is read, and the read information is transmitted to the display device 50.

  When the display device 50 receives the information read by the power measurement device 40, the display device 50 processes the received information into a screen and displays the information on, for example, a liquid crystal display. Specifically, the display device 50 includes information indicating the power consumption measured by the power measuring device 40, information indicating the content of the event input by the event input unit 18, and information indicating the content of the event input by the display device 50. Are associated according to the date and time (each timing). Then, the display device 50 processes the associated information into a screen and displays the information on, for example, a liquid crystal display.

  The screen displayed on the liquid crystal display includes, for example, information on the transition of power consumption of the air conditioner 2a shown in FIG.

  As described above, the power measurement device 40 according to the second embodiment transmits the information stored in the storage unit 19 to the display device 50 via the USB cable 51. Thereby, the display device 50 can display information indicating the contents of the event on the liquid crystal display, for example, in association with the transition of the power consumption. Therefore, the user can confirm how much the power consumption of the air conditioner 2a has changed due to which event. In this way, the power measuring device 40 facilitates grasping the cause of fluctuations in the power consumption of the air conditioner 2a.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications and applications are possible.

  For example, the power measurement devices 1 and 40 of each embodiment measure the power consumption amount of the air conditioners 2a and 2b by obtaining the power consumption amount supplied from the three-phase AC power supply, but this is not limitative. It is not a thing. That is, when the air conditioners 2a and 2b use a three-phase four-wire power source, the power measuring devices 1 and 40 obtain the amount of power supplied from the three-phase four-wire power source, thereby obtaining the air conditioners 2a and 2b. The power consumption amount 2b may be measured. In this case, the following configuration may be used. That is, the voltage terminal of the voltage unit 14 is increased by one, and the voltage terminal is connected to the lead-in wire connected to the N phase of the three-phase four-wire power source. And the voltage part 14 is set as the structure which measures the phase voltage of each phase (R phase, S phase, T phase). Moreover, the current conducting wire of the current section 15 is increased by one, and a current transformer connected to the current conducting wire is installed on the outer periphery of the lead-in wire 7b. And the electric current part 15 should just be set as the structure which measures the electric current (consumption current) IS which flows in into the air conditioner 2a (or air conditioner 2b) from the lead-in wire 7b. From the R-phase, S-phase, and T-phase phase voltages measured by this configuration, and the currents IR, IT, and IT, the power measuring devices 1 and 40 consume power that is supplied from a three-phase four-wire power source. You can ask for. With this configuration, the power measuring devices 1 and 40 can measure the power consumption of the air conditioners 2a and 2b even when power is supplied to the air conditioners 2a and 2b from the three-phase four-wire power source.

  Further, when the air conditioners 2a and 2b use a commercial power source, the power measuring devices 1 and 40 measure the power consumption of the air conditioners 2a and 2b by obtaining the power consumption amount supplied from the commercial power source. May be. In this case, the following configuration may be used. That is, the voltage terminal of the voltage unit 14 is reduced by one. And the voltage part 14 is set as the structure which measures the voltage between 2 wires. Further, the current conducting wire of the current unit 15 is reduced by one. And the electric current part 15 should just be set as the structure which measures the electric current (consumption electric current) which flows into the air conditioner 2a (or air conditioner 2b) from the lead-in wire connected to 1 line of 2 lines. From the two-line voltage measured by this configuration and the current flowing into the current flowing into the air conditioner 2a (or air conditioner 2b), the power measuring devices 1 and 40 can calculate the amount of power consumed from the commercial power supply. That's fine. With this configuration, the power measuring devices 1 and 40 can measure the power consumption of the air conditioners 2a and 2b even when power is supplied from the commercial power source to the air conditioners 2a and 2b.

  Moreover, the power measuring devices 1 and 40 of each embodiment may have a liquid crystal display, for example. In this case, when an instruction to display the information stored in the storage unit 19 on the liquid crystal display is made by the user via the event input unit 18, the power measurement devices 1 and 40 store the information stored in the storage unit 19. The read and power consumption amount is associated with information indicating the content of the event input by the event input unit 18 according to the date and time (each timing). Then, the power measurement devices 1 and 40 may process each associated information into a screen and display the information on, for example, a liquid crystal display. With this configuration, the user can check the information stored in the storage unit 19 even near the installation positions of the air conditioners 2a and 2b. In the case of this configuration, the power measurement device 1 according to the first embodiment may be configured to receive information stored in the storage unit 33 of the controller 6 and store the information in the storage unit 19. In order to realize this, the following configuration may be used. That is, the controller 6 according to the first embodiment stores the information associated with the information indicating the content of the event, the input date and time, and the information associated with the name of the air conditioner in the storage unit 33. A configuration for transmitting to the power measuring apparatus 1 is adopted. Then, the power measurement device 1 may be configured to store the received information in the storage unit 19 when receiving the information transmitted from the controller 6 (associated information).

  Moreover, in the electric power measurement apparatus 1 of Embodiment 1, when the input of the information which shows the content of the event which generate | occur | produced in the air conditioner 2a (or air conditioner 2b) is performed by the user via the event input part 18, it inputs The information indicating the contents of the event is stored in the storage unit 19 in association with the date and time of the timekeeping unit 20 and the name of the air conditioner, and the associated information is stored in the controller via the communication unit 22. Although it transmitted to 6, it is not restricted to this. That is, the power measurement device 1 may be configured to store the associated information in the storage unit 19 while not storing the associated information in the storage unit 19 when storing the associated information in the storage unit 19. In the case of this configuration, the power measuring apparatus 1 sets the power consumption and the power consumption in accordance with a request command periodically transmitted from the controller 6 to the information (associated information) stored in the storage unit 19. What is necessary is just to transmit to the controller 6 with the information (information memorize | stored in the memory | storage part 19) which matched the measured date and the name of an air conditioning machine.

  In addition, the power measurement device 40 and the display device 50 according to the second embodiment perform communication using the USB method, but the present invention is not limited to this. That is, the power measurement device 40 and the display device 50 may perform communication by a method such as RS-232C or RS-485, or may perform optical communication using an optical fiber as a medium.

  Further, the display device 50 according to the second embodiment displays information indicating the contents of the event that has occurred in the air conditioner 2a, for example, on a liquid crystal display in association with the transition of the power consumption of the air conditioner 2a and the date and time. It is not limited to. That is, the display device 50 is connected to, for example, the display device 50 without displaying the information indicating the content of the event that has occurred in the air conditioner 2a, the transition of the power consumption of the air conditioner 2a, and the date and time on the liquid crystal display, for example. It may be printed (displayed) on paper using an existing printer. Even with such printing (display), the user can check how the power consumption of the air conditioner 2a has changed due to the occurrence of an event.

  In the above embodiment, the program executed by the arithmetic control units 17, 35, 61 is a flexible disk, a CD-ROM (Compact Disc Read-Only Memory), a DVD (Digital Versatile Disc), an MO (Magneto-). An optical disc) is stored in a computer-readable recording medium and distributed, and the program is installed in the computer to configure a device that performs the same control as the arithmetic control units 17, 35, and 61. Also good.

  Further, the above-described program may be stored in a disk device or the like of a predetermined server device on a communication network such as the Internet, and may be downloaded, for example, superimposed on a carrier wave.

  Further, when the above-described program executed by the arithmetic control units 17, 35, 61 is realized by sharing each OS (Operating System), or when the program is realized by cooperation between the OS and the application, etc. Only the part other than the OS may be stored and distributed in a medium, or may be downloaded.

  Various embodiments and modifications can be made to the present invention without departing from the broad spirit and scope of the present invention. The above-described embodiments are for explaining the present invention and do not limit the scope of the present invention. In other words, the scope of the present invention is indicated by the scope of claims, not the embodiment described above. Various modifications within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

DESCRIPTION OF SYMBOLS 1,40 Power measuring device 2 Air conditioner 3 Control transmission line 4 Power line 5 Control board 6 Controller 7 Lead-in wire 11 Voltage lead wire 12 Current lead wire 13, 31 Power source portion 14 Voltage portion 15 Current portion 16 A / D conversion portion 17 , 35, 61 Arithmetic control unit 18 Event input unit 19, 33 Storage unit 20, 34 Timing unit 21, 37 Insulation circuit 22, 38, 62 Communication unit 23, 39 Power supply unit 32 Input unit 36 Display unit 50 Display device 51 USB cable 100,200 Power measurement system

Claims (7)

A measurement generation unit that measures the power consumption of the measurement target device for each predetermined timing, and generates information in which the measured power consumption is associated with the measurement timing;
When a change in the state of the measurement target device affecting the power consumption occurs and information indicating the content of the change is input, an acquisition unit that acquires information indicating the content of the input change; ,
A correspondence generation unit that generates information in which the information indicating the content of the change acquired by the acquisition unit is associated with the input timing;
Information in which the timing of the measurement generated by the measurement generation unit and the power consumption are associated with each other, and the input timing generated by the correspondence generation unit and information indicating the content of the change are associated with each other A storage unit comprising a non-volatile memory for storing the received information;
An output unit that outputs the information stored in the storage unit to the external device in response to a request from the external device ;
The information indicating the content of the change is information indicating the content of the change caused by maintenance of the measurement target device.
A total of measuring apparatus. The acquisition unit receives an input of information indicating the content of the change,
The measuring device according to claim 1, comprising: The acquisition unit is a receiving unit that receives information indicating the content of the change from an external device,
The measuring device according to claim 1 or 2. The information indicating the content of the change is information indicating a change in a computer program for controlling the operation of the measurement target device.
The measuring device according to any one of claims 1 to 3. A display unit that acquires information output by the output unit and displays the power consumption amount and the information indicating the content of the change in association with each other according to the timing;
The measuring device according to any one of claims 1 to 4 , further comprising: A measurement generation step of measuring a power consumption amount of a measurement target device, measuring the power consumption amount at every predetermined timing, and generating information in which the measured power consumption amount is associated with a measurement timing;
When the change of the state of the measurement target device that affects the power consumption occurs and the information indicating the content of the change is input, the measurement device displays information indicating the content of the input change. An acquisition step to acquire;
A correspondence generation step in which the measurement device generates information in which the information indicating the content of the change acquired in the acquisition step is associated with the timing of the input;
The measurement device indicates information in which the measurement timing generated in the measurement generation step is associated with the power consumption, and the input timing generated in the correspondence generation step and the content of the change. A storage step of storing information associated with the information in a nonvolatile memory;
The measuring device includes an output step of outputting the information stored in the nonvolatile memory in the storing step to the external device in response to a request from the external device ,
The information indicating the content of the change is information indicating the content of the change caused by maintenance of the measurement target device.
Total measurement method. To the computer that controls the measuring device that measures the power consumption of the measurement target device,
A measurement generation function for measuring the power consumption at every predetermined timing and generating information in which the measured power consumption is associated with the measurement timing;
When a change in the state of the measurement target device that affects the power consumption occurs and information indicating the content of the change is input, an acquisition function that acquires information indicating the content of the input change,
A correspondence generation function for generating information in which the information indicating the content of the change acquired by the acquisition function is associated with the input timing;
Information in which the measurement timing generated by the measurement generation function is associated with the power consumption amount, and the input timing generated by the correspondence generation function are associated with information indicating the content of the change. Storage function for storing stored information in a non-volatile memory,
An output function for outputting the information stored in the nonvolatile memory by the storage function to the external device in response to a request from the external device ,
The information indicating the content of the change is information indicating the content of the change caused by maintenance of the measurement target device.
Program.

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