JP6243464B2 - Management device, management system, and management method - Google Patents

Description

  The present invention relates to a management device, a management system, and a management method for managing energy usage.

  2. Description of the Related Art In recent years, an energy management apparatus that manages energy usage in a grid power consumer is known (for example, Patent Document 1). In particular, a residential energy management apparatus is referred to as a HEMS (Home Energy Management System).

  In addition, a technique is known in which an energy management apparatus manages energy usage in a consumer by using a measuring instrument (hereinafter referred to as “meter”) including a pulse signal transmitter. Such a meter outputs one pulse each time a predetermined amount of energy (hereinafter referred to as “unit energy amount”) is detected (for example, Patent Document 2).

  The energy management device calculates a value obtained by multiplying the number of pulses received from the meter (the number of received pulses) by an energy amount (pulse rate) per pulse as an energy usage amount.

JP 2011-129085 A JP 2008-224390 A

  By the way, the meter is connected to a plurality of wires including a signal line and a ground line, but the number of received pulses in the energy management device differs depending on the number of signal lines connected to the meter. Therefore, the energy management apparatus can also calculate the energy usage amount using a numerical value obtained by replacing the pulse rate according to the number of signal lines instead of the pulse rate. However, in the meter specifications, the pulse rate includes a unit energy amount described as it is and a unit energy amount read according to the number of signal lines.

  Therefore, if the pulse rate described in the specification is set in the energy management apparatus, the energy management apparatus may not be able to calculate the energy usage correctly.

  Then, an object of this invention is to provide the management apparatus, management system, and management method which can calculate an energy usage-amount correctly.

The management device according to the first feature includes a pulse receiving unit that receives a pulse from a meter that measures an amount of energy in a consumer via a predetermined number of signal lines, and a per-pulse according to the number of the signal lines. A control unit that receives an input of a pulse rate that is an energy amount, and a storage unit that stores a unit flow rate, the number of signal lines, and a reference pulse rate corresponding to a flow rate indicated by one received pulse. The unit calculates the amount of energy used by the consumer based on the number of the signal lines, the number of received pulses, and the input pulse rate.

A management system according to a second feature is a management system including a meter that measures an amount of energy in a consumer and outputs a pulse via a predetermined number of signal lines, and an energy management device that receives the pulse. The energy management device includes a control unit that receives an input of a pulse rate that is an energy amount per pulse according to the number of the signal lines, a unit flow rate, the number of the signal lines, and one received pulse. A storage unit that stores a reference pulse rate corresponding to the flow rate indicated, and the control unit is configured to provide the consumer based on the number of the signal lines, the number of received pulses, and the input pulse rate. It is characterized by calculating the amount of energy used.

A management method according to a third feature is applied to an energy management apparatus that receives a pulse in an energy management system having a meter that measures an energy amount in a consumer and outputs a pulse through a predetermined number of signal lines. The energy management apparatus includes a step of receiving an input of a pulse rate that is an energy amount per pulse corresponding to the number of the signal lines, and a received 1 stored in the storage unit. A step of calculating an energy usage amount of the consumer based on a reference pulse rate calculated based on the number of signal lines, the number of received pulses, and the input pulse rate, corresponding to a flow rate indicated by one pulse It is characterized by comprising.

  ADVANTAGE OF THE INVENTION According to this invention, the management apparatus, management system, and management method which can calculate energy usage correctly can be provided.

FIG. 1 is a diagram showing an energy management system according to the present embodiment. FIG. 2 is a diagram illustrating the meter according to the present embodiment. FIG. 3 is a block diagram showing the EMS according to the present embodiment. FIG. 4 is a diagram illustrating a table stored in the storage unit of the EMS according to the present embodiment. FIG. 5 is a diagram showing an example of display on the display unit according to the present embodiment. FIG. 6 is a flowchart showing the energy management method according to the present embodiment.

  Hereinafter, an energy management system, a management apparatus, and an energy management method according to an embodiment of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals.

  However, it should be noted that the drawings are schematic and ratios of dimensions and the like are different from actual ones. Therefore, specific dimensions and the like should be determined in consideration of the following description. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included between the drawings.

[Outline of Embodiment]
The energy management apparatus according to the embodiment receives the pulse in an energy management system including a meter that outputs a pulse via a predetermined number of signal lines. The energy management apparatus includes a control unit that calculates a value obtained by multiplying the number of received pulses by a pulse rate, which is an energy amount per pulse, as an energy usage amount. The control unit is a case where the pulse rate is designated, and the combination of the number of the signal lines and the designated pulse rate is determined by the number of the signal lines and the received one pulse. When the specific combination is different from the reference combination that is a combination with the reference pulse rate that is the energy amount to be displayed, the reference pulse rate is used for the calculation of the energy usage amount instead of the designated pulse rate. .

  Thus, it is possible to provide an energy management device, an energy management system, and an energy management method that can correctly calculate the amount of energy used.

[This embodiment]
(Energy management system)
Below, the energy management system which concerns on this embodiment is demonstrated. FIG. 1 is a diagram showing an energy management system 100 according to the present embodiment.

  As shown in FIG. 1, the energy management system 100 includes a distribution board 110, a load 120, a PV device 130, a storage battery device 140, a fuel cell device 150, a hot water storage device 160, a meter 180, and an EMS 200. And a display device 255. Each device may be connected to the power line in any order.

  The distribution board 110 is connected to the system. Distribution board 110 is connected to load 120, PV device 130, storage battery device 140, and fuel cell device 150 via a power line.

  The load 120 is a device that consumes power supplied via a power line. For example, the load 120 includes devices such as a refrigerator, a freezer, lighting, and an air conditioner.

  The PV device 130 includes a PV 131 and a PCS 132. The PV 131 is an example of a power generation device, and is a solar power generation device that generates power in response to reception of sunlight. The PV 131 outputs the generated DC power. The amount of power generated by the PV 131 changes according to the amount of solar radiation applied to the PV 131. The PCS 132 is a device (Power Conditioning System) that converts DC power output from the PV 131 into AC power. The PCS 132 outputs AC power to the distribution board 110 via the power line.

  The storage battery device 140 includes a storage battery 141 and a PCS 142. The storage battery 141 is a device that stores electric power. The PCS 142 is a device (Power Conditioning System) that converts AC power supplied from the distribution line 31 (system) into DC power. Further, the PCS 142 converts DC power output from the storage battery 141 into AC power.

  The fuel cell device 150 includes a fuel cell 151 and a PCS 152. The fuel cell 151 is an example of a power generation device, and is a device that outputs electric power using fuel gas. The fuel cell 151 may be, for example, a SOFC (Solid Oxide Fuel Cell) or a PEFC (Polymer Electrolyte Fuel Cell). The PCS 152 is a device (Power Conditioning System) that converts DC power output from the fuel cell 151 into AC power.

  The hot water storage device 160 is an example of a heat storage device that converts electric power into heat, accumulates the converted heat as hot water, and stores heat generated by a cogeneration device such as the fuel cell device 150 as hot water. Specifically, the hot water storage device 160 has a hot water storage tank, and warms water supplied from the hot water storage tank by exhaust heat generated by the operation (power generation) of the fuel cell 151. Specifically, the hot water storage device 160 warms the water supplied from the hot water storage tank and returns the heated hot water to the hot water storage tank.

  The meter 180 is a device that measures the amount of energy used by consumers. When the meter 180 detects energy corresponding to the unit energy amount, the meter 180 outputs a pulse to the EMS 200. For example, the meter 180 is a gas meter for measuring the amount of gas used. Alternatively, meter 180 may be a water meter for metering water usage when energy is interpreted as a resource required for life or production.

  The EMS 200 is an example of an energy management device, and is a device (Energy Management System) that controls the PV device 130, the storage battery device 140, the fuel cell device 150, and the hot water storage device 160. Specifically, the EMS 200 is connected to the PV device 130, the storage battery device 140, the fuel cell device 150, and the hot water storage device 160 via signal lines. The EMS 200 controls the PV device 130, the storage battery device 140, the fuel cell device 150, and the hot water storage device 160 using signals that comply with a communication protocol such as Echonet Lite or Zig Bee (registered trademark).

  Further, the EMS 200 manages the energy usage measured by the meter 180. Specifically, the EMS 200 receives a pulse output from the meter 180 via a signal line, and calculates an energy usage amount based on the received pulse.

  The display device 255 is connected to the EMS 200, and displays various types of information stored in the EMS 200 by using an application. The connection format between the EMS 200 and the display device 255 may be wired or wireless. In addition, the display device 255 may be a touch panel that accepts user input. In such a case, the user inputs information for controlling the device connected to the EMS 200 via the display device 255, and the display device 255 transmits the control information input by the user to the EMS 200. .

(Configuration of meter and EMS)
Below, the meter and EMS which concern on this embodiment are demonstrated. FIG. 2 is a diagram illustrating a configuration of the meter 180 according to the present embodiment. FIG. 3 is a block diagram showing the EMS 200. FIG. 4 is a diagram illustrating a table stored in the storage unit 220 of the EMS 200 according to the present embodiment.

  First, the configuration of the meter 180 will be described. As shown in FIG. 2, the meter 180 includes a meter main body 181 and a pulse transmitter 182. Further, the meter 180 is connected to a plurality of wirings 183.

  The meter main body 181 is provided in a pipe 180P that transmits energy. Hereinafter, gas will be described as an example of energy, and a gas meter will be described as an example of meter 180.

  The meter main body 181 has a flow rate signal generator such as a magnet type. The flow signal generator operates when it detects gas flowing through the pipe 180P (gas pipe), and outputs a flow signal to the pulse transmitter 182. The pulse transmitter 182 integrates the input flow rate signal, and outputs a pulse through the plurality of wires 183 when the integrated value reaches a unit flow rate (unit energy amount). The unit flow rate is set for each meter.

  The plurality of wirings 183 include a signal line 183S and a ground line 183G. For example, the plurality of wirings 183 include one ground line 183G and one or more signal lines 183S. Specifically, a meter connected to one signal line 183S and one ground line 183G is called a two-wire meter, and a meter connected to two signal lines 183S and one ground line 183G. Is called a three-wire meter. The pulse output from the pulse transmitter 182 is transmitted through the signal line 183S.

  Here, it should be noted that when the pulse transmitter 182 outputs a pulse, the number of pulses corresponding to the number of the signal lines 183S is transmitted through the signal line 183S. In other words, when the two-wire meter detects a gas corresponding to the unit flow rate and outputs one pulse, the number of received pulses in the EMS 200 is one. On the other hand, when the three-wire meter detects a gas corresponding to the unit flow rate and outputs one pulse, the number of received pulses in the EMS 200 is two. That is, the number of pulses received by the EMS 200 is n times the number of pulses output by the meter 180 when the number of signal lines 183S connected to the meter 180 is n (n ≧ 2).

  By the way, in the specifications of the meter 180, the flow rate per pulse is described as the pulse rate. In general, the flow rate per pulse (ie, unit flow rate) output from the meter 180 is described as the pulse rate. On the other hand, it should be noted that in the specification of the meter 180, there is a case where the flow rate per pulse received by the EMS 200 from the meter 180 is described as the pulse rate.

  Next, the configuration of the EMS 200 will be described. As illustrated in FIG. 3, the EMS 200 includes a communication unit 210, a storage unit 220, a pulse reception unit 230, a control unit 240, and a display unit 250.

  The communication unit 210 transmits / receives various signals to / from the connected device via a signal line. For example, the communication unit 210 may receive information indicating the power generation amount of the PV 131 from the PV device 130. The communication unit 210 may receive information indicating the storage amount V of the storage battery 141 from the storage battery device 140. The communication unit 210 may receive information indicating the power generation amount of the fuel cell 151 from the fuel cell device 150. The communication unit 210 may receive information indicating the amount of hot water stored in the hot water storage device 160 from the hot water storage device 160. For example, when the display device 255 is a touch panel, the communication unit 210 may receive information input by the user via the display device 255 from the display device 255. Moreover, the communication part 210 transmits the signal for controlling the PV apparatus 130, the storage battery apparatus 140, the fuel cell apparatus 150, and the hot water storage apparatus 160 to each apparatus, for example.

  The storage unit 220 stores information received by the communication unit 210. In addition, the storage unit 220 stores control information set by the control unit 240 in order to control the connected device.

  As illustrated in FIG. 4, the storage unit 220 includes a table that stores information on the pulse rate. Specifically, the storage unit 220 stores the meter type, the unit flow rate, the number of signal lines, and the reference pulse rate in association with each other. The meter type is information for identifying the type of energy (for example, gas or water) measured by the meter. The unit flow rate is, for example, 10 L, 100 L, or 1000 L for a gas meter, and 1 L, 10 L, or 100 L for a water meter. The number of signal lines is a value obtained by subtracting the number of ground lines 183G (for example, one) from the number of wirings 183. The reference pulse rate is a numerical value obtained by dividing the unit flow rate by the number of signal lines, as will be described in detail later.

  The pulse receiving unit 230 receives a pulse output from the meter 180 via the signal line 183S.

  The control unit 240 controls the load 120, the PV device 130, the storage battery device 140, the fuel cell device 150, the hot water storage device 160, and the display device 255 using signals that comply with a communication protocol such as Echonet Lite.

  In the present embodiment, the control unit 240 calculates a gas usage amount (energy usage amount) by multiplying the number of pulses received by the pulse receiving unit 230 by the pulse rate.

  The control unit 240 acquires the pulse rate described in the specifications of the meter 180 via the input of the user (or setting contractor) and uses it for calculation of the gas usage. However, as described above, the pulse rate includes a flow rate per pulse output from the meter 180 (that is, a unit flow rate) and a flow rate per pulse received from the meter 180. Specifically, in a three-wire meter having two signal lines 183S, when the unit flow rate is 10L, there are cases where the pulse rate is described as 10L in the specification, and the pulse rate is described as 5L. There are also cases. In the former case, if the number of received pulses is multiplied by the pulse rate, a value that is twice the actual gas consumption will be calculated.

  Therefore, the control unit 240 refers to the storage unit 220 and acquires a reference combination that is a combination of the number of signal lines 183S and the reference pulse rate. The reference pulse rate corresponds to the flow rate indicated by one received pulse, and is a numerical value that can be used to calculate the amount of gas used by multiplying the number of received pulses. Specifically, the reference pulse rate is a numerical value obtained by dividing the unit flow rate by the number of signal lines as described above. In the table shown in FIG. 4, the reference combination corresponds to the combination of the number of signal lines and the corresponding reference pulse rate. The control unit 240 compares the combination of the designated number of signal lines 183S and the designated pulse rate (hereinafter referred to as “designated combination”) with the reference combination. When the designated combination matches the reference combination, the control unit 240 multiplies the designated pulse rate and the number of received pulses to calculate the gas usage amount.

  When the designated combination is different from the reference combination, the control unit 240 compares the designated combination with a specific combination. The specific combination is a combination of the number of signal lines 183S and the flow rate indicated by a plurality of pulses received simultaneously via all the signal lines 183S (that is, the unit flow rate per pulse output from the meter 180). Equivalent to. In the table shown in FIG. 4, the specific combination corresponds to the combination of the number of signal lines and the corresponding unit flow rate. When the designated combination matches the specific combination, the control unit 240 calculates the gas usage by multiplying the reference pulse rate and the number of received pulses instead of the designated pulse rate.

  The display unit 250 has a function similar to that of the display device 255 described above. The display unit 250 visualizes and displays various information stored in the storage unit 220 by an application. Display unit 250 may be a touch panel that accepts user input. In such a case, the user may input information for controlling the device connected to the EMS 200 via the display unit 250.

(Display section)
FIG. 5 shows an example of display on the display unit in the present embodiment. In the present embodiment, the display unit 250 displays a plurality of options for designating a combination of the number of signal lines 183S and a pulse rate.

  Specifically, as shown in FIG. 5A, the display unit 250 displays a wiring option 251 for designating the number of wirings 183 and a pulse rate option 252 for designating a pulse rate. The wiring option 251 includes a radio button 251a for designating a two-wire meter including one signal line 183S and a radio button 251b for designating a three-wire meter including two signal lines 183S. . The display unit 250 accepts an operation for selecting a radio button corresponding to the number of wires 183 of the meter 180 from the wiring options 251 from the user.

  As illustrated in FIG. 5B, when the radio button 251 a is selected from the wiring options 251, the display unit 250 displays a pull-down menu 252 a corresponding to the two-wire meter from the pulse rate options 252. To do. The pull-down menu 252a shows options for selecting a pulse rate corresponding to the two-wire meter. The display unit 250 accepts an operation for selecting a numerical value corresponding to the pulse rate described in the specifications of the meter 180 from the pull-down menu 252a from the user.

  As illustrated in FIG. 5C, when the radio button 251 b is selected from the wiring options 251, the display unit 250 displays a pull-down menu 252 b corresponding to the 3-wire meter from the pulse rate options 252. To do. The pull-down menu 252b shows options for selecting the pulse rate corresponding to the 3-wire meter. Here, in the specification of the meter 180, in order to cope with both the case where the unit flow rate is described as the pulse rate and the case where the reference pulse rate is described as the pulse rate, the pull-down menu 252b It should be noted that in addition to the pulse rate, unit flow is also shown. The display unit 250 accepts an operation for selecting a numerical value corresponding to the pulse rate described in the specifications of the meter 180 from the pull-down menu 252b from the user.

  The control unit 240 obtains the number and pulse rate of the wiring 183 designated via the wiring option 251 and the pulse rate option 252 displayed by the display unit 250, and the designated combination of the number of signal lines 183S and the pulse rate. Is identified. When the designated combination matches the reference combination, the control unit 240 multiplies the designated pulse rate and the number of received pulses to calculate the gas usage amount. When the designated combination is different from the reference combination and matches the specific combination, the control unit 240 multiplies the reference pulse rate by the number of received pulses instead of the designated pulse rate, and uses the gas. Calculate the amount.

(Energy management method)
Hereinafter, an energy management method according to the present embodiment will be described. FIG. 6 is a flowchart showing the energy management method according to the present embodiment.

  In step S100, the EMS 200 receives an operation for designating the number of signal lines 183S from the user. Next, in step S110, the EMS 200 receives an operation for designating a pulse rate from the user. The number of signal lines 183S and the pulse rate are specified based on the selection by the user from among a plurality of options displayed on the display unit 250. However, the selection is not limited to a plurality of options, and the user may input a value indicating the number of signal lines 183S and a value indicating the pulse rate.

  In step S120, the EMS 200 determines whether or not the specified combination matches the reference combination. If the determination result is “YES”, the EMS 200 proceeds to the process of step S130. In step S130, the EMS 200 multiplies the designated pulse rate and the number of received pulses to calculate an energy usage amount (for example, a gas usage amount). If the determination result is “NO” in step S120, the EMS 200 proceeds to the process of step S140. In step S140, the EMS 200 determines whether or not the specified combination matches a specific combination. If the determination result is “YES”, the EMS 200 proceeds to the process of step S150. In step S150, the EMS 200 calculates the energy usage by multiplying the reference pulse rate and the number of received pulses instead of the designated pulse rate. If the determination result is “NO” in step S140, the EMS 200 determines that there is an error in either the number of the designated signal line 183S or the pulse rate, and ends the process.

  As described above, in the present embodiment, the EMS 200 calculates a value obtained by multiplying the number of received pulses by a pulse rate that is an energy amount per pulse as an energy usage amount. The EMS 200 is a case where a pulse rate is designated, and the combination of the number of signal lines 183S and the designated pulse rate is received via the number of signal lines 183S and one signal line 183S. In the case of a specific combination different from the reference combination that is a combination with the reference pulse rate that is the energy amount indicated by one pulse, the reference pulse rate is used to calculate the energy usage instead of the specified pulse rate. use. As a result, the EMS 200 can correctly calculate the energy usage.

[Other Embodiments]
Although the present invention has been described with reference to the above-described embodiments, it should not be understood that the descriptions and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

The EMS 200 may be a HEMS (Home Energy Management System), or a SEMS (Store Energy Management).
System), BEMS (Building Energy Management System), or FEMS (Factor Energy Management System).

  In the embodiment, the energy management system 100 includes a load 120, a PV device 130, a storage battery device 140, a fuel cell device 150, and a hot water storage device 160. However, the energy management system 100 only needs to include at least one of the load 120 and the PV device 130, the storage battery device 140, the fuel cell device 150, and the hot water storage device 160.

  In the embodiment, gas or water has been exemplified as energy for measuring the amount of use by the meter 180. However, the meter 180 may be a meter for measuring the power usage. In such a case, the energy management system 100 may include the meter 180 in the distribution board 110, for example.

  In the embodiment, the display unit 250 displays a plurality of options for designating the number of wirings 183 and the pulse rate. However, instead of the display unit 250, the display device 255 may display a plurality of options for designating the number of wirings 183 and the pulse rate.

  In the embodiment, the display unit 250 displays the radio buttons 251a and 251b as a plurality of options for selecting the number of wirings 183. However, the display unit 250 may display the radio buttons 251a and 251b as a plurality of options for selecting the number of signal lines 183S instead of the number of wirings 183.

DESCRIPTION OF SYMBOLS 100 ... Energy management system 110 ... Distribution board 120 ... Load 130 ... PV device 131 ... PV 132 ... PCS 140 ... Storage battery device 141 ... Storage battery 142 ... PCS 150 ... Fuel cell device 151 ... Fuel cell, 152 ... PCS, 160 ... Hot water storage device, 180 ... Meter, 180P ... Piping, 181 ... Meter body, 182 ... Pulse transmitter, 183 ... Wiring, 183S ... Signal wire, 183G ... Grounding wire, 200 ... EMS, 210 ... Communication unit, 220 ... Storage unit, 230 ... Pulse receiving unit, 240 ... Control unit, 250 ... Display unit, 255 ... Display device

Claims (6)

A pulse receiving unit that receives a pulse from a meter that measures the amount of energy in a consumer via a predetermined number of signal lines;
A control unit that receives an input of a pulse rate that is an energy amount per pulse according to the number of the signal lines;
A storage unit that stores a unit flow rate, the number of the signal lines, and a reference pulse rate corresponding to a flow rate indicated by one received pulse;
The said control part calculates the energy usage-amount of the said consumer based on the number of the said signal lines, the number of received pulses, and the said input pulse rate.   The management apparatus according to claim 1, wherein the control unit outputs a plurality of signals indicating the pulse rate according to reception of the number of signal lines.   The management apparatus according to claim 2, wherein the control unit displays a plurality of different pulse rates according to the number of the signal lines as the plurality of pulse rates.   The management device according to claim 1, wherein the meter is a gas meter that measures the amount of gas used or a water meter that measures the amount of water used. A meter that measures the amount of energy in a consumer and outputs a pulse via a predetermined number of signal lines;
A management system comprising an energy management device for receiving the pulses,
The energy management device includes a control unit that receives an input of a pulse rate that is an energy amount per pulse according to the number of the signal lines;
A storage unit that stores a unit flow rate, the number of the signal lines, and a reference pulse rate corresponding to a flow rate indicated by one received pulse;
The said control part calculates the energy usage-amount of the said consumer based on the number of the said signal lines, the number of received pulses, and the said input pulse rate. In an energy management system having a meter that measures the amount of energy in a consumer and outputs a pulse via a predetermined number of signal lines, the management method is applied to an energy management device that receives the pulse,
The energy management device receiving an input of a pulse rate that is an energy amount per pulse according to the number of the signal lines;
It corresponds to the flow rate indicated by one received pulse stored in the storage unit, and is based on the reference pulse rate calculated based on the number of signal lines, the number of received pulses, and the input pulse rate. And a step of calculating energy usage of the consumer.

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