JP2018102130A - Transmission device and transmission method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmission device and a transmission method capable of efficiently transmitting data having high importance.SOLUTION: A transmission device (101) comprises: an acquisition unit (121) for acquiring power consumption of each of a plurality of power loads; a communication unit (125) for transmitting data based on the power consumption to a server through a network; and a control unit (127) for acquiring degree of congestion of the network. The control unit (127) determines degree of importance of the data on the basis of the degree of congestion, and controls the communication unit (125) so as to preferentially transmit the data in descending order of the degree of importance.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a transmission apparatus and a transmission method.

  In recent years, there has been a demand for power saving in each store, home, building, etc. (hereinafter abbreviated as each store, etc.) against the background of fear of power shortage and demand for global environmental protection. Especially in summer and winter, the demand for electric power increases, and the power consumption in each store may exceed the contracted electric power. Therefore, in order to save power effectively so that the power consumption does not exceed the contract power, the power consumption in each store is monitored and the power consumption of various electrical products (hereinafter referred to as power loads) is controlled. A so-called BEMS (Building and Energy Management System) has been proposed. In BEMS, the power sensor detects the power consumption of each power load, and transmits the detected power consumption data to, for example, a remote server. And a server transmits the control signal according to power consumption to each power load, monitoring power consumption, and the power consumption of each power load is reduced efficiently.

  Here, when the amount of data from the power sensor increases with an increase in the number of power loads, a traffic load or a server load increases in data transmission to the server. Then, data acquired by the power sensor may not be transmitted to the server within a certain time, and control according to the current power consumption may not be performed.

  Thus, for example, a method has been devised in which transmission is performed while reducing the amount of data when the traffic load increases (see, for example, Patent Document 1). In the method described in Patent Document 1, the transmission apparatus acquires traffic amount information on the network prior to data transmission to the reception apparatus (server). Then, when the acquired traffic volume information is larger than a predetermined value, the transmission device changes the data attribute (resolution, etc.), and transmits the data with a reduced data volume.

JP 2000-216932 A

  However, since the transmission apparatus of Patent Document 1 does not change the attributes of only a part of the data to be transmitted, the entire data becomes rough to reduce the amount of data, and the quality of the entire data is degraded. Even if the attribute of only a part of the data is changed, there is a possibility that only the attribute of the data having high importance is changed because no consideration is given to the weighting of the data. In this case, the receiving device cannot acquire accurate information from highly important data.

  Accordingly, an object of the present invention made in view of the above problems is to provide a transmission apparatus and a transmission method capable of efficiently transmitting highly important data.

In order to solve the above-described problems, the invention of the transmitting apparatus according to the first aspect is as follows:
An acquisition unit for acquiring the power consumption of each of the plurality of power loads;
A communication unit that transmits predetermined data to a server at a first transmission time via a network, and receives a response signal for the predetermined data from the server at a first reception time;
And a control unit that determines whether to transmit data based on the power consumption based on a time from the first transmission time to the first reception time.
Moreover, the invention which concerns on a 2nd viewpoint WHEREIN: In the transmitter which concerns on a 1st viewpoint, the said control part is
When the time from the first transmission time to the first reception time is equal to or longer than a predetermined time, the communication unit is controlled to preferentially transmit highly important data. It is.

The invention according to a third aspect is the transmission device according to the second aspect, wherein the control unit is
The sum of the power consumption as main data,
It is characterized in that the main data has the highest importance.

Further, the invention according to the fourth aspect is that, in the transmission device according to the third aspect, when the time from the first transmission time to the first reception time is equal to or greater than a first time threshold, Is
Based on the power consumption, calculate the distribution type power consumption for each power distribution method as sub-data,
The importance of the sub-data is increased next to the main data.

The invention according to a fifth aspect is the transmission device according to the fourth aspect, wherein the time from the first transmission time to the first reception time is less than the first time threshold. When the second time threshold is smaller than the time threshold, the control unit
Comparing the sum to a power threshold;
If the sum is greater than or equal to the power threshold,
The power consumption as sub-data,
Increase the importance of the sub data next to the main data,
Among the sub-data, the importance is increased as the power consumption increases in the instantaneous value or the change amount.

The invention according to a sixth aspect is that, in the transmission device according to the fifth aspect, when the sum is less than the power threshold, the control unit
Based on the power consumption, calculating the phase power consumption for each voltage line with the same ground voltage as sub-data,
Compare the power difference of the phase power consumption with the power difference threshold,
When the power difference is equal to or greater than the power difference threshold, the importance of the sub data is set next to that of the main data.

Moreover, the invention which concerns on a 7th viewpoint WHEREIN: When the said power difference is less than the said power difference threshold value in the transmission apparatus which concerns on a 6th viewpoint, the said control part is
Based on the power consumption, calculate the load type power consumption for each type of power load as sub-data,
Increase the importance of the sub data next to the main data,
Among the sub-data, the load type power consumption having a larger instantaneous value has a higher importance.

Moreover, the invention which concerns on an 8th viewpoint WHEREIN: When the said sum total is less than the said power threshold value in the transmission apparatus which concerns on a 5th viewpoint, the said control part is
Compare the transmission charge and the charge threshold in the network,
When the transmission charge is equal to or higher than the charge threshold, based on the power consumption, the power distribution type power consumption for each power distribution method is calculated as sub-data, and the importance of the sub-data is the second highest after the main data. It is characterized by doing.

Further, the invention according to a ninth aspect is the transmission device according to any one of the fourth to eighth aspects, wherein the control unit includes:
Of the acquired power consumption, power consumption different from the sub data is the untransmitted data,
The importance of the untransmitted data is increased next to the sub data.

Further, the invention according to a tenth aspect is the transmission device according to the ninth aspect, wherein the control unit is
Compare the transmission charge and the charge threshold in the network,
When the transmission fee is equal to or higher than the fee threshold, the communication unit is controlled not to transmit the untransmitted data.

The invention according to an eleventh aspect is the transmission device according to any one of the fifth to eighth aspects, wherein the time from the first transmission time to the first reception time is the second time threshold value. If it is less than the control unit,
The power consumption as sub-data,
Increase the importance of the sub data next to the main data,
Among the sub-data, the importance of each power consumption is the same.

The invention according to a twelfth aspect is the transmitter according to the third aspect,
The communication unit receives a signal specifying data to be transmitted by the transmission device from the server,
The control unit increases the importance of the data to be transmitted next to the main data.

  As described above, the solution of the present invention has been described as an apparatus. However, the present invention can be realized as a method, a program, and a storage medium storing the program, which are substantially equivalent thereto, and the scope of the present invention. It should be understood that these are also included.

For example, the invention of the power control method according to the thirteenth aspect for realizing the present invention as a method is as follows:
A transmission method in a transmission device that communicates with a server via a network,
Obtaining power consumption of each of a plurality of power loads;
Transmitting predetermined data to the server at a first transmission time via the network;
Receiving a response signal for the predetermined data from the server at a first reception time;
Determining whether to allow data transmission based on the power consumption based on a time from the first transmission time to the first reception time.

  According to the transmission apparatus and the transmission method according to the present invention configured as described above, highly important data can be efficiently transmitted.

FIG. 1 is a schematic configuration diagram of a power control system according to an embodiment of the present invention. FIG. 2 is a functional block diagram showing a schematic configuration of a transmission apparatus according to an embodiment of the present invention. FIG. 3 is a flowchart showing processing of the transmission apparatus according to the embodiment of the present invention. FIG. 4 is an explanatory diagram showing power consumption according to an embodiment of the present invention. FIG. 5 is a flowchart showing main data transmission processing of the transmission apparatus according to the embodiment of the present invention. FIG. 6 is a flowchart showing sub-data transmission processing of the transmission apparatus according to an embodiment of the present invention. FIG. 7 is an explanatory diagram showing power distribution type power consumption according to an embodiment of the present invention. FIG. 8 is a flowchart showing detailed sub-data transmission processing of the transmission apparatus according to an embodiment of the present invention. FIG. 9 is an explanatory diagram showing power consumption in the order of instantaneous values according to an embodiment of the present invention. FIG. 10 is an explanatory diagram showing power consumption in order of change according to an embodiment of the present invention. FIG. 11 is an explanatory diagram showing phase power consumption according to an embodiment of the present invention. FIG. 12 is an explanatory diagram showing load type power consumption according to an embodiment of the present invention. FIG. 13 is a flowchart showing untransmitted data transmission processing of the transmission apparatus according to an embodiment of the present invention.

  Hereinafter, a transmission apparatus according to an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic configuration diagram of a power control system according to an embodiment of the present invention. The power control system 100 includes a transmission device 101, a power meter 103, a plurality of power loads 105 (105-1 to 105-6), sensors 107 (107-1 to 107-5), and a server 109. It is a waste.

  The transmission device 101 acquires (collects) the power consumption of each power load, and transmits data based on the power consumption to the server 109 via the network 111, and includes a computer that performs processing described below. It is a waste. The power meter 103 is connected to the main breaker and measures the power consumption of the entire power load 105 (hereinafter referred to as total power consumption). The power load 105 is various electric products that consume power, such as a light, a microwave oven, an air conditioner, a TV (television receiver), and a refrigerator. The power load 105 is connected to a branch breaker (wiring breaker) connected to the main breaker. In FIG. 1, six power loads 105 are shown, but the present invention is not limited to this mode, and two or more power loads 105 can be provided.

  The sensor 107 converts power consumption into data that can be handled by the transmission apparatus 101 and transmits the data to the transmission apparatus 101. In addition to the value of the power consumption itself, the sensor 107 also has information on which power load the power consumption is due to, and information on which power distribution is supplied by which power distribution method described later. It can be sent to the transmission device 101. The sensor 107-1 is connected to the wattmeter 103 and acquires the total power consumption. The sensors 107-2 to 107-5 are connected to the power loads 105-1 to 105-6, and acquire power consumption at each power load.

  The server 109 determines how to reduce power consumption from data based on the received power consumption, and transmits a control signal instructing reduction of power consumption to the power load 105. The server 109 is composed of, for example, a BEMS controller. Data based on power consumption is data of power consumption itself of each power load, data obtained by summing up a plurality of power consumptions, and the like. The network 111 is a line connecting the transmission apparatus 101 and the sensor 107 and the server 109, and is, for example, a LAN (Local Area Network) or a WAN (Wide Area Network).

  FIG. 2 is a functional block diagram showing a schematic configuration of a transmission apparatus according to an embodiment of the present invention. The transmission apparatus 101 includes an acquisition unit 121, a storage unit 123, a communication unit 125, and a control unit 127. The acquisition unit 121, the storage unit 123, and the communication unit 125 are connected to the control unit 127.

  The acquisition unit 121 acquires the power consumption of each of the plurality of power loads 105 from the sensor 107, and is a communication unit that communicates with the sensor 107, for example. In the present invention, the transmission apparatus 101 can include the sensor 107 itself. In this case, the acquisition unit 121 converts the sensor itself or an analog signal from the sensor into a digital signal that can be handled by the control unit 127. It can be an ADC (Analog to Digital Converter). In FIG. 2, a communication unit 125 and an acquisition unit 121 to be described later for communicating with the server 109 are expressed as separate functional blocks. However, when the acquisition unit 121 is a communication unit, the present invention The acquisition unit 121 and the communication unit 125 are not limited to being realized by separate hardware. The transmission apparatus 101 can include one communication unit that has both the function of the acquisition unit 121 and the function of the communication unit 125.

  The storage unit 123 stores information such as various threshold values, which will be described later, and also functions as a work memory. The storage unit 123 is, for example, a memory or an HDD. The communication unit 125 transmits data based on power consumption to the server 109 via the network 111.

  The control unit 127 controls and manages the entire transmission apparatus 101 including each functional block of the transmission apparatus 101. The control unit 127 is configured as software executed on an arbitrary suitable processor such as a CPU (central processing unit) or a dedicated processor (for example, DSP (digital signal processor)) specialized for each process. You can also.

  The control unit 127 acquires the degree of congestion of the network 111 and determines the importance of data based on power consumption based on the degree of congestion. The congestion degree of the network 111 indicates the amount of data being transmitted through the network 111. The higher the degree of congestion, the smaller the amount of data that can be transmitted by the transmission apparatus 101 and the lower the throughput.

  The higher the degree of congestion, the longer the time required for the data from the transmission apparatus 101 to reach the server 109, or it may not reach in some cases. Therefore, the control unit 127 determines the importance level for the data based on the power consumption, and controls the communication unit 125 to preferentially transmit data with high importance level. The control unit 127 uses a congestion threshold as an index for evaluating the degree of congestion when determining the importance.

  The degree of congestion is, for example, a transmission delay time or a transmission amount that increases as the network 111 is congested. The transmission delay time is, for example, a time (RTT: Round-Trip Time) from when the communication unit 125 transmits certain data until a response signal (ACK signal or NACK signal) for the data is received from the server 109. Expressed. Data transmitted to the server 109 for measuring the transmission delay time may be data based on power consumption or measurement test data. Hereinafter, in the present embodiment, the congestion degree is RTT, and the congestion threshold is a time threshold related to RTT. Further details of the importance determination method will be described later with reference to FIG.

  Next, a transmission method of the transmission apparatus 101 will be described with reference to FIG. FIG. 3 is a flowchart showing processing of the transmission apparatus according to the embodiment of the present invention. Note that the various threshold values used in the following description are items that can be arbitrarily set according to the transmission path capacity of the network 111, contract power, and the like.

  First, the transmission apparatus 101 repeats the following processes of steps S102 to S107 during the operation of the transmission apparatus 101 by the repetition process of step S101. First, the acquisition unit 121 acquires power consumption from the sensor 107 regularly or irregularly, and sends the power consumption to the control unit 127 (step S102). In the present embodiment, as shown in FIG. 4, the total power consumption indicated by the wattmeter 103 is Wd, and the power consumptions of the power loads 105-1 to 105-6 are W1 to W6, respectively.

  Then, the control unit 127 can control the communication unit 125 to transmit data based on the power consumption Wd and W1 to W6 at a predetermined transmission timing (step S103). The transmission timing is regular or irregular, and can be, for example, a reporting timing to the server 109 necessary for receiving the BEMS subsidy. In order to realize the auxiliary rate of 1/2, it is necessary to report within 10 minutes. Therefore, the transmission timing is changed at intervals of 10 minutes or shorter than 10 minutes.

  When the current time is not the transmission timing (No in Step S103), the control unit 127 can store the acquired power consumption Wd and W1 to W6 in the storage unit 123 (Step S104). At this time, the control unit 127 can store the power consumption in the storage unit 123 in association with the time so that the history of power consumption can be specified.

  When the current time is the transmission timing (Yes in step S103), the control unit 127 determines the importance for the data based on the power consumption Wd and W1 to W6. The control unit 127 determines main data and sub data from data based on power consumption, sets the importance of the main data highest, and sets the importance of the sub data next to the main data. Further, the control unit 127 sets the power consumption different from the sub data among the acquired power consumptions Wd and W1 to W6, that is, the power consumption not selected as the sub data as untransmitted data, and the importance of the untransmitted data. Is set next to the sub data. Therefore, the control unit 127 performs transmission processing in the order of main data, sub data, and untransmitted data (steps S105 to S107).

  First, details of the main data transmission process (step S105) will be described with reference to FIG. FIG. 5 is a flowchart showing main data transmission processing of the transmission apparatus according to the embodiment of the present invention.

  In the present embodiment, the control unit 127 uses the total power consumption W1 to W6 of all the power loads 105-1 to 105-6, that is, the total power consumption Wd of the entire power load 105 as main data, and uses the total power consumption Wd as the main data. The communication unit 125 is controlled to transmit to the server 109 (step S201). Note that the control unit 127 can acquire the total power consumption Wd from the sensor 107-1 connected to the wattmeter 103. The control unit 127 can also acquire the total power consumption Wd by adding all the power consumptions W1 to W6 from the sensors 107-2 to 107-5 connected to the power load 105.

  When the total power consumption Wd reaches the server 109, the server 109 transmits a response signal to the transmission device 101. Then, the communication unit 125 of the transmission apparatus 101 receives this response signal and sends the response signal to the control unit 127 (step S202). Then, the control unit 127 calculates RTT from the time when the total power consumption Wd is transmitted and the time when the response signal is received (step S203).

  When the main data transmission process ends, the transmission apparatus 101 performs a sub data transmission process (step S106). Details of the sub data transmission processing will be described with reference to FIG. FIG. 6 is a flowchart showing sub-data transmission processing of the transmission apparatus according to an embodiment of the present invention.

  First, the control unit 127 compares the RTT with a first time threshold (first congestion threshold) (step S301). When the RTT is equal to or greater than the first time threshold value (Yes in step S301), the control unit 127 calculates, as sub-data, power distribution type power consumption for each power distribution method based on the power consumption W1 to W6. The power distribution type power consumption is the sum of the power consumption of the power loads connected for each power distribution method. In the present embodiment, it is assumed that a single-phase three-wire system or a three-phase three-wire system is adopted as the power distribution method of the power system, and the power loads 105-1 to 105-4 are supplied with power by the single-phase three-wire system. Assume that 105-5 and 105-6 are supplied with electric power by a three-phase three-wire system. Therefore, the control unit 127 calculates the single-phase three-wire power consumption Wt by the sum of W1, W2, W3, and W4. In addition, the control unit 127 obtains the power consumption Ws of the three-phase three-wire system by summing W5 and W6. In the present invention, the distribution system of the power system is not limited to a single-phase three-wire system or a three-phase three-wire system, and may be, for example, a single-phase two-wire system.

  Then, the control unit 127 controls the communication unit 125 to transmit the power distribution type power consumption (step S302). And the control part 127 memorize | stores the power consumption of each power consumption W1-W6 which was not transmitted in the memory | storage part 123 as untransmitted data (step S303). That is, when the RTT is equal to or greater than the first time threshold, three power consumptions Wd, Wt, and Ws are transmitted to the server 109 as shown in FIG.

  In step S301, when the RTT is less than the first time threshold (No in step S301), the control unit 127 compares the RTT with a second time threshold (second congestion threshold) smaller than the first time threshold ( Step S304). When the RTT is equal to or greater than the second time threshold value (Yes in step S304), the control unit 127 performs a detailed sub-data transmission process described later (step S305). And the control part 127 memorize | stores the power consumption of each electric power load which was not transmitted by the detailed sub data transmission process in the memory | storage part 123 as untransmitted data (step S303).

  In step S304, when the RTT is less than the second time threshold value (No in step S304), the power consumptions W1 to W6 of the power loads 105-1 to 105-6 are all set as sub data, and each of the sub data Make the importance of power consumption the same. That is, the control unit 127 controls the communication unit 125 to transmit all the power consumptions W1 to W6 in random order (step S306).

  Next, details of the detailed sub-data transmission process (step S305) will be described with reference to FIG. FIG. 8 is a flowchart showing detailed sub-data transmission processing of the transmission apparatus according to an embodiment of the present invention.

  First, the control unit 127 compares the total power consumption Wd with a power threshold (step S401). When the total power consumption is equal to or greater than the power threshold (Yes in step S401), the control unit 127 uses the power consumption W1 to W6 of each of the power loads 105-1 to 105-6 as sub data, and among the sub data, The importance is increased as the power consumption increases in the instantaneous value or the amount of change. Note that the power threshold is an arbitrarily set item, but the power threshold can be set low in a time zone when the power rate is high such as a summer daytime or when a power saving request is made.

  The instantaneous value is the power consumption W1 to W6 acquired immediately before the transmission timing, and the amount of change is the difference between the instantaneous value and the past power consumption stored in the storage unit 123, or the instantaneous value. Is a standard deviation or variance of power consumption within a certain period including the acquired time. For example, when the magnitude relationship between the instantaneous values of power consumption is W6> W3> W5> W1> W4> W2, the importance is low in the order of W6, W3, W5, W1, W4, and W2, as shown in FIG. Become. When the amount of change is small in the order of the power loads 105-6, 105-5, 105-1, 105-3, 105-4, and 105-2, as shown in FIG. 10, W6, W5, W1, W3, The importance decreases in the order of W4 and W2.

  Then, the control unit 127 controls the communication unit 125 to transmit the power consumptions W1 to W6 in descending order of importance until the current time reaches the next transmission timing (step S402). The power consumption that has not been transmitted due to the time being the next transmission timing is stored in the storage unit 123 as untransmitted data (step S303).

  In step S401, when the total power consumption Wd is less than the power threshold (No in step S401), the control unit 127 can compare the transmission fee in the network 111 at the current time with the charge threshold (step S403). When the transmission fee is less than the charge threshold (Yes in step S403), the control unit 127 calculates the phase power consumption for each voltage line having the same ground voltage as sub-data based on the power consumption. In the present embodiment, the voltage lines having the same ground voltage are the R line (100 V) and the T line (100 V) constituting the single-phase three-wire system, and the phase power consumption of the voltage line is the power consumption of the RN phase. And TN phase power consumption. N means a neutral line (0 V). Assuming that the power loads 105-1 to 105-3 are connected to the RN phase and the power load 105-4 is connected to the TN phase, the control unit 127 includes the power consumption Wrn of the RN phase. Is obtained by summing W1, W2 and W3, and the power consumption Wtn of the TN phase is determined to be W4.

  And the control part 127 compares the power difference (Wrn-Wtn (however, Wrn> Wtn)) of phase power consumption with a power difference threshold value (step S404). When the power difference is greater than or equal to the power difference threshold (Yes in step S404), the control unit 127 controls the communication unit 125 to transmit the phase power consumption Wrn and Wtn (step S405). That is, when the power difference of the phase power consumption is equal to or greater than the power difference threshold, three power consumptions Wd, Wrn, and Wtn are transmitted to the server 109 as shown in FIG. Note that the control unit 127 can also cause the communication unit 125 to transmit the RT-phase power consumption and the power distribution type power consumption Ws related to the three-phase three-wire system together with the phase power consumption Wrn and Wtn.

  In step S404, when the power difference of the phase power consumption is less than the power difference threshold (No in step S404), the control unit 127 calculates the load type power consumption for each type of power load based on the power consumption W1 to W6. Calculate as sub-data. In the present embodiment, the power loads 105-1 and 105-2 are the same type in terms of lighting fixtures, the power loads 105-3 and 105-4 are the same type in terms of cooking appliances, and the power load 105-5. And 105-6 are the same type in terms of air conditioners. Note that the type of power load is an item that can be arbitrarily set in advance, and a narrower group (for example, a microwave oven) or a wider group (for example, a power load (for example, only a cooking device) installed in a kitchen). As well as refrigerators))).

  Therefore, the control unit 127 calculates the power consumption WL of the lighting fixture by the sum of W1 and W2, obtains the power consumption Wc of the cooking appliance by the sum of W3 and W4, and determines the power consumption Wa of the air conditioning fixture as W5 and W6. It is calculated by the sum of Then, the control unit 127 increases the importance of the load type power consumption having a larger instantaneous value among the load type power consumptions WL, Wc, and Wa. For example, when the magnitude relationship of the power consumption by load type is Wa> Wc> WL, the importance becomes lower in the order of Wa, Wc, WL as shown in FIG.

  Then, the control unit 127 controls the communication unit 125 to transmit the power consumptions Wa, Wc, and WL in descending order of importance until the current time reaches the next transmission timing (step S406). The load type power consumption that has not been transmitted due to the time becoming the next transmission timing is stored in the storage unit 123 as untransmitted data (step S303).

  In step S403, when the transmission fee is equal to or higher than the charge threshold value (No in step S403), the control unit 127 controls the communication unit 125 to transmit the power distribution type power consumption, similarly to step S302 (step S407).

  When the transmitting apparatus 101 performs the sub-data transmission process (step S106) as described above, it subsequently performs the untransmitted data transmission process (step S107). Details of the unsent data transmission process will be described with reference to FIG. FIG. 13 is a flowchart showing untransmitted data transmission processing of the transmission apparatus according to an embodiment of the present invention.

  First, the control unit 127 compares the transmission charge at the current time with a charge threshold value (step S501). When the transmission fee is less than the charge threshold (Yes in step S501), the transmission apparatus 101 performs the following step S503 until all the untransmitted data stored in the storage unit 123 is transmitted by the repetition process in step S502. And the process of S504 is repeated.

  First, the control unit 127 determines whether the current time is the next transmission timing (step S503). When the time is not the next transmission timing (No in step S503), the control unit 127 controls the communication unit 125 to transmit the untransmitted data stored in the storage unit 123 (step S504).

  When the transmission fee is equal to or higher than the charge threshold (No in step S501) or when the time is the next transmission timing (Yes in step S503), the transmission apparatus 101 ends the untransmitted data transmission process. That is, the control unit 127 controls the communication unit 125 so as not to transmit untransmitted data.

  As described above, in the present embodiment, the control unit 127 of the transmission apparatus 101 determines the importance of data based on the power consumption Wd and W1 to W6 based on the RTT, and preferentially transmits data with high importance. The communication unit 125 is controlled as described above. As a result, data with high importance is more likely to reach the server 109 before the time when the server 109 needs the data. Therefore, efficient transmission of highly important data is realized.

  Further, in the present embodiment, the control unit 127 can use the total power consumption (total power consumption) Wd as main data, and can maximize the importance of the main data. The server 109 can first determine whether the total power consumption Wd is likely to exceed the contract power by receiving the total power consumption Wd before other data. If it is predicted that the total power consumption Wd is likely to exceed the contract power, the server 109 can instruct any power load to reduce power consumption. Thereby, the possibility that the total power consumption Wd exceeds the contract power can be reduced, and the occurrence of a penalty due to the excess of the contract power and the increase of the contract power can be prevented.

  Further, in the present embodiment, when the RTT is equal to or greater than the first time threshold, the control unit 127 calculates the distribution type power consumption Ws and Wt for each power distribution method as sub data, and the importance of the sub data Can be made higher than the main data. As a result, the total power consumption Wd, power board power consumption Ws, and power board power consumption Wt that need to be reported for receiving the BEMS subsidy are preferentially transmitted to the server 109. Therefore, the certainty of the report for receiving the BEMS subsidy can be improved. In addition, since the distribution type power consumption Ws and Wt are obtained by summing a plurality of power consumptions, the number (two) of the distribution type power consumptions Ws and Wt is the power loads 105-1 to 105-6. This is less than the number of power consumptions W1 to W6 (six). Therefore, transmission of power distribution type power consumption can reduce communication charges compared to transmission of power consumption of a power load.

  In the present embodiment, the control unit 127 can compare the total power consumption Wd with the power threshold when the RTT is less than the first time threshold and greater than or equal to the second time threshold. Subsequently, when the total power consumption Wd is equal to or greater than the power threshold, the control unit 127 uses the power consumptions W1 to W6 of the power loads 105-1 to 105-6 as sub data, and determines the importance of the sub data as main data. Can be higher next. And the control part 127 can make importance high, so that the power consumption with a large instantaneous value or change amount is large among subdata. As a result, the server 109 can easily identify the power consumption having a large instantaneous value or amount of change. The server 109 can efficiently reduce the total power consumption Wd by instructing the power load related to the power consumption with a large instantaneous value or change amount to reduce the power consumption.

  In the present embodiment, when the total power consumption Wd is less than the power threshold, the control unit 127 calculates the phase power consumption Wrn and Wtn for each voltage line having the same ground voltage as sub-data based on the power consumption. The power difference between the phase power consumption Wrn and Wtn can be compared with the power difference threshold. Then, when the power difference is equal to or greater than the power difference threshold, the control unit 127 can increase the importance of the sub data next to the main data. As a result, the phase power consumption Wrn and Wtn preferentially reach the server 109, and the server 109 can specify that a load imbalance has occurred between voltage lines having the same ground voltage. Accordingly, the server 109 can instruct the power load to reduce power consumption so that the imbalance is corrected. Further, since the phase power consumption Wrn and Wtn are obtained by summing a plurality of power consumptions, the number (two) of the phase power consumptions Wrn and Wtn is the power consumption of the power loads 105-1 to 105-6. Less than the number of W1-W6 (six). Therefore, transmission of phase power consumption can suppress communication charges more than transmission of power consumption of a power load.

  Further, in the present embodiment, the control unit 127, when the power difference between the phase power consumption Wrn and Wtn is less than the power difference threshold, based on the power consumption, the load type power consumption WL, Wc, Wa can be calculated as sub-data. Then, the control unit 127 can increase the importance of the sub data next to the main data, and can increase the importance of the load type power consumption having a larger instantaneous value in the sub data. This makes it easier for the server 109 to identify the type of power load that consumes more power. Further, since the load type power consumption WL, Wc, and Wa are obtained by summing a plurality of power consumptions, the number (three) of the load type power consumptions WL, Wc, Wa is determined by the power loads 105-1 to 105-1. This is less than the number (six) of the power consumption W1 to W6 of 105-6. Therefore, transmission of load type power consumption can suppress communication charges more than transmission of power consumption of a power load.

  Further, in the present embodiment, the control unit 127 can compare the transmission fee in the network 111 and the charge threshold when the total power consumption Wd is less than the power threshold. Then, when the transmission fee is equal to or higher than the charge threshold, the control unit 127 calculates the distribution type power consumption Ws and Wt for each distribution method of the power system as sub data, and sets the importance of the sub data next to the main data. Can be high. That is, in a time zone in which the transmission fee is relatively expensive, the transmission device 101 transmits only the minimum data necessary for receiving the BEMS subsidy to the server 109, thereby reducing the power fee and reducing the communication fee. Reduction can be achieved.

  In the present embodiment, the control unit 127 sets the power consumption different from the sub data among the acquired power consumptions Wd and W1 to W6 as untransmitted data, and sets the importance of the untransmitted data next to the sub data. can do. Thereby, the transmission apparatus 101 can transmit the power consumption of each power load that has not been transmitted as sub data to the server 109. Therefore, the server 109 can grasp the transition of the power consumption for each power load.

  In the present embodiment, the control unit 127 compares the transmission fee in the network 111 with a fee threshold value, and controls the communication unit 125 so as not to transmit untransmitted data when the transmission fee is equal to or higher than the fee threshold value. Can do. Thereby, the transmission apparatus 101 can suppress a communication charge from significantly increasing due to transmission of untransmitted data in a time zone in which the transmission charge is relatively expensive.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention.

  For example, functions included in each member, each means, each step, etc. can be rearranged so as not to be logically contradictory, and a plurality of means, steps, etc. can be combined or divided into one. Is possible.

  In the above description of the embodiment of the present invention, the transmission apparatus 101 determines data to be transmitted with priority to the server 109, but the present invention is not limited to this aspect. For example, the server can transmit a signal specifying data to be transmitted to the server by the transmission device. Then, the communication unit of the transmission apparatus receives the signal, and the control unit can increase the importance of the data designated by the server next to the main data. Thereby, the transmission apparatus can transmit the data which a server requires efficiently to a server. The designation of transmission data by the server is effective, for example, when the server wants to check an instantaneous value or to specify a power load that has been forgotten to be turned off. When the server wants to specify a power load that has been forgotten to be turned off, the server instructs the transmission apparatus to increase the importance of the power consumption that has a larger change amount compared to the previous day. When the activity pattern at the store is close to every day (for example, the time zone after closing), the usage pattern of the power load approximates. Therefore, when a certain power load consumes power at the current time and does not consume power at the same time of the previous day, it is highly likely that the power source of this power load has been forgotten to be turned off.

  Further, in the description of the embodiment of the present invention described above, the meaning of the technical idea of the expression such as the threshold “more than” or “less than” is not necessarily a strict meaning. The meaning of the case where the value is included or not included is included. For example, the threshold “above” may imply not only when the comparison target reaches the threshold but also when the threshold is exceeded. Further, for example, “less than the threshold value” may imply not only the case where the comparison target falls below the threshold value but also the case where the threshold value is reached, that is, the case where the comparison target is below the threshold value.

DESCRIPTION OF SYMBOLS 100 Power control system 101 Transmission apparatus 103 Power meter 105-1 to 105-6 Power load 107-1 to 107-5 Sensor 109 Server 111 Network 121 Acquisition part 123 Storage part 125 Communication part 127 Control part

Claims (13)

An acquisition unit for acquiring the power consumption of each of the plurality of power loads;
A communication unit that transmits predetermined data to a server at a first transmission time via a network, and receives a response signal for the predetermined data from the server at a first reception time;
And a control unit that determines whether to transmit data based on the power consumption based on a time from the first transmission time to the first reception time. The transmission device according to claim 1, wherein the control unit includes:
The transmission is characterized in that when the time from the first transmission time to the first reception time is equal to or longer than a predetermined time, the communication unit is controlled so as to preferentially transmit highly important data. apparatus. The transmission device according to claim 2, wherein the control unit includes:
The sum of the power consumption as main data,
A transmission apparatus characterized in that importance of the main data is made highest. The transmission device according to claim 3, wherein when the time from the first transmission time to the first reception time is equal to or greater than a first time threshold,
Based on the power consumption, calculate the distribution type power consumption for each power distribution method as sub-data,
A transmitting apparatus, wherein the importance of the sub data is set next to the main data. 5. The transmission device according to claim 4, wherein a time from the first transmission time to the first reception time is less than the first time threshold and is equal to or greater than a second time threshold smaller than the first time threshold. If there is, the control unit
Comparing the sum to a power threshold;
If the sum is greater than or equal to the power threshold,
The power consumption as sub-data,
Increase the importance of the sub data next to the main data,
A transmission apparatus characterized in that, in the sub-data, the importance is increased as the power consumption increases in the instantaneous value or the change amount. 6. The transmission apparatus according to claim 5, wherein when the sum is less than the power threshold, the control unit
Based on the power consumption, calculating the phase power consumption for each voltage line with the same ground voltage as sub-data,
Compare the power difference of the phase power consumption with the power difference threshold,
When the power difference is greater than or equal to the power difference threshold, the transmission apparatus is characterized in that the importance of the sub data is set next to the main data. The transmitter according to claim 6, wherein when the power difference is less than the power difference threshold, the control unit
Based on the power consumption, calculate the load type power consumption for each type of power load as sub-data,
Increase the importance of the sub data next to the main data,
A transmission apparatus characterized in that, in the sub data, the importance is increased as the load type power consumption having a larger instantaneous value. 6. The transmission apparatus according to claim 5, wherein when the sum is less than the power threshold, the control unit
Compare the transmission charge and the charge threshold in the network,
When the transmission charge is equal to or higher than the charge threshold, based on the power consumption, the power distribution type power consumption for each power distribution method is calculated as sub-data, and the importance of the sub-data is the second highest after the main data. A transmission apparatus characterized by: The transmission device according to any one of claims 4 to 8, wherein the control unit includes:
Of the acquired power consumption, power consumption different from the sub data is the untransmitted data,
A transmitting apparatus, wherein the importance of the untransmitted data is set next to that of the sub data. The transmission device according to claim 9, wherein the control unit includes:
Compare the transmission charge and the charge threshold in the network,
When the transmission fee is equal to or higher than the fee threshold, the transmission unit controls the communication unit not to transmit the untransmitted data. 9. The transmission device according to claim 5, wherein when the time from the first transmission time to the first reception time is less than the second time threshold, the control unit includes:
The power consumption as sub-data,
Increase the importance of the sub data next to the main data,
The transmission apparatus characterized in that the importance of each power consumption is the same among the sub-data. The transmission device according to claim 3, wherein
The communication unit receives a signal specifying data to be transmitted by the transmission device from the server,
The control unit increases the importance of the data to be transmitted next to the main data. A transmission method in a transmission device that communicates with a server via a network,
Obtaining power consumption of each of a plurality of power loads;
Transmitting predetermined data to the server at a first transmission time via the network;
Receiving a response signal for the predetermined data from the server at a first reception time;
Determining whether to transmit data based on the power consumption based on a time from the first transmission time to the first reception time.

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