JP2018124031A - Hot water storage type water heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily know what kind of contrivance should be performed for behavior of consumption power to reduce the maximum consumption electric energy (peak value).SOLUTION: In a hot water storage type water heater 1, when a user performs operation input of a mode of shift processing as desired by using a "menu/determination" switch 75, a cross key 74, and the like of a remote control device 50, an actual consumption power value of the hot water storage type water heater 1 before shift processing and a post-processing actual value after shift processing are displayed on a display part 60 so as to be compared. As a result, the user can visually and easily know a result of time variation behavior of consumption power including distribution of the maximum value of consumption power of the hot water storage type water heater 1, and can easily compare and discuss in what mode shift processing should be performed to reduce the maximum consumption electric energy (peak value) in a building or the like by diversely adjusting a processing mode of shift processing and confirming display contents of the post-processing actual value.SELECTED DRAWING: Figure 8

Description

  The present invention relates to a hot water storage type water heater for heating hot water in a hot water storage tank.

  Conventionally, in this type of hot water storage type hot water heater, as described in Patent Document 1, in a hot water type hot water heater that heats hot water in a hot water storage tank, the actual value of power consumption that varies with time in a certain day is displayed in a graph. There was something to do.

JP 2011-179810 A

  In recent years, a so-called “actual amount system” is being introduced in which a basic charge is determined by the magnitude of the maximum demand electric energy (peak value of one year) in the charge menu of an electric power company. In order to reduce the running cost under such a system, the time variation behavior of the power consumed by the hot water storage water heater, especially in which time zone the maximum value of power consumption was distributed, etc. It is important to know. Moreover, in order to reduce the maximum amount of power demand (peak value), if it is possible to easily know what kind of device should be taken with respect to the behavior of power consumption that has been known as described above, Convenient. However, the prior art has a problem that no particular consideration is given to such a point.

  In order to solve the above-described problem, according to claim 1 of the present invention, a hot water storage tank for storing hot water and a heating means for heating the hot water are provided, and the heating means heats the hot water in the hot water storage tank. In the hot water storage type hot water heater that performs, the actual power consumption value determining means for determining the actual power consumption value that fluctuates over time consumed by the hot water storage type water heater in a specific period in the past, and the power consumption actual value are predetermined. The post-processing actual value determining means for determining the post-processing actual value, the display means for displaying the power consumption actual value and the post-processing actual value in a comparable manner, and the power distribution changing It has operation means capable of operating and inputting at least the former of the presence / absence of processing and the mode of processing.

  According to a second aspect of the present invention, the display means displays the post-processing actual value as a graph in a common screen area and displays the power consumption actual value as a trace.

  According to a third aspect of the present invention, the display means includes two left and right screen areas having the same size and the same scale, and the actual power consumption value is displayed in a graph in one of the two screen areas. At the same time, the post-processing result value is displayed in a graph in the other screen area.

  According to a fourth aspect of the present invention, the display means includes upper and lower two screen areas having the same size and the same scale, and the actual power consumption value is displayed in a graph in one of the two screen areas. At the same time, the post-processing result value is displayed in a graph in the other screen area.

  According to a fifth aspect of the present invention, the display means displays the actual power consumption value and the post-processing actual value as a vertical bar graph with time on the vertical axis and power value on the horizontal axis.

  According to a sixth aspect of the present invention, the display means, as the power distribution change process, the post-processing actual value after performing the shift process of the boiling operation time and the consumption before performing the shift process. The actual power value is displayed so that it can be compared.

  According to a seventh aspect of the present invention, the display means performs the power saving process by performing the power saving process for limiting the maximum value of power consumption to a predetermined value as the power distribution changing process, and the power saving process. The actual power consumption value before application is displayed so as to be comparable.

  Further, in the present invention, the display means performs the post-processing actual value after performing the peak cut process for zero-cutting the power consumption in a specific time zone and the peak cut process as the power distribution change process. The previous actual power consumption value is displayed so as to be comparable.

  According to a ninth aspect of the present invention, the display means and the operation means are provided in a remote operation means capable of manually operating the hot water storage type water heater.

  According to the first aspect of the present invention, the hot water storage type water heater performs a boiling operation in which the heating means heats the hot water in the hot water storage tank using electric power. According to claim 1, the power consumption actual value determining means and the post-process actual value determining means are provided. The actual power consumption value determining means determines the actual power consumption value of the hot water storage type hot water heater that fluctuates over time in a past specific period (for example, a certain day). In addition, the post-processing actual value determining means automatically sets a predetermined power distribution changing process (for example, a shift process for shifting the entire operation time of the boiling operation, a maximum value of power consumption) to the actual power consumption value. Power saving processing that redistributes operating time to limit the value, peak cut processing that redistributes operating time to cut power consumption in a specific time zone to zero), and determines the actual value after processing . The power consumption actual value (actual value before processing) determined in this way and the post-processing actual value are displayed on the display means so as to be comparable. At this time, the presence or absence of the power distribution change process and the mode of the process (for example, the value of the shift time in the shift process, the designation of a specific time zone for performing the peak cut process) are determined by the operation means as desired. Operation input is possible.

  As a result, the user can visually easily know the actual performance of the time fluctuation behavior of the power consumption including the distribution of the maximum value of the power consumption of the hot water storage type hot water heater from the actual power consumption value. Furthermore, by operating the operation means as appropriate and confirming the display contents of the post-processing actual value while variously adjusting the processing mode of the power distribution change processing, which processing is performed in what mode, the maximum It is possible to easily compare and examine whether the amount of power demand (peak value) can be reduced. As a result, the running cost can be easily reduced and the convenience can be improved.

  In addition, according to the second aspect, since both the graph of the power consumption actual value and the graph of the processed actual value are displayed in one screen area, the user can easily visually compare them. .

  According to the third aspect, the graph of the power consumption actual value is displayed on one side and the graph of the processed actual value is displayed on the other side using the left and right screen areas, so that the user can easily visually Can be compared.

  According to claim 4, the graph of the power consumption actual value is displayed on one side using the upper and lower two screen areas, and the graph of the processed actual value is displayed on the other side. Can be compared.

  Further, according to claim 5, by displaying the power consumption actual value and the processed actual value in a form in which vertical bar graphs are arranged along the horizontal time axis, the time fluctuation of the power value is intuitively displayed. Can be expressed in an easy-to-understand manner.

  According to the sixth aspect, the graph of the actual power consumption value and the graph of the actual value after processing after performing the shift processing of the operation time of the boiling operation are displayed in comparison. Thus, the user can easily compare and examine in what manner the actual power consumption value can be shifted to reliably reduce the maximum demand power amount (peak value).

  According to claim 7, the graph of the power consumption actual value and the graph of the post-processing actual value after performing the power saving process for limiting the maximum value to a predetermined value are displayed in comparison. . As a result, the user can easily compare and examine whether or not to perform the power saving process in order to reduce the maximum demand power amount (peak value).

  Further, according to claim 8, the graph of the actual power consumption value and the graph of the actual value after processing after performing the peak cut processing for zero-cutting the power consumption in the specific time zone are displayed in contrast. Is done. Thus, the user can easily compare and examine in what manner the peak cut processing should be performed in order to reduce the maximum demand power amount (peak value).

  Further, according to the ninth aspect, since both the display means and the operation means are provided in the remote operation means, the user only holds and operates one remote operation means, and in what manner and in what process It is possible to easily compare and examine whether or not the maximum power demand (peak value) can be reduced.

1 is an overall schematic configuration diagram of a hot water storage type water heater according to an embodiment of the present invention. External view showing configuration of remote control device Functional block diagram showing detailed functions of control device and remote control device In order to explain the shift process, a bar graph conceptually showing an example of the time fluctuation of the actual power consumption value of a hot water storage hot water heater, an air conditioner, and a general load Bar graph diagram conceptually showing actual power consumption values of hot water storage hot water heater, air conditioner, and general load before shift processing Bar graph diagram conceptually showing actual power consumption values of hot water storage hot water heaters, air conditioners, and general loads after shift processing External view of remote control device displaying actual power consumption value before shift processing on the display unit External view of the remote control device displaying the actual power consumption values before and after the shift process so that they can be compared on the display External view of a remote control device displaying actual power consumption values before and after shift processing in a modified example in which two left and right areas are compared and displayed in one screen External view of a remote control device displaying actual power consumption values before and after shift processing in a modified example in which two upper and lower areas are compared and displayed on one screen External view of a remote control device that displays actual power consumption values before processing on a display unit in a modified example in which power saving processing is performed External view of remote control device that displays actual power consumption values before and after processing in a modified example for performing power saving processing so that they can be compared on the display unit External view of remote control device displaying power consumption actual value before processing in display unit in modified example of performing peak cut processing and shift processing External view of a remote control device that displays power consumption actual values before and after processing in a modified example in which peak cut processing and shift processing are performed so that they can be compared on the display unit Overall schematic configuration diagram of a hot water storage type hot water heater in a modification using solar power generation External view of remote control device displaying actual power consumption value before shift processing on the display unit External view of the remote control device displaying the actual power consumption values before and after the shift process so that they can be compared on the display

  Next, an embodiment of the present invention will be described with reference to the drawings.

  The system configuration of the hot water supply system of the present embodiment is shown in FIG. In FIG. 1, a hot water supply system 100 of the present embodiment is connected to a heat pump hot water storage type hot water heater 1 installed in a building such as a house (not shown) (corresponding to a specific power consumption facility) and a commercial power source 49. The distribution board 2, the air conditioner 6 and other general loads 48 that constitute loads other than the hot water storage type hot water heater 1, a network communication network 8, and a server 9 are provided.

  The hot water storage type water heater 1 includes a remote controller 50 (corresponding to a remote control means), a hot water storage tank 10 for storing hot water, a water supply pipe 11 for supplying water to the bottom of the hot water storage tank 10, and a top of the hot water storage tank 10. The hot water discharge pipe 12 for hot water, the water supply bypass pipe 13 branched from the water supply pipe 11, the hot water from the hot water discharge pipe 12 and the water from the water supply bypass pipe 13 are set to the hot water supply set temperature set by the remote controller 50. A mixing valve 14 for mixing, a hot water supply pipe 15 for supplying hot water to a hot water supply terminal (not shown), a hot water flow rate sensor 16 for detecting the hot water flow rate and outputting a corresponding detection signal, and a detection signal corresponding to the detected hot water temperature. It has a hot water supply temperature sensor 17 for outputting and a hot water storage temperature sensor 18 for detecting the hot water storage temperature in the hot water storage tank 10 and outputting a corresponding detection signal. A plurality of hot water storage temperature sensors 18 are provided on the side surface of the hot water storage tank 10 at different height positions. For example, each of the plurality of hot water storage temperature sensors 18 detects a hot water temperature that is set in advance corresponding to the temperature of hot water in a sufficiently heated state and is equal to or higher than a predetermined threshold value. Is output to the control device 31. Thereby, based on how many of the plurality of hot water storage temperature sensors 18 are outputting the detection signal, the control device 31 is sufficiently heated in the hot water storage tank 10. The amount of hot water (ie, the amount of hot water stored) can be detected.

  The hot water storage type water heater 1 further includes a heat pump device 19 (corresponding to a heating means) that heats the hot water in the hot water storage tank 10 to the boiling target temperature. The heat pump device 19 includes a compressor 20 that compresses and conveys refrigerant to a high temperature and a high pressure, a water refrigerant heat exchanger 21 that performs heat exchange between the high temperature and high pressure refrigerant and water from the hot water storage tank 10, and the water refrigerant. An expansion valve 22 that decompresses and expands the refrigerant after heat exchange in the heat exchanger 21, an air heat exchanger 23 that exchanges heat between the outside air and the low-pressure refrigerant to evaporate the low-pressure refrigerant, and the outside air to the air heat exchanger 23. The blower 24 that blows air, the discharge temperature sensor 25 that detects the temperature of the refrigerant discharged from the compressor 20 and outputs a corresponding detection signal to the control device 31, and the detection signal corresponding to the outside air temperature that is detected. An outside air temperature sensor 30 that outputs to the control device 31 is provided.

  The hot water storage type hot water heater 1 further connects the control device 31 that controls the operation of the hot water storage type hot water heater 1, the lower part of the hot water storage tank 10, and the water side inlet of the water refrigerant heat exchanger 21. A heating return pipe 27, a heating return pipe 27 connecting the water outlet of the water-refrigerant heat exchanger 21 and the upper part of the hot water storage tank 10, a heating circulation pump 28 provided in the middle of the heating forward pipe 26, It has a boiling temperature sensor 29 that is provided in the heating return pipe 27 and outputs a detection signal to the control device 31. The heating forward pipe 26, the heating return pipe 27, and the heating circulation pump 28 constitute a heating circulation circuit (hereinafter simply referred to as “heating circulation circuits 26, 27, 28” as appropriate).

  Next, a detailed configuration of the remote controller 50 is shown in FIG. In FIG. 2, the remote control device 50 has a display unit 60 (corresponding to display means) and a “bath automatic” for automatically performing hot water filling from the hot water storage tank 10 into the bathtub or hot water after filling. "Switch 71", "Call" switch 72 for making a call in the bathroom, speaker 73, various numerical values such as the hot water supply temperature, etc., and the upward setting of the cursor in the display unit 60 -A cross key 74 for performing a leftward / downward / horizontal movement operation, a "menu / decision" switch 75, and a manual operation, for example, in a daytime zone (described later) other than a nighttime zone (described later) A “tank hot water” switch 76 for increasing the hot water storage amount in the hot water storage tank 10 by a predetermined amount by performing “daytime boiling operation” will be described later, and the hot water storage amount in the hot water storage tank 10 is determined in advance. Before “Automatic hot water supply stop” switch 77 that pauses the automatic hot water heating function for raising the daytime boiling capacity when it decreases below a threshold value by manual operation (only on the day of operation), and a “saving” prepared in advance. An “eco guide” switch 78 for causing the display unit 60 to display various guides including descriptions of a plurality of operation modes (detailed description is omitted) such as “eco mode” and the display unit 60. A “return” switch 79 for returning the display screen to the previous display screen is provided. The switches 71, 72, 73, 75, 76, 77, 78, 79, the cross key 74 and the like are hereinafter simply referred to as an operation unit 51 (corresponding to operation means; see FIG. 3 described later) as appropriate.

  The display unit 60 is configured to be able to switch a plurality of display screens each displaying predetermined contents. In the illustrated display screen 60A, a date and time display unit 61 for displaying the current date and time (in this example, Friday, May 31, 22:30) and the temperature of hot water in the bathtub (in this example, 40 ° C.) A bath temperature display unit 62 for displaying the hot water supply temperature display unit 63 for displaying the hot water supply temperature (40 ° C. in this example), a hot water storage amount display unit 64 for displaying the hot water storage amount in the hot water storage tank 10, and the A network display unit 65 indicating that it is connected to the server 9 via the network communication network 8, and which mode is selected from among the plurality of modes (in this example, “auto energy saving” mode. And a mode display unit 66 representing (omitted).

  The hot water storage amount display unit 64 displays the hot water storage amount in the hot water storage tank 10 in accordance with the detection result of the hot water storage temperature sensor 18 under the control of the display control unit 80 (see FIG. 3 described later). In the illustrated example, the hot water storage amount display unit 64 can display the hot water storage amount in five stages by five display elements 64A to 64E.

  In the example shown in FIG. 2, the amount of hot water stored in the hot water storage tank 10 is reduced to about 1/5 of the full tank by using hot water during housework or bathing (see 22:30 time display on the date and time display unit 61). (Only the lowermost display element 64A of the hot water storage amount display section 64 is lit). In the present embodiment, the boiling operation (night heating operation) is performed by using the power supplied from the commercial power supply 49 in the nighttime period (for example, 23: 00 to 7:00) where the unit price of electric power is low. .

This night boiling operation is performed by the control device 31 according to a known normal method, for example, in the following flow (a) to (f).
(A) First, the required amount of hot water required for the next day is calculated from the amount of hot water used for a plurality of days on the previous day.
(B) Thereafter, the amount of hot water required for boiling (for the next day) is calculated by subtracting the amount of hot water in the hot water storage tank at that time from the required amount of hot water.
(C) Then, the heating time required to boil the amount of hot water required for boiling by a heating means (in this example, the heat pump device 19) having a predetermined heating capacity is calculated.
(D) After that, a time that is back by the calculated heating time from the boiling completion target time near the end time of the night time zone is calculated as the night boiling start time.
(E) Then, when the night boiling start time is reached, the heat pump device 19 starts boiling.
(F) Then, when the required amount of boiling water is boiled or when the boiling completion target time is reached, the boiling is completed.

  By the way, in recent years, the so-called “actual amount system” has been introduced in which the basic charge is determined by the magnitude of the maximum demand power (peak value in one year) used in houses, etc., in the price menu of electric power companies. It is being broken. In such a system, in order for the user to reduce the running cost, in order to reduce the running cost of the electric power consumed by the hot water storage hot water supply 1, particularly in which time zone the maximum value of the power consumption was distributed, It is important to know these. Moreover, in order to reduce the maximum amount of power demand (peak value), if it is possible to easily know what kind of device should be taken with respect to the behavior of power consumption that has been known as described above, Convenient.

  Therefore, in the present embodiment, as shown in FIG. 3, the control device 31 is provided with a power consumption actual value determination unit 81 (corresponding to a power consumption actual value determination unit) and a post-processing actual value determination unit 82. It is done. Of the past power consumption values of the hot water storage type hot water heater 1 that have already been acquired and stored in appropriate locations, the actual power consumption value determination unit 81 has a desired specific period (for example, corresponding to the operation in the operation unit 51). The power consumption value of the hot water storage type hot water heater 1 that fluctuates with time on the day before the operation day, etc.) is determined as the actual power consumption value to be displayed. Further, the post-processing result value determining unit 82 shifts the power distribution actual value determined by the power consumption actual value determining unit 81 to a predetermined power distribution changing process (in this example, shifting the operation time of the boiling operation). Process) to determine the post-processing result value.

  In the boiling operation after the shift process is performed, the control device 31 inputs the desired operation time to be shifted (details will be described later). Shift boiling completion target time by time.

  The shift process will be described with reference to FIGS. In FIG. 4, the horizontal axis indicates the time axis in which the time is engraved, such as “0 o'clock”, “1 o'clock”, “2 o'clock”, “23:00”, and the vertical axis indicates the electric energy [kWh]. 3 is a bar graph conceptually showing an example of temporal variation of a power consumption actual value of the hot water storage type hot water heater 1, a power consumption actual value of the air conditioner 6, and a power consumption actual value of the general load 48 in one day.

  As shown in FIG. 4, in this example, the actual power consumption actual value of the general load 48 is 0.95 [kWh] at 0 o'clock, and the actual power consumption actual values of the air conditioner 6 and the hot water storage hot water heater 1 are As a result, the total power consumption actual value (hereinafter referred to as “total power consumption actual value” as appropriate) of the general load 48, the air conditioner 6, and the hot water storage hot water heater 1 is 0.95 [kWh]. ing.

  Thereafter, the actual power consumption actual value of the general load 48 gradually decreases with the passage of time, while the actual power consumption actual value of the hot water storage hot water heater 1 gradually increases with the execution of the night boiling operation. The actual power consumption value of the general load 48 is 0.7 [kWh], the actual power consumption value of the hot water storage hot water heater 1 is 0.4 [kWh], and the actual power consumption value of the air conditioner 6 is 0. As a result, the actual power consumption actual value has increased to 1.1 [kWh].

  Thereafter, at 2 o'clock, the actual power consumption value of the general load 48 decreases to 0.3 [kWh], while the actual power consumption value of the hot water storage hot water heater 1 increases to 1.6 [kWh]. The total power consumption actual value is 1.9 [kWh]. At 3 o'clock, the actual power consumption value of the general load 48 is 0.25 [kWh], while the actual power consumption value of the hot water storage hot water heater 1 is 1.75 [kWh], and the total power consumption The actual value is 2 [kWh]. Further, at 4 o'clock, the actual power consumption value of the general load 48 increases again to 0.45 [kWh], while the actual power consumption value of the hot water storage hot water heater 1 is 1.75 [kWh] as described above. The actual power consumption actual value is 2.2 [kWh]. Further, at 5 o'clock, the actual power consumption value of the general load 48 is further increased to 0.65 [kWh], while the actual power consumption value of the hot water storage hot water heater 1 is 1.75 [kWh] as described above. The actual power consumption actual value is 2.4 [kWh].

  Thereafter, the use of the air conditioner 6 starts anew. At 6 o'clock, the actual power consumption value of the air conditioner 6 is 1.1 [kWh], while the actual power consumption value of the hot water storage hot water heater 1 is 1.2 [kWh]. kWh], the actual power consumption actual value of the general load 48 is 0.8 [kWh], and the total power consumption actual value of these is 3.1 [kWh]. I am greeted.

  Thereafter, when the boiling operation of the hot water storage type hot water heater 1 is finished, at 7 o'clock, the actual power consumption value of the hot water storage type hot water heater 1 becomes 0 and the actual power consumption value of the air conditioner 6 becomes 1.05 [ kWh], the actual power consumption actual value of the general load 48 becomes 0.8 [kWh], and the total total power consumption actual value of these decreases to 1.85 [kWh] at a stretch.

  Thereafter, the operation of the air conditioner 6 is also terminated, so that at 8 o'clock, the actual power consumption values of the hot water storage hot water heater 1 and the air conditioner 6 are both 0, and the actual power consumption value of the general load 48 is 0. 6 [kWh], and the total power consumption actual value is also reduced to 0.6 [kWh].

  After that, the actual power consumption value of the general load 48 is further decreased to 0.4 [kWh] at 9 o'clock while the actual power consumption value of the hot water storage type hot water heater 1 and the air conditioner 6 remains 0. The total power consumption actual value is also 0.4 [kWh]. At 10:00, the actual power consumption actual value of the general load 48 is further reduced to 0.25 [kWh], and the total power consumption actual value is also 0.25 [kWh].

  Thereafter, at 11:00 and 12:00, the actual power consumption actual value of the general load 48 is maintained at 0.25 [kWh], and the total actual power consumption is also 0.25 [kWh].

  After that, at 13:00, the actual power consumption value of the general load 48 slightly increased to 0.35 [kWh] (the total power consumption actual value was also 0.35 [kWh]), and remained almost flat. , The actual power consumption value of the general load 48 at 14:00 is 0.4 [kWh] (the actual total power consumption value is also 0.4 [kWh]), and the actual power consumption value of the general load 48 is 0.3 at 15:00. [KWh] (the actual power consumption actual value is also 0.3 [kWh]).

  After that, the actual power consumption value of the general load 48 suddenly increases due to the execution of various housework in the evening, and becomes 2.2 [kWh] at 16:00 (the total power consumption actual value is also 2.2 [kWh]). After that, it decreases slightly at 17:00 to 1.4 [kWh] (the total power consumption actual value is also 1.4 [kWh]), and slightly decreases even at 18:00 to 1.15 [kWh] (the total power consumption The actual value is also 1.15 [kWh]).

  After that, the above-mentioned daytime boiling operation is executed by manual operation of the hot water heater 1 for bathing, and the actual power consumption value of the hot water heater 1 is generated. The actual power value is 1.05 [kWh], the actual power consumption value of the hot water storage type water heater 1 is 0.35 [kWh], and as a result, the total power consumption actual value is 1.4 [kWh]. ing.

  After that, at 20:00, the actual power consumption value of the hot water storage type hot water heater 1 further increases and the actual power consumption value of the hot water storage type water heater 1 becomes 0.6 [kWh], while the power consumption value of the general load 48 The actual value decreases to 0.85 [kWh], and as a result, the total power consumption actual value is 1.45 [kWh].

  After that, when the bathing and the like are finished, at 21:00, the actual power consumption value of the hot water storage hot water heater 1 becomes 0 again, while the actual power consumption value of the general load 48 increases again to 0.95 [kWh. The actual power consumption actual value is also 0.95 [kWh].

  Thereafter, the actual power consumption value of the general load 48 is further reduced to 0.65 [kWh] at 22:00 while the actual power consumption value of the hot water storage type hot water heater 1 and the air conditioner 6 remains 0. The actual power consumption actual value is also 0.65 [kWh]), and at 23:00, the actual power consumption actual value of the general load 48 is 0.9 [kWh] (the total power consumption actual value is also 0.9 [kWh]). It becomes.

  In the behavior of the actual power consumption value shown in FIG. 4, for example, as shown in FIG. 5, the operation time of the night boiling operation is shifted by 1 hour as a whole by a user's appropriate operation (details will be described later). Consider the case. In this case, the time behavior of the actual power consumption value of the hot water storage water heater 1 from about 1 o'clock to about 6 o'clock (0.4 [kWh] at 1 o'clock and 1.6 [kWh] at 2 o'clock, 3 1.75 [kWh] at 4 o'clock, 1.75 [kWh] at 4 o'clock, 1.75 [kWh] at 5 o'clock, and 1.2 [kWh] at 6 o'clock, respectively. That is, the time behavior of the actual power consumption value of the hot water storage type hot water heater 1 from about 0 o'clock to about 5 o'clock is 0.4 [kWh] at 0 o'clock, 1.6 [kWh] at 1 o'clock, and 1 at 2 o'clock. .75 [kWh] 1.75 [kWh] at 3 o'clock, 1.75 [kWh] at 4 o'clock, 1.2 [kWh] at 5 o'clock.

  As a result, the time fluctuations of the actual power consumption values of the hot water storage hot water heater 1, the air conditioner 6, and the general load 48 after the one hour shift are as shown in FIG. As a result of the actual power consumption value of the general load 48 being 0.95 [kWh] and the actual power consumption value of the hot water storage hot water heater 1 being 0.4 [kWh], the total power consumption actual value is 1.35 [ kWh].

  Similarly, at 1 o'clock, the actual power consumption actual value of the general load 48 is 0.7 [kWh], and the actual power consumption actual value of the hot water storage type hot water heater 1 is 1.6 [kWh]. The value is 2.3 [kWh]. Furthermore, at 2 o'clock, the actual power consumption actual value of the general load 48 is 0.3 [kWh], the actual power consumption value of the hot water storage hot water heater 1 is 1.75 [kWh], and the total power consumption actual value is Is 2.05 [kWh], and at 3 o'clock, the actual power consumption value of the general load 48 is 0.25 [kWh], and the actual power consumption value of the hot water storage hot water heater 1 is 1.75 [kWh]. The actual power consumption actual value is 2 [kWh]. At 4 o'clock, the actual power consumption value of the general load 48 is 0.45 [kWh], the actual power consumption value of the hot water storage hot water heater 1 is 1.75 [kWh], and the total power consumption actual value is 2 2 [kWh], at 5 o'clock, the actual power consumption value of the general load 48 is 0.65 [kWh], the actual power consumption value of the hot water storage hot water heater 1 is 1.2 [kWh], and The total power consumption actual value is 1.85 [kWh]. At 6 o'clock, the actual power consumption actual value of the general load 48 is 0.8 [kWh], the actual power consumption actual value of the air conditioner 6 is 1.1 [kWh], and the total power consumption actual value is 1.9. [KWh]. In addition, about the behavior of the power consumption actual value after 7:00, it is the same as that of FIG.

  In FIG. 4 before the shift process, as shown in the corresponding FIG. 5, the peak value of the total power consumption actual value is 3.1 [kWh] at 6 o'clock. On the other hand, in FIG. 6 after performing the shift process, the peak value of the total power consumption actual value is 2.3 [kWh] at 1 o'clock. As described above, in the example shown in FIGS. 4 to 6, by performing the shift process for shifting the operation time during the night boiling operation of the hot water storage water heater 1 (the actual power consumption of the hot water heater 1). As a result, the peak value of the total power consumption actual value in the house or the like can be reduced.

  In the present embodiment, as a maximum feature, the display control unit 80 (see FIG. 3) of the control device 31 controls the power distribution change process (in this example, before the shift process) before the power distribution change process as described above. The actual power consumption value of the hot water storage hot water heater 1 (determined by the actual power consumption value determination unit 81) and the post-processing actual value of the power consumption of the hot water storage hot water heater 1 after the shift process (determining the actual value after processing) Are determined on the display unit 60 so that they can be compared with each other. Such an example will be described with reference to FIGS.

  7 shows a state where the display screen 60A shown in FIG. 2 is displayed on the display unit 60, and the user performs an appropriate operation (for example, the switches 71, 72, 73, 75, 76, 77, 78, 79). In addition, the shift process setting screen 60P (in place of the display screen 60A) is displayed on the display unit 60 by operating at least one of the cross key 74 and the cross key 74). In this shift processing setting screen 60P, as shown in the figure, one graph display area 83 (corresponding to one screen area) and a shift (setting time) for shifting the boiling operation can be set, for example, in integer units. A time setting area 85 and an operation guide message display area 84 are provided.

  In the shift time setting area 85, for example, after the user appropriately operates the “menu / decision” switch 75 and the cross key 74 to move the cursor to the ▲ mark and ▼ mark in the area 82, the cross key 74 is displayed. The set time can be set as desired by setting the desired value by increasing / decreasing the number of the set time and pressing the “menu / decision” switch 75. In the example shown in the figure, the set time is “0” time, that is, the shift process is not performed. In correspondence with this, the upper part of the graph display area 83 indicates “the current setting is 0 hour”. "Is also displayed. In other words, in the shift time setting area 85, the presence / absence of shift processing as the power distribution change processing can be selected by the cross key 74 or the “menu / decision” switch 75.

  4 to 6, the graph display area 83 takes the time axis on the horizontal axis and the electric energy [kWh] on the vertical axis, and the hot water storage type in a past day designated by the user through an appropriate operation. This is an area for displaying time variation of power consumption of the water heater 1 as a graph (in this example, a bar graph). At this time, as shown in the figure, when the set time is “0”, the value (the actual power consumption value) for which the shift process is not performed is displayed as it is. In other cases, the value is set to the set time value. Accordingly, the value after the shift processing (the post-processing actual value) is displayed. The graph display G1 shown in FIG. 7 is in line with the example shown in FIGS. 4 to 6 (the same applies to the graph display G1 ′ shown in FIG. 8 described later), and the setting time “0” is set (that is, no shift processing is performed). ), The actual power consumption value of the hot water storage water heater 1 is 0 [kWh] at 0 o'clock, 0.4 [kWh] at 1 o'clock, 1.6 [kWh] at 2 o'clock, and 1 at 3 o'clock. .75 [kWh], 1.75 [kWh] at 4 o'clock, 1.75 [kWh] at 5 o'clock, 1.2 [kWh] at 6 o'clock, 0 [kWh] from 7 o'clock to 9 o'clock, A graph display G1 is displayed.

  The operation guide message display area 84 displays an operation guide such as the shift time setting area 85 as described above. In the example shown in the figure, “selected by (upper triangle mark) (lower triangle mark)” “( Three messages are displayed: “Confirm with right triangle mark” and “OK with [MENU / OK]”.

  FIG. 8 shows a shift time setting area in which the user uses the “menu / decision” switch 75 and the cross key 74 in a state where the shift processing setting screen 60P shown in FIG. This shows a case where the shift processing setting screen 60Q is displayed on the display unit 60 by setting the set time at 85 to “1” time.

  In the shift process setting screen 60Q, as in the shift process setting screen 60P of FIG. 7, one graph display area 83 (corresponding to one screen area), the shift time setting area 85, and an operation guide message display area 84 are displayed. ′.

  In the graph display area 83, the time variation of the actual power consumption value of the hot water storage hot water heater 1 is 1 corresponding to the setting change from the set time “0” to the set time “1”. The post-processing actual value in a time-shifted (advanced) mode is displayed. That is, 0.4 [kWh] at 0 o'clock, 1.6 [kWh] at 1 o'clock, 1.75 [kWh] at 2 o'clock, 1.75 [kWh] at 3 o'clock, 1.75 [kWh] at 4 o'clock ] A graph display G2 is displayed (1.2% kWh] at 5 o'clock and 0 [kWh] after 6 o'clock (substance display that is not a broken line as will be described later).

  On the other hand, at this time, a graph display G1 ′ corresponding to the graph display G1 of FIG. 7 before the shift processing is displayed as a trace of a broken line bar graph different from FIG. Thereby, on this shift process setting screen 60Q, the power consumption actual value (actual value before processing) of the hot water storage type hot water heater 1 and the actual value after processing can be compared in one graph display area 83. Will be displayed. Although not shown, even when the set time in the shift time setting area 85 is set to other time, the same display as described above is performed in the graph display area 83, for example, by setting the time to “2”. The graph display G2 having a content shifted by 2 hours is displayed as the substance, and the graph display G1 ′ before the shift process is displayed as the trace.

  Instead of the trace display of the graph display G1 ′ before the shift process, the previous graph display may be displayed as a trace. That is, from the state shown in FIG. 7, when the set time is first set to “1” time and then the set time is further changed to “2” time, the graph display G2 having a content shifted by 1 hour. May be displayed as the trace and the graph display G2 with a content shifted by 2 hours may be displayed as the substance. Alternatively, in this case, the graph display G1 ′ (trace display) before the shift process, the graph display G2 (trace display or entity display) with a content shifted by 1 hour, and the graph display G2 (substance display) with a content shifted by 2 hours. , Three (or four or more) may be displayed so as to be comparable. Furthermore, the display of traces and the display of actual displays may be appropriately changed. Although not shown or described in detail, the present invention is not limited to the case where forward shift processing is performed as described above (in the above example, a positive integer is set in the shift time setting area 85). For example, the shift time setting area By setting a negative integer at 85, it is possible to perform the shift process in the forward direction.

  In the illustrated example, the operation guide message display area 84 ′ includes “select with (upper triangle mark) (lower triangle mark)”, “return with (left triangle mark)”, and “decide with [menu / decision]”. These three messages are displayed. Corresponding to the “1” time setting of the set time, a message “Current setting is 1 hour” is also displayed at the top of the graph display area 83.

  As described above, according to the hot water storage type hot water heater 1 of the present embodiment, the actual power consumption value and the processing of the hot water storage type hot water heater 1 before the power distribution change process (in this example, the shift process, the same applies hereinafter). The post-actual value is displayed on the display unit 60 so as to be comparable. At this time, whether or not the power distribution change process is performed and the mode of the process (in the above example, the value of the time to be shifted in the shift process) can be input as desired by the user using the remote controller 50 (power It may be possible to operate a specific time zone for performing distribution change processing.

  As a result, the user can visually easily know the actual performance of the time variation behavior of the power consumption including the distribution of the maximum value of the power consumption of the hot water storage water heater 1 by the actual power consumption value (see FIG. 7). ). Further, by appropriately operating the “menu / decision” switch 75, the cross key 74, etc., the display contents of the post-process result values are confirmed while variously adjusting the processing mode of the shift process (see FIG. 8). Thus, it is possible to easily compare and examine in what manner the shift process should be performed in order to reduce the maximum demand power amount (peak value). As a result, the running cost can be easily reduced and the convenience can be improved.

  In the present embodiment, in particular, the graph of the actual power consumption value and the graph of the actual value after processing after performing the shift processing of the operation time of the boiling operation are displayed in comparison. Thus, the user can easily compare and examine in what manner the actual power consumption value can be shifted to reliably reduce the maximum demand power amount (peak value).

  In the present embodiment, in particular, both the graph of the power consumption actual value and the graph of the processed actual value are displayed in one graph display area 83 (see FIG. 8). As a result, the user can easily make a visual comparison.

  In the present embodiment, the power consumption actual value and the processed actual value are displayed in a form in which vertical bar graphs are arranged along the horizontal time axis (see FIGS. 7 and 8). As a result, it is possible to intuitively and easily express the time variation of the power value.

  In the present embodiment, in particular, the remote control device 50 is provided with both the display unit 60 as display means, the cross key 74 and the “menu / decision” switch 75 as operation means, and the like. . As a result, the user can easily compare and examine in what manner the process can be performed to reduce the maximum demand power amount (peak value) simply by grasping and operating the remote controller 50.

  In addition, this invention is applicable to the range which does not change the meaning, without being limited to the above aspect. Hereinafter, such modifications will be described in order. In each modification, the same reference numerals are given to the same parts as those in the above embodiment, and the description will be omitted or simplified as appropriate.

(1) Case where contrast display is performed in two areas of left and right in one screen This modification is shown in FIG. In FIG. 9, in this modification, a shift process setting screen 60R is displayed on the display unit 60. The shift process setting screen 60R has two graph display areas 83a, left and right having the same scale and width. 83b (corresponding to two screen areas on the left and right) and the shift time setting area 85.

  On the other hand (on the left side in this example), in the graph display area 83a, as in FIG. 7, the actual power consumption value of the hot water storage water heater 1 corresponding to the state where the set time is “0” (that is, no shift processing). (0 [kWh] at 0 o'clock, 0.4 [kWh] at 1 o'clock, 1.6 [kWh] at 2 o'clock, 1.75 [kWh] at 3 o'clock, 1.75 [kWh] at 4 o'clock, 5 The graph display G1 of 1.75 [kWh] at hour, 1.2 [kWh] at 6 o'clock,.

  In the other (right side in this example) graph display area 83b, the hot-water storage type hot water heater after the shift processing corresponding to the set time “1” in the shift time setting area 85, as in FIG. 1 power consumption actual value (0.4 [kWh] at 0 o'clock, 1.6 [kWh] at 1 o'clock, 1.75 [kWh] at 2 o'clock, 1.75 [kWh] at 3 o'clock, 4 o'clock at 4 o'clock The graph display G2 of 1.75 [kWh], 1.2 [kWh] at 5 o'clock, 0 [kWh] at 6 o'clock,.

  An arrow (in this example, a right-pointing block arrow) indicating the flow from before the shift process to after the shift process is displayed between the graph display area 83a and the graph display area 83b.

  Also in this modification, the same effect as the above-described embodiment is obtained. In particular, by using the left and right graph display areas 83a and 83b, the graph of the actual power consumption value is displayed on one side and the post-processing actual value graph is displayed on the other side, so that the user can easily visually Can be compared.

(2) Case where contrast display is performed in two upper and lower areas in one screen This modification is shown in FIG. In FIG. 10, in this modification, a shift process setting screen 60S is displayed on the display unit 60, and the upper and lower graph display areas 83c and 83d having the same scale and the same width are displayed on the shift process setting screen 60S. (Corresponding to the upper and lower two screen areas) and the shift time setting area 85 are provided.

  On the other hand (upper side in this example), in the graph display area 83c, as in FIG. 7, the actual power consumption value of the hot water storage hot water supply 1 corresponding to the state where the set time is “0” (that is, no shift processing). (0 [kWh] at 0 o'clock, 0.4 [kWh] at 1 o'clock, 1.6 [kWh] at 2 o'clock, 1.75 [kWh] at 3 o'clock, 1.75 [kWh] at 4 o'clock, 5 A graph display G3 corresponding to the graph display G1 of 1.75 [kWh] at hour and 1.2 [kWh] at 6 o'clock is displayed. In this modification, not only the operation time of the night boiling operation in the night zone but also the operation time of the day boiling operation by manual operation in the evening (0.35 [kWh] at 19:00, 0. 6 [kWh] (see FIG. 4) is also an object of shift processing, and these values are also displayed as the actual power consumption values in the graph display G3.

  On the other (lower side in this example) graph display area 83d, as in FIG. 8, the hot water storage type hot water supply after the shift processing corresponding to the set time in the shift time setting area 85 being “1”. Actual power consumption value of machine 1 (0.4 [kWh] at 0 o'clock, 1.6 [kWh] at 1 o'clock, 1.75 [kWh] at 2 o'clock, 1.75 [kWh] at 3 o'clock, 4 o'clock 1.75 [kWh] at 5 o'clock, 1.2 [kWh] at 5 o'clock, 0 [kWh] at 6 o'clock, ..., 0.35 [kWh] at 18 o'clock, 0.6 [kWh] at 19 o'clock, ... The graph display G4 corresponding to the graph display G2 is displayed.

  Note that arrows or the like indicating the flow from before the shift process to after the shift process may be added and displayed between the graph display area 83c and the graph display area 83d.

  Also in this modification, the same effect as the above-described embodiment is obtained. In particular, by using the upper and lower graph display areas 83c and 83d, the graph of the power consumption actual value is displayed on one side and the graph of the processed actual value is displayed on the other side. Can be compared.

  In the modified examples (1) and (2), as in the above-described embodiment (not shown), the setting time in the shift time setting area 85 is set to other times as in the above case. Is displayed in the graph display areas 83b and 83d. For example, by setting the set time to “2” time, the graph displays G2 and G4 with contents shifted by 2 hours are displayed. Further, instead of displaying the traces of the graph displays G1 and G3 before the shift process in the graph display areas 83a and 83c, the previous graph display may be displayed as a trace. That is, similarly to the above, when the set time is first set to “1” time and then the set time is further changed to “2” time, the graph displays G2 and G4 having contents shifted by 1 hour are displayed. The graph displays G2 and G4, which are displayed in the graph display areas 83a and 83c and shifted by 2 hours, may be displayed in the graph display areas 83b and 83d. Alternatively, in this case, the graph display G1, G3 before the shift process, the graph display G2, G4 of the content shifted by 1 hour, and the graph display G2, G4 of the content shifted by 2 hours (plus 4 or more). May be displayed in multiple stages so that they can be compared. Although not shown or described in detail, the present invention is not limited to the case where forward shift processing is performed as described above (in the above example, a positive integer is set in the shift time setting area 85). For example, the shift time setting area By setting a negative integer at 85, it is possible to perform the shift process in the forward direction.

(3) When performing power save processing In this modification, as the power distribution change processing, power save processing for redistributing the operation time so as to automatically limit the maximum value of power consumption to a predetermined value is performed. That is, the control device 31 limits the predetermined heating capacity of the heating means (in this example, the heat pump device 19) in the night boiling operation to a low value. As a result, the heating time of the step (c) in the above-described night boiling operation flow is calculated as a long time, and the night boiling start time in the step (d) is advanced by that amount. is there. A modification for performing this power saving process will be described with reference to FIGS.

  First, in FIG. 11, in this modification, the user performs an appropriate operation (for example, the switches 71, 72, 73, 75, 76) with the display screen 60 </ b> A shown in FIG. 2 displayed on the display unit 60. , 77, 78, 79, and the cross key 74), the power saving process setting screen 60 </ b> T (in place of the display screen 60 </ b> A) is displayed on the display unit 60. Yes. In this power save process setting screen 60T, as shown in the figure, there is one graph display area 83 (corresponding to one screen area), and a power save setting area 86 for setting whether or not to perform the power save process. And an operation guide message display area 84 similar to that described above.

  In the power save setting area 86, for example, after the user appropriately operates the “menu / decision” switch 75 and the cross key 74 to move the cursor to the ▲ mark and ▼ mark in the area 86, the cross key 74 is displayed. Then, the power save process is set to either “Yes” for performing the power save process or “No” for not performing the power save process, and further pressing the “Menu / Determination” switch 75 to execute the power save process. Whether it is performed or not can be set as desired. In the example shown in the figure, the above setting is set to “No”, that is, the power saving process is not performed. In correspondence with this, the upper part of the graph display area 83 is “Current setting is [No]”. "Is also displayed. In other words, in the power save setting area 86, the presence / absence of the power save process as the power distribution change process can be selected by the cross key 74 or the “menu / decision” switch 75.

  4 to 6, the graph display area 83 takes the time axis on the horizontal axis and the electric energy [kWh] on the vertical axis, and the hot water storage type in a past day designated by the user through an appropriate operation. This is an area for displaying time variation of power consumption of the water heater 1 as a graph (in this example, a bar graph). At this time, as shown in the figure, in the case of “No”, the value (the actual power consumption value) that is not subjected to the power saving process is displayed as it is, and in the case of “Yes”, the value that has been subjected to the power saving process. (The post-processing actual value) is displayed. The graph display G1 shown in FIG. 11 is in line with the example shown in FIGS. 4 to 6 as in FIG. 7, and corresponds to the absence of the power saving process, and the actual power consumption value of the hot water storage type hot water heater 1 is shown. Is 0 [kWh] at 0 o'clock, 0.4 [kWh] at 1 o'clock, 1.6 [kWh] at 2 o'clock, 1.75 [kWh] at 3 o'clock, 1.75 [kWh] at 4 o'clock, The graph display G1, which is 1.75 [kWh] at 5 o'clock, 1.2 [kWh] at 6 o'clock, and 0 [kWh] from 7 o'clock to 9 o'clock, is displayed.

  12 shows a state in which the power save process setting screen 60T shown in FIG. 11 is displayed on the display unit 60, and the user uses the “menu / decision” switch 75 and the cross key 74 to set the shift time. The case where the power saving process setting screen 60U is displayed on the display unit 60 by setting the set time in the area 85 to “1” time is shown.

  In the power save process setting screen 60U, as in the shift process setting screen 60T in FIG. 11, one graph display area 83 (corresponding to one screen area), the power save setting area 86, and the same operation as described above. A guide message display area 84 '.

  In the graph display area 83, the maximum value of the time fluctuation of the actual power consumption value of the hot water storage hot water heater 1 described above corresponds to the change of the setting from “No” to “Yes”. (In this example, the post-processing result value is displayed in a manner limited to, for example, 1.2 [kW] as a predetermined ratio of the rated value). That is, 1.6 [kWh] at 2 o'clock, 1.75 [kWh] at 3 o'clock, 1.75 [kWh] at 4 o'clock, 1.75 [kWh] at 5 o'clock are 1.2 [kW], respectively. The graph display G5 in which 0.4 [kWh] at 1 o'clock is increased to 1.2 [kW] and 0 [kW] at 0 o'clock is increased to 1 [kW] correspondingly. Is displayed (an entity display that is not a broken line as will be described later).

  On the other hand, at this time, the graph display G1 ′ corresponding to the graph display G1 of FIG. 11 before the shift processing is displayed as a trace of a broken bar graph different from FIG. Thereby, on this shift process setting screen 60U, the power consumption actual value (actual value before processing) of the hot water storage type hot water heater 1 and the actual value after processing can be compared in one graph display area 83. Will be displayed. In the graph display G5, the newly added portion compared to the graph display G1 may be displayed in a different mode (for example, blinking).

  Also in this modification, the same effect as the above-described embodiment is obtained. In other words, the user can easily know visually the actual performance of the time variation behavior of the power consumption including the distribution of the maximum value of the power consumption of the hot water storage water heater 1 by the actual power consumption value (see FIG. 11). . Then, by appropriately operating the “menu / decision” switch 75, the cross key 74, etc., the display contents of the post-processing result values are confirmed while switching the power saving processing as appropriate (see FIG. 12). Thus, it is possible to easily compare and examine whether or not to perform the power saving process in order to reduce the maximum demand power amount (peak value). As a result, the running cost can be easily reduced and the convenience can be improved.

(4) When performing a peak cut process In this modification, the peak cut process for zero-cutting the power consumption generated with the boiling operation in a specific time zone is performed as the power distribution change process. Such a modification will be described with reference to FIGS. In this modification, the peak cut process and the shift process described in the embodiment are performed as an example. However, only the peak cut process may be performed alone.

In this peak cut process, the following processes (g) to (j) are performed by the control device 31 by a known normal method.
(G) First, the power consumption of the hot water storage type hot water heater 1 in the time zone set by an appropriate operation of the user is acquired.
(H) Thereafter, the acquired power consumption is converted into a hot water amount by a predetermined conversion formula.
(I) Then, the converted hot water amount is added to the required boiling hot water amount in the night time zone before the set time zone on the next day.
(J) The night boiling operation is calculated using the necessary boiling water amount after the addition.

  First, referring to FIG. 13, in this modification, the user performs an appropriate operation (for example, the switches 71, 72, 73, 75, 76 described above) while the display screen 60A shown in FIG. , 77, 78, 79 and the cross key 74), the peak cut processing setting screen 60V (instead of the display screen 60A) is displayed on the display unit 60. Yes. In the peak cut processing setting screen 60V, as shown in the figure, a graph display area 83e equivalent to the graph display area 83c in FIG. 10 and a shift time setting area 87 having the same function as the shift time setting area 85, A peak cut time zone setting area 88 and an operation guide message display area 89 are provided.

  In the shift time setting area 87, for example, after the user appropriately operates the “menu / decision” switch 75 and the cross key 74 to align the cursor with the ▲ mark and ▼ mark in the area 87, the cross key 74 is displayed. The number of the set time is increased / decreased to set a desired value, and the “menu / decision” switch 75 is pressed to set the set time in the shift process as desired. In the example shown in the figure, the set time is “0” time, that is, a state in which shift processing is not performed (see a hyphen “−” in the figure). In other words, in this shift time setting area 87, the presence / absence of shift processing as the power distribution change processing can be selected by the cross key 74 or the “menu / decision” switch 75.

  In the peak cut time zone setting area 88, for example, after the user appropriately operates the “menu / decision” switch 75 or the cross key 74 to move the cursor to the ▲ mark or ▼ mark in the area 88, the cross cut time zone setting area 88 is displayed. The number representing the start time and the end time to end the peak cut processing is increased or decreased with the key 74 and set to a desired value, and further, the “menu / decision” switch 75 is pressed, whereby the peak cut processing in the peak cut processing is performed. A specific time zone can be set as desired. In the illustrated example, the start time and end time are not set (see the hyphen “-” in the figure), that is, the state where the peak cut processing is not performed is shown. In other words, in the peak cut time zone setting area 88, the presence / absence of the peak cut processing as the power distribution change processing can be selected by the cross key 74 or the “menu / decision” switch 75.

  In the graph display area 83e, similarly to the graph display area 83c, the horizontal axis indicates the time axis and the vertical axis indicates the electric energy [kWh], and the hot water storage hot water supply in a past day designated by the user through an appropriate operation is displayed. This is an area for displaying the time fluctuation of the power consumption of the machine 1 as a graph (in this example, a bar graph). At this time, as shown in the figure, when the set time is “0” and the start time / end time of the peak cut process is not set, a value (the actual power consumption value) where the shift process and the peak cut process are not performed is set. Otherwise, at least one of the shift process according to the set time value and the peak cut process according to the start time / end time value of the peak cut process is performed. A value (actual value after processing) is displayed. In this example, the power consumption actual value (0 at 0 o'clock) corresponding to the set time “0” (that is, no shift process) and the start / end times of the peak cut process are not set. [KWh] 0.4 [kWh] at 1 o'clock, 1.6 [kWh] at 2 o'clock, 1.75 [kWh] at 3 o'clock, 1.75 [kWh] at 4 o'clock, 1.75 at 5 o'clock [KWh], 1.2 [kWh] at 6 o'clock,..., 0.35 [kWh] at 19:00, 0.6 [kWh] at 20:00,. A display G6 is displayed.

  The operation guide message display area 89 displays operation guides such as the shift time setting area 87 and the peak cut time zone setting area 88 as described above. In the illustrated example, “(right triangle mark) is used for confirmation. Is displayed.

  FIG. 14 shows the shift time setting by the user using the “menu / decision” switch 75 and the cross key 74 in a state where the peak cut processing setting screen 60V shown in FIG. By setting the set time in the area 87 to “1” time, the start time in the peak cut time zone setting area 88 to “17”, and the end time to “19”, the display unit 60 The case where the peak cut processing setting screen 60W is displayed is shown.

  In the peak cut processing setting screen 60W, as in the peak cut processing setting screen 60V of FIG. 13, one graph display area 83f, the shift time setting area 87, the peak cut time zone setting area 88, and an operation guide A message display area 84 '.

  In the graph display area 83f, the setting is changed from the set time “0” to the set time “1”, and the start time “17” and the end time “19” are set. Correspondingly, the above-mentioned time fluctuation of the power consumption actual value of the hot water storage type hot water heater 1 is shifted by 1 hour (forward), and the peak cut that zero-cuts the power consumption value in the time zone from 17:00 to 19:00 The post-process result value of the aspect with which the process was made is displayed. That is, 0.4 [kWh] at 0 o'clock, 1.6 [kWh] at 1 o'clock, 1.75 [kWh] at 2 o'clock, 1.75 [kWh] at 3 o'clock, 1.75 [kWh] at 4 o'clock ] At 5 o'clock 1.2 [kWh], after 6 o'clock 0 [kWh] (part corresponding to 0.35 [kWh] at 19 o'clock and 0.6 [kWh] at 20 o'clock in FIG. 13) Graph display G7 is displayed).

  On the other hand, at this time, the graph display G6 ′ corresponding to the graph display G6 of FIG. 13 before the shift process and the peak cut process is displayed as a bar graph with a broken line different from FIG. 13 in the graph display area 83f. Thereby, on this shift process setting screen 60W, the said power consumption actual value (actual value before a process) and the post-process actual value of the hot water storage type water heater 1 can be compared within one graph display area 83f. Will be displayed.

  In the operation guide message display area 89 ′, in the illustrated example, a message “return with (left triangle mark)” is displayed.

  Also in this modification, the same effect as the above-described embodiment is obtained. That is, the user can visually easily know the actual performance of the time variation behavior of the power consumption including the distribution of the maximum value of the power consumption of the hot water storage type hot water heater 1 from the actual power consumption value (see FIG. 13). . Then, by appropriately operating the “menu / decision” switch 75, the cross key 74, etc., the display content of the post-processing actual value is confirmed while variously adjusting the processing mode of the peak cut processing (see FIG. 14). Thus, it is possible to easily compare and examine in what manner the peak cut processing should be performed in order to reduce the maximum demand power consumption (peak value). As a result, the running cost can be easily reduced and the convenience can be improved.

(5) Replacing the function of each part In the above, the power consumption actual value determination part 81 in the desired specific period from the power consumption value of the past hot water storage hot water heater 1 which has already been acquired and stored in an appropriate place. Instead of determining the actual power consumption value, a desired specification is obtained from the stored power consumption value of the past hot water storage water heater 1 at an appropriate location outside the hot water storage water heater 1 (for example, the server 9). You may make it determine by acquiring the thing from which the said power consumption performance value in the period was calculated (specific) from the appropriate location outside the said hot water storage type water heater 1. FIG. Similarly, instead of the post-processing actual value determining unit 82 calculating (determining) the post-processing actual value by applying the power distribution change process to the power consumption actual value determined as described above, as described above. For the actual power consumption value determined as described above, the power distribution change processing is performed at an appropriate location outside the hot water storage hot water heater 1 (for example, the server 9), and the post-processing actual value is calculated. You may make it determine by acquiring from the appropriate location outside the type | formula water heater 1. FIG. In other words, “determination” in this specification includes both what is calculated (specified) by itself and what is acquired (specified) by other parts without being calculated by itself. It is.

  Further, a display function provided on the display screen 60A of the display unit 60 is provided by an appropriate display (corresponding to display means in this case) provided in a part other than the remote control device 50 in the hot water storage hot water supply 1, for example, the control device 31. You may have. Alternatively, a display control unit (corresponding to display control means in this case) having a function equivalent to that of the display control unit 80 is provided in the remote control device 50, and the display control similar to the above is performed on the display unit 60. May be. In that case, at least one of the actual power consumption value determining unit 81 and the post-processing actual value determining unit 82 may be provided in the remote control device 50.

(6) When using solar power generation In the hot water supply system 100 of this embodiment, the solar power generation device 3 is additionally provided, and the boiling operation is performed using the power generated by the solar power generation device 3. May be. FIG. 15 corresponding to FIG. 1 shows a system configuration of a hot water supply system 100 ′ in this modification. In FIG. 15, in the hot water supply system 100 ′ of the present modified example, the photovoltaic panel 4 installed on the roof of the house and the generated power of the photovoltaic panel 4 are converted into an AC power source and the distribution board 2 is converted. The solar power generation device 3 provided with an inverter 5 to be supplied to and a HEMS (= Home Energy Management System) device 7 for performing power management in the home of the house are newly provided.

  The HEMS device 7 is connected to the hot water storage type hot water heater 1, the solar power generation device 3, and the distribution board 2 so as to be capable of bidirectional communication. As a result, the HEMS device 7 can collect the usage status of the hot water storage type hot water heater 1, the generated power information of the solar power generation device 3, and the information of the power consumption for each branch circuit of the distribution board 2. Further, the HEMS device 7 is further connected to the server device 9 via the network communication network 8 and can exchange necessary information with each other. In addition, instead of the HEMS device 7 collecting the generated power information through communication with the solar power generation device 3, the HEMS device 7 inputs the generated power to the distribution board 2, or the distribution board 3 and the commercial You may make it collect the electric power generation information of the solar power generation device 3 by monitoring transmission / reception of the electric power between the power supplies 49. FIG.

  In the above configuration, when the sunshine conditions are good, the solar power generation device 3 receives sunlight from the solar power generation panel 4 to generate power, and the hot water storage water heater 1 is connected to the solar power generation device 3. The boiling operation is performed in the daytime using the electric power generated in the above. Since the solar power generation device 3 cannot perform sufficient power generation by receiving sunlight when the sunshine conditions are not so good, the hot water storage type water heater 1 is the commercial power supply in the nighttime zone as described above. The boiling operation is performed using electric power supplied from the power source 49.

  Also in this modified example, as in the embodiment, for example, the actual power consumption value during boiling operation in the daytime of the hot water storage water heater 1 before the power distribution change process (shift process in this example), The post-processing actual value of the power consumption during the boiling operation of the hot water storage hot water heater 1 after the shift processing in the daytime zone is displayed on the display unit 60 so as to be comparable. Such an example will be described with reference to FIGS.

  FIG. 16 shows a state where the display screen 60 </ b> A shown in FIG. 2 is displayed on the display unit 60, and the user performs an appropriate operation (for example, the switches 71, 72, 73, 75, 76, 77, 78, 79). In addition, the shift process setting screen 60X (in place of the display screen 60A) is displayed on the display unit 60 by operating at least one of the cross key 74 and the cross key 74). In the shift processing setting screen 60X, as shown in the figure, one graph display area 83 '(corresponding to one screen area) and the time (setting time) for shifting the boiling operation can be set, for example, in integer units. The shift time setting area 85 and the operation guide message display area 84 are provided.

  The illustrated shift time setting area 85 has a function equivalent to that of the above-described embodiment, and in the illustrated example, the set time indicates “0” time, that is, a state where shift processing is not performed.

  The graph display area 83 ′ has a function equivalent to that of the graph display area 83 of the above-described embodiment. The horizontal axis represents the time axis and the vertical axis represents the electric power [kWh], which is designated by the user through an appropriate operation. This is an area for displaying, in a graph (in this example, a bar graph), the time variation of the power consumption of the hot water storage type hot water heater 1 in a past day. At this time, as shown in the figure, when the set time is “0”, the value (the actual power consumption value) for which the shift process is not performed is displayed as it is. In other cases, the value is set to the set time value. Accordingly, the value after the shift processing (the post-processing actual value) is displayed. In the example shown in FIG. 16, the actual power consumption value of the hot water storage hot water heater 1 that uses the power generated by the solar power generation corresponds to the setting of the set time “0” (that is, no shift processing) is 10:00. Until then, a graph display G8 is displayed, which is 0 [kWh], 1.5 [kWh] from 11:00 to 14:00, and 0 [kWh] after 15:00.

  FIG. 17 shows a shift time setting area in which the user uses the “menu / decision” switch 75 and the cross key 74 in a state where the shift processing setting screen 60X shown in FIG. 16 is displayed on the display unit 60. This shows a case where the shift processing setting screen 60Y is displayed on the display unit 60 by setting the set time at 85 to “1” time.

  In the shift processing setting screen 60Y, as in the shift processing setting screen 60Y of FIG. 16, one graph display area 83 ′ (corresponding to one screen area), the shift time setting area 85, and an operation guide message display area. 84 '.

  In the graph display area 83 ′, in response to the setting change from the set time “0” to the set time “1”, the time fluctuation of the power consumption actual value of the hot water storage type hot water heater 1 is changed. The post-process result value in a mode shifted by 1 hour (advanced) is displayed. That is, until 9 o'clock, the graph display G9 becomes 0 [kWh] from 10 o'clock to 13 o'clock and 1.5 [kWh] after 14:00, and 0 [kWh] after 14 o'clock. )

  On the other hand, at this time, the graph display G8 ′ corresponding to the graph display G8 of FIG. 16 before the shift processing is displayed as a trace of a broken line bar graph different from FIG. 16 in the graph display area 83 ′. Thereby, on the shift processing setting screen 60Y, the power consumption actual value (actual value before processing) and the post-processing actual value of the hot water storage type water heater 1 can be compared in one graph display area 83 ′. Will be displayed. Although not shown, even when the set time in the shift time setting area 85 is set to other time, the same display as described above is performed in the graph display area 83 ′, for example, “2” time. Then, the graph display G9 with the contents shifted by 2 hours is displayed as the substance, and the graph display G8 ′ before the shift process is displayed as the trace.

  Similar to the above-described embodiment, the graph display G8 ′ before the shift process may be displayed as a trace instead of the trace display. That is, from the state shown in FIG. 16, when the set time is first set to “1” time and then the set time is further changed to “2” time, the graph display G9 with a content shifted by 1 hour is used. May be displayed as the trace and the graph display G9 with a content shifted by 2 hours may be displayed as the substance. Alternatively, in this case, the graph display G8 ′ (trace display) before the shift process, the graph display G9 (trace display or entity display) with a content shifted by 1 hour, and the graph display G9 (substance display) with a content shifted by 2 hours. , Three (or four or more) may be displayed so as to be comparable. Furthermore, the display of traces and the display of actual displays may be appropriately changed. Although not shown or described in detail, the present invention is not limited to the case where forward shift processing is performed as described above (in the above example, a positive integer is set in the shift time setting area 85). For example, the shift time setting area By setting a negative integer at 85, it is possible to perform the shift process in the forward direction.

  In the present modification, even when the boiling operation is performed using the power generated by the solar power generation device 3, the same effect as in the above embodiment can be obtained.

  In addition, you may further apply the method by the modification of said (1) (2) (3) (4) (5) with respect to this modification using photovoltaic power generation. In this case, the same effect as each modification can be obtained.

(7) Others In the above, for example, instead of the heat pump device 19, an electric heater type heating means may be used.

DESCRIPTION OF SYMBOLS 1 Hot water storage type water heater 10 Hot water storage tank 19 Heat pump apparatus (heating means)
26 Heating pipe (Heating circuit)
27 Heating return pipe (Heating circuit)
28 Heating circulation pump (heating circulation circuit)
31 Control device 48 General load 49 Commercial power supply 50 Remote control device (remote control means)
60 Display section (display means)
71 "Buro automatic" switch (operation means)
72 “Talk” switch (operation means)
74 Four-way controller (operation means)
75 “Menu / Enter” switch (operating means)
76 “Tank refill” switch (operation means)
77 Hot water stop switch (operating means)
78 “eco guide” switch (operating means)
79 “Return” switch (operating means)
80 Display control unit (display control means)
81 Power consumption actual value determination unit (power consumption actual value determination means)
82 Processed Actual Value Determination Unit (Processed Actual Value Determination Means)
83 Graph display area (one screen area)
83 'Graph display area (one screen area)
83a, 83b Graph display area (two left and right screen areas)
83c, 83d Graph display area (upper and lower two screen areas)
100 Hot water supply system G1 to G9 Graph display G1 ′ Graph display G1 ″ Graph display G6 ′ Graph display G8 ′ Graph display

Claims (9)

A hot water storage tank for storing hot water, a heating means for heating the hot water, and a heating water heater for performing a boiling operation in which the heating means heats the hot water in the hot water tank.
The actual power consumption value determining means for determining the actual power consumption value that fluctuates over time consumed by the hot water storage type water heater in the past specific period;
A post-process result value determining means for performing a predetermined power distribution change process on the power consumption actual value and determining a post-process result value;
Display means for displaying the power consumption actual value and the processed actual value in a comparable manner;
A hot water storage type hot-water supply machine comprising operating means capable of operating and inputting at least the former among the presence and absence of the power distribution changing process and the processing mode. The display means includes
The hot water storage type hot water heater according to claim 1, wherein the post-processing actual value is displayed in a graph in a common screen area, and the power consumption actual value is displayed in a trace in the graph. The display means includes two left and right screen areas of the same size and scale.
2. The actual power consumption value is displayed in a graph in one of the two screen regions, and the processed actual value is displayed in a graph in the other screen region. The hot water storage water heater described. The display means includes upper and lower two screen areas of the same size and scale.
2. The actual power consumption value is displayed in a graph in one of the two screen regions, and the processed actual value is displayed in a graph in the other screen region. The hot water storage water heater described. The display means includes
5. The power consumption actual value and the post-processing actual value are displayed in a vertical bar graph with time on the vertical axis and power value on the horizontal axis. The hot water storage water heater described. The display means includes
As the power distribution change process, the post-processing actual value after the shift process of the boiling operation time and the power consumption actual value before the shift process are displayed in a comparable manner. The hot water storage type water heater according to any one of claims 1 to 5. The display means includes
As the power distribution change process, the post-processing actual value after performing the power saving process for limiting the maximum value of power consumption to a predetermined value is compared with the actual power consumption value before performing the power saving process. The hot water storage type hot water supply device according to any one of claims 1 to 6, wherein the hot water storage type water heater is displayed. The display means includes
As the power distribution change processing, the post-processing actual value after performing the peak cut processing for zero-cutting the power consumption in a specific time zone can be compared with the actual power consumption value before performing the peak cut processing. The hot water storage type water heater according to any one of claims 1 to 7, wherein the hot water storage type water heater is displayed. The display means and the operation means are:
The hot water storage type hot water heater according to any one of claims 1 to 8, wherein the hot water storage type hot water heater is provided in a remote control means capable of manually operating.

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