JP6789012B2 - Heat supply device - Google Patents

Description

The present invention supplies heat, for example, a hot water supply device that supplies heated hot water to a hot water supply location, a heating device that supplies a heated heat medium to a heating terminal, a bath device that reheats a bath, or a combination thereof. Regarding the heat supply device.

Heat supply devices such as hot water supply devices and heating devices are widely used. This type of heat supply device is required to reduce energy consumption from various viewpoints such as economic efficiency and environmental protection. In this regard, Patent Document 1 discloses a system for notifying the user of the energy usage status in order to promote energy saving (hereinafter referred to as energy saving) by the user. In this system, a plurality of system elements including a heat supply device (heat pump type water heater) are configured to visually display the flow of energy transferred between the system elements. According to this system, it is explained that the user can know which device consumes energy and how it is consumed, thereby enabling efficient use of the device.

JP-A-2010-169314

In the technique described in Patent Document 1, even if it is possible to know which device consumes energy and how, the objective standard for evaluating the energy consumption is unknown. May not be able to use the equipment efficiently. Therefore, the present specification provides a technique capable of promoting energy saving of a heat supply device based on an objective standard of energy consumption.

The present specification discloses a heat supply device communicably connected to an external network. This heat supply device includes a storage means for storing own device data and a receiving means for receiving other device data transmitted to an external network by another heat supply device of the same type as the heat supply device. The own device data is data that at least describes environmental information regarding the usage environment of the heat supply device and consumption information regarding the actual energy consumption of the heat supply device. The other device data at least describes environmental information regarding the usage environment of the other heat supply device and consumption information regarding the actual energy consumption of the other heat supply device. The heat supply device further includes a sorting means for selecting other device data that matches or is similar to the own device data with respect to environmental information from a plurality of other device data received by the receiving means, and another device selected by the sorting means. It is provided with a display means for displaying data consumption information.

According to the above-mentioned heat supply device, the user determines how much energy the other user who uses the same type of heat supply device consumes based on the consumption information of the other device data displayed on the display means. You can know about. In particular, the consumption information of the data of other devices displayed on the display means is not only of the same type in terms of configuration but also of the heat supply device having the same or similar usage environment, so that the user can obtain his / her own energy consumption record. It can be an objective criterion for evaluation. By using this as a reference, the user can correctly evaluate his / her own energy consumption record, and for example, by reviewing the usage method and lifestyle of the heat supply device, energy saving can be effectively promoted.

FIG. 5 is a diagram schematically showing a configuration of a system in which a plurality of heat supply devices 10 are connected via an external network 102. The figure which shows typically the structure of the heat supply device 10. The figure which shows the content of own device data 60 and other device data 70 stored in processor 48. The flowchart which shows the flow of the energy saving support process executed by a processor 48. The figure which shows an example of the initial screen of the energy saving report displayed on the touch panel 44. An example of ranking display displayed on the touch panel 44 (by prefecture, utility bill). An example of ranking display displayed on the touch panel 44 (by prefecture, water consumption). An example of ranking display displayed on the touch panel 44 (by number of households, utility bills). An example of selected other device data (history information) displayed on the touch panel 44. An example of a display for confirming the reflection of data displayed on the touch panel 44. An example of teaching information (hot water supply start time) displayed on the touch panel 44. Another example of teaching information (hot water supply start time) displayed on the touch panel 44. An example of teaching information (bath start time) displayed on the touch panel 44. Another example of teaching information (bath start time) displayed on the touch panel 44. An example of teaching information (hot water supply end time) displayed on the touch panel 44. Another example of teaching information (hot water supply end time) displayed on the touch panel 44.

In one embodiment, it is preferable that the display means rank-displays the consumption information of the plurality of other device data sorted by the sorting means. According to such a configuration, the user can easily perceive the energy consumption record of the upper user who is excellent in energy saving, and can easily objectively evaluate the degree of achievement of his / her own energy saving.

When the consumption information described in the data of other devices includes consumption information (for example, actual value) for a plurality of items such as utility cost, electricity usage, gas usage, water usage, and energy efficiency, the display means are those. It is preferable that the ranking can be displayed for each item. In addition, or instead, when the environmental information described in the data of the other device includes environmental information about a plurality of items such as the geographical position of the heat supply device and the number of users (for example, the number of households), the display means is It is preferable that the ranking can be displayed for each of these items.

In one embodiment, the heat supply device preferably further includes an operating means operated by the user in order to select one from a plurality of other device data whose consumption information is displayed on the display means. In this case, it is preferable that the display means can further display other information described in the data of the other device selected by the operating means. With such a configuration, the user can obtain more detailed information about other users who are interested in the consumption information.

In the above-described embodiment, the other device data may further describe historical information regarding the operation history of the other heat supply device. In this case, the display means can further display teaching information according to the difference between the operation history described in the data of the other device selected by the operation means and the actual operation state of the heat supply device. preferable. Here, it is preferable that the history information describes at least one day's operation history. For example, the hot water supply start time when the hot water is first supplied in the day and the bath start time when the hot water filling of the bathtub is started. , It is good to describe the operation history such as the end time of hot water supply when the last hot water supply was performed in the day. As an example, it is assumed that 7:00 am is described as the hot water supply start time in the data of another device selected by the operating means. On the other hand, when the user's heat supply device does not supply the first hot water at the stage of 7:00 am, the display means may display, for example, a message prompting the user to wake up together with voice as necessary.

In one embodiment, the heat supply device preferably further comprises a transmission means for transmitting its own device data to an external network. According to such a configuration, the own device data is used as other device data in other heat supply devices, and energy saving can be mutually promoted among a plurality of users.

In one embodiment, it is preferable that the environmental information of the own device data includes information regarding the geographical position of the heat supply device, and the environmental information of the other device data includes information regarding the geographical position of the other heat supply device. Since the energy and energy efficiency consumed by the heat supply device are affected by the climate such as temperature and humidity, they change significantly depending on the geographical location where the heat supply device is installed. If the environmental information includes information about the geographical location of the heat supply device, information on other heat supply devices with the same or similar geographical location can be selected and displayed to the user. As a result, the user can correctly evaluate his / her energy consumption performance based on the information of other users excluding the influence of the geographical location.

In one embodiment, it is preferable that the environmental information of the own device data includes information on the number of users of the heat supply device, and the environmental information of the other device data includes information on the number of users of the other heat supply device. The energy consumed by the heat supply device changes significantly depending on the number of users of the heat supply device (for example, the number of households). When the environmental information includes information on the number of users of the heat supply device, information on other heat supply devices having the same or similar number of users can be selected and displayed to the user. As a result, the user can correctly evaluate his / her own energy consumption performance based on the information of other users excluding the influence of the number of users.

In one embodiment, it is preferable that the heat supply device further includes a heat source, a heat storage means for accumulating heat by the heat source, and a control means for controlling the heat source according to a heat storage schedule based on the actual heat demand. In this type of heat supply device, the timing and amount of heat stored in the heat storage means are automatically adjusted according to the user's life pattern. As a result, the energy consumption and energy efficiency of the heat supply device also change according to the user's life pattern. Therefore, when the user reviews the life pattern, the energy saving degree of the heat supply device is often significantly improved. The techniques disclosed herein can be effectively applied to such heat supply devices.

The heat supply device 10 of one embodiment and the system 100 using the heat supply device 10 will be described with reference to the drawings. FIG. 1 schematically shows the configuration of the system 100. The system 100 includes a plurality of heat supply devices 10 and a data server 104. The plurality of heat supply devices 10 are of the same type (same specifications) as each other. Each heat supply device 10 is arranged in various parts of Japan such as Aichi prefecture, Kagawa prefecture, and Iwate prefecture, and is communicably connected to the data server 104 via an external network 102. The data server 104 may be a physical server or a cloud server (or virtual server) configured by using a part of the physical server. Various data transmitted from each heat supply device 10 is accumulated in the data server 104, and each heat supply device 10 transmits various data transmitted from the other heat supply device 10 from the data server 104. Can be obtained.

Here, the system 100 does not necessarily have to include the data server 104. For example, each heat supply device 10 may be able to directly communicate with another heat supply device 10 via the external network 102. In this case, the set of memories and the like possessed by each heat supply device 10 can virtually function as the data server 104.

The configuration of the heat supply device 10 will be described with reference to FIG. The heat supply device 10 of this embodiment can supply heated hot water to hot water supply points such as the curan 2 and the bathtub 4. Further, the heat supply device 10 can supply the heated heat medium to the heating terminal 6. Further, the heat supply device 10 can reheat the bath (heat the bath water in the bathtub 4). That is, the heat supply device 10 of this embodiment also has functions as a hot water supply device, a heating device, and a bath device. However, the heat supply device 10 may have at least one function of a hot water supply device, a heating device, and a bath device.

As shown in FIG. 2, the heat supply device 10 includes a tank 12 for storing hot water and a heat pump 14 for heating the hot water in the tank 12. The heat pump 14 is an example of a heat source, and the tank 12 is an example of a heat storage means for accumulating heat from the heat source. The tank 12 and the heat pump 14 are connected to each other via a heat storage circulation path 18. The heat storage circulation path 18 circulates the hot water in the tank 12 between the tank 12 and the heat pump 14. As a result, the hot water in the tank 12 is heated by the heat pump 14 and returned to the tank 12. Although not shown, various sensors, valves, and pumps are provided in the heat storage circulation path 18.

A water supply path 22 and a hot water supply path 24 are connected to the tank 12. The hot water in the tank 12 is supplied to hot water supply points such as the curan 2 and the bathtub 4 through the hot water supply path 24. When the hot water in the tank 12 is discharged from the hot water supply path 24, clean water is supplied from the water supply path 22 into the tank 12 accordingly. That is, the inside of the tank 12 is always full, and the temperature stratification is formed in the tank 12, so that hot water is stored in the upper part of the tank 12 and cold water is stored in the lower part of the tank 12. Although not shown, a plurality of temperature sensors are arranged in the tank 12 along the vertical direction, and the amount of hot water and the amount of heat stored in the tank 12 are specified based on the values detected by the plurality of temperature sensors.

The heat supply device 10 further includes a gas unit 16. The gas unit 16 is an example of a second heat source, and by burning a flammable gas, it heats hot water flowing through a hot water supply path 24, bath water in a bathtub 4, and a heat medium supplied to a heating terminal 6. Can be done. The gas unit 16 is provided in the middle of the hot water supply path 24 from the tank 12 to the hot water supply location (curan 2 or bathtub 4). Further, the gas unit 16 is connected to the bathtub 4 via the bath circulation path 26, and is connected to the heating terminal 6 via the heating circulation path 28. The bath circulation path 26 circulates bath water between the bathtub 4 and the gas unit 16. As a result, the bath water in the bathtub 4 is heated by the gas unit 16 and returned to the bathtub 4. The heating circulation path 28 circulates the heat medium (for example, antifreeze) of the heating terminal 6 between the heating terminal 6 and the gas unit 16. As a result, the heat medium of the heating terminal 6 is heated by the gas unit 16 and returned to the heating terminal 6. Although not shown, various sensors, valves, and pumps are provided in the bath circulation path 26 and the heating circulation path 28. Here, the heat in the tank 12 may be used for heating the bath water or the heat medium. In this case, a heat exchanger that exchanges heat between the hot water in the tank 12 and the heat medium can be added.

The heat supply device 10 further includes a control device 40 and a remote controller 42. The control device 40 and the remote controller 42 are examples of control means for controlling the operation of each part of the heat supply device 10. The control device 40 may be a single unit or a set of a plurality of units. The control device 40 is connected to the tank 12, the heat pump 14, the gas unit 16, the above-mentioned sensors, valves, pumps, and the like, and can monitor and control their operations. The remote controller 42 is connected to the control device 40, and gives an operation command to the control device 40 in response to an operation by the user. The remote controller 42 is an operation unit that accepts operations by the user and is a display unit that displays various types of information to the user.

The remote controller 42 includes a touch panel 44, a communication interface 46, and a processor 48. The touch panel 44 is, for example, a touch panel using a liquid crystal display, and various information is visually displayed to the user. Further, the user can give various instructions to the heat supply device 10 by operating the buttons displayed on the touch panel 44. For example, by operating the touch panel 44, the user can set the hot water supply temperature, fill the bathtub 4 with hot water, reheat the bath water, operate the heating terminal 6, set the temperature, and the like. The communication interface 46 connects the heat supply device 10 (particularly the remote controller 42) to the external network 102 so as to be communicable. Although not shown, the communication interface 46 may be connected to an external network via a Wi-Fi router. The processor 48 includes a CPU and a memory, stores various data and programs, and controls the operation of the heat supply device 10 by using the data and programs.

In the heat supply device 10 of the present embodiment, in order to effectively utilize the heat pump 14 having excellent primary energy efficiency, a heat storage schedule is created based on the time-dependent results of heat demand, and the heat pump 14 is prepared according to the heat storage schedule. To control. For example, suppose a household has a constant heat demand during the morning hours, little heat demand during the daytime hours, and a large heat demand from evening to night. By learning the results of such heat demand over time, the control device 40 (or remote controller 42) stores a certain amount of heat by just before the morning time zone, does not store heat in the daytime, and does not store heat in the evening time. Create a heat storage schedule that maximizes heat storage by just before the band. As a result, the energy efficiency of the heat supply device 10 can be improved by suppressing heat dissipation from the tank 12, for example, while preventing so-called running out of hot water.

As described above, in the heat supply device 10 of the present embodiment, the timing and the amount of heat to be stored in the tank 12 are automatically adjusted according to the life pattern of the user. With such a configuration, the energy consumption and energy efficiency of the heat supply device 10 change according to the life pattern of the user. Therefore, the degree of energy saving of the heat supply device 10 is often significantly improved when the user reviews the life pattern. As will be described in detail below, in the heat supply device 10 of this embodiment, attention is paid to this point, and the energy saving degree of the heat supply device 10 is improved by utilizing the communication function of the heat supply device 10. ing.

As shown in FIG. 3, the processor 48 of the remote controller 42 can store the own device data 60 and a plurality of other device data 70. The own device data 60 is information about the heat supply device 10, and the other device data 70 is information about the other heat supply device 10 and is information transmitted from the other heat supply device 10 to the external network 102. .. The other device data 70 is received by the communication interface 46 and stored in the memory of the processor 48. Further, the heat supply device 10 can transmit the own device data 60 to the external network 102 through the communication interface 46. The own device data 60 transmitted by the heat supply device 10 is received as other device data 70 in the other heat supply device 10.

Environmental information 62, consumption information 64, and history information 66 are mainly described in the own device data 60. The environmental information 62 is information regarding the usage environment of the heat supply device 10. The environmental information 62 includes, for example, information such as the name of the prefecture where the heat supply device 10 is installed, the number of households using the heat supply device 10, and the age group of the households using the heat supply device 10. Here, the prefecture name of the environmental information 62 is an example of information on the geographical position of the heat supply device 10, and as another embodiment, the name of the municipality where the heat supply device 10 is installed, the name of the region, the name of the old country, etc. It may be. Further, the number of households in the environmental information 62 is an example of information regarding the number of users of the heat supply device 10, and as another embodiment, it may be the number of employees of the business establishment where the heat supply device 10 is installed. .. These pieces of information may be set manually by the user, or may be set automatically using GPS, for example, for information about geographic location.

The consumption information 64 is information on the actual energy consumption of the heat supply device 10 during a predetermined period (for example, last month). The consumption information 64 includes, for example, water unit price, water usage amount, water cost, gas unit price, gas usage amount, gas cost, electricity unit price, electricity usage amount, electricity cost, utility cost (total of electricity cost and gas cost), Information such as primary energy efficiency and the amount of reheating gas (the amount of gas used for reheating) is included. Since these items are widely known, detailed explanations thereof will be omitted. Information such as the water supply unit price, the gas unit price, and the electricity unit price may be set by the user, for example, or may be acquired from an external server via the external network 102. Information such as the amount of water used, the amount of gas used, the amount of electricity used, and the amount of reheating gas may be measured by a sensor (not shown) provided in the heat supply device 10, for example, a smart meter, HEMS (Home Energy Management). It may be obtained from an external device such as System) and a microcomputer meter. Information such as water cost, gas cost, electricity cost, utility cost and primary energy efficiency may be calculated by the processor 48 based on the above-mentioned various information, or may be acquired from an external device such as HEMS.

The history information 66 is information regarding the operation history of the heat supply device 10. The history information 66 is created by the control device 40 and the remote controller 42 (particularly the processor 48) that control the operation of the heat supply device 10. The history information 66 includes information such as a hot water supply start time, a hot water supply end time, a bath start time, a number of reheating times, and a heating usage time in a predetermined cycle (for example, one day). The hot water supply start time is the time when the hot water supply is performed at the beginning of the day, and is described as, for example, "7:00 AM". The hot water supply end time is the time when the hot water supply operation is performed at the end of the day, and is described as, for example, "PM 11:30". The bath start time is the time when the bath operation (supplying hot water to the bathtub 4 and boiling to the set temperature) is performed in the day, and is described as, for example, "7:30 PM". The number of reheating is the number of times the bath water is reheated in a day, and the number of times such as "twice" is described. The heating usage time is the time during which the heating terminal 6 is used in a day, and a time such as "8 hours" is described. The information described in the history information 66 may be the actual results of the last cycle (for example, the previous day), or may be the average of the actual results in a plurality of cycles (for example, one week or one month). Further, since the life cycle of the user can change depending on the day of the week (for example, weekdays and weekends), the history information 66 may be created for each one or more days of the week (for example, for each of weekdays and weekends).

Environmental information 72, consumption information 74, and history information 76 are mainly described in the other device data 70. As described above, the other device data 70 is the own device data 60 of the other heat supply device 10. Therefore, the items of information included in the other device data 70 are the same as those of the own device data 60 described above, but the contents of each item are different between the own device data 60 and the other device data 70.

The heat supply device 10 can execute the energy saving support process described below by using the own device data 60 and the other device data 70. Although the energy saving support process is an example, it is mainly executed by the processor 48 of the remote controller 42. The energy saving support process displays information useful for energy saving to the user of the heat supply device 10. Hereinafter, the energy saving support process will be described in detail with reference to the flowchart shown in FIG.

The energy saving support process is started based on, for example, an operation on the touch panel 44 by the user. First, the initial screen is displayed on the touch panel 44 (step S2). FIG. 5 shows an example of the initial screen. On the initial screen, a plurality of options (D1) such as "ranking by prefecture" and "ranking by number of households" and various operation buttons (D2) are displayed. On the initial screen, for example, when the user selects "ranking by prefecture", the processor 48 sets the "prefecture name" as the selection key. Alternatively, when the user selects "ranking by number of households", the processor 48 sets "number of households" as a selection key (step S4). For example, when the "prefecture name" is set as the selection key (YES in step S4), the processor 48 is particularly "prefecture name" of the environmental information 62 and 72 from among the plurality of other device data 70 stored. The other device data 70 that matches the own device data 60 is selected (step S6). That is, for example, when the heat supply device 10 is installed in Aichi prefecture, the other device data 70 of the other one or a plurality of heat supply devices 10 also installed in Aichi prefecture is selected. This selection may be performed from among the plurality of other device data 70 stored in the processor 48, or may be performed from among the plurality of other device data 70 stored in the data server 104. Further, in this selection, not only the data in which the environmental information 62 and 72 match, but also the data in which the environmental information 62 and 72 are similar are selected, such that the other device data 70 in the adjacent prefecture is also selected. May be good.

Next, the processor 48 displays the information described in the selected one or more other device data 70 on the touch panel 44 (step S8 in FIG. 4). FIG. 6 shows a display example. In this example, the consumption information 74 of the selected one or more other device data 70 is displayed in the ranking display (D3) together with the display (D4) regarding the consumption information 64 of the own device data 60. Has been done. In the example shown in FIG. 6, among the items in the consumption information 64 and 74, the ranking display for the utility cost is performed, but as illustrated in FIG. 7, other items such as the amount of water used Ranking display may be performed. From such a display, the user can know how much energy is consumed by other users who use the same type of heat supply device 10. In particular, since the consumption information 74 of the other device data 70 displayed on the touch panel 44 is that of the heat supply device 10 which is not only the same in terms of configuration but also has the same or similar usage environment, the user can use his / her own energy. It can be an objective criterion in evaluating consumption performance. By using this as a reference, the user can correctly evaluate his / her own energy consumption record, and for example, by reviewing the usage method and lifestyle of the heat supply device, energy saving can be effectively promoted.

As another example, when "household number" is set as the selection key in the previous step S4, the processor 48 is particularly "household" of the environmental information 62 and 72 from among the plurality of other device data 70 stored. Regarding "the number of people", other device data 70 that matches the own device data 60 is selected. As a result, as shown in FIG. 7, a ranking display (D3) is displayed for the utility cost (or other consumption information 74) of another heat supply device 10 used in a household with the same number of households (for example, 4 people). Will be done. Even with such a display, the user can correctly evaluate his / her own energy consumption record, and for example, by reviewing the usage method and lifestyle of the heat supply device, energy saving can be effectively promoted.

On the display screens of FIGS. 6 to 8, the user can select another user who is interested by operating the touch panel 44. When the user selects one of the other users (step S10), the processor 48 displays other information described in the other device data 70 of the selected other user on the touch panel 44 (step S12). For example, as shown in FIG. 9, on the touch panel 44, the history information 76 described in the other device data 70 of another user is displayed (D5) together with the display (D6) of the user's own history information 76. According to such a contrast display, the user can know how to improve his / her own energy saving degree by changing his / her lifestyle.

When the user operates the "Reflect" button on the display screen shown in FIG. 9, the display screen shown in FIG. 10 appears on the touch panel 44. On the screen shown in FIG. 10, along with the display of advice to the user (D8), a display (D7) is performed asking the user to confirm whether or not to reflect the data of another selected user (for example, Mr. A). .. When the user chooses to reflect the data (YES in step S14), the processor 48 starts the teaching process based on the history information 76 of the other selected user (step S16). In this teaching process, teaching information according to the difference between the history information 76 of the selected other user and the actual operating state of the heat supply device 10 of the user, that is, advice is displayed on the touch panel 44. By referring to this teaching information, the user can change his / her lifestyle into a lifestyle that is excellent in energy saving.

11 to 16 are some examples of teaching information displayed on the touch panel 44. For example, as shown in FIG. 11, in the history information 76 of the selected other user, it is assumed that the hot water supply start time is 7:00 am. In this case, the advice (D9) for urging the user to wake up is displayed near the hot water supply start time. Further, when the actual hot water supply start time by the user is later than the hot water supply start time of another user, it is preferable to display the advice (D9) as shown in FIG. 12 (A), for example. On the contrary, when the actual hot water supply start time by the user is earlier than the hot water supply start time of another user, the advice (D9) as shown in FIG. 12B can be displayed, for example.

Further, as shown in FIG. 13, in the history information 76 of the selected other user, for example, it is assumed that the bath start time is 8:00 pm. In this case, when the bath start time is approaching, advice (D9) for encouraging the user to take a bath is displayed on the touch panel 44. When the actual bath start time by the user is later than the bath start time of another user, it is advisable to display the advice (D9) as shown in FIG. 14 (A), for example. On the contrary, when the actual bath start time by the user is earlier than the bath start time of another user, the advice (D9) as shown in FIG. 14B can be displayed, for example.

Further, as shown in FIG. 15, in the history information 76 of the selected other user, for example, it is assumed that the hot water supply end time is 10:30 pm. In this case, when the hot water supply end time is approaching, advice (D9) for urging the user to go to bed is displayed. Further, when the actual hot water supply end time by the user is later than the hot water supply end time of another user, it is preferable to display the advice (D9) as shown in FIG. 16 (A), for example. On the contrary, when the actual hot water supply end time by the user is earlier than the bath start time of another user, the advice (D9) as shown in FIG. 16B can be displayed, for example.

By displaying the teaching information as described above, the lifestyle of the user approaches the lifestyle of another user who is excellent in energy saving. As the user's lifestyle changes, the heat storage schedule of the heat supply device 10 also changes accordingly. As a result, the user's heat supply device 10 operates in the same manner as the user's heat supply device 10 which is excellent in energy saving, and the energy consumption amount and energy efficiency of the user's heat supply device 10 are improved. The teaching process is continued until instructed by the user, such as the operation of the touch panel 44 (step S18 in FIG. 4).

Although specific examples of the present invention have been described in detail above, these are merely examples and do not limit the scope of claims. For example, among the plurality of heat supply devices 10 included in the system 100, those that cannot transmit the own device data 60 to the external network 102 may be included. That is, for some of the heat supply devices 10, the own device data 60 may not be provided to the other heat supply device 10, and only the other device data 70 may be used by the other heat supply device 10. ..

The heat supply device 10 described in the present specification has a touch panel 44 as an example of the display means, but the various displays (that is, various information) described above are displayed on an external display device such as a smartphone. You may. In this case, the heat supply device 10 does not necessarily have to be provided with a display device such as a touch panel 44, and may be configured to be communicable with an external display device so that information necessary for display can be transmitted. That is, the display means described in the claims is not limited to the display device dedicated to the heat supply device 10, and may be configured by using an external display device such as a smartphone or a HEMS monitor.

The techniques described in the claims include various modifications and modifications of the specific examples illustrated above. The technical elements described herein or in the drawings exhibit their technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the techniques illustrated in the present specification or drawings can achieve a plurality of objectives at the same time, and achieving one of the objectives itself has technical usefulness.

10: Heat supply device 12: Tank 14: Heat pump 16: Gas unit 40: Control device 42: Remote control 44: Touch panel 46: Communication interface 48: Processor 60: Own device data 62: Own device data environment information 64: Own device data Consumption information 66: History information of own device data 70: Other device data 72: Environmental information of other device data 74: Consumption information of other device data 76: History information of other device data 100: System 102: External network 104: Data server

Claims (7)

A heat supply device that is communicably connected to an external network.
A storage means for storing the own device data that at least describes the environmental information regarding the usage environment of the heat supply device and the consumption information regarding the energy consumption record of the heat supply device.
Other device data transmitted to the external network by another heat supply device of the same type as the heat supply device, which is environmental information regarding the usage environment of the other heat supply device and the energy consumption record of the other heat supply device. A receiving means for receiving data of another device that describes at least the consumption information related to the above and the history information related to the operation history of the other heat supply device .
A sorting means for selecting other device data that matches or is similar to the own device data with respect to the environmental information from a plurality of other device data received by the receiving means.
A display means for displaying consumption information of the other device data selected by the selection means, and
An operating means operated by the user to select one from the plurality of other device data in which the consumption information is displayed on the display means.
Equipped with a,
In the history information of the other device data, the operation executed by the other heat supply device is described as the operation history together with the time.
The display means teaches that the user's lifestyle is advised according to the difference between the operation history described in the other device data selected by the operation means and the actual operation state of the heat supply device. More information can be displayed,
Heat supply device. The heat supply device according to claim 1, wherein the display means rank-displays the consumption information of a plurality of other device data sorted by the sorting means. The own device data further describes history information regarding the operation history of the heat supply device.
The display means can display the history information described in the other device data selected by the operation means in comparison with the history information described in the own device data, claim 1 or 2. The heat supply device according to. The heat supply device according to any one of claims 1 to 3 , further comprising a transmission means for transmitting the own device data to the external network. The environmental information of the own device data includes information regarding the geographical position of the heat supply device.
The heat supply device according to any one of claims 1 to 4 , wherein the environmental information of the other device data includes information regarding the geographical position of the other heat supply device. The environmental information of the own device data includes information on the number of users of the heat supply device.
The heat supply device according to any one of claims 1 to 5 , wherein the environmental information of the other device data includes information on the number of users of the other heat supply device. Any of claims 1 to 6 , wherein the heat supply device further includes a heat source, a heat storage means for accumulating heat from the heat source, and a control means for controlling the heat source according to a heat storage schedule based on a record of heat demand. The heat supply device according to item 1.

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