KR20180130471A - Heating device and hot water supplying device - Google Patents

Abstract

The present invention provides technique to prevent deterioration of a component forming a heat pump in a heating device using the heat pump absorbing heat from the atmosphere as a heat source. According to the present invention, the heating device comprises: a heat pump absorbing heat from the atmosphere to heat a heat medium; a tank storing the heat medium; a heat storage circulation path circulating the heat medium between the heat pump and the tank; a heating terminal emitting the heat medium for heating; a heating circulation path circulating the heat medium between the tank and the heating terminal; and a means to count the number of starting the heat pump. In the heating device, restarting of the heat pump is prohibited when the number of starting the heat pump reaches the predetermined number of times during a predetermined period.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heating device and a hot water supply device,

The present invention relates to a heating device and a hot water supply device.

Patent Document 1 discloses a heating apparatus. This heating device includes a heat pump that heats heat from the atmosphere and heats the heat medium, a tank that stores the fruit, a heating terminal that heats the fruit by radiating heat, (Heating terminal). Between the heat pump and the tank is connected by a circulation path for heat storage (heat storage) for circulating the heat. The tank and the heating terminal are connected by a circulating path for heating to circulate the fruit.

Japanese Patent Application Laid-Open No. 2003-240341

From the viewpoint of preventing heat loss in the tank when heating is performed while driving the heat pump, it is desirable to balance the amount of heat radiation in the heating terminal and the amount of heat in the heat pump. However, since the conventional heat pump can not perform heating below the minimum heating capacity, when the heating heat quantity is smaller than the minimum heat quantity, the heat pump is repeatedly started and stopped. If the start and stop of the heat pump are frequently repeated, the deterioration of the components constituting the heat pump is accelerated.

The above-described problems also occur in a hot water supply system in which water is heated by using a heat pump that absorbs heat from the atmosphere, heated water is stored in the tank, and hot water is supplied from the tank if necessary. Even in this case, if the starting and stopping of the heat pump is repeated frequently, the deterioration of the components constituting the heat pump is accelerated.

The present specification provides techniques for solving the above problems. The present specification provides a technique capable of preventing deterioration of components constituting a heat pump in a heating device or a hot water supply device that uses a heat pump that absorbs heat from the atmosphere as a heat source.

The heating apparatus disclosed in this specification includes a heat pump that heats heat from the atmosphere to heat the heat medium, a tank that stores the heat, And a heating circulation path for circulating the heat between the tank and the heating terminal. The heating circulation path is a heating circulation path for circulating the refrigerant between the heating terminal and the heating terminal, And means for counting the number of starting times of the heat pump. In this heating device, when the number of starts of the heat pump reaches a predetermined number of times in a predetermined period, the restart of the heat pump is prohibited.

In the above heating apparatus, by limiting the number of times the heat pump is started within a predetermined period (for example, one day), the heat pump is prevented from repeatedly starting and stopping frequently. According to the heating apparatus described above, deterioration of the components constituting the heat pump can be prevented.

In the above heating apparatus, it is preferable to determine the timing at which the number of times of starting the heat pump is counted based on past heating use results.

As shown in FIG. 6, the amount of heating heat required in a general household fluctuates within one day, and the heating heat amount is lower than the minimum heating ability of the heat pump (time zone in which the amount of heat of heating is small) 92 (Time zone in which the amount of heat of heating is large) 94 in which the amount of heat of heating exceeds the minimum heating capacity of the heat pump. In the time zone 92 in which the heating calorie is small, the heat pump is repeatedly started and stopped. When the count of the number of times of starting the heat pump is started at the timing (timing A in FIG. 6) at which the heating calorie amount is small, the number of times the heat pump is started The heat pump can not be started in the time zone 94 in which the heat quantity of heat subsequent to the heat pump 94 reaches a predetermined number of times. On the other hand, when the count of the number of starts of the heat pump is started at the timing (timing of FIG. 6B) when the time zone 94 with a large amount of heating heat is started, You can start as usual. Usually, in the time zone 94 in which the heat quantity of heating is large, since the heat pump is continuously operated without stopping, the heat pump does not repeatedly start and stop, and the number of starting times reaches the predetermined number. According to the heating apparatus described above, the timing at which the start of counting the number of times of starting the heat pump is determined based on the past heating use results, thereby suppressing the situation where the heat pump repeatedly starts and stops, The operation of the heat pump can be ensured.

In the above heating apparatus, the time for switching the heating calorie amount from the past heating use performance to a state in which the heating heat amount is lower than the minimum heating capability of the heat pump is set to a timing for starting counting the number of times of starting the heat pump .

According to the above heating apparatus, it is possible to start counting the number of times of starting the heat pump at the timing (timing of Fig. 6B) when the time zone 94 in which the heat quantity of heat of heating is large starts in Fig. It is possible to secure the operation of the heat pump in a time zone in which the amount of heating heat is large while suppressing the situation in which the heat pump repeatedly starts and stops.

Another heating device disclosed in this specification includes a heat pump that absorbs heat from the atmosphere and heats the heat, a tank that stores the heat, a heat storage circulation path that circulates the heat between the heat pump and the tank, And a heating circulation path for circulating the heat between the tank and the heating terminal. In this heating apparatus, when the outside air temperature is lower than the predetermined temperature and the heating heat amount is lower than the predetermined heat amount after the heat pump is stopped, the restart of the heat pump is prohibited.

In general heating, when the outside temperature is high, the amount of heat required is small, and when the outside temperature is low, the amount of heat required is also large. Even if the outside temperature is low, it is considered that the heating is not so high when the heating calorie is low. In the above heating apparatus, when the outside air temperature is lower than the predetermined temperature and the heating heat amount is lower than the predetermined heat amount, restarting of the heat pump is prohibited, thereby suppressing the frequent repetition of the start and stop of the heat pump. According to the heating apparatus described above, deterioration of the components constituting the heat pump can be prevented.

Another heating device disclosed in this specification includes a heat pump that absorbs heat from the atmosphere and heats the heat, a tank that stores the heat, a heat storage circulation path that circulates the heat between the heat pump and the tank, And a heating circulation path for circulating the heat between the tank and the heating terminal. In this heating device, after the heat pump is stopped, the restart of the heat pump is prohibited until a predetermined time elapses.

The stoppage of the heat pump occurs when, for example, the heating calorie is below the minimum heating capacity, except when the heating operation is stopped. In this case, even if the heat pump is started, the heat pump may be stopped again in a short time. In the heating apparatus described above, the restart of the heat pump is prohibited until a predetermined time elapses after the heat pump is stopped, thereby suppressing the frequent repetition of the start and stop of the heat pump. According to the heating apparatus described above, deterioration of the components constituting the heat pump can be prevented.

The present specification also discloses a hot water supply device. This water heater includes a heat pump that absorbs heat from the atmosphere to heat water, a tank that stores water, a heat storage circulation path that circulates water between the heat pump and the tank, and a water supply path that supplies water to the tank A water supply passage for supplying hot water from the tank, and means for counting the number of starting times of the heat pump. In this water heater, restarting of the heat pump is prohibited when the number of times of starting the heat pump in a predetermined period reaches a predetermined number of times.

In the above hot water supply apparatus, by limiting the number of times the heat pump is started within a predetermined period (for example, one day), the heat pump frequently suppresses the occurrence of repeated start and stop. According to the hot water supply apparatus, deterioration of components constituting the heat pump can be prevented.

1 is a diagram schematically showing a configuration of a hot water heating system 10 of the first embodiment.
2 is a view showing the flow of heat when heating the heat pump unit 20 while being operated.
3 is a view showing the flow of the fruit when the temperature of the fruit sent from the tank 30 to the heating forward path 56 is high with respect to the temperature of the fruit required by the heating terminal 90. Fig.
4 is a view showing the flow of the fruit when the temperature of the fruit sent from the tank 30 to the heating forward path 56 is low with respect to the temperature of the fruit required by the heating terminal 90. Fig.
5 is a flowchart of processing for determining whether to permit or prohibit starting of the heat pump unit 20. [
6 is a diagram showing the relationship between the variation of the heating calorie during one day and the time at which counting of the number of starts of the heat pump unit 20 is started.
7 is a diagram schematically showing the configuration of the hot water heating system 100 of the second embodiment.
8 is a flowchart of a process for determining whether to permit or prohibit starting of the heat pump unit 120. Fig.

In one embodiment of the present invention, it is preferable to use water or an antifreeze (antifreeze liquid) as a heat medium for heating.

In one embodiment of the present invention, it is preferable to adopt a combustion device for burning a fuel such as a combustible gas to the auxiliary heat source (auxiliary heat source).

(Example)

(Embodiment 1)

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described with reference to the drawings. Fig. 1 shows a hot water heating system (hot water heating system) 10 of the first embodiment. 1, the hot water heating system 10 includes a heat pump unit 20, a tank unit 28, a hot water heating unit 80, And a heating terminal (heating terminal) 90.

The heat pump unit 20 is a heat pump that absorbs heat from the atmosphere and heats the fruit sent from the tank unit 28. The heat pump unit 20 includes a compressor, a heat radiator, an expansion valve, an evaporator, and a refrigerant circulation path for connecting them in order Circulation path). In addition to this, a fan for blowing air to the evaporator and a motor for driving it are also provided. In the refrigerant circulation path, carbon dioxide, which is a refrigerant, is charged. The details of the heat pump unit 20 are the same as those known in the art, so that the description thereof is omitted here. The heat pump unit 20 is also provided with a circulation pump 22 for circulating the heat between the heat pump unit 20 and the tank unit 28. The operation of the components of the heat pump unit 20 including the circulation pump 22 is controlled by a controller 21. [ The heat pump unit 20 is also provided with an outside temperature thermistor 26 for detecting the outside air temperature. The outside temperature thermistor (26) is connected to the controller (21).

The tank unit 28 is provided with a tank 30 for storing fruits. The fruit of this embodiment is antifreeze. The tank 30 of this embodiment has a capacity of 30 liters as an example. In the tank 30, a plurality of tank thermistors 42a, 42b, and 42c are provided along the height direction. In this embodiment, the tank thermistor 42a is installed at the upper portion of the tank 30 (for example, at a position of 10 liters from the top of the tank 30), and the tank thermistor 42b is provided at the middle of the tank 30 The tank thermistor 42c is installed at a lower portion of the tank 30 (for example, at a position of 20 liters from the top of the tank 30) Respectively. The tank thermistors 42a, 42b and 42c are connected to the controller 54. [ The controller 54 can grasp the amount of heat stored in the tank 30 from the temperatures detected by the tank thermistors 42a, 42b, and 42c. The thermistor for detecting the temperature of the heat in the tank 30 is not limited to the above three, but four or more thermistors may be provided, and two thermistors for detecting the temperature of the heat in the tank 30 may be provided. The controller 54 also has a counter for counting the number of times the heat pump unit 20 is started.

The tank 30 is connected to the heat pump unit 20 through a heat storage forward path 34 and a heat storage return path 32. The heat storage furnace 34 is a duct for sending the heat from the tank 30 to the heat pump unit 20 and is connected to the bottom of the tank 30. The heat accumulating return path 32 is a conduit for returning the heat from the heat pump unit 20 to the tank 30 and is connected to the top of the tank 30. [ The heat storage forward path 34 and the heat storage return path 32 constitute a circulation path for circulating the heat between the heat pump unit 20 and the tank 30. The circulation pump 22 is provided in the circulation path. Although the circulation pump 22 of this embodiment is incorporated in the heat pump unit 20, the position of the circulation pump 22 is not particularly limited.

The heat storage furnace 34 is provided with a manual valve 24 and a heat storage furnace thermistor 44. Likewise, a passive valve 24 and a heat storage ear thermistor 46 are also provided in the heat storage hearth 32. The heat storage furnace thermistor 44 and the heat storage ear thermistor 46 are connected to the controller 54. The controller 54 checks the temperature of the heat before the heating by the heat pump unit 20 from the temperature detected by the heat storage king thermistor 44 and detects the temperature of the heat from the detection temperature by the heat storage ear thermistor 46 The temperature of the fruit after heating by the heating means 20 can be grasped.

The heating terminal 90 heats the heat from the tank 30 to heat it. The heating terminal 90 is, for example, a panel heater, a panel radiator, a floor heating, a fan convector, and a warm room air conditioner. The heating terminal 90 is connected to the tank 30 through the heating forward path 56 and the heating return path 60. The heating furnace 56 is a duct for sending the heat from the tank 30 to the heating terminal 90 and is connected to the top of the tank 30. The heating return path 60 is a conduit for returning the fruit from the heating terminal 90 to the tank 30 and is connected to the bottom portion of the tank 30. The heating forward path 56 and the heating return path 60 constitute a circulation path for circulating the heat between the tank 30 and the heating terminal 90.

A drain pipe (50) having a manual valve (52) is connected to the heating return path (60). Further, an expansion tank (70) is provided in the heating return path (60). In the present embodiment, since the circuit for circulating the heat is a closed circuit, the expansion tank 70 is prepared to absorb the thermal expansion of the heat. Further, the position where the expansion tank 70 is connected is not limited to the heating return path 60, and may be connected to the heating forward path 56 or another path, for example.

The heating front passageway (56) is connected to the heating terminal (90) via the hot water heating unit (80). The hot water supply heating unit 80 is a combustion type heat source unit and has two burners 84 and 86 for burning a combustible gas. One of the burners 84 heats the water (hot water) flowing through the hot water supply line (hot water supply line) 82 as a hot water supply. The other burner 86 is for heating and heats the fruit flowing through the heating forward path 56 as necessary. The hot water supply heating unit 80 is also provided with a controller 88. The hot water supply heating unit 80 is provided with a circulation pump 87 for circulating the heat between the heating terminal 90 and the tank unit 28. The location of the circulation pump 87 is not limited to the hot water heating unit 80 and is not particularly limited. A burner outlet thermistor 89 is provided downstream of the burner 86 in the heating furnace 56. The burner outlet thermistor 89 is connected to the controller 88. According to this configuration, when the temperature of the fruit to be sent to the heating terminal 90 through the heating front passageway 56 is excessively low, the heating terminal 90 is heated by heating the fruit flowing through the heating front passageway 56 by the burner 86, It is possible to increase the temperature of the fruit to be sent to the heat exchanger.

A heating path 56 and a heating return path 60 are connected to each other through a bypass path 64. Thus, a part or all of the fruit flowing in the heating return path 60 can be sent to the heating forward path 56 without passing through the tank 30. [ A mixing valve 66 is provided at a branching position (branched position) of the heating return path 60 and the bypass path 64 so that the heating forward path 56 is branched from the heating return path 60 through the bypass path 64, And the ratio of the flow rate of the fruit sent from the heating return path 60 to the heating forward path 56 through the tank 30 can be adjusted. The mixing valve 66 is connected to the controller 54 and its operation is controlled by the controller 54. [ According to this configuration, when the temperature of the fruit to be sent to the heating terminal 90 through the heating forward path 56 is excessively high, the fruit after the heat radiation flowing through the heating return path 60 is combined with the fruit flowing through the heating forward path 56 The temperature of the fruit sent to the heating terminal 90 can be lowered.

The heating front furnace 56 is provided with a first heating furnace furnace thermistor 48 and a second heating furnace furnace thermistor 58. The first heating radiator thermistor 48 is provided on the upstream side of the confluence point where the bypass path 64 joins the heating forward path 56 and is connected to the heating front path 56 through the heating path 56, The temperature is detected. The second heating radiator thermistor 58 is provided on the downstream side of the confluence point where the bypass path 64 joins the heating forward path 56 and is connected to the heating path 56 And detects the temperature after the fruit sent from the bypass path 64 to the heating forward path 56 is mixed. A heating ear thermistor 62 is provided in the heating return path 60. The heating ear thermistor 62 detects the temperature of the fruit flowing through the heating return path 60. The first heating king thermistor 48, the second heating king thermistor 58 and the heating ear thermistor 62 are connected to the controller 54. The controller 54 controls the operation of the mixing valve 66 based on the detected temperatures of the first heating king thermistor 48, the second heating king thermistor 58 and the heating ear thermistor 62, The temperature of the fruit to be sent to the heat exchanger 90 can be adjusted to a desired temperature.

The controller 88 can calculate the heating calorie amount in the heating terminal 90. [ The heating calorie amount in the heating terminal 90 can be calculated using, for example, the detection temperature of the heating ear thermistor 62, the detection temperature of the burner outlet thermistor 89, and the rotation number of the circulation pump 87 . Or the heating terminal 90 can be obtained by using the detected temperature of the thermostat-controlled thermistor 44, the detected temperature of the thermostat ear thermistor 46 and the rotational speed of the circulating pump 22, Can be calculated.

Fig. 2 shows the flow of the heat when the heat pump unit 20 is heated while being operated. As shown in Fig. 2, the heating terminal 90 is supplied with high-temperature fruit from the upper portion of the tank 30 through the heating forward path 56. [ The high-temperature fruit sent to the heating terminal 90 is returned to the lower portion of the tank 30 through the heating return path 60 after being discharged from the heating terminal 90. On the other hand, the heat pump unit 20 is fed with low-temperature heat from the lower portion of the tank 30 through the heat-storage royal road 34. The low-temperature heat transferred to the heat pump unit 20 is returned to the upper portion of the tank 30 through the heat accumulating return path 32 after being heated by the heat pump unit 20. [

3 shows the flow of the fruit when the temperature of the fruit sent from the tank 30 to the heating forward path 56 is high with respect to the temperature of the fruit required by the heating terminal 90. [ In this case, the mixing valve 66 is controlled to increase the flow rate of the heat from the heating return path 60 to the heating forward path 56 via the bypass path 64, To reduce the flow rate of the fruit sent to the heating heating furnace 56. The temperature of the fruit to be sent from the heating forward path 56 to the heating terminal 90 can be adjusted to the temperature of the fruit required by the heating terminal 90. [ Even when the temperature of the heat required by the heating terminal 90 is lowered, it is possible to quickly respond to the change in the demand of the heating terminal 90 without changing the heating ability of the heat pump unit 20. [

4 shows the flow of the fruit when the temperature of the fruit sent from the tank 30 to the heating forward path 56 is low with respect to the temperature of the fruit required by the heating terminal 90. Fig. In this case, the burner 86 heats the heat flowing through the heating forward path 56. The temperature of the fruit sent from the heating forward path 56 to the heating terminal 90 can be quickly adjusted to the temperature of the fruit required by the heating terminal 90 by adjusting the amount of heating in the burner 86. [ Even when the temperature of the heat required by the heating terminal 90 rises, it is possible to quickly respond to the change in the demand of the heating terminal 90 without changing the heating ability of the heat pump unit 20. [

In the hot water heating system 10 of the present embodiment, when the heating operation is performed in the heating terminal 90 and the detected temperature of the tank thermistor 42a is equal to or lower than a predetermined temperature (for example, 75 degrees) (20).

The heating operation of the heating terminal 90 is stopped or the detection temperature of the tank thermistor 42c is lower than a predetermined temperature (for example, The heat pump unit 20 is stopped when the detected temperature of the thermistor 44 exceeds a predetermined temperature (for example, 70 degrees).

If the amount of heat to be heated by the heating terminal 90 is smaller than the minimum heating capability of the heat pump unit 20 when the start and stop of the heat pump unit 20 is controlled as described above, ) There is a situation where the start and stop are repeated. If the heat pump unit 20 repeatedly starts and stops, the components constituting the heat pump unit 20 are rapidly deteriorated. Here, the hot water heating system 10 of this embodiment judges whether or not to permit the starting of the heat pump unit 20 by the process of FIG.

In step S2, a time (count start time) for starting counting the number of times of starting the heat pump unit 20 is determined. In the hot water supply heating system 10 of the present embodiment, the count start time is set based on past heating use results. More specifically, in the hot water heating system 10 of the present embodiment, the average time when the amount of heating heat is switched from a state in which the heating capacity of the heat pump unit 20 is lower than the minimum heating capacity to a state in which the heating capacity is higher , And sets the time as the count start time. In the past, the heating use results of the previous day or the previous day may be used, the heating use results of the same day of the past may be used, and the heating use results of the past predetermined period (for example, one week) May be used.

In step S4, the process waits until the count start time is reached.

In step S6, counting of the number of times of starting the heat pump unit 20 is started. Thereafter, the number of starting times increases each time the heat pump unit 20 is started.

In step S8, the process waits until the heat pump unit 20 is stopped. When the heat pump unit 20 is stopped, the process proceeds to step S10.

In step S10, it is determined whether or not the number of times the heat pump unit 20 is started reaches a predetermined number (for example, 10). When the number of times of starting the heat pump unit 20 reaches a predetermined number (YES), the process proceeds to step S18 to prohibit the heat pump unit 20 from starting. When the number of times of starting the heat pump unit 20 has not reached the predetermined number (NO in step S10), the process proceeds to step S12.

In step S12, it is determined whether or not the outside air temperature is equal to or lower than a predetermined temperature (for example, 5 degrees) and the heating heat amount is equal to or lower than a predetermined heat amount (for example, 1500 kcal / h). When the outside air temperature is lower than the predetermined temperature and the heating heat amount is lower than the predetermined heat amount (YES), the process proceeds to step S18 to prohibit the start of the heat pump unit 20. [ When the outside air temperature exceeds the predetermined temperature or the heating heat amount exceeds the predetermined heat amount (NO in step S12), the process proceeds to step S14.

In step S14, it is determined whether or not a predetermined time (for example, one hour) has elapsed after the heat pump unit 20 is stopped. If one hour has not elapsed after the heat pump unit 20 is stopped (NO), the process proceeds to step S18 to prohibit the heat pump unit 20 from starting. When one hour has elapsed after the heat pump unit 20 is stopped (YES in step S14), the process proceeds to step S16.

In step S16, the start of the heat pump unit 20 is permitted.

In step S20, it is determined whether or not one day has elapsed from the count start time. If one day has not elapsed from the count start time (NO), the process returns to step S8. When one day has elapsed from the count start time (YES in step S20), the process is terminated.

In the hot water heating system 10 of the present embodiment, the time to start counting the number of times of starting the heat pump unit 20 is determined based on past heating use results. As shown in Fig. 6, the amount of heat required is fluctuated within one day, and the amount of heat of heating is lower than the minimum heating capacity of the heat pump unit 20 (time period during which the heating calorie is small) 92 (Time zone in which the heating calorie is large) 94 in which the heating calorie exceeds the minimum heating capacity. In the time zone 92 in which the heating calorie is small, the heat pump unit 20 repeats starting and stopping. If the heat pump unit 20 starts counting the number of starts of the heat pump unit 20 at the timing (timing A in FIG. 6) at which the heat quantity of heat is small, The number of times of starting the pump unit 20 reaches a predetermined number of times and the heat pump unit 20 can not be started in the time zone 94 in which the heat quantity of heat subsequent to the pump unit 20 is large. On the other hand, in the hot water heating system 10 of this embodiment, the count of the number of times of starting the heat pump unit 20 is started at the timing (timing of FIG. 6B) at which the time zone 94 in which the heat quantity of heat is large starts. Since the heat pump unit 20 continues to operate without stopping in the time zone 94 where the heat quantity of heat is large, the heat pump unit 20 does not repeatedly start and stop, Do not throw it away. According to the hot water heating system 10 of the present embodiment, the operation of the heat pump unit 20 in the time zone 94 with a large amount of heat of heating can be ensured while suppressing the situation in which the heat pump unit 20 repeatedly starts and stops can do.

In the hot water heating system 10 of the present embodiment, when the outside air temperature is lower than the predetermined temperature and the heating heat amount is lower than the predetermined heat amount, the start of the heat pump unit 20 is prohibited. In general heating, when the outside temperature is high, the amount of heat required is small, and when the outside temperature is low, the amount of heat required is also large. Even if the outside temperature is low, it is considered that the heating is not so high when the heating calorie is low. In the hot water heating system 10, the starting of the heat pump unit 20 is prohibited in such a case, thereby suppressing the situation in which the heat pump unit 20 frequently repeats starting and stopping. Deterioration of parts constituting the heat pump unit 20 can be prevented.

In the hot water heating system 10 of the present embodiment, starting of the heat pump unit 20 is prohibited until a predetermined time elapses after the heat pump unit 20 is stopped. The stoppage of the heat pump unit 20 occurs when the amount of heat required for heating other than when the heating operation of the heating terminal 90 is stopped is lower than the minimum heating capacity of the heat pump unit 20, for example. In such a case, even if the heat pump unit 20 is started, the heat pump unit 20 may be stopped again in a short time. In the hot water heating system 10 of the present embodiment, starting of the heat pump unit 20 is prohibited until a predetermined time elapses after the heat pump unit 20 is stopped, It suppresses the situation where the stop is frequently repeated. According to the hot water heating system 10 described above, deterioration of the components constituting the heat pump unit 20 can be prevented.

At the time when the start of the heat pump unit 20 is prohibited by the process of Fig. 5, the heat pump unit 20 (for example, at 0, 6, 12, 18) May be allowed to start.

(Second Embodiment)

Fig. 7 shows a hot water heating system according to the second embodiment. 7, the hot water heating system 100 includes a heat pump unit 120, a tank unit 128, a hot water heating unit 180, and a heating terminal 190.

The heat pump unit 120 has the same configuration as the heat pump unit 20 of the first embodiment. The heat pump unit 120 is a heat pump that heats the water sent from the tank unit 128 by absorbing heat from the atmosphere. The heat pump unit 120 is provided with a circulation pump 122 for circulating water between the heat pump unit 120 and the tank unit 128. The operation of the components of the heat pump unit 120 including the circulation pump 122 is controlled by the controller 121.

The tank unit 128 has a tank 130 for storing water. The tank 130 of this embodiment has a capacity of, for example, 50 liters. In the tank 30, a plurality of tank thermistors 142a, 142b, and 142c are provided along the height direction. The tank thermistors 142a, 142b, and 142c are connected to the controller 154. [ The controller 154 can grasp the amount of heat stored in the tank 130 from the temperatures detected by the tank thermistors 142a, 142b, and 142c. The controller 154 also has a counter that counts the number of times the heat pump unit 120 is started.

The tank 130 is connected to the heat pump unit 120 through a heat storage heating path 134 and a heat storage return path 132. The heat storage heating furnace 134 is a duct for sending water from the tank 130 to the heat pump unit 120 and is connected to the bottom of the tank 130. The heat accumulation return path 132 is a conduit for returning water from the heat pump unit 120 to the tank 130 and connected to the top of the tank 130. [ The heat storage forward path 134 and the heat storage return path 132 constitute a circulation path for circulating water between the heat pump unit 120 and the tank 130. The circulation pump 122 is provided in the circulation path.

A manual valve 124 and a storage-and-storage furnace thermistor 144 are provided in the heat storage furnace 134. Similarly, a passive valve 124 and a heat accumulating ear thermistor 146 are also provided in the heat accumulating return path 132. The thermostat-king thermistor 144 and the thermostat-ear thermistor 146 are connected to the controller 154. The controller 154 grasps the temperature of the water before the heating by the heat pump unit 120 from the temperature detected by the heat storage king thermistor 144 and controls the temperature of the heat pump unit 120 It is possible to grasp the temperature of the water after heating by the heating means.

The heating terminal 190 heats by heat radiation from the heating-purpose fruit. In this embodiment, the heating-purpose fruit is an antifreeze. The heating terminal 190 is, for example, a panel heater, a panel radiator, a floor heating, a fan curve, and a hot-room type air conditioner. The heating terminal 190 is connected to the heat exchanger (heat exchanger) 110 through the heating forward path 156 and the heating return path 160. The heat exchanger 110 is a double wall type liquid-liquid heat exchanger (not shown) for performing heat exchange between hot water from the tank 130 and low temperature heating fruits from the heating terminal 190 Liquid-liquid heat exchanger). The heating furnace 156 is a conduit for sending heating heat from the heat exchanger 110 to the heating terminal 190. The heating return path 160 is a duct for returning heating-purpose fruit from the heating terminal 190 to the heat exchanger 110. The heating pathway 156 and the heating pathway 160 constitute a circulation path for circulating heat for heating between the heat exchanger 110 and the heating terminal 190. A heating ear thermistor 162 is provided in the vicinity of the inlet of the heat exchanger 110 of the heating return path 160. In the vicinity of the outlet of the heat exchanger 110 of the heating furnace furnace 156, a heating furnace furnace thermistor 158 is provided.

The tank 130 is connected to the heat exchanger 110 through a heat dissipation path (heat dissipation forward path) 112 and a heat dissipation return path (heat dissipation return path) 114. The heat radiating heat exchanger 112 is a duct for sending water from the tank 130 to the heat exchanger 110 and is connected to the upper portion of the tank 130. The heat releasing return path 114 is a pipe for returning water from the heat exchanger 110 to the tank 130 and is connected to the bottom of the tank 130. The heat radiating heat exchanger 112 and the heat radiating heat exchanger 114 constitute a circulation path for circulating water between the heat exchanger 110 and the tank 130. A heat radiating thermostat 148 is provided in the vicinity of the inlet of the heat exchanger 110 of the heat radiating heat exchanger 112. A circulation pump 116 is provided in the heat-releasing return path 114. The operation of the circulation pump 116 is controlled by the controller 154. The controller 154 adjusts the number of rotations of the circulation pump 116 based on the detected temperatures of the heat radiating furnace thermistor 148, the heating mantle thermistor 158 and the heating hearth thermistor 162.

The heating front wheel 156 is connected to the heating terminal 190 via the hot water supply heating unit 180. [ The hot water supply heating unit 180 is a combustion type heat source unit and has two burners 184 and 186 for burning a combustible gas. One of the burners 184 is for hot water supply and heats the water flowing through the hot water duct 182 as necessary. A burner outlet thermistor 185 is provided downstream of the burner 184 in the hot water supply line 182. The burner outlet thermistor 185 is connected to the controller 188. According to this configuration, when the hot water supply temperature from the hot water supply duct 182 is too low, the temperature of the hot water supply can be raised by heating the water flowing through the hot water supply duct 182 by the burner 184. The other burner 186 is for heating, and heats the heating heat flowing through the heating forward path 156 as necessary. The hot water supply heating unit 180 is also provided with a controller 188. The hot water heating unit 180 is provided with a circulation pump 187 for circulating heat for heating between the heating terminal 190 and the tank unit 128. A burner outlet thermistor 189 is provided downstream of the burner 186 in the heating furnace 156. The burner outlet thermistor 189 is connected to the controller 188. According to this configuration, when the temperature of the heat for heating to be sent to the heating terminal 190 through the heating front passageway 156 is excessively low, the heating heat flowing through the heating front passageway 156 is heated by the burner 186, 190 can be increased.

A water supply line (water supply line) 102 for supplying water from the water supply to the tank 130 is connected to the bottom of the tank 130. In the water supply line 102, a water supply thermistor 103 is provided. A high temperature water conduit 104 for supplying high temperature water from the upper portion of the tank 130 is connected to the top of the tank 130. The high-temperature water line 104 is provided with a high-temperature water thermistor 105. A low-temperature water pipe (106) for supplying low-temperature water from the water supply is branched from the water supply pipe (102). The hot water conduit 104 and the low-temperature water conduit 106 are connected to the mixing valve 108. In the mixing valve 108, the hot water from the hot water duct 104 is mixed with the low-temperature water from the low-temperature water duct 106, and the mixed water is supplied to the hot water duct 182. In the vicinity of the mixing valve 108 in the hot water supply line 182, a hot water tank thermistor 109 for detecting the water temperature after mixing is provided. The controller 154 adjusts the opening degree of the mixing valve 108 based on the detection values of the water supply thermistor 103, the hot water thermistor 105 and the hot water supply thermistor 109.

In the hot water heating system 100 of this embodiment, when the hot water supply operation or the heating operation is performed and the detection temperature of the tank thermistor 142a is equal to or lower than a predetermined temperature (for example, 75 degrees), the heat pump unit 120 Start.

In the hot water heating system 100 of the present embodiment, when the hot water supply operation and the heating operation are terminated when the heat pump unit 120 is operating, or when the detection temperature of the tank thermistor 142c reaches a predetermined temperature (for example, 75 degrees) The heat pump unit 120 is stopped when the detected temperature of the thermistor 144 exceeds a predetermined temperature (for example, 70 degrees).

When the amount of heat to be used is smaller than the minimum heating capability of the heat pump unit 120 when the start and stop of the heat pump unit 120 are controlled as described above, the heat pump unit 120 repeatedly starts and stops the heat pump unit 120 There is a case where a situation occurs. When the heat pump unit 120 is repeatedly started and stopped, the components constituting the heat pump unit 120 are rapidly deteriorated. Here, the hot water supply system 100 of the present embodiment determines whether or not the start of the heat pump unit 120 is permitted or prohibited by the processing of FIG.

In step S102, a time (count start time) for starting counting the number of times of starting the heat pump unit 120 is determined. In the hot water heating system 100 of this embodiment, the count start time is set based on the past calorie usage history. More specifically, in the hot water supply heating system 100 of the present embodiment, the average heating time from the past heat quantity use results to the state in which the heat quantity to be used is switched from a state in which the heat capacity of the heat pump unit 120 is lower than the minimum heating capacity And sets the time as the count start time. In the past, calorie use results of the previous day or the previous day may be used, past calorie use results of the same day may be used, and calorie usage of a past predetermined period (for example, one week) may be used Performance may be used.

In step S104, the process waits until the count start time is reached.

In step S106, counting of the number of times of starting the heat pump unit 120 is started. Thereafter, the number of starting times increases each time the heat pump unit 120 is started.

In step S108, the process waits until the heat pump unit 120 is stopped. When the heat pump unit 120 is stopped, the process proceeds to step S110.

In step S110, it is determined whether or not the number of times the heat pump unit 120 is started reaches a predetermined number (for example, 10 times). If the number of times of starting the heat pump unit 120 reaches the predetermined number (YES), the process proceeds to step S116 to prohibit the heat pump unit 120 from being started. When the number of times of starting the heat pump unit 120 has not reached the predetermined number of times (NO in step S110), the process proceeds to step S112.

In step S112, it is determined whether or not a predetermined time (for example, one hour) has elapsed after the heat pump unit 120 is stopped. If it is determined that one hour has not elapsed since the heat pump unit 120 was stopped (NO), the process proceeds to step S116 to prohibit the heat pump unit 120 from starting. When one hour has elapsed after the heat pump unit 120 is stopped (YES in step S112), the process proceeds to step S114.

In step S114, the start of the heat pump unit 120 is permitted.

In step S118, it is determined whether or not one day has elapsed from the count start time. When one day has not elapsed from the count start time (NO), the process returns to step S108. When one day has elapsed from the count start time (YES in step S118), the process is terminated.

The hot water heating system 100 of the present embodiment can suppress the situation where the heat pump unit 120 frequently repeats starting and stopping like the hot water heating system 10 of the first embodiment. According to the hot water heating system 100 described above, deterioration of the components constituting the heat pump unit 120 can be prevented.

While the embodiments of the present invention have been described in detail, the present invention is not limited to these embodiments. The techniques described in the claims include various modifications and changes to the specific examples described above.

The technical elements described in the present specification or drawings exert technical merit by itself or in various combinations, and the invention is not limited to the combination of claims described in the application. Further, the techniques exemplified in the present specification or drawings can achieve a plurality of objectives at the same time, and have technological usefulness by achieving one of them.

10: Hot water heating system
20: Heat pump unit
21: Controller
22: circulation pump
24: Manual valve
26: Outside temperature thermistor
28: Tank unit
30: tank
32: Earmuffs for heat storage
34: Warming furnace
42a, 42b, 42c: tank thermistor
44: Thermocouple thermistor
46: Thermostatic ear thermistor
48: 1st heating king thermistor
50: Water pipe
52: Manual valve
54: controller
56: The heating king
58: 2nd heating king as thermistor
60: heating ear
62: Heating ear thermistor
64: Bypass path
66: mixing valve
70: expansion tank
80: Hot water heating unit
82: Hot water pipeline
84, 86: burner
87: circulation pump
88: Controller
89: Burner outlet thermistor
90: Heating terminal
92: Small time of heating calorie
94: Time zone with high heating calorie
100: Hot water heating system
102: Water pipe
103: Water supply thermistor
104: high temperature water pipe
105: High temperature water thermistor
106: Low temperature water pipe
108: mixing valve
109: Hot water thermistor
110: Heat exchanger
112:
114: Heat-resistant ear
116: circulation pump
120: Heat pump unit
121: Controller
122: circulation pump
124: Manual valve
128: Tank unit
130: tank
132: Ear thermostat
134: Warming furnace
142a, 142b, 142c: tank thermistor
144: Thermocouple thermistor
146: Thermal storage ear thermistor
148: Thermocouple as a heat radiator
154:
156: the heating king
158: Thermistor as a heating king
160: Heating ear
162: Heating ear thermistor
180: Hot water heating unit
182:
184: Burner
185: burner outlet thermistor
186: Burner
187: circulation pump
188:
189: burner outlet thermistor
190: Heating terminal

Claims (2)

A heat pump for heating the heat medium by absorbing heat from the atmosphere,
A tank for storing fruit,
A heat storage circulation path (heat storage circulation path) for circulating the heat between the heat pump and the tank,
A heating terminal (heating terminal) for heating the fruit by radiating heat,
A heating circulation path for circulating the heat between the tank and the heating terminal
Respectively,
When the outside air temperature is lower than the predetermined temperature and the heating heat amount is lower than the predetermined heat amount after the heat pump is stopped, the restart of the heat pump is prohibited
Heating equipment.
A heat pump that absorbs heat from the atmosphere to heat the fruit,
A tank for storing fruit,
A heat storage circulation path for circulating the heat between the heat pump and the tank,
A heating terminal for heating the fruit by dissipating heat,
A heating circulation path for circulating the heat between the tank and the heating terminal
Respectively,
After the heat pump is stopped, the restart of the heat pump is prohibited until a predetermined time elapses
Heating.

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