JP2003194405A - Hot water system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot water system operative at a hot water quantity level corresponding to required hot water heat quantity per day, capable of avoiding the run-out of hot water and reducible in running cost while suppressing the continuous condition of excessive hot water over a long period. <P>SOLUTION: The hot water system comprises a hot water storage tank 3 and a heating source. Plural stages of hot water quantity levels are previously set depending on the required hot water heat quantity per day. The heating source is operated to supply the hot water heat quantity corresponding to the selected hot water quantity level to the hot water storage tank 3. When supplied hot water heat quantity runs short, the hot water quantity level of the next supplied hot water heat quantity is raised corresponding thereto. When the condition of excessively supplied hot water is continued over basically determined days, the hot water quantity level is lowered by one stage. When the hot water quantity level is raised in plural levels, if the condition of excessive hot water is continued over middle-term determined days less than the basically determined days, the hot water quantity level is lowered by one stage. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot water supply apparatus having a hot water storage tank for storing hot water heated by a heating source.

[0002]

2. Description of the Related Art As a hot water supply apparatus, for example, there is a heat pump type hot water supply apparatus as shown in FIG. This heat pump type hot water supply device includes a tank unit 71 having a hot water storage tank 70 and a heat source unit 73 having a refrigerant circuit 72. Further, the refrigerant circuit 72 is configured by connecting a compressor 74, a water heat exchanger 75, an expansion valve 77 and an evaporator 78 in this order. The tank unit 71 includes the hot water storage tank 70 and a circulation path 79, and a water circulation pump 80 and a heat exchange path 81 are provided in the circulation path 79. In this case, the heat exchange passage 81 is composed of the water heat exchanger 75.

In the above apparatus, when the compressor 74 is driven and the pump 80 is driven (operated), stored water (hot water) flows out from the intake port provided at the bottom of the hot water storage tank 70 into the circulation path 79, This flows through the heat exchange passage 81.
At this time, this hot water is heated (boiled) by the water heat exchanger 75 and returned to the upper part of the hot water storage tank 70 from the hot water inlet. As a result, high-temperature hot water is stored in the hot water storage tank 70. In the current power rate system, the unit price of the power rate at midnight is set to be lower than that at daytime. Therefore, in recent years, this operation is low at midnight time (for example, time zone from 23:00 to 7:00). ) In order to reduce running costs. In this case, if the required amount of hot water for one day is small,
The required amount of hot water can be boiled only by the full boiling operation in the midnight hours, but if the required amount of hot water is large, in addition to this midnight operation, additional operation in the daytime (additional additional heating operation) Was going on. That is, the operation of boiling the required amount of hot water for one day is called the required hot water amount ensuring operation.For the required hot water amount ensuring operation, only the full amount boiling operation in the midnight time period and the midnight time period are performed. There are cases where both the total boiling operation and the above-mentioned additional reheating operation during the daytime (hereinafter referred to as additional operation) are performed.

[0004]

In such a hot water supply device, the required amount of heat (the amount of hot water) is boiled up according to the amount of hot water used by the user, and a plurality of hot water supplies are required according to the required amount of hot water for one day. The amount of hot water for each class (for example, 10 levels) is set, and the required amount of hot water ensuring operation is performed to boil the amount of hot water corresponding to the amount of hot water selected from the plurality of levels. However, if the amount of hot water in the hot water storage tank is used and falls below the specified amount, it will be necessary to perform a hot water run-out operation for the shortage (hereinafter referred to as an additional hot water operation) separately from the required hot water quantity ensuring operation during the daytime. . That is, in the case where the required hot water amount ensuring operation is the full-boiling operation in the midnight time period and the additional operation in the daytime, in order to replenish the shortage, the reheating operation for the shortage is further performed in the daytime. . In such a case, in the next required hot water amount ensuring operation, the hot water amount level is raised according to the operating time of the supplementary reheating operation.

Therefore, when the user uses a large amount of hot water, the next time the operation is performed, the operation is performed by raising the hot water amount level by several steps. At this time, if the use of this large amount of hot water is so-called sudden, for example, if the hot water in the hot water storage tank is supplied to the bathtub more than once by a visitor or the like, the level is raised in the next boiling operation. At the level of the amount of hot water, the amount of hot water is boiled more than the required amount of hot water, and thereafter there is a possibility that the excess hot water will be in an "excessive amount of hot water" state.

That is, the conventional hot water supply apparatus of this type performs the control shown in the flowchart of FIG. As shown in step S4, when the boiling of the entire amount is started, it is determined whether or not the excess water state will be caused in the boiling thereafter. In this case, as in step S5, it is determined whether or not the temperature T2 (the temperature of the temperature sensor attached to the predetermined position of the hot water storage tank 70) is equal to or higher than the predetermined temperature (for example, 45 degrees). If it is 45 degrees or more, it is determined that there is an excessive amount of hot water, and the process proceeds to step S6. If it is less than 45 degrees, it is determined that there is not an excessive amount of hot water, and this control ends. Then, in the case of the hot water excess state, the number of days in the hot water excess state (remaining hot water days) is counted in step S6, and if the number of remaining hot water days is, for example, 3 days in step S7, the process proceeds to step S11. The hot water amount level is returned to the original level (automated level = previous level for multiple UPs).

Therefore, when the level of hot water rises by several steps as described above and the hot water state continues for a predetermined number of days (for example, 3 days), conventionally, it is determined that the level is suddenly increased, I had returned to the level of the amount of hot water before the level up. However, depending on the relationship between the reheating operation time in the daytime and the reference hot water amount that raises the hot water amount level, there is a possibility that hunting may occur in which the hot water amount level once returns and then rises again, resulting in a stable hot water amount. It was difficult to set the level. Further, if the amount of hot water before the level up is, for example, level 4, if a large amount of water is used, the next amount of hot water level will rise to level 7, and if the excessive amount of hot water continues for the predetermined number of days (for example, 3 days). , It will return to the original level 4. However, if the proper level of the amount of hot water is level 5 or level 6, there is a hot water shortage phenomenon in which hot water is insufficient at the original level 4.
That is, if the amount of hot water in the hot water storage tank 70 becomes equal to or less than the specified amount (required amount of hot water), it may lead to running out of hot water depending on the subsequent usage. Therefore, when the amount of hot water used by the user changes, it is necessary to bring the amount of hot water to the required level as quickly as possible. However, with the above-described control method of the conventional hot water supply apparatus of this type, it is difficult to make the amount of hot water converge to an appropriate level.

The present invention has been made to solve the above-mentioned conventional drawbacks, and an object thereof is to be able to operate at a hot water amount level corresponding to a required hot water amount per day.
It is an object of the present invention to provide a hot water supply device that can avoid running out of hot water and can suppress running time of an excessive amount of hot water for a long time to reduce running costs.

[0009]

Therefore, in the hot water supply device according to the first aspect of the present invention, in the hot water supply device provided with the hot water storage tank 3 and the heating source, the hot water amount levels of a plurality of classes are determined according to the required hot water heat amount per day. The heating source operates so as to supply the hot water amount according to the selected hot water amount level to the hot water storage tank 3, and when the hot water amount to be supplied is insufficient, the next hot water amount to be supplied is set to that. The hot water supply device is configured to decrease the hot water amount level by one step when the hot water amount level is raised in response to the excessive amount of hot water supplied and continues for the reference determination days. If the hot water overload condition continues for a mid-term judgment days that is less than the above standard judgment days, the hot water level optimization control is performed to decrease the hot water level by one level. It is characterized in.

In the hot water supply apparatus according to the first aspect, when the amount of heat supplied to the hot water becomes insufficient, the amount of hot water to be supplied next time is increased correspondingly to the level of the amount of hot water to prevent (prevent) running out of hot water. Further, when the state of excessive heat of supplied hot water continues for the reference determination days, the level of hot water is decreased by one step, so that it is possible to prevent the excessive hot water state for a long period of time. Furthermore, when the hot water level has increased by multiple levels, if the hot water overload condition continues for a number of medium-term judgment days that are less than the above standard judgment days, it can be determined that this level increase is so-called sudden, and the hot water level is only one level. This can be lowered to prevent this excess hot water.

In the hot water supply apparatus according to the second aspect of the present invention, the hot water level optimizing control is such that if the hot water level is reduced by one step, and if the hot water excess state continues for a short period of short-term determination days slightly shorter than the medium-term determination days. It is characterized by including control for further lowering the level of hot water by one step.

In the hot water supply apparatus according to the second aspect, even if the hot water level is lowered by one step, if the hot water level continues for a short number of days, the hot water level also causes the hot water level. By lowering the level of hot water by one step, the level of hot water can be made appropriate. This makes it possible to prevent the excessive state from continuing.

According to a third aspect of the hot water supply apparatus, the hot water storage tank 3 is provided.
A temperature sensor 18a for reheating reference is provided on the top side of the
When the temperature detected by the temperature sensor 18a becomes lower than the reference temperature on the low temperature side, it is determined that the heat quantity of the supplied hot water is insufficient, and the heating source is operated to supply the hot water to the hot water storage tank 3. When the detected temperature becomes higher than the reference temperature on the high temperature side, the operation of the heating source is stopped and the reheating operation is ended, and the shortage of the supplied hot water amount of heat is operated by the reheating operation. The feature is that the amount of hot water is increased by grasping from the time.

In the hot water supply apparatus according to the third aspect, when the temperature detected by the temperature sensor 18a for the reheating standard becomes lower than the low temperature side reference temperature, it is determined that the supplied hot water amount is insufficient,
Since the reheating operation for supplying the heated hot water to the hot water storage tank 3 is performed by operating the heating source, the hot water replenishing operation can prevent running out of hot water. Further, when the detected temperature becomes higher than or equal to the high temperature side reference temperature, the reheating operation is terminated, so that there is no possibility of boiling extra hot water during reheating. Furthermore, the shortage of the supplied hot water amount can be grasped from this reheating operation time, and the next hot water amount level can be selected, and the selected hot water amount level becomes optimum.

In the hot water supply apparatus according to the present invention, a temperature sensor 18b for determining excessiveness is provided below the temperature sensor 18a for reference to reheating, and the hot water temperature detected by the temperature sensor for excess determination is equal to or higher than the reference temperature. It is characterized in that it is determined that there is a hot water excess state.

In the hot water supply apparatus according to the fourth aspect of the present invention, when the hot water temperature detected by the temperature sensor 18b for determining excess is below the reference temperature sensor 18a for reheating, the hot water is overheated. It is possible to make a determination, and it is possible to make a highly accurate determination of the hot-water condition.

The hot water supply apparatus according to claim 5 is characterized in that the standard determination days are one week, the medium-term determination days are at least two days, and the short-term determination days are one day.

In the hot water supply apparatus according to the fifth aspect, when the level is increased due to sudden use, the hot water level is operated only during the medium-term judgment days shorter than one week of the standard judgment days. , The overdose state does not continue for a long time. Further, since the number of medium-term determination days is at least 2 days, it is possible to determine whether or not the level is raised due to sudden use. Furthermore, since the number of short-term determination days is one day, such an overheated state can be completed in one day.

The hot water supply apparatus according to a sixth aspect of the present invention is characterized in that the hot water level optimization control is returned to the initial state when the hot water level returns to a level before the hot water level rises.

In the hot water supply apparatus according to the sixth aspect, the hot water level optimization control is continued after returning to the previous level, and it is possible to prevent further lowering by one step.
On the other hand, if the hot water amount level optimization control is continued after returning to the previous level and the hot water state becomes excessive, the hot water level is lowered by one level in a short number of days, and hot water runs out. There is a risk.

A hot water supply apparatus according to a seventh aspect includes a hot water storage tank 3 and
In a hot water supply device provided with a heating source, hot water amount levels of a plurality of classes are set in accordance with the required hot water heat amount per day, and the heat source supplies the hot water heat amount according to the selected hot water amount level to the hot water storage tank 3 When the temperature sensor 18a for reheating is provided in the hot water storage tank 3 and the detected temperature of the temperature sensor 18a becomes lower than the reference temperature on the low temperature side, the supplied hot water amount becomes insufficient. Judgment is made to operate the heating source to supply the heated hot water to the hot water storage tank 3, and at the same time increase the amount of hot water according to the amount of heat of supplied hot water thereafter. A temperature sensor 18b for determining excessiveness is provided at a position lower than the temperature sensor 18a, and when the hot water temperature detected by the temperature sensor 18b for excess determination is equal to or higher than a reference temperature, it is determined that there is an excessive amount of hot water. A hot water supply device configured to lower the bell, wherein at least three temperature sensors 18a, 18b, 18c are arranged in the hot water storage tank 3 at different height positions, and the upper sensor 18a is used as a reference for reheating. 1st determination state in which the intermediate sensor 18b is used as the temperature sensor for excessive determination, and the intermediate sensor 1b
It is characterized in that it is possible to select a second determination state in which 8b is used as a temperature sensor for reheating reference and the lower sensor 18c is used as a temperature sensor for excess determination.

In the hot water supply apparatus according to the seventh aspect, if it is determined in the first determination state that the supplied hot water heat quantity is insufficient and there is an excess of hot water, these determinations can be made above the hot water storage tank 3. Since the amount of remaining hot water can be reduced, the running cost required for heating hot water can be reduced. Further, in the second determination state, if it is determined that the amount of hot water supplied is insufficient and the state of excess hot water is present, these determinations can be made in the middle portion of the hot water storage tank 3 and stable drainage can be prevented. can do. Moreover, since the first / second determination state can be selected, the user can set the desired state, and the user can drive in the desired state.

[0023]

BEST MODE FOR CARRYING OUT THE INVENTION Next, specific embodiments of a water heater according to the present invention will be described in detail with reference to the drawings. FIG. 1 shows a simplified view of this hot water supply device (heat pump type hot water supply device in this case). This hot water supply device includes a tank unit 1 and a heat pump unit (heat source unit) 2, and heats water (hot water) from the tank unit 1 into a heat pump unit. It is heated at 2. This tank unit 1
Has a hot water storage tank 3, and the hot water stored in the hot water storage tank 3 is supplied to a bathtub or the like (not shown). That is, the hot water storage tank 3 is provided with a water supply port 5 on its bottom wall and a hot water outlet 6 on its upper wall. Then, city water is supplied from the water supply port 5 to the hot water storage tank 3, and high-temperature hot water is discharged from the discharge port 6. In addition, in the hot water storage tank 3,
The water intake 10 is opened in the bottom wall, and the hot water inlet 11 is opened in the upper part of the side wall (peripheral wall), and the water intake 10 and the hot water inlet 11 are connected by the circulation path 12. A water circulation pump 13 and a heat exchange passage 14 are provided in the circulation passage 12. A water supply channel 8 is connected to the water supply port 5.

By the way, the hot water storage tank 3 is provided with at least three remaining hot water amount detectors (temperature sensors) 18a, 18b, 18c and 18d at a predetermined pitch in the vertical direction. Each of the temperature sensors 18a ... Is, for example, a thermistor. The circulation path 12 is provided with a water intake thermistor 20 on the inlet side of the heat exchange path 14 and a hot water outlet thermistor 21 on the outlet side of the heat exchange path 14.

Next, the heat pump unit (heat source unit) 2 is provided with a refrigerant circuit, and this refrigerant circuit includes a compressor 25.
, A water heat exchanger 26 constituting the heat exchange passage 14, an electric expansion valve (pressure reducing mechanism) 27, and an air heat exchanger 28 are connected in this order. That is, the discharge pipe 29 of the compressor 25
Is connected to the water heat exchanger 26, the water heat exchanger 26 and the electric expansion valve 27 are connected by the refrigerant passage 30, and the electric expansion valve 27 and the air heat exchanger 28 are connected by the refrigerant passage 31. The air heat exchanger 28 and the compressor 25 are connected by a refrigerant passage 33 in which an accumulator 32 is provided. This allows
When the compressor 25 is driven, the water flowing through the heat exchange passage 14 is heated in the water heat exchanger 26. The refrigerant in the refrigerant circuit may be, for example, a supercritical refrigerant such as carbon dioxide as a natural refrigerant. Further, the air heat exchanger 28 is provided with a fan 34 for adjusting the capacity of the air heat exchanger 28.

By the way, the control unit of this hot water supply device is shown in FIG.
As shown in FIG.
Control means 38 to which the data (numerical value) from 7 is input. That is, as shown in FIG. 1, the remaining hot water amount detecting means 37 includes a remaining hot water amount detector 18 attached to the hot water storage tank 3.
a, 18b, 18c, 18d. Then, as shown in FIG. 2, the temperature of the residual hot water amount detector 18a (tank temperature T1), the temperature of the residual hot water amount detector 18b (tank temperature T2), the temperature of the residual hot water amount detector 18c (tank temperature T3), the residual hot water amount The temperature of the detector 18d (tank temperature T4), the temperature of the water intake thermistor 20 (inlet temperature T6), etc. are input to the control means (controller) 38, and the water circulation pump 13 and the compressor 25 are driven based on these data. Then, the operation as described later is performed. The control means 38 can be configured by using, for example, a microcomputer.

According to the hot water supply apparatus constructed as described above, the compressor 25 is driven and the water circulation pump 1 is used.
When 3 is driven (operated), stored water (hot water) flows out from the water intake 10 provided at the bottom of the hot water storage tank 3, and this flows through the heat exchange passage 14 of the circulation passage 12. At this time, the hot water is heated (boiling up) by the water heat exchanger 14 and returned from the hot water inlet 11 to the upper part of the hot water storage tank 3. By continuously performing such an operation, high temperature hot water can be stored in the hot water storage tank 3.

In this case, a certain time (for example, 2 after the start of the midnight time) in the midnight time (23 o'clock to 7 am the next day) band.
Operation is performed for a predetermined time from 4 o'clock, etc., and a total amount boiling operation is performed to boil hot water of a predetermined capacity (for example, the capacity of the hot water storage tank 3) at a predetermined time (midnight end time, that is, 7:00 am) Is. If the required amount of hot water for one day exceeds the capacity of the hot water storage tank 3, after the full boiling operation at midnight, the additional reheating operation (hereinafter referred to as additional operation) in the daytime outside the midnight time. To secure the required amount of hot water for the day. In other words, the operation of boiling the required amount of hot water for one day is called the required hot water amount ensuring operation.In this case, the required hot water amount ensuring operation includes only the case where only the total amount boiling operation is performed in the midnight time period and the midnight time period operation. There is a case where both the total boiling operation and the additional operation are performed.

The operation for securing the required amount of hot water ends when the temperature of the water intake thermistor 20 (inlet temperature) reaches a predetermined temperature (for example, 60 ° C.). In this case, in the above total boiling, the hot water amount levels of a plurality of classes are set according to the daily required hot water amount, and the heating source (heat pump heating source) sets the hot water amount corresponding to the selected hot water amount level. It is set to operate to supply to the hot water storage tank. Here, the hot water amount level has, for example, 1 to 10 levels as shown in Table 1 below. That is, in Table 1, level 1 is for boiling up 65 ° C. hot water by a predetermined amount (volume of hot water storage tank 3), and level 5 is a predetermined amount of hot water at 80 ° C. (volume of hot water storage tank 3).
Along with boiling up, additional operation for 1 hour during the day,
Furthermore, 50 liters of hot water at 80 ° C. is boiled. In this case, the higher the grade, the higher the amount of hot water. In addition, from level 1 to level 4, the required amount of hot water for one day can be secured without performing additional operation during the day.

[0030]

[Table 1]

When a certain amount of hot water is used, it is used a lot during the day, and when the amount of hot water at this amount of hot water causes a shortage of hot water, during this day, in order to make up for the deficiency. In addition to the above-described additional operation, a hot water outrunning operation (hereinafter referred to as an additional running operation) will be performed. The above-described reheating operation is performed as shown in the flowchart of FIG. In this case, first, in step S1, T1 (the temperature sensor 1 on the top side of the hot water storage tank 3
It is determined whether the temperature of 8a) is lower than the low temperature side reference temperature (for example, 45 ° C.). If it exceeds 45 ° C, there is no need to reheat, and the state is maintained as it is. T1 is 45 ° C
In the following cases, since it is necessary to perform the reheating operation, the process proceeds to step S2 and the reheating operation is started.

Then, the process proceeds to step S3, and it is determined whether T1 is higher than the high temperature side reference temperature (for example, 60 ° C.). If the temperature is 60 ° C. or higher, there is no need to reheat, so the reheating is ended. If it is less than 60 ° C,
Continue driving.

Then, after that, the shortage is grasped from the operating time of this reheating operation, and in the next time, the above-mentioned hot water amount level is increased, and the boiling water operation of the supplied hot water amount of this increased hot water amount level is performed. It will be. In this case, for example, if the reheating operation time is within 60 minutes, the level is increased by 1 and the reheating operation time exceeds 60 minutes and 120
If it is within a minute, the level can be increased by 2 levels, and if the reheating operation time exceeds 120 minutes and is within 180 minutes, the level can be increased by 3 levels, but of course, it is not limited to this.

Further, as described above, even when the hot water amount level for the next required hot water amount ensuring operation is increased or not, the hot water in the hot water storage tank 3 is left over. It is determined whether or not the state. That is, the operation is performed at a certain amount of hot water (boiling amount boiling operation), and then, when the operation is performed at this amount of hot water, it is determined whether there is an excessive amount of hot water. When it is continued for a number of days (for example, one week), the hot water level is decreased by one step.

Further, when the hot water replenishment operation causes the hot water amount level to rise by a plurality of levels in accordance with the time of the hot water replenishing operation, the hot water overload state is present for a number of medium-term judgment days (for example, 3 days) smaller than the reference judgment days. If continued, the hot water amount level is decreased by one stage after the lapse of the mid-term determination days without continuing the hot water excess state for the reference determination days. It should be noted that the above-mentioned determination days exclude hot water unused days. This hot water unused day determination can be made, for example, if the temperature T4 of the water supply determination temperature sensor 18d provided in the hot water storage tank 3 does not fall below a predetermined temperature (for example, 45 ° C.). That is, the city water is not supplied from the water supply port 5 to the hot water storage tank 3, so that
This is because it can be determined that the hot water in the hot water storage tank 3 is not used.

Further, in the above-mentioned hot water level optimization control, if the hot water level is decreased by one step, and if the hot water state continues for a short period of time (a day, for example) that is a little shorter than the number of medium-term determination days, then Control for further reducing the level of hot water by one step is included.

By the way, whether or not there is an excess of hot water is determined by, for example,
It is determined whether or not the temperature T2 detected by the temperature sensor 18b below the temperature sensor 18a, which is the reference for starting the reheating operation, is equal to or higher than a reference temperature (for example, 45 ° C.). This is because when the temperature of the hot water at the position of this temperature sensor 18b is 45 ° C or higher,
This is because it cannot be said that there is too much hot water. Therefore, this T2
Is less than 45 ° C., it is determined that there is no excess water.

Next, regarding the above-mentioned hot water amount level optimization control, FIG. 5 showing a case where the hot water amount level is increased by a plurality of levels.
A detailed description will be given with reference to the flowchart of FIG.
First, as shown in FIG. 5, the process of the hot water amount level optimization control is started, and it is determined in step S4 whether or not the entire amount has been boiled. In this case, as shown in FIG. 7, it is determined whether or not the total amount of boiling has been reached. That is, the total boiling amount of the hot water is changed based on the daytime reheating operation before starting the boiling (different from the additional operation in order to secure the required hot water amount for one day). . Further, in this case, it is assumed that the hot water level has increased by a plurality of levels. And, if the whole amount of is not boiled, wait until this is boiled. If the whole amount is boiled, the whole amount boiling operation is performed. Next, the process proceeds to step S5, and it is determined whether or not there is too much hot water at this hot water level operation. In this case, as shown in FIG. 7, monitoring and determination are performed until the time when the next total amount boiling starts. Then, as this determination, as described above, it is determined whether the detected temperature T2 of the temperature sensor 18b below the temperature sensor 18a which is the reference for starting the reheating operation is equal to or higher than the reference temperature (for example, 45 ° C.).

If T2 is less than 45.degree. C. in step S5, there is not an excessive amount of hot water, so the hot water level optimization control itself is terminated. Also, T2 is 45 ° C in step S5.
If it is above, there is an excessive amount of hot water, so the process proceeds to step S6. In this step S6, the number of days in which there is an excessive amount of hot water (remaining hot water days) is counted, and in step S7 it is determined whether the number of remaining hot water days exceeds the mid-term determination days (for example, 3 days). If the number of remaining hot water days does not exceed the number of medium-term determination days, the process returns to step S4. If the number of remaining hot water days exceeds the number of medium-term determination days, the process proceeds to step S8 and the hot water level is set to 1
Lower the level. That is, if the hot water level greatly increases and the hot water condition continues for 3 days, the operation at the hot water level reduced by 1 level is performed on the 4th day. This is because the reheating operation during the daytime, which is the cause of the increase in the amount of hot water, is sudden (there is a visitor, etc., and the hot water of the hot water storage tank 3 is supplied to the bathtub more than once more than normal days. Used) and by lowering the level of hot water,
This is an attempt to obtain an appropriate amount of hot water.

When the level of the amount of hot water is lowered in the above, after that, as shown in the flowchart of FIG. 6, it is determined in step S9 whether or not the next total amount is to be boiled. And
It is determined whether or not there is an excessive amount of hot water even at this hot water level.
That is, it is determined in step S10 whether T2 is 45 ° C. or higher. If T2 is less than 45 ° C., it means that there is no excess hot water, and this control is ended. If it is 45 ° C. or higher in step S10, it is decreased by one level as shown in step S11.

Next, the process proceeds to step S12, where a plurality of U
It is determined whether or not the level has returned to the level before P, and if it has returned, this processing ends. If not returned, the process returns to step S9 and waits until the next full boiling. In addition,
Completing this process means returning to the process start state, that is, the initial state of this hot water level optimization control.

The above control method is shown in the graph of FIG. For example, when the operation is performed at level 4 and the hot water amount according to the selected hot water amount level is supplied to the hot water storage tank 3, the reheating operation (the heat amount required for one day The operation to replenish the shortage for excess use is performed), the level is increased to level 7 in the next boiling operation, and the amount of hot water is excessive at this level of operation, and this excessive amount of hot water continues for 3 days. Sometimes, the level is lowered by 1 to level 6. Then, at this level, if the excess hot water condition is resolved, this level 6 is continued. That is, A in FIG. 8 (level 4 → level 7 → level 6 →) is obtained. In addition, if the overheated condition is not resolved even if the level is lowered to level 6, further decrease it by one level,
Level 5 Then, at this level, if the excessive hot water state is resolved, this level 5 is continued. That is, B of FIG. 7 (level 4 → level 7 → level 6 → level 5
→) Further, if the excess hot water state is not resolved even if the level is reduced to level 5, the level is further reduced to level 1 to level 4. That is, C (level 4 → level 7 → level 6 → level 5 → level 4 →) in FIG. 8 is obtained. Then, when the level becomes 4, the level has returned to the level before the rise, so this processing is ended.

By the way, when the hot water level has not risen by a plurality of levels, for example, when the operation is performed at level 4 and it is still level 4 at the next operation, or when it is increased by one level at the next operation. Even when the level is 5 and so on, it is determined whether or not there is an excessive amount of hot water. In this case, even if the hot water excess state continues for the number of medium-term determination days (for example, 3 days), it is 1 until the reference determination days (for example, 1 week) are exceeded.
Do not lower the level. That is, when the hot water level has not risen by a plurality of levels, if the hot water condition continues for one week, the hot water level is lowered by one level. As a result, it is possible to prevent the level from being lowered by one level with a short number of determination days, and to prevent the occurrence of hot water shortage.

As described above, in this hot water supply device, when the amount of heat supplied to the hot water becomes insufficient, the amount of hot water to be supplied next time is increased correspondingly to the level of the amount of hot water to prevent (prevent) running out of hot water. . Further, when the state of excessive heat of supplied hot water continues for the reference determination days, the level of hot water is decreased by one step, so that it is possible to prevent the excessive hot water state for a long period of time. Furthermore, when the hot water level has increased by multiple levels, if the hot water overload condition continues for a number of medium-term determination days that are less than the above-mentioned reference determination days, it is determined that this level increase is so-called sudden, and the hot water level is increased. It is possible to prevent this excess of hot water by lowering it by one step. That is, it is possible to prevent run-out of hot water, avoid long-term continuation of an excessive hot water state, and prevent useless operation.

On the other hand, when the hot water level increases by a plurality of levels, as shown in the flow chart of FIG. 9, if the hot water overload condition continues for three days, the hot water will be returned to its original level. There was a risk of running out of hot water. For example, the level of hot water before level up is level 4
If a large amount of hot water is used and the next hot water level rises to level 7 and the excess hot water continues for the predetermined number of days (for example, 3 days), the original level 4 is restored. Become. However, if the appropriate hot water level is level 5 or 6, a hot water shortage phenomenon occurs in which hot water is insufficient.

By the way, in the above embodiment, the hot water storage tank 3 is provided with three temperature sensors 18a, 18b and 18c, and the upper temperature sensor 18a is reheated for determining that the amount of hot water supplied from the heating source is insufficient. Along with the reference temperature sensor, the intermediate temperature sensor 18b is a temperature sensor for determining excess in determining that there is an excess of hot water, but the intermediate temperature sensor 18b is a temperature sensor for reheating reference and The lower temperature sensor 18c may be used as the excess determination temperature sensor. In addition, the upper temperature sensor 1
A first temperature sensor 8a is used as a reference heating temperature sensor, and an intermediate temperature sensor 18b is used as an excessive determination temperature sensor.
The first determination state and the second determination state are defined as the second determination state in which the determination state and the intermediate temperature sensor 18b is used as the shortage determination temperature sensor and the lower temperature sensor 18c is used as the excess determination temperature sensor. It may be possible to select.

As in the embodiment, the upper temperature sensor 1
8a and the intermediate temperature sensor 18b are used,
Since the end of the reheating is determined by the upper rank of the hot water storage tank, the amount of remaining hot water can be reduced, and thus the running cost required for heating the hot water can be reduced. Further, when the intermediate temperature sensor 18b and the lower temperature sensor 18c are used, the hot water runout determination and the midway portion of the hot water storage tank are performed, and the reliability of hot water runout prevention improves. Therefore, if the selection of the first and second determination states is possible, the user can set the desired state, and the driving in the state desired by the user becomes possible.

Although the specific embodiments of the present invention have been described above, the present invention is not limited to the above-mentioned embodiments, and various modifications can be carried out within the scope of the present invention. For example, the standard judgment days are not limited to one week, but within a range shorter than the mid-term judgment days,
It may be more than one week or less than one week. Further, the number of medium-term determination days is not limited to three days, but may be at least two days and may be within a range shorter than the standard determination days. Furthermore, the number of short-term days may be any number that is shorter than the number of medium-term determination days. Further, the amount of hot water is not limited to that shown in Table 1 above, and various levels can be set.
It is not limited to stages. Further, the temperature of T1 (or T2), which is the reference for starting the reheating operation, the temperature of T1 (or T2), which is the reference for stopping the reheating operation, and T2 (or T3), which is the reference for determining the excessive hot water state. The temperature of) can of course be changed according to the preference of the user or the season. When the heat pump type hot water supply device is used as the hot water supply device as in the above embodiment, it is preferable to use carbon dioxide gas as the refrigerant of the refrigerant circuit, but in addition, dichlorodifluoromethane (R-12) or chlorodifluoromethane is used. Even with a refrigerant such as (R-22), due to problems such as ozone layer destruction and environmental pollution, 1,1,
It may be an alternative refrigerant such as 1,2-tetrafluoroethane (R-134a). As a water heater,
It may be an electric water heater or a gas water heater as long as it has a hot water storage tank for storing hot water heated by a heating source.

[0049]

According to the hot water supply apparatus of the present invention, when the amount of heat supplied to the hot water becomes insufficient, the amount of hot water to be supplied next time is increased correspondingly to the level of the amount of hot water to avoid (prevent) running out of hot water. You can As a result, the user can use the hot water in the hot water storage tank with peace of mind, and can spend comfortably. Further, when the state of excessive heat of supplied hot water continues for the reference determination days, the level of hot water is decreased by one step, so that it is possible to prevent the excessive hot water state for a long period of time. Furthermore, when the hot water level has increased by multiple levels, it can be determined that this level increase is so-called sudden if the hot water overload condition continues for a number of medium-term determination days that are less than the standard determination days. This level can be reduced by one step to prevent this excess hot water. As a result, it is possible to prevent the excessive hot water condition for a long period of time and reduce the running cost.

According to the hot water supply apparatus of the second aspect, the hot water amount level can be brought to an appropriate level at an early stage. As a result, it is possible to prevent the excessive state from being continued, and it is possible to reliably reduce the running cost.

According to the hot water supply apparatus of the third aspect, hot water can be prevented from running out by additional heating, and there is no fear of boiling extra hot water during additional heating. Furthermore, the shortage of the supplied hot water amount can be grasped from this reheating operation time, and the next hot water amount level can be selected, and the selected hot water amount level becomes optimum. In this way, the amount of hot water to be boiled can be set to an appropriate amount, and the hot water supply device can be operated without waste.

According to the hot water supply apparatus of the fourth aspect, it is possible to highly accurately determine the hot water excess state, and it is possible to reliably prevent the hot water excess state.

According to the hot water supply apparatus of the fifth aspect, it is possible to prevent the excessive hot water state from being continued for a long period of time, and prevent running costs from increasing. Further, since the number of medium-term determination days is at least 2 days, it is possible to determine whether or not the level is increased due to sudden use, the reliability of the set amount of hot water is improved, and the hot water becomes overloaded. The number of days can be surely reduced. Furthermore, since the number of short-term determination days is one day, it is possible to converge the excess hot water state in a short period of time, and it is possible to end wasteful operation in a short period of time.

According to the hot water supply apparatus of the sixth aspect, the hot water amount level optimization control is continued after returning to the previous level, and it is possible to prevent further lowering by one step.
As a result, the hot water is prevented from being turned off, and the user can use the hot water in the hot water storage tank without anxiety.

According to the hot water supply apparatus of the seventh aspect, it is possible to reduce the running cost in the first determination state, and it is possible to stably prevent running out of the hot water in the second determination state. Moreover, since the first and second determination states can be selected, the user can set the desired state, and the user can operate in the state desired by the user, and the device becomes a convenient water heater.

[Brief description of drawings]

FIG. 1 is a simplified diagram showing an embodiment of a hot water supply device of the present invention.

FIG. 2 is a simplified block diagram showing data input to a control unit of the hot water supply device.

FIG. 3 is a simplified block diagram of a control unit of the hot water supply device.

FIG. 4 is a flowchart showing a reheating operation of the hot water supply device.

FIG. 5 is a flowchart showing a hot water level optimization control of the hot water supply device.

FIG. 6 is a flowchart showing a hot water amount level optimization control of the hot water supply device.

FIG. 7 is a time chart diagram showing a time zone in which the entire amount is boiled.

FIG. 8 is a graph showing a hot water amount level during the hot water amount level optimization control of the hot water supply device.

FIG. 9 is an operation flowchart diagram when the hot water level optimization control is not used.

FIG. 10 is a simplified diagram of a conventional hot water supply device.

[Explanation of symbols]

3 hot water storage tank 18a Temperature sensor 18b Temperature sensor 18c Temperature sensor

Claims (7)

[Claims] 1. A hot water supply apparatus comprising a hot water storage tank (3) and a heating source, wherein hot water amount levels of a plurality of classes are set according to the required hot water heat amount per day, and the heating source is selected. When the hot water amount corresponding to the hot water amount level is supplied to the hot water storage tank (3), and when the hot water amount supplied is insufficient, the hot water amount to be supplied next time is increased correspondingly to the hot water amount level, Further, the hot water supply device is configured to reduce the hot water amount level by one step when the excessive amount of hot water heat supply continues for the reference determination days, and when the hot water amount level rises by a plurality of levels,
A hot water supply apparatus which performs hot water level optimization control for reducing the hot water level by one stage if the hot water overload condition continues for a medium number of days less than the standard decision days. 2. The hot water level optimization control further reduces the hot water level if the hot water level continues for a short number of short-term determination days slightly shorter than the medium-term determination days after lowering the hot water level by one step. The hot water supply apparatus according to claim 1, further comprising a control for reducing the temperature by one step. 3. A hot-melting reference temperature sensor (18a) is provided on the top side of the hot water storage tank (3), and when the temperature detected by the temperature sensor (18a) becomes lower than the low temperature side reference temperature, When it is determined that the amount of heat supplied from the hot water is insufficient, the heating source is operated to perform the reheating operation for supplying the hot water to the hot water storage tank (3), and when the detected temperature becomes equal to or higher than the high temperature side reference temperature, It is configured such that the operation of the heating source is stopped to end the reheating operation, and the shortage of the supplied hot water heat amount is grasped from the reheating operation time to raise the hot water level. 1 or claim 2
Water heater. 4. A temperature sensor (18) for the reheating reference.
A temperature sensor (18) for determining excess is located below the position a).
b) is provided, and when the hot water temperature detected by the temperature sensor (18b) for overload determination is equal to or higher than the reference temperature, it is determined that the hot water excess state is present. Water heater. 5. The method according to claim 1, wherein the standard determination days is one week, the medium-term determination days is at least two days, and the short-term determination days is one day. Water heater. 6. The hot water supply apparatus according to claim 1, wherein the hot water amount level optimization control is returned to an initial state when the hot water amount level returns to a level before rising. 7. A hot water supply device comprising a hot water storage tank (3) and a heating source, wherein hot water amount levels of a plurality of classes are set in accordance with the required hot water heat amount per day, and the heating source is selected. It operates so as to supply the amount of hot water according to the level of the amount of hot water to the hot water storage tank (3), the hot water storage tank (3) is provided with a temperature sensor (18a) for reheating, and the temperature sensor (18a) detects the temperature. When the temperature becomes equal to or lower than the low temperature side reference temperature, it is determined that the supplied hot water heat amount is insufficient, the heating source is operated to perform the reheating operation for supplying the heated hot water to the hot water storage tank (32), The hot water amount level is raised according to the amount of hot water supplied thereafter, and a temperature sensor (18b) for determining excessiveness is provided at a position lower than the temperature sensor (18a) for reference of reheating, and the temperature sensor (18b) for excessiveness determination is provided. Of the temperature sensor (18b) A hot water supply device configured to determine that there is an excessive amount of hot water when the hot water discharge temperature is equal to or higher than the reference temperature, and lower the hot water level, wherein at least three temperature sensors (18a) are provided in the hot water storage tank (3). , 18
b, 18c) are arranged at different height positions, and the upper sensor (18a) is used as a reference heating temperature sensor, and the intermediate sensor (18b) is used as an excessive determination temperature sensor. It is possible to select between the determination state and the second determination state in which the intermediate sensor (18b) is used as a temperature sensor for reheating reference and the lower sensor (18c) is used as a temperature sensor for excess determination. A characteristic hot water supply device.