JP2004263905A - Heat source control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heat source control device having the high energy efficiency of the whole heat system, and further saving energy by accurately predicting a quantity of heat to be used. <P>SOLUTION: This heat source control device has a heat quantity arithmetic operation means 10 for arithmetically operating a consumption heat quantity Q at a specific interval, a past data arithmetic operation means 11 for calculating past data W by applying a prescribed arithmetic operation on the basis of the consumption heat quantity Q, a past data storage means 12, and a heat quantity predicting means 13 for predicting a required heat quantity on the basis of the past data W, and controls a heat source along a prediction provided by the heat quantity predicting means 13, and also has an arithmetic operation correcting means 11a and a prediction correcting means 13a. The arithmetic operation correcting means 11a and the prediction correcting means 13a correct the arithmetic operation or the prediction on the basis of the comparing result of the consumption heat quantity Q arithmetically operated in the past and the past data previous by a reference period of the consumption heat quantity Q. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a heat source control device.
[0002]
[Prior art]
BACKGROUND ART Conventionally, heat from equipment having a heat source has been used effectively for hot water supply, heating, and the like. In large-scale business establishments, waste heat generated during power generation is effectively used as a heat source.
2. Description of the Related Art In recent years, generators that can use waste heat for homes and small businesses have been developed. Then, energy can be saved by effectively using waste heat generated during power generation as a heat source.
[0003]
The above waste heat is generated with power generation. Therefore, electricity and waste heat are generated at the same time, and if a large amount of electric power is generated, the waste heat increases. However, the required amount of power and the required thermal energy are not necessarily related.
Usually, the fluctuation of the heat energy is larger than the fluctuation of the electric energy. This is because a large amount of energy such as hot water supply or heating may be used temporarily.
[0004]
For this reason, a hot water storage tank is provided, and a heat storage unit for temporarily storing heat energy by hot water is provided to use the heat energy when the use of the heat energy increases rapidly. In addition, a heat source such as a combustion device is provided separately from the generator to prepare for when the use of heat energy further increases.
[0005]
Prior art document information related to the invention of this application includes the following.
[Patent Document]
Japanese Patent No. 2580504
[0006]
Patent Literature 1 discloses a “use result data measurement unit that measures the amount of use of energy and a use time, a determination of an energy use act that is a use of energy based on data measured by the use result data measurement unit, While waking up, absent or sleeping, an activity estimating unit that determines which of the living states the user is in, an activity list storage unit that stores results determined by the activity estimating unit, and an activity estimating unit that determines From the results of the energy use act and the usage record data measurement unit, the use start time, use duration, and average and variance of the amount of use are determined for each energy use act, and the regularity of the energy use act is determined based on the past energy use. A feature extraction unit that extracts the rules prepared in advance and the degree of belonging to the rules from the occurrence of the act, There is an action presence / absence prediction unit that determines whether there is no activity based on a predetermined rule based on the past action estimation results and the rules for the occurrence of energy use actions extracted by the feature extraction unit. If it is determined that the start time, an action start time prediction unit that determines the start time, and the energy use amount for each energy use act extracted by the action start time prediction unit and the characteristic extraction unit, Which is an energy load prediction device having a load prediction unit that determines the energy use of a vehicle. Patent Literature 1 discloses an invention that “can make predictions that can cope with various resident's life patterns and can use an effective heat generation system for energy supply equipment of an apartment house”.
[0007]
[Problems to be solved by the invention]
However, in the case of generators that use exhaust heat for homes and small business establishments, the amount of heat energy used varies greatly, especially when hot water is used, such as when using a bath. In a short time.
Further, the energy of waste heat generated by power generation is relatively small, and large heat energy cannot be supplied at one time. Then, when a large amount of heat energy that is larger than the heat energy stored in the heat storage unit is required, the heat energy must be supplied by a heat source such as a combustion device provided separately from the generator. In such a case, energy efficiency is reduced by the use of the heat source.
[0008]
On the other hand, if a large amount of heat energy is always stored in the heat storage unit, the necessary heat energy can be supplied from the heat storage unit even if a large amount of heat energy is required. However, if the state in which the heat energy is not used continues, the heated water stored in the heat storage unit radiates heat, which does not result in energy saving.
[0009]
In order to solve this problem, if it is possible to predict the required amount of heat energy from the past usage conditions and to achieve an optimal operation state, it is desirable to save energy.
[0010]
However, in reality, the above prediction was difficult.
For example, in the invention described in Patent Literature 1 as a conventional technique, “a regularity and a variance of a use start time, a use duration, and a use amount are obtained for each energy use act, and the regularity of occurrence of the energy use act is determined. However, when an unusual situation occurs due to the absence of a certain period or the like, accurate prediction was not possible, and energy saving was not achieved.
That is, since the average and the variance are obtained in a state including an unusual situation, a difference occurs between the predicted required energy and the actual required energy. Then, the vehicle is driven based on predictions that differ from the actual required energy.
[0011]
Therefore, an object of the present invention is to provide a heat source control device that accurately predicts the use of heat energy, has high energy efficiency in the entire heat system, and can save energy.
[0012]
[Means for Solving the Problems]
According to the first aspect of the present invention, there is provided a heat amount calculating means for calculating a heat consumption amount at regular intervals, and a heat amount calculating means for performing a predetermined calculation based on the heat consumption amount to calculate past data. Data calculation means, past data storage means for storing the past data, and heat quantity prediction means for predicting a necessary heat quantity based on past data corresponding to a reference period that is a predetermined period before, the heat quantity prediction A heat source control device capable of controlling the heat source in accordance with the prediction obtained by the means, wherein the heat quantity prediction means can correct the prediction by prediction correction means, and the prediction correction means The heat source control device is characterized in that the prediction is corrected based on a comparison result of the calculated heat consumption and past data obtained by a reference cycle before the heat consumption.
[0013]
According to the first aspect of the present invention, the heat consumption is calculated at regular intervals, the past data is calculated and stored, and the required heat is predicted based on the past data preceding by the reference period to control the heat source. In addition, since the prediction is corrected based on the comparison result between the calorie consumption calculated in the past and the past data only before the reference cycle of the calorie consumption, not only the data before the reference cycle but also the previous trend is corrected. Based on the above, it is possible to make a prediction, and it is possible to make a more accurate prediction of the required heat quantity.
[0014]
The invention according to claim 2, wherein the reference cycle is one week, and the prediction correction means compares the calorie consumption calculated on the previous day with the past data of the calorie consumption just before the reference cycle. , And a comparison between the heat consumption calculated before two days before the heat consumption to be calculated and the past two days comparison result, which is a comparison between the heat consumption calculated in the past two days earlier and the past data. 2. The heat source control device according to claim 1, wherein the heat source control device corrects the heat source.
[0015]
According to the second aspect of the present invention, since the prediction is performed using the comparison result of the previous day and the comparison result of two days before, not only the past data before the reference cycle but also the tendency of the previous day and the day before the second day are considered. Can predict. In addition, since the reference cycle is one week, the prediction is performed based on the past data corresponding to one week before, so that the required amount of heat can be accurately predicted.
Note that the comparison result used for the prediction is not limited to only the previous day and the day before the previous day, and it is also possible to use the comparison results of three days before, four days ago, and a plurality of days before that. Furthermore, when using the comparison results of a plurality of days, the comparison results of consecutive days may be used, or the comparison results of discontinuous days may be used.
[0016]
According to a third aspect of the present invention, the prediction correction means does not correct the prediction if the comparison result of the previous day and the comparison result of the previous day are satisfied and a predetermined condition is satisfied. The heat source control device according to claim 2, wherein:
[0017]
According to the third aspect of the present invention, the prediction correction unit does not correct the prediction when the comparison result between the previous day and the comparison result two days before is satisfied by satisfying a predetermined condition. In addition, even when an unusual usage situation occurs or an abnormal value is output for some reason, the required heat quantity can be accurately predicted.
[0018]
According to a fourth aspect of the present invention, there is provided a calorific value calculating means for calculating the amount of heat consumed at regular intervals, a past data calculating means for performing a predetermined calculation based on the consumed heat amount to calculate past data, and storing the past data. Past data storage means, and a heat quantity predicting means for predicting a required heat quantity based on past data corresponding to a reference period which is a predetermined period earlier, and a heat source is provided in accordance with the prediction obtained by the heat quantity predicting means. A heat source control device capable of performing the control described above, wherein the past data calculation means can correct at the time of calculation by a calculation correction means, and the calculation correction means determines the amount of heat consumption calculated in the past, The heat source control device is characterized in that correction is performed at the time of calculation based on a comparison result of past heat data with reference to previous data by a reference cycle.
[0019]
According to the fourth aspect of the present invention, the calculation correction unit corrects the calculation based on a comparison result between the heat consumption calculated in the past and past data that is a reference cycle of the heat consumption previously. Therefore, not only the data before the reference cycle but also the calculation based on the tendency immediately before can be performed, and the past data becomes closer to the actual required heat amount, thereby enabling more accurate prediction of the required heat amount. .
[0020]
6. The invention according to claim 5, wherein the reference cycle is one week, and the calculation correction means calculates the heat consumption calculated on the day before the heat consumption to be calculated and the past data before the reference cycle of the heat consumption. The comparison result of the previous day, which is a comparison with the previous day, and the comparison result of the previous two days, which is a comparison of the heat consumption calculated on the day before the heat consumption of the calculation target and the past data only by the reference cycle of the heat consumption concerned. 5. The heat source control device according to claim 4, wherein the correction is performed at the time of calculation based on the following.
[0021]
According to the fifth aspect of the present invention, since the calculation is performed using the comparison result of the previous day and the comparison result of the day before two days, not only the past data before the reference cycle but also the tendency of the day before and the day before two days is considered. Past data can be calculated. In addition, since the reference cycle is one week, the prediction is performed based on the past data corresponding to one week before, so that the required amount of heat can be accurately predicted.
Note that the comparison result used for the calculation is not limited to only the previous day and the day before the previous day, and it is also possible to use the comparison results of three days ago, four days ago, and a plurality of days earlier. Furthermore, when using the comparison results of a plurality of days, the comparison results of consecutive days may be used, or the comparison results of discontinuous days may be used.
[0022]
According to a sixth aspect of the present invention, the past data storage means updates the past data calculated by the past data calculation means by replacing the past data by a reference cycle before, and updates the previous day comparison result and the previous data. The heat source control device according to claim 5, wherein the past data is not updated by the past data storage unit when a predetermined condition is satisfied by comparing the result with the comparison result every day.
[0023]
According to the invention described in claim 6, since the comparison result between the previous day and the comparison result before two days is satisfied, if the predetermined condition is satisfied, the past data is not updated by the past data storage means. If the usage data is different from normal, or if an abnormal value occurs for some reason and the past data that is far from the actual situation is calculated, it is possible to prevent the past data from being updated. , Can only be updated.
[0024]
The invention according to claim 7, further comprising an absence detection unit, wherein the absence detection unit detects the absence when the comparison result of the previous day and the comparison result of two days before satisfies a certain standard continuously. The determination is made, and when the absence is determined, the updating of the past data by the past data storage unit is stopped, and further, when a predetermined condition is satisfied, the home determination is made, and the updating of the past data by the past data storage unit is restarted. The heat source control device according to claim 6, wherein
[0025]
According to the seventh aspect of the invention, when the comparison result of the previous day and the comparison result of two days ago satisfies a certain standard continuously, the absence is detected and the absence is determined. Since the update of the past data is stopped, the absence of the past data causes the heat consumption to drop extremely, thereby preventing the past data from moving away from the normal value of the heat consumption.
Further, when the absence is determined, it is preferable to use the past data before update as the past data of the previous day and the two days before. In this case, a method of changing the past data Wa of the previous day and two days before the previous day to the past data Wb of one week ago, or suspending the update, and confirming that the absence determination is not made after the next day, and confirming the past. This is performed by a method of updating the data Wa.
[0026]
The invention according to claim 8 uses the preset initial value when the period of the reference cycle has not elapsed since the start of use or when the past data before the reference cycle is not stored. 8. A method for calculating past data, wherein when calculating past data using an initial value, the past data is calculated by reflecting heat consumption more than in a normal calculation. A heat source control device according to any one of the above.
[0027]
According to the invention as set forth in claim 8, when the past data is calculated using the initial value, the past data is calculated by reflecting the heat consumption more than in the normal calculation. Fast and accurate predictions are possible.
[0028]
According to a ninth aspect of the present invention, the heat consumption is compared with the past data preceding the heat consumption by a reference cycle, and if there is a difference equal to or more than a certain value, the past data is calculated using the initial value. The heat source control device according to claim 8, wherein the past data is calculated by a method similar to the method.
[0029]
According to the ninth aspect of the present invention, when the difference between the heat consumption and the past data obtained by a reference cycle of the heat consumption is larger than a predetermined value, the heat consumption is calculated more than the normal calculation. Since the past data is calculated by largely reflecting the past data, a more accurate prediction can be made faster.
[0030]
The invention according to claim 10 is used in a thermal system including a bath, and has a bath residual energy detecting unit for detecting an amount of heat energy remaining in the bath, and the past data calculating unit performs the calculation by the calculation correcting unit. The heat source control device according to any one of claims 1 to 7, wherein the arithmetic correction means calculates and corrects according to the amount of heat energy remaining in the bath. is there.
[0031]
According to the invention as set forth in claim 10, since the calculation and correction means corrects and calculates in accordance with the amount of heat energy remaining in the bath, when the bath is operated using the remaining hot water in the bath, the remaining amount of the bath remains. The past data can be calculated in consideration of the amount of heat of the hot water. Therefore, the amount of heat consumed in the bath operation can be the same whether or not the remaining hot water in the bath is used. Then, when the required heat quantity is predicted using the past data, the accuracy is accurate.
[0032]
The invention according to claim 11 is used in a thermal system including a bath, and has a bath residual energy detecting unit for detecting a heat energy remaining in the bath, and the heat amount predicting unit corrects the prediction by the prediction correcting unit. The heat source control device according to any one of claims 1 to 10, wherein the prediction correction unit corrects the prediction in accordance with the amount of heat energy remaining in the bath. .
[0033]
According to the eleventh aspect of the present invention, the amount of heat energy remaining in the bath is detected and corrected by the prediction correction means at the time of prediction according to the amount of heat energy remaining in the bath. It is also possible to accurately predict the required amount of heat even when a bath operation is performed by using.
[0034]
The invention according to claim 12 is used in a thermal system including a bath, and has a bath reservation function for reserving bath use, wherein the calorie prediction means can correct prediction by prediction correction means, The heat source control device according to any one of claims 1 to 11, wherein the correction means corrects such that predetermined heat is obtained at a time reserved by the bath reservation function.
[0035]
According to the twelfth aspect of the present invention, the prediction correction unit corrects the predetermined time so as to obtain predetermined heat at the time reserved by the bath reservation function, so that the time of bath operation can be accurately determined. It is possible to accurately predict the required heat quantity.
[0036]
The invention according to claim 13 has bath use calorie estimating means, and the bath use calorie estimating means is a time when the heat consumption is the highest in a day or a time when the bath is predicted to be operated. The heat consumption around is estimated as the amount of heat used in the bath, and the prediction correction unit corrects the predicted value of the required amount of heat around the time when the amount of heat used in the bath is generated based on the amount of heat used in the bath. The heat source control device according to claim 11, wherein
[0037]
The invention according to claim 13 is a bath use heat amount estimating means for estimating, as a bath use heat amount, a heat consumption amount around a time when the heat consumption is the largest in a day or around a time when the bath is predicted to be operated. The prediction correction means corrects so that predetermined heat is obtained at the time reserved by the bath reservation function, and further calculates the predicted value of the required heat amount near the time when the bath use heat amount is generated. The correction is performed based on the amount of heat used in the bath. Therefore, when the bath operation is reserved and the time of the bath operation is accurately known, the correction is performed so that the predetermined heat is obtained at the reserved time, and further, the correction is also performed based on the estimated bath use heat amount. The required heat quantity can be predicted very accurately.
[0038]
The invention according to claim 14 is used in a thermal system including a bath, and has a calorie prediction unit for predicting the required calorie of the day from past use results, and operates the heat source according to the prediction of the calorie prediction unit. A heat source control device that has a bath reservation function for reserving bath use, and when there is a prediction of a required heat amount corresponding to the amount of bath use near the reserved time, a predetermined heat is reserved at the reserved time. A heat source control device characterized in that the heat source is operated so as to obtain the required heat amount, and the heat source is operated by predicting a required heat amount obtained by subtracting a required heat amount corresponding to a bath usage amount from around a reserved time.
[0039]
According to the fourteenth aspect of the present invention, when the required heat amount corresponding to the bath usage is predicted near the reserved time, the heat source is operated so that predetermined heat is obtained at the reserved time. At the same time, since the heat source is operated by predicting the required heat amount that is obtained by subtracting the required heat amount corresponding to the bath usage from the vicinity of the reserved time, the required heat amount corresponding to the bath usage is added at the reserved time, By reducing the required amount of heat corresponding to the amount of use of the bath, the amount of heat can be accurately predicted.
[0040]
The invention according to claim 15 is used for a heat system including a bath, and has a calorie prediction unit for predicting the required calorie of the day from past use results, and operates the heat source according to the prediction of the calorie prediction unit. It has a bath reservation function to reserve the use of the bath, and there is no prediction of the required amount of heat corresponding to the amount of bath use near the reserved time, and the amount of use of the bath at other times is reduced. When there is a prediction of the required heat amount, the heat source is operated so that predetermined heat is obtained at the reserved time, and the required heat amount is calculated by subtracting the required heat amount corresponding to the bath usage from the predicted time. A heat source control device characterized by operating a heat source.
[0041]
According to the invention described in claim 15, when there is a required heat amount prediction corresponding to the amount of use of the bath at another time, the heat source is operated so that predetermined heat is obtained at the reserved time, and the predicted heat amount is calculated. Since the heat source is operated according to the required heat amount that is obtained by subtracting the required heat amount corresponding to the bath usage from the time when the bath is used, the required heat amount corresponding to the bath usage is added to the reserved time to correspond to the bath usage. By reducing the required amount of heat, the amount of heat can be accurately predicted.
[0042]
An invention according to claim 16 is a heat source control device that controls a heat system capable of extracting heat and electric power and a heat system including a heat storage unit, and determines a required heat amount for each time of the day based on past use results. It has a heat quantity prediction means for predicting, and a required power prediction means for predicting the required power for each time of the day based on the past usage results. The heat source control device is characterized in that the operation pattern of the heat source is calculated.
[0043]
According to the sixteenth aspect of the present invention, it is possible to calculate the most appropriate operation pattern of the heat source from the required amount of heat storage, the amount of heat radiation, the time of use of heat, and the time of use of electric power, by including the necessary power prediction means. Energy can be saved more.
[0044]
The invention according to claim 17 is a heat source control device that controls a heat system capable of extracting heat and electric power and a heat system including a heat storage unit, and determines a required heat amount for each time on the day based on past use results. It has a heat quantity prediction means for predicting and a required power prediction means for predicting the required power for each time of the day based on the past usage results, and uses the current power usage status, current heat usage status, current heat storage status for current Comparing the energy consumption within a predetermined period when the heat source is operated with the energy consumption during the predetermined period when the heat source is operated in the future based on the heat amount prediction means and the required power prediction means, and satisfying a predetermined condition. The heat source control device is characterized in that the heat source is operated when the heat source is operated.
[0045]
According to the invention described in claim 17, from the current power usage status, the current heat usage status, and the current heat storage status, the energy consumption within a predetermined period when the heat source is currently operated, and the heat amount prediction means And energy consumption within a predetermined period when the heat source is operated in the future based on the required power prediction means, and when the predetermined condition is satisfied, the heat source is operated. It becomes possible and energy saving can be achieved.
[0046]
The invention according to claim 18 is provided with a heat source having a calorific value less than the amount of heat consumed at the peak time, and a heat storage means, and operating the heat source so that a predetermined amount of heat is stored in the heat storage means at a predetermined time. The heat source control device according to any one of claims 1 to 17, wherein
[0047]
According to the invention described in claim 18, since the heat source can be operated so as to store a predetermined amount of heat in the heat storage means at a predetermined time, the heat source can be operated at a predetermined time. The present invention is applicable to a thermal system having a heat source having a relatively small heat value.
[0048]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, specific examples of the present invention will be described. FIG. 1 is a block diagram showing a thermal system according to the first embodiment of the present invention. FIG. 2 is a block diagram showing a thermal system according to the first embodiment of the present invention. FIG. 3 is a flowchart showing a method of calculating past data and a method of performing absence determination. FIG. 4 is a flowchart illustrating a method of performing the absence determination. FIG. 5 is a diagram showing a flowchart illustrating a method of calculating the required heat amount prediction value Ty. 6 to 8 are block diagrams showing a thermal system according to the second to fourth embodiments of the present invention. FIG. 9 is a graph showing past data W at each time of day in chronological order. FIG. 10 is a graph showing past data and heat consumption for each week in chronological order from the start of using the thermal system. FIG. 11 is a graph showing a comparison result H every day. 12 to 14 are graphs showing the required heat quantity predicted value Ty and the corrected required heat quantity predicted value Ty 'at each time of day in a time series.
[0049]
The heat source control device 1 according to the first embodiment of the present invention is shown in FIG. 1, and includes a calorie computing unit 10, a past data computing unit 11, a computation correcting unit 11a, a past data storage unit 12, a calorific value It has a prediction unit 13, a prediction correction unit 13a, and a past data comparison unit 14.
The heat source control device 1 is a control device provided in the heat system 8, and the heat system 8 is provided with a heat source 16, a storage unit 17, and a heat energy use device 18.
[0050]
The calorie computing means 10 measures the physical quantity related at regular intervals to compute the calorie consumption. Specifically, as will be described later, using the water temperature T1 introduced into the heat system 8 and the temperature T2 of the hot water used in the thermal energy using device 18 and the amount V thereof, these results are calculated and calculated. Have been. In the present embodiment, the interval of the calculation is every hour, and therefore, the measurement is performed 24 times a day.
[0051]
The past data calculation means 11 calculates the past data W by performing a predetermined calculation based on the heat consumption Q. The past data W is data used for predicting the required heat quantity, as described later. Also, when calculating the past data W, the past data W is calculated with reference to the past data W that is earlier by the reference cycle. Here, the reference cycle is a predetermined period, but is one week in the embodiment of the present invention. Accordingly, the calculated past data W is calculated based on the measured physical quantity and the past past data W one week ago, and thus is calculated with reference to the past data W on the same day of the past. Note that when the thermal system 8 is started to be used, the initial value S is used instead of the past data W before the reference cycle.
The calculation by the past data calculation means 11 is corrected by the calculation correction means 11a as described later.
[0052]
The past data storage means 12 stores the past data W. When the past data W is stored, the past data W is updated by replacing the past data W with a reference cycle before. Therefore, as the past data W, the latest past data W for one week, which is the reference cycle, is stored.
[0053]
The calorie estimating unit 13 estimates the required calorific value based on the past data W before the reference cycle stored in the past data storage unit 12. Therefore, it is performed based on the past data W one week ago.
Further, at the time of the prediction by the calorific value predicting means 13, it is corrected by the prediction correcting means 13a. Specifically, this is performed using the previous heat consumption Q or the like measured before the time when the required heat amount is predicted.
[0054]
The past data comparison unit 14 is used when performing the operation correction unit 11a and the prediction correction unit 13a. The past data comparison unit 14 compares the consumed heat amount Q calculated by the calorific value calculation unit 10 with the past data W that is earlier by the reference period. This comparison may be expressed as a difference or a ratio between the consumed heat amount Q and the past data W, but a combination of these may be used, and the comparison may be performed by adding another coefficient or the like.
[0055]
The heat source control device 1 is controllably connected to the heat source 16.
The heat source 16 is a generator that can be controlled from the outside, and is a device that can cool waste heat generated during power generation with cooling water and extract the cooling water as heat energy. Then, heating is directly supplied by waste heat, or the water in the storage unit 17 and the thermal energy using device 18 is heated via a heat exchanger or the like.
The power generated by the heat source (generator) 16 is consumed by a power load 22 such as a television or a refrigerator.
[0056]
The storage unit 17 is a tank having a heat retaining function, and the water inside the storage unit 17 is heated by the exhaust heat of the heat source 16 as described above.
The heat energy use device 18 performs heating or the like using water heated by the exhaust heat of the heat source 16 or heated water supplied from the storage unit 17, and specifically, the hot water supply device 19, A bath device 20 and a heating device 21. Hot water supply device 19 is a device for supplying hot water, and more specifically, a hot water tap or a shower. The bath apparatus 20 is provided with a bathtub, can circulate water in the bathtub and reheat it, and can supply high-temperature water to the bathtub. The heating device 21 circulates water higher than room temperature through a circulation path and performs heat exchange indoors to perform heating.
[0057]
The heat source 16, the storage unit 17, and the heat energy using device 18 are connected by a pipe 24, and temporarily store the heat energy generated by the heat source 16 in the storage unit 17. As shown in FIG. 2, the pipe 24 is connected so that water flows in a direction indicated by an arrow, and heat energy can be transferred. Note that the pipe 24 may have a configuration in which a heat exchanger or the like is provided at an intermediate portion, and may not have a channel directly connected.
[0058]
Further, as shown in FIG. 2, in the thermal system 8, a water supply thermistor 10 a for measuring the introduced water temperature T 1, and a temperature T 2 of the hot water used in the heat energy using device 18 and the amount V thereof are measured. A tapping thermistor 10b and a tapping flow rate sensor 10c are provided. The calorific value calculating means 10 is calculated based on these detected data.
[0059]
Next, the control by the heat source control device 1 using the heat system 8 having the heat source control device 1 will be described.
[0060]
When the heat source 16 having the power generation function of the thermal system 8 operates, it generates heat while generating power, and recovers waste heat with cooling water.
Further, the above-mentioned introduced water temperature T1, the temperature T2 of the hot water used by the thermal energy using device 18 and the amount V thereof are measured every hour by the water supply thermistor 10a, the hot water thermistor 10b and the hot water flow sensor 10c.
Then, the calorific value calculating means 10 calculates the calorific value Q. The heat consumption Q is an estimated heat consumption calculated from a predetermined physical quantity. Specifically, the water temperature T1 introduced into the heat system 8, the temperature T2 of the hot and cold water used in the heat energy use device 18, and It is obtained from the amount V, and is the amount of heat considered to be consumed in the thermal system 8. In the present embodiment, it is obtained by Expression 1.
[0061]
Q = (T2−T1) × V (Formula 1)
[0062]
Then, as shown in FIG. 3, the past data W is calculated by the past data calculation means 11. Since the past data W is calculated based on the past data W one week ago, the past data one week ago is described as Wb, and the past data obtained is described as Wa. Specifically, the past data Wa is calculated by Expression 2 (STEP 3). In the present embodiment, α is set to 0.25.
[0063]
Wa = Q × α + Wb × (1−α) (2)
[0064]
However, since there is no past data Wb one week before within one week from the installation, a preset initial value S is used instead (STEP 1). At this time, the following equation 3 is used when calculating the past data Wa (STEP 5).
[0065]
Wa = Q × β + S × (1−β) (3)
[0066]
In the above formula, α and β are 0 or more and 1 or less. Further, β is larger than α, and the past data W is brought close to the heat consumption Q as early as possible after installation.
If the difference between the consumed heat amount Q and the past data Wb is large, β may be used even after one week has passed since the installation (STEP 2). When calculating the past data Wa, the following equation 4 is used (STEP 4).
[0067]
Wa = Q × β + Wb × (1-β) (4)
[0068]
Then, the past data Wa is stored by the past data storage unit 12 (STEP 10). This storage is updated by replacing the past data Wb one week ago.
However, it is not updated when the absence is determined by the absence detecting means as described below, and is updated in other cases (STEPs 6 to 9).
More specifically, first, the past data comparison unit 14 compares the heat consumption Q1 of the previous day with the past data Wb1 before the reference cycle (one week before) of the heat consumption and the consumption H2 of the previous two days. A comparison result H2 between the heat quantity Q2 and the past data Wb2 before the reference cycle of the heat consumption is calculated (STEP6, STEP7). Specifically, it is as shown in Expressions 5 and 6.
[0069]
H1 = Q1 / Wb1 (Equation 5)
[0070]
H2 = Q2 / Wb2 (Equation 6)
[0071]
Then, the comparison result H1 and the comparison result H2 are confirmed. As a result, if "H1 and H2 are smaller than a predetermined value" are not satisfied, it is determined that there is no absence.
[0072]
As described above, when the difference between the consumed heat amount Q and the past data Wb is large continuously from the previous day and the day before the previous day, the absence is determined, and the past data Wa obtained by the arithmetic correction unit 11a is compared with the past data one week ago. Processing is performed to adopt the data Wb, and the past data W is not updated. Otherwise, the past data W is updated (STEP 9).
[0073]
When it is determined that the user is absent, the updating of the past data W by the past data storage unit 12 is stopped, and the operation does not return to the normal operation until the home is confirmed by the predetermined detection unit.
The absence determination by the absence detection means is automatically performed as described above, but can also be manually performed by a user. In the present embodiment, control is performed as shown in FIG.
[0074]
First, when the absence setting is performed by the user when the user is absent, the determination is NO in STEP21, and the user does not move from STEP23 until the absence setting is canceled in STEP23. If the absence setting has not been made, the process moves from STEP 21 to STEP 24, and the absence detection is performed by the absence detection means as described above.
[0075]
If the absence is not determined, the past data W is updated as described above (STEP 26). Further, when the absence determination is performed, the past data Wb before the absence determination period, that is, the past data W of the previous day and two days before is also taken as the past data Wb of one week before. Specifically, after updating once, the past data Wa of the previous day and two days before is changed to the past data Wb of one week ago (STEP 25). The update of the past data Wa may be performed after the lapse of the absence determination period, that is, after confirming that the absence determination is not performed.
[0076]
Therefore, since the past data Wa is not updated at the time of absence, even if the heat consumption Q decreases during the long-term absence, the required heat amount predicted value Ty described later does not decrease, and the subsequent control is immediately performed before the long-term absence. State.
[0077]
Further, an operation can be used using the following conditions.
That is, when the difference between the heat consumption Q and the past data W is large, the heat consumption today is not updated as an abnormal value.
However, if all of the previous day comparison result H1, the two day before comparison result H2, and the day comparison result H have the same tendency, the past data W is updated assuming that they are normal values. In this case, the past data W of the previous two days is not updated unless the same tendency is observed for three consecutive days. However, when the condition of this proviso is satisfied, the past data W of the previous two days is not updated. Be updated.
With such a configuration, when the use conditions used by the thermal system 8 fluctuate, for example, when the user changes, the past data W that can be accurately predicted is stored and updated. I can go.
[0078]
Next, a method of estimating the required amount of heat using the past data W and the like by the calorie estimating means 13 using the recorded past data Wa will be described. The interval at which the calorie prediction unit 13 performs the prediction is not particularly limited, but may be hourly in accordance with the timing of measuring the calorie consumption Q, or may be collectively performed every day. Should be shorter than the period.
[0079]
The prediction of the required heat amount is shown in FIG. 5, and is performed based on the past data Wb one week ago. Further, the prediction is corrected using the prediction correction means 13a. Specifically, the prediction of the required heat quantity is corrected in consideration of the comparison result H1 the day before and the comparison result H2 two days ago. The previous day comparison result H1 and the two days ago comparison result H2 are calculated by the past data comparison means 14.
As shown in STEP40 and STEP41, the previous day comparison result H1 is “the ratio of the heat consumption Q1 of the day before the required heat quantity is predicted to the corresponding past data Wb1 one week ago”, and the comparison result H2 two days ago is “Necessary. The ratio of the calorific value Q2 two days before the predicted calorific value and the corresponding past data Wb2 one week ago ”. Note that these values may use the sum of the heat consumption Q of the day and the sum of the past data Wb of the day on the previous day (two days before the previous day). The heat consumption Q1 of two days before and the past data Wb1 may be used, and any value may be used as long as the value can be compared.
[0080]
As a specific calculation method, the heat consumptions Q1 and Q2 and the past data Wb1 and Wb2 are obtained, and are calculated by Expressions 7 and 8.
[0081]
H1 = Q1 / Wb1 (Equation 7)
[0082]
H2 = Q2 / Wb2 (Equation 8)
[0083]
Then, the relationship between the previous day comparison result H1 and the two days ago comparison result H2 is confirmed (STEP 42 to STEP 44). As a result, when any of “H1> 1 and H2 <1”, “H1 <1 and H2> 1” and “H1 / H2 or H2 / H1 is larger than a predetermined value”, the prediction correction is performed. The value G is unconditionally set to 1 (STEP 46), and in other cases, the prediction correction value G is calculated by Expression 9 (STEP 45).
[0084]
G = (H1 + H2) × 0.5 (Equation 9)
[0085]
Further, a required heat amount prediction value Ty is calculated based on the prediction correction value G and the past data Wb. Specifically, it is calculated by Expression 10 (STEP 47).
[0086]
Ty = G × Wb (Equation 10)
[0087]
In the present embodiment, since the configuration is as described above, the prediction of the required heat quantity is more accurate. That is, since the required heat quantity prediction value Ty is calculated by multiplying the past correction data G by the prediction correction value G, the prediction can be made based on the tendency of the previous day and the day before the previous day. In addition, when the prediction correction value G is any one of “H1> 1 and H2 <1”, “H1 <1 and H2> 1”, “H1 / H2, or H2 / H1 is larger than a predetermined value” Since the prediction correction value G is unconditionally set to 1, the past data Wb can be used as the required heat quantity prediction value Ty while temporarily ignoring large fluctuations and fluctuations in the error range. Factors and the like can be eliminated.
[0088]
Then, the required heat amount prediction value Ty is continuously calculated, and control is performed so that the output state of the heat source 16 becomes an optimum state.
[0089]
Next, second and third embodiments will be described.
When the bath apparatus 20 is provided in the thermal system 8, a specific problem may occur. That is, when the bath apparatus 20 is operated, a large amount of heat is required. However, the user using the thermal system 8 does not always operate the bath apparatus 20 at the same time every day. There is a case to reheat.
This variation greatly changes the prediction of the required heat quantity. Therefore, energy can be further saved by solving this problem.
[0090]
The heat source control device 2 in the second embodiment is used when the bath system 20 is provided in the heat system 8, and measures a physical quantity related to the residual energy of the bath to determine the thermal energy remaining in the bath. It has a bath residual energy detecting means 51 for detecting the amount of heat and a bath use heat amount estimating means 52, and is compared with the heat source control device 1 of the first embodiment in the past data calculating means 11 and the heat amount predicting means 13. This is a modification of a method of calculating the required heat quantity prediction value Ty.
[0091]
The heat source control device 2 will be described with reference to FIG. 6. The bath device 20 is provided with a bath tub thermistor 10d and a water amount sensor 10e capable of measuring the temperature T3 and the water amount L of the water in the bath tub 20a. The thermal energy amount is calculated by the detecting means 51. And it is measured every hour similarly to the water supply thermistor 10a, the tap water thermistor 10b, and the tap water flow rate sensor 10c.
[0092]
Then, the bath residual energy E1 is calculated by equation (11).
[0093]
E1 = (T3−T1) × L (Equation 11)
[0094]
Further, when calculating the required heat amount prediction value Ty by the heat amount prediction means 13, correction is performed based on the bath residual energy E1. Specifically, the correction is performed such that the amount of heat generated by the heat source 16 is reduced by the bath residual energy E1.
The time at which the correction for reducing the required heat amount prediction value Ty is performed and the heat amount are determined by the bath use heat amount estimation unit 52. The bath usage calorie estimating means checks the past past data W to determine the time at which the heat consumption is the highest in the day or the time at which the bath is predicted to be operated from the past operating conditions. to decide. Then, the required heat amount prediction value Ty at this time is corrected.
[0095]
The past data calculation means 11 in the heat source control device 2 calculates the consumed heat quantity Q ′ from each physical quantity in consideration of the residual bath energy E1. Specifically, the calculation is performed by Expression 12. In addition, Q is the calorific value calculated from the measurement result as described above.
[0096]
Q ′ = Q−E1 (Equation 12)
[0097]
The heat source control device 2 has a bath residual energy detecting unit 51 and a bath use heat amount estimating unit 52, and can detect a heat energy amount remaining in the bath. Then, the prediction correction means 13a corrects the prediction according to the amount of heat energy remaining in the bath at the time of the prediction, so that even when the bath operation is performed using the remaining hot water in the bath, the required amount of heat can be accurately predicted. It becomes.
[0098]
Further, the heat source control device 3 in the third embodiment is used when the bath system 20 is provided in the heat system 8 like the heat source control device 2 in the second embodiment. 20 is provided with a bath operation reservation function. This is a modification of the method of calculating the required heat amount prediction value Ty in the heat amount prediction means 13 as compared with the heat source control device 1 of the first embodiment.
[0099]
The heat source control device 3 will be described with reference to FIG. 7. The thermal system 8 is provided with a reservation operation unit 30 that can perform a reservation operation of a bath operation, and a user reserves a bath operation. In this case, a predetermined input including conditions such as time is performed on the reservation operation unit 30. Then, when the reservation operation unit 30 is input, information is transmitted to the heat source control device 3 by the transmission unit 55. Further, bath operation energy E2, which is energy required for bath operation, is calculated based on predetermined conditions.
[0100]
Further, when calculating the required heat amount prediction value Ty by the heat amount prediction means 13, correction is performed based on the bath operation energy E2. Note that the bath operation energy E2, which is the energy required for bath operation, is set in advance or calculated according to predetermined conditions.
Specifically, the required heat amount prediction value Ty near the bath operation reservation time is increased by the bath operation energy E2, so that the amount of heat generated by the heat source 16 is increased. Further, similarly to the heat source control device 2 in the second embodiment, the bath use heat amount estimating means 52 is provided, and correction is performed so as to decrease the required heat amount prediction value Ty at the time determined by the bath use heat amount estimating means 52. . More specifically, this is performed by Expression 13.
[0101]
Ty '= Ty-E2 (Equation 13)
[0102]
In the heat source control device 3, the bath operation time can be accurately determined by the bath reservation function. Therefore, the heat correction is performed by the prediction correction means 13a so that the predetermined heat is obtained at the time reserved by the bath reservation function. Accurate prediction is possible.
[0103]
Next, a fourth embodiment will be described.
In the above-described first to third embodiments, the required amount of heat is predicted to control the amount of heat generated by the heat source 16 of the heat system 8. Since the heat source 16 is a generator, the generation and use of the required amount of heat are performed. In the case of a use situation where the balance with the amount of power to be used is poor, it is difficult to save energy.
Therefore, in the heat source control device 4 according to the fourth embodiment, in order to solve the above-described problem, the necessary power prediction unit 40 is provided, and the required power prediction predicted by the required power prediction unit 40 and the heat amount prediction unit 13 described above are performed. The operation of the heat source 16 is controlled such that the heat source 16 is in an optimal operation state based on the prediction result of the required heat amount.
[0104]
The heat source control device 4 is shown in FIG. 8 and includes a required power prediction unit 40 and a heat amount prediction unit 13. Further, a power meter 42 that can measure the amount of power at the place where the heat source control device 4 is installed is provided, and electricity is consumed by the electric appliance 44. The amount of power is measured at regular intervals, and the required power predicting means 40 performs the required power prediction based on past usage results and the like in the same manner as the prediction of the required amount of heat by the calorific value predicting means 13 described above.
The heat source control device 4 determines the most appropriate operation pattern of the heat source based on the amount of heat stored in the storage unit 17, the amount of heat released from the storage unit 17, the use time of the heat stored in the storage unit 17, and the use time of the electric power. Is calculated.
[0105]
Further, instead of the above calculation, the future heat source based on the energy consumption within a predetermined period when the heat source 16 is currently operated and the heat amount prediction unit 13 and the required power prediction unit 40 based on the current heat storage state in the storage unit 17. The control method of operating the heat source 16 when the predetermined condition is satisfied by comparing the energy consumption in a predetermined period when the device is operated can be adopted.
[0106]
Specifically, the operation of the heat source 16 in the case where the required heat amount for a certain period is generated by the heat source 16 is determined based on the generated power amount due to the operation of the heat source 16 and the prediction of the power consumption amount in the vicinity of the certain period. .
For example, when the power consumption is large in a later time period during the operation of the heat source 16, the heat energy is less radiated, so it is better to operate the latter as much as possible. If there are many, it is preferable to operate the heat source 16 in advance in order to prevent unnecessary power generation in a later time zone.
[0107]
In the present invention described above, any heat source 16 can be used. Then, since it is possible to perform control so that heat can be generated efficiently, by operating a heat source such that a predetermined amount of heat is stored in a heat storage unit such as a storage unit at a predetermined time, heat is generated. Since energy can be supplied, it is particularly effective when the amount of heat generated by the heat source 16 is less than the amount of heat consumed at the peak time.
[0108]
In addition, when the heat source 16 is operated based on the required heat amount predicted value Ty, the heat source 16 can be operated in advance and the storage unit 17 can store heat energy. In addition, this operation may be performed in advance or immediately before, or may be performed by dividing into several times.
[0109]
【Example】
Next, a use situation when the above-mentioned thermal system 8 is used will be described.
[0110]
FIG. 9 is a graph showing past data W at each time for a certain day of the week in chronological order. As described above, since the past data W is calculated based on the past heat consumption Q at each time, the past data W indicates the past heat consumption Q.
As described above, the calculation method is calculated from the heat consumption Q one week ago, the past data Wb and α, but since the past data W does not exist for one week when the thermal system 8 is used, the initial The value S is used. At this time, if the initial value S and the heat consumption Q are far apart from each other as shown in FIG. 10, the number of times is required until the prediction is made with high accuracy. However, as shown in FIG. Is used instead of. Therefore, accurate prediction can be performed more quickly.
[0111]
Further, when performing the operation correction means 11a and the prediction correction means 13a, the comparison result H calculated by the past data comparison means 14 is used. The comparison result H is a ratio between the heat consumption Q and the past data W one week ago, and becomes larger than 1 when the heat consumption Q is relatively large.
[0112]
FIG. 11 is a graph of the comparison result H every day.
Here, when the calorific value is predicted at D1, the comparison result H1 of the day before D1 and the comparison result H2 of the day before two days (X1 in FIG. 11) satisfy “H1> 1” and “H2 <1”. This state is a state in which the relation with the past data W is such that the heat consumption Q is relatively large and the heat consumption Q is relatively small. In this case, the prediction correction value G is set to 1 to reduce the fluctuation of the prediction and perform the prediction with higher accuracy.
[0113]
Further, when the calorific value is predicted in D2, the comparison result H1 of the day before the day of D2 is extremely large (X2 in FIG. 11), and it is considered that a large amount of consumed heat Q temporarily increases.
In such a case, the prediction correction value G becomes 1 unconditionally, so that more accurate prediction can be performed. The same applies to the case where the calorific value is predicted in D3.
[0114]
In D6, the comparison result H1 of the day before (D5) on the day of D6 and the comparison result H2 of the day before (D4) are extremely small (X3 in FIG. 11). Then, as described above, the absence is determined, and the past data W is not updated.
[0115]
Further, when the bath residual energy E1 is calculated by including the bath residual energy detecting unit 51 and the bath use heat amount estimating unit 52, the required heat amount predicted value Ty is reduced by reducing the bath residual energy E1. is expected.
FIG. 12 shows a required heat quantity predicted value Ty when the bath residual energy E1 is not provided and a required heat quantity predicted value Ty ′ when the bath residual energy E1 is provided. Then, as shown in FIG. 12, the required heat amount prediction value Ty 'is calculated so as to be smaller by the bath residual energy E1 than the required heat amount prediction value Ty (A1 in FIG. 12).
[0116]
If the bath apparatus 20 is provided with a bath operation reservation function, the required heat amount prediction value Ty can be predicted according to the reservation time.
FIG. 13 shows a case where the bath reservation time is 17:00. Also, the normal bath operation time in this embodiment is estimated by the bath use calorie estimating means 52 to be 19:00 to 21:00.
Then, the predicted value of the required heat amount prediction value Ty is corrected as indicated by the required heat amount prediction value Ty ′. This correction, as shown in FIG. 13, increases the required heat amount prediction value Ty ′ near the reserved bath operation time and decreases the required heat amount prediction value Ty ′ at the time determined by the bath use heat amount estimation unit 52. It is. The total amount of heat before and after the correction is not changed, and A2 and A3 in FIG. 13 are the same.
[0117]
Further, even when the bath operation time determined by the bath use calorie estimating means 52 and the bath reservation time are close, the correction is performed so as to more accurately predict the required calorie.
FIG. 14 shows a case where the bath reservation time is 21:00. The normal bath operation time in this embodiment is estimated to be 19:00 to 21:00 by the bath use heat amount estimating means 52. As shown in FIG. 14, the necessary heat amount around 21:00 is particularly increased. to correct.
[0118]
【The invention's effect】
The heat source control device of the present invention accurately predicts the use of heat energy, has high energy efficiency of the entire heat system, and can achieve more energy saving.
[0119]
In particular, according to the first aspect of the present invention, the calorie consumption is calculated at regular intervals, the past data is calculated and stored, and the required calorie is predicted based on the past data preceding by the reference period, and the heat source is calculated. Control, and further, the prediction is corrected based on the comparison result between the calorie consumption calculated in the past and the past data before the reference cycle of the calorie consumption, so that not only the data before the reference cycle but also the Based on this tendency, it is possible to make predictions, and it is possible to more accurately predict the required amount of heat.
[0120]
In particular, according to the second aspect of the present invention, since the prediction is made using the comparison result of the previous day and the comparison result of two days ago, not only the past data before the reference cycle but also the tendency of the previous day and the day before the previous day are considered. Prediction can be made. In addition, since the reference cycle is one week, the prediction is performed based on the past data corresponding to one week before, so that the required amount of heat can be accurately predicted.
[0121]
In particular, according to the third aspect of the present invention, the prediction correction unit compares the previous day comparison result and the two day before comparison result and corrects the prediction when a predetermined condition is satisfied. Since it is not available, it is possible to accurately predict the required heat even when an unusual use situation occurs or when an abnormal value appears for some reason.
[0122]
In particular, according to the invention as set forth in claim 4, the calculation correction means performs the calculation based on a comparison result between the heat consumption calculated in the past and the past data of the heat consumption before a reference cycle. It is possible to calculate not only based on the data before the reference cycle but also on the basis of the previous trend, so that the past data is closer to the actual required heat quantity, and it is possible to more accurately predict the required heat quantity It becomes.
[0123]
In particular, according to the fifth aspect of the present invention, since the calculation is performed using the comparison result of the previous day and the comparison result of two days before, not only the past data before the reference cycle but also the tendency of the previous day and the day before the previous day. The past data can be calculated in consideration of the above. In addition, since the reference cycle is one week, the prediction is performed based on the past data corresponding to one week before, so that the required amount of heat can be accurately predicted.
[0124]
In particular, according to the invention as set forth in claim 6, when the comparison result between the previous day and the comparison result before two days is satisfied and a predetermined condition is satisfied, the past data is updated by the past data storage unit. Since there is no such situation, it is possible to prevent the past data from being updated when the usage is different from normal or when an abnormal value is calculated for some reason and the past data that is far from the actual situation is calculated. Updating can be performed only when updating is allowed.
[0125]
In particular, according to the invention described in claim 7, when the comparison result of the previous day and the comparison result of two days before the day continuously satisfy a certain standard, the absence is detected and the absence is determined. Since the updating of the past data by the means is stopped, it is prevented that the past data departs from the normal value of the heat consumption due to the absence of the heat consumption and an extreme decrease in the heat consumption.
[0126]
In particular, according to the invention of claim 8, when the past data is calculated using the initial value, the past data is calculated by reflecting the heat consumption more than in the normal calculation, so that the calculation is performed from the beginning. , Faster and more accurate predictions are possible.
[0127]
In particular, according to the ninth aspect of the present invention, when the difference between the heat consumption and the past data obtained by a reference cycle of the heat consumption is larger than a certain value, the heat consumption is more than the normal calculation. Since the past data is calculated by largely reflecting the calorific value, accurate prediction can be performed more quickly.
[0128]
In particular, according to the invention as set forth in claim 10, since the calculation and correction means corrects and calculates in accordance with the amount of heat energy remaining in the bath, when the bath is operated using the remaining hot water in the bath, the bath The past data can be calculated in consideration of the amount of heat of the remaining hot water. Therefore, the amount of heat consumed in the bath operation can be the same whether or not the remaining hot water in the bath is used. Then, when the required heat quantity is predicted using the past data, the accuracy is accurate.
[0129]
In particular, according to the eleventh aspect of the present invention, the amount of heat energy remaining in the bath is detected and corrected by the prediction correction means at the time of prediction according to the amount of heat energy remaining in the bath. Even when the bath operation is performed using the remaining hot water, the required heat quantity can be accurately predicted.
[0130]
In particular, according to the twelfth aspect of the present invention, since the prediction correction means corrects so that a predetermined heat is obtained at the time reserved by the bath reservation function, the bath operation time can be accurately determined. Therefore, the required amount of heat can be accurately predicted.
[0131]
In particular, according to the invention as set forth in claim 13, when bath operation is reserved and the time of bath operation is accurately known, correction is made so that predetermined heat is obtained at the reserved time, Since the correction is also made based on the estimated amount of heat used in the bath, the required amount of heat can be predicted very accurately.
[0132]
In particular, according to the invention as set forth in claim 14, when there is a prediction of a required heat amount corresponding to the amount of use of the bath near the reserved time, the heat source is set so that predetermined heat is obtained at the reserved time. At the same time as driving, the heat source is operated by estimating the required heat amount that is obtained by subtracting the required heat amount corresponding to the amount of bath use from the vicinity of the reserved time. By reducing the required amount of heat corresponding to the amount of bath used, the amount of heat can be accurately predicted.
[0133]
In particular, according to the invention as set forth in claim 15, when there is a required heat amount prediction corresponding to the amount of use of the bath at another time, the heat source is operated such that predetermined heat is obtained at the reserved time, The heat source is operated by the required heat amount prediction, which is obtained by subtracting the required heat amount corresponding to the bath usage from the predicted time, so the required heat amount corresponding to the bath usage is added at the reserved time, and By reducing the corresponding required amount of heat, the amount of heat can be accurately predicted.
[0134]
In particular, according to the invention as set forth in claim 16, it has a necessary power prediction means, and can calculate the most appropriate operation pattern of the heat source from the heat storage amount, the heat release amount, the heat use time, and the power use time. Therefore, energy can be saved more.
[0135]
In particular, according to the seventeenth aspect of the invention, based on the current power usage status, the current heat usage status, and the current heat storage status, the energy consumption within a predetermined period when the heat source is currently operated, and the heat amount The energy consumption within a predetermined period when the heat source is operated in the future based on the prediction means and the required power prediction means is compared, and the heat source is operated when the predetermined condition is satisfied. Operation becomes possible, and energy can be further saved.
[0136]
In particular, according to the invention as set forth in claim 18, since the heat source can be operated such that the heat storage means is provided and the predetermined amount of heat is stored in the heat storage means at a predetermined time, the heat consumption at the peak time can be reduced. The present invention is applicable to a thermal system having a heat source having a relatively small calorific value.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a thermal system according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing a thermal system according to the first embodiment of the present invention.
FIG. 3 is a flowchart showing a method of calculating past data and a method of performing absence determination.
FIG. 4 is a flowchart showing a method of performing absence determination.
FIG. 5 is a flowchart illustrating a method for calculating a required heat amount prediction value Ty.
FIG. 6 is a block diagram showing a thermal system according to a second embodiment of the present invention.
FIG. 7 is a block diagram showing a thermal system according to a third embodiment of the present invention.
FIG. 8 is a block diagram showing a thermal system according to a fourth embodiment of the present invention.
FIG. 9 is a graph showing past data W at each time of day in a time series.
FIG. 10 is a graph showing past data and heat consumption for each week in chronological order from the start of use of the thermal system.
FIG. 11 is a graph showing daily comparison results H;
FIG. 12 is a graph showing the required heat quantity predicted value Ty and the corrected required heat quantity predicted value Ty ′ at each time of day in a time series.
FIG. 13 is a graph showing the required heat quantity predicted value Ty and the corrected required heat quantity predicted value Ty ′ at each time of day in a time series.
FIG. 14 is a graph showing the required heat quantity predicted value Ty and the corrected required heat quantity predicted value Ty ′ at each time of day in a time series.
[Explanation of symbols]
1,2,3,4 heat source control device
8 Thermal system
10 Calorie calculation means
11 Past data calculation means
11a Operation correction means
12 Past data storage means
13 Calorie prediction means
13a Prediction correction means
16 heat source
17 Reservoir
20 Bath equipment
40 Required power prediction means

Claims (18)

A calorific value calculating means for calculating a calorie consumption at regular intervals; a past data calculating means for performing a predetermined calculation based on the calorie consumption to calculate past data; a past data storage means for storing the past data; Heat amount prediction means for predicting a necessary heat amount based on past data corresponding to a reference cycle which is a period before, and a heat source control capable of controlling the heat source in accordance with the prediction obtained by the heat amount prediction means In the apparatus, the calorie prediction means can correct the prediction by prediction correction means, and the prediction correction means compares the calorie consumption calculated in the past with past data that is earlier by a reference cycle of the calorie consumption. A heat source control device for correcting a prediction based on a comparison result. The reference cycle is one week, and the prediction correction unit calculates the heat consumption calculated on the previous day and the previous day comparison result that is a comparison between the heat consumption calculated on the previous day and the past data of the heat consumption calculated by the reference cycle, and the heat consumption calculated on the previous day. The correction is made at the time of prediction based on the heat consumption calculated on the day before two days ago and the comparison result of two days before two days, which is a comparison between the heat consumption and the past data obtained by a reference cycle before the heat consumption. The heat source control device according to claim 1, wherein The method according to claim 2, wherein the prediction correction unit does not correct the prediction when the comparison result between the previous day and the comparison result before two days is satisfied and a predetermined condition is satisfied. The heat source control device as described in the above. A calorific value calculating means for calculating a calorie consumption at regular intervals; a past data calculating means for performing a predetermined calculation based on the calorie consumption to calculate past data; a past data storage means for storing the past data; Heat amount prediction means for predicting a necessary heat amount based on past data corresponding to a reference cycle which is a period before, and a heat source control capable of controlling the heat source in accordance with the prediction obtained by the heat amount prediction means The past data calculation means can correct at the time of calculation by a calculation correction means, the calculation correction means compares the heat consumption calculated in the past with the past heat amount preceding the reference cycle by the reference cycle of the heat consumption. A heat source control device, wherein the correction is performed at the time of calculation based on a result of comparison with data. The reference cycle is one week, the calculation correction means, the previous day comparison result is a comparison of the heat consumption calculated on the day before the heat consumption of the calculation target and the past data only by the reference cycle of the heat consumption, In addition, when the calculation is performed based on the comparison result of the heat consumption amount calculated two days before the heat consumption amount to be calculated before and the past data obtained by comparing the past heat data by the reference cycle of the heat consumption amount before the reference period, The heat source control device according to claim 4, wherein the correction is performed. The past data storage means updates the past data calculated by the past data calculation means by replacing the past data with the previous data only by the reference period, and compares the previous day comparison result with the two days ago comparison result. 6. The heat source control device according to claim 5, wherein the past data is not updated by the past data storage unit when a predetermined condition is satisfied. Absent detecting means, wherein the absent detecting means detects absent when the previous day comparison result and the two days before comparison result continuously satisfy a certain criterion, and determines absence; 7. The heat source according to claim 6, wherein the update of the past data by the storage unit is stopped, and if the predetermined condition is satisfied, the home determination is made and the update of the past data by the past data storage unit is restarted. Control device. If the period of the reference cycle has not elapsed since the start of use, or if the past data before the reference cycle is not stored, the past data is calculated using a preset initial value, The heat source control device according to any one of claims 1 to 7, wherein when calculating the past data using the initial value, the past data is calculated by reflecting the heat consumption more greatly than in a normal calculation. . If the difference between the calorie consumption and the past data only by the reference cycle of the calorie consumption is equal to or more than a certain value, the past data is calculated in the same manner as the method of calculating the past data using the initial value. The heat source control device according to claim 8, wherein the calculation is performed. The apparatus is used in a thermal system including a bath, and has bath residual energy detecting means for detecting the amount of thermal energy remaining in the bath, and the past data calculating means can be corrected at the time of calculation by the calculating correction means. The heat source control device according to any one of claims 1 to 9, wherein the correction unit is configured to correct and calculate according to an amount of heat energy remaining in the bath. Used in a thermal system including a bath, has a bath residual energy detecting means for detecting the amount of heat energy remaining in the bath, the heat amount prediction means can correct the prediction by prediction correction means, the prediction correction means The heat source control device according to any one of claims 1 to 10, wherein the correction is performed at the time of prediction according to the amount of heat energy remaining in the bath. Used in a thermal system including a bath, a bath reservation function for reserving bath use is provided, and the calorie prediction means can correct prediction by prediction correction means, and the prediction correction means The heat source control device according to any one of claims 1 to 11, wherein the correction is performed so that predetermined heat is obtained at a reserved time. It has a bath use calorie estimating means, the bath use calorie estimating means, as the bath use calorie, the heat consumption around the time when the heat consumption is the highest in the day or the time when the bath is predicted to be operated. 13. The method according to claim 11, wherein the prediction correction unit corrects a predicted value of a required heat amount near a time when the bath use heat amount is generated based on the bath use heat amount. Heat source control device. A heat source control device that is used in a heat system including a bath, includes a calorie prediction unit that predicts a required amount of heat of the day based on past use results, and operates a heat source according to the prediction of the calorie prediction unit. If you have a bath reservation function to reserve the use of the bath, and if there is a prediction of the required amount of heat corresponding to the amount of bath used near the reserved time, operate the heat source so that the predetermined heat is obtained at the reserved time And a heat source control device that operates the heat source by predicting a required heat amount obtained by subtracting a required heat amount corresponding to a bath usage amount from around a reserved time. A heat source control device that is used in a heat system including a bath, includes a calorie prediction unit that predicts a required amount of heat of the day based on past use results, and operates a heat source according to the prediction of the calorie prediction unit. If you have a bath reservation function to reserve the use of the bath, there is no prediction of the required amount of heat equivalent to the amount of bath usage near the reserved time, and there is a prediction of the required amount of heat equivalent to the amount of bath usage at other times Operating the heat source so that predetermined heat is obtained at the reserved time, and operating the heat source according to the required heat amount prediction obtained by subtracting the required heat amount corresponding to the amount of use of the bath from the predicted time. Heat source control device. A heat source capable of extracting heat and electric power, and a heat source control device for controlling a heat system including a heat storage means, the heat amount prediction means for predicting a required heat amount for each time of the day from past use results, It has the required power prediction means for predicting the required power at each time of the day from the actual usage, and calculates the most appropriate heat source operation pattern from the amount of stored heat, the amount of heat released, the time of heat use, and the time of power use. Heat source control device. A heat source capable of extracting heat and electric power, and a heat source control device for controlling a heat system including a heat storage means, the heat amount prediction means for predicting a required heat amount for each time of the day from past use results, It has a required power prediction means for predicting the required power for each time of the day from the actual use, and a predetermined period when the heat source is currently operated based on the current power usage status, current heat usage status, and current heat storage status. The energy consumption within a predetermined time period when the heat source is operated in the future based on the heat amount prediction means and the required power prediction means is compared with each other, and when the predetermined condition is satisfied, the heat source is operated. Characteristic heat source control device. 18. A heat source having a calorific value less than the amount of heat consumed during a peak, and a heat storage means, wherein the heat source is operated such that a predetermined amount of heat is stored in the heat storage means at a predetermined time. The heat source control device according to any one of the above.

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