JP2002122356A - Regenerative heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a regenerative heater capable of being used as a heater even if the heat stored in a heat storage block runs short during any time other than midnight power service time. SOLUTION: In the case the quantity of the heat stored in the regenerative heater 10 becomes smaller than a lower limit enabling heating, ordinary power is used to heat the heat storage block 12 so as to increase the quantity of the stored heat.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a heat storage heater using midnight power.

[0002]

2. Description of the Related Art In order to eliminate the imbalance between daytime and nighttime power load factors, each electric power company provides a service in which a late-night electric power time zone is set and a unit price of electric power is set at a low price. Therefore, conventionally, heat is stored in the heat storage block using the midnight power, and heating is performed in the daytime using the heat storage block as a heat source. Note that the midnight power time zone here will be described as a time zone from 11:00 pm to 7:00 am in the following description, but since the set time may vary depending on the power company, it is limited to only this time zone. Not something.

Conventionally, this type of heat storage heater has a heat storage block for storing heat, a heater for heating the heat storage block,
The air conditioner was provided with a fan that ventilates the heat storage block and sends warm air into the room, and a control unit that turns off the heater when the temperature of the heat storage block exceeds the upper limit. Then, at midnight power time, the heater is turned on to store heat in the heat storage block, and during use in the daytime or the like, natural heat is radiated from the heat storage block,
Alternatively, a fan is operated to ventilate the heat storage block to generate warm air, which has been used as heating.

[0004] The heat storage heater described above has, for example, characteristics as shown in FIG. The amount of heat stored in the heat storage block using the late-night electric power is gradually reduced by being used as a heat source for heating, and thus is reduced, for example, by drawing a curve as indicated by the line A (solid line). And
Start time of midnight power (11 pm
Time). In the heat storage heater, a heating pattern of the E line (dotted line) set so that the heat storage amount becomes 100% near the end time of the late night power (7:00 am) is stored in advance. Therefore, at the time of the point P where the line A and the line E intersect, that is, at the time t determined according to the remaining amount of heat storage, the power supply to the heater is started, and the heating is performed so as to follow the temperature rising pattern of the line E. The energization control is performed, and the heat storage amount increases. By this energization control, efficient heat storage was performed while suppressing waste of power.

[0005]

However, in the case where the consumption of heat storage is intense due to factors such as the difference from the temperature is too large,
For example, draw a curve like the B line (dash-dot line)
Before 1 o'clock, there was a case where the value fell below the lower limit (heat storage amount capable of heating). However, since the conventional thermal storage heater is configured to store heat using only cheap midnight power, in such a case, the time zone of the part C in which the heating by the thermal storage heater cannot be used occurs. Therefore, there is a problem that a sufficient heating effect cannot be obtained.

[0006] In order to avoid such a problem, a heating design is generally made with an allowance of 20 to 40% for a necessary heat quantity in case of a shortage of heat storage. However, this method uses a heat storage heater one rank larger in consideration of safety than a heat storage heater with a heat capacity suitable for the space actually used. Has a problem that the physical burden increases.

In a relatively high temperature period such as early spring, the difference between the temperature of the heat storage block and the air temperature is small, so that the amount of heat storage consumed is small, and a curve such as a D-line (two-dot chain line) is formed. I sometimes draw. In this case, even if 100% of the heat storage block is stored every morning at the end of the midnight power time zone, the amount of stored heat is not sufficiently used and the power used for the heat storage is wasted. I was

[0008] In consideration of such conventional problems, the present invention can be used as heating even when the amount of heat stored in the heat storage block is insufficient outside midnight power hours, while saving power and reducing cost. It is another object of the present invention to provide a heat storage heater that can make full use of the stored heat amount without waste.

[0009]

Means for Solving the Problems In order to solve the above problems, the heat storage heater of the present invention employs the following means.

That is, in the first aspect of the present invention, there is provided a heat storage heater that heats a heat storage block using midnight power during a midnight power time and heats the heat by consuming the heat storage amount of the heat storage block. When the stored heat quantity falls below the lower limit value at which heating can be performed, a heat storage increasing function is provided for heating the heat storage block using normal power.

According to this means, when the heat storage amount falls below the lower limit outside the midnight power hours and heating cannot be performed, the heat storage increasing function is used to heat the heat storage block by using the normal power which is not the midnight power. By increasing the volume, the heating effect is maintained. In addition, the lower limit here means the minimum heat storage amount that can be heated among the heat storage amounts of the heat storage block.

According to a second aspect of the present invention, in the heat storage heater according to the first aspect, an operation unit for starting a heat storage increasing function is provided.

According to this means, since the heat storage increasing function uses relatively expensive normal electric power, the heating of the heat storage block is started only by operating the operation unit by the user's will.

According to a third aspect of the present invention, in the thermal storage heater according to the second aspect, a switch is provided in the operation unit, and the heat storage increasing function is started by the first operation of the switch, and the heat storage is increased by the second operation. The function is released.

According to this means, the start and release of the heat storage increasing function are reliably performed.

According to a fourth aspect of the present invention, in the heat storage heater according to any one of the first to third aspects, the heat storage increasing function includes:
It is automatically released after a lapse of a predetermined time from the start.

According to this means, the heat storage increasing function is automatically released after the lapse of the predetermined time, so that it is possible to prevent unnecessary power consumption due to forgetting to release the function.

According to a fifth aspect of the present invention, there is provided a heat storage heater that heats a heat storage block by using midnight power during a midnight power time and heats the heat storage block by consuming the amount of heat stored in the heat storage block. The setting of the upper limit value of the amount of heat stored in the battery is adjustable.

With this means, even if the heat storage block is 100% heat-stored at the end of midnight power, if the heat storage amount is not sufficiently consumed, the heat storage is performed by adjusting the upper limit of the heat storage amount to a lower value. As a result, the amount of heat stored by the midnight power is utilized. In addition, the upper limit here means the value of the heat storage amount reached by the power supply control near the midnight power end time of 7:00 am, and the maximum heat storage amount that can be stored in the heat storage block is 100%. It is a value determined by a value between 0-100%.

According to a sixth aspect of the present invention, in the heat storage heater according to the fifth aspect, the amount of heat stored during the midnight power end time is selected from a plurality of upper limits set in stages. It is characterized by being adjusted.

In this means, the heat storage amount is adjusted only by selecting from the upper limit value set in advance step by step, so that the operability of the user is improved.

Hereinafter, a basic embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows an embodiment (1).
FIG. 2 is an explanatory diagram showing the function of the embodiment (1), FIG. 3 is a flowchart showing the operation of the embodiment (1), and FIG. 4 is a block diagram of the heat storage heater of the embodiment (1). FIG. 5 is a cross-sectional view illustrating an example, and FIG. 5 is a circuit diagram illustrating an example of the circuit configuration of Embodiment (1).

The heat storage heater 10 of the embodiment (1) heats the heat storage block 12 by using the midnight power during the midnight power time, and heats the heat by consuming the amount of heat stored in the heat storage block 12. In addition, when the stored heat amount falls below the lower limit value for heating outside the midnight power hours, the power storage function is provided to heat the heat storage block 12 using normal power.

The basic configuration of the heat storage heater 10 is the same as that of a conventional heat storage heater, and includes a heat storage block 12 for storing heat and storing heat, a heater 14 for heating the heat storage block 12, and a heat storage block 12. A fan 16 that ventilates and sends warm air into the room, and a control unit 21 that controls energization of the heater 14 are provided. The control unit 21 includes a temperature-raising-pattern storing unit 22 that previously stores a temperature-raising pattern of the heat storage block 12 that rises with time and has a predetermined heat storage amount near the end time of late-night power; A clock unit 23 that outputs information, an energization control unit 24 that controls energization of the heater, and a temperature measurement unit 25 that measures the temperature of the heat storage block 12 are provided.

In addition to the basic configuration described above, in the heat storage heater 10 of the embodiment (1), as a heat storage increasing function, a heat storage increasing operation section 11 for performing an operation of turning on and off the heat storage increasing function, The control unit 21 includes a heat storage increasing control unit 26 that turns on and off the power supply to the heater 14 by operating the heat storage increasing operation unit 11. This heat storage increase function is available outside of midnight power hours (from 7:00 am to 11 pm
When the amount of heat storage required for heating is insufficient at the time of), power is supplied to the heater 14 by using normal power, and the heat storage block 12 is heated to increase the amount of heat storage. .

The heat storage increasing function may be configured to start automatically when the heat storage amount falls below the lower limit value.
Since the above-mentioned time zone from 7:00 am to 11:00 pm is a time zone in which an expensive electricity rate is set as normal power, the start of the heat storage increasing function may be determined by the user's will. preferable. Therefore, a heat storage increasing operation unit 11 for performing an artificial operation is provided. Further, the on / off operation of the heat storage increasing operation unit 11 includes:
A toggle-type switch is preferable, and the heat storage increasing function is started by the first pressing operation, and is released by the second pressing operation, so that the start and the release are reliably performed.

When the heat storage increasing operation unit 11 is turned on, the time information is input from the clock unit 23 in the storage heat increasing control unit 26. Then, after it is determined that the current time is outside the midnight power time, the power supply to the heater 14 is started. Further, the heat storage increasing operation unit 11 is provided with a timer function. When a predetermined time, for example, 3 hours, has elapsed from the time when the heat storage increasing operation unit 11 is operated, the power supply to the heater 14 is stopped. As a result, it is possible to prevent the user from forgetting to turn off the heat storage increasing function and wastefully consuming the expensive power. Of course, before the predetermined time elapses, the heat storage increasing operation unit 1
1 is turned off, the heater 14 is turned on by the user's will.
It is also possible to stop energizing the power supply. Further, when the heat storage increasing function is turned on, the heater 14 may be energized after confirming the actual heat storage amount, thereby preventing erroneous operation of the heat storage enhancement function.

Heat storage heater 1 having the function of increasing heat storage described above
The operation of 0 will be described with reference to FIGS. Outside the midnight power hours, normally, the heat storage block 12, which stores 100% of the heat at 7:00 am, performs natural heat radiation or forced heat radiation using the fan 16, so that the heat storage amount gradually decreases. The curve of the decrease draws a sharp decrease curve as shown by the line B (dashed line) in FIG. 2, and when the temperature falls below the lower limit and cannot be used as heating, the heat storage increasing operation unit 11 is operated at the point P1. Turned on [Step 10
1]. Next, when the time during which the heat storage increasing operation unit 11 is turned on is measured by the clock unit 23 and it is determined that it is outside the midnight power time [Step 102], the heater 14 is turned on and the power supply to the heat storage block 12 is started. [Step 10
3]. As a result, the heat storage amount rises from the point P1 and the fan 1
Heating is carried out by forced heat radiation or natural heat radiation by 6. Note that the point P1 is a point at which the time is determined by the user's will after falling below the lower limit.

Next, it is determined whether a predetermined time has elapsed or whether the heat storage increasing operation unit has been operated for the second time (steps 105 and 106). At any point P2, the function of increasing heat storage is released, and the heater 14 is turned off [Step 107]. Thereafter, as shown by the G line, heating is performed by forced heat radiation or natural heat radiation by the fan 16, and the heat storage amount is gradually consumed.

Then, similarly to the conventional case, when the midnight power start time comes, the start time of the temperature rise pattern is determined according to the remaining heat storage amount, and the heat storage amount becomes 100% from the point P to the vicinity of the midnight power end time. The energization control to the heater 14 is performed so as to be as follows.

FIG. 4 shows an example of the overall configuration of the heat storage heater 10.
Shown in The side surface, the upper surface, and the lower surface of the heat storage block 12 are covered with heat insulating materials 30, 32, and 34, respectively. The outer surfaces of these heat insulating materials 30, 32, and 34 are covered with a housing 35 made of a metal plate, and a heater 14 is embedded in the heat storage block 12. An intake port 36 and a blow port 38 are provided below the housing 35, and the fan 16 is installed in the intake port 36. The outside air OW taken in from the intake port 36 by the fan 16 is stored in the heat storage block 1.
While passing through the outer surface of No. 2, the air is heated and discharged from the air outlet 38.

Next, an example of a circuit configuration of the heat storage heater 10 is shown in FIG. The temperature measurement unit 25, the clock unit 23, the temperature rise pattern storage unit 22, and the power supply control unit 24 are configured by a programmed microcomputer 40. The microcomputer 40 includes a CPU 42, a ROM 44,
It comprises a RAM 46, an input interface 48, an output interface 50, and the like.

The input interface 48 includes a thermistor TH, operation switches SW1 to SWn, and an oscillation circuit 52.
Is connected. The thermistor TH has a positive characteristic in which the resistance value increases with an increase in temperature, is closely attached to the outer surface of the heat storage block 12, and outputs a voltage drop corresponding to the temperature of the heat storage block 12 to the temperature measuring unit 18. . The oscillation circuit 52 uses a crystal oscillator.
The reference pulse is oscillated and output to the clock unit 20.

The output interface 50 is connected to transistors Tr1 and Tr2 for driving the relay.
The heater 14 embedded in the heat storage block 12
Each is connected in parallel to a 0 V AC power supply 54. The normally open contact RY1a of the relay RY1 is interposed between the heater 14 and the AC current 54. Fan 16 is 100
V power supply 56. The normally open contact RY2a of the relay RY2 is interposed between the fan 16 and the AC power supply 56. A DC power supply 58 is connected to the AC power supply 56 to rectify the AC and obtain a DC voltage Vd. In addition,
The resistors R1 and R2 are for current limiting, and the resistor Rth is for voltage division.

The heat storage increasing operation section 11 of the embodiment (1) is configured to correspond to one of the SWs in FIG. 5, for example, SW1. When the user presses SW1, an ON signal is output from the output interface 50 to the transistor Tr1, and the transistor Tr1 is turned on. Then, the relay RY1 is driven to close the normally open contact RY1a, the heater 14 is energized, and the heat storage block 12 starts heating.

When the heat storage increasing operation section 11 is pressed again or a predetermined time has elapsed, the transistor Tr1 is turned off, the relay RY1 is opened, and the energization of the heater 14 is terminated.

As described above, in the embodiment (1) of the present invention, by providing the heat storage increasing function, when the heat storage amount becomes lower than the lower limit value outside the midnight power hours and the heat storage cannot be used as heating. In addition, heating can be performed by energizing the heater using normal power, and the inconvenience of interrupting heating can be eliminated. This eliminates the need to set the heat capacity of the heat storage block larger than necessary in case of emergency.
Since a heat storage heater that is just suitable for the space to be used can be installed, the cost burden on the user at the time of purchase is reduced. Further, since this heat storage increasing function is operated by the user's will, it is not necessary to use the heat storage function when it is not necessary to store the heat until using the relatively expensive normal power.

The heat storage heater 10 according to the embodiment (1)
Is suitable when using the same main line as the metered light and using daytime power (normal power) at a higher price, but using a time-based lighting system that makes nighttime power as cheap as midnight power.

Next, an embodiment (2) of the present invention will be described with reference to the drawings. FIG. 6 is a block diagram showing the embodiment (2), FIG. 7 is an explanatory diagram showing the functions of the embodiment (2), and FIG. 8 is a flowchart showing the operation of the embodiment (2). Since the basic configuration of the embodiment (2) is the same as that of the embodiment (1), the same description is given the same reference numeral and the detailed description is omitted.

The heat storage heater 10a of the embodiment (2)
A heat storage heater that heats the heat storage block using the midnight power during the midnight power time and heats by consuming the heat storage amount of the heat storage block, and the upper limit of the heat storage amount stored at the midnight power end time. The settings are adjustable.

In the embodiment (2), as a method of adjusting the upper limit value of the heat storage amount, a plurality of heating patterns in which the upper limit value of the heat storage amount is set in advance in advance are prepared.
The heat storage amount is adjusted by selecting a desired heating pattern from the above.

The configuration of the embodiment (2) has the same basic configuration as that of the embodiment (1), and also includes a temperature-raising-pattern operating section 13 for performing an operation for selecting a desired temperature-raising pattern.
And a heating pattern storage unit 22a provided in the control unit 21a and storing the plurality of heating patterns.

FIG. 7 shows an example of the heating pattern. In the embodiment (2), the temperature rising patterns E1 to E become linear with respect to the time t, and reach the upper limit value near the end time of the late-night power.
4 are stored. Heating pattern E
1, the upper limit is set to 100%, which is the maximum value of the heat storage amount, the heating pattern E2 is set to 80% of the maximum value, the heating pattern E3 is set to 60% of the maximum value, and the heating pattern E4 is set to 40% of the maximum value. ing. These heating patterns are examples showing that the upper limit value is set in a stepwise manner, and the number of types may be increased or decreased, or the pattern itself, the condition of the power supply control, or the like may be changed as appropriate.

Further, in the heating pattern operation section 13,
A display indicating the amount of stored heat in four stages from "small" to "large";
It has one operation button. As a selection operation, a method is used in which the temperature rising pattern is sequentially switched in accordance with a change in the display every time the operation button is pressed, and the display of the desired heat storage amount is confirmed to complete the setting. As described above, the user's convenience is improved by performing the operation of selecting from the four stages, and the setting and switching of the heat storage amount are reliably performed by performing the operation with one button. The operation of the heating pattern operation unit 13 is an example, and the operation is not limited to this. For example, the operation buttons may be made to correspond to the magnitude of the heat storage amount, or a dial-type knob may be used, or the upper limit value may be continuously adjusted without stepwise selection.

The circuit configuration of the embodiment (2) will be described with reference to FIG. 5 of the embodiment (1). The temperature rise pattern operation section 13 is set at an arbitrary position of SWn. Further, the heating pattern storage unit 22a stores the microcomputer 40
The temperature rise pattern is stored in the ROM 44 or the RAM 46.

The heat storage heater 10a of this embodiment (2)
Will be described with reference to FIGS. 7 and 8. FIG. First, the user selects a desired heating pattern from the heating patterns E1 to E4 (dotted lines) according to his / her preference, and the setting is performed by the heating pattern operation unit 13 [Step 201]. Here, for example, when selecting the heating pattern E3, the setting is performed by pressing the button several times in the heating pattern operation unit 13.
Next, the start time of the midnight power time is reached [Step 20].
2] and the temperature P of the heating pattern E3 at time t.
(T) is read from the temperature increase pattern storage unit 22a [Step 203], and the temperature M (t) of the heat storage block 12 at time t is measured by the temperature measurement unit 25 [Step 204].

Subsequently, the temperature P (t) is compared with the temperature M (t) [Step 205]. If P (t) <M (t), the process returns to Step 203. The temperature of the heat storage block 12 decreases with time t as indicated by the line A (solid line), but the temperature rise pattern increases with time t as indicated by the line E3. Then, when P (t) ≧ M (t), the power supply control unit 24 turns on the heater 14 [Step 206].
In this way, the temperature M (t) of the heat storage block 12 rises along the temperature rising pattern E3, and heat is stored up to 60% of the heat storage amount in the vicinity of the midnight power end time. When the end time of the midnight power comes (Step 207), the power supply control unit 24 turns off the heater 14 (Step 208).

Thus, the heat storage at 7:00 am is 60%
Is set to, the heater 14
Is started from time t3. In the case where the temperature rise pattern E1 of the heat storage amount of 100% is set, even in the state of the heat storage block indicated by the same line A, the operation is started from the time t1. Becomes unnecessary, and the power cost can be reduced.

Although the heat storage heater of the present invention has been described above as being divided into the embodiments (1) and (2), a synergistic effect can be exhibited by combining these into one heat storage heater. be able to. As a result, the setting options are expanded according to the temperature and the user's preference, the amount of heat storage can be controlled, and power saving can be achieved.

[0050]

As has been described in detail, in the heat storage heater of the present invention, when the stored heat falls below the lower limit value for heating outside the midnight power hours, the heat storage block is heated using the normal power. It is characterized by having an additional function.
Thus, even if the heat storage amount is insufficient outside the midnight power hours, the heat storage heating can be maintained without fear of interruption of the heating.

In addition, there is no need to design with a sufficient amount of required heat in preparation for a shortage of heat storage, and this has the effect of reducing the cost burden on the user when purchasing a heat storage heater. ing.

Further, since the heat storage increasing function is started only when the user operates the operation unit, it is not necessary to use the heat storage when it is not necessary to store the heat using the normal electric power. Burden can be reduced as much as possible.

Further, in the heat storage heater of the present invention, the setting of the upper limit of the heat storage amount stored during the midnight power end time can be adjusted. Accordingly, when the heat storage amount stored in the heat storage block is not sufficiently consumed, the upper limit value of the heat storage amount can be set lower in order to obtain a heat storage amount that is proportional to the consumption amount. Power consumption can be reduced, and power can be saved.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment (1).

FIG. 2 is an explanatory diagram showing functions of the embodiment (1).

FIG. 3 is a flowchart showing an operation of the embodiment (1).

FIG. 4 is a cross-sectional view illustrating an example of a heat storage heater according to Embodiment (1).

FIG. 5 is a circuit diagram illustrating an example of a circuit configuration of Embodiment (1).

FIG. 6 is a block diagram showing an embodiment (2).

FIG. 7 is an explanatory diagram showing functions of the embodiment (2).

FIG. 8 is a flowchart showing the operation of the embodiment (2).

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Heat storage heater 11 Heat storage increasing operation part 12 Heat storage block 13 Heating pattern operation part 14 Heater 16 Fan 21 Control part 22 Heating pattern storage part 23 Clock part 24 Power supply control part 25 Temperature measuring part 26 Heat storage increasing control part

────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] October 26, 2000 (2000.10.
26)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Brief description of drawings

[Correction method] Change

[Correction contents]

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment (1).

FIG. 2 is an explanatory diagram showing functions of the embodiment (1).

FIG. 3 is a flowchart showing an operation of the embodiment (1).

FIG. 4 is a cross-sectional view illustrating an example of a heat storage heater according to Embodiment (1).

FIG. 5 is a circuit diagram illustrating an example of a circuit configuration of Embodiment (1).

FIG. 6 is a block diagram showing an embodiment (2).

FIG. 7 is an explanatory diagram showing functions of the embodiment (2).

FIG. 8 is a flowchart showing the operation of the embodiment (2).

FIG. 9 is an explanatory diagram showing characteristics of a heat storage heater.

[Description of Signs] 10 Heat storage heater 11 Heat storage increasing operation unit 12 Heat storage block 13 Heating pattern operation unit 14 Heater 16 Fan 21 Control unit 22 Heating pattern storage unit 23 Clock unit 24 Power supply control unit 25 Temperature measurement unit 26 Heat storage increase Control unit ──────────────────────────────────────────────── ─────

[Procedure amendment]

[Submission date] November 30, 2001 (2001.11.
30)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of the Invention] Heat storage heater

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a heat storage heater using midnight power.

[0002]

2. Description of the Related Art In order to eliminate the imbalance between daytime and nighttime power load factors, each electric power company provides a service in which a late-night electric power time zone is set and a unit price of electric power is set at a low price. Therefore, conventionally, heat is stored in the heat storage block using the midnight power, and heating is performed in the daytime using the heat storage block as a heat source. Note that the midnight power time zone here will be described as a time zone from 11:00 pm to 7:00 am in the following description, but since the set time may vary depending on the power company, it is limited to only this time zone. Not something.

Conventionally, this type of heat storage heater has a heat storage block for storing heat, a heater for heating the heat storage block,
The air conditioner was provided with a fan that ventilates the heat storage block and sends warm air into the room, and a control unit that turns off the heater when the temperature of the heat storage block exceeds the upper limit. Then, at midnight power time, the heater is turned on to store heat in the heat storage block, and during use in the daytime or the like, natural heat is radiated from the heat storage block,
Alternatively, a fan is operated to ventilate the heat storage block to generate warm air, which has been used as heating.

[0004] The heat storage heater described above has, for example, characteristics as shown in FIG. The amount of heat stored in the heat storage block using the late-night electric power is gradually reduced by being used as a heat source for heating, and thus is reduced, for example, by drawing a curve as indicated by the line A (solid line). And
Start time of midnight power (11 pm
Time). In the heat storage heater, a heating pattern of the E line (dotted line) set so that the heat storage amount becomes 100% near the end time of the late night power (7:00 am) is stored in advance. Therefore, at the time of the point P where the line A and the line E intersect, that is, at the time t determined according to the remaining amount of heat storage, the power supply to the heater is started, and the heating is performed so as to follow the temperature rising pattern of the line E. The energization control is performed, and the heat storage amount increases. By this energization control, efficient heat storage was performed while suppressing waste of power.

[0005]

However, in the case where the consumption of heat storage is intense due to factors such as the difference from the temperature is too large,
For example, draw a curve like the B line (dash-dot line)
Before 1 o'clock, there was a case where the value fell below the lower limit (heat storage amount capable of heating). However, since the conventional thermal storage heater is configured to store heat using only cheap midnight power, in such a case, the time zone of the part C in which the heating by the thermal storage heater cannot be used occurs. Therefore, there is a problem that a sufficient heating effect cannot be obtained.

[0006] In order to avoid such a problem, a heating design is generally made with an allowance of 20 to 40% for a necessary heat quantity in case of a shortage of heat storage. However, this method uses a heat storage heater one rank larger in consideration of safety than a heat storage heater with a heat capacity suitable for the space actually used. Has a problem that the physical burden increases.

In a relatively high temperature period such as early spring, the difference between the temperature of the heat storage block and the air temperature is small, so that the amount of heat storage consumed is small, and a curve such as a D-line (two-dot chain line) is formed. I sometimes draw. In this case, even if 100% of the heat storage block is stored every morning at the end of the midnight power time zone, the amount of stored heat is not sufficiently used and the power used for the heat storage is wasted. I was

[0008] In consideration of such conventional problems, the present invention can be used as heating even when the amount of heat stored in the heat storage block is insufficient outside midnight power hours, while saving power and reducing cost. It is another object of the present invention to provide a heat storage heater that can make full use of the stored heat amount without waste.

[0009]

Means for Solving the Problems In order to solve the above problems, the heat storage heater of the present invention employs the following means.

That is, in the first aspect of the present invention, there is provided a heat storage heater that heats a heat storage block using midnight power during a midnight power time and heats the heat by consuming the heat storage amount of the heat storage block. When the stored heat amount falls below the minimum heat storage amount that can be heated, the storage unit has a heat storage increasing function of heating the heat storage block using normal power, and an operation unit for starting the heat storage function is provided. .

According to this means, when the heat storage amount becomes less than the minimum heat storage amount that can be heated outside the midnight power time and heating cannot be performed, the normal heat power which is not the midnight power is intentionally used by the heat storage increasing function. The heating effect is maintained by heating the block to increase the amount of stored heat. Further, since the heat storage increasing function uses expensive normal power, the heating of the heat storage block is started only by operating the operation unit by the user's will.

According to a second aspect of the present invention, in the thermal storage heater according to the first aspect, a switch is provided in the operation unit, and a heat storage increasing function is started by a first operation of the switch, and a heat storage increasing function is performed by a second operation. The function is released.

According to this means, the start and release of the heat storage increasing function are reliably performed.

According to a third aspect of the present invention, in the heat storage heater according to the first or second aspect, the heat storage increasing function is automatically released after a lapse of a predetermined time from the start.

In this means, since the heat storage increasing function is automatically released after the lapse of the predetermined time, it is possible to prevent unnecessary power consumption due to forgetting to release the function.

According to a fourth aspect of the present invention, there is provided a heat storage heater that heats a heat storage block by using midnight power during a midnight power time and heats the heat storage block by consuming the amount of heat stored in the heat storage block. Is adjusted by selecting from among a plurality of upper limit values set in stages.

With this means, even if the heat storage block is 100% stored at the end of midnight power, if the amount of stored heat is not sufficiently consumed, the upper limit of the amount of stored heat is adjusted to a lower value to perform the heat storage. As a result, the amount of heat stored by the midnight power is utilized. Further, the heat storage amount is adjusted only by selecting from the upper limit values set in advance in stages, so that the operability of the user is improved. Note that the upper limit here means the value of the heat storage amount reached by the energization control near the midnight power end time at 7:00 am, and the maximum heat storage amount that can be stored in the heat storage block is 100%. , 0-
It is a value determined by a value between 100%.

Hereinafter, a basic embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows an embodiment (1).
FIG. 2 is an explanatory diagram showing the function of the embodiment (1), FIG. 3 is a flowchart showing the operation of the embodiment (1), and FIG. 4 is a block diagram of the heat storage heater of the embodiment (1). FIG. 5 is a cross-sectional view illustrating an example, and FIG. 5 is a circuit diagram illustrating an example of the circuit configuration of Embodiment (1).

The heat storage heater 10 of the embodiment (1) heats the heat storage block 12 by using the midnight power during the midnight power time, and heats the heat by consuming the heat stored in the heat storage block 12. In addition, when the stored heat amount falls below the minimum heat storage amount that can be heated outside the midnight power hours, the power storage function is provided to heat the heat storage block 12 using normal power.

The basic configuration of the heat storage heater 10 is the same as that of the conventional heat storage heater, and includes a heat storage block 12 for storing heat and storing heat, a heater 14 for heating the heat storage block 12, and a heat storage block 12. A fan 16 that ventilates and sends warm air into the room, and a control unit 21 that controls energization of the heater 14 are provided. The control unit 21 includes a temperature-raising-pattern storing unit 22 that previously stores a temperature-raising pattern of the heat storage block 12 that rises with time and has a predetermined heat storage amount near the end time of late-night power; A clock unit 23 that outputs information, an energization control unit 24 that controls energization of the heater, and a temperature measurement unit 25 that measures the temperature of the heat storage block 12 are provided.

In addition to the basic configuration described above, in the heat storage heater 10 of the embodiment (1), as a heat storage increasing function, a heat storage increasing operation unit 11 for performing an on / off operation of the heat storage increasing function, The control unit 21 includes a heat storage increasing control unit 26 that turns on and off the power supply to the heater 14 by operating the heat storage increasing operation unit 11. This heat storage increase function is available outside of midnight power hours (from 7:00 am to 11 pm
When the amount of heat storage required for heating is insufficient at the time of), power is supplied to the heater 14 by using normal power, and the heat storage block 12 is heated to increase the amount of heat storage. .

The heat storage increasing function may be configured to be started automatically when the heat storage amount falls below the minimum heat storage amount that can be heated. Since the time zone is a time zone in which an expensive electricity rate is set as the normal power, the start of the heat storage increasing function is preferably determined by the user's will. Therefore, a heat storage increasing operation unit 11 for performing an artificial operation is provided. Further, as the on / off operation of the heat storage increasing operation unit 11, a toggle type switch is preferable.
By configuring so that the heat storage increasing function is started by the first pressing operation and released by the second pressing operation, the start and the release are reliably performed.

When the heat storage increasing operation unit 11 is turned on in the heat storage increasing control unit 26, time information is input from the clock unit 23. Then, after it is determined that the current time is outside the midnight power time, the power supply to the heater 14 is started. Further, the heat storage increasing operation unit 11 is provided with a timer function. When a predetermined time, for example, 3 hours, has elapsed from the time when the heat storage increasing operation unit 11 is operated, the power supply to the heater 14 is stopped. As a result, it is possible to prevent the user from forgetting to turn off the heat storage increasing function and wastefully consuming the expensive power. Of course, before the predetermined time elapses, the heat storage increasing operation unit 1
1 is turned off, the heater 14 is turned on by the user's will.
It is also possible to stop energizing the power supply. Further, when the heat storage increasing function is turned on, the heater 14 may be energized after confirming the actual heat storage amount, thereby preventing erroneous operation of the heat storage enhancement function.

Heat storage heater 1 having the function of increasing heat storage described above
The operation of 0 will be described with reference to FIGS. Outside the midnight power hours, normally, the heat storage block 12, which stores 100% of the heat at 7:00 am, performs natural heat radiation or forced heat radiation using the fan 16, so that the heat storage amount gradually decreases. When the curve of this decrease draws a sharp decrease curve like the B line (dash-dot line) in FIG. 2 and becomes less than the minimum heat storage amount that can be used and cannot be used as heating, the heat storage increases at point P1. The operation unit 11 is operated and turned on [Step 101]. Next, the heat storage increasing operation unit 1
When the time when 1 is turned on is measured by the clock unit 23 and it is determined that it is outside the midnight power time [Step 102], the heater 14 is turned on and the power supply to the heat storage block 12 is started [Step 103]. As a result, the heat storage amount rises from the point P1, and heating is performed by forced heat radiation or natural heat radiation by the fan 16. The point P1 is a point at which the time is determined according to the user's will after falling below the minimum heat storage amount that can be heated.

Next, it is determined whether a predetermined time has elapsed or whether the heat storage increasing operation unit has been operated for the second time (steps 105 and 106). At any point P2, the function of increasing heat storage is released, and the heater 14 is turned off [Step 107]. Thereafter, as shown by the G line, heating is performed by forced heat radiation or natural heat radiation by the fan 16, and the heat storage amount is gradually consumed.

Then, similarly to the conventional case, when the midnight power start time comes, the start time of the temperature rise pattern is determined according to the remaining heat storage amount, and the heat storage amount becomes 100% from the point P to the vicinity of the midnight power end time. The energization control to the heater 14 is performed so as to be as follows.

FIG. 4 shows an example of the overall configuration of the heat storage heater 10.
Shown in The side surface, the upper surface, and the lower surface of the heat storage block 12 are covered with heat insulating materials 30, 32, and 34, respectively. The outer surfaces of these heat insulating materials 30, 32, and 34 are covered with a housing 35 made of a metal plate, and a heater 14 is embedded in the heat storage block 12. An intake port 36 and a blow port 38 are provided below the housing 35, and the fan 16 is installed in the intake port 36. The outside air OW taken in from the intake port 36 by the fan 16 is stored in the heat storage block 1.
While passing through the outer surface of No. 2, the air is heated and discharged from the air outlet 38.

Next, an example of a circuit configuration of the heat storage heater 10 is shown in FIG. The temperature measurement unit 25, the clock unit 23, the temperature rise pattern storage unit 22, and the power supply control unit 24 are configured by a programmed microcomputer 40. The microcomputer 40 includes a CPU 42, a ROM 44,
It comprises a RAM 46, an input interface 48, an output interface 50, and the like.

The input interface 48 includes a thermistor TH, operation switches SW1 to SWn, and an oscillation circuit 52.
Is connected. The thermistor TH has a positive characteristic in which the resistance value increases with an increase in temperature, is closely attached to the outer surface of the heat storage block 12, and outputs a voltage drop corresponding to the temperature of the heat storage block 12 to the temperature measuring unit 18. . The oscillation circuit 52 uses a crystal oscillator.
The reference pulse is oscillated and output to the clock unit 20.

The output interface 50 is connected to transistors Tr1 and Tr2 for driving the relay.
The heater 14 embedded in the heat storage block 12
Each is connected in parallel to a 0 V AC power supply 54. The normally open contact RY1a of the relay RY1 is interposed between the heater 14 and the AC current 54. Fan 16 is 100
V power supply 56. The normally open contact RY2a of the relay RY2 is interposed between the fan 16 and the AC power supply 56. A DC power supply 58 is connected to the AC power supply 56 to rectify the AC and obtain a DC voltage Vd. In addition,
The resistors R1 and R2 are for current limiting, and the resistor Rth is for voltage division.

The heat storage increasing operation unit 11 of the embodiment (1) is configured to correspond to one of the SWs in FIG. 5, for example, SW1. When the user presses SW1, an ON signal is output from the output interface 50 to the transistor Tr1, and the transistor Tr1 is turned on. Then, the relay RY1 is driven to close the normally open contact RY1a, the heater 14 is energized, and the heat storage block 12 starts heating.

When the heat storage increasing operation section 11 is pressed again or a predetermined time has elapsed, the transistor Tr1 is turned off, the relay RY1 is opened, and the energization of the heater 14 is terminated.

As described above, in the embodiment (1) of the present invention, by providing the heat storage increasing function, the heat storage amount becomes lower than the minimum heat storage amount that can be heated outside the midnight power hours, and the heat storage function is used for heating. In the case where the heating cannot be performed, the heater can be energized by using the normal electric power to perform the heating, and the disadvantage that the heating is interrupted can be solved. This eliminates the need to set the heat capacity of the heat storage block to an unnecessarily large value in preparation for an emergency, and allows the installation of a heat storage heater that is just suitable for the space to be used. Burden is reduced. Further, since this heat storage increasing function is operated by the user's will, it is not necessary to use the heat storage function when it is not necessary to store the heat until using the relatively expensive normal power.

The heat storage heater 10 of the embodiment (1)
Is suitable when using the same main line as the metered light and using daytime power (normal power) at a higher price, but using a time-based lighting system that makes nighttime power as cheap as midnight power.

Next, an embodiment (2) of the present invention will be described with reference to the drawings. FIG. 6 is a block diagram showing the embodiment (2), FIG. 7 is an explanatory diagram showing the functions of the embodiment (2), and FIG. 8 is a flowchart showing the operation of the embodiment (2). Since the basic configuration of the embodiment (2) is the same as that of the embodiment (1), the same description is given the same reference numeral and the detailed description is omitted.

The heat storage heater 10a of the embodiment (2)
A heat storage heater that heats the heat storage block using the midnight power during the midnight power time and heats by consuming the heat storage amount of the heat storage block, and the upper limit of the heat storage amount stored at the midnight power end time. The settings are adjustable.

In the embodiment (2), as a method of adjusting the upper limit value of the heat storage amount, a plurality of heating patterns in which the upper limit value of the heat storage amount is set in advance in advance are prepared.
The heat storage amount is adjusted by selecting a desired heating pattern from the above.

The configuration of the embodiment (2) has the same basic configuration as that of the embodiment (1), but also includes a heating pattern operation unit 13 for performing an operation for selecting a desired heating pattern.
And a heating pattern storage unit 22a provided in the control unit 21a and storing the plurality of heating patterns.

FIG. 7 shows an example of the heating pattern. In the embodiment (2), the temperature rising patterns E1 to E become linear with respect to the time t, and reach the upper limit value near the end time of the late-night power.
4 are stored. Heating pattern E
1, the upper limit is set to 100%, which is the maximum value of the heat storage amount, the heating pattern E2 is set to 80% of the maximum value, the heating pattern E3 is set to 60% of the maximum value, and the heating pattern E4 is set to 40% of the maximum value. ing. These heating patterns are examples showing that the upper limit value is set in a stepwise manner, and the number of types may be increased or decreased, or the pattern itself, the condition of the power supply control, or the like may be changed as appropriate.

In the temperature rise pattern operation section 13,
A display indicating the amount of stored heat in four stages from "small" to "large";
It has one operation button. As a selection operation, a method is used in which the temperature rising pattern is sequentially switched in accordance with a change in the display every time the operation button is pressed, and the display of the desired heat storage amount is confirmed to complete the setting. As described above, the user's convenience is improved by performing the operation of selecting from the four stages, and the setting and switching of the heat storage amount are reliably performed by performing the operation with one button. The operation of the heating pattern operation unit 13 is an example, and the operation is not limited to this. For example, the operation buttons may be made to correspond to the magnitude of the heat storage amount, or a dial-type knob may be used, or the upper limit value may be continuously adjusted without stepwise selection.

The circuit configuration of the embodiment (2) will be described with reference to FIG. 5 of the embodiment (1). The temperature rise pattern operation section 13 is set at an arbitrary position of SWn. Further, the heating pattern storage unit 22a stores the microcomputer 40
The temperature rise pattern is stored in the ROM 44 or the RAM 46.

The heat storage heater 10a of this embodiment (2)
Will be described with reference to FIGS. 7 and 8. FIG. First, the user selects a desired heating pattern from the heating patterns E1 to E4 (dotted lines) according to his / her preference, and the setting is performed by the heating pattern operation unit 13 [Step 201]. Here, for example, when selecting the heating pattern E3, the setting is performed by pressing the button several times in the heating pattern operation unit 13.
Next, the start time of the midnight power time is reached [Step 20].
2] and the temperature P of the heating pattern E3 at time t.
(T) is read from the temperature increase pattern storage unit 22a [Step 203], and the temperature M (t) of the heat storage block 12 at time t is measured by the temperature measurement unit 25 [Step 204].

Subsequently, the temperature P (t) is compared with the temperature M (t) [Step 205]. If P (t) <M (t), the process returns to Step 203. The temperature of the heat storage block 12 decreases with time t as indicated by the line A (solid line), but the temperature rise pattern increases with time t as indicated by the line E3. Then, when P (t) ≧ M (t), the power supply control unit 24 turns on the heater 14 [Step 206].
In this way, the temperature M (t) of the heat storage block 12 rises along the temperature rising pattern E3, and heat is stored up to 60% of the heat storage amount in the vicinity of the midnight power end time. When the end time of the midnight power comes (Step 207), the power supply control unit 24 turns off the heater 14 (Step 208).

Thus, the heat storage at 7:00 am is 60%
Is set to, the heater 14
Is started from time t3. In the case where the temperature rise pattern E1 of the heat storage amount of 100% is set, even in the state of the heat storage block indicated by the same line A, the operation is started from the time t1. Becomes unnecessary, and the power cost can be reduced.

Although the heat storage heater of the present invention has been described above as being divided into the embodiments (1) and (2), a synergistic effect can be exhibited by combining these into one heat storage heater. be able to. As a result, the setting options are expanded according to the temperature and the user's preference, the amount of heat storage can be controlled, and power saving can be achieved.

[0046]

As has been described in detail, in the heat storage heater of the present invention, when the stored heat falls below the minimum heat storage amount that can be heated outside the midnight power hours, the heat storage block is operated using the normal power. It is characterized by having a function of increasing heat storage for heating. Thus, even if the heat storage amount is insufficient outside the midnight power hours, the heat storage heating can be maintained without fear of interruption of the heating.

In addition, there is no need to design with a sufficient amount of required heat in preparation for a shortage of heat storage, and the effect of reducing the cost burden on the user when purchasing a heat storage heater is also provided. ing.

Further, since the heat storage increasing function is started only when a user operates the operation unit, it is not necessary to use the heat storage when it is not necessary to store the heat until normal power is used. Burden can be reduced as much as possible.

Further, in the heat storage heater of the present invention, the setting of the upper limit of the amount of heat stored at the end of the midnight power can be adjusted. With this, when the heat storage amount stored in the heat storage block is not sufficiently consumed, the upper limit value of the heat storage amount can be set lower in order to obtain a heat storage amount commensurate with the consumption amount. Power consumption can be reduced, and power can be saved.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment (1).

FIG. 2 is an explanatory diagram showing functions of the embodiment (1).

FIG. 3 is a flowchart showing an operation of the embodiment (1).

FIG. 4 is a cross-sectional view illustrating an example of a heat storage heater according to Embodiment (1).

FIG. 5 is a circuit diagram illustrating an example of a circuit configuration of Embodiment (1).

FIG. 6 is a block diagram showing an embodiment (2).

FIG. 7 is an explanatory diagram showing functions of the embodiment (2).

FIG. 8 is a flowchart showing the operation of the embodiment (2).

FIG. 9 is an explanatory diagram showing a conventional function.

[Description of Signs] 10 Heat storage heater 11 Heat storage increasing operation unit 12 Heat storage block 13 Heating pattern operation unit 14 Heater 16 Fan 21 Control unit 22 Heating pattern storage unit 23 Clock unit 24 Power supply control unit 25 Temperature measurement unit 26 Heat storage increase Control unit

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Masayuki Kikuchi 3-18-14 Takada, Toshima-ku, Tokyo F-term in Hakusan Works 3L072 AA05 AC02 AD06 AE10 AF00 AG07

Claims (6)

[Claims] 1. A heat storage heater that heats a heat storage block using midnight power during a midnight power time and heats the heat by consuming the amount of heat stored in the heat storage block. A heat storage heater having a heat storage increasing function of heating a heat storage block using normal electric power when the temperature falls below a possible lower limit. 2. The heat storage heater according to claim 1, further comprising an operation unit for starting a heat storage increasing function. 3. The heat storage heater according to claim 2, wherein a switch is provided in the operation unit, a heat storage increasing function is started by a first operation of the switch, and the heat storage increasing function is released by a second operation. A heat storage heater characterized in that: 4. The heat storage heater according to claim 1, wherein the heat storage increasing function is automatically canceled after a lapse of a predetermined time from the start. 5. A heat storage heater that heats a heat storage block using midnight power during a midnight power time and heats the heat by consuming the amount of heat stored in the heat storage block, wherein the heat storage is stored during a midnight power end time. Heat storage heater with adjustable upper limit setting. 6. The heat storage device according to claim 5, wherein the amount of heat stored during the midnight power end time is adjusted by being selected from a plurality of upper limit values set in stages. Heat storage heater characterized.