JPH074751A - Cooking table with solar heat collector - Google Patents

Abstract

PURPOSE:To realize a clean energy-based cooking table by transmitting heat to a cooker, etc., through the heat medium collected by a solar heat collector. CONSTITUTION:When a solar heat collector 6 receives solar heat to thereby raise the heat medium therein to a high temp., a high temp. sensor 21 provided on the side of a high temp. passage 61 detects temp. T1 and a low temp. sensor 22 provided in a heat reserving device 1 detects temp. T0 therein. These data detected are sent to a control means 2 where a computation is made. When the value of the difference T1-T0 between the high temp. T1 and the low temp. T0 reaches at least a predetermined value or a predetermined temp. condition is met, the control means 2 sends a signal to a motor 31 to drive a pump 3 in order that a high temp. heat medium may be introduced from the solar heat collector 6 into the heat reserving device 1. In this method, a clean energy- based cooking table can be realized.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooking table having a heat source accumulated by a heat storage method, and more particularly, it transfers heat to a cooker or the like via a heat medium collected by a solar heat collecting device. It is related to the device.

[0002]

2. Description of the Related Art A conventional cooking table uses gas as its heat source,
Most of them use energy such as electricity.

[0003]

By the way, in most of the above-mentioned conventional devices, a heat source is generated by burning fossil fuel or the like. Therefore, carbon dioxide gas (CO ₂ ) must be generated as the heat source is generated.
Will be generated. As a result, there are problems such as global warming due to CO ₂ which have recently been taken up as an environmental problem. Therefore, it is an attempt to provide a cooking table based on clean energy, which is intended to solve the problems such as global warming due to the generation of CO ₂ .
It is an object (problem) of the present invention.

[0004]

In order to solve the above-mentioned problems, the following measures are taken in the present invention. That is, with respect to a cooking table having a heat source to be supplied to a cooker or the like, a double tank including an outer case and an inner case is provided, an insulating layer is provided between the double tanks, and the double tank is sealed. And also has a heat transfer plate that plays a role of transmitting the heat accumulated in the double tank to the cooker, and also has a diffuser for discharging a heat medium into the double tank formed by these. Further, a heat storage device having a drain passage for discharging the heat medium discharged from the diffuser from the inside of the double tank, a solar heat collector for generating a heat source to be supplied to the heat storage device, and these solar heat collectors. When a pipe consisting of a high temperature path and a low temperature path for flowing a heat medium between the device and the heat storage device, a pump provided in the middle of the low temperature path for recirculating the heat medium, and a temperature of the circulating heat medium is measured. Tomo And control means for controlling the operation and the like of the pump by sensing the temperature condition regarding the heat transfer medium,
It was decided to adopt a configuration consisting of.

[0005]

By adopting the above construction, the following effects are exhibited in the present invention. First, in FIG. 1, when the solar heat collecting device 6 receives solar heat and the heat medium in the solar heat collecting device 6 reaches a constant temperature (high temperature), the high temperature sensor 21 provided on the high temperature path 61 side concerned. Temperature (T
₁ ) is detected (measured), and the low temperature sensor 22 provided in the heat storage device 1 detects the temperature (T
₀ ) is detected (measured). These data are the control means 2
Is sent to, and arithmetic processing is performed there. As a result, the difference between the high temperature (T ₁ ) and the low temperature (T ₀ ), that is, T ₁
When the value of −T ₀ becomes a predetermined value or more, or when a predetermined temperature condition is satisfied, the control means 2 causes the motor to introduce a high-temperature heat medium from the solar heat collecting device 6 side into the heat storage device 1. 31 to send a signal to the motor 31 to pump 3
Control action to drive the.

As a result, the heat medium (liquid) existing in the heat storage device 1 is sucked from the drain passage 18 by the pump 3 and sent out to the solar heat collecting device 6 via the low temperature passage 62, where solar heat is collected. Upon receiving it, it becomes hot. By repeating these series of cycles, the heat medium becomes high-temperature steam and is discharged into the heat storage device 1 through the diffuser 16. As a result, the inside of the heat storage device 1 is in a high temperature state. Particularly in the present invention, since the temperature inside the solar heat collector 6 is raised to a state of 200 ° to 300 ° C, the circulating heat medium is also heated to this temperature in the high temperature passage 61.

As shown in FIGS. 1 and 2, the heat storage device 1 from which these heat mediums are discharged comprises double tanks 11 and 13 having a heat insulating layer 12 therebetween, and the heat transfer plate 4 is also provided. It is configured to be sealed by. Therefore, the inside of the heat storage device 1 is also raised to a temperature of 200 ° to 300 ° C., which is almost the same as the temperature of the heat medium. Such high-temperature heat is transferred via the heat transfer plate 4 to the cooking device 9 or the like installed on the heat transfer plate 4. Therefore, in the present invention, by utilizing the solar heat (energy) collected by the solar heat collecting device 6, the cooker 9 and the like can be sufficiently heated,
It is possible to cook food with clean energy.

As shown in FIG. 1, the heat storage device 1 of the present invention is provided with the auxiliary heater 51 as an auxiliary heat source device, so that the solar heat collecting device 6 functions at night or in cloudy weather. Even when the heat storage device 1 cannot be operated, the heat medium (liquid) staying in the heat storage device 1 is directly warmed by the auxiliary heater 51 or the like by the operation of the control means 2, whereby the inside of the heat storage device 1 is heated. It can be maintained at a high temperature.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT An embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 1, the configuration of the present embodiment has a heat storage device 1 including a double tank of an outer case 11 and an inner case 13 and a heat insulating layer 12 provided between the double tanks, and the heat storage device. 1. The solar heat collector 6 serving as a generation base of the heat source to be supplied to the No. 1 and the solar heat collector 6 concerned.
And a pump 3 that circulates a heat medium between the heat storage device 1 and the heat storage device 1, and detects (measures) the temperature of the heat medium in each of the solar heat collector 6 and the heat storage device 1, and based on the measurement result, It is basically composed of a control means 2 for controlling the operation of the pump 3 and the like.

In the above structure, the solar heat collecting device 6 is
It is a heat exchange type formed by a double type vacuum glass pipe or the like, which is already known. Then, from these solar heat collecting devices 6, a high temperature path 61 for sending the heat medium (steam) heated to high temperature in the solar heat collecting device 6 to the heat storage device 1, and the low temperature heat medium from the heat storage device 1. The low temperature path 62 for returning the (liquid) is provided. A high temperature sensor 21 that detects (measures) the temperature of the heat medium in the high temperature path 61 and transmits the detection result to the control unit 2 is provided on the high temperature path 61 side. is there.

As shown in FIGS. 1 and 2, the heat storage device 1 to which high-temperature heat energy is supplied from the solar heat collecting device 6 having the above-mentioned structure has an outer case 11 and an inner case 13.
And a heat insulating layer (insulator) 12 made of a heat insulating material is provided between the double tanks. A heat transfer plate 4 is provided on the upper side of such a double tub to seal the double tub and also to transfer the heat energy accumulated in the double tub to the cooking device 9 or the like. It has the same structure as that described above. Further, the heat storage device 1 composed of the double tank is connected to a high temperature path 61 for supplying the high temperature heat medium (steam or the like) from the solar heat collector 6 to the heat storage device 1, and further, the high temperature The passage 61 is provided with a diffuser 16 that releases a high-temperature heat medium into the heat storage device 1. Further, the drain passage 18 for discharging the heat medium (liquid) in a low temperature state after being discharged from the diffuser 16 from the heat storage device 1 is provided.

Further, the heat storage device 1 is provided with a pressure gauge 17 (see FIG. 2) for detecting the pressure in the heat storage device 1, and the internal pressure does not exceed a certain value. A pressure adjusting valve 15 for adjusting the pressure is provided. Further, the water level gauge 14 is provided to detect the water level in the heat storage device 1 and to operate to supply water when the water level falls below the standard water level. Further, the heat storage device 1
A low temperature sensor 22 that detects (measures) the temperature of the heat medium inside and transmits the detection result to the control unit 2 is provided.
Further, in the heat storage device 1, there is provided an auxiliary heater 51 as an auxiliary heat source device that operates when heat energy cannot be collected from the solar heat collecting device 6 at night or in cloudy weather. It is composed of The auxiliary heater 51 is composed of an electric heater or the like that operates by electric power from a power source 52 or the like.

A pump 3 which circulates a heat medium between the heat storage device 1 and the solar heat collecting device 6 having the above structures is provided in the middle of a low temperature passage 62 connected to the drain passage 18. The pump 3 is configured to be driven by a motor 31 which is controlled based on the control action of the control means 2 described later.

Further, the temperature of the heat medium in the heat storage device 1 and the solar heat collecting device 6 having the above-mentioned configurations is measured, and the motor 31 for driving the pump 3 is controlled based on the measurement result. The auxiliary heater 51
Is provided with a control means 2 for controlling the operation of the device, and the control means 2 is a microprocessor unit (MPU).
It is formed mainly of a computer including the above.

The operation and the like of this embodiment having the above configuration will be described. First, in FIG. 1, when the solar heat collecting device 6 receives solar heat and the heat medium in the solar heat collecting device 6 reaches a constant temperature (high temperature), the high temperature sensor 21 provided on the high temperature passage 61 side The temperature (T ₁ ) is detected (measured)
At the same time, the temperature (T ₀ ) in the heat storage device 1 is detected (measured) from the low temperature sensor 22 provided in the heat storage device 1. These data are sent to the control means 2 where arithmetic processing is performed. As a result, the high temperature (T
₁ ) and the low temperature (T ₀ ), that is, when the value of T ₁ −T ₀ becomes a predetermined value or more, or when a predetermined temperature condition is satisfied, high temperature heat from the solar heat collecting device 6 side. In order to introduce the medium into the heat storage device 1, the control means 2 uses the motor 31
To control the motor 3 so as to drive the pump 3.

As a result, the heat medium (liquid) existing in the heat storage device 1 is sucked from the drain passage 18 by the pump 3 and sent out to the solar heat collecting device 6 via the low temperature passage 62, and at the same time, the solar heat is collected. After receiving the high temperature state, the high temperature state is returned to the heat storage device 1 via the high temperature path 61. By repeating these series of cycles,
The heat medium becomes high-temperature steam and is discharged into the heat storage device 1 through the diffuser 16. As a result, the inside of the heat storage device 1 is in a high temperature state. Particularly in the present embodiment, the temperature inside the solar heat collector 6 is raised to a state of 200 ° to 300 ° C., so that the circulating heat medium is also heated to this temperature in the high temperature passage 61.

As shown in FIGS. 1 and 2, the heat storage device 1 from which these heat mediums are discharged is composed of double tanks 11 and 13 having a heat insulating layer 12 therebetween, and a heat transfer plate 4 is also provided. The heat storage device 1 is heated to a temperature of 200 ° to 300 ° C., which is almost the same as the temperature of the heat medium. Such high-temperature heat is transferred to the cooker 9 and the like installed on the heat transfer plate 4 via the heat transfer plate 4. Therefore, in this embodiment, the solar heat (energy) collected by the solar heat collecting apparatus 6 can be used to sufficiently heat the cooker 9 and the like, and cooking energy can be used for cooking food and the like. can do.

Further, in this embodiment, when the solar heat collecting device 6 cannot be operated at night or in cloudy weather, the heat accumulated in the heat storage device 1 is activated by the operation of the control means 2. The medium (liquid) can be heated directly by the auxiliary heater 51 or the like, whereby the inside of the heat storage device 1 can be maintained in a high temperature state.

As the auxiliary heat source device, a heat storage type device as shown in FIG. 3 can be considered. The auxiliary heat source device 5 basically has a separate heat storage tank 55, and a lithium compound such as lithium hydroxide is enclosed in the heat storage tank 55. The heat storage tank 55 having such a configuration is connected to the heat storage device 1 via the heat storage path 57 and the heat radiation path 58, and a control signal from the control means 2 is provided in the middle of the heat radiation path 58. The fan 59 that operates based on the above is provided.

In the auxiliary heat source device 5 having such a structure, first, when the temperature inside the heat storage device 1 is in a high temperature state, heat energy is transferred from the heat storage device 1 side via the heat storage path 57 to the heat storage device. The heat is propagated to the material 56 and stored in the heat storage material 56. Next, the solar heat collector 6 at night, etc.
When the heat energy cannot be collected from the side, the fan 59 is operated by the operation of the control means 2, the heat energy stored in the heat storage material 56 is taken out, and the heat energy is stored in the heat radiation path 58. , Is released into the heat storage device 1. As a result, the cooking function of the heat storage device 1 can be exerted even when the solar heat collector 6 cannot operate at night.

[0021]

According to the present invention, with respect to a cooking table having a heat source to be supplied to a cooking device or the like, a double tank composed of an outer case and an inner case is provided, and a heat insulating layer is provided between the double tanks. , Further has a heat transfer plate that seals the double tank and transfers the heat accumulated in the double tank to the cooker, and the heat is stored in the double tank formed by these. A heat storage device having a diffuser for discharging the medium, and further having a drain passage for discharging the heat medium discharged from the diffuser from the inside of the double tank, and a solar generator for generating a heat source to be supplied to the heat storage device. A heat collecting device, a pipe consisting of a high temperature path and a low temperature path for flowing the heat medium between the solar heat collecting apparatus and the heat accumulating device, a pump provided in the middle of the low temperature path for refluxing the heat medium, and these. Circulating heat medium In addition to measuring the temperature and sensing the temperature conditions related to the heat medium, the control means for controlling the operation of the pump is adopted. It has become possible to heat cooking appliances etc. with energy. Therefore, the generation of CO ₂ can be prevented, which contributes to the prevention of global warming. In addition, by providing a heat storage type auxiliary heat source device made of heat storage material, it is possible to take out heat energy even at night or in cloudy weather, and even when the solar heat collector cannot be operated It became possible to give heat energy to etc.

[Brief description of drawings]

FIG. 1 is a skeleton structure diagram showing an overall configuration of the present invention.

FIG. 2 is an exploded perspective view showing the overall configuration of the heat storage device according to the present invention.

FIG. 3 is a skeleton structure diagram showing a configuration of another embodiment of the auxiliary heat source device according to the present invention.

[Explanation of symbols]

 1 Heat Storage Device 11 Outer Case 12 Thermal Insulation Layer 13 Inner Case 14 Water Level Meter 15 Pressure Adjustment Valve 16 Diffuser 17 Pressure Gauge 18 Drain Path 2 Control Means 21 High Temperature Sensor 22 Low Temperature Sensor 3 Pump 31 Motor 4 Heat Transfer Plate 5 Auxiliary Heat Source Device 51 Auxiliary Heater 52 Power source 55 Heat storage tank 56 Heat storage material 57 Heat storage path 58 Radiation path 59 Fan 6 Solar heat collector 61 High temperature path 62 Low temperature path 9 Cooker

Claims (1)

[Claims] 1. A cooktop having a heat source to be supplied to a cooker or the like, having a double tank consisting of an outer case and an inner case, having a heat insulating layer between the double tanks, and further comprising the double tank. It has a heat transfer plate that seals the tank and transfers the heat accumulated in the double tank to the cooker, and a diffuser for discharging the heat medium into the double tank formed by these. Further, a heat storage device having a drain passage for discharging the heat medium released from the diffuser from the inside of the double tank, a solar heat collection device generating a heat source to be supplied to the heat storage device, and these. Piping consisting of a high-temperature path and a low-temperature path for flowing the heat medium between the solar heat collector and the heat storage device, a pump provided in the middle of the low-temperature path for returning the heat medium, and the temperatures of the circulating heat medium. When you measure In the meantime, a control means for sensing the temperature condition relating to the heat medium and controlling the operation of the pump,
A cooking table having a solar heat collecting device.