JP2002181393A - Hot-water supplier utilizing solar heat - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hot-water supplier utilizing solar heat, which indicates heat-collecting state of a hot-water storage tank, based on the condition of operation of a pump and indicates the collecting amount of heat which is acquired by water in the hot-water storage tank from heating medium. SOLUTION: The hot-water supplier utilizing solar heat is provided with a temperature sensor 8 for measuring a high-temperature heat medium temperature, heated in a solar heat collector 1 and another temperature sensor 5, for measuring a low temperature heat medium temperature, after effecting heat exchange in the hot-water storage tank 2, while a pump 3 is operated by a control device 9, when the high-temperature heat medium temperature is higher than a low-temperature heat medium temperature, and the condition of collecting heat is indicated in an operation indicating remote controller 10. The collecting amount of heat acquired by the water in the hot-water storage tank 2 is calculated by the control device 9 through data measured by a flow rate sensor 7 for measuring the flow rate of heat medium supplied from the solar heat collector 1 into the hot-water storage tank 2 and the temperature sensors 5, 6, and then the operated data are indicated through a heat-collecting amount indicating bar 18.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar hot water supply apparatus, and more particularly to a solar hot water supply apparatus which displays an operation state where heat is collected by a solar heat collector and displays a heat collection amount. Things.

[0002]

2. Description of the Related Art In recent years, carbon dioxide emissions have increased along with the increase in energy consumption, and interest in global environmental issues such as global warming has increased. The use of solar water heaters utilizing solar heat has been expanding.

[0003] As such a solar water heater utilizing solar heat, there is a technique described in Japanese Patent Application Laid-Open No. 10-185332, and this technique will be described with reference to FIG.
FIG. 4 is a schematic diagram showing the solar hot water supply device 20 described above. A solar heat collector 21 is installed on a roof surface or the like, a hot water storage tank 22 installed in a building that uses solar heat collected by the solar heat collector 21, a solar heat collector 21 and a hot water storage tank 22. Pipe 23 for circulating and supplying a heat medium provided between
24, and a circulating pump 25 for circulating a heat medium from the hot water storage tank 22 to the solar heat collector 21 in the solar water heater using solar heat provided in the pipe.
Pipes 23 and 24 circulating and supplying a heat medium provided between the hot water storage tank 22 and the hot water storage tank 22 are connected to a heat exchanger 26 built in the hot water storage tank 22, and heat the water supplied into the hot water storage tank 22. It is configured to be warmed by the exchanger 26.

The above-mentioned solar hot water supply apparatus 20 includes a solar heat collector 21, a hot water storage tank 22, a circulation pump 25 for circulating a heat medium, a solar cell 27, and a drive / stop mechanism 28 for the circulation pump 25. Have. Drive / stop mechanism 28
Is a high-temperature detection thermometer 29 that measures the heat medium temperature TH in the solar heat collector 21, a low-temperature detection thermometer 30 that detects the hot water temperature TL in the hot water storage tank 22, and a high-temperature detection thermometer 29 and a low-temperature detection thermometer 30. A thermostat 31 which is a detector for detecting a temperature difference (TH-TL). Solar cell 2
7 detects the luminous intensity of the amount of solar radiation,
It has a function to drive the.

As shown in FIG. 5, when the luminous intensity is smaller than the reference value, a signal for stopping the driving of the circulating pump 25 is sent to the circulating pump. The heating medium temperature TH in the heater 21 is
If the hot water temperature TL is equal to or lower than
5, a signal for stopping the drive is issued. Accordingly, the circulation pump 25 is driven only when the luminous intensity is equal to or higher than the reference value and the temperature of the heat medium at the outlet of the solar heat collector 1 is higher than the hot water temperature in the hot water storage tank 22 by a predetermined value or more. I have.

[0006]

However, the above-mentioned solar hot water supply system detects the luminous intensity of the solar irradiance, compares the detected luminous intensity of the sun with a preset reference value, and simultaneously detects the luminous intensity of the solar heat collector. Is compared with the hot water temperature TL in the hot water tank, and a signal is output based on the result of the comparison to drive or stop the pump. And the said solar-heat utilization hot-water supply apparatus heats the hot water in a hot-water storage tank by the heat of the heat medium heated and collected by the solar-heat collector, but between the solar-heat collector and the hot-water storage tank. There was no indication as to whether or not there was a heat collection state and how much heat was collected from the heat medium in the hot water storage tank.

The present invention has been made in view of such a problem, and an object of the present invention is to determine whether or not a heat collecting operation is performed between a solar heat collector and a hot water storage tank. The present invention is to provide a solar water heater that displays the amount of heat collected by the water in the hot water storage tank while displaying the water.

[0008]

In order to achieve the above-mentioned object, a solar water heating apparatus according to claim 1 of the present invention comprises:
A solar heat collector in which an internal heat medium is heated by solar energy, a hot water storage tank provided with a heat exchanger therein and storing water used for hot water supply, and a heat exchanger for the heat medium in the solar heat collector. A pump having a pump circulating in the vessel, and a control device having an operation display remote control, wherein the control device displays the state of the heat collection operation during the operation of the pump with the operation display remote control, and also displays the state of the hot water tank from the heat medium. It is characterized by displaying the amount of heat collected by water.

A solar hot water supply apparatus according to a second aspect of the present invention includes a temperature sensor for measuring a temperature of a high-temperature heat medium heated by the solar heat collector, and a low-temperature heat source after heat exchange in the hot water storage tank. With a temperature sensor that measures the medium temperature,
The control device operates the pump when the high-temperature heat medium temperature is higher than the low-temperature heat medium temperature from the measurement data measured by the temperature sensor, and obtains water in the hot water tank from the heat medium. Q = S ×
It is characterized by being calculated by G × M × (HT−LT). Here, S is the specific heat of the heat medium, G is the heat medium density,
M is the heat medium flow rate, HT is the high-temperature heat medium temperature, and LT is the low-temperature heat medium temperature.

The solar hot water supply apparatus according to claim 3 of the present invention uses the low-temperature heat medium temperature LTa measured by a temperature sensor around the heat exchanger instead of the low-temperature heat medium temperature LT, and uses the heat collection amount. Q is represented by Q = S × G × M × (HT−LT
a) It is the same as the solar hot water supply device control device according to claim 2 except that the calculation is performed using / C. Here, C is a correction coefficient, which is a function of the minimum water temperature WT for a certain period. For example, when the correction coefficient C is WT ≦ 0 ° C. based on the low-temperature heat medium temperature LTa measured by a temperature sensor existing around the heat exchanger in the hot water tank, a predetermined coefficient C ₁ (normally 3-6), 0 ° C <WT <27
K × WT + C ₁ (−0.05 ≦ K ≦ −0.1
5), and when WT ≧ 27 ° C. or higher, C ₂ (usually 1-2.
5) Fix to 6.

According to a fourth aspect of the present invention, in the solar hot water supply apparatus, the flow rate of the heat medium is measured by a flow sensor that measures the flow rate of the heated heat medium supplied from the solar heat collector to the hot water storage tank. It is characterized by measuring. Further, in the solar hot water supply apparatus according to claim 5 of the present invention, the operation display remote controller includes a step-shaped heat collection amount display bar, and the control device integrates the operation time of the pump into the heat collection amount. The integrated heat collection amount is calculated by the step, and the step-shaped heat collection amount display bar displays the integrated heat collection amount in a stepwise manner.

[0012] According to the solar water heating apparatus configured as described above, the pump is operated when the high-temperature heat medium temperature is higher than the low-temperature heat medium temperature, and during operation of the pump that circulates the heat medium, In addition to displaying that heat is being collected, it is possible to display the amount of heat collected by the water in the hot water tank from the heat medium. Further, by measuring the flow rate of the heat medium by the flow rate sensor, it is possible to calculate the heat collection amount with high accuracy. The magnitude of the amount of heat collection can be determined stepwise by the step-like heat collection amount display bar. Furthermore, the status display of the heat collecting operation and the amount of heat collected from solar energy can be monitored in real time without providing a special device.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The construction of a solar water heater according to the present invention will be described below with reference to FIGS. FIG. 1 is a schematic configuration diagram showing a solar hot water supply apparatus of the present invention, and FIG.
FIG. 3 is a front view showing a display unit of the operation display remote controller of FIG. 1;
FIG. 5 is an operation explanatory diagram showing a display example of a heat collection amount display bar provided on a display unit of the operation display remote controller in FIG. 2. As shown in FIG. 1, the solar hot water supply apparatus of the present invention includes a solar heat collector 1 installed on a roof surface or the like, a hot water storage tank 2 installed in a building for storing hot water, and a roof surface or the like. Pipes 11 and 12 and a pipe 13 are connected to circulate and supply the heat medium heated by the solar heat collector 1 installed above to the hot water storage tank 2 installed in the building.

A heat exchanger 4 is provided inside the hot water storage tank 2, and a pipe 13 is provided at the heat medium inlet side of the heat exchanger 4.
Is connected, and a pipe 11 is connected to the heat medium outlet side of the heat exchanger 4.
The pump 3 is connected to the pipe 11, and the pipe 12 connected to the solar heat collector 1 is connected to the pump 3. Pump 3 provided between pipe 11 and pipe 12
Thus, the heat medium heated by the solar heat collector 1 is supplied from the pipe 13 to the heat exchanger 4 in the hot water storage tank 2, and heats the water in the hot water storage tank 2 by heat exchange with the heat of the heat medium. Hot water tank 2
Warm the water inside. On the outlet side of the heat medium of the solar heat collector 1, a temperature sensor 6 for measuring the temperature of the heat medium heated by solar heat is provided.

The heat medium that has warmed the water in the hot water storage tank 2 is supplied to the solar heat collector 1 via the pipe 11, the pump 3, and the pipe 12, and is again heated by the solar heat collector 1 to be heated. A heat exchange circulation system circulated and supplied to is provided. A control device 9 is connected to the pump 3 by a power supply cable 15, and the operation display remote control 10 is connected to the control device 9.
Is connected.

A hot water supply pipe 12 is connected to the hot water storage tank 2, and hot water heated by the heat exchanger 4 is supplied to a kitchen, a washroom,
Hot water is supplied to bathrooms or used as a heat source for heating. Further, a water supply pipe 13 having a water stop valve 14 is connected to the hot water storage tank 2. When the hot water in the hot water storage tank 2 decreases with the hot water supply, the reduced water is automatically or manually supplied from the water supply pipe 13. The water supply valve 14 is operated to supply the water.

The hot water tank 2 is provided with a temperature sensor 5 (hereinafter simply referred to as "temperature sensor 5") which is provided around the heat exchanger in the hot water tank and measures the water temperature of a portion of the hot water tank whose temperature rises due to heat exchange. "), And the piping 1
3, a flow rate sensor 7 for measuring a flow rate of the heated heat medium supplied from the solar heat collector 1 to the hot water storage tank 2 is provided at an inlet side of the hot water storage tank 2. On the outlet side, a temperature sensor 8 for measuring the temperature of the heat medium is provided.

The control unit 9 receives the measurement data measured by the temperature sensor 5, the temperature sensor 6, the temperature sensor 8 and the flow rate sensor 7. The control unit 9 determines whether the pump is running or stopped, and stores hot water. An operation for calculating and displaying whether or not the water in the tank is in a heat collection state and the amount of heat collection in which the water in the hot water tank 2 is obtained from the heat medium is performed.

FIG. 2 shows the display unit 1 of the operation display remote controller 10 connected to the control unit 9 of the solar water heater according to the present invention.
6 is shown. The display unit 16 is composed of a display device such as a liquid crystal display, a light emitting diode display, a fluorescent tube display, and the like. It is displayed. The heat collection amount display bar 18 has a step-like display bar having a maximum of 20 steps for displaying the heat collection amount in a stepwise manner. FIG. 3 shows a display example of the heat collection amount display bar 18 of the display unit 16 of the operation display remote controller 10.

The operation of the solar hot water supply apparatus of the present invention configured as described above will be described. When the power is turned on by operating the operation display remote controller 10, the temperature sensor 6 that measures the temperature of the heat medium heated by the solar heat collector 1 measures the water temperature of the portion of the hot water storage tank 2 where the temperature rises due to heat exchange. When the temperature becomes higher than that of the temperature sensor 5, the controller 3 sends a signal for driving the pump 3 to operate the pump 3 for circulating the heat medium. At this time, the display unit 16 of the operation display remote controller 10 indicates that the hot water storage tank 2 is collecting heat,
As shown in FIG. 2, a display 17 of “during heat collection” is displayed.

Pump 3-pipe 12-solar heat collector 1-pipe 13-heat exchanger in hot water storage tank 2-pipe 11-pump 3
The heat medium in the heat exchange circulating system formed by the above is sent to the solar heat collector 1 and is heated by the solar heat energy in the solar heat collector 1. The temperature of the heating medium heated by the solar heat collector 1 is measured by the temperature sensor 6 provided on the exit side of the heating medium of the solar heat collector 1, and the temperature of the heated medium is measured by the pipe 13. From the hot water storage tank 2 to the heat exchanger 4. In addition, the flow rate of the heat medium sent to the heat exchanger 4 in the hot water tank 2 is measured with high accuracy by the flow rate sensor 7 provided on the inlet side of the pipe 13 to the hot water tank 2.

The heat medium heated by the solar heat collector 1 and sent to the heat exchanger 4 in the hot water storage tank 2 to heat the water in the hot water storage tank 2 is again supplied from the pipe 11 by the pump 3 via the pipe 12 to the solar heat collector. It is supplied to the heater 1 and circulates. At this time, the temperature of the low-temperature heat medium that has heated the water in the hot water tank 2 sent from the pipe 11 to the pump 3 is measured by the temperature sensor 8 provided on the outlet side of the hot water tank 2 of the pipe 11. The temperature of the hot water in the hot water tank 2 heated by the heat exchanger 4 is measured by the temperature sensor 5. Then, the temperature of the hot water in the hot water tank 2 measured at this time is sent to the control device 9,
Display 1 of hot water supply temperature on display section 16 of operation display remote control 10
9 is displayed.

The hot water in the hot water storage tank 2 heated by the heat exchanger 4 is supplied from a hot water supply pipe 12 to a kitchen, a washroom, a bathroom, or the like, or supplied as a heat source for heating. When the amount of water in the hot water storage tank 2 decreases due to hot water from the hot water storage tank 2,
Water is supplied from the water supply pipe 13 into the hot water storage tank 2 by operating the water stop valve 14 manually or automatically.

As described above, the temperature sensor 6 provided on the outlet side of the heat medium of the solar heat collector 1, the flow sensor 7 provided on the inlet side of the hot water storage tank 2, and the temperature sensor provided in the hot water storage tank 2 5. The data measured by the temperature sensor 8 provided on the outlet side of the hot water storage tank 2 is sent to the control device 9. The measured data sent to the control device 9 is calculated by the following formula (1) stored in the control device 9.
Accordingly, an operation for calculating the amount of heat collected by the water in the hot water storage tank 2 from the heat medium heated by the solar heat collector 1 is performed.

The amount of heat collection Q = S × G × M × (HT−LT) (1) The amount of heat collection is calculated using the following formula. However, Q: Heat collection amount (J / sec) S: Heat medium specific heat (J / Kg · K) G: Heat medium density (Kg / cubic meter) M: Heat medium flow rate (cubic meter / sec) HT: High temperature heat medium temperature ( K) LT: Low-temperature heat medium temperature (K)

The high-temperature heat medium temperature is the temperature of the heat medium heated by the solar heat collector 1 and measured by the temperature sensor 6, and the low-temperature heat medium temperature is the temperature of the heat medium and water in the hot water tank 2. This is the temperature of the heat medium measured by the temperature sensor 8 after the heat exchange. In this way, based on the calculation formula (1) for calculating the heat collection amount Q, the heat collection amount is changed every second by the control device 9.
Is calculated by

In order to convert the heat collection amount into display units every second, the heat collection amount Q is set to a constant operating time T of the pump.
Is integrated to calculate an integrated heat collection amount in a certain display unit.
In this example, one bar is set to display the integrated heat collection amount of 1 (MJ / Tsec) corresponding to the heat collection amount display bar 18 of 20 steps. That is, when the integrated heat collection amount calculated as described above is 1 (MJ / Tsec), one bar is displayed at intervals of T seconds, and 10 (MJ / Ts) is displayed.
In the case of ec), 10 bars are set to be displayed at intervals of T seconds.

For example, if the integrated heat collection amount is “0” (MJ / Ts
ec, the same applies hereinafter), display is performed without lighting as shown in FIG. 3A, and when the integrated heat collection amount is equal to or more than “0” and less than “1”, as shown in FIG. The first bar blinks during operation, and the first bar lights up during operation stop. When the accumulated heat collection amount is “3” or more and less than “4”, as shown in FIG. 3C, the first to third bars are turned on, the fourth bar blinks while the pump is operating, and the operation is stopped. Lights the fourth bar. In addition,
The hatching in FIG. 3 indicates a blinking state.

The accumulated heat collection amount is "19" or more and "20"
If it is less than 1, as shown in FIG. 3D, the 1st to 19th bars are turned on, the 20th bar blinks while the pump is operating, and the 20th bar is turned on when the pump is stopped. Further, when the integrated heat collection amount is “20” or more, the first to twentieth bars are constantly lit as shown in FIG. In this way, by displaying the accumulated heat collection amount stepwise in 20 steps, the accumulated heat collection amount due to solar heat can be monitored in real time. Further, by blinking or lighting the rightmost bar, it is possible to monitor whether the operation state of the pump is operating or stopped. In this example, an example in which the heat collection amount is displayed as an integrated heat collection amount for T seconds has been described, but the heat collection amount per second may be displayed.

Next, the temperature of the water in the hot water tank corresponding to the low-temperature heat medium temperature is measured by using a temperature sensor 5 for measuring the low-temperature heat medium temperature around the heat exchanger of the hot water tank 2. The correction of the amount of heat collection when the amount of heat collection is calculated using is described. The heat collection amount Q is calculated by the following calculation formula (2). Q = S × G × M × (HT−LTa) / C (2) C is a correction coefficient, and the minimum water temperature WT during a certain period is 0 ° C.
Fix to 4.16 in the following cases. Minimum water temperature WT is 0 ° C
When the temperature is higher than 27 ° C., C = −0.08 × WT +
Calculate from 4.16. When the temperature is 27 ° C. or more, C is fixed at 2.

For example, when WT is 0 ° C., C = 4.1.
6. When WT is 5 ° C., C = −0.08 × 5 + 4.16
= 3.76, C = −0.08 × 1 when WT is 10 ° C.
0 + 4.16 = 3.36, C = − when WT is 20 ° C.
When 0.08 × 20 + 4.16 = 2.56 and WT is 30 ° C., C = 2, and the heat collection amount Q can be calculated by the equation (2) to calculate the heat collection amount from the temperature sensor 5.

In this case, it is not necessary to separately provide a temperature sensor for measuring the temperature of the low-temperature heat medium, and the amount of heat collection is calculated by using an existing temperature sensor, and the corrected amount of heat collection is calculated by multiplying a predetermined correction coefficient. The configuration can be simplified.

[0033]

As described above, the solar hot water supply apparatus of the present invention comprises a temperature sensor for measuring the temperature of a high-temperature heating medium heated by a solar heat collector, and a low-temperature heat source after heat exchange in a hot water storage tank. A temperature sensor for measuring the medium temperature is provided, and when the high-temperature heat medium temperature is higher than the low-temperature heat medium temperature, the pump is operated and the operation display remote controller 10 indicates that the heat is being collected, thereby indicating that the heat is currently being collected. .

A flow sensor for measuring the flow rate of the heat medium supplied from the solar heat collector to the hot water tank, and a collector for obtaining water in the hot water tank from the heat medium based on measurement data measured by the temperature sensor. The calorie can be calculated by the control device and displayed by the operation display remote controller. For this reason, pump operation
It is possible to display the determination of the stop, whether or not the hot water storage tank is in the heat collection state, and the amount of heat collection can be displayed stepwise.

Further, the configuration can be simplified if the amount of heat collection is calculated using the measurement data of the existing temperature sensor in the hot water storage tank, and the corrected amount is obtained to obtain the corrected amount of heat collection. When the heat collection amount is displayed on a step-like heat collection amount display bar, the magnitude of the heat collection amount can be confirmed stepwise.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing a solar hot water supply apparatus of the present invention.

FIG. 2 is a front view showing a display unit of the operation display remote controller of FIG. 1;

3 is an operation explanatory diagram showing a display example of a heat collection amount display bar provided on a display unit of the operation display remote controller of FIG. 2;

FIG. 4 is a schematic view showing a conventional solar water heater.

FIG. 5 is a flowchart illustrating the operation of a conventional solar water heater.

[Explanation of symbols]

1 Solar collector, 2 Hot water tank, 3 Pump, 4
Heat exchanger, 5 temperature sensor, 6 temperature sensor,
7 flow rate sensor, 8 temperature sensor, 9 control device, 10 operation display remote control, 11 piping, 12
Piping, 13 piping, 14 water shutoff valve, 15 power supply cable, 16 display, 17 display during heat collection, 18
Heat collection amount display bar

Claims (5)

[Claims] 1. A solar heat collector in which an internal heat medium is heated by solar energy, a hot water storage tank having an internal heat exchanger and storing water used for hot water supply, and a heat source of the solar heat collector. A solar water heater that includes a pump that circulates a medium through the heat exchanger and a control device having an operation display remote controller, wherein the control device is in a state of a heat collection operation during the pump operation with the operation display remote controller. A hot water supply system using solar heat, which displays the amount of heat collected by the water in the hot water storage tank from the heat medium. A temperature sensor for measuring a temperature of a high-temperature heat medium heated by the solar heat collector; and a temperature sensor for measuring a low-temperature heat medium temperature after heat exchange in the hot water storage tank, wherein the control is performed. The apparatus operates the pump when the high-temperature heat medium temperature is higher than the low-temperature heat medium temperature, from the measurement data measured by the temperature sensor, and obtains water in the hot water tank from the heat medium. Q = S × G × M × (HT-LT) where Q: Heat collection amount (J / sec) S: Heat medium specific heat (J / Kg · K) G: Heat medium density (Kg / cubic meter) The solar hot water supply apparatus according to claim 1, wherein: M: heat medium flow rate (cubic meter / sec) HT: high-temperature heat medium temperature (K) LT: low-temperature heat medium temperature (K) A temperature sensor for measuring a temperature of a high-temperature heat medium heated by the solar heat collector, and a temperature sensor for measuring a low-temperature heat medium temperature around a heat exchanger in the hot water storage tank; The device operates the pump when the high-temperature heat medium temperature is higher than the low-temperature heat medium temperature LTa, based on the low-temperature heat medium temperature LTa measured by a temperature sensor around the heat exchanger. Q = S × G × M × (HT-LTa) / C where C = f (WT) where Q: heat collection (J / sec) S: heat Medium specific heat (J / Kg · K) G: Heat medium density (Kg / cubic meter) M: Heat medium flow rate (cubic meter / sec) HT: High temperature heat medium temperature (K) LTa: Measured by temperature sensor around heat exchanger Heat medium temperature (K) 2. The solar water heater according to claim 1, wherein the positive coefficient WT is calculated based on a minimum water temperature (K) for a certain period. 4. The heat medium flow rate is measured by a flow rate sensor that measures a flow rate of a heated heat medium supplied from the solar heat collector to a hot water storage tank.
4. The solar water heater according to any one of claims 1 to 3. 5. The operation display remote control includes a step-shaped heat collection amount display bar, and the control device calculates an integrated heat collection amount by integrating an operation time of the pump with the heat collection amount. The solar hot water supply device according to any one of claims 1 to 4, wherein the display bar has a shape in which the accumulated heat collection amount is displayed stepwise.