JPS6332251A - Solar system - Google Patents

Abstract

PURPOSE:To provide a solar system that is highly usable by effectively operating both in the summer and winter seasons by heating feed water in a heat exchanger by liquid thermal medium heated by the solar heat, and by causing the liquid thermal medium heated in a boiler to release its heat while being circulated in a heat collecting and dissipating device. CONSTITUTION:In the summer season, the liquid thermal medium delivered from the return pipe 12b of a heat collecting and dissipating device 10 is heated to a high temperature by sunshine. The water in a water tank 21 of a heat exchanger 20 is heated by exchanging heat with the high temperature liquid thermal medium, and is delivered to an outlet pipe 21b as hot water which is sufficiently usable for household utility. For melting snow, the liquid thermal medium flowing through a meandering pipe line 33 is heated via water in a water tank 31 by igniting a burner 32 of a boiler 30, and the high-temperature liquid thermal medium is supplied to a heat collecting and dissipating device 10 by a thermal medium circulation pump 14. As the hot thermal medium flows in the heat collecting and dissipating device 10, the snow melting can be efficient ly performed.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application This invention relates to a novel solar system that has both a hot water supply function using solar heat in the summer and a roof snow melting function in the winter.

Prior Art In snowy regions, people are forced to work on the roof roofing of houses in the winter, but this work is very hard work because the snow is heavy, and it is difficult to do it in high places on the roof. As this is work, there is always a risk of falling.

Therefore, various methods have been devised for the purpose of quickly melting roof snow on roofs. In other words, well-known methods include installing sprinklers on the roof to melt snow using water, and installing heaters with electric heating wires on the roof to melt snow using electric heat. .

On the other hand, even in snowy areas, it is often possible to utilize solar heat in the summer, so recently it has become increasingly common to install heat collectors for solar systems on rooftops to utilize solar heat. It is becoming like this,
The most common shape is a flat box-like container whose top surface is covered with a transparent reinforced glass or reinforced plastic panel, with a water pipe and a water storage tank built into it.

Problems to be Solved by the Invention Regarding the above-mentioned snow melting methods that have been proposed in the past, it is difficult to say that they are necessarily perfect. In other words, sprinklers cannot be expected to have a sufficient snow melting effect unless a large amount of groundwater is used, making it difficult to install in urban areas. The efficiency of snow melting is poor as it only creates a tunnel of snow, and the melted snow blocks obstruct the flow of water on the top of the tiles, often causing water to flow backwards and causing rain leaks. There is a problem with this. In addition, the electric heater method requires a large amount of electric power to obtain an effective snow melting effect, resulting in excessive running costs and is hardly practical for use in general houses.

On the other hand, heat collectors installed on roofs to construct solar systems are completely buried under snow during the winter, so they cannot function as they should to collect solar heat.
It is something that cannot be performed at all. As well,
Conventional heat collectors, whose top surfaces are usually made of reinforced glass or reinforced plastic panels, are extremely slippery and can therefore become dangerous obstacles when carrying out roof snow removal operations. There was a lot of stuff. In particular, when a heat collection device is installed over a wide area on the roof in order to improve heat collection efficiency, it may become almost impossible to remove accumulated snow from the top of the heat collection device. , the solar system is simply used during the winter period.
It is recognized that not only does it cause the loss of its physical functions, but it also poses a major hindrance to roof snow removal work, and this is a major factor hindering the spread of solar systems in snowy regions. It is something that

Therefore, in view of the actual state of the prior art, it is an object of the present invention to effectively collect and utilize solar heat in the summer, and to efficiently melt snow on roofs in the winter. The idea behind installing a heat collecting and dissipating device on the roof is that the heat collecting and dissipating device can operate effectively in both summer and winter, making it a new type of solar power plant that has extremely high utility value even in snowy areas. The goal is to provide a system.

Means for Solving the Problems The structure of the present invention to achieve the above object is to circulate a heat medium liquid through a meandering pipe line arranged along the upper surface of the roof to form a heat collecting and dissipating device. A heat exchanger and a boiler are provided so that the heat medium liquid can be circulated between the heat collection and radiation device and either the heat exchanger or the boiler, while the water supply is provided between the heat exchanger and the boiler. The gist is that hot water can be supplied by being heated by at least one of the boiler and the boiler.

Accordingly, with the above configuration, the heat medium liquid circulates between the heat collection and radiation device and the heat exchanger during the summer, and
When there is snow in winter, the circulation route can be switched so that it circulates between the heat collector and the boiler, so in the former case, the heat medium heated by solar heat in the heat exchanger It is possible to heat the feed water with a liquid and supply it as hot water as it is or after additionally heating it to a predetermined temperature in a boiler.In the latter case, the heat transfer liquid heated by the boiler is collected. Snow on the roof can be efficiently melted by circulating heat through the heat radiating device.

Example Examples will be described below with reference to the drawings.

The solar system includes a heat collection and radiation device 10 installed on the roof, a heat exchanger 20, and a boiler 30 (FIG. 1).

The heat collecting and dissipating device 10 includes an outgoing header 11 and a returning header 12.
and a plurality of sets of meandering pipes 13, 13... connected between these headers 11, 12 (Fig. 2), each header 11, 12 is a heating medium liquid supply pipe. Road 1
1b and the return pipe 12b, stop valves 11a, 12a are provided.
It is equipped with The meandering pipes 13, 13... are pipes arranged along the upper surface of the roof R, for example,
When the roof R has a tiled roof, the meandering pipes 13 are preferably arranged perpendicularly to the inclination direction of the roof R along the upper surface of the roof tiles Rk, Rk... 3
figure). That is, a stopper 13a is hooked to the upper end of the roof R that is partially overlapped with the roof tiles Rk, Rk, which are lined up in the vertical direction, and a stopper 13a is formed at the tip of the stopper 13a. The meandering pipe line 13 is attached to the circular arc portion to form the heat collecting and dissipating device 10 (the fourth
figure).

Each meandering conduit 13 starts from below the outgoing header 11 on the upper surface of the roof R, turns back at the side end of the roof R (FIG. 2), and ends above the starting position from the outgoing header 11. It is preferable to determine the number of turns so that the vehicle returns to the return header 12 at a certain point, and the length between the two headers 11 and 12 is approximately 40 m or less.

A heat medium liquid supply pipe 11b and a return pipe 12b are connected to the outgoing header 11 and the return header 12 of the heat collecting and dissipating device 10 via stop valves 11a and 12a, respectively. , 12b are switching valves 11G,
Via 11d, 12C, and 12d, it is branch-connected to flexible pipes 22 and 33 incorporated in the heat exchanger 20 and the boiler 30 (FIG. 1). In addition, a heat medium circulation pump 14 is interposed on the inlet side of the heat collecting and dissipating device 10 of the supply pipe line 11b, and a replacement fluid tank 15 is provided on the suction side of the supply pipe line 11b, while a A temperature detector 16 is installed at the exit end from the heat collection and radiation device 10.

The heat exchanger 20 consists of a water tank 21 and a flexible pipe 22 built into the water tank 21.
A water supply pipe 21a from a water supply source W and a drain pipe 21b are connected, and a temperature detector 23 is attached. Further, the drain pipe 21b is provided with a stop valve 2IC.

The boiler 30 is, for example, a kerosene-fired hot water boiler that includes a water tank 31, a flexible pipe 33 built into the water tank 31, and a burner 32 for heating water stored inside the water tank 31. The heat source is not limited to kerosene, but may also be gas, electricity, etc.

A water supply pipe 31a is connected to the boiler 30 from a water supply source W via a pressure reducing valve 34 and a hot water circulation pump 35, and a hot water supply pipe 31b for supplying hot water to a hot water usage area (not shown) is connected. has been done. On the other hand, if a device that uses only the heat of hot water and does not consume the hot water itself, such as a hot water heating device, is connected to a hot water usage location (not shown), the hot water return pipe 34a is Although it is piped, this one has a stop valve 34b and a check valve 34.
G, connected to the outlet end of the stop valve 2IC inserted into the drain pipe 21b of the heat exchanger 20, and the water supply pipe 3
1a, at the connection point between the pressure reducing valve 34 and the hot water circulation pump 35.

The heat medium liquid used in the heat medium liquid system including the heat collection and radiation device 10, the heat exchanger 20, and each flexible pipe 22, 33 of the boiler 30 has a melting point of 0°C or less and a boiling point of 100°C or less. heat transfer liquid that always maintains a liquid state in the normal operating temperature range, such as ■ tyrene glycol liquid (melting point -1
1.5°C (boiling point 197.5°C) is suitable. Of course, it is also possible to use a heat transfer liquid with a lower melting point or a higher boiling point, such as silicone oil, but when considering the possibility of leakage in the corrugated pipe 22.33, Needless to say, it is desirable that the material be completely harmless to the human body.

In the solar system having such a configuration, when the heat medium circulation pump 1/I is operated, the heat medium liquid flows through the heat collection and radiation device 10.
and one of the heat exchanger 20 and the boiler 30. That is, the switching valves 11c and 12G are opened, and the switching valve 1 is opened.
When closing 1d and 12d, close the flexible pipe 22 of the heat exchanger 20.
On the other hand, when the switching valves 11C and 112C are closed and the switching valves 11d and 12d are opened, the boiler 30
can be circulated through a flexible pipe 33.

Therefore, in summer, by opening the switching valves 11C and 112C and closing the switching valves 11d and 12d, the heat transfer liquid discharged from the return pipe 12b of the heat collection and radiation device 10 is
While flowing through the meandering pipes 13.13... installed on the crosspiece tiles Rk, Rk... on the roof R, they are heated to a sufficiently high temperature by sunlight, so that heat exchange is not possible. The water stored in the water tank 21 of the container 20 is heated by this heat exchange with the high-temperature heat transfer liquid, and the water is heated by the heat exchanger 2.
In the drain pipe 21b of No. 0, for example, hot water that can be sufficiently used as domestic water is obtained. That is, in this state, hot water was obtained by using solar heat, just like a general solar system, and this hot water passed through the stop valve 21G, which was opened in advance, the hot water circulation pump 35, and then passed through the boiler 30. On the other hand, hot water can be supplied to an unillustrated location using hot water via the hot water supply pipe 31b. Note that the meandering pipes 13.13... of the heat collection and dissipation device 10 are arranged along the crosspiece tiles Rk, Rk... on the upper surface of the roof R, so that the meandering pipes 13.13... The heat transfer liquid flowing through the roof tiles Rk and R becomes hot due to solar radiation.
Heat is well transferred from the heat collecting and dissipating device 10, and therefore extremely high solar heat collecting efficiency can be achieved in the heat collecting and dissipating device 10.

If the total amount of solar heat collected by the heat collecting and dissipating device 10 is insufficient due to seasonal or weather conditions, the temperature of the heat medium liquid in the return pipe 12b of the heat collecting and dissipating device 10 decreases, and the temperature of the heat medium liquid in the return pipe 12b decreases. temperature sensor 16 which is
Since the temperature difference between the temperature and the temperature detector 23 installed in the water tank 21 of the heat exchanger 20 approaches each other, this temperature difference can be used to determine whether reheating by the boiler 30 is necessary or not. can be judged. That is, when the temperature difference obtained by the output of the temperature detector 16.23 becomes less than the set temperature difference, the burner 32 of the boiler 30 is ignited to drain the water stored in the water tank 31 of the boiler 30. Since additional heating can be done, the hot water supply pipe 31
The temperature of the hot water supplied via b can always be kept above a predetermined value.

When using this solar system to melt snow accumulated on the roof R, the switching valves 11c and 12G are closed, and the switching valves 11d and 12d are opened to transfer the heat medium liquid to the heat collecting and dissipating device 10. It is circulated between the boiler 30 and the boiler 30.

At this time, by igniting the burner 32 of the boiler 30, it is possible to heat the heat medium liquid flowing in the corrugated pipe 33 via the water in the water tank 31, and furthermore, this high temperature heat medium liquid can be heated. Since the heat medium circulation pump 14 can send the heat medium to the heat collection and radiation device 10, the high temperature heat medium liquid can be sent to the meandering pipes 13, 13, etc. of the heat collection and radiation device 10 installed on the roof R. flow and therefore the serpentine conduit 13
．． The snow accumulated on the roof R can be efficiently melted by the heat radiation from 13. Here, when performing such snow melting operation, it is better to wait until as much snow has accumulated on the roof R as much as the load-bearing strength of the building allows, so that the heat dissipation from the meandering pipes 13, 13... This reduces the amount of snow dissipated into the air, thereby further increasing snow melting efficiency. Note that even during this snow melting operation, the water stored in the water tank 31 of the boiler 30 is being heated by the burner 32, so
The hot water supply function of the system itself is not lost in any way. Furthermore, during the snow melting operation, the heat exchanger 20 stops functioning, so the stop valve 21C inserted in the drain pipe 21b may be closed, and in that case, the water supply from the water supply source W is The water is directly supplied to the hot water circulation pump 35 via the pressure reducing valve 34 without passing through the heat exchanger 20.

In the above description, the hot water circulation pump 35 and the hot water return pipe 34a are prepared on the assumption that, for example, a hot water heating device is used that generates hot water return at a hot water usage location. Therefore, these devices can be omitted if only equipment that does not cause the return of dry water, such as cooking, bathing, and shirts, is used.

Furthermore, during the snow melting operation, the heat collecting and dissipating device 1
It has been found that the difference between the temperature of the heat transfer liquid supplied to the forward header 11 of No. 0 and that discharged from the return header 12 is preferably about 20'C. If this temperature difference is too large, a large imbalance will occur in the distribution of the snow melting effect on the roof R, and the distribution of the speed of snow melting depending on the location on the roof R will become extremely uneven, resulting in an overall snow melting effect. On the other hand, if the temperature difference is too small, the overall snow melting ability itself will be insufficient, while the energy required to complete the process will be rather large. Therefore, it is preferable to select the length of one set of meandering pipes 13 and the circulation amount of the heat transfer liquid so as to obtain the above-mentioned preferable temperature difference. This is a suitable example.

As described in detail, according to the present invention, a meandering pipe is arranged on the upper surface of the roof, and this serves as a heat collecting and dissipating device.
Circulating a heat medium liquid between either one of the heat exchanger or the boiler and the heat collection/dissipation device, further heating the feed water in at least one of the heat exchanger or the boiler, By being able to supply hot water, the heat collecting and dissipating device performs its original function of collecting solar heat in the summer, while in the winter it performs its original function of collecting solar heat.
Since it can be operated as a snow melting device that radiates heat from the heat transfer liquid heated by the boiler, it has the excellent effect of providing a system with extremely high utility value even in snowy areas.

In addition, the combined use of a heat exchanger and a boiler has the practical effect of making it easy to additionally heat hot water using the boiler when the amount of solar heat collected is insufficient.

[Brief explanation of the drawing]

Figures 1 to 4 show an embodiment, where Figure 1 is an overall system diagram, Figure 2 is a detailed view of the main parts of Figure 1, Figure 3 is a perspective view of the main parts of the heat collection and dissipation device, and Figure 4. 3 is a sectional view taken along the line XX in FIG. 3. FIG. R... Roof 10... Heat collection and radiation device 13... Meandering pipe line 20... Heat exchanger 30... Boiler

Claims (1)

[Claims] 1) A heat collection and radiation device configured by circulating a heat medium liquid in a meandering pipe line arranged along the upper surface of the roof, a heat exchanger and a boiler connected to the heat collection and radiation device, and the heat medium liquid is , the water can be switched to circulate between the heat collection and radiation device and either the heat exchanger or the boiler, and the water supply is heated by at least one of the heat exchanger and the boiler. A solar system characterized by being able to supply hot water.