KR810002645Y1 - Hot water tank in solar energy system - Google Patents

Abstract

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Description

Hot Water Storage Tank in Solar Heating System

1 is a cross-sectional view of the present invention.

Figure 2 is a perspective view showing an embodiment of the heating water supply pipe and the circulation discharge pipe in the present invention.

3 is a principle diagram of the operating state of the present invention.

The present invention is a heating device using solar heat, according to the solar heat collection state according to the sunshine time when the heated water inflow into the storage tank is different, or when the hot water stored in the storage tank used for heating and re-introduced The present invention relates to a storage tank for effectively storing hot water heated in a solar heat collecting plate by excluding a case of naturally lowering the temperature of hot water in a storage tank due to a phenomenon in which a low temperature water and a high temperature water flow back to each other during storage. The upper and lower middle portions of the storage tank filled with ordinary insulation, more specifically, the water supply pipe and the circulation pipe of about 7/8 of the total height of the storage tank and about 1/4 of the height of the storage tank It circulates heating hot water by heating pipe, but it is about 7/8 of the total height of the storage tank. In this way, a branch pipe is formed radially in the supply pipe and the circulating discharge pipe installed at about a quarter height, and a plurality of suction holes or discharge holes are drilled, respectively, and the diameters of the suction and discharge holes are increased as they go outwards. When the hot water for heating is gradually sucked into the supply pipe or discharged to the circulation pipe by the circulation pump, the surrounding hot water is prevented from flowing backward and mixed by the suction and discharge pressure, and further, the upper middle part of the storage tank. And the lowermost part, more specifically, the hot water having the temperature changed according to the solar irradiation time by installing the hot water inflow pipe and the cold water outflow pipe, which are 3/4 of the total height of the storage tank and the solar collector at the lower end, respectively. When entering and storing into the storage tank, convection occurs due to the relative temperature of hot water located around the inlet pipe. Red hot water rises to the upper part of the storage tank and separates the hot water heated in the solar collector from the low temperature hot water so that water layers of different temperature gradients are formed in the storage tank and heated by solar heat. In order to store and utilize the hot water more effectively, and to supply cold water to the solar collector, cold water is supplied to the lowest temperature part formed in the lowermost layer of the storage tank to increase the heat collection efficiency of the solar collector, thereby utilizing solar heat. It is to provide a storage tank that can increase the efficiency.

In general, it is well known that the heated water heated in a conventional solar collector varies in temperature every hour according to the irradiation state of the sun. The temperature is about the same, and as the sunrise time passes, the hot water heated in the solar collector also increases in temperature, and the temperature rises to the highest peak temperature of the day around 2-5 pm and then shows a downward curve again. .

However, although the temperature change of the hot water heated in the solar collector is the same as above, the storage tank of the conventional solar heating apparatus has a heated water inlet pipe for introducing hot water from the solar collector at the top of the storage tank, and is almost the same position. The hot water supply pipe for heating was installed on the opposite side of the furnace to circulate the heating pipe by using the high temperature hot water heated in the solar collector directly as the heating water. The hot water of the hot water was drained into the storage tank as it was not effectively used, and was reflowed to the bottom of the storage tank.

Therefore, the hot water re-introduced into the storage tank from the heating pipe heats the low temperature hot water or cold water located at the lower part of the storage tank, but it is only a fraction of the volume of the storage tank. In addition to reducing the average water temperature in the storage tank, the hot water re-introduced through the heating pipe as described above is directly discharged back to the solar collector and the discharged pipe to recycle the solar collector. There is a defect that results in a decrease in solar heat collection efficiency and thus extremely low solar utilization.

The present invention is to fundamentally eliminate the deficiencies of the conventional storage tank as described above, the supply pipe for supplying hot water to the heating pipe in the middle of the upper portion of the storage tank, specifically, 7/8 of the overall height of the storage tank In the middle of the lower end of the storage tank, specifically, the 1/4 position of the total height of the storage tank is provided with a heating water circulating discharge pipe, each of which forms a radial branch pipe, and draws a suction hole on the bottom of the radial tube of the supply pipe and circulates it. In the upper part of the radial branch pipe of the discharge pipe, a plurality of discharge holes are drilled, respectively, in order to supply hot water to the heating pipe. By distributing hot water to the supply pipe, when hot water is sucked in, the hot water of different temperature layers stored in the storage tank is reversed. It is possible to eliminate the phenomenon that water flows into the storage tank because it is possible to eliminate the phenomenon that the water flows into the storage tank, and the hot water at the desired temperature can be effectively utilized. Even in the upper part of the radial discharge pipe of the circulation discharge pipe, the circulating water is discharged to the upper side by the pressure of the even distribution through the discharge hole evenly distributed and re-introduced into the storage tank, so that there is no case of flowing back to the hot water around the circulation discharge pipe. The hot water re-introduced into the storage tank forms a water layer with the cold water layer formed at the bottom of the storage tank at the top, so that only the cold water having the lowest temperature in the storage tank flows out to the solar collector. It can increase the thermal efficiency and pipe the inlet pipe to the storage tank. In the case of hot water, which is installed at about 3/4 of the total height of the storage tank, the hot water of the hot water flows into the upper layer and the hot water of the cold water into the lower layer according to the convection phenomenon. The hot water having the highest temperature of the day is stored in the uppermost part of the storage tank and used for hot water heating, so that hot water can be used even when the weather conditions are not good.

In forming the storage tank of a solar heating apparatus, the cylindrical storage tank 1 is formed with the ratio of diameter r and height h 1: 2.5.

On one side wall of the storage tank (1), the solar collector (2) and the heated hot water inlet pipe (3) and the cold water outlet pipe (4) are respectively provided, but the heated hot water inlet pipe (3) is the height of the storage tank (1). At the point of 3 / 4h with respect to (h) and the cold water outlet pipe (4), respectively, at the lowermost end slightly above the bottom of the storage tank (1), respectively, the other side wall of the storage tank (1) and the heating pipe (5) and The supply pipe 6 and the smooth discharge pipe 7 are provided, but the supply pipe 6 is on the point of 7 / 8h with respect to the height h of the storage tank 1, and the circulation discharge pipe 7 is the storage tank 1 The temperature gradient of the water column, that is, the temperature layer of the hot water flowing into the storage tank 1 from the solar collector 2, heats the hot water in the hot portion above the age. Hot water of considerable temperature that is discharged into the pipe and circulated through the heating pipe is located at a position higher than the lowest temperature layer, thereby increasing thermal efficiency.

Further, branch pipes 8 and 9 are radially formed in the supply pipe 6 and the circulation discharge pipe 7 connected to the above points, respectively, and suction holes 8 on the branch pipes 8 and 9 respectively. '8' (8 ＂) is drilled, and the diameter of the suction hole (8 ') is gradually enlarged as it goes outward, and the suction hole (8') (8＂) is disposed at the bottom surface of the radial tube (8). ) Is perforated on the upper surface of the radial paper tube (9) to prevent the detention during heating water intake, discharge.

In addition, the top end of the storage tank (1) is installed in the heat exchange device 10 to use the hot water having the highest temperature of the storage tank (1). (Unexplained symbols a, b, c, d, e in the drawing indicate the temperature gradient layer formed in the storage tank 1)

Referring to the effect of the present invention made of such a member as follows.

First, as shown in FIG. 4, the heated hot water introduced into the storage tank 1 from the solar collector 2 varies according to the irradiation time of the sun, and the temperature of the hot water heated based on the sunrise time gradually increases. It will have the highest peak temperature of the whole day around 2-5 pm, and after 5 pm the temperature will show a downward curve.

Therefore, in the case of 9 am after sunrise, the heat collecting effect in the solar collector 2 is not so effective, and the heated hot water is 3 / 4h with respect to the total height h of the storage tank 1. Inflow to the d-layer part through the inlet pipe (3) installed in the, the temperature of the storage water already stored in the d-layer part of the storage tank (1) to a temperature higher than the inlet water through the inlet pipe (2) While being maintained, the temperature of the influent water is formed in the d-layer portion or the lower c-layer portion due to the convection of the fluid.

Since the sunrise time after 11 am to 1 pm hot water heated in the solar collector (2) flows into the point 3 / 4h of the storage tank (1) through the inlet pipe (3), the temperature of the influent The state is higher than the temperature of the water layer formed in the d layer, and the incoming hot water at this time rises to the top of the d layer or the e layer, and is heated to the highest peak temperature of the day at about 2-5 pm The heated hot water is located at the upper end of the d layer or the e layer, so that the hot water at the highest temperature of the day is naturally located at the top end (e layer) of the storage tank 1.

Therefore, according to the sunlight conditions, the water layer is naturally formed as a water layer having a temperature gradient of a, b, c, d, e, etc. according to the temperature difference of the hot water heated in the solar collector 2 every hour. The most efficiently heated high temperature influent is formed in the d and e layers.

Therefore, in using the hot water formed by the temperature layer (a, b, c, d, e layer) having such a difference for heating, the hot water supply pipe (7 / 8h) at the point 7 / 8h of the total height (h) of the storage tank (1). 6) is installed to supply the hot water of the upper part of the d layer directly heated by the solar collector (2) among the heating hot water of the day to the heating pipe. The suction hole (8) is provided on the lower surface of the radial paper tube (8) of the hot water supply pipe (6). ') (8') is perforated. As the diameter of the suction hole 8 '(8 ＂) is gradually increased as it goes outward from the center of the radial tube 8, hot water having the same water vapor, water level, and the same temperature has the same suction force on the same plane. Since evenly suctioned and supplied to the heating pipe 5 through the supply pipe (6), when the hot water intake is mixed with the hot water of the different temperature gradient layer stored in the storage tank (1) to countercurrently mixed to lower the temperature It can be excluded.

After installing the circulation discharge pipe (7) for circulating the heating pipe (5) and re-introduced into the storage tank (1) is installed on the 1 / 4h point relative to the total height (h) of the storage tank (1), The supply pipe 6 and the same type of radial paper tube (9) is formed, while the discharge hole (9 ') (9 ＂) perforated to the upper surface of the radial paper tube (9) so as to perforate upward, the supply pipe ( As in 6), the circulating water is prevented from mixing backward with hot water around the radial paper tube 9 of the circulating discharge pipe 7, and at this time, the circulating water is re-introduced into the storage tank 1 through the circulating discharge pipe 7. Although the temperature is lowered when the temperature is sucked into and supplied to the initial supply pipe 6 (that is, the temperature is lower than the temperature of the d-layer), since the heat loss deodorized from the heating pipe 5 is conventional, the circulation discharge pipe ( 7) the temperature of the circulating water flowing back into the storage tank 1 through the b layer part Becomes higher than that walking can be a relatively high temperature cycle than layer portion b by the fluid convection is elevated position as part upper layer portion b, or c layer.

Therefore, since the hot water of the storage tank 1 having a temperature lower than the circulating water is positioned downward to the bottom of the b-layer or the a-layer, the low temperature cold water layer a in the storage tank 1 below the circulation discharge pipe 7. Layer) is formed.

On the other hand, in supplying the heating water to the solar collector 2 through the outlet pipe 4, the outlet pipe 4 is formed at the lower end of the storage tank 1, thereby circulating and reintroducing each of the heating pipes 5. It is possible to increase the heat collecting efficiency in the solar collector 2 by supplying only the hot water at a lower temperature than the circulating water, that is, the cold water of the lowermost part (a layer) to the solar collector 2. .

The present invention forms a water layer with various temperature gradient layers by introducing hot water having a different heating state into the storage tank 1 every time. The uppermost layer (e layer), that is, the water layer having the highest peak temperature of the day (e) The hot water of the floor) is considerable, so it is not used for direct heating. In the e-layer part, which is the highest temperature layer in the storage tank 1, a hot water supply heat exchanger 10 for separate water supply is installed and It is possible to supply hot water at all times regardless of the situation such as day and night.

In the present invention, in storage and storage of inflow water having a different temperature from the solar collector in the storage tank, the water layer of various temperature gradient layers is formed by the convection of the fluid so that the upper layer in the storage tank is always hot. The hot water can be stored and stored effectively, and the hot water stored in the storage tank can be effectively utilized by varying the installation site of the hot water supply pipe, the circulation pipe, and the inlet pipe and the discharge pipe from the solar collector. At the same time, the heat storage efficiency can be increased and the solar collector can always supply only the coldest water at the lowest temperature in the storage tank, thereby greatly increasing the heat collection efficiency of the solar collector.

Claims (1)

As shown in the drawing, the storage tank 1 of the solar heating system is formed in a cylindrical shape with a ratio of diameter r and height h of 1: 2.5, and the total height of the cylindrical storage tank 1 (h). In the well-known thing provided with the heating hot water inflow pipe (3) and the cold water discharge pipe (4) at the point which becomes 3 / 4h, and the lowest end, respectively, it suctions at the point which is 7 / 8h and 1 / 4h to the other side Supply pipe (6) and circulation discharge pipe (8) (8 ＂) and discharge hole (9 () (9＂) are enlarged in diameter as they go outwards, and the radial ducts (8) (9), which are perforated, are addressed. (7) (7) A hot water storage tank in a solar heating system provided with the installation.