KR20120132916A - Heat storage tank - Google Patents

Abstract

PURPOSE: A heat storage tank with a simple structure is provided to effectively use warm water flowing into the tank by improving a structure. CONSTITUTION: A heat storage tank comprises an inner tank(11), a tank inlet, a tank outlet(23), a heating water supply port(33), a heating water return port(31), an outer tank(12), a vacuum valve(13), and a spring(14). The outer tank is installed outside the inner tank to surround the inner tank. The vacuum valve maintains a space formed between the inner and outer tanks in a vacuum state. The spring is formed into a coil shape between the inner and outer tanks. The spring prevents the inner and outer tanks from being deformed when the space between the inner and outer tanks is maintained in a vacuum state.

Description

Heat storage tank {HEAT STORAGE TANK}

The present invention relates to a heat storage tank, and more particularly, to a heat storage tank for maintaining a constant temperature of the hot water in the heat storage tank for a long time, and to efficiently use the hot water introduced into the heat storage tank.

Solar heating system has a lot of initial installation cost, but does not require a separate maintenance cost and does not cause pollution problems, so various types of solar heating devices are being developed.

Various types of heat storage tanks are also being developed in heat storage tanks for receiving heated hot water among such solar heating apparatuses. As an example, the heat storage tanks of Patent Publication No. 10-2010-0101325 have a heat collector as shown in FIG. The heat exchange medium heated in (1) circulates in the heat exchange coil 5 installed in the heat storage tank 2, and heats the water introduced through the heating water supply pipe 3 in the heat storage tank 2, wherein the heated water is Hot water heated in the heat storage tank 2 is discharged to a place where heating is required through the water outlet pipe 4 for heating, and at the same time, the hot water heated in the heat storage tank 2 is provided. The water circulating in the interior is heated so that hot water is used by the water circulating in the heat exchange coil 6. Reference numeral 7 is a reflector.

However, the heat storage tank having the above structure has the disadvantage that the heat transfer efficiency due to heat transfer is lowered because the heat medium oil heated in the heat collector 1 is used to indirectly heat the water contained in the heat storage tank 2 to be used as heating water. Further, since the hot water is obtained by heat exchange with the heating water heated in the heat storage tank 2, this also lowers the heat transfer efficiency and thus lowers the heat transfer efficiency of the heat storage tank 2 as well as the heat storage tank 2. The structure becomes too complicated and there is a problem that the productivity is lowered.

In addition, the heat storage tank as described above generally includes an inner tank in which water is contained, an outer tank installed to surround the inner tank on the outside of the inner tank, and an insulating material installed between the inner tank and the outer tank. It is composed.

In the conventional heat storage tank configured as described above, the hot water heated inside the inner tank is kept warm by using a heat insulating material such as polyurethane installed on the outer circumference of the inner tank. Accordingly, since the temperature of the hot water heated inside the heat storage tank is directly affected, there is a disadvantage in that heat loss increases.

The present invention has been made to solve the problems of the prior art as described above, the object is to improve the structure of the heat storage tank to make it possible to efficiently use the hot water introduced into the heat storage tank, and also to the structure of the heat storage tank It is to provide a heat storage tank that can improve the productivity by simplifying.

Another object of the present invention is to provide a heat storage tank for allowing the temperature of the hot water heated in the heat storage tank to be kept constant.

Another object of the present invention is to provide a heat storage tank for preventing the deformation of the inner tank installed in the heat storage tank to maintain a vacuum between the inner tank and the outer tank.

The heat storage tank according to the present invention for achieving the above object, the inner tank in which the receiving space is formed; A tank inlet for introducing hot water heated by a collector installed outside the inner tank into the inner tank; A tank outlet for discharging hot water contained in the inner tank to the collector; A heating water supply port for supplying hot water contained in the inner tank to a heating load; A heating water recovery port for recovering the heating water recovered from the heating load to the inner tank; An outer tank installed outside the inner tank to surround the inner tank; A vacuum valve for maintaining a vacuum formed in the space between the inner tank and the outer tank; And a spring installed in a coil shape between the inner tank and the outer tank to prevent the inner tank and the outer tank from being deformed when the space between the inner tank and the outer tank is maintained in a vacuum. It is characterized by.

Here, the heat storage tank according to the present invention, the heat exchange coil for heat-exchanging the cold water inside with hot water using the hot water contained in the inner tank; A tank cold water inlet connected to an inlet side of the heat exchange coil to introduce cold water into the heat exchange coil from a tap water supply pipe; It is preferable that the tank hot water outlet for being connected to the outlet side of the heat exchange coil for discharging the hot water discharged from the heat exchange coil.

Here, the inner tank is preferably attached to the cushioning material on the outer circumference.

According to the heat storage tank according to the present invention, it is possible to efficiently use the hot water introduced into the heat storage tank to improve the heat transfer efficiency, and to improve the productivity by simplifying the structure of the heat storage tank.

In addition, according to the present invention, by forming a vacuum space portion between the inner tank and the outer tank to ensure that the hot water inside the inner tank is constantly kept warm, it is possible to improve the thermal insulation effect of the inner tank.

In addition, according to the present invention, by installing a spiral coil at regular intervals on the outer surface of the inner tank, and by installing a cushioning material on the outer surface of the inner tank, the deformation of the inner tank can be prevented as much as possible, It is possible to improve the heat insulation effect by preventing the vacuum from breaking in the space.

1 is a schematic configuration diagram of a conventional heat storage tank.
2 is a schematic configuration diagram of a heat storage tank according to the present invention.
Figure 3 is an external perspective view of the heat storage tank according to the present invention

Hereinafter, the heat storage tank according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2, the heat storage tank according to the present invention includes an inner tank 11, a tank inlet 21, a tank outlet 23, a heating water supply port 33, and a heating water recovery. It consists of a sphere 31, an outer tank 12, a vacuum valve 13, and a spring 14.

The inner tank 11 has an accommodating space therein and has a cylindrical shape.

The tank inlet 21 is a connection port for introducing hot water heated in the collector 26 installed outside the inner tank 11 into the inner tank 11 through the tank inlet pipe 22. At this time, the hot water introduced through the tank inlet 21 has a high temperature temperature range as the hot water heated in the collector 26, the lower portion of the inner tank 11 which is a relatively low temperature in the inner tank 11 It is preferable to introduce the heated hot water from the collector 26 toward the side.

The tank outlet 23 is a connection port for outflowing hot water contained in the inner tank 11 to the collector 26 through a collector inlet pipe 24.

The heating water supply port 33 is a connection port for supplying hot water contained in the inner tank 11 to a predetermined heating load 35 that requires heating through the heating water supply pipe 34. At this time, the inner temperature of the hot water in the inner tank (11) due to the density difference according to the temperature of the hot water contained therein is located toward the upper side of the inner tank (11) due to the low density, the heating water supply port ( The heating water discharged through the 33 is preferably discharged the hot water of the inner tank 11 to the heating load 35 from the upper side of the inner tank 11, which is a relatively high temperature in the inner tank (11). Do.

The heating water recovery port 31 is a connection port for recovering the heating water recovered from the heating load 35 to the inner tank 11 through the heating water recovery pipe 32.

The outer tank 12 is installed on the outside of the inner tank 11 to surround the inner tank 11, as shown in Figure 2, to form a vacuum in the space between the inner tank 11 By doing so, the temperature of the hot water stored in the inner tank 11 can be maintained for a long time without lowering.

The vacuum valve 13 is to maintain the space formed between the inner tank 11 and the outer tank 12 in a vacuum as shown in Figures 2 and 3 as the inner tank 11 and the outer tank. After the installation of 12 is completed, the vacuum valve 13 is opened to form a space between the inner tank 11 and the outer tank 12 as a vacuum.

The spring 14 is installed in a coil shape between the inner tank 11 and the outer tank 12, as shown in Figure 2 to fill the space between the inner tank 11 and the outer tank 12 When the vacuum is maintained, the inner tank 11 and the outer tank 12 are prevented from being crushed, deformed or broken.

At this time, the spring 14 and the inner tank 11 may be further attached to the cushioning material 15, the cushioning material 15 is between the inner tank 11 and the outer tank 12 When the vacuum is formed, it is possible to prevent deformation of the inner tank 11, and as the water inside the inner tank 11 is heated, the inner tank 11 is expanded to the inner tank ( Even if the pressure between 11) and the spring 14 increases, the pressure may be relaxed to prevent the inner tank 11 from being deformed or broken.

On the other hand, the heat storage tank according to the present invention is a heat exchange coil 40 for heat-exchanging the cold water inside with hot water using the hot water contained in the inner tank 11, and is connected to the inlet side of the heat exchange coil 40 tap water A tank cold water inlet 41 for introducing cold water into the heat exchange coil 40 from a supply pipe 42 and an outlet side of the heat exchange coil 40 are connected to a tank hot water discharge pipe from the heat exchange coil 40. It may be configured to further include a tank hot water outlet 43 for discharging the hot water discharged through 44.

On the other hand, inside the inner tank 11, the heater rod 54 as an auxiliary heat source for heating the water in the inner tank 11 when the hot water contained in the inner tank 11 is lowered below a predetermined temperature. This may be further provided as shown in Figure 3, the heater rod 54 receives the external power to heat the water inside the inner tank (11). 2 is a schematic explanatory view of a heat storage tank according to the present invention, in FIG. 2, reference numeral 16 denotes an inlet for initially introducing water into the inner tank, 17 a pedestal, and 18 discharges water in the inner tank to the outside. Discharge valves, 25, 36 and 45 are circulation pumps, 27 are reflectors, 51 are auxiliary tanks, and 52 are safety valves. In addition, Figure 3 is an external view of the heat storage tank according to the present invention, the location of each connection port is different from the Figure 2 for convenience of explanation, the actual location of the connection port is based on Figure 3, 61 in Figure 3 Is the temperature gauge, 62 is the temperature sensor, and 63 is the pressure gauge.

In the heat storage tank according to the present invention having the above configuration, when sunlight is collected from the collector 26 installed outdoors as shown in FIG. 2, the heat heats the water circulating in the collector 26, The heated hot water is introduced into the inner tank 11 through the tank inlet pipe 22, and again the hot water inside the inner tank 11 is collected in the collector 26 through the collector inlet pipe 24 for reheating. The furnace is heated and heated.

In this state, when the user wants to heat the place requiring heating, when the heating circulation pump 36 is operated, the hot water contained in the inner tank 11 receives a predetermined heating load 35 through the heating water supply pipe 34. The heating is supplied to the furnace, and the heating water recovered from the heating load 35 is recovered to the inside of the inner tank 11 again through the heating water collection pipe 32.

In addition, when the user needs hot water, the cold water introduced into the heat exchange coil 40 through the tank cold water inlet 41 through the tap water supply pipe 42 is heated while being heated by the hot water contained in the inner tank 11, The heated hot water is discharged through the tank hot water discharge pipe 44 so that hot water can be used.

However, in the heat storage tank according to the present invention, the outer tank 12 is surrounded by the outside of the inner tank 11, and the vacuum is formed between the inner tank 11 and the outer tank 12, as in the prior art. It is possible to obtain an excellent heat insulating effect without the need to install a heat insulating material on the outside of the inner tank (11).

In addition, the heat storage tank according to the present invention is installed between the inner tank 11 and the outer tank 12 in the form of a coil 14 in the coil shape between the inner tank 11 and the outer tank 12 Since the inner tank 11 and the outer tank 12 are all parts of the inner tank 11 and the outer tank 12 are evenly supported by the spring 14 when the space is to be vacuumed, Pressure is suddenly applied to any part of the inner tank 11 or the outer tank 12 to prevent the inner tank 11 or the outer tank 12 from being deformed or damaged while being crushed, and further, the inner tank 11 Since the cushion material 15 is inserted between the spring 14 and the outside of the), when the space formed between the inner tank 11 and the outer tank 12 is formed in a vacuum, Negative pressure does not act directly on the wall of the inner tank (11). Since first, the cushioning material 15 is caught, the force applied to the inner tank 11 can be reduced as much as possible, thereby preventing deformation of the inner tank 11, and by the pressure inflated inside the inner tank 11, Even if the deformation of the tank 11 occurs, the pressure applied between the inner tank 11 and the spring 14 by the cushion member 15 can be reduced, so that deformation of the inner tank 11 can be prevented, so that the inner tank The phenomenon in which the vacuum state formed between the 11 and the outer tank 12 is destroyed can be prevented.

While specific embodiments of the present invention have been described above by way of example, these are for illustrative purposes only and are not intended to limit the protection scope of the present invention. It will be apparent to those skilled in the art that various changes, substitutions, and alterations can be made therein without departing from the spirit of the invention.

11: inner tank 12: outer tank
13: vacuum valve 14: spring
21: tank inlet 23: tank outlet
31: heating water recovery port 33: heating water supply port

Claims (3)

An inner tank 11 having a receiving space formed therein;
A tank inlet (21) for introducing hot water heated in a collector (26) installed outside of the inner tank (11) into the inner tank (11);
A tank outlet 23 for flowing hot water contained in the inner tank 11 to the collector 26;
A heating water supply port 33 for supplying hot water contained in the inner tank 11 to the heating load 35;
A heating water recovery port 31 for recovering the heating water recovered from the heating load 35 to the inner tank 11;
An outer tank 12 installed outside the inner tank 11 to surround the inner tank 11;
A vacuum valve (13) for maintaining a vacuum formed in the space formed between the inner tank (11) and the outer tank (12); And
When installed in a coil shape between the inner tank 11 and the outer tank 12 to maintain a space between the inner tank 11 and the outer tank 12 in a vacuum, the inner tank 11 and And a spring (14) for preventing the outer tank (12) from being deformed. The method of claim 1,
A heat exchange coil 40 for heat-exchanging cold water therein with hot water by using hot water contained in the inner tank 11;
A tank cold water inlet (41) connected to an inlet side of the heat exchange coil (40) for introducing cold water from the tap water supply pipe (42) to the heat exchange coil (40);
And a tank hot water outlet (43) connected to the outlet side of the heat exchange coil (40) to discharge hot water discharged from the heat exchange coil (40). The method according to claim 1 or 2,
The inner tank 11 is a heat storage tank, characterized in that the cushion material 15 is attached to the outer circumference.

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