KR101795292B1 - A blind board apparatus solar-heat heating device of combination a boiler for anti-superheating - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a solar energy heating apparatus and a solar energy heating apparatus for preventing overheating of solar heaters using solar energy.
That is, a solar heat storage device is formed on the roof (A), a heat storage tank and a boiler are formed on the room (B), and the heating water heated by the solar heat storage device and the boiler is heated to the heating place (C) The shielding film 81 is wound around the outer periphery of the operating shaft 83 rotated by the driving motor 91 and released to the solar heat storage device 10 of the solar heating device combined with the superheat prevention boiler for heating the heating place, A screening device 60 for opening and closing the front surface of the apparatus 10 is additionally provided to shield the solar heat from the front surface of the solar heat storage device 10 with the shielding film 81 to prevent the solar heat storage device 10 from being overheated. The solar heat storage device 10 is provided with a separate screening device on the front surface thereof so as to stably prevent overheating of the solar heat storage device .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a solar heating apparatus,

More particularly, the present invention relates to an overheating prevention device for preventing overheating of a solar collector using solar energy by mechanically preventing the overheat of the solar collector, To a screening apparatus for a solar heating apparatus combined with a boiler.

Generally, it is common to use a boiler to burn oil or gas to supply heating and domestic hot water. However, fossil fuels such as oil and gas have limited reserves, As the problem of pollution increases, the development and necessity of environmentally friendly alternative energy is expanding.

In recent years, in order to reduce heating costs and prevent environmental pollution, the heat transmitted through the solar heat collecting plate is directly used for heating, or is stored in a separate heat storage tank, and then a solar heating device used for heating is installed. A heating and hot water system in which a boiler for heating a boiler or heating a boiler to use it as an auxiliary heat source and a solar heat storage tank has been proposed.

However, since most of the heating and hot water systems that connect the boiler and the solar heat storage tank operate the solar heat storage tank and the boiler at the same time to supply heating water and hot water to the indoor space, unnecessary energy consumption of the solar heat storage tank and the boiler is high, Not only the efficiency is relatively large but also all of the operations are complicated and installation costs are high.

As an example, in the Publication No. 10-2011-0079035 (published on Jul. 07, 2011), there is provided a heat collecting device comprising: a heat collecting means; and a heat accumulating means for storing solar energy absorbed by the heat collecting means, 1. A solar heating apparatus comprising a tank, a boiler for replenishing a sufficient amount of heat for heating and heating, and a hot water tank for passing hot water through the heat storage tank and the boiler for hot water supply, The heat collecting means, the heat storage tank, the boiler; Wherein a heater is disposed inside the heat storage tank to supply energy by using low-temperature nighttime electricity when the solar energy for hot water supply or heating is insufficient, and a boiler heat source complementary switching system But it has disadvantages that the operation is complicated, the installation cost is high, and the efficiency of the solar energy is not relatively large.

In addition, in the registered patent publication No. 10-1090376 (registered date November 30, 2011), the fluid from the supply distribution pipe 20 is heated by the solar heat storage device 10 and then returned to the recovery distribution pipe 21 A solar heating circuit coming in; The fluid discharged from the supply distribution pipe 20 or the recovery distribution pipe 21 is drawn into the chamber 30 to heat the chamber 30 and then returned to the recovery distribution pipe 21 or the supply pipe 20 A circuit; And a heat storage circuit for returning the fluid from the recovery and distribution pipe 21 to the supply distribution pipe 20 after passing through the heat storage tank 20. The solar heat storage system includes a solar heat storage device, a distribution pipe, a heat storage tank, In addition, it was applied to Korea where the oil boiler is connected with the heat storage tank and the solar heat storage device and divided into the summer season and the winter season, so that the oil boiler Not only the energy efficiency at the time of operation is lowered but also the energy efficiency is remarkably different according to the difference of the external temperature.

Recently, as can be confirmed through Registration No. 10-1488089 (Jan. 23, 2015) invented by the inventor of the present invention, a solar heating storage device, a heat storage tank and a boiler are constituted and connected to each other through a heating circuit A solar heating apparatus for heating a boiler for preventing overheating by moving heating water heated by a solar heating plate and a boiler to a heating place,

The heating water heated by the solar heat storage device 10 is supplied to the heating means 50 connected to the heating pipe 18 equipped with the heating pump P to heat the heating space C and then the heating means 50 A solar heating circuit (1) for allowing the solar heat storage device (10) to flow into the solar heat storage device (10) through a heat recovery pipe (14)

The heating water held in the heat storage tank 20 through the heat storage supply pipe 21 equipped with the heating pump P connected to the heat storage tank 20 and the heating supply pipe 18 communicates with the heating supply pipe 18 The heating space C is heated through the heating means 50 and the heating water discharged to the heating return pipe 14 is supplied to the heat storage tank 22 through the heat storage recovery pipe 22 connected to the heating return pipe 14 20 directly into the heating circuit (2);

The heating water heated in the boiler 30 is supplied to the heating pipe 18 through the boiler feed pipe 31 equipped with the heating pump P connected to the boiler 30 and the heating pipe 18 so as to communicate with each other, The heating space C is heated through the means 50 and then the heating water discharged to the heating return pipe 14 is returned to the boiler 30 through the boiler return pipe 32 connected to the heating return pipe 14 And a heating circuit (3) for preventing the overheating of the boiler, and a solar heating device for preventing overheating, wherein the heat source of the solar heat and the heat source of the boiler can be sequentially used, By supplying the heat source to the heating space, it is possible to reduce the energy required for heating while increasing the efficiency of the solar energy, It is possible to prevent the heating and freezing of the solar heat storage device from being overheated due to the problem of separately configuring each individual pump for operating each heating circuit and the problem of not being able to effectively prevent overheating of the summer heat storage device It is in a state of being unable to substantially observe the effect of protection of the solar heat storage device due to the sudden temperature difference due to the seasonal change and the cost of the installation cost compared with the energy efficiency.

In this way, the conventional solar heating apparatuses have a risk of overheating of the solar collectors due to the lack of preparation for the high temperature phenomenon in the summer especially in the country where the temperature change is extreme, The installation cost for constructing a plurality of driving devices constituted for use in combination with a boiler as well as necessary facilities for utilizing the same is high. Therefore, when the boiler facility and the solar heating device are used separately and in combination It is not possible to propose a solution to solve the fundamental problem to be solved by the manufacturer that manufactures the heating device or the installation company that installs the heating device.

KR Patent Publication No. 10-2011-0079035 KR Patent No. 10-1090376 KR Patent No. 10-1488089

Accordingly, it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a solar heating circuit for heating a hot water heated by solar heat generated in a solar heat storage device, A boiler heating circuit for heating the hot water generated by operating a normal boiler, and a heat accumulation heating heating circuit for heating the hot water stored in the heat storage tank by a boiler, It is possible to prevent overheating of solar heat storage device mechanically by installing a separate screening device in the solar heat storage device, thereby improving the durability of the solar heating circuit as well as preventing heating and freezing of heating water But it is easy to operate, low installation cost, and solar energy The present invention aims at solving the above problems in order to provide an over-heating preventive apparatus for a solar heating apparatus combined with a boiler having a high efficiency.

The present invention relates to a solar heating apparatus for a solar heating apparatus combined with a boiler for preventing overheating, wherein a solar heat storage apparatus is constructed on the roof, a heat storage tank and a boiler are arranged in the room, A curtain thinning apparatus for a solar heating apparatus combined with a boiler for preventing overheating, the curtain heating apparatus comprising:

The heating water heated by the solar heat storage device 10 is supplied to the heating supply pipe 18 connected to the solar heat supply pipe 13 through the installed heating pump P and is supplied to the heating space C) and then flows into the solar heat storage device (10) through a heat recovery pipe (14) connected to the heating means (50);

The heating water supplemented into the heat accumulation tank 20 is supplied to the heating supply pipe 18 connected to the heat storage supply pipe 21 through the installed heating pump P and is supplied to the heating space The heating water discharged to the heating return pipe 14 connected to the heating means 50 is introduced into the heat storage tank 20 through the heat storage recovery pipe 22 connected to the heating return pipe 14 A heat storage direct heating circuit 2;

The heating water heated by the boiler 30 is supplied to the heating supply pipe 18 connected to the boiler supply pipe 31 equipped with the heating pump P so that the heating space C is heated through the heating means 50 A boiler heating circuit 3 for introducing the heating water discharged to the next heating return pipe 14 back into the boiler 30 through a boiler return pipe 32 connected to the heating return pipe 14;

The heating water supplemented into the heat storage tank 20 is supplied to the boiler 30 through the heat storage supplement pipe 33 and the heating water heated by the boiler 30 is connected to the boiler supply pipe 31, Is supplied to the heating supply pipe 18 connected through the heating pump P to heat the heating space C through the heating means 50 and then the heating water discharged to the heating return pipe 14 is supplied to the heating return pipe 14 And a heat storage heating circuit (4) for flowing back to the boiler through a boiler return pipe (32) connected to the solar heat storage device (10) 60 for preventing the solar heat storage device 10 from being overheated by intercepting the solar heat by the shielding film 81 on the front surface of the solar heat storage device 10 during the summer season, The thin film device of .

As described above, according to the present invention, there is provided a solar heating apparatus for a solar heating apparatus which is combined with a boiler for preventing overheating, comprising a solar heating circuit, a heat storage direct heating circuit, a boiler heating circuit and a heat storage heating circuit, It is possible to sequentially supply the heat source necessary for heating to the heating space sequentially without any operation according to the weather conditions and to provide a separate screening device so as to increase the efficiency of the solar energy and reduce the energy required for heating In addition to being able to prevent overheating of heating water generated in the summer solar heating plate mechanically and safely as well as to prevent freezing in winter, it is easy to operate, low installation cost, Low maintenance cost, high heat A very significant effect that all of the present invention without a significant burden overload preventing solar heating it combine with the ratio is very large bar invention will be readily expected that in a variety of clear advantages to be installed by using each home.

1 is an overall heating circuit diagram showing a preferred embodiment of the present invention.
2 is a circuit diagram of a solar heating circuit showing a preferred embodiment of the present invention.
FIG. 3 is a heat accumulation heating circuit diagram showing a preferred embodiment of the present invention. FIG.
FIG. 4 is a circuit diagram of a boiler heating circuit showing a preferred embodiment of the present invention. FIG.
FIG. 5 is a heat accumulating heating circuit diagram showing a preferred embodiment of the present invention. FIG.
FIG. 6 is a circuit diagram of a heating water storage and heating circuit showing a preferred embodiment of the present invention. FIG.
7 is a freeze prevention circuit diagram showing a preferred embodiment of the present invention.
FIG. 8 is a circuit diagram of an emergency frost prevention circuit showing a preferred embodiment of the present invention. FIG.
FIG. 9 is a circuit diagram of a solar thermal overheating prevention circuit showing a preferred embodiment of the present invention. FIG.
10 is a use state view of a screening apparatus showing a preferred embodiment of the present invention.
11 is a front structural view of a screening apparatus showing a preferred embodiment of the present invention.
FIG. 12 is a left side view of a screening apparatus showing a preferred embodiment of the present invention. FIG.
FIG. 13 is a right side view of a screening apparatus showing a preferred embodiment of the present invention. FIG.
FIG. 14 is a cross-sectional view taken along the line II-II 'of FIG. 11 showing a preferred embodiment of the present invention.
Fig. 15 is an operating state view of a screening apparatus showing a preferred embodiment of the present invention. Fig. 15 (a) is an operating state for sealing the screening film, and Fig. 15 is an operating state for opening the screening film.

The present invention relates to a solar heating apparatus for a solar heating apparatus combined with a boiler for preventing overheating, which comprises a solar heat storage device on a roof (A) and a heat storage tank and a boiler in a room (B) (C), the heating water heated by the solar heat storage device and the boiler is moved so as to heat the heating space.

The heating water heated by the solar heat storage device 10 is supplied to the heating supply pipe 18 connected to the solar heat supply pipe 13 through the installed heating pump P and is supplied to the heating space C) and then flows into the solar heat storage device (10) through a heat recovery pipe (14) connected to the heating means (50);

The heating water supplemented into the heat accumulation tank 20 is supplied to the heating supply pipe 18 connected to the heat storage supply pipe 21 through the installed heating pump P and is supplied to the heating space The heating water discharged to the heating return pipe 14 connected to the heating means 50 is introduced into the heat storage tank 20 through the heat storage recovery pipe 22 connected to the heating return pipe 14 A heat storage direct heating circuit 2;

The heating water heated by the boiler 30 is supplied to the heating supply pipe 18 connected to the boiler supply pipe 31 equipped with the heating pump P so that the heating space C is heated through the heating means 50 A boiler heating circuit 3 for introducing the heating water discharged to the next heating return pipe 14 back into the boiler 30 through a boiler return pipe 32 connected to the heating return pipe 14;

The heating water supplemented into the heat storage tank 20 is supplied to the boiler 30 through the heat storage supplement pipe 33 and the heating water heated by the boiler 30 is connected to the boiler supply pipe 31, Is supplied to the heating supply pipe 18 connected through the heating pump P to heat the heating space C through the heating means 50 and then the heating water discharged to the heating return pipe 14 is supplied to the heating return pipe 14 A heat storage heating circuit (4) for flowing back to the boiler through a boiler return pipe (32) connected to the boiler;

Temperature heating water heated by the solar heat storage device 10 is stored in the heat accumulation backflow pipe 25 which communicates the solar heat supply pipe 13 and the heating supply pipe 18 and is then supplied to the pump connection pipe Pp of the heating pump P, And a heating water storage and heating circuit (5) for allowing the water to flow into the heat storage tank (20) through the heat storage connection pipe (21) connected to the heat storage tank (20) and then discharging it to the necessary heating facilities.

At this time, in constructing the solar heating circuit (1), a plurality of solar heat storage devices (10) are sequentially connected according to the entire heating range required only in the roof (A) The water replenishment tank 12 communicating with the heating water replenishment pipe 15 having the heating water replenishment electromagnetic valve 15v constituted only on the upper part of the one solar heat storage device 10 directly connected to the solar heat accumulator 10 10 to the quantity replenishing tank 12 and constitutes a high temperature sensor 13s at the starting point of the solar heat pipe 13 connected by the solar heat storage device 10 And the solar hot water supply electronic valve 13v is formed at the end point of the solar heat supply pipe 13 connected to the pump connection pipe Pp constituting the inflow portion side of the heating pump P, The heating water supply pipe (18) And is connected to one side of the heating means 50 and connected to the other side of the heating means 50 from the solar heat storage device 10 side of the heating return pipe 14 to the low temperature detection sensor 14s And a plurality of heating water recovery electronic valves 14va and 14vb are sequentially formed (see Fig. 2).

In addition, in the construction of the heat accumulation direct heating circuit 2, the heat storage tank 20 having the heat storage water level sensor 20t and the heat storage temperature sensor 20s provided in the room B and the heat supply pipe 18 Is connected to one side of the storage tank 20 at one end and to the pump connection pipe Pp at the other end of the heat pump P, The heat accumulation recovery pipe 22 having the regenerative hot water supply electronic valve 21v at the end point of the heat storage supply pipe 21 and connecting the heat storage tank 20 and the heat recovery pipe 14 has one end connected to the heat storage tank 20, And the other end is connected to the heating return pipe 14 between the plurality of hot water returning electromagnetic valves 14va and 14vb while the heat accumulating returning electromagnetic valve 22v is formed in the heat storage returning pipe 22, Is connected to the heat recovery pipe (14) between the low temperature sensor (14s) and the hot water recovery electromagnetic valve (14vb), which is led out from the upper part of the heat storage tank (20) A heat storage pressure discharge pipe 23 having a discharge exhaust valve 23v and a heat storage drain pipe 24 leading to a lower portion of the heat storage tank 20 and opening to the outside and having a drain valve 24v, (See Fig. 3)

The boiler supply line 31 connecting the boiler 30 installed in the room B to the heating supply line 13 is connected to the boiler 30 at one end thereof And the other end is connected to a pump connection pipe (Pp) communicating with a plurality of communication pipes at the inflow portion of the heating pump (P), and a boiler supply electronic valve (31v) is connected to the end point of the boiler supply pipe (31) One end of the boiler return pipe 32 connecting the boiler 30 and the heat recovery pipe 14 is connected to the boiler 30 and the other end thereof is connected to the respective hot water recovery electromagnetic valves 14va (14vb), and the boiler returning tube (32) is constituted by the boiler returning electromagnetic valve (32v) (see Fig. 4).

The heat storage supply pipe 21 connecting the heat storage tank 20 provided in the room B and the heating supply pipe 18 is connected to one end of the heat storage tank 20 (21v) is connected to an end of the heat storage supply pipe (21) which connects the other end of the heat pump (P) to a side of the heat pump (P) And a heat storage recovery pipe 22 connecting the heat storage tank 20 and the heat recovery pipe 14 has one end connected to one side portion of the heat storage tank 20 and the other end connected to a plurality of hot water recovery The heat accumulation recovery valve 22 is connected to the heating return pipe 14 between the electronic valves 14va and 14vb and constitutes the heat accumulation recovery electronic valve 22v in the heat accumulation recovery pipe 22. The low temperature detection sensor 14s ) And the hot water recovering electromagnetic valve (14vb), while the heat storage pressure having the pressure exhausting electromagnetic valve (23v) And chulgwan 23, is led to the lower portion of the heat storage tank 20 but open to the outside, respectively constitute a heat storage water pipe 24 is provided with a drain solenoid valve (24v), and;

One end of a boiler feed pipe 31 for connecting a boiler 30 installed in the room B and the heating pump P is connected to the boiler 30 and the other end is connected to the inlet portion of the heating pump P A boiler feed detection sensor 31s is connected to the boiler feed pipe 31 at one end thereof and a boiler feed detection sensor 31s is connected to the connection pipe Pp at an end point of the boiler feed pipe 31. The boiler 30 and the heat recovery pipe 14 One end of the connecting boiler return pipe 32 is connected to the boiler 30 and the other end is connected to the heating return pipe 14 between the respective hot water returning electronic valves 14va and 14vb, And one end of the heat storage supplementary pipe 33 connecting the boiler return pipe 32 and the heat storage supply pipe 21 is connected to the heat storage tank 20 and the heat storage recovery electromagnetic valve 21v And the other end is connected to the boiler return pipe 32 between the boiler 30 and the boiler return electromagnetic valve 32v Are each configured to be a heat storage replacement tube can supplement the heat storage (33) solenoid valve (33v). (See Fig. 5)

A heating water storage and heating circuit 5 for storing the hot water generated by the solar heat storage device 10 in the heat storage tank 20 so that the heat storage direct heating circuit 2 and the heat storage heating heating circuit 4 can proceed, Is connected to a heat accumulation backflow pipe (25) having an accumulator backflow electromagnetic valve (25v) so that the solar heating pipe (13) constituting the solar heating circuit (1) and the heating supply pipe (18) are in direct communication with each other, Is connected to the heating supply pipe 18 between the heating pump P and the hot water supply pipe 19 and the other end is connected to the solar heat supply pipe 13 adjacent to the solar heat supply electronic side 13v.

That is, when the heating water heat accumulating and heating circuit 5 is constructed, the high temperature sensor 13s is constituted at the starting point of the solar heat supply pipe 13 connected by the solar heat storage device 10 provided on the roof A, The solar hot water supply electronic valve 13v is formed at the end point of the solar heat pipe 13 connected to the pump connection pipe Pp constituting the inlet side of the pump P and the connection of the discharge side of the heating pump P One end of which is connected to the heating pipe 18 between the heating pump P and the hot water supply pipe 19 and the other end of which is connected to the solar heating electronic supply side And a regenerative back flow electromagnetic valve (25v) connected to the solar heat supply pipe (13) adjacent to the regenerative back flow pipe (13v);

The heat storage supply pipe 21 connecting the heat storage tank 20 and the heat supply pipe 18 installed in the room B is connected to one side portion of the heat storage tank 20 at one end and the other end is connected to a heat pump And the heat storage tank 20 and the heat recovery pipe 14 are provided at the ends of the heat storage supply pipe 21 connected to the pump connection pipe Pp constituting the inlet side of the heat storage tank 20, One end of the heat accumulation recovery pipe 22 to be connected is connected to one side of the heat storage tank 20 and the other end is connected to the heat recovery pipe 14 between the plurality of hot water recovery electrons 14va and 14vb The heat accumulation recovery pipe 22 constitutes a heat accumulation recovery electronic valve 22v and is connected to the heat recovery pipe 14 between the low temperature sensor 14s and the hot water recovery electronic valve 14vb, A heat storage pressure discharge pipe 23 provided with a pressure exhausting electromagnetic valve 23v, and a condenser 23 which is connected to the lower part of the heat storage tank 20 and opens to the outside, (See Fig. 6). The heat storage and drainage pipe 24 has a plurality of heat storage tubes 24v.

At this time, a hot water supply pipe 19 having a hot water supply electronic valve 19v is connected to the heating supply pipe 18 between the heating pump P and the heating supply electronic valve 18v, and the hot water recovery electronic valve 14va, It is preferable to construct a replenishing water supply pipe 17 having a replenishing water supply electronic valve 17v connected to the heating return pipe 14 between the boiler return pipes 32 to supply the replenishing water outside.

The apparatus for preventing overheating of the solar heating apparatus according to the present invention comprises a heating state of the heating space and the operation of the solar heat storage apparatus 10 as well as the water temperature of the heating water held in the heat storage tank 20, The heating operation of the respective heating circuits is progressed according to the outside temperature of the heat storage device 10, so that the respective heating circuits can be implemented in accordance with the respective drawings shown in the drawings of the embodiment of the present invention. A detailed example is given below.

2, the heating water, which has increased in temperature from the solar heat in the solar heat storage device 10, is supplied to the inflow portion side of the heat pump P via the solar heat supply pipe 13 by operating the heat pump P, The heating space C is supplied to the heating means 50 through the heating pipe 18 connected to the discharging portion through the inlet of the heating pump P through the pump connection pipe Pp to heat the heating space C, The heating space C is heated by heating the solar water as an energy source through the solar heating circuit 1, which is returned to the solar heat storage device 10 through the heat exchanger 14.

That is, the heating pump P is operated in a state in which the minimum temperature of the high temperature sensor 13s formed in the solar heat pipe 13 on the side taken out from the solar heat storage device 10 is set to 50 ° C, 10, the high temperature sensor 13s stops the operation of the heating pump P, and when the heating water in the solar heat storage device 10 is heated to 50 DEG C or higher, The heating water P flowing through the solar heat pipe 13 is discharged through the heating pipe 18 through the heating pump P so as to heat the heating space C so that the temperature of the heating water remains The heat is recovered to the solar heat storage device 10 through the heat recovery pipe 14 so that the heating of the solar heat storage device 10 and the heating of the heating space C are efficiently performed.

At this time, in order to efficiently flow the heating water, the heat storage supply electromagnetic valve 21v and the regenerative back flow electromagnetic valve 25v are opened in a state in which both the solar supply electronic valve 13v, the hot water supply valve 18v and the hot water recovery valve 14va The supplementary water supply electronic valve 17v, the hot water supply electronic valve 19v and the pressure discharge electromagnetic valve 23v are closed as well as the boiler feeder electromagnetic valve 31v, the heat accumulation recovery electromagnetic valve 22v and the boiler recovery electromagnetic valve 32v .

In addition, since the solar heat storage device 10 has a structure in which heating water is heated by the sun when power is supplied, when the solar heat storage device 10 is in operation and heating is not required, And the heating water is used in a scaled manner by rotating the heating pump P in the reverse direction so that the heating water heated by the solar heat in the solar heat storage device 10 is supplied to the solar heat supply pipe 13, Is supplied to the heat storage tank 20 through the heat storage supply pipe 21 connected to the pump connection pipe Pp through the heating pump P and then the heat storage water is supplied to the heat storage tank 20 (20st), the heat is recovered to the solar heat storage device (10) through the heat recovery pipe (14) again through the heat storage recovery pipe (22) or discharged to the outside through the heat storage drain pipe The circuit (5) To heat the heater to be stored in the heat storage tank (20).

That is, in the state where the lowest temperature of the high temperature sensor 13s formed in the heating supply pipe 18 on the side of the solar heat storage device 10 is set at 50 占 폚, the number of heating water discharged from the solar heat storage device 10 is 50 The heating pump P is rotated in the reverse direction while the heating water is heated to 50 DEG C or more in the solar heat storage device 10 so that the solar heat storage P The heating water heated by the solar heat in the apparatus 10 is sequentially passed through the solar heat supply pipe 13, the heat storage backflow pipe 25 and the heating supply pipe 18 and connected to the pump connection pipe Pp through the heating pump P And the heat is supplied to the heat storage tank 20 through the heat storage supply pipe 21 to collect the hot water of high temperature inside the heat storage tank 20. (See FIG. 6)

At this time, in order to efficiently flow the hot water, only one heat recovery electromagnetic valve 14vb is opened while only one heat storage electromagnetic valve 25v, the heat storage supply electromagnetic valve 21v, the heat storage recovery electromagnetic valve 22v and one hot water recovery electromagnetic valve 14vb are opened, The boiler feeder electronic valve 31v and the hot water supply valve 18v and the makeup water supply valve 17v and the hot water supply valve 19v and the boiler return valve 32v are closed It may be desirable to have the

When the temperature of the heating water flowing into the heat storage tank 20 is higher than 95 ° C when the maximum temperature of the heat storage temperature sensor 20s in operation is set to 95 ° C, The pressure exhausting electromagnetic valve 23v is opened to prevent the pressure rise due to the heating water stored in the heat exchanger 20 and the gasified pressure water is discharged through the heat storage pressure discharge pipe 23 to the heat recovery pipe 14 It is preferable to stop the operation of the heating pump P so as to stop the supply of the heating water when the water level of the storage water level detection sensor 20t for measuring the water level of the heating water reaches the set water level.

At this time, when the temperature of the heating water is a high temperature of 95 ° C or more, the heat storage recovery electromagnetic valve 22v is closed and the drainage electromagnetic valve 24v is opened so that the heating water in the heat storage tank 20 is recovered to the heat storage recovery pipe 22 The replenishment water supply valve 17v is opened to fill the amount of heating water that is lost to the outside through the heat storage drain pipe 24 to supply the replenishment water supply pipe 17 The heating water is prevented from being overheated by the solar heat storage device 10 and the heating water is supplied to the solar heat storage device 10 through the heating / It can be seen that it is a circuit that is essential for the summer season in which the outside temperature is maintained at room temperature or more.

However, in the above-mentioned overheat preventing circuit 6, the temperature of the solar heat storage device 10 is drastically increased at the noon during the summer, and not only is the overheat of the regenerator 11b for storing the solar heat even by the operation of the overheat preventing circuit 6, The temperature of the outside of the apparatus 10 itself rapidly increases, shortening the life and durability of the solar heat storage device 10, so that the present invention requires a separate screening device 60 to protect the solar heat storage device 10 from the summer heat do.

A fixed structure 70 formed by fixing a guide rail 71 having a plurality of unit bearings 73 to the guide groove 72 by a support base 75 and a fixing piece 74 so as to be kept symmetrically inclined, and;

The shielding structure 80 is constructed so that the shielding film 81 is wound around the outer diameter of the operation shaft 82 while the reference shaft 83 and the operation shaft 82 are kept parallel to each other and the end of the shielding film 81 is connected to the center of the outer diameter. and;

A working structure 90 having a guide bar 92 formed on one outer side of the fixed structure 70 and having a guide block 93 fixed parallel to the guide rail 71 and fixed to the outer diameter of the drive motor 91, And fixed to opposite ends of the operation shaft 82 to the upper unit bearing 73 of the plurality of unit bearings 73 slidable in the guide grooves 72 of the guide rail 71. The lower unit bearings 73 And the one end of the operating shaft 82 is connected to the motor shaft 92 of the driving motor 91 constituting the operating structure 90. In this case, One end of the damper string 94 is fixed to the outer diameter of the operation shaft 82 between the unit bearings 73 and the other end thereof is fixedly connected to the fixing piece 74 constituting the upper end of the fixed structure 70, (60). (See Figs. 11 to 15)

The screening apparatus 60 used to protect the solar heat collecting apparatus 10 configured as described above is constructed by a solar heat collecting apparatus 10 having a plurality of heat collecting units 11b formed below a collecting column 11a fixed by a fixed column 11c, The shielding film 81 is held on the entire surface of the regenerator 11b of the main body 10 so that the shielding film 81 is opened and closed at an angle similar to the inclination angle of the regenerator 11b, It can be seen that the solar heat collecting apparatus 10 provided therein can be shielded from solar heat. (See Fig. 10)

When the motor shaft 92 is rotated in the forward direction by operating the drive motor 91 in the forward rotation when the temperature of the solar heat collection apparatus 10 is equal to or higher than a predetermined temperature, the motor shaft 92 is connected to the coupling 95 The one end of the spiral cord 94 connected to both sides of the operation shaft 82 is rotated around the outer diameter of the operation spindle 82 by the rotation of the operation spindle 82, The upper end of the curtain 81 held at the outer periphery of the center of the operating shaft 82 is moved forward by the forward rotation of the operating shaft 82, The shielding film 81 gradually covers the entire surface of the solar heat collecting apparatus 10 while being moved upward along the operation shaft 82 while the shielding film 81 is loosened.

At this time, the unit bearing 73 fixed to both ends of the operating shaft 82, which is moved upward by the retaining rods 94 while being rotated, is slid upward along the guide grooves 72 of the guide rails 71 The drive motor 91 fixed to the guide block 93 as well as the guide block 92 moves upward together with the guide block 93 slidably mounted on the guide rod 92. Therefore, It is possible to protect the solar heat collecting apparatus 10 including the heat accumulating unit 11b from the foreign substances moving by the wind from the outside as well as the solar heat by covering the front surface of the regenerator 11b with the covering film 81 spreading. .

When the drive motor 91 is rotated in the opposite direction to the direction of rotation of the drive motor 91, the drive shaft 91 is rotated while the drive shaft 82 is rotated in the opposite direction while rotating the drive motor 91 And the reverse rotation of the shielding structure 80 are opposite to each other, so that the detailed description will be omitted.

At this time, the fixed cap 85 formed at both ends of the operation shaft 82 and the reference shaft 83 prevents the operation shaft 82 and the reference shaft 83 from deviating freely from the unit bearing 73.

When the heating water heated by the solar heat storage device 10 is heated to a high temperature during the operation of the solar heating circuit 1 and the heating water storage and heating circuit 5, the volume of the heating water is expanded and the pressure of the solar heat storage device 10 becomes high. The maximum temperature of the high temperature sensor 13s formed on the solar heat pipe 13 drawn out from the solar heat storage device 10 is set to 95 deg. C to prevent the expansion and overpressure of the heat pump 10, P is activated and the hot water sensor 13s senses that the heating water discharged from the solar heat accumulator 10 is 95 DEG C or higher, the heating water supplementing electromagnetic valve 15v is opened, and the heating water is supplied to the heating water supplement pipe 15 so that the high temperature steam generated in the solar heat accumulator 10 flows into the heating water replenishment pipe 15 through the air exhaust pipe 16, The heat retaining device 10 When the quantity of the number may not be enough to supplement that by opening the heating makeup water solenoid valve (15v) holding a quantity replenishment tank 12 so as to supplement the number of heating to ensure that flows into the solar thermal storage apparatus 10.

At this time, it is preferable that the water level and the inflow temperature of the replenishing water to be replenished in the water replenishment tank 12 are adjusted through a separate replenishment water level sensor 12t and replenishment temperature sensor 12s (see FIG. 6) )

The heating water stored in the heat storage tank 20 through the heating water heat accumulating and circulating circuit 5 is heated when the heating space C is required to be heated in the state where the solar heat storage device 10 is not operated at night or in a bad weather, The heating water P accumulated in the heat storage tank 20 is connected to the heat storage supply pipe 21 through the heating water storage and heating circuit 5 and is supplied to the heating means 50 through the heating supply pipe 18 The heating space C is heated and then the solar heat is heated as an energy source through the heat accumulation direct heating circuit 2 that is returned to the heat accumulation tank 20 through the heat accumulation pipe 22 through the heat recovery pipe 14 And then the heating space C is heated by the heating water stored in the heat storage tank 20.

That is to say, the temperature of the heating water held in the heat storage tank 20 by operating the heating pump P in a state where the lowest temperature of the heat accumulation temperature sensor 20s built in the heat storage tank 20 is set to 50 캜 The heat accumulation temperature detection sensor 20s stops the operation of the heating pump P and the heating pump P is operated in a state where the heating water is kept at 50 ° C or more in the solar heat storage device 10 The heating water in the heat storage tank 20 is heated through the heating supply pipe 18 communicating with the heat storage supply pipe 21 and then the heat storage recovery pipe 22 communicating with the heating return pipe 14 The heating water is recovered to the inside of the heat storage tank 20 in a state where the temperature of the heating water remains, so that the heating of the heating space C can be efficiently performed without any additional energy consumption (see FIG. 3).

At this time, in order to efficiently flow the heating water, only the heat storage supply electromagnetic valve 21v and the hot water supply electromagnetic valve 18v, one hot water recovery electromagnetic valve 14va and the heat storage recovery electromagnetic valve 22v are opened The boiler feeder electromagnetic valve 31v and the heat storage supplementary water valve 33v and the other hot water recovery electromagnetic valve 14vb and the boiler return electromagnetic valve 32v are of course supplied with the supplementary water supply electromagnetic valve 17v and the hot water supply electromagnetic valve 19v, It is preferable that all the electromagnetic valves 23v are closed.

However, when the temperature of the heating water is lowered by the outside temperature in the course of the above-mentioned heat storage direct heating circuit 2 and is not easy to use as heating water, that is, when the heating operation is mostly performed in spring, The temperature of the heating water held in the heat storage tank 20 is lowered and the heating efficiency is lowered, so that it is preferable not to utilize it.

In order to effectively use the heating water whose temperature has been lowered through the heat storage direct heating circuit 2, the heating water supplemented in the storage tank 20 is supplied to the boiler 30 through the heat storage supplement pipe 33 The heating water heated by the boiler 30 is supplied to the heating supply pipe 18 connected to the boiler supply pipe 31 through the installed heating pump P and is supplied to the heating space It is preferable to proceed with the heat accumulation heating heating circuit 4 for heating the condensers C as shown in Fig.

That is, when the temperature of the heating water drops to 40 ° C or lower in the course of the heat accumulation direct heating circuit 2 in the state where the lowest temperature of the accumulation temperature sensor 20s in the accumulation tank 20 is set to 40 ° C, The heat storage circuit 2 is stopped and the heat storage heating circuit 4 according to the present invention proceeds so that the heat storage temperature sensor 20s built in the heat storage tank 20 is connected to the boiler 30 and the heating pump P And the heating water inside the storage tank 20 flows into the boiler 30 through the storage heat supplement pipe 33 communicating with the heat storage supply pipe 21 and heated by the boiler 30, The heating space C is heated by discharging the supply pipe 31 and the heating pump P sequentially through the heating supply pipe 18 so that the temperature of the heating water remains, The process of collecting the recovered water into the storage tank 20 again through the recovery pipe 22 is repeated So that heating and heating of the heating space C are efficiently performed (see Fig. 5). [

At this time, in order to efficiently flow the heating water, the boiler feeder electromagnetic valve 31v, the heat storage supplement water valve 33v, the hot water supply valve 18v, the hot water recovery valve 14va and the heat storage recovery valve 22v are opened The solar heat supply electronic side 13v and the heat storage supply electronic side 21v and the regenerative back flow electronic side 25v and the hot water recovery electronic side 14vb and the hot water supply electronic side 19v and the boiler return side electronic side 32v, And the hot water recovery electromagnetic valve 14vb are closed.

However, it can be seen that the pressure exhausting electromagnetic valve 23v can maintain the opening and closing by necessity.

In addition, when the above-described solar heating circuit 1 and the heating water heat accumulation circuit 5 are stopped, or when the external temperature falls below zero in the operating state of the heat accumulation direct heating circuit 2, In order to prevent the freezing of the heating water held in the apparatus 10, the boiler feed pipe 13 and the heating return pipe 14 from freezing and the heating return pipe 18 and the heating return pipe 14 to be frozen, When the lowest temperature of the low temperature sensor 14s constituting the heating return pipe 14 adjacent to the solar heat storage device 10 is set to 2 占 폚 and the temperature of the low temperature sensor 14s is lower than 2 占 폚, The heating water remaining in the storage tank 20 at room temperature flows into the heating pump P through the heat storage supply pipe 21 and then flows through the heat storage backflow pipe 25 and the solar heat supply pipe 13, (10), and then the heat recovery pipe (14) and the heat storage and recovery pipe (22) The temperature of the low temperature sensor 14s is detected to be 2 ° C or more by repeating the operation of allowing the temperature of the low temperature sensor 14s to flow into the heat storage tank 20 by about two to five times, So as to prevent the shape of the freeze of the heating device (see Fig. 7).

At this time, in order to efficiently flow the hot water, only one heat recovery electromagnetic valve 14vb is opened while only one heat storage electromagnetic valve 25v, the heat storage supply electromagnetic valve 21v, the heat storage recovery electromagnetic valve 22v and one hot water recovery electromagnetic valve 14vb are opened, The boiler feeder electronic valve 31v and the hot water supply valve 18v and the makeup water supply valve 17v and the hot water supply valve 19v and the boiler return valve 32v are closed It may be desirable to have the

At this time, since the temperature of the heating water inside the heat storage tank 20 is remarkably low, it is not easy to use it as heating water or the temperature of the outside is lowered to a subzero or less, so that the solar heat storage device 10 and the solar heat supply pipe 13 exposed to the outside, When the external constituent of the present invention such as the recovery pipe 14 is frozen or there is a danger, the boiler 30 is operated and the heating pump P is rotated in the reverse direction so that the room temperature water remaining in the storage tank 20 The heating water that has flowed into the boiler 30 through the supply pipe 21 and the heat storage supplement pipe 33 and has been heated to a high temperature by the boiler 30 is introduced into the heating pump P through the boiler feed pipe 31 And then flows into the solar heat storage device 10 through the rear heat storage backflow pipe 25 and the solar heat supply pipe 13 and then flows into the heat storage tank 20 through the heat recovery pipe 14 and the heat storage recovery pipe 22 sequentially Emergency freeze to prevent freezing (See FIG. 8) of the heating device, which may occur in winter, through the prevention circuit 8 (see FIG. 8)

At this time, only the boiler feeder electromagnetic valve 31v, the regenerating water valve 33v, the regenerator backflow electromagnetic valve 25v, the heat accumulation recovery valve 22v, and the single hot water recovery valve 14vb are opened The other one of the hot water recovery electromagnetic valve 14va and the solar heat supply electromagnetic valve 13v and the hot water supply electromagnetic valve 18v and the heat storage supply electromagnetic valve 21v and the hot water supply electromagnetic valve 19v and the boiler recovery electromagnetic valve 32v, It is preferable that the electromagnetic valve 17v and the heat storage drain valve 24v are closed.

Alternatively, when the heating water inside the heat storage tank 20 is frozen, the boiler 30 is operated, and constant water is supplied to the boiler 30 through the replenishing water supply pipe 17 to heat the heated high temperature water to the boiler feed pipe 31 To the solar heat storage device 10 through the heat storage backflow pipe 25 and the solar heat supply pipe 13 and then to the heat recovery pipe 14 and the heat storage recovery pipe 22, It is possible to prevent the freeze wave form of the heating device, which may occur during the winter, through the emergency frost preventing circuit 8 that prevents freezing by an operation of flowing the water into the heat storage tank 20 sequentially.

In addition, in the case where the boiler-combined solar heating apparatus according to the present invention is not used for a long period of time, or when the heating water in the heat storage tank 20 becomes unusable due to the absence of heating water or sudden cold in winter, The heating water heated by the boiler 30 is supplied to the heating means 50 through the heating supply pipe 18 connected to the boiler supply pipe 31 and the heating pump P to heat the heating space C, And then the heating space C is heated separately from the solar heat through the boiler heating circuit 3 that is returned to the boiler 30 through the heat recovery pipe 14 through the boiler return pipe 32. [

The heating pump P is stopped by the heat accumulation temperature sensor 20s when the temperature of the heating water held in the heat accumulation tank 20 in the heat accumulation direct heating circuit 2 is 40 ° C or lower, The hot water heated by the boiler 30 is supplied to the heating means 50 through the heating supply pipe 18 connected to the boiler supply pipe 31 when the heating of the heating place is required in the state where the operation of the heating means is stopped, The heating space C is heated separately and then passed through the heating water recovery pipe 14 and returned to the boiler 30 through the boiler recovery pipe 32. The heating space C is separated from the solar heat by the boiler heating circuit 3, .

That is, the boiler 30 is operated and the hot water recovery valve 14vb is shut off and the boiler return electromagnetic valve 32v is opened to allow the heating water to flow into the boiler 30, The heating space C is heated through the heating supply pipe 18 communicating with the boiler feed pipe 31 and then the boiler return pipe 32 communicating with the heating return pipe 14 is heated (See FIG. 4) when the operation of the solar collector is not possible because the temperature of the heating water remains in the boiler 30,

At this time, in order to efficiently flow the hot water, only the boiler feeder electromagnetic valve (31v), the boiler return electromagnetic valve (32v), the hot water supply electromagnetic valve (18v) and the hot water recovery electromagnetic valve (14va) 14v and the solar heat supply electronic side 13v and the storage heat supply electronic side 21v and the storage heat backflow electronic side 25v and the hot water supply electronic side 19v and the storage heat supply side electronic side 33v as well as the supplementary water supply electronic side 17v As shown in FIG.

In the solar heating apparatus for combined heating and cooling of the present invention, the solar heat heating circuit (1) is provided with a heat storage direct heating circuit (2), a boiler heating circuit (3) The circuit 4 and the heating water heat accumulating circuit 5 are individually connected to each other. The construction is simple and the installation cost is reduced, and the heat source of the solar heat source and the heat source of the boiler can be used sequentially It can be converted into various circuits such as the freezing prevention circuit 7 and the emergency freezing prevention circuit 8 depending on the weather condition so that the heat source necessary for heating can be sequentially supplied to the heating space without any special operation A separate screening device 60 is constructed and exposed to the outside as in the case of a roof, It is possible to prevent the overheating of the solar heat collecting device 10 and protect it from the external physical pressure, thereby reducing the energy required for heating while increasing the efficiency of the solar energy, Can be prevented from being heated or frozen. Therefore, it can be understood that the invention has various advantages that it is simple to operate, low in installation cost, has a remarkable effect with high thermal efficiency, and will be used without any great burden by anyone.

1: Solar heating circuit 2: Heat storage direct heating circuit
3: Boiler heating circuit 4: Heat storage heating circuit
5: Heating water storage and heating circuit 6: Overheat prevention circuit
7: Freezing prevention circuit 8: Emergency freeze prevention circuit
10: Solar heat storage device 11b:
12: Quantity replenishment tank 13: Solar heat supply pipe
13s: High temperature sensor 13v: Hot water supply electronic
14: Heat recovery tube 14s: Low temperature sensor
14va, 14vb: Hot water recovery electronic valve 15: Heating water supplement pipe
15v: Heating water replenishment electronic valve 16: Air exhaust pipe
17: replenishment water supply pipe 18: heating supply pipe
19: hot water supply pipe 20: heat storage tank
20t: Storage temperature sensor 20s: Storage temperature sensor
21: heat storage supply tube 21v: heat storage supply electronic side
22: heat storage recovery pipe 22v: heat storage recovery electronic side
23: Heat storage pressure discharge pipe 23v: Pressure exhaust valve
24: heat storage pipe 24v: drain water
30: boiler 31: boiler feed pipe
31v: boiler supply electronic valve 32: boiler recovery pipe
32v: Boiler recovery electronic valve 33: Heat storage supplement pipe
33v: heat storage supplementary water electronic valve 40: heating means
60: Screening device 70: Fixing structure
71: guide rail 72: guide groove
73: Unit bearing 74: Fixing piece
75: Support base 80: Screening structure
81: Shielding film 82: Operation shaft
83: reference axis 90: operating structure
91: drive motor 92: guide rod
93: Information block 94:
A: Rooftop B: Indoor
C: Heating place P: Heating pump

Claims (2)

A solar heat storage device is constructed on the roof (A), a heat storage tank and a boiler are constructed in the room (B), and the heating water heated in the solar heat storage device and the boiler is moved to the heating place (C) Which is installed on the front surface of a solar heat storage device of a solar heating device combined with an overheat prevention boiler for heating a heating space, and a solar heating device for preventing overheating, the solar heating device comprising:

A screening device 60 is provided to separately open and close the front surface of the solar heat storage device 10 while the screening film 81 is wound on the outer diameter of the operating shaft 83 rotated by the drive motor 91 and released, 10) to block the solar heat by the screening membrane (81) to structurally prevent the solar heat storage device (10) from being overheated;
The screening apparatus 60 is fixed to the guide groove 72 by the support table 75 and the fixing piece 74 so as to keep the guide rails 71 provided with the plurality of unit bearings 73 symmetrically and inclined A fixed structure (70) constituted by:
The shielding structure 80 is constructed so that the shielding film 81 is wound around the outer diameter of the operation shaft 82 while the reference shaft 83 and the operation shaft 82 are kept parallel to each other and the end of the shielding film 81 is connected to the center of the outer diameter. and;
A working structure 90 having a guide bar 92 formed on one outer side of the fixed structure 70 and having a guide block 93 fixed parallel to the guide rail 71 and fixed to the outer diameter of the drive motor 91, And fixed to opposite ends of the operation shaft 82 to the upper unit bearing 73 of the plurality of unit bearings 73 slidable in the guide grooves 72 of the guide rail 71. The lower unit bearings 73 And the one end of the operating shaft 82 is connected to the motor shaft 92 of the driving motor 91 constituting the operating structure 90. In this case, One end portion of the spiral string 94 is fixed to the outer diameter of the operation shaft 82 between the unit bearings 73 and the other end portion is connected and fixed to the fixed piece 74 constituting the upper end portion of the fixed structure 70 ;
The shielding film 81 is held on the entire surface of the regenerator 11b of the solar thermal collector 10 so that the shielding film 81 is opened and closed at an angle similar to the inclination angle of the regenerator 11b, 11b) is shielded from solar heat, characterized in that the solar heat collecting device (10) having the solar heat collecting device (11a, 11b) is intercepted from solar heat. delete

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