CN116499016A - Multi-energy complementary heating device - Google Patents

Abstract

The invention discloses a multi-energy complementary heating device which comprises a solar energy component, a water heating furnace, a heat exchanger, a pipeline and a water distributor, wherein the solar energy component comprises a water tank and a plurality of heat-conducting pipes, the water tank is connected with an exhaust pipe, a drain pipe and an upper water pipe and a lower water pipe, the heat-conducting pipes comprise pipe bodies, one ends of the pipe bodies are connected with connecting rings, the inside of the pipe bodies and the inside of the connecting rings are hollow structures, the inside of the pipe bodies are communicated with the inside of the connecting rings, the pipe bodies are arranged outside the water tank, the connecting rings are arranged inside the pipe bodies, the water heating furnace comprises a furnace body and a heat-conducting pipe, a combustion cavity is arranged inside the furnace body, the heat-conducting pipe is coiled outside the combustion cavity, the heat-conducting pipe comprises an inner pipe and an outer pipe, a plurality of ventilation holes are formed in the outer pipe, and a plurality of supporting blocks are arranged between the outer pipe and the inner pipe. The invention adopts various heating modes, thereby greatly improving the comfort level of the house while reducing the cost.

Description

Multi-energy complementary heating device

Technical Field

The invention belongs to the field of heating devices, and particularly relates to a heating device with multiple energy sources complementary.

Background

For people living in northern cities, central heating is certainly the lowest-cost and best-effect heating mode, but for rural areas without heating and southern cities without heating, heating in winter mainly depends on own coal stove to burn.

Because the rural areas do not have central heating, the heating modes are diversified, some solar heating is adopted for saving cost, and some water heating furnaces are adopted for adjusting the temperature for heating, but the heating modes have certain defects, only one heating mode can be selected, and the practical use is very inconvenient.

Disclosure of Invention

The invention aims to provide a multi-energy complementary heating device, which combines a plurality of heating modes to diversify heating modes, thereby greatly reducing the use cost, and greatly improving the comfort level due to adjustable temperature in houses.

In order to solve the problems in the prior art, the invention adopts the following technical scheme:

the heating device with multiple energy sources comprises a solar energy component, a water heating stove, a heat exchanger, a pipeline and a water separator.

The solar energy component comprises a water tank and a plurality of heat-conducting pipes, wherein the water tank is connected with an exhaust pipe, a drain pipe and an upper water pipe and a lower water pipe, the heat-conducting pipes comprise pipe bodies, one ends of the pipe bodies are connected with connecting rings, the inside of the pipe bodies and the inside of the connecting rings are hollow structures, the inside of the pipe bodies are communicated with the inside of the connecting rings, the pipe bodies are arranged outside the water tank, and the connecting rings are positioned inside the pipe bodies.

The water heating furnace comprises a furnace body and a heat exchange tube, a combustion chamber is arranged in the furnace body, the heat exchange tube is coiled outside the combustion chamber, the heat exchange tube comprises an inner tube and an outer tube, the outer tube is provided with a plurality of ventilation holes, and a plurality of supporting blocks are arranged between the outer tube and the inner tube.

The water separator is connected with the solar energy component and the water heating furnace through the heat exchanger.

The pipeline comprises a water inlet pipe, a water return pipe, a first circulating pipe, a second circulating pipe, a cold water pipe, a hot water pipe and a communicating pipe, wherein one end of the water inlet pipe is communicated with the first circulating pipe, the other end of the water inlet pipe is communicated with the cold water pipe, one end of the water outlet pipe is communicated with the second circulating pipe, the other end of the water outlet pipe is respectively communicated with the cold water pipe and the hot water pipe through a four-way pipe, the four-way pipe is communicated with the hot water pipe through the communicating pipe, one end of the cold water pipe is communicated with a heat exchange pipe, the other end of the cold water pipe is communicated with a heat exchanger, one end of the hot water pipe is communicated with the heat exchange pipe, and the first circulating pipe is communicated with the second circulating pipe through a bent pipe.

Further, the first circulating pipe is located at the lower side of the second circulating pipe, the first circulating pipe is sleeved with a plurality of heat-conducting pipes, one end of the first circulating pipe is communicated with the water inlet pipe, the other end of the first circulating pipe is communicated with the second circulating pipe through the bent pipe, the second circulating pipe comprises two main pipes and a plurality of branch pipes communicated between the two main pipes, one main pipe is communicated with the water return pipe, the other main pipe is communicated with the bent pipe, the first circulating pipe, the bent pipe and the second circulating pipe form a closed loop, liquid in the first circulating pipe is independent of water in the water tank, mixing of the two liquids is avoided, the connecting ring of the heat-conducting pipes is directly sleeved on the first circulating pipe, and the heat transfer effect is better because the first circulating pipe is directly contacted with the heat-conducting pipes, the second circulating pipe is provided with a plurality of branch pipes, the main pipes are divided into a plurality of branch pipes, the contact area between the branch pipes and water is increased, the heat exchange efficiency is higher, and meanwhile the branch pipes can be connected with fins to improve the heat absorption efficiency.

Further, still be equipped with the inlet channel in the furnace body, the upside in combustion chamber is equipped with a plurality of inlet ports, inlet channel corresponds the setting with the inlet port, through setting up the inlet port at the combustion chamber, can let in air to flame upper portion for combustible material fully burns, heat exchange tube's both ends respectively with hot-water line and cold water pipe intercommunication, because the liquid in the water heating stove need get into solar module, and solar module locates the roof generally, the ground is located generally to the water heating stove, this can make heat exchange tube bear great pressure, will the heat exchange tube designs bilayer structure, utilizes the support of outer tube to the inner tube, prevents that the inner tube from receiving pressure deformation, compares in the pipe wall thickening with the heat exchange tube, bilayer structure can guarantee sufficient compressive property, can also guarantee heat exchange efficiency for the heat make full use of the water heating stove.

Further, the top intercommunication of inlet tube has first expansion tank, is connected with the fourth valve between inlet tube and the cross valve, the wet return is connected with first valve, be equipped with the second valve between cross valve and the hot-water heating stove, the second valve is connected in the cold water pipe, communicating pipe is connected with the third valve, because liquid is by expend with heat and contract with cold, through setting up expansion tank, not only can automatic moisturizing, can also prevent to rise the pipeline broken, through the switch of different valves, can select different heating methods to heat.

Furthermore, the heat exchanger is a plate heat exchanger, and liquid in the first circulating pipe, the second circulating pipe and the heat exchange pipe is not mixed with water in the water tank and the water separator by adopting the heat exchanger, so that antifreeze liquid can be adopted, a pipeline is not frozen, scale is not easy to generate, an electric heater is connected between the water separator and the heat exchanger, the water separator is communicated with the second expansion water tank, and heat can be independently supplied by the electric heater by adopting the electric heater.

The invention has the following beneficial effects:

according to the invention, by arranging a plurality of heating modes, the heating modes are diversified, and different conditions can be adapted.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

FIG. 3 is a schematic view of the solar module of FIG. 1;

FIG. 4 is a schematic diagram of the heat pipe in FIG. 3;

FIG. 5 is a schematic view of the internal structure of the heat pipe;

FIG. 6 is a schematic diagram of connection of heat pipes;

FIG. 7 is a schematic view of a heat exchange assembly;

FIG. 8 is a schematic view of the structure of a water heating stove;

fig. 9 is a schematic cross-sectional view of the heat exchange tube of fig. 8.

In the figure: 1-a solar module; 11-a water tank; 12-a heat conduction pipe; 121-a tube body; 122-connecting rings; 13-an exhaust pipe; 14-a drain pipe; 15-an up-down water pipe; 16-a water supplementing pipe; 17-a water pipe; 2-water heating furnace; 21-a furnace body; 22-heat exchange tubes; 221-an outer tube; 222-an inner tube; 223-supporting blocks; 23-combustion chamber; 24-an air inlet hole; 25-an intake passage; 3-heat exchanger; 4-a water separator; 51-water inlet pipe; 52-a water return pipe; 53-a second circulation tube; 531-manifold; 532-branch pipes; 54-a first circulation pipe; 55-a cold water pipe; 56-a hot water pipe; 57-communicating tube; 58-bending the pipe; 61-a first valve; 62-a second valve; 63-a third valve; 64-fourth valve; 71-a first expansion tank; 72-a second expansion tank; 8-an electric heater.

Detailed Description

The invention is further described with reference to the drawings and reference numerals.

In order that the above-recited objects, features and advantages of the present invention will be more clearly understood, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It should be noted that, in the case of no conflict, the embodiments of the present application and the features in the embodiments may be combined with each other.

The terms "first," "second," "third," and the like are used merely to distinguish between descriptions and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

The following describes specific embodiments of the present invention in detail with reference to the drawings. It should be understood that the detailed description and specific examples, while indicating and illustrating the invention, are not intended to limit the invention.

Example 1:

as shown in fig. 1 to 3, the heating apparatus is complementarily supplied with various energy sources, including a solar module 1, a water heating furnace 2, a heat exchanger 3, a pipe line and a water separator 4.

The solar module 1 comprises a water tank 11 and a plurality of heat-conducting pipes 12, the water tank 11 is connected with an exhaust pipe 13, a drain pipe 14 and an up-down water pipe 15, the up-down water pipe 15 is connected with a water supplementing pipe 16 and a water consuming pipe 17, the heat-conducting pipes 12 comprise a pipe body 121, one end of the pipe body 121 is connected with a connecting ring 122, the inside of the pipe body 121 and the inside of the connecting ring 122 are hollow structures, the inside of the pipe body 121 is communicated with the inside of the connecting ring 122, the pipe body 121 is arranged outside the water tank 11, and the connecting ring 122 is positioned inside the pipe body 121.

The water heating furnace 2 comprises a furnace body 21 and a heat exchange tube 22, a combustion chamber 23 is arranged inside the furnace body 21, the heat exchange tube 22 is coiled outside the combustion chamber 23, the heat exchange tube 22 comprises an inner tube 222 and an outer tube 221, the outer tube 221 is provided with a plurality of ventilation holes, and a plurality of supporting blocks 223 are arranged between the outer tube 221 and the inner tube 222.

The water separator 4 is connected with the solar module 1 and the water heating furnace 2 through the heat exchanger 3.

The pipeline comprises a water inlet pipe 51, a water return pipe 52, a first circulating pipe 54, a second circulating pipe 53, a cold water pipe 55, a hot water pipe 56 and a communicating pipe 57, one end of the water inlet pipe 51 is communicated with the first circulating pipe 54, the other end of the water inlet pipe 51 is communicated with the cold water pipe 55, one end of the water outlet pipe is communicated with the second circulating pipe 53, the other end of the water outlet pipe is respectively communicated with the cold water pipe 55 and the hot water pipe 56 through four-way pipes, the four-way pipes are communicated with the hot water pipe 56 through the communicating pipe 57, one end of the cold water pipe 55 is communicated with the heat exchange pipe 22, the other end of the cold water pipe 55 is communicated with the heat exchanger 3, one end of the hot water pipe 56 is communicated with the heat exchange pipe 22, the other end of the hot water pipe 56 is communicated with the heat exchanger 3, and the first circulating pipe 54 is communicated with the second circulating pipe 53 through an elbow 58.

Example 2:

on the basis of embodiment 1, as shown in fig. 4 to 6, the first circulation pipe 54 is located at the lower side of the second circulation pipe 53, the first circulation pipe 54 is sleeved with a plurality of heat transfer pipes 12 (because scale is generated inside the water tank for a long time, the heat transfer efficiency of the first circulation pipe 54 is reduced, the first circulation pipe 54 is directly contacted with the heat transfer pipes 12, even if scale is generated, heat transfer is not affected), one end of the first circulation pipe 54 is communicated with the water inlet pipe 51, the other end of the first circulation pipe 54 is communicated with the second circulation pipe 53 through the elbow pipe 58, the second circulation pipe 53 comprises two main pipes 531 and a plurality of branch pipes 532 communicated between the two main pipes 531, one main pipe 531 is communicated with the water return pipe 52, and the other main pipe 531 is communicated with the elbow pipe 58.

The first circulation pipe 54, the bent pipe 58 and the second circulation pipe 53 form a closed loop, so that the liquid in the first circulation pipe 54 is independent of the water in the water tank 11, and the two liquids are prevented from being mixed.

The connecting ring 122 of the heat conducting pipe 12 is directly sleeved on the first circulating pipe 54, and the heat transfer effect is better because the first circulating pipe 54 is directly contacted with the heat conducting pipe 12.

The second circulation pipe 53 is provided with a plurality of branch pipes 532, the main pipe 531 is divided into a plurality of branch pipes 532, the contact area between the plurality of branch pipes 532 and water is increased, the heat exchange efficiency is higher, and meanwhile, the branch pipes 532 can be connected with fins, so that the heat absorption efficiency is improved.

If two tanks 11 are provided, two first circulation pipes 54, two second circulation pipes 53 and one elbow 58 are required to ensure that the liquid in the circulation pipes is independent of the water in the tanks 11.

The exhaust pipe 13 is arranged on the upper side of the water tank 11, and the water shrinkage drain pipe 14 extends into the bottom of the water tank 11.

Example 3:

on the basis of embodiment 2, as shown in fig. 7-9, an air inlet channel 25 is further provided in the furnace body 21, a plurality of air inlet holes 24 are provided on the upper side of the combustion chamber 23, and the air inlet channel 25 is disposed corresponding to the air inlet holes 24.

By providing the air intake holes 24 in the combustion chamber 23, air can be introduced into the upper portion of the flame so that the combustible material can be fully combusted.

The two ends of the heat exchange tube 22 are respectively communicated with a hot water tube 56 and a cold water tube 55.

Since the liquid in the water heating furnace 2 needs to enter the solar module 1, the solar module 1 is usually arranged on the roof, and the water heating furnace 2 is usually arranged on the ground, the heat exchange tube 22 can bear larger pressure, the heat exchange tube 22 is designed into a double-layer structure (an inner tube 222 and an outer tube 221), and the inner tube 222 is supported by the outer tube 221 to prevent the inner tube 222 from being deformed by pressure.

Compared with the thickening of the pipe wall of the heat exchange pipe 22, the double-layer structure can ensure enough compression resistance and heat exchange efficiency, so that the heat of the water heating furnace 2 is fully utilized.

Example 4:

on the basis of embodiment 3, the top end of the water inlet pipe 51 is communicated with a first expansion water tank 71, a fourth valve 64 is connected between the water inlet pipe 51 and the four-way pipe, the water return pipe 52 is connected with a first valve 61, a second valve 62 is arranged between the four-way pipe and the water heating furnace 2, the second valve 62 is connected with a cold water pipe 55, and the communicating pipe 57 is connected with a third valve 63.

Because the liquid is by expend with heat and contract with cold, through setting up expansion tank, not only can the automatic moisturizing, can also prevent to rise broken with the pipeline.

Different heating modes can be selected for heating through the opening and closing of different valves.

The heat exchanger 3 is a plate heat exchanger 3.

By adopting the heat exchanger 3, the liquid in the first circulation pipe 54, the second circulation pipe 53, and the heat exchange pipe 22 is not mixed with the water in the water tank 11 and the water separator 4, so that an antifreeze solution can be used, not only the pipeline is not frozen, but also the scale is not easily generated.

An electric heater 8 is connected between the water separator 4 and the heat exchanger 3, and the water separator 4 is communicated with a second expansion water tank 72.

By providing the electric heater 8, heat supply can be performed by the electric heater 8 alone.

The specific working principle is as follows:

the working state is as follows: the solar energy supplies heat independently, the first valve 61 and the third valve 63 are opened, the second valve 62 and the fourth valve 64 are closed, the cooling liquid enters the first circulating pipe 54 and the second circulating pipe 53 through the water inlet pipe 51, absorbs heat in the water tank 11, then flows into the hot water pipe 56 through the water return pipe 52, then enters the heat exchanger 3 to release heat, and finally enters the water supply pipe through the cold water pipe 55 to circulate in this way.

And the working state is as follows: the water heating furnace 2 supplies heat independently, the second valve 62 and the fourth valve 64 are opened, the first valve 61 and the third valve 63 are closed, the cooling liquid flows into the heat exchange tube 22 from the cold water tube 55, absorbs heat in the water heating furnace 2, flows to the heat exchanger 3 through the hot water tube 56 to release heat, and finally flows back to the cold water tube 55 for circulation.

And the working state is three: the solar energy component 1 and the water heating furnace 2 supply heat at the same time, the first valve 61 and the second valve 62 are opened, the third valve 63 and the fourth valve 64 are closed, cooling liquid enters the first circulating pipe 54 and the second circulating pipe 53 through the water inlet pipe 51, absorbs heat in the water tank 11 and then flows into the hot water pipe 56 through the water return pipe 52, then enters the heat exchange pipe 22 to absorb heat continuously, then enters the heat exchanger 3 through the hot water pipe 56 to exchange heat, and finally enters the water supply pipe through the cold water pipe 55 to circulate like this.

And the working state is four: the electric heater 8 supplies heat, and the first valve 61, the second valve 62, the third valve 63 and the third valve 63 are closed, so that the electric heater 8 is used for heating and heating.

The invention is not limited to the above-described alternative embodiments, and any person who may derive other various forms of products in the light of the present invention, however, any changes in shape or structure thereof, all falling within the technical solutions defined in the scope of the claims of the present invention, fall within the scope of protection of the present invention.

Claims (7)

1. The utility model provides a complementary heating device of multiple energy, its characterized in that: comprises a solar energy component (1), a water heating furnace (2), a heat exchanger (3), a pipeline and a water separator (4);

the solar energy assembly (1) comprises a water tank (11) and a plurality of heat conduction pipes (12), wherein the water tank (11) is connected with an exhaust pipe (13), a drain pipe (14) and an up-down water pipe (15), the heat conduction pipes (12) comprise a pipe body (121), one end of the pipe body (121) is connected with a connecting ring (122), the inside of the pipe body (121) and the inside of the connecting ring (122) are hollow structures, the inside of the pipe body (121) is communicated with the inside of the connecting ring (122), the pipe body (121) is arranged outside the water tank (11), and the connecting ring (122) is positioned inside the pipe body (121);

the water heating furnace (2) comprises a furnace body (21) and a heat exchange tube (22), wherein a combustion cavity (23) is arranged in the furnace body (21), the heat exchange tube (22) is coiled outside the combustion cavity (23), the heat exchange tube (22) comprises an inner tube (222) and an outer tube (221), the outer tube (221) is provided with a plurality of ventilation holes, and a plurality of supporting blocks (223) are arranged between the outer tube (221) and the inner tube (222);

the water separator (4) is connected with the solar energy component (1) and the water heating furnace (2) through the heat exchanger (3);

the pipeline comprises a water inlet pipe (51), a water return pipe (52), a first circulating pipe (54), a second circulating pipe (53), a cold water pipe (55), a hot water pipe (56) and a communicating pipe (57), one end of the water inlet pipe (51) is communicated with the first circulating pipe (54), the other end of the water inlet pipe (51) is communicated with the cold water pipe (55), one end of the water outlet pipe is communicated with the second circulating pipe (53), the other end of the water outlet pipe is respectively communicated with the cold water pipe (55) and the hot water pipe (56) through a four-way pipe, the four-way pipe is communicated with the hot water pipe (56) through the communicating pipe (57), one end of the cold water pipe (55) is communicated with a heat exchange pipe (22), the other end of the cold water pipe (55) is communicated with the heat exchanger (3), and the other end of the hot water pipe (56) is communicated with the heat exchanger (3), and the first circulating pipe (54) is communicated with the second circulating pipe (53) through a bent pipe (58).

2. The multiple energy complementary heating device according to claim 1, wherein: the first circulating pipe (54) is located at the lower side of the second circulating pipe (53), the first circulating pipe (54) is sleeved with the plurality of heat conducting pipes (12), one end of the first circulating pipe (54) is communicated with the water inlet pipe (51), the other end of the first circulating pipe (54) is communicated with the second circulating pipe (53) through the bent pipe (58), the second circulating pipe (53) comprises two main pipes (531) and a plurality of branch pipes (532) communicated between the two main pipes (531), one main pipe (531) is communicated with the water return pipe (52), and the other main pipe (531) is communicated with the bent pipe (58).

3. The multiple energy complementary heating device according to claim 1, wherein: the exhaust pipe (13) is arranged on the upper side of the water tank (11), and the water shrinkage drain pipe (14) stretches into the bottom of the water tank (11).

4. The multiple energy complementary heating device according to claim 1, wherein: an air inlet channel (25) is further arranged in the furnace body (21), a plurality of air inlet holes (24) are formed in the upper side of the combustion cavity (23), and the air inlet channel (25) and the air inlet holes (24) are correspondingly arranged.

5. The multiple energy complementary heating device according to claim 1, wherein: the two ends of the heat exchange tube (22) are respectively communicated with a hot water tube (56) and a cold water tube (55).

6. The multiple energy complementary heating device according to claim 1, wherein: the top intercommunication of inlet tube (51) has first expansion tank (71), is connected with fourth valve (64) between inlet tube (51) and the cross valve, wet return (52) are connected with first valve (61), be equipped with second valve (62) between cross valve and water heating stove (2), second valve (62) are connected in cold water pipe (55), communicating pipe (57) are connected with third valve (63).

7. The multiple energy complementary heating device according to claim 1, wherein: an electric heater (8) is connected between the water separator (4) and the heat exchanger (3), and the water separator (4) is communicated with a second expansion water tank (72).