CN219572316U - Energy-saving heat exchange device for solar equipment - Google Patents

Abstract

The utility model provides an energy-saving heat exchange device for solar equipment, which comprises: the solar heat collector assembly is connected to the lower end of the water tank assembly, and the heat exchange mechanism assembly is arranged in the water tank assembly; the solar heat collector assembly consists of an upper connecting plate, a mounting base, a solar heat collecting plate, a circulating pipeline and an electromagnetic valve; the heat exchange mechanism assembly consists of a heat exchange pipeline, a fixing plate and a fixing sleeve, and the fixing sleeve is connected to the outer side of the heat exchange pipeline. The energy-saving heat exchange device for the solar equipment solves the problems that an auxiliary heating mechanism is not arranged in the prior art, hot water is not used in long-time overcast and rainy weather, meanwhile, the water temperature cannot be automatically increased when the water temperature is insufficient, and a heat exchange medium in a heat collector cannot be replaced.

Description

Energy-saving heat exchange device for solar equipment

Technical Field

The utility model relates to the technical field of solar equipment, in particular to an energy-saving heat exchange device for solar equipment.

Background

The solar water heater has the advantages of clean and environment-friendly energy, higher safety coefficient and the like, and is widely applied. The solar water heater mainly comprises a solar heat collector and a water tank, wherein the solar heat collector can convert solar energy into heat energy to heat a circulating medium, and the heated circulating medium can conduct energy to water stored in the water tank through the heat exchanger, so that hot water is produced, such as:

chinese patent publication No. CN104764225a relates to a solar heat exchange device. The structure of the device comprises a solar water storage tank provided with a water outlet, a heat exchange tube arranged in the solar water storage tank and a heat conducting medium heating mechanism connected with the water storage tank, wherein a water inlet and a water outlet of the heat exchange tube are arranged on the wall of the solar water storage tank; the solar water storage tank is divided into a sub water tank and a heat exchange water tank by a vertical folding partition plate with a diversion hole, and the heat conducting medium heating mechanism is communicated with the heat exchange water tank; the heat exchange tube is fixed in the heat exchange water tank; the diversion holes are arranged on the vertical plates forming the vertical folding partition plates. The device enables the heat energy of water in the solar water storage tank to be stored and fully utilized. The solar water heater can be suitable for the integral and split installation of the solar water heater; has the characteristics of high-efficiency energy collection, energy conservation and safety.

The prior art solutions described above have the following drawbacks: the auxiliary heating mechanism is not arranged, so that the situation of no hot water use is caused in long-time overcast and rainy weather, meanwhile, the water temperature cannot be automatically increased when the water temperature is insufficient, and the heat exchange medium in the heat collector cannot be replaced, so that a person skilled in the art needs to design a heat exchange device capable of being inserted in a rotating mode.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides an energy-saving heat exchange device for solar equipment, which solves the problems that no auxiliary heating mechanism is arranged in the prior art, hot water is not used in long-time overcast and rainy weather, the water temperature can not be automatically increased when the water temperature is insufficient, and a heat exchange medium in a heat collector can not be replaced. (II) technical scheme

In order to achieve the above purpose, the utility model is realized by the following technical scheme:

an energy-saving heat exchange device for solar equipment comprises a water tank assembly, a solar heat collector assembly connected to the lower end of the water tank assembly and a heat exchange mechanism assembly arranged inside the water tank assembly,

the water tank assembly consists of a water tank shell, a water tank heat-insulating layer, a heating plate, a water outlet and a water inlet, wherein the water tank heat-insulating layer is connected to the inner end of the water tank shell, the heating plate is connected to the upper end of the interior of the water tank heat-insulating layer, the water outlet is connected to the left end of the water tank shell, and the water inlet is arranged below the water outlet;

the solar heat collector assembly consists of an upper connecting plate, a mounting base, a solar heat collecting plate, a circulating pipeline and an electromagnetic valve, wherein the lower end of the upper connecting plate is connected with the solar heat collecting plate, the lower end of the solar heat collecting plate is connected with the mounting base, the electromagnetic valve is arranged in the upper connecting plate, and the lower end of the electromagnetic valve is connected with a water outlet;

the heat exchange mechanism assembly consists of a heat exchange pipeline, a fixing plate and a fixing sleeve, wherein the fixing sleeve is connected to the outer side of the heat exchange pipeline, and the fixing plate is connected to the lower end of the fixing sleeve.

In one possible implementation manner, the water outlet is connected with the water tank shell and the water tank heat insulation layer in a communicating manner, and the water inlet is connected with the water tank shell and the water tank heat insulation layer in a communicating manner, and water pumps are arranged on the water outlet and the water inlet.

In one possible implementation manner, the upper connecting plate is internally provided with a cavity structure, and the circulating pipeline is connected with the upper connecting plate in a communicating manner.

In one possible implementation manner, the front end of the upper connecting plate is provided with a mounting door, and the upper connecting plate is connected with the water tank shell in a bolt connection manner.

In one possible implementation manner, the longitudinal section of the circulating pipeline is U-shaped, and electromagnetic valves are connected to two ends of the circulating pipeline.

In one possible implementation, the cross-sectional shape of the heat exchange tube is serpentine.

In one possible implementation, the heat exchange pipeline and the circulating pipeline are connected in a sealing connection mode.

In one possible implementation manner, the inner end of the fixing sleeve is provided with a foam-rubber cushion, and the fixing sleeve is arranged at the left end and the right end of the heat exchange pipeline.

(III) beneficial effects

The utility model provides an energy-saving heat exchange device for solar equipment, which can slow down heat dissipation in a water tank shell through arranging the water tank heat preservation layer in the water tank shell, has a good white-spot effect, is internally provided with a heating plate, can perform temperature compensation when the water temperature is insufficient, and can utilize the heating plate to heat water when encountering long-time overcast and rainy weather, so as to prevent the use of no hot water.

The utility model provides an energy-saving heat exchange device for solar equipment, which is characterized in that an upper connecting plate is connected with a water tank shell by bolts, and meanwhile, a safety door is arranged for connecting and disassembling a circulating pipeline and a heat exchange pipeline, so that the energy-saving heat exchange device can be more convenient and rapid to maintain or replace a heat exchange medium when a solar heat collector assembly is required, and can save labor and improve efficiency.

The utility model provides an energy-saving heat exchange device for solar equipment, which can enable heat exchange to be more thorough and improve the efficiency of the heat exchange by arranging a heat exchange pipeline in a snake shape.

Drawings

The foregoing description is only an overview of the present utility model, and is intended to provide a better understanding of the present utility model, as it is embodied in the following description, with reference to the preferred embodiments of the present utility model and the accompanying drawings.

Fig. 1 is a schematic cross-sectional elevation of a heat exchange device according to a first embodiment;

FIG. 2 is a schematic front view of the first embodiment;

FIG. 3 is a schematic top sectional view showing the connection of the water tank case and the heat exchange mechanism assembly in the first embodiment;

FIG. 4 is an enlarged schematic view of the structure A in FIG. 1 according to the first embodiment;

legend description: 1-a water tank assembly; 11-a tank housing; 12-a water tank heat preservation layer; 13-heating plate; 14-a water outlet; 15-a water inlet;

a solar collector assembly; 21-an upper connecting plate; 22-mounting a base; 23-a solar heat collecting plate; 24-a circulation pipeline; 25-electromagnetic valve;

a heat exchange mechanism assembly; 31-heat exchange pipelines; 32-a fixed plate; 33-fixing sleeve.

Description of the embodiments

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model. In addition, hereinafter, for convenience of description, references to "upper", "lower", "left", "right" are equal to directions of upper, lower, left, right, etc. of the drawing itself, and the references to "first", "second", etc. are to be distinguished in description, and have no other special meaning.

The utility model provides an energy-saving heat exchange device for solar equipment, which aims at the problems existing in the prior art, and comprises a water tank assembly, a solar heat collector assembly connected at the lower end of the water tank assembly and a heat exchange mechanism assembly arranged inside the water tank assembly, wherein the heat exchange mechanism assembly is specifically described as follows:

1-cistern assembly

The water tank assembly consists of a water tank shell, a water tank heat-insulating layer, a heating plate, a water outlet and a water inlet, wherein the water tank heat-insulating layer is connected to the inner end of the water tank shell, the heating plate is connected to the upper end of the water tank heat-insulating layer, the water outlet is connected to the left end of the water tank shell, and the water inlet is arranged below the water outlet. The heat-insulating layer of the water tank can slow down heat dissipation, plays a role in heat preservation, and meanwhile, the heating plate can play a role in temperature compensation when the temperature is insufficient.

In some examples, the water outlet and the water tank shell are connected with the water tank insulating layer in a communicating way, and the water inlet and the water tank shell are connected with the water tank insulating layer in a communicating way, and water pumps are arranged on the water outlet and the water inlet. The water quantity in the water tank assembly can be ensured by arranging the water outlet and the water inlet, and the water shortage condition can not occur.

2-solar collector assembly

The solar heat collector assembly is composed of an upper connecting plate, a mounting base, a solar heat collecting plate, a circulating pipeline and an electromagnetic valve, wherein the lower end of the upper connecting plate is connected with the solar heat collecting plate, the lower end of the solar heat collecting plate is connected with the mounting base, the electromagnetic valve is arranged in the upper connecting plate, and the lower end of the electromagnetic valve is connected with a water outlet. Solar energy can be converted into heat energy and transferred to water for storage.

In some examples, the upper connecting plate is internally provided with a cavity structure, and the circulating pipeline is connected with the upper connecting plate in a communicating manner. The connection between the circulating pipeline and the heat exchange pipeline can be carried out in the cavity structure, and the interface is prevented from being exposed.

In some examples, the front end of the upper connecting plate is provided with a mounting door, and the upper connecting plate is connected with the water tank shell by adopting a bolt connection mode. The water tank assembly and the solar heat collector assembly are connected by the bolts, so that the water tank assembly and the solar heat collector assembly are convenient to detach and install.

In some examples, the longitudinal section of the circulating pipeline is U-shaped, and electromagnetic valves are connected to two ends of the circulating pipeline. The electromagnetic valve enables the medium in the circulating pipeline to circulate and convert heat into water in the water tank assembly through the heat exchange pipeline.

3-heat exchange mechanism assembly

The heat exchange mechanism assembly consists of a heat exchange pipeline, a fixing plate and a fixing sleeve, wherein the fixing sleeve is connected to the outer side of the heat exchange pipeline, and the fixing plate is connected to the lower end of the fixing sleeve. The heat in the heat collector can be converted into water through the heat exchange mechanism assembly to be stored.

In some examples, the heat exchange tube has a serpentine cross-sectional shape. The heat exchange speed is accelerated, the heat exchange is more thorough, and the exchange quality is improved.

In some examples, the heat exchange pipeline and the circulating pipeline are connected in a sealing connection mode. The heat exchange pipe and the circulation pipe can be disassembled while preventing leakage of the heat exchange medium.

In some examples, the inner end of the fixing sleeve is provided with a foam cushion, and the fixing sleeve is arranged at the left end and the right end of the heat exchange pipeline. Make the heat exchange pipeline fixed more firm, prevent simultaneously that the heat exchange pipeline from damaging, cause revealing of medium.

Examples

Based on the above-mentioned conception, as shown in fig. 1-4, in a specific application scenario of a rotatable insertion heat exchange device provided by the present utility model, as shown in fig. 1, the heat exchange device includes a water tank assembly 1, a solar collector assembly 2 connected to the lower end of the water tank assembly 1, and a heat exchange mechanism assembly 3 disposed inside the water tank assembly 1, wherein,

as shown in fig. 1, the water tank assembly 1 is composed of a water tank shell 11, a water tank heat-insulating layer 12, a heating plate 13, a water outlet 14 and a water inlet 15, wherein the water tank heat-insulating layer 12 is connected to the inner end of the water tank shell 11, the heating plate 13 is connected to the upper end of the water tank heat-insulating layer 12, the water outlet 14 is connected to the left end of the water tank shell 11, and the water inlet 15 is arranged below the water outlet 14;

as shown in fig. 1, the solar collector assembly 2 is composed of an upper connecting plate 21, a mounting base 22, a solar collector plate 23, a circulating pipeline 24 and an electromagnetic valve 25, wherein the lower end of the upper connecting plate 21 is connected with the solar collector plate 23, the lower end of the solar collector plate 23 is connected with the mounting base 22, the electromagnetic valve 25 is arranged in the upper connecting plate 21, and the lower end of the electromagnetic valve 25 is connected with the water outlet 14;

as shown in fig. 3, the heat exchange mechanism assembly 3 is composed of a heat exchange pipe 31, a fixing plate 32 and a fixing sleeve 33, the fixing sleeve 33 is connected to the outer side of the heat exchange pipe 31, and the fixing plate 32 is connected to the lower end of the fixing sleeve 33.

In a specific application scenario, the water outlet 14 is connected with the water tank shell 11 and the water tank heat insulation layer 12, and the water inlet 15 is connected with the water tank shell 11 and the water tank heat insulation layer 12 in a communication manner, and water pumps are arranged on the water outlet 14 and the water inlet 15.

In a specific application scenario, a cavity structure is formed in the upper connecting plate 21, and the circulation pipeline 24 is connected with the upper connecting plate 21 in a communicating manner.

In a specific application scenario, as shown in fig. 4, an installation door is disposed at the front end of the upper connection plate 21, and the upper connection plate 21 is connected to the tank housing 11 by means of a bolt connection.

In a specific application scenario, the longitudinal section of the circulation pipe 24 is "U" shaped, and both ends of the circulation pipe 24 are connected with electromagnetic valves 25.

In one particular application scenario, the cross-sectional shape of the heat exchange tube 31 is serpentine.

In one specific application scenario, the heat exchange pipeline 31 is connected with the circulation pipeline 24 in a sealing connection manner.

In a specific application scenario, a sponge pad is disposed at the inner end of the fixing sleeve 33, and the fixing sleeve 33 is disposed at both the left and right ends of the heat exchange tube 31.

Those skilled in the art will appreciate that the drawing is merely a schematic illustration of a preferred implementation scenario and that the modules or flows in the drawing are not necessarily required to practice the present utility model.

Those skilled in the art will appreciate that the modules in the heat exchange device in the implementation scenario may be distributed in the heat exchange device in the implementation scenario as described in the implementation scenario, or that corresponding changes may be made in one or more heat exchange devices different from the implementation scenario. The modules of the implementation scenario may be combined into one module, or may be further split into a plurality of sub-modules.

The foregoing disclosure is merely illustrative of the present utility model, but the present utility model is not limited thereto, and any changes that may be contemplated by those skilled in the art should fall within the scope of the present utility model.

Claims (8)

1. An energy-saving heat exchange device for solar equipment comprises a water tank assembly (1), a solar heat collector assembly (2) connected at the lower end of the water tank assembly (1) and a heat exchange mechanism assembly (3) arranged inside the water tank assembly (1), and is characterized in that,

the water tank assembly (1) is composed of a water tank shell (11), a water tank heat-insulating layer (12), a heating plate (13), a water outlet (14) and a water inlet (15), wherein the water tank heat-insulating layer (12) is connected to the inner end of the water tank shell (11), the heating plate (13) is connected to the upper end of the inner part of the water tank heat-insulating layer (12), the water outlet (14) is connected to the left end of the water tank shell (11), and the water inlet (15) is arranged below the water outlet (14);

the solar heat collector assembly (2) is composed of an upper connecting plate (21), a mounting base (22), a solar heat collecting plate (23), a circulating pipeline (24) and an electromagnetic valve (25), wherein the lower end of the upper connecting plate (21) is connected with the solar heat collecting plate (23), the lower end of the solar heat collecting plate (23) is connected with the mounting base (22), the electromagnetic valve (25) is arranged in the upper connecting plate (21), and the lower end of the electromagnetic valve (25) is connected with a water outlet (14);

the heat exchange mechanism assembly (3) is composed of a heat exchange pipeline (31), a fixing plate (32) and a fixing sleeve (33), the fixing sleeve (33) is connected to the outer side of the heat exchange pipeline (31), and the fixing plate (32) is connected to the lower end of the fixing sleeve (33).

2. An energy-saving heat exchange device for solar energy equipment according to claim 1, wherein the water outlet (14) is connected with the water tank shell (11) and the water tank heat insulation layer (12) and the water inlet (15) is connected with the water tank shell (11) and the water tank heat insulation layer (12) in a communicating way, and water pumps are arranged on the water outlet (14) and the water inlet (15).

3. An energy-saving heat exchange device for solar energy equipment according to claim 1, wherein the upper connecting plate (21) is internally provided with a cavity structure, and the circulating pipeline (24) is connected with the upper connecting plate (21) in a communicating manner.

4. An energy-saving heat exchange device for solar energy equipment according to claim 1, characterized in that the front end of the upper connecting plate (21) is provided with an installation door, and the upper connecting plate (21) is connected with the water tank shell (11) by adopting a bolt connection mode.

5. An energy-saving heat exchange device for solar energy equipment according to claim 1, wherein the longitudinal section of the circulating pipe (24) is of a U-shape, and both ends of the circulating pipe (24) are connected with electromagnetic valves (25).

6. An energy efficient heat exchange device for solar energy plants according to claim 1, characterized in that the cross-sectional shape of the heat exchange conduit (31) is serpentine.

7. An energy-saving heat exchange device for solar energy equipment according to claim 1, characterized in that the heat exchange pipe (31) is connected with the circulation pipe (24) in a sealing connection.

8. An energy-saving heat exchange device for solar energy equipment according to claim 1, characterized in that the inner end of the fixing sleeve (33) is provided with a sponge cushion, and the fixing sleeve (33) is arranged at the left and right ends of the heat exchange pipeline (31).