CN218179274U - Solar vertical-insertion type pipe heat collector - Google Patents

Abstract

The utility model discloses a formula venturi tube heat collector is inserted to solar energy vertical belongs to the heat collector field, including heat collector body and the support piece on it, the heat collector body includes nonrust steel pipe, is in the 30-S venturi tube that is the spiral distribution setting in the stainless steel pipe, and 30-S venturi tube both ends are connected with outlet pipe and inlet tube respectively, are located and are provided with first solar vacuum tube and second solar vacuum tube on the 30-S venturi tube lateral wall of outlet pipe and inlet tube department. The utility model discloses a be provided with the circulating pump in the heat collector, carry out continuous circulation to being in the intraductal water of 30-S shape, and for the temperature of guaranteeing that can abundant utilization solar vacuum tube in the cyclic process, set up solar vacuum tube into built-in glass pipe, glass pipe dustcoat and level are in the vacuum layer between the two, when not influencing the heat absorption effect of solar vacuum tube, can utilize its built-in glass pipe to carry out the heat transfer, compare original technique, can show improvement heat transfer effect, ensure that the hydroenergy in the circulation heats fast.

Description

Solar vertical-insertion type pipe heat collector

Technical Field

The utility model relates to a heat collector technical field especially relates to a formula venturi tube heat collector is inserted to solar energy vertical stroke.

Background

The solar water heater is divided into a vacuum tube type solar water heater and a flat plate type solar water heater according to the structural form, a vacuum tube of the solar water heater is a core element of the solar water heater, which is known as the heart of the solar water heater, the quality of the vacuum tube directly influences the service life and the performance of the solar water heater, but the existing solar heat collector does not have the intelligent water inlet and outlet function, so that the solar water heater is completely used and realized when water is fed and discharged, the solar energy is seriously wasted, the water temperature is not uniformly heated, the vacuum tube in the water heater is not communicated with a circulating tube, and the heat exchange effect is also influenced, so that the solar vertical-insertion type tubular heat collector is provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problems existing in the prior art and providing a solar vertical-insertion type pipe heat collector.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a solar vertical-insertion type tubular heat collector comprises a heat collector body and a support piece arranged on the heat collector body, wherein the heat collector body comprises a stainless steel tube and 30-S-shaped tubes which are arranged in the stainless steel tube in a spiral distribution mode, two ends of each 30-S-shaped tube are respectively connected with a water outlet pipe and a water inlet pipe, a first solar vacuum tube and a second solar vacuum tube are arranged on the outer side wall of each 30-S-shaped tube at the positions of the water outlet pipe and the water inlet pipe, a 30-S-shaped solar vacuum tube matched with the 30-S-shaped tubes is arranged between the first solar vacuum tube and the second solar vacuum tube, the 30-S-shaped solar vacuum tubes are communicated with the first solar vacuum tube and the second solar vacuum tube through the 30-S-shaped tubes, and the 30-S-shaped tubes are respectively connected with the first solar vacuum tube, the second solar vacuum tube and the 30-S-shaped solar vacuum tube through a nano-sub connector.

Preferably, the first solar vacuum tube, the second solar vacuum tube and the 30-S-shaped solar vacuum tube are all composed of an internal glass tube, a glass tube outer cover and a vacuum layer arranged between the internal glass tube and the glass tube outer cover, and the outer surface of the glass tube outer cover is sprayed with a coating.

Preferably, getters are arranged at two ends of the first solar vacuum tube, the second solar vacuum tube and the 30-S-shaped solar vacuum tube, a getter film is arranged at one end of each getter, and clips for supporting are arranged on the getter film and the built-in glass tube.

Preferably, a water inlet and a water outlet are arranged on the stainless steel pipe and are respectively communicated with the water inlet pipe and the water outlet pipe, and one end of the water inlet is connected with a circulating pump 11 through an external pipeline.

Preferably, the 30-S-shaped pipe is provided with a plurality of mounting holes, the mounting holes are communicated with the built-in glass pipe through a nano connector arranged outside, and a silica gel ring is arranged between the nano connector and the mounting holes.

Preferably, a plurality of temperature sensors are installed inside the 30-S shaped pipe.

Compared with the prior art, the beneficial effects of the utility model are that:

this scheme adopts to be provided with the circulating pump in the heat collector, carries out continuous circulation to being in the intraductal water of 30-S shape to in order to guarantee the temperature of can abundant utilization solar vacuum tube in the circulation, set up solar vacuum tube into built-in glass pipe, glass pipe dustcoat and level in the vacuum layer between the two, when not influencing the heat absorption effect of solar vacuum tube, can utilize its built-in glass pipe to carry out the heat transfer, compare original technique, can show improvement heat transfer effect, ensure that hydroenergy in the circulation heats fast.

Drawings

Fig. 1 is a schematic perspective view of a solar vertical-insertion type tubular heat collector according to the present invention;

fig. 2 is a schematic view of a vacuum tube distribution three-dimensional structure of a solar vertical-insertion type tube heat collector provided by the present invention;

fig. 3 is a schematic structural view of a cross section of a vacuum tube in a solar vertical-insertion type tube collector provided by the present invention;

fig. 4 is a schematic front structural view of a solar vertical-insertion type tubular heat collector provided by the present invention;

FIG. 5 is a first cross-sectional view of a 30-S-shaped tube in a solar vertical-insertion type tube collector according to the present invention;

fig. 6 is a sectional view of a 30-S-shaped tube in a solar vertical-insertion type tube collector according to the present invention.

In the figure: 1. a stainless steel tube; 2. 30-an S-shaped tube; 3. a water outlet pipe; 4. a water inlet pipe; 5. a first solar vacuum tube; 6. a second solar vacuum tube; 7. 30-S-shaped solar vacuum tubes; 8. a nano-linker; 9. a getter; 101. a glass tube is arranged inside; 102. a glass tube housing; 103. a vacuum layer; 11. and a circulating pump.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, rather than all embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative work belong to the protection scope of the present invention based on the embodiments of the present invention.

Referring to fig. 1-6, a solar vertical-insertion type tubular heat collector comprises a heat collector body and a support member thereon, wherein the heat collector body comprises a stainless steel tube 1, a 30-S-shaped tube 2 spirally distributed in the stainless steel tube 1, two ends of the 30-S-shaped tube 2 are respectively connected with a water outlet tube 3 and a water inlet tube 4, the stainless steel tube 1 is provided with a water inlet and a water outlet which are respectively communicated with the water inlet tube 4 and the water outlet tube 3, one end of the water inlet is connected with a circulating pump 11 through an external pipeline, the circulating pump 11 continuously circulates water in the 30-S-shaped tube, and the temperature of a solar vacuum tube can be fully utilized in the circulating process.

The outer side wall of the 30-S-shaped pipe 2 positioned at the water outlet pipe 3 and the water inlet pipe 4 is provided with a first solar vacuum pipe 5 and a second solar vacuum pipe 6, a 30-S-shaped solar vacuum pipe 7 matched with the 30-S-shaped pipe 2 is arranged between the first solar vacuum pipe 5 and the second solar vacuum pipe 6, the first solar vacuum pipe 5, the second solar vacuum pipe 6 and the 30-S-shaped solar vacuum pipe 7 are all composed of a built-in glass pipe 101, a glass pipe outer cover 102 and a vacuum layer 103 arranged between the glass pipe outer cover and the built-in glass pipe 101, and the outer surface of the glass pipe outer cover 102 is sprayed with a coating.

The 30-S-shaped solar vacuum tube 7 is communicated with the first solar vacuum tube 5 and the second solar vacuum tube 6 through the 30-S-shaped tube 2, the 30-S-shaped tube 2 is respectively connected with the first solar vacuum tube 5, the second solar vacuum tube 6 and the 30-S-shaped solar vacuum tube 7 through the nano joint 8, a plurality of mounting holes are formed in the 30-S-shaped tube 2, the mounting holes are communicated with the built-in glass tube 101 through the nano joint 8 arranged outside, and a silica gel ring is arranged between the nano joint 8 and the mounting holes;

31-of which it is noted that: the connection between the nano joint 8 and the mounting hole ensures sealing, and the other end of the nano joint 8 is communicated with the built-in glass tube 101.

The two ends of the first solar vacuum tube 5, the second solar vacuum tube 6 and the 30-S-shaped solar vacuum tube 7 are respectively provided with a getter 9, one end of each getter 9 is provided with a gas suction film, the gas suction film and the built-in glass tube 101 are respectively provided with a clip for supporting, and the 30-S-shaped tube 2 is internally provided with a plurality of temperature sensors which can control the opening of the circulating pump 11 through a module, so that the circulating pump 11 can be opened timely for heat exchange when needed, and the utilization rate of solar energy is favorably improved.

It should be noted that: the getter 9 is disposed in a vacuum layer inside the vacuum tube, wherein the vacuum layer is configured for vacuum pumping, and the getter 9 and a getter film used in cooperation with the getter 9 are for stabilizing an internal vacuum environment.

This scheme has also improved the heat exchange efficiency of solar vacuum tube when improving hydrologic cycle, when not influencing the endothermic effect of solar vacuum tube, can utilize its built-in glass pipe to carry out the heat transfer, compares original technique, can show improvement heat transfer effect, ensures that the hydroenergy in the circulation heats fast.

The above, only be the embodiment of the preferred of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, which are designed to be replaced or changed equally, all should be covered within the protection scope of the present invention.

Claims (6)

1. The solar vertical-insertion type pipe heat collector comprises a heat collector body and a support piece arranged on the heat collector body, and is characterized in that the heat collector body comprises a stainless steel pipe (1) and 30-S-shaped pipes (2) which are arranged in the stainless steel pipe (1) in a spiral distribution mode, two ends of each 30-S-shaped pipe (2) are respectively connected with a water outlet pipe (3) and a water inlet pipe (4), a first solar vacuum pipe (5) and a second solar vacuum pipe (6) are arranged on the outer side wall of each 30-S-shaped pipe (2) which is located at the positions of the water outlet pipe (3) and the water inlet pipe (4), a 30-S-shaped solar vacuum pipe (7) matched with the 30-S-shaped pipes (2) is arranged between the first solar vacuum pipe (5) and the second solar vacuum pipe (6), the 30-S-shaped solar vacuum pipe (7) is communicated with the first solar vacuum pipe (5) and the second solar vacuum pipe (6) through the 30-S-shaped pipes (2), and the 30-S-shaped pipes (2) are respectively connected with the first solar vacuum pipe (5), the second solar vacuum pipe (6) and the S-shaped solar vacuum pipe (7) through a nano-shaped joint (8).

2. The solar vertical-insertion type tubular heat collector according to claim 1, wherein the first solar vacuum tube (5), the second solar vacuum tube (6) and the 30-S shaped solar vacuum tube (7) are all composed of an internal glass tube (101), a glass tube outer cover (102) and a vacuum layer (103) arranged between the internal glass tube (101) and the glass tube outer cover (102), and the outer surface of the glass tube outer cover (102) is coated with a coating.

3. The solar vertical-insertion type tubular heat collector according to claim 2, wherein the first solar vacuum tube (5), the second solar vacuum tube (6) and the 30-S shaped solar vacuum tube (7) are provided with getters (9) at two ends, one end of each getter (9) is provided with a getter film, and the getter film and the built-in glass tube (101) are provided with clips for supporting.

4. The solar vertical-insertion type tubular heat collector according to claim 1, wherein the stainless steel tube (1) is provided with a water inlet and a water outlet which are respectively communicated with the water inlet tube (4) and the water outlet tube (3), and one end of the water inlet is connected with a circulating pump (11) through an external pipeline.

5. The solar vertical-insertion type tubular heat collector according to claim 2, wherein the 30-S-shaped tube (2) is provided with a plurality of mounting holes, the mounting holes are communicated with the built-in glass tube (101) through the externally arranged nano sub-joints (8), and a silica gel ring is arranged between the nano sub-joints (8) and the mounting holes.

6. The solar vertical-insertion type tubular heat collector according to claim 1, wherein a plurality of temperature sensors are installed inside the 30-S shaped tube (2).

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