CN215864778U - High-efficiency energy-saving heat exchange equipment - Google Patents

Abstract

The utility model discloses high-efficiency energy-saving heat exchange equipment which comprises a box body, wherein mounting holes are formed in the outer walls of two sides of the box body, the inner wall of each mounting hole is connected with the same heat exchange spherical shell through a bearing, a water inlet mechanism and a water outlet mechanism are respectively arranged at two ends of each heat exchange spherical shell, guide plates distributed at equal intervals are arranged on the inner wall of each heat exchange spherical shell and are arranged in an inclined mode, fixing holes are formed in the outer walls of two sides of the box body, middle rotating rings are arranged on the inner walls of the fixing holes, and heat exchange tubes distributed at equal intervals are arranged on the outer walls of the two opposite sides of the middle rotating rings. The water of the utility model can fully exchange heat with hot water in the heat exchange tube while rotating tightly close to the inner wall of the heat exchange spherical shell, and can prevent cold water in the heat exchange spherical shell from accumulating together to cause poor heat exchange efficiency.

Description

High-efficiency energy-saving heat exchange equipment

Technical Field

The utility model relates to the technical field of heat exchangers, in particular to high-efficiency energy-saving heat exchange equipment.

Background

A heat exchanger (also called heat exchanger) is a device that transfers part of the heat of a hot fluid to a cold fluid. The heat exchanger plays an important role in chemical industry, petroleum industry, power industry, food industry and other industrial production, can be used as a heater, a cooler, a condenser, an evaporator, a reboiler and the like in chemical industry production, and is widely applied.

The existing high-efficiency energy-saving heat exchange equipment has the following defects: at present there are a lot of heat exchangers in the market can turn into domestic water or as the heating usage with the heat transfer of the hot water that produces in the mill through the heat exchanger, but current heat exchanger generally all adopts traditional platelike heat transfer mode to carry out the heat transfer, and this kind of heat exchange efficiency is not high, and the practicality is relatively poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects in the prior art and provides high-efficiency energy-saving heat exchange equipment.

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

the utility model provides a high-efficient energy-conserving indirect heating equipment, includes the box, the mounting hole has all been opened to the both sides outer wall of box, the inner wall of mounting hole is connected with same heat transfer spherical shell through the bearing, the both ends of heat transfer spherical shell are provided with water inlet mechanism and water outlet mechanism respectively, the inner wall of heat transfer spherical shell is provided with the baffle that the equidistance distributes, the baffle sets up for the slope, the fixed orifices has all been opened to the both sides outer wall of box, the inner wall of fixed orifices is provided with the meson, two the relative one side outer wall of meson is provided with the heat exchange tube that the equidistance distributes, and the heat exchange tube is spherical distribution around the outer wall all around of heat transfer spherical shell, the outer wall of box is provided with warm braw mechanism.

Furthermore, the water inlet mechanism comprises a first booster pump, a first domestic water pipe is inserted into the input end of the first booster pump, an injection pipe is inserted into the output end of the first booster pump, and the injection pipe and the guide plate are matched for use.

Furthermore, go out water mechanism and include the second booster pump, the output of second booster pump is pegged graft and is had second domestic water pipe, and the input of second booster pump is pegged graft and is had the pipe that absorbs water.

Furthermore, the outer walls of the two middle rotating rings are respectively provided with a water inlet hole and a water outlet hole, the inner wall of the water inlet hole is spliced with a water inlet pipe, and the inner wall of the water outlet hole is spliced with a water outlet pipe.

Furthermore, the number of the heat exchange tubes is 10-15, and the heat exchange tubes are uniformly distributed on the outer wall of the heat exchange spherical shell.

Furthermore, warm braw mechanism includes aspirator pump and heating panel, and the input of aspirator pump has cup jointed the suction fill, and the output of aspirator pump communicates with each other with the cavity inside between box and the heat transfer spherical shell.

Furthermore, the outer wall of one side of the heat dissipation plate is provided with heat dissipation holes, the inner walls of the heat dissipation holes are provided with flow guide buckets, and the inner walls of the heat dissipation plate are provided with grids distributed at equal intervals.

The utility model has the beneficial effects that:

1. this energy-efficient indirect heating equipment, through being provided with the heat transfer spherical shell, the heat exchange tube, baffle and mechanism of intaking, during the heat transfer, mechanism sprays domestic water to the baffle above through intaking, because the baffle sets up for the slope, consequently, domestic water can drive whole heat transfer spherical shell and rotate, can drive the inside water of heat transfer spherical shell and rotate when heat transfer spherical shell pivoted, water pastes and tightly can be abundant carry out abundant heat transfer with the hot water in the heat exchange tube when heat transfer spherical shell inner wall pivoted, can prevent simultaneously that the cold water in the heat transfer spherical shell from piling up and causing heat exchange efficiency poor together, design the heat transfer spherical shell into the globoid, and let the heat transfer pipe surround the heat transfer spherical shell and can let the domestic water in the whole heat transfer spherical shell be heated evenly, thereby promote domestic water's heat exchange efficiency, the practicality is stronger.

2. This energy-efficient indirect heating equipment, through being provided with the aspirator pump, the water conservancy diversion is fought, heat transfer board and grid, can come in the cavity between box and the heat transfer spherical shell with the air suction through the aspirator pump, hot water in the heat exchange tube this moment can carry out the heat transfer with the air to let the air have certain temperature, then in leading-in heating panel of hot-air through the water conservancy diversion fill, people can keep warm through the steam in the heating panel, can adjust the wind direction through the grid.

The part not related in the device all is the same with prior art or can adopt prior art to realize, and the device design structure is reasonable, and convenient to use satisfies people's user demand.

Drawings

FIG. 1 is an overall three-dimensional structure diagram of a high-efficiency energy-saving heat exchange device provided by the utility model;

FIG. 2 is a three-dimensional structure diagram of a heat exchange tube of the high-efficiency energy-saving heat exchange device provided by the utility model;

fig. 3 is a three-dimensional structure diagram inside a heat exchange spherical shell of the high-efficiency energy-saving heat exchange device provided by the utility model.

In the figure: 1-box, 2-air suction pump, 3-first booster pump, 4-water outlet pipe, 5-grid, 6-heat dissipation plate, 7-heat exchange spherical shell, 8-diversion bucket, 9-second booster pump, 10-water inlet pipe, 11-transfer ring, 12-heat exchange pipe, 13-water suction pipe, 14-guide plate and 15-injection pipe.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Reference will now be made in detail to embodiments of the present patent, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present patent and are not to be construed as limiting the present patent.

In the description of this patent, it is to be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientations and positional relationships indicated in the drawings for the convenience of describing the patent and for the simplicity of description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the patent.

In the description of this patent, it is noted that unless otherwise specifically stated or limited, the terms "mounted," "connected," and "disposed" are to be construed broadly and can include, for example, fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed. The specific meaning of the above terms in this patent may be understood by those of ordinary skill in the art as appropriate.

Referring to fig. 1-3, a high-efficiency energy-saving heat exchange device comprises a box body 1, wherein mounting holes are respectively formed in the outer walls of two sides of the box body 1, the inner wall of each mounting hole is connected with the same heat exchange spherical shell 7 through a bearing, a water inlet mechanism and a water outlet mechanism are respectively arranged at two ends of each heat exchange spherical shell 7, guide plates 14 which are distributed equidistantly are fixed on the inner wall of each heat exchange spherical shell 7 through bolts, the guide plates 14 are arranged in an inclined mode, fixing holes are respectively formed in the outer walls of two sides of the box body 1, a transit ring 11 is fixed on the inner wall of each fixing hole through bolts, heat exchange tubes 12 which are distributed equidistantly are fixed on the outer wall of one side, opposite to the two transit rings 11, the heat exchange tubes 12 are distributed in a spherical mode and surround the outer wall of the heat exchange spherical shell 7, a warm air mechanism is arranged on the outer wall of the box body 1, a first booster pump 3 and a second booster pump 9 are started to spray domestic water onto the guide plates 14 through an injection tube 15, and the guide plates 14 are arranged in an inclined mode, therefore domestic water can drive whole heat transfer spherical shell 7 and rotate, can drive the inside water of heat transfer spherical shell 7 and rotate when heat transfer spherical shell 7 pivoted, water pastes and tightly can be abundant when 7 inner walls of heat transfer spherical shell rotate and carry out abundant heat transfer with the hot water in heat exchange tube 12, cold water in the heat transfer spherical shell 7 that can prevent simultaneously piles up and causes heat exchange efficiency poor together, spherical shell 7 designs into the spheroid with the heat transfer, and let heat exchange tube 12 surround heat transfer spherical shell 7 and can let the domestic water in the whole heat transfer spherical shell 7 be heated evenly.

In the utility model, the water inlet mechanism comprises a first booster pump 3, a first domestic water pipe is inserted into the input end of the first booster pump 3, an injection pipe 15 is inserted into the output end of the first booster pump 3, and the injection pipe 15 is matched with a guide plate 14 for use.

In the utility model, the water outlet mechanism comprises a second booster pump 9, a second domestic water pipe is inserted into the output end of the second booster pump 9, and a water suction pipe 13 is inserted into the input end of the second booster pump 9.

In the utility model, the outer walls of the two middle rotating rings 11 are respectively provided with a water inlet hole and a water outlet hole, the inner wall of the water inlet hole is spliced with a water inlet pipe 10, and the inner wall of the water outlet hole is spliced with a water outlet pipe 4.

In the utility model, the number of the heat exchange tubes 12 is 10-15, and the heat exchange tubes 12 are uniformly distributed on the outer wall of the heat exchange spherical shell 7.

In the utility model, the warm air mechanism comprises an air suction pump 2 and a heat dissipation plate 6, an air suction hopper is sleeved at the input end of the air suction pump 2, and the output end of the air suction pump 2 is communicated with the interior of a cavity between the box body 1 and the heat exchange spherical shell 7.

According to the utility model, heat dissipation holes are formed in the outer wall of one side of the heat dissipation plate 6, the flow guide buckets 8 are fixed to the inner walls of the heat dissipation holes through bolts, the grids 5 which are distributed equidistantly are arranged on the inner wall of the heat dissipation plate 6, air can be sucked into a cavity between the box body 1 and the heat exchange spherical shell 7 through the air suction pump 2, hot water in the heat exchange tube 12 can exchange heat with the air at the moment, so that the air has a certain temperature, then the hot air is guided into the heat dissipation plate 6 through the flow guide buckets 8, people can warm through hot air in the heat dissipation plate 6, and the wind direction can be adjusted through the grids 6.

The working principle is as follows: the first booster pump 3 and the second booster pump 9 are started to spray domestic water onto the guide plate 14 through the spraying pipe 15, the guide plate 14 is arranged in an inclined manner, so that the domestic water can drive the whole heat exchange spherical shell 7 to rotate, the water in the heat exchange spherical shell 7 can be driven to rotate when the heat exchange spherical shell 7 rotates, the water can fully exchange heat with hot water in the heat exchange pipe 12 when clinging to the inner wall of the heat exchange spherical shell 7 to rotate, meanwhile, cold water in the heat exchange spherical shell 7 can be prevented from being accumulated together to cause poor heat exchange efficiency, the heat exchange spherical shell 7 is designed into a sphere, the heat exchange pipe 12 surrounds the heat exchange spherical shell 7, so that the domestic water in the whole heat exchange spherical shell 7 can be uniformly heated, air can be sucked into a cavity between the box body 1 and the heat exchange spherical shell 7 through the air suction pump 2, and the hot water in the heat exchange pipe 12 can exchange heat with air, thereby let the air have certain temperature, then through leading-in hot-air to the heating panel 6 of water conservancy diversion fill 8, people can get warm through the steam in the heating panel 6, can adjust the wind direction through grid 6.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (7)

1. The utility model provides a high-efficient energy-conserving indirect heating equipment, includes box (1), its characterized in that, the both sides outer wall of box (1) has all been opened the mounting hole, the inner wall of mounting hole is connected with same heat transfer spherical shell (7) through the bearing, the both ends of heat transfer spherical shell (7) are provided with water inlet mechanism and play water mechanism respectively, the inner wall of heat transfer spherical shell (7) is provided with baffle (14) that the equidistance distributes, baffle (14) set up for the slope, the both sides outer wall of box (1) has all been opened the fixed orifices, the inner wall of fixed orifices is provided with well change ring (11), two the relative one side outer wall of well change ring (11) is provided with heat exchange tube (12) that the equidistance distributes, and heat exchange tube (12) are spherical distribution around the outer wall all around of heat transfer spherical shell (7), the outer wall of box (1) is provided with warm braw mechanism.

2. The efficient energy-saving heat exchange equipment according to claim 1, wherein the water inlet mechanism comprises a first booster pump (3), a first domestic water pipe is inserted into an input end of the first booster pump (3), an injection pipe (15) is inserted into an output end of the first booster pump (3), and the injection pipe (15) and the guide plate (14) are matched for use.

3. The efficient energy-saving heat exchange equipment according to claim 1, wherein the water outlet mechanism comprises a second booster pump (9), a second domestic water pipe is inserted into an output end of the second booster pump (9), and a water suction pipe (13) is inserted into an input end of the second booster pump (9).

4. A high-efficiency energy-saving heat exchange device according to claim 3, characterized in that the outer walls of the two middle rotating rings (11) are respectively provided with a water inlet hole and a water outlet hole, the inner wall of the water inlet hole is inserted with a water inlet pipe (10), and the inner wall of the water outlet hole is inserted with a water outlet pipe (4).

5. An energy-efficient heat exchange device as claimed in claim 4, characterized in that the number of the heat exchange tubes (12) is 10-15, and the heat exchange tubes (12) are uniformly distributed on the outer wall of the heat exchange spherical shell (7).

6. The efficient energy-saving heat exchange device according to claim 5, wherein the warm air mechanism comprises an air suction pump (2) and a heat dissipation plate (6), an air suction hopper is sleeved at the input end of the air suction pump (2), and the output end of the air suction pump (2) is communicated with the interior of the cavity between the box body (1) and the heat exchange spherical shell (7).

7. A high-efficiency energy-saving heat exchange device according to claim 6, characterized in that the outer wall of one side of the heat dissipation plate (6) is provided with heat dissipation holes, the inner walls of the heat dissipation holes are provided with flow guide buckets (8), and the inner walls of the heat dissipation plate (6) are provided with grids (5) distributed at equal intervals.

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