CN219045448U - Cabin cooling assembly for wind power generation - Google Patents

Abstract

The utility model discloses a cabin radiating component for wind power generation, which relates to the field of radiating components, and comprises a cabin and a power generation fan head arranged in the middle of the front end of the cabin, wherein a dehumidifying component is arranged at the right end of the cabin, so that a dehumidifying screen cylinder dehumidifies moisture in the outside air, and the dehumidified air filters dust in the air through a dedusting filter screen, so that the filtered air is led into the cabin through an air outlet, and the moisture is prevented from entering the cabin to cause short circuit of electronic elements in the cabin, thereby improving the working efficiency of the cabin; through having set up the radiator unit in cabin bottom, make the hydraulic telescoping rod open the louvre indirectly and make the air-blower pass through the louvre with the inside steam of cabin and discharge, make gas can flow in cabin inside to the radiating effect has been improved.

Description

Cabin cooling assembly for wind power generation

Technical Field

The utility model relates to the field of heat dissipation assemblies, in particular to a cabin heat dissipation assembly for wind power generation.

Background

Wind power generation is to convert kinetic energy of wind into electric energy, convert the kinetic energy of wind into mechanical kinetic energy and then convert the mechanical energy into electric kinetic energy, namely wind power generation, wherein the principle of wind power generation is to drive windmill blades to rotate by utilizing wind power, and then the rotating speed is increased by a speed increaser to drive a generator to generate electricity, and a device required by wind power generation is called a wind generating set.

For example, chinese patent publication No. CN212690243U is a heat dissipation casing for wind power generation, which comprises a bottom support plate, wherein the top of the bottom support plate is fixedly connected with a box body, one side of the box body is movably connected with a shutter blade, the top of the box body is fixedly connected with an air inlet cover, the inside of the air inlet cover is fixedly connected with a dust removal net, and one side of the air inlet cover is fixedly connected with a communicating pipe; the utility model has the advantages that: this heat dissipation casing for wind power generation through being provided with support frame, division board, stationary flow board and heat dissipation through-hole, wherein the division board can cut apart into a plurality of little space with one side of box, can lead to the air, and the division board cooperation stationary flow board and offer the heat dissipation through-hole on the stationary flow board can make in the even case of blowing into of air, reduces radiating blind area in the box, does benefit to the heat dissipation, and the radiating effect is good, in addition through being provided with the fin in one side of box, can be of price quick radiating effect.

In the above patent, referring to fig. 1 and 2, the heat dissipation fan is located at the top of the box, and because of the flowing property of the gas, the gas is difficult to flow in the whole box, so that the heat dissipation effect of the structure inside the box is inconsistent, thereby reducing the heat dissipation effect; and when the existing engine room is used for radiating heat, moisture easily enters the engine room, so that electronic components in the engine room are easily short-circuited, and the working efficiency of the engine room is reduced.

Disclosure of Invention

Accordingly, in order to solve the above-described drawbacks, the present utility model provides a nacelle heat dissipation assembly for wind power generation.

The utility model is realized in such a way that a cabin radiating assembly for wind power generation is constructed, and the device comprises a cabin and a power generation fan head arranged in the middle of the front end of the cabin;

further comprises:

the dehumidifying component is welded and fixed in the middle of the right end of the engine room; the dehumidifying component can dehumidify outside moist air in operation; the heat dissipation assembly is arranged at the rear part of the bottom end in the cabin; the heat dissipation assembly is used for dissipating heat in the cabin;

the dehumidifying assembly includes:

the left end of the dehumidifying cylinder is welded and fixed in the middle of the right end of the engine room; the bottom end of the first air inlet is connected with a pipeline at the front part of the top end of the dehumidifying cylinder; the front end of the dehumidifying screen cylinder is rotationally connected with the inner front end of the dehumidifying screen cylinder; the second air inlet is arranged at the bottom of the rear end of the outer side surface of the dehumidifying screen cylinder; the front end and the rear end of the dust removing filter screen are respectively inserted and fixed at the front end and the rear end in the dehumidifying screen cylinder; the front end of the air outlet is connected with the middle part of the rear end of the dust removing filter screen through a pipeline; the top end of the water outlet is connected with the pipeline at the bottom end of the dehumidification cylinder; wherein the dehumidifying screen drum is made of montmorillonite.

Preferably, the heat dissipation assembly includes:

the cooling plate is arranged at the rear part of the bottom end in the cabin; the fixing plates are welded and fixed at four corners of the left end and the right end of the radiating plate; the placing groove is arranged in the middle of the top end of the heat dissipation plate; wherein, the fixed plate is L shape board.

Preferably, the heat dissipation assembly further comprises:

the radiating holes are arranged at the front part of the top end of the placing groove; the hydraulic telescopic rod is fixed in the middle of the rear end of the placing groove through bolts; wherein, the heat dissipation hole is circular.

Preferably, the heat dissipation assembly further comprises:

the middle part of the rear end of the positioning plate is fixedly connected with a hydraulic telescopic rod in an inserting manner; the blower is fixed at the front part of the top end of the heat dissipation plate through bolts; wherein, the outer diameter of the air blower is larger than the width of the placing groove.

Preferably, the dehumidifying screen cylinder consists of a dehumidifying screen and a cylinder, and the dehumidifying screen is spirally arranged on the outer side surface of the cylinder.

Preferably, the dust removing filter screen is an active carbon filter screen, and the mesh of the dust removing filter screen is 200 meshes.

Preferably, the locating plate is connected in a sliding manner in the placing groove, and the locating plate is movably connected with the side wall of the placing groove through a hydraulic telescopic rod.

Preferably, the positioning plate is a circular plate, and the diameter of the positioning plate is larger than the diameter of the radiating hole.

The utility model has the following advantages: the utility model provides a cabin heat radiation assembly for wind power generation through improvement, which is improved compared with the same type of equipment as follows:

according to the cabin cooling assembly for wind power generation, the dehumidifying assembly is arranged at the right end of the cabin, so that the dehumidifying screen cylinder dehumidifies moisture in the outside air, and the dehumidified air filters dust in the air through the dust removing filter screen, so that the filtered air is led into the cabin through the air outlet, and the moisture is prevented from entering the cabin to cause short circuit of electronic elements in the cabin, and the working efficiency of the cabin cooling assembly is improved.

According to the cabin cooling assembly for wind power generation, the cooling assembly is arranged at the bottom end in the cabin, so that the hydraulic telescopic rod indirectly opens the cooling hole and simultaneously enables the blower to discharge hot air in the cabin through the cooling hole, and the air can flow in the cabin, and therefore the cooling effect is improved.

Drawings

FIG. 1 is a schematic diagram of a prior art structure;

FIG. 2 is a schematic diagram of a prior art stabilizer plate;

FIG. 3 is a schematic diagram of the structure of the present utility model;

FIG. 4 is a perspective cross-sectional view of the nacelle of the present utility model;

FIG. 5 is a schematic perspective view of a dehumidifying assembly according to the present utility model;

FIG. 6 is a rear cross-sectional view of the dehumidification assembly of the present utility model;

FIG. 7 is a schematic perspective view of a heat dissipating assembly according to the present utility model;

fig. 8 is a perspective exploded view of a heat dissipating assembly of the present utility model.

Wherein: cabin-1, generating fan head-2, dehumidification subassembly-3, radiating subassembly-4, dehumidification section of thick bamboo-31, first air intake-32, dehumidification screen section of thick bamboo-33, second air intake-34, dust removal filter screen-35, air outlet-36, outlet-37, heating panel-41, fixed plate-42, standing groove-43, louvre-44, hydraulic telescopic link-45, locating plate-46, air-blower-47.

Detailed Description

The principles and features of the present utility model are described below with reference to fig. 3-8, which are examples only for illustrating the present utility model and are not intended to limit the scope of the present utility model. The utility model is more particularly described by way of example in the following paragraphs with reference to the drawings. Advantages and features of the utility model will become more apparent from the following description and from the claims. It should be noted that the drawings are in a very simplified form and are all to a non-precise scale, merely for convenience and clarity in aiding in the description of embodiments of the utility model.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When a component is considered to be "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Embodiment one:

referring to fig. 3 and 4, a nacelle heat dissipation assembly for wind power generation according to the present utility model includes a nacelle 1 and a power generation fan head 2 disposed in a middle portion of a front end of the nacelle 1.

Referring to fig. 5 and 6, a nacelle heat dissipation assembly for wind power generation according to the present utility model further includes: the dehumidifying component 3 is welded and fixed in the middle of the right end of the engine room 1, the dehumidifying component 3 can dehumidify outside moist air when running, and the radiating component 4 is arranged at the rear part of the bottom end in the engine room 1;

the heat radiation component 4 can radiate heat inside the engine room 1; the dehumidifying assembly 3 includes: the dehumidifying drum 31, the left end of the dehumidifying drum 31 is welded and fixed in the middle of the right end of the engine room 1, the bottom end of the first air inlet 32 is connected with a front pipeline at the top end of the dehumidifying drum 31, and the front end of the dehumidifying screen drum 33 is rotationally connected with the front end in the dehumidifying drum 31;

the second air inlet 34 is arranged at the bottom of the rear end of the outer side surface of the dehumidifying screen drum 33, the front end and the rear end of the dedusting screen 35 are respectively inserted and fixed at the front end and the rear end of the dehumidifying screen drum 33, the front end of the air outlet 36 is connected with the middle pipe at the rear end of the dedusting screen 35, the top end of the water outlet 37 is connected with the bottom end of the dehumidifying screen drum 31, the dehumidifying screen drum 33 is made of montmorillonite, and external air enters the dehumidifying screen drum 31 through the first air inlet 32, so that the dehumidifying screen drum 33 and the dedusting screen 35 dehumidify and dedusting the external air.

Referring to fig. 4, 7 and 8, a nacelle heat dissipation assembly for wind power generation according to the present utility model, the heat dissipation assembly 4 includes: a heat radiation plate 41, wherein the heat radiation plate 41 is arranged at the rear part of the bottom end in the engine room 1, fixing plates 42 are welded and fixed at four corners of the left end and the right end of the heat radiation plate 41, and a placing groove 43 is arranged at the middle part of the top end of the heat radiation plate 41;

the fixed plate 42 is L-shaped plate, and the louvre 44 sets up in the front portion of standing groove 43 top, and hydraulic telescoping rod 45 bolt fastening is in the middle part of standing groove 43 rear end, and louvre 44 is circular, and the grafting of locating plate 46 rear end middle part is fixed with hydraulic telescoping rod 45, and air-blower 47 bolt fastening is in the front portion of heating panel 41 top, and air-blower 47 outside diameter is greater than the width of standing groove 43, starts air-blower 47 for air-blower 47 is discharged the inside steam of cabin 1 through louvre 44.

Referring to fig. 6, in the cabin cooling assembly for wind power generation of the present utility model, the dehumidifying screen cylinder 33 is composed of a dehumidifying screen and a cylinder, and the dehumidifying screen is spirally disposed on the outer side of the cylinder, so that the dehumidifying effect is better.

Referring to fig. 6, in the cabin heat dissipation assembly for wind power generation of the present utility model, the dust removing filter 35 is an activated carbon filter, and the mesh size of the dust removing filter 35 is 200 mesh, so that the dust removing filter 35 has the effect of filtering dust.

Referring to fig. 8, in the nacelle heat dissipation assembly for wind power generation of the present utility model, a positioning plate 46 is slidably connected in a positioning groove 43, and the positioning plate 46 is movably connected to a side wall of the positioning groove 43 through a hydraulic telescopic rod 45, so that the positioning groove 43 provides a limited sliding area for the positioning plate 46.

Referring to fig. 8, in the nacelle heat dissipation assembly for wind power generation of the present utility model, the positioning plate 46 is a circular plate, and the diameter of the positioning plate 46 is larger than that of the heat dissipation hole 44, so that the positioning plate 46 is convenient for sealing the heat dissipation hole 44.

Embodiment two:

according to the cabin cooling assembly for wind power generation, the rear end of the outer side face of the air outlet 36 is rotatably connected with the inner side of the through hole in the middle of the rear end of the dehumidifying cylinder 31, so that the dehumidifying cylinder 31 provides a limiting rotation area for the air outlet 36, the fixing plate 42 is fixed with the rear end of the inner bottom end of the cabin 1 through bolts, and the cabin 1 provides an installation area for the fixing plate 42.

The utility model provides a cabin heat radiation component for wind power generation through improvement, which has the following working principle;

firstly, when the equipment is used, the equipment is firstly placed in a working area, and then the device is connected with an external power supply, so that the power supply required by the work of the equipment can be provided;

secondly, firstly, the hydraulic telescopic rod 45 is started, so that the hydraulic telescopic rod 45 drives the positioning plate 46 to slide backwards, the air blower 47 is started while the heat dissipation holes 44 are opened, the air blower 47 is used for discharging hot air in the cabin 1 through the heat dissipation holes 44, and the air can flow in the cabin 1, so that the heat dissipation effect is improved;

thirdly, after the hot air in the cabin 1 is exhausted, the outside air is led into the dehumidifying drum 31 through the first air inlet 32, so that the dehumidifying screen drum 33 dehumidifies moisture in the outside air, the dehumidified air is led into the dehumidifying screen drum 33 through the second air inlet 34, dust in the air is filtered through the dust removing filter screen 35, the filtered air is led into the cabin 1 through the air outlet 36, and the moisture is prevented from entering the cabin 1 to short-circuit electronic components in the cabin 1, so that the working efficiency of the cabin is improved.

According to the cabin cooling assembly for wind power generation, the dehumidifying assembly 3 is arranged at the right end of the cabin 1, so that the dehumidifying screen cylinder 33 dehumidifies moisture in the outside air, and the dehumidified air is filtered by the dust removing filter screen 35, so that the filtered air is led into the cabin 1 through the air outlet 36, and the moisture is prevented from entering the cabin 1 to cause short circuit of electronic elements in the cabin 1, and the working efficiency of the cabin cooling assembly is improved; through having set up the radiating assembly 4 in cabin 1 bottom, make hydraulic telescoping rod 45 open the louvre 44 indirectly simultaneously make air-blower 47 pass through louvre 44 with the inside steam of cabin 1 and discharge, make the gas can flow in cabin 1 to the radiating effect has been improved.

The basic principle and main characteristics of the utility model and the advantages of the utility model are shown and described above, standard parts used by the utility model can be purchased from market, special-shaped parts can be customized according to the description of the specification and the drawings, the specific connection modes of the parts adopt conventional means such as mature bolt rivets and welding in the prior art, the machinery, the parts and the equipment adopt conventional models in the prior art, and the circuit connection adopts conventional connection modes in the prior art, so that the description is omitted.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (8)

1. A cabin heat dissipation assembly for wind power generation comprises a cabin (1) and a power generation fan head (2) arranged in the middle of the front end of the cabin (1);

characterized by further comprising:

the dehumidifying component (3) is welded and fixed in the middle of the right end of the engine room (1);

wherein, the dehumidifying component (3) can dehumidify outside moist air in operation;

the heat dissipation assembly (4) is arranged at the rear part of the bottom end in the engine room (1);

the heat dissipation assembly (4) can be used for dissipating heat in the cabin (1) during operation;

the dehumidification assembly (3) comprises:

the dehumidifying cylinder (31) is welded and fixed at the middle part of the right end of the engine room (1) at the left end of the dehumidifying cylinder (31);

the bottom end of the first air inlet (32) is connected with a pipeline at the front part of the top end of the dehumidifying cylinder (31);

the front end of the dehumidifying screen cylinder (33) is rotationally connected with the inner front end of the dehumidifying cylinder (31);

the second air inlet (34) is formed in the bottom of the rear end of the outer side surface of the dehumidifying screen cylinder (33);

the front end and the rear end of the dust removing filter screen (35) are respectively inserted and fixed at the front end and the rear end in the dehumidifying screen cylinder (33);

the front end of the air outlet (36) is connected with the middle part of the rear end of the dust removing filter screen (35) through a pipeline;

a water outlet (37), wherein the top end of the water outlet (37) is connected with the bottom end of the dehumidification cylinder (31) through a pipeline;

wherein the dehumidifying screen drum (33) is made of montmorillonite.

2. A nacelle heat sink assembly for wind power generation according to claim 1, wherein: the heat dissipation assembly (4) includes:

a heat dissipation plate (41), wherein the heat dissipation plate (41) is arranged at the rear part of the inner bottom end of the cabin (1);

fixing plates (42), wherein the fixing plates (42) are welded and fixed at four corners of the left end and the right end of the radiating plate (41);

the placing groove (43) is formed in the middle of the top end of the radiating plate (41);

wherein the fixing plate (42) is an L-shaped plate.

3. A nacelle heat sink assembly for wind power generation according to claim 2, wherein: the heat dissipation assembly (4) further comprises:

a heat radiation hole (44), wherein the heat radiation hole (44) is arranged at the front part of the top end of the placing groove (43);

the hydraulic telescopic rod (45) is fixed in the middle of the rear end of the placing groove (43) through bolts;

wherein the heat dissipation holes (44) are circular.

4. A nacelle heat sink assembly for wind power generation according to claim 3, wherein: the heat dissipation assembly (4) further comprises:

the middle part of the rear end of the positioning plate (46) is fixedly connected with a hydraulic telescopic rod (45) in an inserting manner;

a blower (47), wherein the blower (47) is fixed on the front part of the top end of the heat dissipation plate (41) through bolts;

wherein the outer diameter of the blower (47) is larger than the width of the placing groove (43).

5. A nacelle heat sink assembly for wind power generation according to claim 1, wherein: the dehumidifying screen cylinder (33) consists of a dehumidifying screen and a cylinder, and the dehumidifying screen is spirally arranged on the outer side surface of the cylinder.

6. A nacelle heat sink assembly for wind power generation according to claim 1, wherein: the dust removing filter screen (35) is an active carbon filter screen, and the mesh of the dust removing filter screen (35) is 200 meshes.

7. A nacelle heat sink assembly for wind power generation according to claim 2, wherein: the positioning plate (46) is connected in a sliding manner in the placing groove (43), and the positioning plate (46) is movably connected with the side wall of the placing groove (43) through the hydraulic telescopic rod (45).

8. A nacelle heat sink assembly for wind power generation according to claim 4, wherein: the positioning plate (46) is a circular plate, and the diameter of the positioning plate (46) is larger than that of the radiating hole (44).

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