CN213270167U - V-shaped wind power large-pore cleaning-free radiator - Google Patents

Abstract

The utility model discloses a V type wind-powered electricity generation macropore exempts from to wash radiator, including end plate, briquetting and roof, from top to bottom the outside of end plate links to each other with roof and briquetting are fixed respectively, the inboard of end plate is provided with radiator unit, radiator unit includes fin, water inlet, outlet and stand, and is a plurality of the upper and lower both sides of fin all link to each other with the roof is fixed, the upper and lower both sides of stand all link to each other with the end plate is fixed. This V type wind-powered electricity generation macropore exempts from to wash radiator, structure scientific and reasonable, convenience safe in utilization, be provided with double-shaft motor, the end plate, the montant, the screw rod, the second diaphragm, the spout, the second round bar with scrape the piece, treat to remove to extreme position back, can drive the reversal of double-shaft motor and realize resetting, but make in the radiator use periodic start double-shaft motor carry out the deashing and handle, the problem of need artifical piling up the dust that influences the heat transfer to the fin to handle to clear up after the radiator uses a period has been avoided.

Description

V-shaped wind power large-pore cleaning-free radiator

Technical Field

The utility model relates to a radiator technical field specifically is a V type wind-powered electricity generation macropore exempts from to wash radiator.

Background

The gradual increase of aerogenerator's unit capacity can directly lead to each major component heat dissipation capacity greatly increased such as generator, gear box, converter, in order to avoid aerogenerator's inner structure overheated, utilize the wind-powered electricity generation radiator to carry out the heat dissipation processing usually, although prior art's wind-powered electricity generation radiator can realize the heat dissipation, the in-process that uses still exists and needs the manual work to influence the problem that the dust of piling up of heat transfer is cleared up to fin department after the radiator uses a period, still there is the wind-powered electricity generation radiator and installing or dismantle the bolt that the in-process need tighten a plurality of positions and lead to the problem that the process is complicated.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a V type wind-powered electricity generation macropore exempts from to wash radiator to solve the problem that the piling up dust that provides in the above-mentioned background art needs the manual work to influence the heat transfer to fin department after the radiator uses a period and clears up.

In order to achieve the above object, the utility model provides a following technical scheme: a V-shaped wind power large-pore cleaning-free radiator comprises end plates, pressing blocks and a top plate, wherein the outer sides of the upper end plate and the lower end plate are fixedly connected with the top plate and the pressing blocks respectively, and the inner sides of the end plates are provided with heat dissipation assemblies;

the heat dissipation assembly comprises heat dissipation fins, a water inlet, a water outlet and an upright post;

it is a plurality of the upper and lower both sides of fin all link to each other with the roof is fixed, the water inlet is installed in the right side top of end plate, the water inlet is linked together through end plate and fin, the left end at the end plate is installed to the outlet, the outlet is linked together through end plate and fin, and is a plurality of the stand is located the inboard four corners of end plate respectively, the upper and lower both sides of stand all link to each other with the end plate is fixed.

Preferably, the included angle between adjacent radiating fins is 15 °.

Preferably, the top plate is provided with a dust cleaning component;

the ash removal component comprises a screw rod, a scraping block, a second round rod, a first bevel gear, a rotating shaft, a double-shaft motor, a second bevel gear, a first bearing, a sliding groove, a second transverse plate, a vertical rod and a second bearing;

the double-shaft motor is fixedly connected to the center of the inner wall of the top plate, the left output shaft and the right output shaft of the double-shaft motor are fixedly connected with a rotating shaft, the outer side of the outer wall of the rotating shaft is rotatably connected with the top plate through a first bearing, the left side and the right side of the outer wall of the rotating shaft are fixedly connected with a first bevel gear, the left side below the first bevel gear is meshed with a second bevel gear, the lower end of the second bevel gear is fixedly connected with a screw, the upper side and the lower side of the outer wall of the screw are rotatably connected with an end plate through a second bearing, the center thread of the outer wall of the screw is connected with a second transverse plate, a plurality of sliding grooves are machined in the inner wall of the second transverse plate, a second round rod is slidably clamped in the sliding grooves, scraping blocks are fixedly connected to the rear ends of the second round rod, the scraping blocks are sleeved on the outer wall of the, the upper side and the lower side of the vertical rod are fixedly connected with the end plate.

Preferably, the scraping blocks are axially symmetrically distributed by taking the vertical center of the screw rod or the vertical rod as a reference.

Preferably, the outer wall of the pressing block is provided with a mounting assembly;

the mounting assembly comprises a first spring, a clamping block, a cushion block, a buckling plate, a first round rod, a first transverse plate, a sleeve plate, a pin shaft and a second spring;

the improved structure of the clamp comprises a clamp body, and is characterized in that a sleeve plate is located on the outer side of the outer wall of a press block, the left side and the right side of the sleeve plate are connected with the clamp block in a rotating mode through a pin shaft, the clamp block and the press block are connected in a clamped mode, a second spring is arranged on the outer side of the pin shaft, the two sides of the second spring are fixedly connected with the sleeve plate and the clamp block respectively, a first round rod is fixedly connected to the front end of the clamp block, a first transverse plate is connected to the outer wall of the first round rod in a sliding mode, the outer side of the first transverse plate is fixedly connected with the clamp plate, a cushion block is matched with the inner portion of the lower portion of the clamp plate in a clearance mode.

Preferably, a base is arranged below the pressing block, and the base is fixedly connected with the sleeve plate and the cushion block.

Compared with the prior art, the beneficial effects of the utility model are that: this V type wind-powered electricity generation macropore exempts from to wash radiator, structure scientific and reasonable, convenience safe in utilization:

be provided with the biax motor, the end plate, the montant, the screw rod, the second diaphragm, the spout, the second pole with scrape the piece, after using a period, can drive the biax motor and start, drive screw rotates, make the second diaphragm lead to the drive to scrape the piece at fin outer wall downstream, the realization is scraped the piece and can be scraped the accumulational dust of fin outer wall, treat to remove to extreme position after, can drive the biax motor reversal and realize resetting, make and regularly start the biax motor in the radiator use and carry out the deashing and handle, the problem that needs the manual work to influence the accumulational dust of heat transfer to the fin after having avoided using a period to carry out the clearance.

Be provided with the base, the briquetting, the second spring, the fixture block, the buckle, first diaphragm and first round bar, can carry out the radiator that installs in the top downstream of base, make the briquetting downstream, final fixture block can receive the elasticity of second spring to inwards pop out, carry out fixed mounting between completion radiator and the base, when needing to dismantle, the user can step on the buckle downwards and press, make the buckle downstream, make the first diaphragm of buckle accessible and first round bar drive fixture block outwards rotate and relieve the joint, avoided current wind-powered electricity generation radiator installing or dismantling the problem that the bolt that the in-process need tighten a plurality of positions leads to the process complicacy.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the structure of FIG. 1 at the end plate, fins and screws;

FIG. 3 is a schematic view of the end plate, the threaded rod and the first bevel gear of FIG. 1;

fig. 4 is a schematic structural view of the end plate, the second cross plate and the vertical rod in fig. 1.

In the figure: 1. the heat dissipation device comprises an end plate, 2, a heat dissipation assembly, 201, a heat dissipation fin, 202, a water inlet, 203, a water outlet, 204, a stand column, 3, an installation assembly, 301, a first spring, 302, a clamping block, 303, a cushion block, 304, a clamping plate, 305, a first round rod, 306, a first transverse plate, 307, a sleeve plate, 308, a pin shaft, 309, a second spring, 4, an ash removal assembly, 401, a screw rod, 402, a scraping block, 403, a second round rod, 404, a first bevel gear, 405, a rotating shaft, 406, a double-shaft motor, 407, a second bevel gear, 408, a first bearing, 409, a sliding groove, 410, a second transverse plate, 411, a vertical rod, 412, a second bearing, 5, a base, 6, a pressing block, 7 and a top.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a V-shaped wind power large-aperture cleaning-free radiator comprises an end plate 1, a pressing block 6 and a top plate 7, wherein the outer sides of an upper end plate 1 and a lower end plate 1 are fixedly connected with the top plate 7 and the pressing block 6 respectively, the inner side of the end plate 1 is provided with a radiating component 2, the radiating component 2 comprises radiating fins 201, a water inlet 202, a water outlet 203 and upright posts 204, the upper sides and the lower sides of a plurality of radiating fins 201 are fixedly connected with the top plate 7, the radiating fins 201 are used for cooling liquid to flow for radiating, the water inlet 202 is arranged above the right side of the end plate 1, the water inlet 202 is communicated with the radiating fins 201 through the end plate 1, the water outlet 203 is arranged at the left end of the end plate 1, the water flow at the radiating fins 201 is realized through the water inlet 202 and the water outlet 203, the water outlet 203 is, the angle between adjacent fins 201 is 15 °.

The ash cleaning component 4 is arranged at the top plate 7, the ash cleaning component 4 comprises a screw 401, a scraping block 402, a second round bar 403, a first bevel gear 404, a rotating shaft 405, a double-shaft motor 406, a second bevel gear 407, a first bearing 408, a sliding chute 409, a second transverse plate 410, a vertical bar 411 and a second bearing 412, the double-shaft motor 406 is fixedly connected at the center of the inner wall of the top plate 7, the model of the double-shaft motor 406 is an HDA2525 type servo double-shaft motor, the rotating shaft 405 is fixedly connected with the left and right output shafts of the double-shaft motor 406, the outer wall outer side of the rotating shaft 405 is rotatably connected with the top plate 7 through the first bearing 408, the double-shaft motor 406 can drive the second bevel gear 407 to rotate through the rotating shaft 405 and the first bevel gear 404, the first bevel gear 404 is fixedly connected with the left and right side of the outer wall of the rotating shaft 405, the second bevel gear 407 is engaged with the second bevel, the upper side and the lower side of the outer wall of the screw 401 are rotatably connected with the end plate 1 through a second bearing 412, the center thread of the outer wall of the screw 401 is connected with a second transverse plate 410, a plurality of sliding grooves 409 are machined in the inner wall of the second transverse plate 410, a second round rod 403 is slidably clamped in the sliding grooves 409, the vertical movement of the second transverse plate 410 can be driven by the matching of the sliding grooves 409 and the second round rod 403 to scrape the block 402 to move on the outer wall of the radiating fin 201, the rear end of the second round rod 403 is fixedly connected with a scraping block 402, the scraping block 402 can scrape dust on the outer wall of the radiating fin 201, the scraping block 402 is sleeved on the outer wall of the radiating fin 201 and is in clearance fit with the radiating fin 201, a plurality of vertical rods 411 are in clearance fit on the inner side of the second transverse plate 410, the upper side and the lower side of each vertical rod 411 are fixedly connected with the end plate 1, and the scraping blocks 402.

The outer wall of the pressing block 6 is provided with a mounting assembly 3, the mounting assembly 3 comprises a first spring 301, a clamping block 302, a cushion block 303, a buckling plate 304, a first round rod 305, a first transverse plate 306, a sleeve plate 307, a pin shaft 308 and a second spring 309, the sleeve plate 307 is positioned on the outer side of the outer wall of the pressing block 6, the inner parts of the left side and the right side of the sleeve plate 307 are rotatably connected with the clamping block 302 through the pin shaft 308, the clamping block 302 can rotate inside the sleeve plate 307, the clamping block 302 and the pressing block 6 are clamped with each other, the outer side of the pin shaft 308 is provided with the second spring 309, the second spring 309 is a volute spring with the elastic coefficient K of 500N/m, the two sides of the second spring 309 are respectively fixedly connected with the sleeve plate 307 and the clamping block 302, the clamping block 302 can compress the second spring clamping block 309 when rotating outwards, the front end of the first round rod 305 is fixedly connected with the first round rod 305, the outer wall of the first round rod 305, the first transverse plate 306 moves downwards to drive the clamping block 302 to rotate outwards through the first round rod 305, a cushion block 303 is arranged in the lower portion of the buckling plate 304 in a clearance fit mode, the buckling plate 304 can move above the outer wall of the cushion block 303, a first spring 301 is arranged inside the upper portion of the cushion block 303, the elastic coefficient K of the first spring 301 is 300N/m, the upper side and the lower side of the first spring 301 are fixedly connected with the buckling plate 304 and the cushion block 303 respectively, the buckling plate 304 moves downwards to extrude the first spring 301, a base 5 is arranged below the pressing block 6, and the base 5 is fixedly connected with the sleeve plate 307 and the cushion block 303.

When the V-shaped wind power large-aperture cleaning-free radiator is required to be used, firstly, a user can fix the base 5 in the upper inner space of the wind driven generator, then the radiator to be installed can move downwards above the base 5, so that the pressing block 6 moves downwards, the pressing block 6 can drive the clamping block 302 to move outwards firstly, and finally, the clamping block 302 can be popped inwards by the elastic force of the second spring 309, the clamping connection between the clamping block 302 and the pressing block 6 is realized, the fixed installation between the radiator and the base 5 is completed, when the radiator is required to be disassembled, the user can press the buckling plate 304 downwards, so that the buckling plate 304 moves downwards, the buckling plate 304 can drive the clamping block 302 to rotate outwards through the first transverse plate 306 and the first round rod 305 to release the clamping connection, and the problem that the process is complicated due to the fact that bolts at multiple positions need to be screwed in the installation or disassembly process of the existing wind power radiator is, when the wind driven generator is used, the water inlet pipe 202 and the water outlet pipe 203 can be communicated with a pipeline flowing outside, so that cooling liquid can flow inside the radiating fins 201 through the water inlet pipe 202 and the water outlet pipe 203, heat dissipation and temperature reduction treatment on the upper inner space of the wind driven generator can be realized, after the wind driven generator is used for a period of time, the double-shaft motor 406 can be driven to start to rotate forwards and backwards, the double-shaft motor 406 can drive the screw 401 to rotate through the first bevel gear 404 and the second bevel gear 407, the second transverse plate 410 moves downwards, the scraping block 402 is driven to move downwards on the outer wall of the radiating fins 201 through the sliding groove 409 and the second round rod 403, the scraping block 402 can scrape accumulated dust on the outer wall of the radiating fins 201, after the scraping block 402 moves downwards to the extreme position, the double-shaft motor 406 can be driven to rotate backwards, and upward movement and resetting of the scraping block 402 and the, the double-shaft motor 406 can be started regularly to perform ash cleaning treatment in the use process of the radiator, and the problem that accumulated dust affecting heat transfer at the radiating fins needs to be cleaned manually after the radiator is used for a period of time is solved.

In the description of the present invention, it is to be understood that the terms "coaxial", "bottom", "one end", "top", "middle", "other end", "upper", "one side", "top", "inner", "front", "center", "both ends", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "disposed," "connected," "fixed," "screwed" and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate medium, and may be connected through the inside of two elements or in an interaction relationship between two elements, unless otherwise specifically defined, and the specific meaning of the above terms in the present invention will be understood by those skilled in the art according to specific situations.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a V type wind-powered electricity generation macropore exempts from to wash radiator, includes end plate (1), briquetting (6) and roof (7), from top to bottom the outside of end plate (1) is fixed continuous its characterized in that with roof (7) and briquetting (6) respectively: a heat dissipation assembly (2) is arranged on the inner side of the end plate (1);

the heat dissipation assembly (2) comprises heat dissipation fins (201), a water inlet (202), a water outlet (203) and a stand column (204);

it is a plurality of the upper and lower both sides of fin (201) all link to each other with roof (7) is fixed, the right side top at end plate (1) is installed in water inlet (202), water inlet (202) are linked together through end plate (1) and fin (201), the left end at end plate (1) is installed in outlet (203), outlet (203) are linked together through end plate (1) and fin (201), and are a plurality of stand (204) are located the inboard four corners of end plate (1) respectively, the upper and lower both sides of stand (204) all link to each other with end plate (1) is fixed.

2. The V-shaped wind power large-aperture no-clean radiator according to claim 1, characterized in that: the included angle between the adjacent radiating fins (201) is 15 degrees.

3. The V-shaped wind power large-aperture no-clean radiator according to claim 1, characterized in that: the top plate (7) is provided with an ash removal component (4);

the ash removing component (4) comprises a screw rod (401), a scraping block (402), a second round rod (403), a first bevel gear (404), a rotating shaft (405), a double-shaft motor (406), a second bevel gear (407), a first bearing (408), a sliding groove (409), a second transverse plate (410), a vertical rod (411) and a second bearing (412);

the double-shaft motor (406) is fixedly connected to the center of the inner wall of the top plate (7), the left output shaft and the right output shaft of the double-shaft motor (406) are fixedly connected with a rotating shaft (405), the outer side of the outer wall of the rotating shaft (405) is rotatably connected with the top plate (7) through a first bearing (408), the left side and the right side of the outer wall of the rotating shaft (405) are fixedly connected with a first bevel gear (404), the left side below the first bevel gear (404) is meshed and connected with a second bevel gear (407), the lower end of the second bevel gear (407) is fixedly connected with a screw rod (401), the upper side and the lower side of the outer wall of the screw rod (401) are rotatably connected with the end plate (1) through a second bearing (412), the center thread of the outer wall of the screw rod (401) is connected with a second transverse plate (410), a plurality of sliding grooves (409) are machined in the inner wall of the second transverse plate, the equal rigid coupling in rear end of second pole (403) has scrapes piece (402), scrape piece (402) and cup joint at fin (201) outer wall, and scrape piece (402) and fin (201) clearance fit, the inboard clearance fit of second diaphragm (410) has a plurality of montants (411), the upper and lower both sides of montant (411) all link to each other with end plate (1) is fixed.

4. The V-shaped wind power large-aperture no-clean radiator according to claim 3, characterized in that: the scraping blocks (402) are respectively distributed in an axisymmetric manner by taking the vertical center of the screw rod (401) or the vertical rod (411) as a reference.

5. The V-shaped wind power large-aperture no-clean radiator according to claim 1, characterized in that: the outer wall of the pressing block (6) is provided with a mounting component (3);

the mounting assembly (3) comprises a first spring (301), a clamping block (302), a cushion block (303), a pinch plate (304), a first round rod (305), a first transverse plate (306), a sleeve plate (307), a pin shaft (308) and a second spring (309);

the sleeve plate (307) is positioned on the outer side of the outer wall of the pressing block (6), the insides of the left side and the right side of the sleeve plate (307) are rotatably connected with the clamping block (302) through pin shafts (308), the clamping block (302) and the pressing block (6) are clamped with each other, a second spring (309) is arranged on the outer side of the pin shaft (308), two sides of the second spring (309) are respectively fixedly connected with the sleeve plate (307) and the clamping block (302), the front ends of the clamping blocks (302) are fixedly connected with first round rods (305), the outer walls of the first round rods (305) are slidably clamped with first transverse plates (306), the outer sides of the first transverse plates (306) are fixedly connected with the pinch plate (304), a cushion block (303) is in clearance fit with the inner part below the pinch plate (304), a first spring (301) is arranged inside the upper portion of the cushion block (303), and the upper side and the lower side of the first spring (301) are fixedly connected with the pinch plate (304) and the cushion block (303) respectively.

6. The V-shaped wind power large-aperture no-clean radiator according to claim 1, characterized in that: a base (5) is arranged below the pressing block (6), and the base (5) is fixedly connected with the sleeve plate (307) and the cushion block (303).

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