CN113153664A

CN113153664A - Horizontal floating wind-powered electricity generation blade cabin cover

Info

Publication number: CN113153664A
Application number: CN202110438974.8A
Authority: CN
Inventors: 刘伟
Original assignee: Jiangsu Maijing Environmental Protection Technology Co ltd
Current assignee: Jiangsu Maijing Environmental Protection Technology Co ltd
Priority date: 2021-04-23
Filing date: 2021-04-23
Publication date: 2021-07-23

Abstract

The invention discloses a transverse floating type wind power blade cabin cover which comprises an outer shell, a transverse floating mechanism and an induced draft mechanism, wherein the outer shell is provided with a plurality of wind guide grooves; the air inlet is carried out through the plurality of air inlet channels on the other side of the accommodating cavity, cooling air enters the transverse moving pipe and the transverse floating hose from the air induction pipe after passing through the heating part in the accommodating cavity and then is discharged from the air induction groove, and therefore rapid heat conduction is achieved; according to the invention, the movable threaded barrel is driven to transversely move by rotating the driving screw rod, so that the outer side of the transverse moving pipe is driven to be slidingly clamped on the inner outer side wall of the transverse adjusting groove, and the plurality of air guiding pipes are driven to transversely move, so that the transverse positions of the plurality of air guiding pipes are adjusted, heat dissipation can be carried out according to the requirements of different positions, and the use is flexible and convenient.

Description

Horizontal floating wind-powered electricity generation blade cabin cover

Technical Field

The invention relates to a transverse floating wind power blade cabin cover.

Background

The wind power generation means that kinetic energy of wind is converted into mechanical kinetic energy, and then the mechanical energy is converted into electric kinetic energy, namely wind power generation. The specific principle of wind power generation is that wind power drives windmill blades to rotate, and then the rotating speed is increased through a speed increaser to promote a generator to generate electricity. In wind power generation, a nacelle cover, that is, a wind power generator housing, is used for mounting and protecting a wind power generator and accessories thereof, but the conventional nacelle cover has poor heat dissipation performance, cannot reasonably adjust a heat dissipation position according to an actual heating area, and is not high in use flexibility.

Disclosure of Invention

Aiming at the defects of the prior art, the invention solves the problems that: the transverse floating type wind power blade engine room cover is good in heat dissipation performance and adjustable in heat dissipation position.

In order to solve the problems, the technical scheme adopted by the invention is as follows:

a transverse floating wind power blade cabin cover comprises an outer shell, a transverse floating mechanism and an induced draft mechanism; an accommodating cavity is formed in the middle inside the outer shell; one side of the accommodating cavity is provided with an air guide groove; the upper end and the lower end of the accommodating cavity and the air inducing groove are respectively provided with a transverse adjusting groove; a cross-connecting channel is arranged between the upper end and the lower end of the accommodating cavity and the transverse adjusting groove; an air inducing mechanism is arranged in the air inducing groove; the transverse floating mechanism comprises a transverse floating hose, a transverse moving pipe, an induced draft pipe, a moving threaded cylinder and a driving screw rod; a transverse floating mechanism is respectively arranged in the transverse adjusting grooves; the transverse moving pipe is arranged in the transverse adjusting groove; one end of the transverse moving pipe is provided with a transverse floating hose; the transverse floating hose is communicated with the air inducing groove; the other end of the transverse moving pipe is provided with a moving threaded cylinder; the outer end of the movable threaded cylinder is in threaded connection with a driving screw; the outer end of the driving screw is rotationally clamped outside one end of the transverse adjusting groove; a plurality of induced draft pipes are uniformly arranged on the inner sides of the transverse moving pipes respectively; the inner end of the induced duct passes through the cross-connecting channel and then extends into the accommodating cavity; the outer side of the transverse moving pipe is slidably clamped on the inner outer side wall of the transverse adjusting groove; a plurality of air inlet channels are arranged on the other side of the accommodating cavity; and a filter screen plate is arranged on the inner side of the air inlet channel.

Further, the air inducing mechanism comprises a driving motor, a rotating shaft and air inducing blades; the driving motor is arranged in the middle of the outer side of the interior of the air guide groove; a rotating shaft is arranged at the inner end of the driving motor; a plurality of induced draft blades are uniformly arranged at the end part of the rotating shaft; and a plurality of air exhaust channels are respectively arranged at the upper part and the lower part of the outer side of the air guide groove.

Furthermore, a rotary clamping groove is communicated with the outside of one end of the transverse adjusting groove; the outer end of the rotary clamping groove is provided with a notch; the outer end of the driving screw is provided with a rotary clamping block; the driving screw is rotationally clamped on the rotary clamping groove at one end of the transverse adjusting groove through a rotary clamping block at the outer end; the outer end of the rotary clamping block is provided with a driving port; the driving port is located in the slot.

Further, the outer side of the transverse moving pipe is provided with a sliding clamping tooth; a sliding clamping groove is formed in the inner outer side wall of the transverse adjusting groove; the transverse moving pipe is connected to the sliding clamping groove on the outer side wall in the transverse adjusting groove in a sliding clamping mode through sliding clamping teeth on the outer side.

Furthermore, the upper end and the lower end of the air guide groove are respectively provided with a conduction pipe; the conduction pipes extend into the other ends of the transverse adjusting grooves respectively; the outer end of the transverse floating hose is communicated with the side part of the conduction pipe.

Further, the transverse floating hose is made of a high temperature resistant corrugated pipe.

The invention has the advantages of

The air inlet is carried out through the plurality of air inlet channels on the other side of the accommodating cavity, cooling air enters the transverse moving pipe and the transverse floating hose from the air induction pipe after passing through the heating part in the accommodating cavity and then is discharged from the air induction groove, and therefore rapid heat conduction is achieved; according to the invention, the movable threaded barrel is driven to transversely move by rotating the driving screw rod, so that the outer side of the transverse moving pipe is driven to be slidingly clamped on the inner outer side wall of the transverse adjusting groove, and the plurality of air guiding pipes are driven to transversely move, so that the transverse positions of the plurality of air guiding pipes are adjusted, heat dissipation can be carried out according to the requirements of different positions, and the use is flexible and convenient.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is an enlarged schematic structural view of the lateral floating mechanism of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 and 2, a transverse floating wind power blade nacelle cover comprises an outer shell 1, a transverse floating mechanism 2 and an induced draft mechanism 3; an accommodating cavity 11 is arranged in the middle of the inner part of the outer shell 1; one side of the accommodating cavity 11 is provided with an air guide groove 12; the upper end and the lower end of the accommodating cavity 11 and the air inducing groove 12 are respectively provided with a transverse adjusting groove 13; a cross-connecting channel is arranged between the upper end and the lower end of the accommodating cavity 11 and the transverse adjusting groove 13; an induced draft mechanism 3 is arranged in the induced draft groove 12; the transverse floating mechanism 2 comprises a transverse floating hose 21, a transverse moving pipe 22, an induced draft pipe 25, a moving threaded cylinder 23 and a driving screw 24; a transverse floating mechanism 2 is respectively arranged in the transverse adjusting groove 13; the transverse moving pipe 22 is arranged in the transverse adjusting groove 13; one end of the transverse moving pipe 22 is provided with a transverse floating hose 21; the transverse floating hose 21 is communicated with the air inducing groove 12; the other end of the transverse moving pipe 22 is provided with a moving threaded cylinder 23; the outer end of the movable threaded cylinder 23 is in threaded connection with a driving screw 24; the outer end of the driving screw 24 is rotatably clamped outside one end of the transverse adjusting groove 13; a plurality of induced draft pipes 25 are respectively and uniformly arranged on the inner sides of the transverse moving pipes 22; the inner end of the induced air pipe 25 passes through the cross-connecting channel and then extends into the accommodating cavity 11; the outer side of the transverse moving pipe 22 is slidably clamped on the inner outer side wall of the transverse adjusting groove 13; a plurality of air inlet channels 111 are arranged on the other side of the accommodating cavity 11; the inner side of the air inlet channel 111 is provided with a filter screen plate 4.

As shown in fig. 1 and 2, it is further preferable that the air inducing mechanism 3 includes a driving motor 31, a rotating shaft 32, and an air inducing blade 33; the driving motor 31 is arranged in the middle of the inner outer side of the air guide groove 12; a rotating shaft 32 is arranged at the inner end of the driving motor 31; a plurality of induced draft blades 33 are uniformly arranged at the end part of the rotating shaft 32; a plurality of air exhaust channels 121 are respectively arranged at the upper and lower parts of the outer side of the air guide groove 12. Further, a rotary clamping groove 132 is communicated with the outside of one end of the transverse adjusting groove 13; the outer end of the rotary clamping groove 132 is provided with a groove 133; the outer end of the driving screw 24 is provided with a rotary clamping block 241; the driving screw 24 is rotatably clamped in the rotary clamping groove 132 at one end of the transverse adjusting groove 13 through a rotary clamping block 241 at the outer end; the outer end of the rotary clamping block 241 is provided with a driving port 242; the driving opening 242 is located in the slot 133, and the driving opening 242 can be adjusted by a straight or cross screwdriver passing through the slot 133. Further, the outer side of the transverse moving pipe 22 is provided with a sliding clamping tooth 221; a sliding clamping groove 131 is formed in the inner outer side wall of the transverse adjusting groove 13; the transverse moving pipe 22 is slidably engaged with the sliding engaging groove 131 on the inner outer sidewall of the transverse adjusting groove 13 through the outer sliding engaging tooth 221. Further, the upper and lower ends of the air guiding groove 12 are respectively provided with a conduction pipe 122; the conduction pipes 122 extend to the inside of the other ends of the transverse adjusting grooves 13; the outer end of the lateral floating hose 21 is connected to the side of the conduit 122. Further, the lateral floating hose 21 is made of a high temperature resistant bellows.

The invention enters air through a plurality of air inlet channels 111 at the other side of the accommodating cavity 11, and cooling air enters the transverse moving pipe 22 and the transverse floating hose 21 from the air guide pipe 25 after passing through a heating component in the accommodating cavity 11 and then is discharged from the air guide groove 12, so that quick heat conduction is realized; according to the invention, the driving screw 24 is rotated to drive the movable threaded cylinder 23 to move transversely, so that the outer side of the transverse moving pipe 22 is driven to be clamped on the inner outer side wall of the transverse adjusting groove 13 in a sliding manner, and the plurality of air guiding pipes 25 are driven to move transversely, so that the transverse positions of the plurality of air guiding pipes 25 are adjusted, heat can be dissipated according to different position requirements, and the use is flexible and convenient.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions, improvements, etc. within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A transverse floating wind power blade cabin cover is characterized by comprising an outer shell, a transverse floating mechanism and an induced draft mechanism; an accommodating cavity is formed in the middle inside the outer shell; one side of the accommodating cavity is provided with an air guide groove; the upper end and the lower end of the accommodating cavity and the air inducing groove are respectively provided with a transverse adjusting groove; a cross-connecting channel is arranged between the upper end and the lower end of the accommodating cavity and the transverse adjusting groove; an air inducing mechanism is arranged in the air inducing groove; the transverse floating mechanism comprises a transverse floating hose, a transverse moving pipe, an induced draft pipe, a moving threaded cylinder and a driving screw rod; a transverse floating mechanism is respectively arranged in the transverse adjusting grooves; the transverse moving pipe is arranged in the transverse adjusting groove; one end of the transverse moving pipe is provided with a transverse floating hose; the transverse floating hose is communicated with the air inducing groove; the other end of the transverse moving pipe is provided with a moving threaded cylinder; the outer end of the movable threaded cylinder is in threaded connection with a driving screw; the outer end of the driving screw is rotationally clamped outside one end of the transverse adjusting groove; a plurality of induced draft pipes are uniformly arranged on the inner sides of the transverse moving pipes respectively; the inner end of the induced duct passes through the cross-connecting channel and then extends into the accommodating cavity; the outer side of the transverse moving pipe is slidably clamped on the inner outer side wall of the transverse adjusting groove; a plurality of air inlet channels are arranged on the other side of the accommodating cavity; and a filter screen plate is arranged on the inner side of the air inlet channel.

2. The transverse floating wind turbine blade nacelle cover of claim 1 wherein the inducer mechanism includes a drive motor, a rotating shaft, an inducer blade; the driving motor is arranged in the middle of the outer side of the interior of the air guide groove; a rotating shaft is arranged at the inner end of the driving motor; a plurality of induced draft blades are uniformly arranged at the end part of the rotating shaft; and a plurality of air exhaust channels are respectively arranged at the upper part and the lower part of the outer side of the air guide groove.

3. The transverse floating wind turbine blade nacelle cover of claim 1 wherein a rotary snap groove is provided in communication with the outside of one end of the transverse adjustment groove; the outer end of the rotary clamping groove is provided with a notch; the outer end of the driving screw is provided with a rotary clamping block; the driving screw is rotationally clamped on the rotary clamping groove at one end of the transverse adjusting groove through a rotary clamping block at the outer end; the outer end of the rotary clamping block is provided with a driving port; the driving port is located in the slot.

4. The transverse floating wind turbine blade nacelle cover of claim 1 wherein the outside of the transverse moving tube is provided with sliding snap teeth; a sliding clamping groove is formed in the inner outer side wall of the transverse adjusting groove; the transverse moving pipe is connected to the sliding clamping groove on the outer side wall in the transverse adjusting groove in a sliding clamping mode through sliding clamping teeth on the outer side.

5. The transverse floating wind turbine blade nacelle cover of claim 1 wherein the upper and lower ends of said wind guiding trough are provided with a conduit, respectively; the conduction pipes extend into the other ends of the transverse adjusting grooves respectively; the outer end of the transverse floating hose is communicated with the side part of the conduction pipe.

6. The transverse floating wind turbine blade nacelle cover of claim 1 wherein the transverse floating hose is made of high temperature resistant bellows.