CN217823881U - Cooling and heat dissipation system of offshore wind power booster station - Google Patents

Abstract

The utility model relates to a wind-powered electricity generation booster station technical field specifically discloses a offshore wind power booster station cooling system, including wind-powered electricity generation booster station, bearing board and support frame, the bottom of wind-powered electricity generation booster station is closely laminated with the bearing board, and the front of wind-powered electricity generation booster station all has seted up four through-holes that are square setting in the outside position department near the bottom all around, and this through-hole department installs the intercommunication frame, the inboard fixedly connected with of intercommunication frame is the heat-conducting plate that is the annular setting; the bottom of the bearing plate is provided with four support columns; the utility model discloses a heat-conducting plate that sets up can cooperate the contact plate that sets up can carry out the adaptation with the circulating pump that sets up when using and cooperate being connected of hollow core plate can carry out the sea water suction thereby to form water-cooling, forced air cooling joint application and mutual noninterference's measure, has strengthened the stability that whole wind-powered electricity generation booster station cooling system used.

Description

Cooling and heat dissipation system of offshore wind power booster station

Technical Field

The utility model relates to a wind-powered electricity generation booster station technical field specifically is a marine wind-powered electricity generation booster station cooling system.

Background

The wind power station booster station is a facility for boosting the output voltage of a wind turbine generator to a higher-level voltage and sending the higher-level voltage out, is widely applied to wind power generation in many countries as a clean renewable energy source, and develops the wind power technology from the past small wind power generators which automatically use and independently operate into a large wind power plant with multiple machines connected in parallel and operated in a grid-connected mode, wind power resources are rich in some special zones such as the sea surface, and the air flow is accelerated due to changeable climate, so that the majority of wind power station booster stations are lifted and installed on the sea surface through ship transportation to operate.

In the process of normal operation of the wind power station booster station, the internal voltage is increased and the load of transportation is large, so that the heat dissipation capacity of the whole wind power station booster station is greatly challenged, the existing heat dissipation measures are all that wind power resources blow the wind power station booster station when the wind power station booster station is normally used to form a heat dissipation effect, but the heat dissipation effect is found to be unbalanced in wind power when the heat dissipation effect is used, so that the heat dissipation effect cannot be stably guaranteed, and then the cooling and heat dissipation system of the offshore wind power station booster station is provided.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model provides a cooling and heat dissipation system of a marine wind power booster station, which has the advantages that the cooling and heat dissipation system of the wind power booster station can run more stably and can be matched with wind resources more stably to form more effective heat dissipation measures, the problem of current offshore wind power booster station cooling system measure singleness, the radiating effect that forms is uneven unstable is solved.

The utility model discloses a cooling and heat dissipation system of offshore wind power booster station, including wind power booster station, bearing board and support frame, the bottom and the bearing board of wind power booster station are closely laminated, and the front of wind power booster station all sets up four through-holes that are square setting near the position department of bottom in the outside all around, and this through-hole department installs the intercommunication frame, the inboard fixedly connected with of intercommunication frame is the heat-conducting plate that the ring-type set up; the bottom of the bearing plate is provided with four support columns, a first reinforcing rib and a second reinforcing rib are arranged between every two support columns, and the first reinforcing rib and the second reinforcing rib are arranged in a crossed and symmetrical mode; the outside of support frame is connected with the outside of support column, and the mid-mounting of support frame has the contact plate, the positive outside of contact plate is passed through the auxiliary rod and is fixed continuous with the inboard of support frame.

Through the design of the technical scheme, the wind power booster station, the bearing plate and the support frame are combined and adapted, so that the whole device can stand on the sea more stably when in use, and the bearing plate is matched to be used to enable the whole device to be more stably fixed, thereby meeting the requirement of normal use of the device.

As a further improvement, the top of contact plate links to each other with the bottom of wind-powered electricity generation booster station is fixed, the contact plate is hollow structure, and the bottom of this contact plate sets up two through-holes that can supply the connecting pipe to be connected, two the bottom of connecting pipe is connected with hollow plate.

Through the design of the technical scheme, the through hole that utilizes to set up can let the connecting pipe better carry out the adaptation with hollow core plate to let the contact plate more convenient adsorb the sea water, satisfy the needs that the water-cooling used and strengthened the radiating effect of whole wind-powered electricity generation booster station.

As a further improvement, the bottom fixedly connected with of hollow slab is the protection network that the arc set up, the top mid-mounting of hollow slab has a circulating pump, the both sides and the connecting pipe of circulating pump are linked together.

Through the design of the technical scheme, the protective net and the circulating pump which are arranged by matching the hollow slab can reduce the phenomenon that garbage is attached to the position of the hollow slab to be adsorbed when the circulating pump is used, so that the circulating pump can adsorb seawater on the contact plate better.

As a further improvement, the back up coat is installed to the inboard of wind-powered electricity generation booster station, the inboard fixedly connected with of back up coat is a spacing section of thick bamboo of circular setting, install four water conservancy diversion frames, four in the spacing section of thick bamboo install the base between the water conservancy diversion frame, the top fixedly connected with driving motor of base, the flabellum is installed in driving motor's the output shaft outside.

Through the design of the technical scheme, the wind power booster station which is arranged by the aid of the matching of the arranged reinforcing layer is matched with the guide frame and the driving motor when the wind power booster station is used for connection, the fan blades can better rotate along with the wind power flowing on the sea surface, and therefore more stable heat dissipation measures are formed.

As a further improvement, the wind-powered electricity generation booster station inboard is seted up and is supplied the recess that communicating pipe is connected, a free end of communicating pipe is connected with the intercommunication frame, another free end of communicating pipe runs through with the outside of back up coat and links to each other.

Through the design of the technical scheme, the groove arranged is matched with the communicating frame arranged, so that the whole communicating pipe can be connected and fixed more stably.

As a further improvement, the locating hole has been seted up at the top middle part of support column, a bolt is installed to the inboard of locating hole, and the top of this bolt links to each other with the bottom of wind-powered electricity generation booster station is fixed.

Through the design of the technical scheme, the positioning hole which is arranged is matched with the supporting column, so that the bolt can be more stable and the wind power booster station can be adapted to enable the wind power booster station to be more stable to be fixed.

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

the utility model discloses a heat-conducting plate that sets up can cooperate the contact plate that sets up to carry out the adaptation when using with the circulating pump that sets up and cooperate hollow plate be connected and can suction the sea water thereby form the water-cooling, forced air cooling joint application and mutual noninterference's measure, the stability that whole wind-powered electricity generation booster station cooling system used has been strengthened, and cooperate the flabellum that sets up, can carry out the adaptation with the communicating pipe that sets up when using, the heat-conducting plate of setting is being cooperated, let the inside heat of wind-powered electricity generation booster station can more even quick derivation when the cooperation is used, make the radiating measure of whole wind-powered electricity generation booster station cooling can be more perfect, whole wind-powered electricity generation booster station advantage of steadily using has been guaranteed.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

FIG. 1 is a schematic view of the combined structure of the wind power booster station and the support pillar of the present invention;

FIG. 2 is a schematic view of the assembly structure of the support frame and the support post of the present invention;

fig. 3 is the utility model discloses wind-powered electricity generation booster station and communicating pipe integrated configuration schematic diagram.

In the figure: 01. a wind power booster station; 02. a heat conducting plate; 03. a contact plate; 04. a first reinforcing rib; 05. a connecting pipe; 06. a hollow slab; 07. a circulation pump; 08. a protective net; 09. a support pillar; 10. a second reinforcing rib; 11. a bearing plate; 12. a communication frame; 13. a support frame; 14. an auxiliary lever; 15. positioning holes; 16. a reinforcement layer; 17. a communicating pipe; 18. a drive motor; 19. a flow guide frame; 20. a base; 21. a limiting cylinder; 22. and fan blades.

Detailed Description

In the following description, for purposes of explanation, numerous implementation details are set forth in order to provide a thorough understanding of various embodiments of the present invention. It should be understood, however, that these implementation details should not be used to limit the invention. That is, in some embodiments of the invention, details of these implementations are not necessary. In addition, some conventional structures and components are shown in simplified schematic form in the drawings for the sake of simplicity.

In addition, the descriptions of the present invention as related to "first", "second", etc. are used for descriptive purposes only, not for specifically designating an order or sequence, but also for limiting the present invention, which is used only for distinguishing components or operations described in the same technical terms, and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

Referring to fig. 1, 2 and 3, the cooling and heat dissipating system of the offshore wind power booster station of the present invention comprises a wind power booster station 01, a supporting plate 11 and a supporting frame 13, wherein the bottom of the wind power booster station 01 is tightly attached to the supporting plate 11, four through holes are disposed at positions near the bottom outside the front periphery of the wind power booster station 01, a communicating frame 12 is installed at the through holes, and a heat conducting plate 02 disposed in an annular shape is fixedly connected to the inner side of the communicating frame 12; the bottom of the bearing plate 11 is provided with four support columns 09, a first reinforcing rib 04 and a second reinforcing rib 10 are arranged between every two support columns 09, and the first reinforcing rib 04 and the second reinforcing rib 10 are arranged in a crossed and symmetrical mode; the outside of support frame 13 is connected with the outside of support column 09, and the mid-mounting of support frame 13 has contact plate 03, the front outside of contact plate 03 is fixed continuous through the inboard of auxiliary rod 14 with support frame 13, through the design of above-mentioned technical scheme, utilize wind-powered electricity generation booster station 01, the joint adaptation of bearing board 11 and support frame 13, make whole device can be more stable when using stand on the sea, thereby the use of cooperating bearing board 11 can let whole device more stable fix the needs that have satisfied device normal use.

Please refer to fig. 1, the top of the contact plate 03 is fixedly connected with the bottom of the wind power booster station 01, the contact plate 03 is of a hollow structure, and two through holes for connecting the connecting pipes 05 are formed in the bottom of the contact plate 03, the bottom of the two connecting pipes 05 is connected with the hollow plate 06, by the above technical scheme design, the connecting pipes 05 can be better matched with the hollow plate 06 by the arranged through holes, thereby the contact plate 03 can absorb seawater more conveniently, the heat dissipation effect of the whole wind power booster station 01 is enhanced by meeting the requirement of water cooling, the bottom of the hollow plate 06 is fixedly connected with the protective net 08 which is arranged in an arc shape, a circulating pump 07 is installed in the middle of the top of the hollow plate 06, the two sides of the circulating pump 07 are communicated with the connecting pipes 05, by the above technical scheme design, the protective net 08 which is arranged by matching the arranged hollow plate 06 and the circulating pump 07 can reduce the adhesion of garbage to the position of the hollow plate 06 when in use, so as to enable the circulating pump 07 to better absorb seawater to the contact plate 03.

Please refer to fig. 2, a reinforcing layer 16 is installed on the inner side of the wind power booster station 01, a limiting cylinder 21 is circularly arranged on the inner side of the reinforcing layer 16, four flow guide frames 19 are installed in the limiting cylinder 21, a base 20 is installed between the four flow guide frames 19, a driving motor 18 is fixedly connected to the top of the base 20, and fan blades 22 are installed on the outer side of an output shaft of the driving motor 18, according to the above technical scheme design, the wind power booster station 01 is arranged by using the set reinforcing layer 16 in a matching manner, the flow guide frames 19 and the driving motor 18 are matched when being connected for use, the fan blades 22 can better rotate along with the flow of wind power on the sea surface, so as to form a more stable heat dissipation measure, a groove for connecting the communicating pipe 17 is formed on the inner side of the wind power booster station 01, one free end of the communicating pipe 17 is connected with the communicating frame 12, the other free end of the communicating pipe 17 is connected with the outer side of the reinforcing layer 16 in a penetrating manner, and the whole communicating pipe 17 can be more stably connected and fixed by using the arranged groove matched with the set communicating frame 12.

Referring to fig. 3, a positioning hole 15 is formed in the middle of the top of the supporting column 09, a bolt is installed on the inner side of the positioning hole 15, the top of the bolt is fixedly connected with the bottom of the wind power booster station 01, and by means of the technical scheme design, the positioning hole 15 is matched with the supporting column 09 to enable the bolt to be more stable and to be matched with the wind power booster station 01 to enable the wind power booster station 01 to be more stable to be fixed.

When using the utility model discloses a time:

when the wind power booster station 01 is normally used, seawater can enter the contact plate 03 through the matching use of the hollow plate 06 and the connecting pipe 05 by using the circulating pump 07, and can be matched with the bottom of the wind power booster station 01 through the contact plate 03, so that the cooling and heat dissipation effects required by the normal work of the whole wind power booster station 01 are enhanced;

when receiving the wind-force resource on sea in the time of 01 normal use in wind-powered electricity generation booster station, the cooperation driving motor 18 and the flabellum 22 that are setting up can let flabellum 22 drive wind-powered electricity generation booster station 01 the air flow in inside circulate through water conservancy diversion frame 19 cooperate the communicating pipe 17 that sets up can carry out the adaptation with communicating frame 12 and consolidate the heat-conducting plate 02 that sets up, just can step up the timely derivation of the inside heat of wind-powered electricity generation booster station 01.

The above description is only an embodiment of the present invention, and is not intended to limit the present invention. Various modifications and variations of the present invention will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (6)

1. The utility model provides an offshore wind power booster station cooling system, includes wind power booster station (01), bearing board (11) and support frame (13), its characterized in that: the wind power booster station comprises a wind power booster station (01), wherein the bottom of the wind power booster station (01) is tightly attached to a bearing plate (11), four square through holes are formed in positions, close to the bottom, of the outer side of the periphery of the front face of the wind power booster station (01), a communication frame (12) is installed in each through hole, and a heat conduction plate (02) which is annularly arranged is fixedly connected to the inner side of each communication frame (12); the supporting plate (11), four supporting columns (09) are installed at the bottom of the supporting plate (11), a first reinforcing rib (04) and a second reinforcing rib (10) are installed between every two supporting columns (09), and the first reinforcing rib (04) and the second reinforcing rib (10) are arranged in a crossed and symmetrical mode; the outer side of the support frame (13) is connected with the outer side of the support column (09), a contact plate (03) is installed in the middle of the support frame (13), and the outer side of the front face of the contact plate (03) is fixedly connected with the inner side of the support frame (13) through an auxiliary rod (14).

2. The offshore wind power booster station cooling and heat dissipating system of claim 1, characterized in that: the top of contact plate (03) links to each other with the bottom of wind-powered electricity generation booster station (01) is fixed, contact plate (03) is hollow structure, and the bottom of this contact plate (03) sets up two through-holes that can supply connecting pipe (05) to be connected, two the bottom of connecting pipe (05) is connected with hollow slab (06).

3. The offshore wind power booster station cooling and heat dissipating system of claim 2, characterized in that: the bottom fixedly connected with of hollow core slab (06) is protection network (08) that the arc set up, the top mid-mounting of hollow core slab (06) has a circulating pump (07), the both sides and the connecting pipe (05) of circulating pump (07) are linked together.

4. The offshore wind power booster station cooling and heat dissipating system of claim 1, characterized in that: reinforced layer (16) are installed to the inboard of wind-powered electricity generation booster station (01), the inboard fixedly connected with of reinforced layer (16) is a spacing section of thick bamboo (21) of circular setting, install four water conservancy diversion frames (19), four in a spacing section of thick bamboo (21) install base (20) between water conservancy diversion frame (19), the top fixedly connected with driving motor (18) of base (20), flabellum (22) are installed in the output shaft outside of driving motor (18).

5. The offshore wind power booster station cooling and heat dissipating system of claim 1, characterized in that: the wind-powered electricity generation booster station (01) inboard is seted up and is supplied the recess that communicating pipe (17) are connected, a free end of communicating pipe (17) is connected with intercommunication frame (12), another free end of communicating pipe (17) runs through with the outside of back up coat (16) and links to each other.

6. The offshore wind power booster station cooling and heat dissipating system of claim 1, characterized in that: the wind power booster station is characterized in that a positioning hole (15) is formed in the middle of the top of the supporting column (09), a bolt is installed on the inner side of the positioning hole (15), and the top of the bolt is fixedly connected with the bottom of the wind power booster station (01).

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