CN216870606U - Wind power generation anemometer tower support with adjust structure - Google Patents

Abstract

The utility model relates to the field of new energy, in particular to a wind power generation anemometry tower support with an adjusting structure, wherein the rotating axes of a middle plate and an upper plate are mutually vertical in space, the upper plate is rotationally connected with an upper layer support rod fixed on the middle plate, and after a manual valve is opened, the two dimensions of the middle plate and the upper plate are respectively adjusted by drawing a push rod and utilizing two hydraulic cylinders, so that the upper plate can be adjusted to be horizontal; the level of an upper plate (an anemometer mounting plate) of the anemometer tower support is adjusted.

Description

Wind power generation anemometer tower support with adjust structure

Technical Field

The utility model relates to the field of new energy, in particular to a wind power generation anemometer tower support with an adjusting structure.

Background

The wind measuring tower is a tower type which is set up for meeting the acquisition requirement of wind resource data, the wind measuring tower is arranged in a target wind field, the purpose is to collect the actual measurement data of wind energy resources in the wind field, the side wind tower is arranged in the site of the wind field, the side wind tower is mostly of a folding frame type structure, a steel strand cable is adopted for diagonal reinforcement, and the height is generally 80-150 meters. According to the current national regulations, the height of a crosswind tower is generally 100 meters. Need measure wind data through the support mounting anemoscope on the anemometer tower, in order to improve data detection precision, the installation angle of anemometer must accomplish violently flat vertical, and this has very high requirement to the installation and the processing of anemometer tower support.

The utility model provides a wind power generation anemometer tower support with an adjusting structure.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model provides the wind power generation anemometer tower support with the adjusting structure, so that the level of the anemometer mounting plate of the anemometer tower support can be adjusted.

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

a wind power generation anemometry tower bracket with an adjusting structure comprises a fixed plate, a lower layer supporting rod, a middle plate, a hydraulic cylinder, an upper layer supporting rod, an upper layer plate, an injection oil cylinder and a manual valve;

the horizontal fixing plate is used for fixing the anemometer tower; the lower ends of the two lower-layer supporting rods are fixed on the upper side of the fixing plate, the middle plate is positioned between the two lower-layer supporting rods, and the middle plate is rotatably connected with the two lower-layer supporting rods;

the hydraulic cylinders are two in total and are respectively a first hydraulic cylinder and a second hydraulic cylinder;

the upper end and the lower end of the first hydraulic cylinder are respectively fixedly connected with the lower side of the middle plate and the upper side of the fixed plate;

the lower ends of the two upper layer supporting rods are fixedly connected with the upper side of the middle plate, and the upper plate is rotatably arranged between the two upper layer supporting rods; the rotating axis of the upper plate is mutually vertical to the rotating axis of the middle plate in space; the upper end and the lower end of the second hydraulic cylinder are respectively fixedly connected with the upper side of the middle plate and the lower side of the upper plate;

the injection oil cylinder comprises an oil drum, a piston and a push rod; the oil drum is fixed on the fixing plate, the piston is sleeved in the oil drum in a penetrating mode, and one end of the push rod is fixed with the piston;

two oil pipes are respectively communicated with the oil drum and the first hydraulic cylinder, the second hydraulic cylinder and the oil drum, and a manual valve is installed on a pipeline of the oil pipe and used for controlling the on/off of the oil pipe.

Further, the hydraulic cylinder comprises a hydraulic cylinder body, a rotating plate and a fixing plate; and two ends of the hydraulic cylinder body are respectively fixed with a rotating plate, and two sides of each rotating plate are rotatably connected with the fixed plate.

Further, the manual valve comprises a valve body, a valve cavity, a valve core, a communicating hole, a connecting rod, a spring, a second fixing plate, a limiting plate, a handle and a connecting pipe;

the valve body is provided with a valve cavity from the upper end to the lower end; two opposite connecting pipes are fixedly inserted into the valve body, and one end of each connecting pipe is communicated with the valve cavity; the valve core is embedded into the valve cavity in a sliding manner, and the valve core is provided with a communicating hole; the valve core and the handle are fixedly connected at two ends of the connecting rod, and the spring is sleeved outside the connecting rod in a penetrating manner; a limiting plate is arranged right above the handle, and the limiting plate is fixedly connected with the valve body through a second fixing plate;

when the lower end of the valve core is contacted with the lower part of the valve cavity, the communicating hole communicates the two connecting pipes; when the operator releases the handle, the handle is pushed upwards by the elastic force of the spring, and the communication hole is not communicated with the connecting pipe.

Further, the handle is at least 10cm long and is not positioned right below the limit plate.

Further, a rubber layer is fixedly arranged on the outer wall of the valve core.

The utility model has the beneficial effects that:

when the level of the upper plate needs to be adjusted; because the rotating axes of the middle plate and the upper plate are mutually vertical in space, and the upper plate is rotationally connected with the upper layer supporting rod fixed on the middle plate, (after the manual valve is opened, the push rod is pulled) two hydraulic cylinders are utilized to respectively adjust the two dimensional angles of the middle plate and the upper plate, and the upper plate can be adjusted to be horizontal; the level of an upper plate (an anemometer mounting plate) of the anemometer tower support is adjusted.

Drawings

FIG. 1 is a schematic structural diagram of the present application;

FIG. 2 is a perspective view of a portion of the structure of the present application;

FIG. 3 is a schematic view of the valve construction;

FIG. 4 is a schematic view of a hydraulic cylinder;

reference symbol comparison table:

the wind meter comprises a wind meter 00, a fixed plate 10, a lower layer support rod 20, a middle plate 30, a hydraulic cylinder 40, a hydraulic cylinder body 41, a rotating plate 42, a fixed plate 43, an upper layer support rod 50, an upper layer plate 60, an injection oil cylinder 80, an oil drum 81, a piston 82, a push rod 83, a manual valve 90, a valve body 91, a valve cavity 911, a valve core 92, a communication hole 921, a connecting rod 93, a spring 94, a second fixed plate 95, a limit plate 96, a handle 97 and a connecting pipe 98.

Detailed Description

The following further describes embodiments of the present invention with reference to the accompanying drawings. In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

In order to make the content of the present invention more clearly understood, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention.

As shown in fig. 1 to 4, a wind power generation anemometer tower bracket with an adjusting structure comprises a fixed plate 10, a lower layer strut 20, a middle plate 30, a hydraulic cylinder 40, an upper layer strut 50, an upper layer plate 60, an injection cylinder 80 and a manual valve 90;

referring to fig. 1 and 2, a horizontal fixing plate 10 is used for fixing the anemometer tower; the lower ends of the two lower struts 20 are fixed on the upper side of the fixing plate 10, the middle plate 30 is located between the two lower struts 20, and the middle plate 30 is rotatably connected with the two lower struts 20.

Referring to fig. 4, the hydraulic cylinder 40 includes a hydraulic cylinder body 41, a rotating plate 42, and a fixed plate 43; two ends of the hydraulic cylinder body 41 are both fixed with a rotating plate 42, and both sides of the rotating plate 42 are both rotatably connected with a fixed plate 43.

The hydraulic cylinders 40 are two in total and are respectively a first hydraulic cylinder 40 and a second hydraulic cylinder 40;

(refer to fig. 4 and fig. 1), the upper and lower ends of the first hydraulic cylinder 40 are respectively fixedly connected with the lower side of the middle plate 30 and the upper side of the fixed plate 10;

the lower ends of the two upper layer supporting rods 50 are fixedly connected with the upper side of the middle plate 30, and the upper layer plate 60 is rotatably arranged between the two upper layer supporting rods 50; the rotation axis of the upper plate 60 and the rotation axis of the middle plate 30 are mutually perpendicular in space; the upper and lower ends of the second hydraulic cylinder 40 are fixedly connected to the upper side of the middle plate 30 and the lower side of the upper plate 60, respectively.

The injection oil cylinder 80 comprises an oil drum 81, a piston 82 and a push rod 83; the oil drum 81 is fixed on the fixing plate 10, the piston 82 is sleeved in the oil drum 81 in a penetrating manner, and one end of the push rod 83 is fixed with the piston 8;

two oil pipes communicate oil drum 81 and first pneumatic cylinder 40, second pneumatic cylinder 40 and oil drum 81 respectively to manual valve 90 is installed to the pipeline of oil pipe, and manual valve 90 is used for controlling the oil pipe on/off circuit.

The upper side of the upper plate 60 is used for mounting a wind meter.

The principle is as follows: when the level of the upper plate 60 needs to be adjusted; because the rotation axes of the middle plate 30 and the upper plate 60 are mutually vertical in space, and the upper plate 60 is rotationally connected with the upper layer strut 50 fixed on the middle plate 30, (after the manual valve 90 is opened, the drawing push rod 83 is used) two hydraulic cylinders 40 are utilized to respectively adjust the two dimensional angles of the middle plate 30 and the upper plate 60, namely the upper plate 60 can be adjusted to be horizontal; the leveling of the upper plate 60 (anemometer mounting plate) of the anemometer tower support is adjusted.

Further, the manual valve 90 includes a valve body 91, a valve cavity 911, a valve core 92, a communication hole 921, a connection rod 93, a spring 94, a second fixing plate 95, a limit plate 96, a handle 97, and a connection pipe 98;

referring to fig. 3, a valve cavity 911 is formed in the valve body 91 from the upper end thereof to the lower side; two opposite connecting pipes 98 are fixedly inserted into the valve body 91, and one end of each connecting pipe 98 is communicated with the valve cavity 911; the valve core 92 is slidably embedded into the valve cavity 911, and the valve core 92 is provided with a communication hole 921; the valve core 92 and the handle 97 are fixedly connected at two ends of the connecting rod 93, and the spring 94 is sleeved outside the connecting rod 93 in a penetrating manner; a limit plate 96 is arranged right above the handle 97, and the limit plate 96 and the valve body 91 are fixedly connected by the second fixing plate 95.

When the operator presses the handle 97 downwards, the lower end of the valve core 92 contacts with the lower part of the valve cavity 911, and the communication hole 921 communicates the two connecting pipes 98; when the operator releases the handle 97, the handle 97 is pushed up by the elastic force of the spring 94, and the communication hole 921 is not communicated with the connection pipe 98.

The free end of the connecting tube 98 is adapted to communicate with a pipeline.

Further, the handle 97 is not located right below the stopper plate 96, and has a length of at least 10 cm.

Further, a rubber layer is fixedly arranged on the outer wall of the valve core 92.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and should not be taken as limiting the scope of the present invention, which is intended to cover any modifications, equivalents, improvements, etc. within the spirit and scope of the present invention.

Claims (5)

1. A wind power generation anemometry tower bracket with an adjusting structure is characterized by comprising a fixed plate, a lower layer supporting rod, a middle plate, a hydraulic cylinder, an upper layer supporting rod, an upper layer plate, an injection oil cylinder and a manual valve;

the horizontal fixing plate is used for fixing the anemometer tower; the lower ends of the two lower-layer supporting rods are fixed on the upper side of the fixing plate, the middle plate is positioned between the two lower-layer supporting rods, and the middle plate is rotatably connected with the two lower-layer supporting rods;

the hydraulic cylinders are two in total and are respectively a first hydraulic cylinder and a second hydraulic cylinder;

the upper end and the lower end of the first hydraulic cylinder are respectively fixedly connected with the lower side of the middle plate and the upper side of the fixed plate;

the lower ends of the two upper layer supporting rods are fixedly connected with the upper side of the middle plate, and the upper plate is rotatably arranged between the two upper layer supporting rods; the rotating axis of the upper plate is mutually vertical to the rotating axis of the middle plate in space; the upper end and the lower end of the second hydraulic cylinder are respectively fixedly connected with the upper side of the middle plate and the lower side of the upper plate;

the injection oil cylinder comprises an oil drum, a piston and a push rod; the oil drum is fixed on the fixing plate, the piston is sleeved in the oil drum in a penetrating mode, and one end of the push rod is fixed with the piston;

two oil pipes are respectively communicated with the oil drum and the first hydraulic cylinder, the second hydraulic cylinder and the oil drum, and a manual valve is installed on a pipeline of the oil pipe and used for controlling the on/off of the oil pipe.

2. Wind power tower support with adjustment structure according to claim 1,

the hydraulic cylinder comprises a hydraulic cylinder body, a rotating plate and a fixing plate; and two ends of the hydraulic cylinder body are respectively fixed with a rotating plate, and two sides of each rotating plate are rotatably connected with the fixed plate.

3. Wind power tower support with adjustment structure according to claim 1 or 2,

the manual valve comprises a valve body, a valve cavity, a valve core, a communicating hole, a connecting rod, a spring, a second fixing plate, a limiting plate, a handle and a connecting pipe;

the valve body is provided with a valve cavity from the upper end to the lower end; two opposite connecting pipes are fixedly inserted into the valve body, and one end of each connecting pipe is communicated with the valve cavity; the valve core is embedded into the valve cavity in a sliding manner, and the valve core is provided with a communicating hole; the valve core and the handle are fixedly connected at two ends of the connecting rod, and the spring is sleeved outside the connecting rod in a penetrating manner; a limiting plate is arranged right above the handle, and the limiting plate is fixedly connected with the valve body through a second fixing plate;

when the lower end of the valve core is contacted with the lower part of the valve cavity, the communicating hole communicates the two connecting pipes; when the operator releases the handle, the handle is pushed upwards by the elastic force of the spring, and the communication hole is not communicated with the connecting pipe.

4. Wind power tower support with adjustment structure according to claim 3,

the handle is at least 10cm long and is not positioned right below the limiting plate.

5. A wind power tower support with adjustment structure according to claim 3,

and a rubber layer is fixedly arranged on the outer wall of the valve core.

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