CN109989879B

CN109989879B - Wind energy detection device

Info

Publication number: CN109989879B
Application number: CN201910324910.8A
Authority: CN
Inventors: 郑俊文
Original assignee: Guangxi Power Line Equipment And Fitting Factory Co ltd; Electric Power Research Institute of Guangxi Power Grid Co Ltd
Current assignee: GUANGXI POWER LINE EQUIPMENT AND FITTING FACTORY Co.,Ltd.; Electric Power Research Institute of Guangxi Power Grid Co Ltd
Priority date: 2019-04-22
Filing date: 2019-04-22
Publication date: 2020-12-29
Anticipated expiration: 2039-04-22
Also published as: CN109989879A

Abstract

The invention relates to a wind energy detection device, which comprises a machine body and a cam rotating cavity arranged in the machine body, wherein a cam triggering assembly is arranged in the cam rotating cavity, a measuring cavity communicated with the right side of the cam rotating cavity is arranged on the right side of the cam rotating cavity, a measuring assembly is arranged in the measuring cavity, a measuring power gear meshing cavity is arranged on the right side of the measuring cavity, and a measuring power assembly is arranged in the measuring power gear meshing cavity. The operation is convenient.

Description

Wind energy detection device

Technical Field

The invention relates to the technical field of wind speed measurement, in particular to a wind energy detection device.

Background

As is well known, wind is a common natural phenomenon caused by solar radiant heat, and air at different places on the earth's surface is cooled and heated differently, causing it to flow and thus forming wind. The invention aims to design a device capable of detecting wind energy so as to facilitate later construction of a wind driven generator.

Disclosure of Invention

The technical problem to be solved by the present invention is to provide a wind energy detecting device, which can solve the above problems in the prior art.

The invention is realized by the following technical scheme: the invention relates to a wind energy detection device, which comprises a machine body and a cam rotating cavity arranged in the machine body, wherein a cam trigger assembly is arranged in the cam rotating cavity, a measurement cavity communicated with the right side of the cam rotating cavity is arranged in the right side of the cam rotating cavity, a measurement assembly is arranged in the measurement cavity, a measurement power gear meshing cavity is arranged in the right side of the measurement cavity, and a measurement power assembly is arranged in the measurement power gear meshing cavity, wherein the cam trigger assembly and the measurement assembly complete recording and information transmission of wind speed together, the measurement power assembly is used for providing power for the measurement assembly, an air box rotating cavity with an upward opening is arranged on the upper side of the cam rotating cavity, a rotatable air box assembly is arranged in the air box rotating cavity, a wind direction indicating assembly is fixedly connected to the upper side of the air box assembly and is used for indicating the direction of wind and controlling the, the novel telescopic engine is characterized in that a first-stage telescopic frame sliding cavity with a downward opening is formed in the lower side of the cam rotating cavity, a base is arranged below the engine body, a second-stage telescopic frame sliding cavity with an upward opening is formed in the base, a telescopic frame assembly is arranged in the first-stage telescopic frame sliding cavity, the telescopic frame assembly is used for adjusting the height of the engine body, a telescopic frame control cavity communicated with the second-stage telescopic frame sliding cavity is arranged on the left side of the second-stage telescopic frame sliding cavity, a telescopic frame control assembly is arranged in the telescopic frame control cavity, and the telescopic frame control assembly is used for controlling the telescopic degree of the telescopic frame assembly.

As a preferable technical scheme, the cam triggering assembly comprises a cam rotating shaft which is arranged in the cam rotating cavity and extends forwards and backwards, the cam rotating shaft is connected with a cam driven gear in a rotating fit manner, the cam driven gear is connected with a cam driving gear in a meshing fit manner, the cam driving gear is connected with a central spindle in a rotating fit manner, the central spindle penetrates through the inner wall of the cam rotating cavity and extends into the bellows assembly, the cam rotating shaft is connected with a cam in a rotating fit manner, a communicated cam slider cavity is arranged at the right side of the cam rotating cavity, a slidable cam slider is arranged in the cam slider cavity, the cam is connected with the cam slider in a sliding fit manner, the cam slider is fixedly connected with a dotting pen connecting rod in a matching manner, a top pressure spring is arranged on the periphery of the dotting pen connecting rod in a top pressure, the dotting pen penetrates through the inner wall of the cam slider cavity and extends into the measuring cavity, so that the wind speed is converted into the frequency conveniently, and the measurement is facilitated.

As a preferable technical scheme, the measuring component comprises two groups of recording belt wheel rotating shafts which are arranged in the measuring cavity, extend forwards and backwards and are symmetrical up and down, the rotating shaft of the recording belt wheel is connected with a recording belt wheel in a rotating fit manner, a recording belt is connected between the two groups of recording belt wheels in a rotating fit manner, the inner wall of the right side of the measuring cavity is fixedly connected with a recording image sensor, the right side of the measuring cavity is provided with a cleaning block sliding cavity communicated with the cleaning block sliding cavity, a half gear rotating shaft extending forwards and backwards is arranged in the cleaning block sliding cavity, the half gear rotating shaft is connected with a half gear in a rotating matching way, the half gear is engaged and matched with an upper half-tooth sliding block and a lower half-tooth sliding block, the upper half-tooth sliding block and the lower half-tooth sliding block are fixedly matched and connected with a cleaning block connecting rod, the cleaning block connecting rod is fixedly matched with the cleaning block, so that the recording and cleaning of the wind speed information are facilitated.

As a preferable technical scheme, the measuring power assembly comprises a measuring power input shaft which is arranged in the measuring power gear meshing cavity and extends up and down, the measuring power input shaft penetrates through the inner wall of the measuring power gear meshing cavity and extends into the cleaning block sliding cavity to be connected with the half gear rotating shaft in a power matching way, the measuring power input shaft is connected with a measuring power motor of which the outer surface is embedded in the inner wall of the measuring power gear meshing cavity in a power matching way, the measuring power input shaft is connected with a measuring driving gear in a rotating matching way, the measuring driving gear is connected with a measuring driven gear in a meshing way, the measuring driven gear is connected with a measuring power output shaft in a rotating matching way, the measuring power output shaft penetrates through the inner wall of the measuring power gear meshing cavity and extends into the measuring cavity to be connected with the recording belt wheel rotating shaft, thereby facilitating the provision of power to the measurement assembly.

As a preferred technical scheme, the bellows subassembly including set up in the rotatable bellows casing of bellows rotation intracavity, open-ended star type gear engagement chamber about being provided with in the bellows casing, star type gear engagement intracavity wall fixedly connected with longitudinal symmetry's internal gear, internal gear meshing cooperation is connected with three sets of running gear, the running gear normal running fit is connected with the fan blade drive shaft, the fan blade drive shaft is in star type gear engagement intracavity fixed fit is connected with the fan blade, the running gear meshing cooperation is connected with central gear, central gear with central spindle normal running fit is connected to be convenient for realize turning into the speed of wind fan blade pivoted speed in the bellows casing, and then pass through the central spindle spreads the information of wind.

As the preferred technical scheme, the wind direction indicating assembly comprises two groups of supporting rods which are fixedly matched and connected with the upper side of the air box assembly, the supporting rods are fixedly matched and connected with a wind direction connecting rod, the left end of the wind direction connecting rod is connected with a propeller in a rotating and matching manner, and the right end of the wind direction connecting rod is fixedly connected with a wind direction indicating plate, so that the wind direction is conveniently indicated, and the air box assembly is driven to rotate and adjust the direction which is more beneficial to wind entering.

As a preferable technical scheme, the telescopic frame component comprises a primary pin shaft sliding groove arranged in a primary telescopic frame sliding cavity, two groups of driven pin shafts which are bilaterally symmetrical are connected in the sliding groove of the first-stage pin shaft in a sliding fit manner, the driven pin shafts are connected with driven support rods which are symmetrical along the center of the sliding cavity of the first-stage expansion bracket in a rotating fit manner, the driven support bar is connected with a connecting pin shaft in a rotating fit manner, the connecting pin shaft is connected with a driving support bar in a rotating fit manner, a central pin shaft which is symmetrical up and down is connected between the driving support rod and the driven support rod in a rotating matching way, the driving support rod is connected with a driving pin shaft in a rotating fit mode, a second-stage pin shaft sliding groove is formed in the sliding cavity of the second-stage telescopic frame, the driving pin shaft is connected with the second-stage pin shaft sliding groove in a sliding fit mode, so that the height of the machine body can be adjusted conveniently.

As preferred technical scheme, the expansion bracket control assembly including set up in expansion bracket control gear axis of rotation that extends around in the expansion bracket control intracavity, expansion bracket control gear axis of rotation normal running fit is connected with the surface and inlays and locate expansion bracket control driving motor in the expansion bracket control intracavity wall, expansion bracket control gear axis of rotation normal running fit is connected with expansion bracket control gear, expansion bracket control chamber downside is provided with the rack sliding chamber that is linked together, expansion bracket control gear is in rack sliding intracavity meshing cooperation is connected with the rack, the rack with initiative round pin axle normal running fit connects to be convenient for realize doing the expansion bracket assembly provides power.

The invention has the beneficial effects that: the wind direction specifying component is designed firstly, the defect that only wind speed can be measured but wind direction cannot be measured is overcome, the wind inlet bellows which is designed in a star-shaped arrangement mode is adopted, stable measurement can be achieved even if wind power is small, in the measuring link, the wind speed is converted into mechanical actuation frequency, collection is achieved through the remote camera, stability and high efficiency are achieved, collection is achieved, cleaning and recycling are achieved, the wind direction specifying component is environment-friendly and can be used repeatedly, the replacement frequency of auxiliary parts of equipment is reduced, cost is reduced, the automatic height adjusting component is designed finally, no matter what terrain is limited by the automatic height adjusting component, the whole-process mechanical transmission matching of the device is achieved, rhythm is compact, matching is coherent, the working efficiency of the device is improved, the device is small and exquisite in design, operation is simple and convenient, the automation degree is high.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic view of an internal overall structure of a wind energy detecting apparatus according to the present invention;

FIG. 2 is an enlarged partial view of "A" in FIG. 1;

FIG. 3 is a partially enlarged view of "B" in FIG. 1;

FIG. 4 is a schematic cross-sectional view of "C-C" in FIG. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 4, the wind energy detecting device of the present invention includes a body 122 and a cam rotating cavity 108 disposed in the body 122, a cam triggering component is disposed in the cam rotating cavity 108, a measurement cavity 133 communicated with the right side of the cam rotating cavity 108 is disposed at the right side of the cam rotating cavity, a measurement component is disposed in the measurement cavity 133, a measurement power gear meshing cavity 143 is disposed at the right side of the measurement cavity 133, a measurement power component is disposed in the measurement power gear meshing cavity 143, wherein the cam triggering component and the measurement component complete recording and information transmission of wind speed together, the measurement power component is configured to provide power for the measurement component, a bellows rotating cavity 126 having an upward opening is disposed at an upper side of the cam rotating cavity 108, a rotatable bellows component is disposed in the bellows rotating cavity 126, and a wind direction indicating component is fixedly connected to an upper side of the bellows component, the wind direction indicates the direction and the control that the subassembly is used for instructing the wind bellows subassembly rotates, the cam rotates chamber 108 downside and is provided with the decurrent one-level expansion bracket sliding chamber 109 of opening, the fuselage 122 below is provided with frame 117, be provided with the ascending second grade expansion bracket sliding chamber 114 of opening in the frame 117, one-level expansion bracket sliding chamber 109 with be provided with the expansion bracket subassembly in the second grade expansion bracket sliding chamber 114, the expansion bracket subassembly is used for adjusting the height of fuselage 122, second grade expansion bracket sliding chamber 114 left side is provided with expansion bracket control chamber 155 that is linked together, be provided with expansion bracket control assembly in the expansion bracket control chamber 155, expansion bracket control assembly is used for controlling the flexible degree of expansion bracket subassembly.

Advantageously, the cam trigger assembly comprises a cam rotating shaft 107 extending back and forth and arranged in the cam rotating cavity 108, the cam rotating shaft 107 is rotatably and cooperatively connected with a cam driven gear 106, the cam driven gear 106 is in meshing and cooperatively connected with a cam driving gear 162, the cam driving gear 162 is rotatably and cooperatively connected with a central spindle 105, the central spindle 105 penetrates through the inner wall of the cam rotating cavity 108 and extends into the bellows assembly, the cam rotating shaft 107 is rotatably and cooperatively connected with a cam 128, the right side of the cam rotating cavity 108 is provided with a communicated cam slider cavity 130, a slidable cam slider 129 is arranged in the cam slider cavity 130, the cam 128 is in sliding and cooperatively connected with the cam slider 129, the cam slider 129 is fixedly and cooperatively connected with a dotting pen connecting rod 131, and a jacking spring 127 is jacked on the periphery of the dotting pen connecting rod 131, the dotting pen connecting rod 131 is fixedly connected with a dotting pen 132 in a matched mode, and the dotting pen 132 penetrates through the inner wall of the cam slider cavity 130 and stretches into the measuring cavity 133, so that the wind speed is converted into the frequency conveniently, and the measurement is facilitated.

Advantageously, the measuring assembly comprises two sets of recording tape wheel rotating shafts 148 which are arranged in the measuring cavity 133, extend forwards and backwards and are symmetrical up and down, the recording tape wheel rotating shafts 148 are connected with the recording tape wheels 134 in a rotating fit mode, a recording tape 149 is connected between the two sets of recording tape wheels 134 in a rotating fit mode, a recording image sensor 147 is fixedly connected to the inner wall of the right side of the measuring cavity 133, a clearing block sliding cavity 136 communicated with the right side of the measuring cavity 133 is arranged in the right side of the measuring cavity 133, a half gear rotating shaft 140 extending forwards and backwards is arranged in the clearing block sliding cavity 136, a half gear rotating shaft 140 is connected with a half gear 139 in a rotating fit mode, a half gear 139 is connected with an upper half-tooth sliding block 138 and a lower half-tooth sliding block 138 in a meshing fit mode, a clearing block connecting rod 137 is, thereby being convenient for realizing the recording and the removal of the wind speed information.

Advantageously, the measurement power assembly comprises a measurement power input shaft 141 which is arranged in the measurement power gear meshing cavity 143 and extends up and down, the measurement power input shaft 141 penetrates through the inner wall of the measurement power gear meshing cavity 143 and extends into the cleaning block sliding cavity 136 to be in power fit connection with the half gear rotating shaft 140, the measurement power input shaft 141 is in power fit connection with a measurement power motor 145 of which the outer surface is embedded in the inner wall of the measurement power gear meshing cavity 143, the measurement power input shaft 141 is in rotational fit connection with a measurement driving gear 144, the measurement driving gear 144 is in mesh fit connection with a measurement driven gear 142, the measurement driven gear 142 is in rotational fit connection with a measurement power output shaft 146, the measurement power output shaft 146 penetrates through the inner wall of the measurement power gear meshing cavity 143 and extends into the measurement cavity 133 to be in power fit connection with the recording tape rotating shaft 148, thereby facilitating the provision of power to the measurement assembly.

Advantageously, the bellows assembly comprises a bellows housing 104 rotatably disposed in the bellows rotating chamber 126, a star gear engaging chamber 160 with left and right openings is disposed in the bellows housing 104, inner gears 158 that are symmetrical up and down are fixedly connected to an inner wall of the star gear engaging chamber 160, three sets of rotating gears 156 are connected to the inner gears 158 in a meshing and matching manner, a vane driving shaft 159 is connected to the rotating gears 156 in a rotating and matching manner, vanes 103 are fixedly connected to the vane driving shaft 159 in the star gear engaging chamber 160 in a matching and matching manner, a central gear 157 is connected to the rotating gears 156 in a meshing and matching manner, and the central gear 157 is connected to the central spindle 105 in a rotating and matching manner, so that the speed of wind is converted into the speed of rotation of the vanes 103 in the bellows housing 104, and further, the wind information is transmitted through.

Advantageously, the wind direction indicating assembly comprises two sets of support rods 124 fixedly and fittingly connected to the upper side of the bellows assembly, a wind direction connecting rod 125 is fixedly and fittingly connected to the support rods 124, the left end of the wind direction connecting rod 125 is rotatably and fittingly connected to the propeller 101, and a wind direction indicating plate 123 is fixedly connected to the right end of the wind direction connecting rod 125, so that the wind direction indicating is achieved, the bellows assembly is driven to rotate and the wind direction indicating plate is adjusted to a direction more favorable for wind entering.

Advantageously, the telescoping carriage assembly includes a primary pin sliding slot 121 disposed within the primary telescoping carriage sliding cavity 109, two groups of driven pin shafts 120 which are symmetrical left and right are connected in the first-stage pin shaft sliding groove 121 in a sliding fit manner, the driven pin shaft 120 is connected with the driven support rod 110 which is symmetrical along the center of the primary expansion bracket sliding cavity 109 in a rotating fit manner, the driven support bar 110 is connected with a connecting pin shaft 112 in a rotating fit manner, the connecting pin shaft 112 is connected with a driving support bar 115 in a rotating fit manner, a central pin shaft 119 which is symmetrical up and down is connected between the driving support rod 115 and the driven support rod 110 in a rotating matching way, the driving support rod 115 is connected with a driving pin 154 in a rotating fit manner, a secondary pin sliding groove 116 is arranged in the secondary expansion bracket sliding cavity 114, the active pin 154 is connected with the second-stage pin sliding groove 116 in a sliding fit manner, so that the height of the body 122 can be adjusted conveniently.

Beneficially, the expansion bracket control assembly includes an expansion bracket control gear rotating shaft 151 arranged in the expansion bracket control cavity 155 and extending back and forth, the expansion bracket control gear rotating shaft 151 is connected with an outer surface embedded in an expansion bracket control driving motor in the inner wall of the expansion bracket control cavity 155 in a rotating fit manner, the expansion bracket control gear rotating shaft 151 is connected with an expansion bracket control gear 150 in a rotating fit manner, a rack sliding cavity 152 communicated with the expansion bracket control cavity 155 is arranged on the lower side of the expansion bracket control cavity, the expansion bracket control gear 150 is connected with a rack 153 in an inner meshing fit manner in the rack sliding cavity 152, the rack 153 is connected with an active pin shaft 154 in a rotating fit manner, and therefore the expansion bracket assembly provides power.

When the wind energy detection device is in an initial state, the measurement power motor 145, the expansion bracket control drive motor and the fan blade 103 are all in a stop state, the machine body 122 is in contact with the machine base 117, and the expansion bracket assembly is in a compression state.

When the wind energy detection device works, wind pushes the propeller 101 to rotate and drives the wind direction connecting rod 125 and the wind direction indicating plate 123 to point to the direction of blowing wind, meanwhile, the supporting rod 124 drives the wind box assembly to rotate and adjusts the position of the wind box assembly, so that the wind direction is indicated, the wind box assembly is driven to rotate and the direction of the wind more favorably adjusted, then the wind enters the star-shaped gear meshing cavity 160 to blow the wind blades 103 to rotate, the wind blades 103 drive three groups of rotating gears 156 arranged in a star shape through the wind blade driving shaft 159, so that the three groups of rotating gears 156 drive the central gear 157 to rotate, the central gear 157 drives the central main shaft 105 to rotate, the central main shaft 105 rotates and drives the cam driving gear 162, the cam driven gear 106, the wind direction indicating plate 123 to point to the direction of blowing wind, and then the wind, The cam rotating shaft 107 and the cam rotate, the cam contacts the cam slider 129 during rotation and pushes the cam slider 129 to slide in the cam slider cavity 130, the cam slider 129 drives the dotting pen connecting rod 131 and the dotting pen 132 to enter the measuring cavity 133, meanwhile, the top pressure spring 127 is in a compressed state, so that the wind speed is converted into a frequency magnitude, the measurement is facilitated, before the measurement power motor 145 is started and drives the measurement power input shaft 141, the measurement driving gear 144, the measurement driven gear 142 and the measurement power output shaft 146 to rotate, the measurement power output shaft 146 drives the recording tape rotating shaft 148 to rotate, the measurement power input shaft 141 drives the half gear rotating shaft 140 to rotate, the recording tape rotating shaft 148 rotates and drives the recording tape pulley 134 and the recording tape 149 to rotate, the dotting pen 132 performs dotting recording on the recording tape 149, the recording tape 149 rotates at any time and transmits dotting information to the recording image sensor 147, the recording image sensor 147 records and transmits the dotting information in real time, after the information recording is completed, the half-gear rotating shaft 140 rotates and drives the half-gear 139 to rotate, the half-gear 139 drives the upper half-gear sliding block 138 and the lower half-gear sliding block 138 to slide in the clearing block sliding cavity 136, and the upper half-gear sliding block 138 and the lower half-gear sliding block 138 drive the clearing block connecting rod 137 and the clearing block 135 to slide into the measuring cavity 133 to be in contact with the recording tape 149 and clear the dotting information on the recording tape 149, so that the recording and clearing of wind speed information are realized conveniently.

When the wind energy detection device of the invention needs to adjust the height, the telescoping rack control driving motor is started and drives the telescoping rack control gear rotating shaft 151 and the telescoping rack control gear 150 to rotate, the telescoping rack control gear 150 drives the rack 153 to slide in the rack sliding cavity 152, and finally drives the driving pin 154 to slide in the secondary pin sliding groove 116, in two groups of symmetrical driving pins 154, the driving pin 154 on the left side slides rightwards in the secondary pin sliding groove 116, the driving pin 154 on the right side is in a static state due to the limitation of the secondary pin sliding groove 116, the driving pin 154 drives the driving support bar 115 and the driven support bar 110 to rotate along the central pin 119, and the driven support bar 110 drives the driven pin 120 to slide in the primary pin sliding groove 121, finally, the driving support rod 115 and the driven support rod 110 which are bilaterally symmetrical extend, and the body 122 is lifted accordingly, so that the height of the body 122 can be adjusted conveniently.

The above description is only an embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope defined by the claims.

Claims

1. The utility model provides a wind energy detection device, includes the fuselage and sets up cam rotation chamber in the fuselage which characterized in that: the wind speed measuring device is characterized in that a cam trigger component is arranged in the cam rotating cavity, a measuring cavity communicated with the cam rotating cavity is arranged on the right side of the cam rotating cavity, a measuring component is arranged in the measuring cavity, a measuring power gear meshing cavity is arranged on the right side of the measuring cavity, a measuring power component is arranged in the measuring power gear meshing cavity, the cam trigger component and the measuring component complete recording and information transmission of wind speed together, the measuring power component is used for providing power for the measuring component, a wind box rotating cavity with an upward opening is arranged on the upper side of the cam rotating cavity, a rotatable wind box component is arranged in the wind box rotating cavity, a wind direction indicating component is fixedly connected to the upper side of the wind box component and used for indicating the direction of wind and controlling the wind box component to rotate, a first-stage telescopic frame sliding cavity with a downward opening is, the fuselage below is provided with the frame, be provided with the ascending second grade expansion bracket sliding chamber of opening in the frame, the first grade expansion bracket sliding chamber with second grade expansion bracket sliding chamber is provided with the expansion bracket subassembly, the expansion bracket subassembly is used for adjusting the height of fuselage, second grade expansion bracket sliding chamber left side is provided with the expansion bracket control chamber that is linked together, be provided with expansion bracket control assembly in the expansion bracket control chamber, expansion bracket control assembly is used for controlling the flexible degree of expansion bracket subassembly.

2. A wind energy detection device according to claim 1, wherein: the cam trigger assembly comprises a cam rotating shaft which is arranged in the cam rotating cavity and extends forwards and backwards, the cam rotating shaft is connected with a cam driven gear in a rotating fit manner, the cam driven gear is connected with a cam driving gear in a meshing fit manner, the cam driving gear is connected with a central spindle in a rotating fit manner, the central spindle penetrates through the inner wall of the cam rotating cavity and extends into the air box assembly, the cam rotating shaft is connected with a cam in a rotating fit manner, a communicated cam slider cavity is arranged at the right side of the cam rotating cavity, a slidable cam slider is arranged in the cam slider cavity, the cam is connected with the cam slider in a sliding fit manner, the cam slider is fixedly connected with a dotting pen connecting rod in a matching manner, a top pressure spring is arranged on the periphery of the dotting pen connecting rod in a top, the dotting pen penetrates through the inner wall of the cam slider cavity and extends into the measuring cavity.

3. A wind energy detection device according to claim 2, wherein: the measuring unit including set up in measure two sets of record tape wheel rotating shaft of extending and longitudinal symmetry around the intracavity, record tape wheel rotating shaft normal running fit is connected with the record tape band pulley, normal running fit is connected with the record tape between two sets of record tape band pulleys, measure chamber right side inner wall fixedly connected with record image sensor, it is provided with the piece sliding chamber of cleaing away that is linked together to measure the chamber right side, it is provided with the half gear axis of rotation that extends around the piece sliding intracavity, half gear axis of rotation normal running fit is connected with the half gear, half gear engagement cooperation is connected with half tooth sliding block from top to bottom, half tooth sliding block fixed fit is connected with and clears away a connecting rod from top to bottom, it is connected with and clears away the piece to clear away a connecting.

4. A wind energy detection device according to claim 3, wherein: the measurement power assembly comprises a measurement power input shaft which is arranged in the measurement power gear meshing cavity and extends up and down, the measuring power input shaft penetrates through the inner wall of the measuring power gear meshing cavity and extends into the cleaning block sliding cavity to be in power fit connection with the half gear rotating shaft, the measuring power input shaft is in power fit connection with a measuring power motor with the outer surface embedded in the inner wall of the measuring power gear meshing cavity, the measuring power input shaft is connected with a measuring driving gear in a rotating fit manner, the measuring driving gear is connected with a measuring driven gear in a meshing fit manner, the measuring driven gear is connected with a measuring power output shaft in a rotating fit mode, and the measuring power output shaft penetrates through the inner wall of the measuring power gear meshing cavity and extends into the measuring cavity to be connected with the recording belt wheel rotating shaft in a power fit mode.

5. A wind energy detection device according to claim 4, wherein: the bellows subassembly including set up in rotatable bellows casing in the bellows rotation intracavity, open-ended star type gear engagement chamber about being provided with in the bellows casing, star type gear engagement intracavity wall fixedly connected with longitudinal symmetry's internal gear, internal gear meshing cooperation is connected with three sets of running gear, the running gear normal running fit is connected with the fan blade drive shaft, the fan blade drive shaft is in star type gear engagement intracavity fixed fit is connected with the fan blade, the running gear meshing cooperation is connected with central gear, central gear with central spindle normal running fit connects.

6. A wind energy detection device according to claim 5, wherein: the wind direction indicating assembly comprises two groups of supporting rods which are fixedly matched and connected with the upper side of the air box assembly, the supporting rods are fixedly matched and connected with a wind direction connecting rod, the left end of the wind direction connecting rod is connected with a propeller in a rotating matching mode, and the right end of the wind direction connecting rod is fixedly connected with a wind direction indicating plate.

7. A wind energy detection device according to claim 6, wherein: the telescopic frame assembly comprises a first-stage pin shaft sliding groove arranged in a first-stage telescopic frame sliding cavity, two groups of driven pin shafts which are bilaterally symmetrical are connected in the first-stage pin shaft sliding groove in a sliding fit mode, driven support rods which are bilaterally symmetrical are connected in the first-stage pin shaft sliding groove in a rotating fit mode, the driven support rods are connected with driven support rods which are bilaterally symmetrical in the first-stage telescopic frame sliding cavity in a rotating fit mode, the driven support rods are connected with connecting pin shafts in a rotating fit mode, the connecting pin shafts are connected with driving support rods in a rotating fit mode, the driving support rods are connected with driving pin shafts in a rotating fit mode, a second-stage pin shaft sliding groove is formed in the second.

8. A wind energy detection device according to claim 7, wherein: the expansion bracket control assembly comprises an expansion bracket control gear rotating shaft arranged in the expansion bracket control cavity and extending forwards and backwards, the expansion bracket control gear rotating shaft is connected with an outer surface in a matched mode and embedded in the outer surface, an expansion bracket control driving motor is arranged in the inner wall of the expansion bracket control cavity, the expansion bracket control gear rotating shaft is connected with an expansion bracket control gear in a matched mode and is provided with a rack sliding cavity communicated with the expansion bracket control cavity, the expansion bracket control gear is meshed in the rack sliding cavity in a matched mode and is connected with a rack, and the rack is connected with the active pin shaft in a matched mode and in a rotated mode.