CN113731874B - Energy-saving and environment-friendly self-cleaning mechanism of building engineering anemometer - Google Patents

Abstract

The invention provides an energy-saving and environment-friendly self-cleaning mechanism for a building engineering anemometer, which comprises a main anemometer frame, wherein an outer sleeve ring is movably sleeved on the outer side of the main anemometer frame, a fan blade is arranged on the outer side of the outer sleeve ring, a cleaning component and a control component are arranged at the top end of the main anemometer frame, the control component comprises a lifting rod, a pull rope, an elastic clamping plate and a push plate, and a starting component is arranged on the outer side of the main anemometer frame and above the outer sleeve ring. When the rotational speed of fan blade diminishes, the centrifugal force that the slide received diminishes and inwards moves, and the pawl drives helical gear and magnetic path rotatory, and magnetic path and annular magnetic conduction board are magnetized with it, and homopolar repulsion promotes the lifter and moves upwards, and push pedal pulling elastic clamping plate and draw-in groove separation, the brush is in contact with the fan blade in the promotion down-movement of pressure spring, and debris on the fan blade is scraped the brush, and then has realized the function of automatic clearance, the effectual circumstances that is infected with debris on having avoided the fan blade and influences rotational speed and testing result has improved the reliability in use of anemograph.

Description

Energy-saving and environment-friendly self-cleaning mechanism of building engineering anemometer

Technical Field

The invention belongs to the technical field of building engineering anemometers, and particularly relates to an energy-saving and environment-friendly self-cleaning mechanism of a building engineering anemometer.

Background

Along with the high-speed development of Chinese economy, the urban process speed is also accelerated, a large number of high-rise buildings are continuously emerging in urban construction in order to meet the living and working demands of population in urban, and the quality of the buildings is ensured to meet the requirements in the construction of the high-rise buildings, so that various measurements are often required in the construction engineering, wherein the detection of wind speed is an important procedure.

In the present building engineering, the wind speed is detected by adopting an anemometer, but the structure and the function of the existing anemometer are simpler, and the existing anemometer only can carry out simple wind speed measurement work including a fan blade for receiving wind power, a sensor, a display and the like, and the existing anemometer does not have an automatic cleaning function.

Accordingly, the self-cleaning mechanism of the building engineering anemometer is researched and improved aiming at the existing structure and the defects, and is energy-saving and environment-friendly, so that the purpose of higher practical value is achieved.

Disclosure of Invention

In order to solve the technical problems, the invention provides an energy-saving and environment-friendly self-cleaning mechanism of a building engineering anemometer, which is realized by the following specific technical means:

the utility model provides an energy-concerving and environment-protective building engineering anemometer self-cleaning mechanism, includes the anemometer body frame, the outside activity of anemometer body frame has cup jointed the outer collar, and the fan blade is installed in the outside of outer collar, and cleaning component and control assembly are installed on the top of anemometer body frame, and control assembly includes lifter, stay cord, elastic clamping board and push pedal, and the starting components is installed in the outside of anemometer body frame and the top that is located outer collar.

Further, the cleaning assembly comprises a guide seat fixedly arranged at the top end of the main frame of the anemometer, a brush capable of sliding up and down is movably arranged in the guide seat, a pressure spring is arranged at the top of the brush, the brush adopts a flexible brush such as a bristle brush, the pressure spring is in a compressed energy storage state in an initial state, the pressure spring can push the brush to move downwards after releasing energy, and sundries such as dust on the fan blade can be scraped by the brush after the fan blade rotating at a low speed contacts with the brush.

Further, the lifter activity is pegged graft in the inside of anemograph body frame, the top of lifter is connected with the brush through the stay cord, the activity is pegged graft on the guide seat has the elastic clamping plate that blocks the brush, be provided with the draw-in groove that corresponds with the elastic clamping plate on the brush, the one end that the elastic clamping plate is close to the lifter extends to the outside of guide seat, the push pedal that runs through the elastic clamping plate is fixedly connected with in the outside of lifter, the through-hole that corresponds with the push pedal has been seted up to the inside of elastic clamping plate, be provided with the slope section in the push pedal, and the bottom of slope section is provided with straight flange section, install positioning spring on the lifter, under the initial state, the elastic clamping plate card is in the draw-in groove, thereby fix the position of brush, after the lifter shifts up, through push pedal pulling elastic clamping plate, make elastic clamping plate and draw-in groove separation, then the brush moves down under the promotion of pressure spring.

Further, the starting assembly comprises an annular magnetic conduction plate fixedly arranged on the main frame of the anemometer, a fixed seat which is uniformly distributed is fixedly connected to the top of the outer sleeve ring, a sliding plate is movably inserted in the fixed seat, a reset spring is arranged on the sliding plate, a supporting frame is fixedly connected between the fixed seat and the annular magnetic conduction plate and is arranged on the outer side of the main frame of the anemometer, a bevel gear which is uniformly distributed is rotatably arranged on the supporting frame, a reset torsion spring is arranged on the bevel gear, a pawl meshed with the bevel gear is arranged on the sliding plate, a magnetic block which extends to the inner side of the annular magnetic conduction plate is fixedly connected to the bevel gear, a gap is reserved between the magnetic block and the annular magnetic conduction plate, a magnetic ring is fixedly sleeved on the outer side of the lifting rod and above the annular magnetic conduction plate, the pawl and the bevel gear form a unidirectional rotating mechanism, the sliding plate does not drive the bevel gear to rotate when moving outwards under the action of the reset spring, the annular magnetic conduction plate drives the bevel gear and the magnetic block to rotate through the pawl, and the magnetic block is contacted with the annular magnetic conduction plate, and the annular magnetic conduction plate is magnetized by the magnetic block, and the magnetic block is the same with one side of the magnetic ring opposite to the magnetic ring, and the lifting rod is pushed upwards under the action of the repulsive force.

Advantageous effects

Compared with the prior art, the invention has the following beneficial effects:

1. the fan blade is blown by wind, drive the outer sleeve and rotate jointly, the outer sleeve is looped and is driven the slide to rotate, the slide outwards stretches out under the effect of centrifugal force, through setting up pawl and helical gear constitution unidirectional rotating mechanism, the slide outwards can not drive the helical gear and rotate when moving, when wind speed diminishes or anemograph stops working, the rotational speed of fan blade diminishes, the centrifugal force that the slide received diminishes, inwards move under reset spring's effect, at this moment, drive helical gear and magnetic path rotation through the pawl, make magnetic path and annular magnetic conduction board contact, annular magnetic conduction board has magnetism after being magnetized by the magnetic path, and be the same with one side magnetism of magnetic path opposite face, promote the lifter to reciprocate under the effect of homopolar repulsion, after the lifter is moved up, through the push pedal pulling elastic clamping plate, make elastic clamping plate and draw-in groove separation, then the brush moves down under the promotion of pressure spring, with the fan blade contact of low-speed rotation after the brush moves down, debris such as dust on the fan blade can be scraped by the brush, and then realized carrying out automatic clearance's function to the anemograph, the effectual fan blade that influences the circumstances of rotational speed and testing result of being stained with debris on, the wind speed and the reliability of anemograph has been improved.

2. Through setting up reset torsion spring on the helical gear, the slide is at inwards moving reset back, pawl and helical gear stagger, and the helical gear gyration resets under reset torsion spring's effect, and the magnetic path separates with annular magnetic conduction board, and annular magnetic conduction board loses magnetism, and the lifter moves down under the effect of positioning spring and self gravity and resets, and the lifter of downshifting passes through the stay cord and drives the brush and upwards moves reset, so, the device can realize after clearing up the fan blade, accomplish the function that resets voluntarily to the next time continues to use.

3. Through setting up push pedal and elastic clamping board, after the lifter moves down, the push pedal also moves down simultaneously for elastic clamping board automatic re-setting, the brush is blocked again, has further improved the position stability of brush, uses safe and reliable.

4. The device uses wind power as a power source, and the device automatically cleans through the rotation speed change of the fan blade during working, does not need manual operation, automatically operates, has a simple structure, is energy-saving and environment-friendly, and is convenient to use.

Drawings

FIG. 1 is a front cross-sectional view of the present invention;

FIG. 2 is a schematic view of the bevel gear and anemometer frame connection of the present invention from below;

FIG. 3 is a schematic diagram of the structure of the annular magnetic conduction plate and the elastic lifting rod of the invention;

FIG. 4 is a front cross-sectional view of the startup assembly of the present invention;

FIG. 5 is a front cross-sectional view of the connection of the cleaning assembly and the control assembly of the present invention;

FIG. 6 is a schematic top view of the mating structure of the outer collar and the anemometer frame according to the present invention.

In the figure: 1. an anemometer main frame; 2. an outer collar; 3. a fan blade;

4. cleaning the assembly; 41. a guide seat; 42. a brush; 43. a pressure spring;

5. a control assembly; 51. a lifting rod; 52. a pull rope; 53. an elastic clamping plate; 54. a clamping groove; 55. a push plate; 56. a through hole; 57. a positioning spring;

6. a start assembly; 61. an annular magnetic conductive plate; 62. a fixing seat; 63. a slide plate; 64. a return spring; 651. a support frame; 65. bevel gear; 66. a reset torsion spring; 67. a pawl; 68. a magnetic block; 69. and a magnetic ring.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

embodiment one:

as shown in fig. 1 to 4:

the invention provides an energy-saving and environment-friendly self-cleaning mechanism for a building engineering anemometer, which comprises an anemometer main frame 1, wherein an outer sleeve ring 2 is movably sleeved on the outer side of the anemometer main frame 1, a fan blade 3 is arranged on the outer side of the outer sleeve ring 2, a cleaning component 4 and a control component 5 are arranged at the top end of the anemometer main frame 1, the control component 5 comprises a lifting rod 51 and a pull rope 52, and a starting component 6 is arranged on the outer side of the anemometer main frame 1 and above the outer sleeve ring 2.

Further, the cleaning component 4 comprises a guide seat 41 fixedly installed at the top end of the anemometer main frame 1, a brush 42 sliding up and down is movably installed in the guide seat 41, a pressure spring 43 is installed at the top of the brush 42, the brush 42 is a flexible brush such as a bristle brush, the pressure spring 43 is in a compressed energy storage state in an initial state, the pressure spring 43 can push the brush 42 to move downwards after releasing energy, and sundries such as dust on the fan blade 3 can be scraped by the brush 42 after the fan blade 3 rotating at a low speed contacts with the brush 42.

Further, the lifting rod 51 is movably inserted into the anemometer main frame 1, and the top end of the lifting rod 51 is connected with the brush 42 through a pull rope 52.

Further, the starting assembly 6 comprises an annular magnetic conduction plate 61 fixedly installed on the main anemometer frame 1, a fixing seat 62 which is uniformly distributed is fixedly connected to the top of the outer sleeve 2, a sliding plate 63 is movably inserted in the fixing seat 62, a reset spring 64 is arranged on the sliding plate 63, a supporting frame 651 is fixedly connected between the fixing seat 62 and the annular magnetic conduction plate 61 and outside the main anemometer frame 1, a bevel gear 65 which is uniformly distributed is rotatably installed on the supporting frame 651, a reset torsion spring 66 is arranged on the bevel gear 65, a pawl 67 meshed with the bevel gear 65 is arranged on the sliding plate 63, a magnetic block 68 which extends to the inside of the annular magnetic conduction plate 61 is fixedly connected to the bevel gear 65, a gap is reserved between the magnetic block 68 and the annular magnetic conduction plate 61, and a magnetic ring 69 is fixedly sleeved on the outer side of the lifting rod 51 and above the annular magnetic conduction plate 61.

Specific use and action of the embodiment:

when the wind turbine works, the wind blades 3 are blown by wind to drive the outer sleeve ring 2 to rotate together, the outer sleeve ring 2 drives the sliding plate 63 to rotate, the sliding plate 63 extends outwards under the action of centrifugal force, a unidirectional rotating mechanism is formed by the pawl 67 and the bevel gear 65, and the sliding plate 63 does not drive the bevel gear 65 to rotate when moving outwards;

when the wind speed is reduced or the anemometer stops working, the rotating speed of the fan blade 3 is reduced, the centrifugal force borne by the sliding plate 63 is reduced, the sliding plate moves inwards under the action of the return spring 64, at the moment, the pawl 67 drives the bevel gear 65 and the magnetic block 68 to rotate, the magnetic block 68 contacts with the annular magnetic guide plate 61, the annular magnetic guide plate 61 is magnetized by the magnetic block 68 and has magnetism same as that of one side of the opposite surface of the magnetic ring 69, the lifting rod 51 is pushed to move upwards under the action of the homopolar repulsive force, the brush 42 moves downwards under the pushing of the pressure spring 43, the brush 42 contacts with the fan blade 3 rotating at a low speed, dust and other impurities on the fan blade 3 are scraped off by the brush 42, the function of automatically cleaning the anemometer is realized, the situation that the rotating speed and the detection result are influenced by the impurities on the fan blade 3 is effectively avoided, and the use reliability of the anemometer is improved.

Through setting up reset torsion spring 66 on helical gear 65, slide 63 is after inwards moving reset, pawl 67 staggers with helical gear 65, helical gear 65 gyration reset under reset torsion spring 66's effect, magnet 68 separates with annular magnetic conduction board 61, annular magnetic conduction board 61 loses magnetism, lifter 51 moves down reset under self gravity and the suction effect of magnetic ring 69 and annular magnetic conduction board 61, lifter 51 of downshifting drives brush 42 through stay cord 52 and moves up reset, push pedal 55 also moves down simultaneously for elastic clamping plate 53 automatic reset, the brush 42 is blocked again, so, the device can realize after clearing up fan blade 3, the function of automatic completion reset is so that continue the use next time, the device uses wind-force as the power supply, automatic clearance is carried out through the rotational speed variation of fan blade 3 during operation, need not manual operation, automatic operation, and is simple in structure, energy-concerving and environment-protective, convenient to use.

Embodiment two:

as shown in fig. 1 to 6:

the invention provides an energy-saving and environment-friendly self-cleaning mechanism for a building engineering anemometer, which comprises an anemometer main frame 1, wherein an outer sleeve ring 2 is movably sleeved on the outer side of the anemometer main frame 1, fan blades 3 are arranged on the outer side of the outer sleeve ring 2, a cleaning component 4 and a control component 5 are arranged at the top end of the anemometer main frame 1, the control component 5 comprises a lifting rod 51, a pull rope 52, an elastic clamping plate 53 and a push plate 55, and a starting component 6 is arranged on the outer side of the anemometer main frame 1 and above the outer sleeve ring 2.

Further, the cleaning component 4 comprises a guide seat 41 fixedly installed at the top end of the anemometer main frame 1, a brush 42 sliding up and down is movably installed in the guide seat 41, a pressure spring 43 is installed at the top of the brush 42, the brush 42 is a flexible brush such as a bristle brush, the pressure spring 43 is in a compressed energy storage state in an initial state, the pressure spring 43 can push the brush 42 to move downwards after releasing energy, and sundries such as dust on the fan blade 3 can be scraped by the brush 42 after the fan blade 3 rotating at a low speed contacts with the brush 42.

Further, the lifting rod 51 is movably inserted into the anemometer main frame 1, the top end of the lifting rod 51 is connected with the brush 42 through the pull rope 52, the elastic clamping plate 53 for clamping the brush 42 is movably inserted into the guide seat 41, the clamping groove 54 corresponding to the elastic clamping plate 53 is formed in the brush 42, one end, close to the lifting rod 51, of the elastic clamping plate 53 extends to the outer side of the guide seat 41, the push plate 55 penetrating through the elastic clamping plate 53 is fixedly connected to the outer side of the lifting rod 51, a through hole 56 corresponding to the push plate 55 is formed in the inner side of the elastic clamping plate 53, a slope section is formed in the push plate 55, a straight edge section is arranged at the bottom of the slope section, the positioning spring 57 is installed on the lifting rod 51, in an initial state, the elastic clamping plate 53 is clamped in the clamping groove 54, so that the position of the brush 42 is fixed, after the lifting rod 51 moves upwards, the elastic clamping plate 53 is pulled by the push plate 55, the elastic clamping plate 53 is separated from the clamping groove 54, and then the brush 42 moves downwards under the pushing of the pressure spring 43.

Further, the starting assembly 6 comprises an annular magnetic conduction plate 61 fixedly installed on the anemometer main frame 1, a uniformly distributed fixing seat 62 is fixedly connected to the top of the outer sleeve 2, a sliding plate 63 is movably inserted in the fixing seat 62, a reset spring 64 is arranged on the sliding plate 63, a supporting frame 651 is fixedly connected between the fixing seat 62 and the annular magnetic conduction plate 61, a uniformly distributed bevel gear 65 is rotatably installed on the supporting frame 651, a reset torsion spring 66 is arranged on the bevel gear 65, a pawl 67 meshed with the bevel gear 65 is arranged on the sliding plate 63, a magnetic block 68 extending to the inside of the annular magnetic conduction plate 61 is fixedly connected to the bevel gear 65, a magnetic ring 69 is fixedly sleeved on the outer side of the lifting rod 51 and located above the annular magnetic conduction plate 61, the pawl 67 and the bevel gear 65 form a unidirectional rotating mechanism, the sliding plate 63 does not drive the bevel gear 65 to rotate when moving outwards under the action of the reset spring 64, the pawl 67 drives the bevel gear 65 and the magnetic block 68 to rotate, the magnetic block 68 contacts the annular magnetic conduction plate 61, and the magnetic block 68 is magnetized on the same side of the same magnetic ring 69 after the annular magnetic conduction plate 61 is contacted with the annular magnetic conduction plate 69, and the magnetic block is magnetized on one side of the same magnetic rod.

Specific use and action of the embodiment:

in the invention, as shown in fig. 1, the brush 42 is contracted in the guide seat 41 and is staggered up and down with the fan blade 3 in the initial state; the magnetic block 68 is not in contact with the annular magnetic conduction plate 61, and the annular magnetic conduction plate 61 has no magnetism; the lifting rod 51 is positioned at the bottommost end of the moving position under the action of the positioning spring 57 and self gravity, the positions of the push plate 55 and the elastic clamping plate 53 are as shown in fig. 5, the elastic clamping plate 53 is clamped in the clamping groove 54, so that the position of the brush 42 is fixed, and the pressure spring 43 is in a compressed energy storage state;

when the wind turbine works, the wind blades 3 are blown by wind to drive the outer sleeve ring 2 to rotate together, the outer sleeve ring 2 drives the sliding plate 63 to rotate, the sliding plate 63 extends outwards under the action of centrifugal force, a unidirectional rotating mechanism is formed by the pawl 67 and the bevel gear 65, and the sliding plate 63 does not drive the bevel gear 65 to rotate when moving outwards;

when the wind speed becomes smaller or the anemometer stops working, the rotating speed of the fan blade 3 becomes smaller, the centrifugal force borne by the sliding plate 63 becomes smaller, the sliding plate 63 moves inwards under the action of the return spring 64, at this time, the pawl 67 drives the bevel gear 65 and the magnetic block 68 to rotate, the magnetic block 68 contacts with the annular magnetic guide plate 61, the annular magnetic guide plate 61 is magnetized by the magnetic block 68 and has magnetism same as that of one side of the opposite surface of the magnetic ring 69, the lifting rod 51 is pushed to move upwards under the action of the homopolar repulsive force, after the lifting rod 51 moves upwards, the elastic clamping plate 53 is pulled by the push plate 55, the elastic clamping plate 53 is separated from the clamping groove 54, then the brush 42 moves downwards under the pushing of the pressure spring 43, the brush 42 contacts with the fan blade 3 rotating at a low speed, sundries such as dust on the fan blade 3 are scraped off by the brush 42, the function of automatically cleaning the anemometer is achieved, the situation that the rotating speed and the detection result are affected by sundries on the fan blade 3 is effectively avoided, and the reliability of the anemometer is improved.

By arranging a reset torsion spring 66 on the bevel gear 65, after the sliding plate 63 moves inwards to reset, the pawl 67 is staggered with the bevel gear 65, the bevel gear 65 rotates to reset under the action of the reset torsion spring 66, the magnetic block 68 is separated from the annular magnetic conduction plate 61, the annular magnetic conduction plate 61 loses magnetism, the lifting rod 51 moves downwards to reset under the action of the positioning spring 57 and self gravity, and the lifting rod 51 which moves downwards drives the brush 42 to move upwards to reset through the pull rope 52; by arranging the push plate 55 and the elastic clamping plate 53, after the lifting rod 51 moves downwards, the push plate 55 also moves downwards at the same time, so that the elastic clamping plate 53 automatically resets and clamps the brush 42 again, the position stability of the brush 42 is further improved, and the use is safe and reliable; so, the device can be realized after clearing up fan blade 3, accomplish the function that resets voluntarily to continue to use next time, the device uses wind-force as the power supply, carries out automatic clearance through the rotational speed change of fan blade 3 during operation, need not manual operation, automatic operation, simple structure, energy-concerving and environment-protective, convenient to use.

By utilizing the technical scheme of the invention or under the inspired by the technical scheme of the invention, a similar technical scheme is designed by a person skilled in the art, so that the technical effects are achieved, and the technical scheme falls into the protection scope of the invention.

Claims (2)

1. The utility model provides an energy-concerving and environment-protective building engineering anemometer self-cleaning mechanism, includes anemometer body frame (1), its characterized in that: the wind speed indicator comprises a wind speed indicator main frame (1), a casing ring (2) is movably sleeved on the outer side of the wind speed indicator main frame (1), fan blades (3) are arranged on the outer side of the casing ring (2), a cleaning component (4) and a control component (5) are arranged at the top end of the wind speed indicator main frame (1), the control component (5) comprises a lifting rod (51), a pull rope (52), an elastic clamping plate (53) and a push plate (55), and a starting component (6) is arranged on the outer side of the wind speed indicator main frame (1) and above the outer sleeve ring (2);

the cleaning assembly (4) comprises a guide seat (41) fixedly arranged at the top end of the anemometer main frame (1), a brush (42) which slides up and down is movably arranged in the guide seat (41), and a pressure spring (43) is arranged at the top of the brush (42);

lifting rod (51) activity grafting is in the inside of anemograph body frame (1), the top of lifting rod (51) is connected with brush (42) through stay cord (52), flexible clamping plate (53) that block brush (42) are pegged graft to the activity on guide bracket (41), be provided with draw-in groove (54) that correspond with flexible clamping plate (53) on brush (42), the one end that flexible clamping plate (53) is close to lifting rod (51) extends to the outside of guide bracket (41), the outside fixedly connected with push pedal (55) that run through flexible clamping plate (53) of lifting rod (51), through-hole (56) that correspond with push pedal (55) are seted up to the inside of flexible clamping plate (53), be provided with the slope section on push pedal (55), and the bottom of slope section is provided with straight flange section, install positioning spring (57) on lifting rod (51).

2. The energy-saving and environment-friendly self-cleaning mechanism for the building engineering anemometer according to claim 1, wherein the self-cleaning mechanism is characterized in that: the starting assembly (6) comprises an annular magnetic guide plate (61) fixedly mounted on an anemometer main frame (1), a fixing seat (62) which is uniformly distributed is fixedly connected to the top of an outer sleeve (2), a sliding plate (63) is movably inserted into the fixing seat (62), a reset spring (64) is arranged on the sliding plate (63), a supporting frame (651) is fixedly connected between the outer side of the anemometer main frame (1) and the fixing seat (62) and the annular magnetic guide plate (61), a bevel gear (65) which is uniformly distributed is rotatably mounted on the supporting frame (651), a reset torsion spring (66) is arranged on the bevel gear (65), a pawl (67) which is meshed with the bevel gear (65) is arranged on the sliding plate (63), a magnetic block (68) which extends to the inner portion of the annular magnetic guide plate (61) is fixedly connected to the bevel gear (65), a gap is reserved between the magnetic block (68) and the annular magnetic guide plate (61), and a magnetic ring (69) is fixedly sleeved on the outer side of the lifting rod (51) and the upper portion of the annular magnetic guide plate (61).

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