CN112165756A - Dust protected electronic component static remove device - Google Patents

Abstract

The invention relates to the static electricity related field, and discloses a dustproof electronic component static electricity removing device, which comprises a main box body, wherein a feeding cavity is arranged in the main box body in a left-right through way, the upper side of the feeding cavity is communicated with a ventilation cavity, the upper side of the feeding cavity is communicated with a probe seat cavity, the lower side of the feeding cavity is communicated with a conveyor belt cavity, a wheel shaft conveyor belt cavity is arranged at the rear side of the conveyor belt cavity, the static electricity on an electronic component is pre-treated by utilizing the point discharge effect of a probe, ionized air is blown to the electronic component by a fan to neutralize the static electricity on the surface of the electronic component, the device automatically filters charged dust in the air at the same time, the cleanliness of the ionized air is ensured, the static electricity removing effect on the electronic component is greatly improved, and meanwhile, the fan is automatically switched according to the position of the electronic component on the conveyor belt, so that the electronic component, thereby affecting the use of the electronic component.

Description

Dust protected electronic component static remove device

Technical Field

The invention relates to the static electricity related field, in particular to a dust-proof static electricity removing device for an electronic component.

Background

The static electricity is a static charge, in the production process of electronic elements, if the electronic elements accumulate excessive static electricity, the integrated circuit and precise electronic elements can be punctured, the elements are aged, meanwhile, the electrostatic attraction adsorbs dust, the pollution to the integrated circuit and semiconductor elements is caused, and the yield is greatly reduced.

Disclosure of Invention

The invention aims to provide a dust-proof electronic component static electricity removing device which can overcome the defects in the prior art, so that the practicability of equipment is improved.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention discloses a dust-proof electronic component static electricity removing device, which comprises a main box body, wherein a feeding cavity is arranged in the main box body in a left-right through way, the upper side of the feeding cavity is communicated with a ventilation cavity, the upper side of the feeding cavity is communicated with a probe seat cavity, the lower side of the feeding cavity is communicated with a conveyer belt cavity, the rear side of the conveyer belt cavity is provided with a wheel shaft conveyer belt cavity, the front side of the wheel shaft conveyer belt cavity is provided with a left bevel gear cavity positioned at the upper side of the feeding cavity, the front end wall of the conveyer belt cavity is rotationally and fittingly connected with a conveyer belt shaft which is bilaterally symmetrical and extends backwards to the rear end wall of the conveyer belt cavity, the left conveyer belt shaft extends backwards to penetrate through the conveyer belt cavity to the wheel shaft conveyer belt cavity, the conveyer belt shaft is fixedly connected with a conveyer belt wheel positioned in the conveyer belt cavity, and a conveyer, the rear end of the transmission belt shaft is fixedly connected with a wheel shaft driven belt wheel, the rear end wall of the left bevel gear cavity is connected with a driven bevel gear shaft which extends backwards into the wheel shaft transmission belt cavity and extends forwards into the left bevel gear cavity in a rotating fit manner, the rear end of the driven bevel gear shaft is fixedly connected with a wheel shaft driving belt, the front end of the driven bevel gear shaft is fixedly connected with a left driven bevel gear, the wheel shaft driving belt and the wheel shaft driven belt wheel are connected with a wheel shaft transmission belt in a power fit manner, a probe pin is fixedly connected between the front end wall and the rear end wall of the probe seat cavity, the probe pin is connected with a probe seat in a rotating fit manner, the lower end surface of the probe seat is fixedly connected with a probe, the left end surface of the probe seat and the left end wall of the probe seat cavity are, the dust collecting device is characterized in that a collecting box sliding cavity is communicated with the right side of the ventilating cavity, a dust collecting box is connected in the collecting box sliding cavity in a sliding fit mode, and a dust collecting cavity with an upward opening is arranged in the dust collecting box.

On the basis of the technical scheme, a collecting box magnet is fixedly connected to the right end surface of the dust collecting box, a collecting box electromagnet is fixedly connected to the right end wall of the collecting box sliding cavity, a collecting box spring is fixedly connected between the collecting box magnet and the collecting box electromagnet, the left end wall and the right end wall of the ventilating cavity are both fixedly connected with ionization generators which are bilaterally symmetrical by taking the ventilating cavity as a center, the left side of the ventilating cavity is communicated with a top block sliding cavity, a top block corresponding to the dust collecting box is connected in the top block sliding cavity in a sliding fit manner, a filter screen spring is fixedly connected between the left end surface of the top block and the left end wall of the top block sliding cavity, a filter screen pull rope is fixedly connected to the left end surface of the top block, a fan seat is fixedly connected to the left end wall of the ventilating cavity, and, the inner wall of the lower end of the fan transmission cavity is connected with a probe pin which extends downwards into the ventilation cavity and extends upwards into the fan transmission cavity in a matched mode, the tail end of the lower side of the probe pin is fixedly connected with a fan, and the tail end of the upper side of the fan shaft is fixedly connected with a fan belt wheel.

On the basis of the technical scheme, a right bevel gear cavity is arranged on the lower side of the fan transmission cavity, a motor fixedly connected with the main box body is arranged on the lower side of the right bevel gear cavity, the upper end face of the motor is fixedly connected with a motor shaft which extends upwards and penetrates through the right bevel gear cavity to the fan transmission cavity, the tail end of the upper side of the motor shaft is fixedly connected with a motor belt wheel, a fan belt is connected between the motor belt wheel and the fan belt wheel in a power fit manner, a tension wheel cavity is communicated with the upper side of the fan transmission cavity, a tension wheel shaft which extends downwards and penetrates through the tension wheel cavity and the fan transmission cavity to the lower end wall of the fan transmission cavity is fixedly connected in the upper end wall of the tension wheel cavity, a tension wheel shaft sleeve is connected on the tension wheel shaft in a spline fit manner, a tension wheel is connected on the tension wheel shaft sleeve in a rotating, the probe stay cord other end with tensioning wheel axle sleeve up end fixed connection, the ventilation chamber left and right sides all communicates the filter screen chamber that is equipped with bilateral symmetry, the filter screen chamber is located collecting box slip chamber upside, left side filter screen chamber left side intercommunication is equipped with vibrations board chamber, vibrations board chamber downside intercommunication is equipped with the eccentric wheel chamber.

On the basis of the technical scheme, the filter screen cavity is connected with a filter screen which runs through the ventilation cavity in a sliding fit manner, the left end face of the filter screen is fixedly connected with a vibration plate which is connected with the vibration plate cavity in a sliding fit manner, a filter screen spring is fixedly connected between the upper end face of the filter screen and the upper end wall of the filter screen cavity, the left side of the eccentric wheel cavity is provided with an end face tooth cavity, the left side of the end face tooth cavity is provided with a belt wheel transmission cavity, the left end wall of the eccentric wheel cavity is connected with an eccentric shaft which extends leftwards into the end face tooth cavity and rightwards into the eccentric wheel cavity in an offset manner, the right end of the eccentric shaft is fixedly connected with an eccentric wheel which can be abutted against the vibration plate, the left end of the eccentric shaft is fixedly connected with an end face tooth, the left end wall of the end, the terminal fixedly connected with driven pulleys in slip terminal surface tooth axle left side, the epaxial spline fit connection of slip terminal surface tooth has and is located the terminal surface tooth axle sleeve of terminal surface tooth intracavity, terminal fixedly connected with in terminal surface tooth axle sleeve right side can with the terminal surface tooth engaged with slip terminal surface tooth axle, terminal normal running fit in terminal surface tooth axle sleeve left side is connected with the axle sleeve seat.

On the basis of the technical scheme, an end face gear shaft through cavity is arranged on the left side and the right side of the shaft sleeve seat in a through mode, the sliding end face gear shaft penetrates through the shaft sleeve seat, an end face gear spring is fixedly connected between the left end face of the shaft sleeve seat and the left end wall of the end face gear cavity, the other end of the filter screen pull rope is fixedly connected with the left end face of the end face gear shaft through cavity, a bevel gear transmission shaft which extends leftwards and penetrates through the belt wheel transmission cavity to the left bevel gear cavity is connected in a rotating fit mode on the left end wall of the right bevel gear cavity, a left driving bevel gear which is meshed with the left driven bevel gear is fixedly connected at the left end of the bevel gear transmission shaft, a driving belt which is positioned in the belt wheel transmission cavity is fixedly connected on the bevel gear transmission shaft, a transmission belt is connected in, and a motor bevel gear meshed with the right driven bevel gear is fixedly connected to the motor shaft.

The invention has the beneficial effects that: the device has the advantages that the tip discharge effect of the probe is utilized, the static electricity on the electronic element is preprocessed, the ionized air is blown to the electronic element by the fan, the static electricity on the surface of the electronic element is neutralized, meanwhile, the device automatically filters charged dust in the air, the cleanliness of the ionized air is guaranteed, the static electricity removing effect on the electronic element is greatly improved, meanwhile, the fan is automatically switched on and off according to the position of the electronic element on the conveyor belt, the situation that too much ionized air is blown to the electronic element to cause too many electrons on the electronic element is avoided, and therefore the use of the influenced electronic element is achieved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of an overall structure of a dust-proof electrostatic remover for electronic components according to the present invention;

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

FIG. 3 is an enlarged schematic view of B of FIG. 1;

FIG. 4 is an enlarged schematic view of C in FIG. 1;

fig. 5 is an enlarged schematic view of D in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, 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.

The dust-proof electrostatic removing device for electronic components, which is described with reference to fig. 1-5, includes a main box 10, a feeding cavity 28 is provided in the main box 10, a ventilation cavity 22 is provided on the feeding cavity 28, a probe seat cavity 27 is provided on the feeding cavity 28, a conveyer cavity 23 is provided on the feeding cavity 28, a wheel axle conveyer cavity 39 is provided on the rear side of the conveyer cavity 23, a left bevel gear cavity 35 is provided on the front side of the wheel axle conveyer cavity 39, a conveyer shaft 26 is provided on the front end wall of the conveyer cavity 23, the conveyer shaft 26 is bilaterally symmetrical and extends backwards into the rear end wall of the conveyer cavity 23, the left conveyer shaft 26 extends backwards through the conveyer cavity 23 into the wheel axle conveyer cavity 39, a conveyer belt 24 is fixedly connected to the conveyer shaft 26 and is located in the conveyer cavity 23, a transmission belt 25 is connected between the left transmission belt wheel 24 and the right transmission belt wheel 24 in a power fit manner, a wheel shaft driven belt wheel 38 is fixedly connected to the rear end of the transmission belt shaft 26, a driven bevel gear shaft 33 which extends backwards into the wheel shaft transmission belt chamber 39 and forwards into the left bevel gear chamber 35 is connected to the rear end of the left bevel gear chamber 35 in a power fit manner, a wheel shaft driving belt 41 is fixedly connected to the rear end of the driven bevel gear shaft 33, a left driven bevel gear 34 is fixedly connected to the front end of the driven bevel gear shaft 33, a wheel shaft transmission belt 40 is connected between the wheel shaft driving belt 41 and the wheel shaft driven belt wheel 38 in a power fit manner, a probe pin 32 is fixedly connected between the front end wall and the rear end wall of the probe seat chamber 27, a probe seat 13 is connected to the probe pin 32 in a power fit manner, and a probe 31 is fixedly, the probe base 13 left end face with fixedly connected with probe spring 12 between the probe base cavity 27 left end wall, probe base 13 right end face fixedly connected with probe stay cord 30, ventilation chamber 22 right side intercommunication is equipped with collecting box sliding chamber 17, sliding fit is connected with dust collecting box 15 in collecting box sliding chamber 17, be equipped with the ascending dust in the dust collecting box 15 and collect chamber 14.

In addition, in one embodiment, a collecting box magnet 16 is fixedly connected to the right end surface of the dust collecting box 15, a collecting box electromagnet 19 is fixedly connected to the right end wall of the collecting box sliding cavity 17, a collecting box spring 18 is fixedly connected between the collecting box magnet 16 and the collecting box electromagnet 19, ionization generators 20 which are bilaterally symmetrical with the ventilating cavity 22 as the center are fixedly connected to both the left and right end walls of the ventilating cavity 22, a top block sliding cavity 45 is communicated with the left side of the ventilating cavity 22, a top block 49 corresponding to the dust collecting box 15 is connected in the top block sliding cavity 45 in a sliding fit manner, a filter screen spring 47 is fixedly connected between the left end surface of the top block 49 and the left end wall of the top block sliding cavity 45, a filter screen pull rope 48 is fixedly connected to the left end surface of the top block 49, a fan base 51 is fixedly connected to the left end wall of the ventilating cavity 22, a fan transmission cavity 55 which extends to, the lower end wall of the fan transmission cavity 55 is connected with a probe pin 32 which extends downwards into the ventilation cavity 22 and extends upwards into the fan transmission cavity 55 in a matched mode, the tail end of the lower side of the probe pin 32 is fixedly connected with a fan 53, and the tail end of the upper side of the fan shaft 52 is fixedly connected with a fan belt wheel 50.

In addition, in one embodiment, a right bevel gear chamber 76 is disposed below the fan transmission chamber 55, a motor 29 fixedly connected to the main housing 10 is disposed below the right bevel gear chamber 76, a motor shaft 74 extending upward through the right bevel gear chamber 76 into the fan transmission chamber 55 is fixedly connected to an upper end surface of the motor 29, a motor pulley 73 is fixedly connected to an upper end of the motor shaft 74, a fan belt 54 is connected between the motor pulley 73 and the fan pulley 50 in a power fit manner, a tension pulley chamber 60 is communicated with an upper end surface of the fan transmission chamber 55, a tension pulley shaft 56 extending downward through the tension pulley chamber 60, the fan transmission chamber 55 into a lower end wall of the fan transmission chamber 55 is fixedly connected to an upper end wall of the tension pulley chamber 60, a tension pulley sleeve 57 is connected to the tension pulley shaft 56 in a spline fit manner, and a tension pulley 58 is rotatably connected to the tension pulley sleeve 57, tensioning wheel axle sleeve 57 up end with fixedly connected with take-up pulley spring 59 between the tensioning wheel chamber 60 up end wall, the probe stay cord 30 other end with tensioning wheel axle sleeve 57 up end fixed connection, the ventilation chamber 22 left and right sides all communicates the filter screen chamber 43 that is equipped with bilateral symmetry, filter screen chamber 43 is located the collecting box slides the chamber 17 upside, the left side filter screen chamber 43 left side intercommunication is equipped with vibrations board chamber 42, vibrations board chamber 42 downside intercommunication is equipped with eccentric wheel chamber 82.

In addition, in one embodiment, a filter screen 46 penetrating through the ventilation cavity 22 is slidably connected in the filter screen cavity 43, a vibration plate 64 slidably connected in the vibration plate cavity 42 is fixedly connected to a left end surface of the filter screen 46, a filter screen spring 44 is fixedly connected between an upper end surface of the filter screen 46 and an upper end wall of the filter screen cavity 43, an end surface tooth cavity 70 is arranged on a left side of the eccentric wheel cavity 82, a pulley transmission cavity 80 is arranged on a left side of the end surface tooth cavity 70, an eccentric wheel shaft 63 extending leftwards into the end surface tooth cavity 70 and rightwards into the eccentric wheel cavity 82 is rotatably connected in the left end wall of the eccentric wheel cavity 82, an eccentric wheel 62 capable of abutting against the vibration plate 64 is fixedly connected to a right end of the eccentric wheel shaft 63, an end surface tooth 71 is fixedly connected to a left end of the eccentric wheel cavity 70, an eccentric wheel shaft extending rightwards into the end surface tooth cavity 70 and leftwards into the pulley transmission cavity 80 is rotatably connected in the left end wall, the terminal fixedly connected with driven pulley 81 in slip terminal surface tooth axle 65 left side, the spline fit connection has the terminal surface tooth axle sleeve 72 that is located in the terminal surface tooth chamber 70 on the slip terminal surface tooth axle 65, the terminal fixedly connected with in terminal surface tooth axle sleeve 72 right side can with the mesh slip terminal surface tooth axle 69 of terminal surface tooth 71, terminal normal running fit in terminal surface tooth axle sleeve 72 left side is connected with axle sleeve seat 83.

In addition, in one embodiment, an end face gear shaft through cavity 68 is formed in the shaft sleeve seat 83 in a left-right penetrating manner, the sliding end face gear shaft 65 penetrates through the shaft sleeve seat 83, an end face gear spring 67 is fixedly connected between the left end face of the shaft sleeve seat 83 and the left end wall of the end face gear cavity 70, the other end of the filter screen pull rope 48 is fixedly connected with the left end face of the end face gear shaft through cavity 68, a bevel gear transmission shaft 11 which extends leftwards and penetrates through the pulley transmission cavity 80 to the left bevel gear cavity 35 is connected in a rotating fit manner in the left end wall of the right bevel gear cavity 76, a left driving bevel gear 36 which is meshed with the left driven bevel gear 34 is fixedly connected at the left end of the bevel gear transmission shaft 11, a driving belt 78 which is located in the pulley transmission cavity 80 is fixedly connected to the bevel gear transmission shaft 11, and a transmission belt 79 is connected between, the right end of the bevel gear transmission shaft 11 is fixedly connected with a right driven bevel gear 77, and the motor shaft 74 is fixedly connected with a motor bevel gear 75 meshed with the right driven bevel gear 77.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1-5, when the apparatus of the present invention is in an initial state, the tension of the probe spring 12 is equal to the tension of the tension wheel spring 59, the probe 31 is in a vertical state, the dust collecting box 15 is located in the collecting box sliding chamber 17, the filter pulling rope 48 is in a tensioned state, the elastic force of the end face tooth spring 67 is greater than the elastic force of the filter spring 47, the sliding end face tooth shaft 69 is not engaged with the end face tooth 71, the tension wheel 58 is located in the tension wheel chamber 60, and the fan belt 54 is in a relaxed state; sequence of mechanical actions of the whole device: at the beginning of operation, the ionization generator 20 is powered on to ionize the air in the ventilation chamber 22, the motor 29 is started to rotate the motor shaft 74, so as to rotate the motor bevel gear 75, so as to rotate the right driven bevel gear 77, so as to rotate the bevel gear transmission shaft 11, so as to rotate the left driving bevel gear 36, so as to rotate the left driven bevel gear 34, so as to rotate the driven bevel gear shaft 33, so as to rotate the wheel shaft driving belt 41, so as to rotate the wheel shaft driven belt wheel 38 through the wheel shaft transmission belt 40, so as to rotate the left transmission belt shaft 26, so as to rotate the left transmission belt wheel 24, so as to rotate the transmission belt 25, so as to drive the electronic component on the upper side of the transmission belt 25 to move to the right, when the electronic component touches the probe 31, the probe 31 with the tip takes away a part of static electricity in advance, thereby making the upper side of the probe seat 13 move leftwards, thereby making the probe spring 12 compress, pulling the probe pulling rope 30, making the tensioning wheel shaft sleeve 57 move downwards against the pulling force of the tensioning wheel spring 59, thereby driving the tensioning wheel 58 to move downwards into the fan transmission cavity 55, the diameter of the tensioning wheel 58 is larger than the diameters of the fan belt wheel 50 and the motor belt wheel 73, thereby making the tensioning wheel 58 support the fan belt 54, making the motor shaft 74 rotate to drive the motor belt wheel 73 to rotate, thereby driving the fan belt wheel 50 to rotate through the fan belt 54, thereby making the fan shaft 52 rotate, thereby driving the fan 53 to rotate, thereby generating a downward wind force, thereby making the ionized air in the ventilation cavity 22 to be blown to the surface of the electronic component, thereby neutralizing the surface static electricity of the electronic component, when the electronic component moves to the left side of the probe pin 32, the probe 31 returns to be vertical, waiting for the next electronic component to touch the probe 31; the outside air enters the ventilation cavity 22 through the filter screen 46, the filter screen 46 is electrified to attract charged dust in the air, so that the charged dust is prevented from being adsorbed on the surface of an electronic element, when the dust in the filter screen 46 needs to be cleaned, the collection box electromagnet 19 is electrified to repel the collection box magnet 16 to move leftwards against the collection box spring 18, so that the dust collection box 15 is driven to move leftwards to touch the top block 49, so that the top block 49 moves leftwards to the top block sliding cavity 45, so that the filter screen pull rope 48 is loosened, the filter screen spring 47 is in a compressed state, the filter screen pull rope 48 is loosened, so that the shaft sleeve seat 83 moves rightwards under the action of the elastic force of the end face tooth spring 67, so that the end face tooth shaft sleeve 72 is driven to move rightwards, so that the sliding end face tooth shaft 69 moves rightwards to be meshed with the end face teeth, the driven belt pulley 81 is driven to rotate by the driving belt 79, so that the sliding end face gear shaft 65 rotates, so that the sliding end face gear shaft sleeve 72 rotates, so that the sliding end face gear shaft 69 rotates, so that the end face gear 71 rotates, so that the eccentric wheel shaft 63 rotates, so that the eccentric wheel 62 rotates, so that the vibration plate 64 reciprocates up and down, the filter screen 46 is driven to reciprocate up and down under the elastic force of the filter screen spring 44, so that dust in the filter screen 46 is vibrated and dropped into the dust collection cavity 14, when the dust in the filter screen 46 is cleaned up, the collection box electromagnet 19 is de-energized, the collection box magnet 16 moves rightwards under the tensile force of the collection box spring 18, so that the dust collection box 15 is driven to move rightwards into the collection box sliding cavity 17, because the elastic force of the filter screen pull rope 48 is larger than that of the end face gear spring 67, the de-energized top block 49 moves right, the screen pull cord 48 is pulled so that the sliding end gear shaft 69 disengages from the end gear 71 and the screen 46 stops vibrating.

The invention has the beneficial effects that: the device has the advantages that the tip discharge effect of the probe is utilized, the static electricity on the electronic element is preprocessed, the ionized air is blown to the electronic element by the fan, the static electricity on the surface of the electronic element is neutralized, meanwhile, the device automatically filters charged dust in the air, the cleanliness of the ionized air is guaranteed, the static electricity removing effect on the electronic element is greatly improved, meanwhile, the fan is automatically switched on and off according to the position of the electronic element on the conveyor belt, the situation that too much ionized air is blown to the electronic element to cause too many electrons on the electronic element is avoided, and therefore the use of the influenced electronic element is achieved.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides a dust protected electronic component static remove device, includes the main tank body, its characterized in that: a feeding cavity is arranged in the main box body in a left-right through mode, a ventilation cavity is arranged on the upper side of the feeding cavity in a communicated mode, a probe seat cavity is arranged on the upper side of the feeding cavity in a communicated mode, a conveyor belt cavity is arranged on the lower side of the feeding cavity in a communicated mode, a wheel shaft transmission belt cavity is arranged on the rear side of the conveyor belt cavity, a left bevel gear cavity located on the upper side of the feeding cavity is arranged on the front side of the wheel shaft transmission belt cavity, a conveying belt shaft which is bilaterally symmetrical and extends backwards into the rear end wall of the conveyor belt cavity is connected to the front end wall of the conveyor belt cavity in a rotating and matching mode, the conveying belt shaft on the left side extends backwards to penetrate through the conveyor belt cavity to the wheel shaft transmission belt cavity, a conveying belt wheel located in the conveyor belt cavity is fixedly connected to the conveying belt shaft, a conveying belt wheel is, the rear end wall of the left bevel gear cavity is connected with a driven bevel gear shaft which extends backwards into the wheel shaft transmission belt cavity in a rotating fit manner and extends forwards into the left bevel gear cavity, the rear end of the driven bevel gear shaft is fixedly connected with a wheel shaft driving belt, the front end of the driven bevel gear shaft is fixedly connected with a left driven bevel gear, the wheel shaft driving belt and the wheel shaft driven belt are connected with a wheel shaft transmission belt in a power fit manner, a probe pin is fixedly connected between the front end wall and the rear end wall of the probe seat cavity, the probe pin is connected with a probe seat in a rotating fit manner, the lower end surface of the probe seat is fixedly connected with a probe, a probe spring is fixedly connected between the left end surface of the probe seat and the left end wall of the probe seat cavity, the right end surface of the probe seat is fixedly connected with a probe pull rope, the right side, the dust collecting box is internally provided with a dust collecting cavity with an upward opening.

2. The electrostatic removing apparatus for dust-protected electronic component of claim 1, wherein: dust collecting box right-hand member face fixedly connected with collecting box magnet, fixedly connected with collecting box electro-magnet on the collecting box slip chamber right-hand member wall, collecting box magnet with fixedly connected with collecting box spring between the collecting box electro-magnet, the equal fixedly connected with in end wall uses about the chamber of ventilating the ionization generator of chamber for central bilateral symmetry about ventilating, the chamber left side intercommunication of ventilating is equipped with kicking block slip chamber, kicking block slip intracavity sliding fit be connected with the kicking block that the dust collecting box corresponds, kicking block left end face with fixedly connected with filter screen spring between the chamber left end wall of kicking block slip, kicking block left end face fixedly connected with filter screen stay cord, fixedly connected with fan seat on the chamber left end wall of ventilating, be equipped with in the chamber left end wall of ventilating and extend to right fan transmission chamber in the fan seat, fan transmission chamber lower extreme wall normal running fit is connected with and extends to down the ventilation intracavity upwards extend to The probe pin in the cavity, the terminal fixedly connected with fan of probe pin downside, fan epaxial side terminal fixedly connected with fan band pulley.

3. The electrostatic removing apparatus for dust-protected electronic component of claim 2, wherein: a right bevel gear cavity is arranged on the lower side of the fan transmission cavity, a motor fixedly connected with the main box body is arranged on the lower side of the right bevel gear cavity, a motor shaft which extends upwards and penetrates through the right bevel gear cavity to the fan transmission cavity is fixedly connected with the upper end face of the motor, a motor belt wheel is fixedly connected with the tail end of the upper side of the motor shaft, a fan belt is connected between the motor belt wheel and the fan belt wheel in a power fit manner, a tension pulley cavity is communicated with the upper side of the fan transmission cavity, a tension pulley shaft which extends downwards and penetrates through the tension pulley cavity and the fan transmission cavity to the lower end wall of the fan transmission cavity is fixedly connected in the upper end wall of the tension pulley cavity, a tension pulley shaft sleeve is connected on the tension pulley shaft in a spline fit manner, a tension pulley is connected on the tension pulley shaft sleeve in a rotating fit, the probe stay cord other end with tensioning wheel axle sleeve up end fixed connection, the ventilation chamber left and right sides all communicates the filter screen chamber that is equipped with bilateral symmetry, the filter screen chamber is located collecting box slip chamber upside, left side filter screen chamber left side intercommunication is equipped with vibrations board chamber, vibrations board chamber downside intercommunication is equipped with the eccentric wheel chamber.

4. The device for removing static electricity from electronic components of claim 3, wherein: the filter screen cavity is connected with a filter screen penetrating through the ventilation cavity in a sliding fit manner, the left end face of the filter screen is fixedly connected with a vibration plate connected with the vibration plate cavity in a sliding fit manner, a filter screen spring is fixedly connected between the upper end face of the filter screen and the upper end wall of the filter screen cavity, the left side of the eccentric wheel cavity is provided with an end face tooth cavity, the left side of the end face tooth cavity is provided with a belt wheel transmission cavity, the left end wall of the eccentric wheel cavity is connected with an eccentric shaft which extends leftwards into the end face tooth cavity and rightwards extends into the eccentric wheel cavity, the right end of the eccentric shaft is fixedly connected with an eccentric wheel which can be abutted against the vibration plate, the left end of the eccentric shaft is fixedly connected with an end face tooth, the left end wall of the end face tooth cavity is connected with a driven belt wheel which extends rightwards into the end face tooth, the sliding end face tooth shaft is connected with an end face tooth shaft sleeve in a spline fit mode, the end face tooth shaft sleeve is located in the end face tooth cavity, the end face tooth shaft sleeve right side end fixedly connected with can be connected with the sliding end face tooth shaft meshed with the end face teeth, and the end face tooth shaft sleeve left side end is connected with a shaft sleeve seat in a rotating fit mode.

5. The device for removing static electricity from electronic components of claim 4, wherein: the left and the right of the shaft sleeve seat are provided with end face gear shaft through cavities in a through way, the sliding end face gear shaft penetrates through the shaft sleeve seat, an end face tooth spring is fixedly connected between the left end face of the shaft sleeve seat and the left end wall of the end face tooth cavity, the other end of the filter screen pull rope is fixedly connected with the left end face of the end face gear shaft through cavity, the left end wall of the right bevel gear cavity is rotationally connected with a bevel gear transmission shaft which extends leftwards and penetrates through the belt wheel transmission cavity to the left bevel gear cavity in a matching way, the left end of the bevel gear transmission shaft is fixedly connected with a left driving bevel gear meshed with the left driven bevel gear, a driving belt positioned in the belt wheel transmission cavity is fixedly connected to the bevel gear transmission shaft, a transmission belt is connected between the driving belt and the driven belt wheel in a power fit manner, the right end of the bevel gear transmission shaft is fixedly connected with a right driven bevel gear, and a motor shaft is fixedly connected with a motor bevel gear meshed with the right driven bevel gear.

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