CN112892806B

CN112892806B - Environment-friendly recovery processing method

Info

Publication number: CN112892806B
Application number: CN202110058834.8A
Authority: CN
Inventors: 张荣芳; 张涛
Original assignee: Anhui Huayu Property Development Co ltd
Current assignee: Anhui Huayu Property Development Co ltd
Priority date: 2021-01-17
Filing date: 2021-01-17
Publication date: 2022-11-15
Anticipated expiration: 2041-01-17
Also published as: CN112892806A

Abstract

The invention discloses an environment-friendly recovery processing method, which comprises the following steps: the waste energy-saving lamp tube is placed into the recycling cavity, and the energy-saving lamp tube falls downwards into the guide cavity; the main motor is started, the main motor drives the vibrating plate to move up and down so as to drive the vibrating box to vibrate, the energy-saving lamp tube in the guide cavity is vibrated to break through the vibration of the vibrating box so as to flow out the mercury liquid in the energy-saving lamp tube, and the main motor synchronously drives the fan to rotate so as to generate wind power downwards, so that the mercury liquid is blown downwards and penetrates through the filter plate so as to flow into the water cavity; after mercury liquid collection finishes, shovel the energy-saving lamp tube piece of filter up end through the scraper bowl and go into the collection intracavity, can clear up the energy-saving lamp tube piece of collecting the intracavity through the intercommunication chamber this moment, less energy-saving lamp tube piece can drop to the water intracavity downwards when vibrations of vibrations case to fall on the separator up end. The energy-saving lamp tube shatters the energy-saving lamp tube through violent vibration, and mercury liquid in the energy-saving lamp tube flows out.

Description

Environment-friendly recovery processing method

Technical Field

The invention relates to the technical field of environmental protection, in particular to an environmental protection recovery processing method.

Background

The energy-saving lamp, as a very environment-friendly lamp, has replaced the status of incandescent lamps, and has become a tool which is provided by each household at present, but a large number of energy-saving lamps are difficult to recover, because the mercury liquid sealed in the energy-saving lamps has better recovery significance, but is difficult to separate, the existing energy-saving lamp tube recovery processing methods are difficult to separate the lamp tube and the mercury liquid well, and the better sealing property is difficult to ensure in the separation process, the volatility of the mercury liquid per se is often ignored, the functionality is poor, and the recovery requirement is difficult to meet.

Disclosure of Invention

The invention aims to solve the technical problem of providing an environment-friendly recovery processing method aiming at the defects in the prior art.

According to the invention, the environment-friendly recovery processing method comprises the following steps:

the waste energy-saving lamp tube is placed into the recycling cavity, and the energy-saving lamp tube falls downwards into the guide cavity;

the main motor is started to drive the fan shaft to rotate, the centrifugal wheel is driven to rotate through the rotation of the fan shaft, the centrifugal blocks on the left side and the right side are driven to stretch out to one side far away from the fan shaft through the rotation of the centrifugal wheel, so that the sealing plate is pushed to move leftwards through the tension of the connecting spring, when the sealing plate moves to a left limit position to seal the feeding cavity, the sealing blocks stretch into the sealing cavity to improve the sealing property, the fan shaft rotates to drive the middle belt wheel to rotate, the belt wheels on the left side and the right side are driven to rotate through the transmission of the belt, the driving bevel gears on the left side and the right side are driven to rotate through the meshing transmission, the cam shafts on the left side and the right side are driven to rotate, the cam is driven to rotate, the push plate is driven to move upwards and downwards through the connection of the push plate spring, the vibration plate is driven to move upwards and downwards, so that the vibration box is driven, the energy-saving lamp tubes in the guide cavity are vibrated to shake, so that the mercury liquid flows out of the wind power mercury in the filter plate, and the main motor synchronously drives the fan to rotate downwards;

after mercury liquid is collected, the left and right screw motors are started to drive the left and right movable screws to rotate, the left and right collecting boxes are driven to move towards one side direction close to each other through threaded connection through rotation of the left and right movable screws, the left and right closed doors are pushed to overcome torsional spring force of a reset torsional spring to turn upwards and open, the left and right collecting boxes are driven to move into the guide cavity, energy-saving lamp tube fragments on the upper end face of the filter plate are shoveled into the collecting cavity through the scraper buckets, the left and right scraper buckets can be driven to overcome torsional spring force of the closed torsional spring to turn upwards after being contacted with the left and right end faces of the guide block, distances between the magnetic blocks and the magnets are close to each other to adsorb each other, the left and right screw motors are driven to turn backwards, the left and right collecting boxes are driven to move back into the screw cavities, the closed collecting cavities are driven, the energy-saving lamp tube fragments in the collecting cavities can be cleaned through the communicating cavities at the moment, small energy-saving lamp tube fragments in the vibrating boxes can possibly fall into water cavities downwards while vibrating boxes, and fall onto the upper end faces of the separating plates.

Further, the method also comprises the following steps: if the smaller fragments of the energy-saving lamp tube fall into the water cavity downwards, the lifting motor is started to enable the separation plate to ascend and incline, and the fragments of the energy-saving lamp tube on the upper end face of the separation plate are collected rightwards.

Further, the starting of the lifting motor to lift and incline the separation plate specifically includes: the lifting motor is started, so that the water tank screw rod is driven to vibrate, the water tank screw rod is rotated to drive the connecting plate to move upwards through threaded connection, the hinged plate is driven to move upwards, the upward movement of the hinged plate drives the left end of the separating plate to upwards overturn through hinging, and the energy-saving lamp tube fragments on the upper end surface of the separating plate roll rightwards at the moment.

Further, the hinged plate continues to move upwards, so that the movable block is driven to move upwards through the connection of the separating plate, and the movable block stops after contacting with the limiting block, so that the inclination angle of the separating plate is further increased.

According to the invention, after the recovery cavity is well sealed, the energy-saving lamp tube is shattered through violent vibration, the mercury liquid in the energy-saving lamp tube flows out, and the fan can be synchronously driven to rotate while vibrating, so that the mercury liquid is quickly blown downwards into the water tank to be separated, the volatilization time of the mercury liquid is shortened, the fragments in the water tank can be collected, and the cleaning difficulty is well reduced.

Drawings

A more complete understanding of the present invention, and the attendant advantages and features thereof, will be more readily understood by reference to the following detailed description when considered in conjunction with the accompanying drawings wherein:

fig. 1 is a schematic structural view of the present invention.

Fig. 2 is an enlarged schematic view of a in fig. 1.

Fig. 3 is an enlarged schematic view of B in 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.

Fig. 6 is an enlarged schematic view of E in fig. 5.

It should be noted that the appended drawings illustrate rather than limit the invention. It is noted that the drawings representing structures may not be drawn to scale. Also, in the drawings, the same or similar elements are denoted by the same or similar reference numerals.

Detailed Description

In order that the present disclosure may be more clearly and readily understood, reference will now be made in detail to the present disclosure as illustrated in the accompanying drawings.

As shown in fig. 1 to 6, the environmental protection recycling device of this embodiment includes a mercury liquid recycling tank 11, a recycling chamber 20 is provided in the mercury liquid recycling tank 11, an upper wall of the recycling chamber 20 is communicated with a feeding chamber 18 with an upward opening, an upper side of the recycling chamber 20 is provided with a centrifugal wheel chamber 12 located at a right side of the feeding chamber 18, a left side of the feeding chamber 18 is provided with a pulley chamber 19, lower walls of the pulley chamber 19 and the centrifugal wheel chamber 12 are both communicated with bevel gear chambers 14 symmetrically located at left and right sides of the recycling chamber 20, upper walls of the pulley chamber 19 and the centrifugal wheel chamber 12 are both rotatably connected with a pulley shaft 13 extending downward into the bevel gear chamber 14, the centrifugal wheel cavity 12 is rotatably connected with a fan shaft 38 positioned on the left side of the right belt wheel shaft 13, the fan shaft 38 extends downwards and extends upwards to the upper end face of the mercury liquid recovery box 11, the outer circular face of one side of the fan shaft 38 positioned in the centrifugal wheel cavity 12 is fixedly connected with a centrifugal wheel 34, the upper end face of the mercury liquid recovery box 11 is fixedly provided with a main motor 16, the lower end face of the main motor 16 is in power connection with the upper end face of the fan shaft 38, the outer circular face of the fan shaft 38 positioned on the upper side of the centrifugal wheel 34 and the top ends of the outer circular faces of the left and right belt wheel shafts 13 are fixedly connected with belt wheels 15, and belts 17 bypassing the feeding cavity 18 from the front side and the rear side are wound on the outer circular faces of the three belt wheels 15.

Centrifugal spring cavities 36 with openings towards the left side and the right side are arranged in the centrifugal wheel 34, a sliding cavity 41 is communicated between the left wall of the centrifugal wheel cavity 12 and the right wall of the feeding cavity 18, centrifugal blocks 35 are connected to the front wall and the rear wall of the centrifugal spring cavities 36 on the left side and the right side in a left-right sliding mode, centrifugal springs 37 are fixedly connected between one side end face, close to the centrifugal blocks 35 on the left side, and one side wall, close to the centrifugal spring cavities 36 on the left side, of the centrifugal wheel cavity 12, a fixing block 39, located on the left side of the centrifugal wheel 34, is fixedly connected to the upper wall and the lower wall of the sliding cavity 41, a sealing plate 42 capable of sealing the feeding cavity 18 is connected in a left-right sliding mode, a connecting spring 40 is fixedly connected between the right end face of the sealing plate 42 and the left end face of the fixing block 39, a sealing cavity 43 with an opening towards the left side is arranged in the sealing plate 42, and a sealing block 71 capable of extending into the sealing cavity 43 is fixedly connected to the left wall of the feeding cavity 18.

The upper wall of the recovery cavity 20 is fixedly connected with a fan cover 31, a fan cavity 33 is arranged in the fan cover 31, and a fan shaft 38 extends downwards into the fan cavity 33 and is fixedly connected with a fan 32 on the outer circular surface of one side in the fan cavity 33. The left wall and the right wall of the recycling cavity 20 are communicated with vibration cavities 44 which are bilaterally symmetrical, the front wall and the rear wall of each of the left vibration cavity 44 and the right vibration cavity 44 are vertically and slidably connected with vibration plates 50, one end face of each of the left vibration plate 50 and the right vibration plate 50 which are close to each other is fixedly connected with a vibration box 26 which is vertically and slidably connected with the front wall and the rear wall of the recycling cavity 20, the bottom ends of the outer circular surfaces of the left belt wheel shaft 13 and the right belt wheel shaft 13 are fixedly connected with a drive bevel gear 21, one side wall of each of the left bevel gear cavity 14 and the right bevel gear cavity 14 which are close to each other is rotatably connected with a cam shaft 23 extending into the vibration cavity 44 towards one side, one outer circular surface of each of the left cam shaft 23 and the right cam cavity 14 is fixedly connected with a driven bevel gear 22 which is meshed with the drive bevel gear 21, one side outer circular surface of each cam shaft 23 which is located in the vibration cavity 44 is fixedly connected with a cam 47, the front wall and rear wall of the vibration cavity 44 are vertically and slidably connected with a push plate 48 which is located between the vibration plates 50 and the cam 47, and a push plate 49 is fixedly connected between the upper end face of the left push plate 48 and the lower end face of the left and the right vibration plate 50. The vibration box 26 is internally provided with a guide cavity 27 with an upward opening, the lower side of the guide cavity 27 is communicated with a filter plate cavity 28 with a downward opening, the left wall and the right wall of the filter plate cavity 28 are communicated with symmetrical screw cavities 58, the lower wall of the left screw cavity 58 and the lower wall of the right screw cavity 58 are connected with collecting boxes 61 capable of extending into the filter plate cavity 28 in a left-right sliding mode, the collecting boxes 61 on the left side and the right side are internally provided with collecting cavities 62 with upward openings and one sides close to each other, the left wall and the right wall of the filter plate cavity 28 are fixedly connected with filter plates 30 in a left-right sliding mode, the upper end face of each filter plate 30 is fixedly connected with a guide block 29, one side of each left screw cavity 58 far away from each other is fixedly provided with a screw motor 59, the left side collecting boxes 61 are internally provided with internal thread cavities 66 located on the lower sides of the collecting cavities 62 and open to one sides far away from each other, one side of the collecting boxes 61 is connected with a movable screw 60 extending into the internal thread cavity 66 and in a manner towards one side of the collecting box 61, the bottom end face of each side close to the collecting box 61 is hinged with a bucket 64, the left side end face of the collecting box cavity 64 hinged with a closed door 72, the left side and right side hinged with a closed door 72 connected with a closed screw cavity 72, the left side hinged door 72 connected with a closed screw cavity 58, the left side hinged door 72 capable of the left side and right side hinged with a closed door 72 connected with a closed door.

The lower wall of the recovery cavity 20 is fixedly connected with a water tank 24, a water cavity 25 with an upward opening is arranged in the water tank 24, and the left end of the upper end surface of the water tank 24 is rotatably connected with a water tank screw 53. Lifting motor 52 is fixedly arranged at the left end of the upper end face of water tank 24, power connection is carried out between the upper end face of lifting motor 52 and the lower end face of water tank screw 53, connecting plate 54 is in threaded connection with the outer circular face of water tank screw 53, hinged plate 55 which is in sliding connection with the left wall of water chamber 25 in the vertical direction is fixedly connected to the lower end face of connecting plate 54, separating plate 51 is hinged to the right end face of hinged plate 55, moving block 56 which is in sliding connection with the right wall of water chamber 25 in the vertical direction is hinged to the right end face of separating plate 51, base plate 57 which is located on the lower side of moving block 56 is fixedly connected to the right wall of water chamber 25, and limiting block 70 which is located on the upper side of moving block 56 is fixedly connected to the right wall of water chamber 25.

In the initial state: the connecting spring 40 is in a relaxed state, so that the closing plate 42 is pulled to a right limit position, the centrifugal spring 37 is in a relaxed state, so that the centrifugal block 35 is pulled to be positioned in the centrifugal spring cavity 36 and not to be extended, the push plate spring 49 is in a relaxed state, the closing torsion spring 67 is in a relaxed state, the reset torsion spring 65 is in a relaxed state, so that the closing door 72 is driven to close the screw rod cavity 58, and water is placed in the water cavity 25.

The environmental protection recycling method of the embodiment comprises the following steps: when the energy-saving lamp tube feeding device works, a waste energy-saving lamp tube is placed into the recovery cavity 20, the energy-saving lamp tube falls downwards into the guide cavity 27, the main motor 16 is started to drive the fan shaft 38 to rotate, the centrifugal wheel 34 is driven to rotate through the rotation of the fan shaft 38, the left and right centrifugal blocks 35 are driven to extend out to the side far away from the fan shaft 38 through the rotation of the centrifugal wheel 34 to overcome the pulling force of the centrifugal spring 37, so that the sealing plate 42 is pushed to move leftwards through the pulling force of the connecting spring 40, when the sealing plate 42 moves to the left limit position to seal the feeding cavity 18, the sealing block 71 extends into the sealing cavity 43 to improve the sealing performance, the middle belt wheel 15 is driven to rotate through the rotation of the fan shaft 38, the left and right belt wheels 15 are driven to rotate through the transmission of the belt 17, the left and right belt wheel shafts 13 are driven to rotate, and the left and right driving bevel gear 21 is driven to rotate through the rotation of the left and right belt wheel shafts 13, thereby driving the left and right driven bevel gears 22 to rotate through the meshing transmission, thereby driving the left and right cam shafts 23 to rotate, thereby driving the cam 47 to rotate, thereby pushing the push plate 48 to move up and down through the rotation of the cam 47, thereby driving the vibration plate 50 to move up and down through the connection of the push plate spring 49, thereby driving the vibration box 26 to generate vibration, thereby shattering the energy-saving lamp tube in the guide cavity 27 through the vibration of the vibration box 26 to flow out the mercury liquid inside, at this time, driving the fan 32 to rotate through the rotation of the fan shaft 38 to generate wind power downward, thereby blowing the mercury liquid downward and passing through the filter plate 30 to flow into the water cavity 25, after the mercury liquid is collected, starting the left and right screw motors 59 to drive the left and right moving screws 60 to rotate, thereby driving the left and right collecting boxes 61 to move to a direction close to each other through the screw connection through the rotation of the left and right moving screws 60, thereby push left and right sides closing door 72 and overcome the torsional spring power of reset torsion spring 65 and turn over and open upwards, thereby drive left and right sides collecting box 61 to move to guide chamber 27 and shovel the energy-saving lamp tube piece of the upper end surface of filter plate 30 into collecting chamber 62 through bucket 64, can drive left and right sides bucket 64 to overcome the torsional spring power of closed torsion spring 67 and turn over upwards after left and right sides bucket 64 contacts with the left and right sides end surface of guide block 29, the distance of magnet 69 and magnet 68 is close to and therefore adsorbs each other at this moment, it drives the reversal of movable screw 60 through hinged plate motor 59, thereby drive left and right sides collecting box 61 to move back to screw chamber 58, thereby drive closing door 72 in vertical state, thereby will collect chamber 62 and seal, at this moment, can clear up the energy-saving lamp tube piece in collecting chamber 62 through hinged plate chamber 63, the vibration of hinged plate box 26 is smaller energy-saving lamp tube piece can drop down to water chamber 25, thereby fall on the upper end surface of separation plate 51, at this moment, start lift motor 52 thereby drive water tank vibration screw 53, thereby drive connecting plate 54 through the rotation of water tank 53 to move upwards through threaded connection plate 55, thereby drive the energy-saving lamp tube piece that turns over and the energy-saving lamp tube piece that the separation moves upwards through the contact movement block 55, thereby it can drive the separation block 51 that the energy-saving lamp tube separation is further drive the right to move upwards through the separation block 55, thereby it can drive the separation block 51, thereby it can drive the energy-saving lamp tube separation to move upwards through the separation, thereby it drives the energy-saving lamp tube separation block 51, thereby it can drive the energy-saving lamp tube separation block 51 to move upwards when the energy-saving lamp tube separation block 55, thereby it drives the energy-saving lamp tube separation block 51.

It is to be understood that while the present invention has been described in conjunction with the preferred embodiments thereof, it is not intended to limit the invention to those embodiments. It will be apparent to those skilled in the art from this disclosure that many changes and modifications can be made, or equivalents modified, in the embodiments of the invention without departing from the scope of the invention. Therefore, any simple modification, equivalent change and modification made to the above embodiments according to the technical essence of the present invention are still within the scope of the protection of the technical solution of the present invention, unless the contents of the technical solution of the present invention are departed.

Claims

1. An environmental protection recovery processing method is characterized by comprising the following steps:

after mercury liquid collection is finished, a left side screw motor and a right side screw motor are started to drive a left side moving screw to rotate, a left side collecting box and a right side collecting box are driven to move towards a direction close to one side through threaded connection through rotation of the left side moving screw, a left side closing door is pushed to overcome torsional spring force of a reset torsional spring to turn upwards and open, the left side collecting box and the right side collecting box are driven to move into a guide cavity, energy-saving lamp tube fragments on the upper end face of a filter plate are shoveled into the collecting cavity through a shovel, the left side shovel and the right side shovel can be driven to overcome torsional spring force of the closed torsional spring to turn upwards after being in contact with the left side end face and the right side end face of the guide block, the distance between a magnetic block and a magnet is close to adsorb each other, the left side screw motor and the right side screw motor drive the moving screw to turn backwards, the left side collecting box is driven to move back into the screw cavity, the closed collecting cavity, the energy-saving lamp tube fragments in the collecting cavity can be cleaned through a communicating cavity at the moment, and small energy-saving lamp tube fragments can fall into a water cavity when a vibration box, and fall onto the upper end face of a separation plate.

2. The environmental-friendly recycling method according to claim 1, further comprising: if the smaller fragments of the energy-saving lamp tube fall into the water cavity downwards, the lifting motor is started so that the separation plate rises and inclines, and the fragments of the energy-saving lamp tube on the upper end face of the separation plate are collected rightwards.

3. The environmentally friendly recycling method of claim 2, wherein the step of activating the lift motor to raise and tilt the separator plate includes: the lifting motor is started, so that the water tank screw rod is driven to vibrate, the rotating of the water tank screw rod drives the connecting plate to move upwards through threaded connection, the hinged plate is driven to move upwards, the upward movement of the hinged plate drives the left end of the separating plate to turn upwards through hinging, and the energy-saving lamp tube fragments on the upper end face of the separating plate can roll rightwards.

4. The environment-friendly recycling method according to claim 3, wherein the hinged plate continues to move upwards so as to drive the moving block to move upwards through the connection of the separating plate, and the moving block stops when contacting the limiting block, so as to further increase the inclination angle of the separating plate.