JP2021079056A - Pick up device for picking up glass manufacturing residual material fragment - Google Patents

Abstract

To disclose a pick up device for picking up a glass manufacturing residual material fragment.SOLUTION: A pick up device for picking up a glass manufacturing residual material fragment comprises a housing. On a left end in the housing, a rotation space which is open downward is installed. On a right end in the housing, a stickiness space which is open downward is installed. On an upper end in the housing, a transmission space is installed. In the transmission space, a transmission mechanism for providing power to the pick up device is installed. In the rotation space, a first collecting mechanism for collecting a glass fragment having large volume is installed. In the stickiness space, a stickiness mechanism for collecting a glass fragment having small volume is installed. The first collecting mechanism includes a rotation shaft which is coupled to front and rear walls on a left end of the rotation space. On a rear end of the rotation shaft, a first gear is installed. On a front end of the rotation shaft, a first roller is installed. In the surrounding of the first roller, six expandable spaces which are open outward, are arranged at equal intervals.SELECTED DRAWING: Figure 1

Description

The present invention takes up the field of glass, and specifically, is a glass manufacturing residual material debris picking device.

Glass looks good in everyday life, and glass processing is common in industry, but glass processing produces a lot of glass shavings, and these shavings have different volumes and must be thoroughly cleaned for safety. There is a risk of.
Currently, after cutting glass products and completing the processing, the remaining glass debris is manually cleaned, and not only is there a situation where it is not thoroughly cleaned, but also the cleaning efficiency is low and there is a safety risk for workers. is there.

Chinese Patent Application Publication No. 106718119

The technical problem to be solved by the present invention is to provide a glass manufacturing residual material debris picking device, overcome problems such as low cleaning efficiency and incomplete cleaning, and improve cleaning efficiency and thorough cleaning.

The present invention is realized through the following technical plan.

The glass manufacturing residual material debris picking device includes a housing, and a turning space opened downward is installed at the left end in the housing, and a sticky space opened downward is installed at the right end in the housing. A transmission space is installed at the upper end of the housing, a transmission mechanism that provides power to the present invention is installed in the transmission space, and a large volume of glass debris is collected in the rotation space. A collection mechanism is installed, and a stickiness mechanism for collecting small volumes of glass debris is installed in the sticky space.
The first collecting mechanism includes a rotating shaft connected to the front and rear walls at the left end of the rotating space so as to be rotatable, a first gear is installed at the rear end of the rotating shaft, and a first gear is installed at the front end of the rotating shaft. One roller is installed, six telescopic spaces opened to the outside are arranged at equal intervals around the first roller, and a rotating block that can slide up and down in the space is installed in the telescopic space. A telescopic spring is fixedly installed on the lower end surface of the turning block, the telescopic spring is connected to the lower wall of the telescopic space, and the intermediate shaft is connected to the rear wall of the turning space so that the intermediate shaft can rotate. A second gear connected so as to mesh with the first gear is installed at the rear end of the shaft, a driving sprocket is installed at the front end of the intermediate shaft, and a rotating shaft is installed on the front and rear walls at the right end of the turning space. It is installed so that it can rotate, a first driven pulley is installed at the rear end of the rotating shaft, a driven sprocket is also installed at the rear end of the first driven pulley, and a chain is installed on the driven sprocket. The chain is rotatably connected to the driven sprocket, a third gear is installed at the front end of the driven sprocket, and a second roller located on the front side of the third gear is installed at the front end of the driven sprocket. Ten receiving spaces opened to the outside are arranged at equal intervals around the second roller, fixed shafts are fixedly installed on the front and rear walls of the receiving spaces, and rake plates are installed on the fixed shafts. A torsion spring is connected between the rake plate and the fixed shaft, the rotating rod is connected to the front and rear walls at the right end of the turning space so that the rotating rod can rotate, and the second end of the rotating rod is connected to the first. A fourth gear connected so as to mesh with the three gears is installed, a rotating block is installed at the front end of the rotating rod, and fixed rods are arranged at equal intervals around the rotating block to the right of the rotating space. A second collection mechanism that opens upward is fixedly installed on the wall,
In the present invention, power is provided by the transmission mechanism, a large volume of glass debris is collected by the first collection mechanism, and the remaining small volume of glass debris is collected by the stickiness mechanism.

Further, the transmission mechanism includes a first driven space located on the left side of the transmission space and a second driven space located on the right side of the transmission space, and a motor is fixedly installed on the rear wall of the transmission space. A transmission shaft was connected to the front end of the motor so that it could be transmitted, a first umbrella gear was installed on the transmission shaft, and the left end was inserted into the first driven space on the left wall of the transmission space. The first driven shaft is connected so as to be rotatable, and a second umbrella gear connected so as to mesh with the first umbrella gear is installed at the right end of the first driven shaft, and at the left end of the first driven shaft. A first worm located in the first driven space is installed, connected to the front and rear walls of the first driven space so that the first rotating rod can rotate, and at the rear end of the first rotating rod. A first worm wheel connected so as to mesh with the first worm is installed, a first driven pulley is installed at the front end of the first rotating rod, and a first belt is installed on the first driven pulley. The first belt is rotatably connected to the first driven pulley, the second driven shaft is rotatably connected to the right wall of the transmission space, and the first umbrella is connected to the left end of the second driven shaft. A third umbrella gear connected so as to mesh with the gear is installed, and a second worm located in the second driven space is installed at the right end of the third umbrella gear, and the front and rear walls of the second driven space are installed. A second worm wheel connected so that the second rotating rod can rotate is installed at the rear end of the second rotating rod, and a second worm wheel connected so as to mesh with the second worm is installed at the rear end of the second rotating rod. The second main pulley is installed in.

Further, the sticky mechanism includes a rotating shaft connected to the front and rear walls of the sticky space so as to be rotatable, a second driven pulley is installed at the rear end of the rotating shaft, and the second driven pulley is equipped with the first driven pulley. A second belt connected to the two main moving pulleys so as to rotate is installed, a fifth gear located on the front side of the second driven pulley is installed at the rear end of the rotating shaft, and a fifth gear located on the front side of the second driven pulley is installed at the front end of the rotating shaft. A third roller is installed, a sticky layer is installed on the outer periphery of the third roller, a rotating rod is connected to the front and rear walls at the right end of the sticky space so that the rotating rod can rotate, and a fourth roller is attached to the rotating rod. Ten pressing plates are arranged at equal intervals on the outer periphery of the fourth roller, and the left end of the pressing plates is pressed against the outer surface of the sticky layer, and is above the right wall of the sticky space. The second collection space opened in is fixedly installed.

Further, the elasticity of the telescopic spring is larger than the frictional force received when the turning block slides in the expansion and contraction space.

Further, the torsional force of the torsion spring is larger than the sum of the resistance forces received when the rake plate rotates on the fixed shaft.

The beneficial effect of the present invention is: The present invention has a simple structure, is convenient to operate, can collect glass debris on the ground step by step when it operates, and first cleans and collects a large volume of glass debris. , And collect small glass debris finely, greatly increasing the efficiency and cleanliness of collecting glass debris.

In order to explain the present invention in detail with reference to FIGS. 1 to 5 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention, and is described above and below. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 are the same.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention. FIG. 2 is a schematic structural diagram of AA of FIG. 1 according to an embodiment of the present invention. FIG. 3 is a schematic structure diagram of BB of FIG. 1 according to an embodiment of the present invention. FIG. 4 is a schematic structure diagram of C of FIG. 1 according to an embodiment of the present invention. FIG. 5 is a schematic diagram of the structure of FIG. 1D of the embodiment of the present invention.

With reference to FIGS. 1 to 5, the glass manufacturing residual material debris picking device includes a housing 10, and a rotating space 26 opened downward is installed at the left end of the housing 10 and at the right end of the housing 10. A sticky space 44 opened downward is installed, a transmission space 38 is installed at the upper end of the housing 10, and a transmission mechanism 33 that provides power to the present invention is installed in the transmission space 38. A first collection mechanism 25 for collecting large-volume glass debris is installed in the turning space 26, and a sticky mechanism 16 for collecting small-volume glass debris is installed in the sticky space 44. (1) The collecting mechanism 25 includes a rotating shaft 24 connected to the front and rear walls at the left end of the rotating space 26 so as to be rotatable, and a first gear 48 is installed at the rear end of the rotating shaft 24. A first roller 23 is installed at the front end, and six expansion / contraction spaces 60 opened to the outside are arranged around the first roller 23 at equal intervals, and slide up and down in the expansion / contraction space 60. A possible turning block 62 is installed, a telescopic spring 61 is fixedly installed on the lower end surface of the turning block 62, the telescopic spring 61 is connected to the lower wall of the telescopic space 60, and the rear wall of the turning space 26 is connected. A second gear 49 connected so that the intermediate shaft 50 can rotate is installed at the rear end of the intermediate shaft 50, and a second gear 49 connected so as to mesh with the first gear 48 is installed at the rear end of the intermediate shaft 50. A driving sprocket 47 is installed, a rotating shaft 21 is installed on the front and rear walls at the right end of the rotating space 26 so that the rotating shaft 21 can rotate, and a first driven pulley 52 is installed at the rear end of the rotating shaft 21. A driven sprocket 54 is also installed at the rear end of the driven pulley 52, a chain 51 is installed on the driven sprocket 54, the chain 51 is connected to the driven sprocket 47 so as to be rotatable, and the driven sprocket 54 is connected to the front end of the driven sprocket 54. A third gear 55 is installed, a second roller 22 located on the front side of the third gear 55 is installed at the front end of the driven sprocket 54, and ten pieces opened to the outside around the second roller 22. The receiving spaces 66 are arranged at equal intervals, a fixed shaft 63 is fixedly installed on the front and rear walls of the receiving space 66, a sprocket plate 65 is installed on the fixed shaft 63, and the rake plate 65 and the fixing are fixed. A torsion spring 64 is connected to the shaft 63, and a rotating rod 18 is connected to the front and rear walls at the right end of the rotating space 26 so that the rotating rod 18 can rotate. A fourth gear 56 connected so as to mesh with the third gear 55 is installed at the rear end of 18, a rotating block 19 is installed at the front end of the rotating rod 18, and is fixed around the rotating block 19. The rods 20 are arranged at equal intervals, and a second collecting mechanism 17 opened upward is fixedly installed on the right wall of the turning space 26. In the present invention, power is provided by the transmission mechanism 33, and the first The collecting mechanism 25 collects a large volume of glass shavings, and the sticking mechanism 16 collects the remaining small volume of glass shavings.

Beneficially, the transmission mechanism 33 includes a first driven space 28 located on the left side of the transmission space 38 and a second driven space 39 located on the right side of the transmission space 38, on the rear wall of the transmission space 38. The motor 35 is fixedly installed, the transmission shaft 36 is connected to the front end of the motor 35 so that the transmission shaft 36 can be transmitted, the first umbrella gear 34 is installed on the transmission shaft 36, and the left wall of the transmission space 38 is installed. The left end is connected so that the first driven shaft 27 inserted in the first driven space 28 can rotate, and the right end of the first driven shaft 27 is connected so as to mesh with the first umbrella gear 34. The second umbrella gear 32 is installed, and the first worm 67 located in the first driven space 28 is installed at the left end of the first driven shaft 27, and is installed on the front and rear walls of the first driven space 28. Is connected so that the first rotating rod 29 can rotate, and a first worm wheel 68 connected so as to mesh with the first worm 67 is installed at the rear end of the first rotating rod 29. A first driven pulley 30 is installed at the front end of the rod 29, a first belt 31 is installed on the first driven pulley 30, and the first belt 31 is connected to the first driven pulley 52 so as to be rotatable. The second driven shaft 42 is connected to the right wall of the transmission space 38 so as to be rotatable, and the third umbrella gear is connected to the left end of the second driven shaft 42 so as to mesh with the first cap gear 34. 37 is installed, a second worm 70 located in the second driven space 39 is installed at the right end of the third umbrella gear 37, and a second rotating rod 40 is installed on the front and rear walls of the second driven space 39. A second worm wheel 69 is installed at the rear end of the second rotating rod 40 so as to be engaged with the second worm 70, and at the front end of the second rotating rod 40. A second driven pulley 41 is installed.

Advantageously, the sticking mechanism 16 includes a rotating shaft 14 rotatably connected to the front and rear walls of the sticking space 44, and a second driven pulley 57 is installed at the rear end of the rotating shaft 14. A second belt 43 connected to the second driven pulley 41 so as to be rotatable is installed on the second driven pulley 57, and a second belt 43 located at the rear end of the rotating shaft 14 is located on the front side of the second driven pulley 57. A five-gear 58 is installed, a third roller 13 is installed at the front end of the rotating shaft 14, a sticky layer 15 is installed on the outer periphery of the third roller 13, and a sticky layer 15 is installed on the front and rear walls at the right end of the sticky space 44. The rotary rods 12 are connected so as to be rotatable, a fourth roller 45 is installed on the rotary rod 12, and ten pressing plates 46 are arranged at equal intervals on the outer periphery of the fourth roller 45. The left end of 46 is pressed against the outer surface of the sticky layer 15, and a second collection space 11 opened upward is fixedly installed on the right wall of the sticky space 44.

Advantageously, the elasticity of the telescopic spring 61 is greater than the frictional force received when the turning block 62 slides in the expansion and contraction space 60.

Advantageously, the torsional force of the torsion spring 64 is greater than the sum of the resistance forces received when the rake plate 65 rotates on the fixed shaft 63.

Flow of mechanical operation of the entire invention of the present application:
1. 1. The motor 35 is started, and the motor 35 operates to rotate the transmission shaft 36, thereby rotating the first umbrella gear 34, thereby engaging with the second umbrella gear 32 so as to mesh with the first umbrella gear 34. The third umbrella gear 37 is rotated, and the second umbrella gear 32 is rotated to rotate the first driven shaft 27 and the first worm 67 at the left end of the first driven shaft 27 so as to mesh with the first worm 67. The first worm wheel 68 connected to the first worm wheel 68 is rotated, and the first worm wheel 68 is rotated to rotate the first rotating rod 29 and the first driven pulley 30 on the first rotating rod 29, whereby the first belt 31 is rotated. The first driven pulley 52 connected so as to be able to rotate with the first driven pulley 30 is rotated to rotate the rotating shaft 21, and the rotating shaft 21 is rotated to rotate the driven sprocket 54, the third gear 55, and the second roller. 22 is rotated, the driven sprocket 54 is rotated to rotate the driven sprocket 47 connected to the driven sprocket 54 by the chain 51, whereby the intermediate shaft 50 and the second gear 49 are rotated, and the second gear 49 is rotated. The first gear 48, which is connected so as to mesh with the second gear 49, is rotated, thereby rotating the rotating shaft 24 and the first roller 23 on the rotating shaft 24, and the first roller 23 rotates to make six turns. Block 62 turns large glass debris back.
2. The second roller 22 rotates and the twelve rake plates 65 on the second roller 22 are interlocked to scoop the glass debris on the ground and place it on the surface of the rake plate 65. The fourth gear is connected so as to collect the glass debris that has been turned backward together, send the glass debris on the rake plate 65 to the rear by the rotation of the second roller 22, rotate the third gear 55, and mesh with the third gear 55. The gear 56 is rotated, whereby the rotating rod 18 and the rotating block 19 at the front end of the rotating rod 18 are rotated, whereby the six fixed rods 20 in the rotating block 19 are interlocked and continuously on the second roller 22. The rake plate 65 is turned so that the glass debris on the rake plate 65 falls into the second collection mechanism 17 and is collected.
3. 3. The third umbrella gear 37 rotates to rotate the second driven shaft 42 and the second worm 70 at the right end of the second driven shaft 42, thereby causing the second worm wheel 69 connected so as to mesh with the second worm 70. The second worm 69 is rotated to rotate the second rotating rod 40 and the second main pulley 41 at the front end, whereby the second belt 43 is connected to the second main pulley 41 so as to be able to rotate. The driven pulley 57 is rotated, the second driven pulley 57 is rotated to rotate the rotating shaft 14, thereby rotating the fifth gear 58 and the third roller 13 on the rotating shaft 14, and the fifth gear 58 is rotated. The sixth gear 59, which is connected to the fifth gear 58 so as to mesh with the fifth gear 58, is rotated, thereby rotating the rotating rod 12 and the fourth roller 45 on the rotating rod 12, and the third roller 13 rotates to reduce small glass chips. Is pressed into the sticky layer 15, the sticky layer 15 and the fourth roller 45 rotate in opposite directions, and the fourth roller 45 rotates to rotate the ten pressing plates 46 to rotate the glass debris in the sticky layer 15. Is pressed and scraped off and dropped into the second collection space 11 for collection.

The above is merely a specific embodiment of the invention of the present application, but the scope of protection of the invention of the present application is not limited to this. Changes and replacements that come to mind through all creative labor are covered by the scope of the invention of the present application. Therefore, the scope of protection of the present invention is based on the scope of protection in which the request for rights is limited.

The present invention takes up the field of glass, and specifically, is a glass manufacturing residual material debris picking device.

Glass looks good in everyday life, and glass processing is common in industry, but glass processing produces a lot of glass shavings, and these shavings have different volumes and must be thoroughly cleaned for safety. There is a risk of.
Currently, after cutting glass products and completing the processing, the remaining glass debris is manually cleaned, and not only is there a situation where it is not thoroughly cleaned, but also the cleaning efficiency is low and there is a safety risk for workers. is there.

Chinese Patent Application Publication No. 106718119

The technical problem to be solved by the present invention is to provide a glass manufacturing residual material debris picking device, overcome problems such as low cleaning efficiency and incomplete cleaning, and improve cleaning efficiency and thorough cleaning.

The present invention is realized through the following technical plan.

Glassmaking residual material clastic pick device includes a housing, on the left side in the housing is installed turning space opened downward, sticky space opened downward is installed in the right side in the housing , on the side in said housing is installed transmission space in said housing is installed transmission mechanism, the first collection mechanism is installed to collect a large glass clastic of volume in the turning space In the sticky space, a sticky mechanism for collecting small-volume glass debris is installed.
The first collection mechanism includes a concatenated rotary shaft for rotation around the wall of the left side of the turning space, wherein the rear side of the rotary shaft is installed first gear, before end of the rotary shaft A first roller is installed, six telescopic spaces opened to the outside are arranged at equal intervals around the first roller, and a rotating block that can slide in the telescopic space is installed in the telescopic space. The turning block and the wall of the telescopic space are connected by a telescopic spring, are connected to the rear wall of the turning space so that the intermediate shaft can rotate, and mesh with the first gear on the rear side of the intermediate shaft. second gear is connected is installed in the before side of the intermediate shaft is installed driver sprocket, the right side of the front and rear walls of the turning space is disposed so as to be rotated flipping axis, of the flipping axis A first driven pulley is installed on the rear side , a driven sprocket is installed on the front side of the first driven pulley, a chain is installed on the driven sprocket, and the chain is connected to the main driven sprocket so as to be rotatable. the prior side of the driven sprocket is disposed a third gear, the before side of the driven sprocket second roller is installed which is located on the front side of the third gear, outside the circumference of the second roller Ten open receiving spaces are arranged at equal intervals, fixed shafts are fixedly installed on the front and rear walls of the receiving spaces, and a rake plate is installed on the fixed shafts. torsion spring is connected between, on the right side of the front and rear walls of the turning space is connected for rotation is flipping rod, the flipping rod positioned on the right side of the flipping axis, the rear side of the flipping rod fourth gear coupled to mesh with the third gear is installed in the said flipping before side of the rod is provided rotating blocks, the first collecting mechanism further equally spaced around the rotary block A second collection mechanism that opens upward is fixedly installed on the right wall of the turning space, including a fixed rod arranged in.
In the present invention, power is provided by the transmission mechanism, a large volume of glass debris is collected by the first collection mechanism, and the remaining small volume of glass debris is collected by the stickiness mechanism.

Further, the transmission mechanism includes a first driven space located on the left side of the transmission space and a second driven space located on the right side of the transmission space, and a motor is fixedly installed on the rear wall of the transmission space. wherein the lower side of the motor is connected to the transmission shaft can be transmission inserted into the transmission shaft is installed first bevel gear, in the left wall of the transmission space is left side of the first driven space coupled to allow the first driven shaft rotation that is, above the right side of the first driven shaft second bevel gear coupled to mesh with said first bevel gear is disposed, of the first driven shaft the first worm located within said first follower space is installed in the left side, the the front and rear walls of the first driven space is connected so that it can rotate the first rotating rod, after said first rotation rod the side first worm wheel is installed which is connected to mesh with the first worm, the prior side of the first rotating rod is installed first main driving pulley, a first belt to said first main drive pulley There is provided, said first belt is connected for rotation with the first driven pulley, the right wall of the transmission space is connected for rotation the second driven shaft, the left side of the second driven shaft said third bevel gear which is connected so as to mesh with the first bevel gear is installed, the right side of the third bevel gear second worm is installed located within said second driven space in the A second worm wheel connected so that the second rotating rod can rotate is installed on the front and rear walls of the second driven space, and a second worm wheel connected so as to mesh with the second worm is installed on the rear side of the second rotating rod. The transmission mechanism further includes a second driven pulley installed on the front side of the second rotating rod .

Further, the sticky mechanism includes a rotating shaft connected to the front and rear walls of the sticky space so as to be rotatable, a second driven pulley is installed on the rear side of the rotating shaft, and the second driven pulley has the first driven pulley. two main driving the second belt is disposed which is connected for rotation with the pulley, said behind around shaft fifth gear located on the front side of the second driven pulley is disposed, before the side of the rotation axis a third roller is provided, the is installed and sticky layer on the outer periphery of the third roller, wherein the right side of the front and rear walls of stickiness space is connected so that it can rotate rotating rod, said the rotarod fourth rollers are installed, the the outer periphery of the fourth roller is ten pressing plate are arranged at equal intervals, the left side of the pressing plate is pressed against the outer surface of the sticky layer, the right wall of the stickiness space A second collection space that opens upward is fixedly installed in the area.

Further, the elasticity of the telescopic spring is larger than the frictional force received when the turning block slides in the expansion and contraction space.

The beneficial effect of the present invention is: The present invention has a simple structure, is convenient to operate, can collect glass debris on the ground step by step when it operates, and first cleans and collects a large volume of glass debris. , And collect small glass debris finely, greatly increasing the efficiency and cleanliness of collecting glass debris.

In order to explain the present invention in detail with reference to FIGS. 1 to 5 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention, and is described above and below. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 are the same.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention. FIG. 2 is a schematic structural diagram of AA of FIG. 1 according to an embodiment of the present invention. FIG. 3 is a schematic structure diagram of BB of FIG. 1 according to an embodiment of the present invention. FIG. 4 is a schematic structure diagram of C of FIG. 1 according to an embodiment of the present invention. FIG. 5 is a schematic diagram of the structure of FIG. 1D of the embodiment of the present invention.

Referring to FIGS. 1-5, glassmaking residual material clastic pick apparatus comprises a housing 10, turning space 26 which opens downward is installed in the left side in the housing 10, right in the housing 10 the side is installed stickiness space 44 which is open downward, said on side of the housing 10 the transmission space 38 is installed, in the housing 10 is a transmission mechanism 33 is disposed, of the turning space 26 A first collection mechanism 25 for collecting large-volume glass debris is installed therein, and a stickiness mechanism 16 for collecting small-volume glass debris is installed in the sticky space 44. includes a concatenated rotary shaft 24 for rotation around the wall of the left side of the turning space 26, the behind of the rotary shaft 24 is disposed a first gear 48, the front side of the rotary shaft 24 The first roller 23 is installed, and six telescopic spaces 60 opened to the outside are arranged around the first roller 23 at equal intervals, and in the telescopic space 60, a rotating gear that can slide in the telescopic space 60. A block 62 is installed, the turning block 62 and the wall of the telescopic space 60 are connected by a telescopic spring 61, and the intermediate shaft 50 is connected to the rear wall of the turning space 26 so that the intermediate shaft 50 can rotate. rear second pinion 49 which is connected to mesh with the first gear 48 is installed in the said prior side of the intermediate shaft 50 is installed driver sprocket 47, the right side of the front and rear walls of the turning space 26 The rotating shaft 21 is installed so as to be rotatable, a first driven pulley 52 is installed on the rear side of the rotating shaft 21, and a driven sprocket 54 is installed on the front side of the first driven pulley 52. chain 51 is installed in the sprocket 54, the chain 51 is connected for rotation with the main drive sprocket 47, the third gear 55 is installed in the front side of the driven sprocket 54, front side of the driven sprocket 54 A second roller 22 located on the front side of the third gear 55 is installed in the second roller 22, and ten receiving spaces 66 opened to the outside are arranged around the second roller 22 at equal intervals. A fixed shaft 63 is fixedly installed on the front and rear walls of the above, a rake plate 65 is installed on the fixed shaft 63, and a torsion spring 64 is connected between the rake plate 65 and the fixed shaft 63. Turn on the right side of the front and rear walls of the space 26 is connected for rotation is flipping rod 18, the flipping rod 18 is positioned to the right of the flipping shaft 21, after the flipping rod 18 The side is the fourth gear 56 is installed which is connected to mesh with the third gear 55, the flipping before side of the rod 18 the rotation block 19 is disposed, the first collecting mechanism 25 further includes the rotation A second collecting mechanism 17 opened upward is fixedly installed on the right wall of the turning space 26 including fixed rods 20 arranged around the block 19 at equal intervals. Power is provided, the first collecting mechanism 25 collects large volumes of glass debris, and the sticking mechanism 16 collects the remaining small volumes of glass debris.

Beneficially, the transmission mechanism 33 includes a first driven space 28 located on the left side of the transmission space 38 and a second driven space 39 located on the right side of the transmission space 38, on the rear wall of the transmission space 38. The motor 35 is fixedly installed , the transmission shaft 36 is connected to the lower side of the motor 35 so that the transmission shaft 36 can be transmitted, the first umbrella gear 34 is installed on the transmission shaft 36, and the left side of the transmission space 38. the walls first driven shaft 27 has a left side is inserted into said first follower space 28 is connected for rotation, meshing with the first bevel gear 34 on the right side of the first driven shaft 27 second bevel gear 32 connected is installed as the the left side of the first driven shaft 27 first worm 67 is disposed that is located within the first driven space 28, the first driven space 28 A first worm wheel 68 is installed on the front and rear walls of the first rotating rod 29 so as to be rotatable, and a first worm wheel 68 connected so as to mesh with the first worm 67 is installed on the rear side of the first rotating rod 29. the prior side of the first rotating rod 29 is provided a first main driving pulley 30 is said in the first main driving pulley 30 is installed the first belt 31, rotates the first belt 31 and the first driven pulley 52 coupled to allow, on the right wall of the transmission space 38 is connected for rotation the second driven shaft 42, connected to mesh with said first bevel gear 34 on the left side of the second driven shaft 42 It is installed the third bevel gear 37 which is the third in the right side of the bevel gear 37 second worm 70 is installed which is located within the second driven space 39, front and rear walls of the second driven space 39 A second worm wheel 69 is installed on the rear side of the second rotating rod 40 so as to be engaged with the second worm 70, and the transmission mechanism is installed. 33 further includes a second driven pulley 41 installed on the front side of the second rotating rod 40 .

Advantageously, the sticking mechanism 16 includes a rotating shaft 14 rotatably connected to the front and rear walls of the sticking space 44, and a second driven pulley 57 is installed on the rear side of the rotating shaft 14. A second belt 43 connected to the second driven pulley 41 so as to be rotatable is installed on the second driven pulley 57, and a second belt 43 located on the rear side of the rotating shaft 14 is located on the front side of the second driven pulley 57. placed five gears 58, wherein the front side around axis 14 is installed the third roller 13, wherein the outer periphery of the third roller 13 is disposed sticky layer 15, right side of the front and rear walls of the stickiness space 44 A fourth roller 45 is installed on the rotary rod 12 so that the rotary rod 12 can rotate, and ten pressing plates 46 are arranged at equal intervals on the outer periphery of the fourth roller 45. left side of the pressing plate 46 is pressed against the outer surface of the sticky layer 15, the right wall of the stickiness space 44 second collecting space 11 that opens upward is fixedly installed.

Advantageously, the elasticity of the telescopic spring 61 is greater than the frictional force received when the turning block 62 slides in the expansion and contraction space 60.

Flow of mechanical operation of the entire invention of the present application:
1. 1. The motor 35 is started, and the motor 35 operates to rotate the transmission shaft 36, thereby rotating the first umbrella gear 34, thereby engaging with the second umbrella gear 32 so as to mesh with the first umbrella gear 34. rotating the third bevel gear 37, to rotate the first worm 67 to the second bevel gear 32 is a first driven shaft 27 rotates in the left side of the first driven shaft 27, meshes thereby the first worm 67 The first worm wheel 68 connected in this manner is rotated, and the first worm wheel 68 is rotated to rotate the first rotating rod 29 and the first driven pulley 30 on the first rotating rod 29, whereby the first belt is rotated. The first driven pulley 52 connected so as to be rotatable with the first driven pulley 30 by 31 is rotated to rotate the rotating shaft 21, and the rotating shaft 21 is rotated to rotate the driven sprocket 54, the third gear 55, and the second. The roller 22 is rotated, the driven sprocket 54 is rotated to rotate the driven sprocket 47 connected to the driven sprocket 54 by the chain 51, whereby the intermediate shaft 50 and the second gear 49 are rotated, and the second gear 49 is rotated. Then, the first gear 48 connected so as to mesh with the second gear 49 is rotated, thereby rotating the rotating shaft 24 and the first roller 23 on the rotating shaft 24, and the first roller 23 rotates to six. The turning block 62 turns large glass debris backwards.
2. The second roller 22 rotates clockwise to interlock the twelve rake plates 65 on the second roller 22 to scoop the glass debris on the ground and place it on the surface of the rake plate 65, and the rake plate 65 is rotated. The block 62 collects the glass debris rotated counterclockwise together, and the clockwise rotation of the second roller 22 sends the glass debris on the rake plate 65 clockwise, and the third gear 55 rotates to rotate the third gear. The fourth gear 56, which is connected so as to mesh with 55, is rotated, whereby the rotating rod 18 and the rotating block 19 on the front side of the rotating rod 18 are rotated counterclockwise, whereby the six fixed rods in the rotating block 19 are rotated. 20 are interlocked to continuously rotate the rake plate 65 on the second roller 22, whereby the glass debris on the rake plate 65 falls into the second collection mechanism 17 and is collected .
3. 3. Third umbrella gear 37 is rotated to rotate the second driven shaft 42 and the second worm 70 on the right side of the second driven shaft 42, thereby the second worm wheel 69 which is connected to mesh with the second worm 70 is rotated, the second worm 69 is rotated to rotate the second rotating rod 40 and the second main driving pulley 41 of the front side, are connected thereby to the second belt 43 can be rotated with the second main drive pulley 41 The second driven pulley 57 is rotated, the second driven pulley 57 is rotated to rotate the rotating shaft 14, thereby rotating the fifth gear 58 and the third roller 13 on the rotating shaft 14, and the fifth gear 58 is rotated. The sixth gear 59, which is rotated and connected so as to mesh with the fifth gear 58, is rotated, thereby rotating the rotating rod 12 and the fourth roller 45 on the rotating rod 12, and the third roller 13 is rotated to be small. Glass shavings are pressed into the viscous layer 15, the viscous layer 15 and the fourth roller 45 rotate in opposite directions, and the fourth roller 45 rotates to rotate ten pressing plates 46 in the viscous layer 15. The glass shavings are pressed and scraped off and dropped into the second collection space 11 for collection.

The above is merely a specific embodiment of the invention of the present application, but the scope of protection of the invention of the present application is not limited to this. Changes and replacements that come to mind through all creative labor are covered by the scope of the invention of the present application. Therefore, the scope of protection of the present invention is based on the scope of protection in which the request for rights is limited.

Claims (5)

A rotating space that opens downward is installed at the left end of the housing including the housing, a sticky space that opens downward is installed at the right end of the housing, and a transmission space is installed at the upper end of the housing. Is installed, a transmission mechanism that provides power to the present invention is installed in the transmission space, and a first collection mechanism that collects a large volume of glass shavings is installed in the rotation space. A sticking mechanism that collects small volumes of glass debris is installed inside.
The first collecting mechanism includes a rotating shaft connected to the front and rear walls at the left end of the rotating space so as to be rotatable, a first gear is installed at the rear end of the rotating shaft, and a first gear is installed at the front end of the rotating shaft. One roller is installed, six telescopic spaces opened to the outside are arranged at equal intervals around the first roller, and a rotating block that can slide up and down in the space is installed in the telescopic space. A telescopic spring is fixedly installed on the lower end surface of the turning block, the telescopic spring is connected to the lower wall of the telescopic space, and the intermediate shaft is connected to the rear wall of the turning space so that the intermediate shaft can rotate. A second gear connected so as to mesh with the first gear is installed at the rear end of the shaft, a driving sprocket is installed at the front end of the intermediate shaft, and a rotating shaft is installed on the front and rear walls at the right end of the turning space. It is installed so that it can rotate, a first driven pulley is installed at the rear end of the rotating shaft, a driven sprocket is also installed at the rear end of the first driven pulley, and a chain is installed on the driven sprocket. The chain is rotatably connected to the driven sprocket, a third gear is installed at the front end of the driven sprocket, and a second roller located on the front side of the third gear is installed at the front end of the driven sprocket. Ten receiving spaces opened to the outside are arranged at equal intervals around the second roller, fixed shafts are fixedly installed on the front and rear walls of the receiving spaces, and rake plates are installed on the fixed shafts. A torsion spring is connected between the rake plate and the fixed shaft, the rotating rod is connected to the front and rear walls at the right end of the turning space so that the rotating rod can rotate, and the second end of the rotating rod is connected to the first. A fourth gear connected so as to mesh with the three gears is installed, a rotating block is installed at the front end of the rotating rod, and fixed rods are arranged at equal intervals around the rotating block to the right of the rotating space. A second collection mechanism that opens upward is fixedly installed on the wall,
The present invention is characterized in that power is provided by the transmission mechanism, a large volume of glass shavings is collected by the first collection mechanism, and the remaining small volume of glass shavings is collected by the stickiness mechanism. Material debris picking device. The transmission mechanism includes a first driven space located on the left side of the transmission space and a second driven space located on the right side of the transmission space, and a motor is fixedly installed on the rear wall of the transmission space. The transmission shaft is connected to the front end of the transmission shaft so that it can be transmitted, the first umbrella gear is installed on the transmission shaft, and the left end is inserted into the first driven space on the left wall of the transmission space. The driven shaft is connected so as to be rotatable, and a second umbrella gear connected so as to mesh with the first umbrella gear is installed at the right end of the first driven shaft, and the first driven shaft is connected to the left end of the first driven shaft. A first worm located in the driven space is installed, connected to the front and rear walls of the first driven space so that the first rotating rod can rotate, and at the rear end of the first rotating rod. A first worm wheel connected so as to mesh with the worm is installed, a first driven pulley is installed at the front end of the first rotating rod, a first belt is installed on the first driven pulley, and the first The belt is rotatably connected to the first driven pulley, is connected to the right wall of the transmission space so that the second driven shaft can rotate, and the left end of the second driven shaft is connected to the first umbrella gear. A third umbrella gear connected so as to mesh is installed, a second worm located in the second driven space is installed at the right end of the third umbrella gear, and a second worm located in the second driven space is installed on the front and rear walls of the second driven space. A second worm wheel connected so that the second rotating rod can rotate is installed at the rear end of the second rotating rod, and a second worm wheel connected so as to mesh with the second worm is installed at the rear end of the second rotating rod, and at the front end of the second rotating rod. The device for picking up shavings of glass manufacturing residual material according to claim 1, wherein a second driven pulley is installed. The sticky mechanism includes a rotating shaft connected to the front and rear walls of the sticky space so as to be rotatable, a second driven pulley is installed at the rear end of the rotating shaft, and the second driven pulley is equipped with the second driven pulley. A second belt connected to the pulley so that it can rotate is installed, a fifth gear located on the front side of the second driven pulley is installed at the rear end of the rotating shaft, and a third gear is installed at the front end of the rotating shaft. A roller is installed, a sticky layer is installed on the outer periphery of the third roller, a rotating rod is connected to the front and rear walls at the right end of the sticky space so that the rotating rod can rotate, and a fourth roller is installed on the rotating rod. Ten pressing plates are arranged at equal intervals on the outer periphery of the fourth roller, the left end of the pressing plate is pressed against the outer surface of the sticky layer, and the right wall of the sticky space is opened upward. The device for picking up waste materials from glass production according to claim 1, wherein the second collection space is fixedly installed. The glass manufacturing residual material debris picking device according to claim 1, wherein the elasticity of the telescopic spring is larger than the frictional force received when the turning block slides in the expansion and contraction space. The glass manufacturing residual material debris picking device according to claim 1, wherein the torsional force of the torsion spring is larger than the sum of the resistance forces received when the rake plate rotates on the fixed shaft.

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