CN110092136B

CN110092136B - Waste metal recovery device for heavy industry plant

Info

Publication number: CN110092136B
Application number: CN201910488414.6A
Authority: CN
Inventors: 吴刚
Original assignee: Suzhou Gonghu Precision Manufacturing Industry Development Co Ltd
Current assignee: Suzhou Gonghu Precision Manufacturing Industry Development Co ltd
Priority date: 2019-06-05
Filing date: 2019-06-05
Publication date: 2020-11-20
Anticipated expiration: 2039-06-05
Also published as: CN110092136A

Abstract

The invention discloses a waste metal recovery device for heavy industry plants, which comprises a machine body, wherein four corners of the lower end surface of the machine body are respectively provided with rolling wheels, a recovery cavity is arranged in the machine body, a recovery block is rotatably arranged in the recovery cavity through a rotating shaft, a transmission shaft is rotatably arranged in the rotating shaft, the rear side of the recovery cavity is provided with a power conversion device, the transmission shaft and the rotating shaft are in power connection with the power conversion device, and a magnetic strip is arranged in the recovery block.

Description

Waste metal recovery device for heavy industry plant

Technical Field

The invention relates to the technical field of environmental management, in particular to a waste metal recovery device for a heavy industrial plant.

Background

Traditional heavy industry factory can retrieve the old and useless metal of major possession usually, and the waste and useless metal of small volume such as the other metal fillings of workshop lathe is handled as refuse, causes the waste of metal renewable resources, and the metallics increase the degree of difficulty of administering the environment, and secondly, traditional old and useless metal recovery unit is bulky, is not suitable for using in the small region, leads to the recovery region not comprehensive, and the recovery process is complicated. The present invention sets forth a device that solves the above problems.

Disclosure of Invention

The technical problem is as follows:

the traditional heavy work factory can usually recover large waste metals, which causes waste of metal regeneration resources, and the traditional waste metal recovery device is large in size and not suitable for being used in small areas.

In order to solve the problems, the embodiment designs a waste metal recovery device of a heavy work plant, which comprises a machine body, wherein four corners of the lower end surface of the machine body are respectively provided with a rolling wheel, a recovery cavity is arranged in the machine body, a recovery block is arranged in the recovery cavity in a rotating mode through a rotating shaft, the rotating shaft is provided with a transmission shaft in a rotating mode, the rear side of the recovery cavity is provided with a power conversion device, the transmission shaft and the rotating shaft are in power connection with the power conversion device, a magnetic strip is arranged in the recovery block, a conveying belt is sleeved on the periphery of the recovery block, a rotating cavity is arranged in the right end surface of the recovery block, a rotating gear is arranged in the rotating cavity in a rotating mode through a connecting shaft, the rotating gear is meshed with the inner end surface of the conveying belt, the connecting shaft is in power connection with the transmission shaft, a fixed block is fixedly arranged on the left end wall of the moving cavity, a moving device is arranged in the moving cavity, the fixed block is abutted against the moving device, a collecting device is arranged on the lower side of the moving cavity, a locking device is arranged on the collecting device, and a power transmission device is arranged on the right side of the moving cavity and is used for connecting the locking device with the moving device; the recovery block inclines and the lower end is close to the ground, so that the metal object with the magnetic attraction effect can be adsorbed on the conveying belt through the magnetic attraction force of the magnetic strip, and finally the metal object is recovered through the collecting device.

Preferably, the magnetic strip is arranged at the left side position of the rotating gear, so that the metal blocks on the conveying belt are conveyed to the position of the rotating gear, lose the magnetic adsorption force and enter the collecting device for recovery.

Wherein, the moving device comprises a moving rod, a telescopic hole is arranged in the moving rod, a telescopic rod is arranged in the telescopic hole in a sliding manner, the lower end of the telescopic rod is hinged with the collecting device, a telescopic spring is fixedly arranged between the upper end of the telescopic rod and the telescopic hole, a through groove is arranged in the telescopic rod and is abutted against the fixed block, the upper side of the moving cavity is communicated with and provided with a moving space, a moving lead screw is arranged in the moving space in a rotating manner, the upper end of the moving rod is in threaded connection with the moving lead screw, a moving motor is fixedly arranged on the left end wall of the moving space, the left end of the moving lead screw is in power connection with the moving motor, an extrusion groove is arranged on the left side of the moving cavity in a communicating manner, an extrusion rod is arranged in the extrusion groove in a sliding manner, the right end of the extrusion rod is abutted against, a meshing gear is rotatably arranged on the lower end wall of the extrusion groove and meshed with the rack, a gear rotating shaft is fixedly arranged at the axis of the meshing gear and is in power connection with the power conversion device; the collecting device can work due to the movement of the moving rod, the moving rod pushes the extrusion rod to move, and the power conversion device performs power conversion through transmission.

The collecting device comprises a connecting cavity communicated with the moving cavity, a connecting plate is rotatably arranged in the connecting cavity, a sliding gap is arranged in the connecting plate, the right end of the connecting plate is hinged with the lower end of the telescopic rod, a recovery box is arranged on the lower side of the connecting cavity, locking blocks which are symmetrical in the front-back direction are fixedly arranged on the upper end face of the recovery box, through holes are arranged in the locking blocks, the through holes are spliced with the locking device, a cavity is arranged in the recovery box, and the cavity is communicated with the connecting cavity; and the metal on the conveying belt enters the recovery box through the connecting plate to be recovered and stored.

The locking device comprises a locking cavity which is symmetrical front and back, the locking block extends into the locking cavity, one side of the locking cavity, which is far away from the symmetrical center, is communicated with a sliding groove, an insertion block is arranged in the sliding groove in a sliding mode, one end, which is close to the locking cavity, of the insertion block extends into the through hole, the other end of the insertion block is fixedly provided with a torsion spring, and a hollow groove is formed in the torsion spring; the inserting block is inserted into the through hole to lock the recycling box.

The power transmission device comprises a pushing groove communicated with the moving cavity, a pushing block is arranged in the pushing groove in a sliding mode, a first reset assembly used for resetting the pushing block is fixedly arranged on the upper end face of the pushing block, a sliding rod groove is formed in the lower side of the pushing groove in a communicating mode, a connecting sliding rod is arranged in the sliding rod groove in a sliding mode, a second reset assembly used for resetting the connecting sliding rod is fixedly arranged on the right end face of the connecting sliding rod, rotating grooves which are symmetrical in the front and back are formed in the lower side of the sliding rod groove in a communicating mode, a push rod is arranged between the rotating groove and the sliding rod groove in a sliding mode, a third reset assembly used for resetting the push rod is fixedly arranged on the right end face of the push rod, a shifting rod is rotatably arranged in the rotating groove, the rear end of the shifting rod extends into the empty groove, and a; the pushing block is extruded by the moving rod and then drives the shifting rod to rotate, so that the inserting block is controlled to be separated from the through hole, and the recovery box is unlocked.

Wherein, the power conversion device comprises a conversion cavity communicated with the recovery cavity, the rear end of the rotating shaft extends into the conversion cavity and is fixedly provided with a first gear, the rear end of the transmission shaft extends into the conversion cavity and is fixedly provided with a second gear, a conversion block is arranged in the conversion cavity in a sliding manner, a power gear is arranged in the conversion block in a rotating manner and can be meshed with the second gear and the first gear, the axis of the power gear is connected with a spline shaft through a spline, the front end of the spline shaft is rotationally connected with the front end wall of the conversion cavity, the rear end wall of the conversion cavity is fixedly provided with a power motor, the rear end of the spline shaft is dynamically connected with the power motor, the spline shaft is rotationally connected with the conversion block in a sliding manner, the right end wall of the conversion cavity is provided with a transmission gear, the left end of the transmission gear is meshed with the conversion block, and, the front end surface of the transmission bevel gear is fixedly provided with a mandrel, and the mandrel is in power connection with the gear rotating shaft through a belt; the power motor respectively drives the recovery block to rotate to adjust the magnetic attraction angle and the conveying belt to rotate to recover metal.

Preferably, the transmission gear is formed by vertically and fixedly connecting a bevel gear and a straight gear.

The invention has the beneficial effects that: according to the invention, the magnetic metal object is recovered through the magnetic attraction of the metal, the magnetic attraction device can directly recover the metal object and collect the metal object, the recovery block is contracted in the machine body, the device can be protected from being damaged, and then the angle of the recovery block can be adjusted according to the actual road condition and the coverage thickness of the metal object on the ground, so that the adsorption recovery rate of the metal is maximized, and the recovery box is separable from the machine body, convenient to assemble and disassemble and convenient to operate.

Drawings

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

FIG. 1 is a schematic view of the overall structure of a waste metal recovery apparatus of a heavy industry plant according to the present invention;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

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

FIG. 4 is a schematic view of the structure in the direction "C-C" of FIG. 1;

FIG. 5 is a schematic view of the structure in the direction "D-D" of FIG. 4.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, for ease of description, the orientations described below will now be 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 invention relates to a waste metal recovery device for a heavy factory, which is mainly used for the recovery work of waste magnetic metal in the heavy factory, and the invention is further explained by combining the attached drawings of the invention:

the invention relates to a waste metal recovery device for a heavy industry plant, which comprises a machine body 10, wherein four corners of the lower end surface of the machine body 10 are respectively provided with rolling wheels 11, a recovery cavity 12 is arranged in the machine body 10, a recovery block 14 is rotatably arranged in the recovery cavity 12 through a rotating shaft 13, a transmission shaft 21 is rotatably arranged in the rotating shaft 13, a power conversion device 901 is arranged at the rear side of the recovery cavity 12, the transmission shaft 21 and the rotating shaft 13 are in power connection with the power conversion device 901, a magnetic strip 16 is arranged in the recovery block 14, a conveying belt 15 is sleeved on the periphery of the recovery block 14, a rotating cavity 17 is arranged in the right end surface of the recovery block 14, a rotating gear 19 is rotatably arranged in the rotating cavity 17 through a connecting shaft 18, the rotating gear 19 is meshed with the inner end surface of the conveying belt 15, and the connecting shaft 18 is in power, a moving cavity 40 is arranged on the right side of the recycling cavity 12, a fixed block 49 is fixedly arranged on the left end wall of the moving cavity 40, a moving device 902 is arranged in the moving cavity 40, the fixed block 49 is abutted against the moving device 902, a collecting device 903 is arranged on the lower side of the moving cavity 40, a locking device 904 is arranged on the collecting device 903, a power transmission device 905 is arranged on the right side of the moving cavity 40, and the power transmission device 905 is used for connecting the locking device 904 with the moving device 902; the recycling block 14 is inclined and the lower end of the recycling block is close to the ground, so that the metal objects with magnetic attraction can be adsorbed on the conveying belt 15 through the magnetic attraction of the magnetic strip 16, and finally the metal objects are recycled through the collecting device 903.

Advantageously, the magnetic strip 16 is arranged at the left position of the rotating gear 19, so that the metal blocks on the conveyor belt 15 are conveyed to the position of the rotating gear 19, lose the magnetic adsorption force and enter the collecting device 903 for recovery.

According to an embodiment, the moving device 902 is described in detail below, the moving device 902 includes a moving rod 44, a telescopic hole 45 is provided in the moving rod 44, a telescopic rod 46 is slidably provided in the telescopic hole 45, a lower end of the telescopic rod 46 is hinged to the collecting device 903, a telescopic spring 47 is fixedly provided between an upper end of the telescopic rod 46 and the telescopic hole 45, a through groove 48 is provided in the telescopic rod 46, the through groove 48 abuts against the fixed block 49, a moving space 42 is provided in communication with an upper side of the moving cavity 40, a moving screw 43 is rotatably provided in the moving space 42, an upper end of the moving rod 44 is in threaded connection with the moving screw 43, a moving motor 39 is fixedly provided on a left end wall of the moving space 42, a left end of the moving screw 43 is dynamically connected to the moving motor 39, a squeezing groove 34 is provided in communication with a left side of the moving cavity 40, and a squeezing rod 41 is, the right end of the extrusion rod 41 is abutted against the movable rod 44, a rack 37 is arranged on the left side of the extrusion rod 41, a pressure spring 38 is fixedly arranged between the rack 37 and the extrusion rod 41, a meshing gear 35 is rotatably arranged on the lower end wall of the extrusion groove 34, the meshing gear 35 is meshed with the rack 37, a gear rotating shaft 36 is fixedly arranged at the axis of the meshing gear 35, and the gear rotating shaft 36 is in power connection with the power conversion device 901; the collection device 903 can be operated by moving the moving rod 44, and the pressing rod 41 is pushed by the moving rod 44 to move, so that the power conversion device 901 performs power conversion through transmission.

According to an embodiment, a detailed description is given below on the collecting device 903, where the collecting device 903 includes a connecting cavity 71 communicated with the moving cavity 40, a connecting plate 70 is rotatably disposed in the connecting cavity 71, a sliding gap 72 is disposed in the connecting plate 70, a right end of the connecting plate 70 is hinged to a lower end of the telescopic rod 46, a recycling box 68 is disposed at a lower side of the connecting cavity 71, locking blocks 66 symmetrical front and back are fixedly disposed on an upper end surface of the recycling box 68, a through hole 67 is disposed in the locking block 66, the through hole 67 is inserted into the locking device 904, a cavity 69 is disposed in the recycling box 68, and the cavity 69 is communicated with the connecting cavity 71; the metal on the conveyor belt 15 enters the recycling bin 68 through the connecting plate 70 for recycling and storage.

According to an embodiment, the locking device 904 is described in detail below, the locking device 904 includes a locking cavity 65 that is symmetrical front and back, the locking block 66 extends into the locking cavity 65, one side of the locking cavity 65, which is far away from the center of symmetry, is provided with a sliding groove 61 in a communicating manner, an insertion block 62 is slidably arranged in the sliding groove 61, one end of the insertion block 62, which is close to the locking cavity 65, extends into the through hole 67, the other end of the insertion block 62 is fixedly provided with a torsion spring 64, and the torsion spring 64 is provided with a hollow groove 63; the inserting block 62 is inserted into the through hole 67 to lock the recycling bin 68.

According to the embodiment, the power transmission device 905 is described in detail below, the power transmission device 905 includes a push groove 50 communicated with the moving cavity 40, a push block 51 is slidably disposed in the push groove 50, a first reset component 52 for resetting the push block 51 is fixedly disposed on an upper end surface of the push block 51, a slide bar groove 55 is disposed on a lower side of the push groove 50 in communication, a connecting slide bar 53 is slidably disposed in the slide bar groove 55, a second reset component 54 for resetting the connecting slide bar 53 is fixedly disposed on a right end surface of the connecting slide bar 53, a rotation groove 58 symmetrical in front and back is communicated with a lower side of the slide bar groove 55, a push rod 56 is slidably disposed between the rotation groove 58 and the slide bar groove 55, a third reset component 57 for resetting the push rod 56 is fixedly disposed on a right end surface of the push rod 56, a shift lever 59 is rotatably disposed in the rotation groove 58, a rear end of the shift lever 59 extends into the empty groove 63, a rotating spring 60 is fixedly arranged between the shift lever 59 and the rotating groove 58; after the pushing block 51 is pressed by the moving rod 44, the shifting lever 59 is driven to rotate, and the inserting block 62 is controlled to be separated from the through hole 67, so that the recycling box 68 is unlocked.

According to the embodiment, the power conversion device 901 is described in detail below, the power conversion device 901 includes a conversion cavity 22 communicated with the recovery cavity 12, the rear end of the rotating shaft 13 extends into the conversion cavity 22 and is fixedly provided with a first gear 23, the rear end of the transmission shaft 21 extends into the conversion cavity 22 and is fixedly provided with a second gear 24, a conversion block 25 is slidably provided in the conversion cavity 22, a power gear 26 is rotatably provided in the conversion block 25, the power gear 26 can be meshed with the second gear 24 and the first gear 23, a spline shaft 27 is splined to the axis of the power gear 26, the front end of the spline shaft 27 is rotatably connected with the front end wall of the conversion cavity 22, a power motor 28 is fixedly provided on the rear end wall of the conversion cavity 22, the rear end of the spline shaft 27 is power connected with the power motor 28, and the spline shaft 27 is slidably connected with the conversion block 25, a transmission gear 30 is rotatably arranged in the right end wall of the conversion cavity 22, the left end of the transmission gear 30 is meshed with the conversion block 25, the front side of the transmission gear 30 is meshed and connected with a transmission bevel gear 31, the front end face of the transmission bevel gear 31 is fixedly provided with a mandrel 32, and the mandrel 32 is in power connection with the gear rotating shaft 36 through a belt 33; the power motor 28 respectively drives the recovery block 14 to rotate to adjust the magnetic attraction angle and the conveying belt 15 to rotate to recover metal.

Advantageously, the transmission gear 30 is composed of a bevel gear and a straight gear which are fixedly connected up and down.

The following detailed description of the steps of a heavy-duty plant scrap metal recycling apparatus will be provided with reference to fig. 1 to 5: at the beginning, power gear 26 and the meshing of first gear 23, then power motor 28 work drive first gear 23 rotates for axis of rotation 13 rotates, then retrieves piece 14 and rotates certain angle, makes and retrieves that piece 14 left end is close but not the butt with ground, then can adsorb the metal that has magnetism on conveyer belt 15 through the magnetic attraction of magnetic strip 16, can promote organism 10 free movement through rolling wheel 11, carries out the metal recovery work of large tracts of land.

During recovery, the moving motor 39 works to drive the moving screw 43 to rotate, the moving rod 44 moves leftwards, the connecting plate 70 is driven to move leftwards through the telescopic rod 46, the telescopic rod 46 moves leftwards and descends simultaneously under the action of the fixed block 49, the connecting plate 70 rotates leftwards movably, the left end of the connecting plate 70 is positioned at the lower side position of the right end of the recovery block 14, the moving distance of the moving rod 44 can be controlled according to the inclination angle of the recovery block 14, so that the moving and inclination angles of the connecting plate 70 are controlled, the extrusion rod 41 moves leftwards in the moving process of the moving rod 44, the rack 37 is pushed to move leftwards, the meshing gear 35 rotates, the transmission gear 30 is driven to rotate through the belt 33, the conversion block 25 moves backwards, the power gear 26 is meshed with the second gear 24, the power motor 28 works to drive the second gear 24 to rotate, the transmission shaft 21 drives the connecting shaft 18 to rotate, the conveyer belt 15 rotates, the metal objects on the conveyer belt 15 lose adsorption force when being transported to the right end of the recovery block 14, and the metal objects enter the cavity 69 through the connecting plate 70 to be collected; after the collection is finished, the moving motor 39 works reversely, so that the moving rod 44 moves rightwards and the extrusion pushing block 51 moves rightwards, the push rod 56 connected with the sliding rod 53 descends and extrudes forwards and backwards moves backwards, the push rod 56 pushes the shifting rod 59 to rotate, the shifting rod 59 shifts the insertion block 62 to move, so that the insertion block 62 is separated from the through hole 67, the recovery box 68 is pulled downwards to separate the recovery box 68 from the machine body 10, metal objects in the cavity 69 can be unloaded, at the moment, the power gear 26 is meshed with the first gear 23, the power motor 28 works reversely to drive the recovery block 14 to rotate to the initial position, and the recovery block 14 retracts into the recovery cavity 12.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims

1. A waste metal recovery device for heavy industry plants comprises a machine body; four corners of the lower end surface of the machine body are respectively provided with rolling wheels, a recovery cavity is arranged in the machine body, a recovery block is rotatably arranged in the recovery cavity through a rotating shaft, and a transmission shaft is rotatably arranged in the rotating shaft; the rear side of the recovery cavity is provided with a power conversion device, the transmission shaft and the rotating shaft are in power connection with the power conversion device, a magnetic strip is arranged in the recovery block, a conveying belt is sleeved on the periphery of the recovery block, a rotating cavity is arranged in the right end face of the recovery block, a rotating gear is rotatably arranged in the rotating cavity through a connecting shaft, the rotating gear is meshed with the inner end face of the conveying belt, and the connecting shaft is in power connection with the transmission shaft through a synchronous toothed belt; a movable cavity is arranged on the right side of the recovery cavity, a fixed block is fixedly arranged on the left end wall of the movable cavity, a movable device is arranged in the movable cavity, the fixed block is abutted against the movable device, a collecting device is arranged on the lower side of the movable cavity, a locking device is arranged on the collecting device, and a power transmission device is arranged on the right side of the movable cavity and is used for connecting the locking device with the movable device; the magnetic strip is arranged at the left position of the rotating gear; the moving device comprises a moving rod; a telescopic hole is formed in the moving rod, a telescopic rod is arranged in the telescopic hole in a sliding mode, the lower end of the telescopic rod is hinged to the collecting device, a telescopic spring is fixedly arranged between the upper end of the telescopic rod and the telescopic hole, a through groove is formed in the telescopic rod, and the through groove is abutted to the fixed block; the upper side of the moving cavity is communicated with a moving space, a moving screw rod is rotatably arranged in the moving space, the upper end of the moving rod is in threaded connection with the moving screw rod, a moving motor is fixedly arranged on the left end wall of the moving space, and the left end of the moving screw rod is in power connection with the moving motor; an extrusion groove is formed in the left side of the moving cavity in a communicated manner, an extrusion rod is arranged in the extrusion groove in a sliding manner, the right end of the extrusion rod is abutted to the moving rod, a rack is arranged on the left side of the extrusion rod, and a pressure spring is fixedly arranged between the rack and the extrusion rod; a meshing gear is rotatably arranged on the lower end wall of the extrusion groove and meshed with the rack, a gear rotating shaft is fixedly arranged at the axis of the meshing gear and is in power connection with the power conversion device; the collecting device comprises a connecting cavity communicated with the moving cavity; a connecting plate is rotatably arranged in the connecting cavity, a sliding gap is arranged in the connecting plate, and the right end of the connecting plate is hinged with the lower end of the telescopic rod; a recycling box is arranged on the lower side of the connecting cavity, locking blocks which are symmetrical in front and back are fixedly arranged on the upper end face of the recycling box, a through hole is formed in each locking block, each through hole is connected with the corresponding locking device in an inserting mode, a cavity is formed in the recycling box, and the cavity is communicated with the connecting cavity; the locking device comprises a locking cavity which is symmetrical front and back; the locking block extends into the locking cavity, one side of the locking cavity, which is far away from the symmetry center, is communicated with a sliding groove, an inserting block is arranged in the sliding groove in a sliding mode, one end, close to the locking cavity, of the inserting block extends into the through hole, the other end of the inserting block is fixedly provided with a torsion spring, and a hollow groove is formed in the torsion spring; the power transmission device comprises a pushing groove communicated with the moving cavity; a pushing block is arranged in the pushing groove in a sliding mode, and a first resetting component used for resetting the pushing block is fixedly arranged on the upper end face of the pushing block; a sliding rod groove is formed in the lower side of the pushing groove in a communicated manner, a connecting sliding rod is arranged in the sliding rod groove in a sliding manner, and a second resetting component for resetting the connecting sliding rod is fixedly arranged on the right end face of the connecting sliding rod; the lower side of the sliding rod groove is communicated with a rotating groove which is symmetrical front and back, a push rod is arranged between the rotating groove and the sliding rod groove in a sliding manner, a third reset assembly for resetting the push rod is fixedly arranged on the right end face of the push rod, a deflector rod is rotatably arranged in the rotating groove, the rear end of the deflector rod extends into the hollow groove, and a rotating spring is fixedly arranged between the deflector rod and the rotating groove; the power conversion device comprises a conversion cavity communicated with the recovery cavity; the rear end of the rotating shaft extends into the conversion cavity and is fixedly provided with a first gear, the rear end of the transmission shaft extends into the conversion cavity and is fixedly provided with a second gear, a conversion block is arranged in the conversion cavity in a sliding manner, a power gear is rotatably arranged in the conversion block and can be meshed with the second gear and the first gear, a spline shaft is connected to the axis of the power gear through a spline, and the front end of the spline shaft is rotatably connected with the front end wall of the conversion cavity; a power motor is fixedly arranged on the rear end wall of the conversion cavity, the rear end of the spline shaft is in power connection with the power motor, and the spline shaft is in sliding connection with the conversion block; a transmission gear is rotatably arranged in the right end wall of the conversion cavity, the left end of the transmission gear is meshed with the conversion block, the front side of the transmission gear is meshed and connected with a transmission bevel gear, the front end face of the transmission bevel gear is fixedly provided with a mandrel, and the mandrel is in power connection with the gear rotating shaft through a belt; the transmission gear is formed by fixedly connecting a bevel gear and a straight gear up and down.