CN114260519A - Gear machining apparatus - Google Patents

Abstract

The invention discloses gear processing equipment, which comprises a bottom plate, wherein a connecting cylinder is arranged at the top of the bottom plate, symmetrical containing cavities are arranged at the top of the bottom plate, symmetrical side grooves are communicated and arranged in the front end wall and the rear end wall of the containing cavities, sliding convex plates are arranged in the side grooves in a sliding manner, a pushing sliding plate is arranged at one side of each sliding convex plate, containing cavities are arranged at the lower sides of the pushing sliding plates, the containing cavities at the front side and the rear side are connected in a sliding fit manner, an open matching groove is formed in each pushing sliding plate, an internal matching cavity is formed in the connecting cylinder, symmetrical driving gears are arranged in the internal matching cavity, the equipment can be used for containing gears with various specifications, and can keep more contact surfaces to increase the stability of containing when containing gears with different thicknesses in a containing process, and can also collect and regularly clean debris in a centralized manner, the scraps can be discharged by linkage sliding after being accumulated downwards.

Description

Gear machining apparatus

Technical Field

The invention relates to the technical field of gear machining equipment, in particular to gear machining equipment.

Background

The existing gear processing equipment has more defects, firstly, the common mode of clamping the gear adopts a mode of directly locking the gear onto a bracket by using a locking piece, but the mode of clamping the inside of the gear is not adopted to indirectly fix the gear, so that the stability of the gear during processing is lower, and due to the defects, the gear cannot keep good supporting stability during processing, and furthermore, because more chips are generated during the processing of the gear, generally, flowing cooling liquid adopted in the gear slotting processing can carry the chips to move after flowing and then be contained in a containing structure, and then in the process of milling the gear, a large amount of chips can be deposited in the containing structure during milling, and the chips can overflow during long-time processing, so that the cleaning is inconvenient, there is a certain probability that the debris will fly and then abrade the gear surface causing scratches.

Disclosure of Invention

The technical problem to be solved by the present invention is to provide a gear machining apparatus which can solve the above-mentioned problems in the prior art.

The invention is realized by the following technical scheme: the gear processing equipment comprises a bottom plate, wherein a connecting cylinder is arranged at the top of the bottom plate, symmetrical containing cavities are arranged at the top of the bottom plate, symmetrical side grooves are communicated and arranged in the front end wall and the rear end wall of the containing cavity, sliding convex plates are arranged in the side grooves in a sliding manner, a pushing sliding plate is arranged at one side of each sliding convex plate, containing cavities are arranged at the lower sides of the pushing sliding plates, the containing cavities at the front side and the rear side are connected in a sliding fit manner, an open matching groove is formed in each pushing sliding plate, an internal matching cavity is formed in the connecting cylinder, symmetrical driving gears are arranged in the internal matching cavities, the driving gears are driven by a motor to rotate, telescopic racks are arranged between the connecting cylinders in a meshing manner, the telescopic racks penetrate through the internal matching cavities and the connecting cylinder in a sliding manner, and the driving gears extend into the containing cavities, the telescopic rack is characterized in that symmetrical side convex plates are arranged on two sides of the telescopic rack, symmetrical abutting matching wheels are rotationally arranged in the side convex plates, the abutting matching wheels are connected with the matching grooves in an abutting rolling matching mode, and the containing cavity is of a fan-shaped structure.

The technical scheme is that a rotating shell is arranged on the outer surface of the connecting column in a rotating mode, an open loading inner cavity is formed in the rotating shell, a falling cavity is formed in one side of the loading inner cavity in a communicating mode, a connecting toothed ring is arranged on the inner side of the rotating shell, a side protruding block is arranged on one side of the connecting column, a top side motor is arranged in the side protruding block, a driving connecting gear is arranged on one side of the top side motor in a power connecting mode, the driving connecting gear is meshed with the connecting toothed ring and is arranged, a rotating connecting plate is arranged on the outer surface of the connecting column in a rotating mode, a sliding plate is arranged on one side of the rotating connecting plate and is abutted to the loading inner cavity, and a power device which enables the rotating connecting toothed ring to rotate is arranged on one side of the connecting column.

According to a further technical scheme, the power device comprises a matching toothed ring arranged on the lower side of the rotating connecting plate, a connecting fixing block is arranged on one side of the connecting cylinder, an intermediate connecting shaft is arranged in the connecting fixing block in a rotating mode, a side connecting gear is arranged on one side of the intermediate connecting shaft, the side connecting gear is meshed with the matching toothed ring, a bottom side gear is arranged on one side of the intermediate connecting shaft, and the bottom side gear is meshed with the connecting toothed ring.

Further technical scheme, it is provided with the fixed box of side to connect the cylinder top, be provided with four slide-out holes in the fixed box of side, slide-out hole ring distribution in the fixed box of side, the downthehole gliding slide that is provided with of slide-out, slide-out one side is provided with bottom dress card casing, be provided with downside barrel chamber in the bottom dress card casing, the gliding top centre gripping casing that is provided with in downside barrel chamber, be provided with in the fixed box of side and make all around the slide-out section of thick bamboo carries out the flexible drive arrangement that removes, be provided with between bottom dress card casing and the top centre gripping casing can still make after the top centre gripping casing stretches out top centre gripping casing one side and bottom dress card casing carry out the clamping device of centre gripping with the gear.

According to the technical scheme, the telescopic driving device comprises a transmission connecting inner cavity arranged in the side fixing box body, a bevel gear driving motor is arranged at the top of the side fixing box body, a driving bevel gear is arranged on one side of an output shaft of the bevel gear driving motor, symmetrical side-meshing bevel gears are arranged on two sides of the driving bevel gear in a meshing mode, a rotating threaded rod is arranged on one side of each side-meshing bevel gear, the rotating threaded rod is connected with the sliding-out hole in a rotating matching mode, and the rotating threaded rod is connected with an internal-matching threaded cavity in the sliding barrel in a threaded matching mode.

In a further technical scheme, the clamping device comprises an internal sliding cavity arranged in the top clamping shell, a threaded connecting hole positioned in the center of the internal sliding cavity is arranged in the top clamping shell, a plurality of side connecting grooves which are symmetrical up and down are arranged in the end wall of the internal sliding cavity, an extruding cylinder is arranged in the side connecting groove in a sliding manner, a matching connecting spring is elastically arranged between the extruding cylinder and the side connecting groove, an internal elastic cavity is arranged in the extrusion cylinder, a telescopic connecting block is arranged in the internal elastic cavity in a sliding way, a spring is elastically arranged between the telescopic connecting block and the inner elastic cavity, one side of the telescopic connecting block is provided with a matching inclined plane, and a telescopic abutting assembly which enables the extrusion cylinder to extend out to abut against the inside of the gear when the top clamping shell moves telescopically is arranged in the bottom clamping shell.

In a further technical scheme, the telescopic abutting component comprises a lower side cylinder cavity arranged in the bottom clamping shell, an internal driving motor is arranged in the lower end wall of the lower side cylinder cavity, one side of the internal driving motor is connected with a side output rod in a power way, the lower side cylinder cavity is connected with the top clamping shell in a sliding fit manner, the side output rod is connected with the threaded connecting hole in a threaded fit manner, a sliding rod is arranged in the end wall of the lower side cylinder cavity, a lifting driving motor is arranged in the end wall of the lower side cylinder cavity, one side of the lifting driving motor is connected with a transmission threaded rod in a power way, the outer surface of the sliding rod is provided with an extending ring cylinder in a sliding way, the stretching ring cylinder is in threaded fit connection with the transmission threaded rod, the stretching ring cylinder stretches into the inner sliding cavity in a sliding mode, and the stretching ring cylinder is abutted to the matching inclined plane.

The invention has the beneficial effects that:

the device is simple in structure, can clamp gears with various specifications, can keep more contact surfaces to increase clamping stability when clamping gears with different thicknesses, can collect and regularly clean scraps in a centralized manner, and can discharge the scraps by linkage sliding after the scraps are accumulated downwards.

When the equipment works, firstly, when the equipment is clamped according to gears of different specifications, firstly, the bevel gear driving motor drives the driving bevel gear to rotate after working, because the driving bevel gear is meshed with the side meshing bevel gear, the driving bevel gear drives the side meshing bevel gear to rotate, and after the rotating screw rod rotates, the rotating screw rod is in threaded fit connection with the internal fit threaded cavity, so that the sliding cylinder moves in the sliding hole in a telescopic way, the sliding cylinder can drive the bottom clamping shell and the top clamping shell to move in a telescopic way, the bottom clamping shell and the top clamping shell are in butt clamping with the inside of the gear, in the process, the internal driving motor drives the side output rod to rotate after working, because the side output rod is in threaded fit connection with the threaded connection hole, and the top clamping shell is connected with the bottom clamping shell in a sliding fit manner, so that the bottom clamping shell and the top clamping shell can be fully abutted against and clamped with the end face of a gear from the upper side and the lower side, in the process, the extruding cylinder in the top clamping shell can extend out of the top clamping shell and is abutted against the inside of the gear, in the process, the lifting driving motor drives the transmission threaded rod to rotate after working, so that the extending ring cylinder slides in the lower side cylinder cavity and the inner sliding cavity, the extending ring cylinder can be pushed upwards and is in contact with the matching inclined plane, the telescopic connecting block in the bottom clamping shell can firstly push the telescopic connecting block to be retracted into the inner elastic cavity, a spring in the inner elastic cavity is compressed, and the telescopic connecting block outside the bottom clamping shell is extruded by the extending ring cylinder to be stretched and stretched The telescopic connecting block can push the extruding cylinder under the action of the spring in the internal elastic cavity, the spring in the side connecting groove can be extruded, after the telescopic connecting block pushes the extruding cylinder, the extruding cylinder is enabled to be abutted against the inner wall of the gear, and the spring in the internal elastic cavity is pre-compressed, so that the pre-tightening degree of the extruding cylinder on one side of the top clamping shell against the inner wall of the gear is improved, the firmness of the top clamping shell and the bottom clamping shell for clamping the gear is improved, when the gear is machined by machining equipment in an external space, scraps can be generated to be retained in the loading inner cavity, the dropping cavity is a dropping hole, but the dropping cavity does not occupy the whole part in the loading inner cavity, and only occupies a part of the area on the lower side of the loading inner cavity, so that the sliding plate and the rotating shell need to be relatively rotated at this moment, so that the chips in the loading cavity can be uniformly distributed in the containing cavity to avoid excessive accumulation to influence the cleaning effect and further processing of the gear, at this time, the top side motor is operated to drive the active connecting gear to rotate, so that the active connecting gear drives the rotating shell to rotate through the connecting toothed ring, on the other hand, the bottom side gear is meshed with the connecting toothed ring, so that the bottom side gear drives the intermediate connecting shaft to rotate after rotating, the side connecting gear rotates after rotating, so that the side connecting gear drives the matching toothed ring to rotate after rotating, so that the rotating connecting plate rotates synchronously, and the chips in the loading cavity can be fully poured out from the falling cavity downwards due to the sliding of the sliding plate in the loading cavity by the rotating connecting plate, and the driving gear drives the telescopic rack to slide back and forth in the internal matching cavity and the containing cavity after working when the scraps in the containing cavity are clear, on one hand, one side of the pushing sliding plate is connected with the side groove in a sliding fit manner through the sliding convex plate, because the containing cavity is of a fan-shaped structure, the abutting matching wheels are connected with the matching grooves in a rolling matching way, the side convex plate and the propping and matching wheel can be driven to indirectly push the pushing and sliding plate to do telescopic movement in the process of the telescopic rack telescopic movement, the pushing sliding plates can slide mutually, so that the pushing sliding plates are abutted against the front end wall and the rear end wall of the containing cavity, the pushing sliding plates push the scraps out, and the design is designed to fully push the scraps out of the containing cavity after the scraps are removed.

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 internal overall structure of the gear processing apparatus of the present invention;

FIG. 2 is a schematic view at A in FIG. 1;

FIG. 3 is a schematic view at B of FIG. 1;

FIG. 4 is a schematic view at C of FIG. 1;

FIG. 5 is a schematic view at D of FIG. 1;

FIG. 6 is a schematic view of the direction E in FIG. 5;

FIG. 7 is a schematic view of FIG. 6 taken in the direction F;

in the figure, a connecting column 11, a bottom plate 12, a containing cavity 13, a side groove 14, a bottom clamping shell 15, a falling cavity 16, a loading inner cavity 17, a rotating shell 18, a top clamping shell 21, a threaded connecting hole 22, an internal sliding cavity 23, a sliding barrel 24, an internal matching threaded cavity 25, a rotating threaded rod 27, a sliding hole 28, a side fixing box 29, a sliding plate 31, an extending ring barrel 32, a transmission threaded rod 33, a side output rod 34, a lower side barrel cavity 35, a matching inclined plane 36, an extruding barrel 37, a side connecting groove 38, a matching connecting spring 39, a sliding rod 40, an internal driving motor 42, a lifting driving motor 43, an internal elastic cavity 44, a telescopic connecting block 45, a driving bevel gear 51, a bevel gear driving motor 52, a transmission connecting inner cavity 53, a side meshing bevel gear 54, a driving gear 61, a telescopic rack 62, a pushing sliding plate 63, a butting matching wheel 64, a side convex plate 65, a driving connecting gear 66, a sliding gear, a top side motor 67, a side convex block 68, a matching toothed ring 69, a rotating connecting plate 71, a side connecting gear 72, a connecting fixed block 73, an intermediate connecting shaft 74, a connecting toothed ring 75, a bottom side gear 77, an internal matching cavity 78, a matching groove 79 and a sliding convex plate 81.

Detailed Description

As shown in fig. 1 to 7, the present invention is explained in detail, and for convenience of description, the following orientations are defined as follows: the gear processing equipment comprises a bottom plate 12, wherein the top of the bottom plate 12 is provided with a connecting cylinder 11, the top of the bottom plate 12 is provided with symmetrical containing cavities 13, the front and rear end walls of the containing cavities 13 are communicated with symmetrical side grooves 14, the side grooves 14 are internally provided with sliding convex plates 81 in a sliding manner, one side of each sliding convex plate 81 is provided with a pushing sliding plate 63, the lower side of each pushing sliding plate 63 is provided with a containing cavity 13, the containing cavities 13 at the front and rear sides are connected in a sliding fit manner, the pushing sliding plates 63 are internally provided with open matching grooves 79, the connecting cylinder 11 is internally provided with an internal matching cavity 78, the internal matching cavity 78 is internally provided with symmetrical driving gears 61, and the driving gears 61 are driven by a motor to rotate, the meshing is provided with flexible rack 62 between the connection cylinder 11, the gliding passing of flexible rack 62 inside cooperation chamber 78 and connection cylinder 11, driving gear 61 stretches into hold in the chamber 13, flexible rack 62 both sides are provided with symmetrical side flange 65, the side flange 65 internal rotation be provided with the counterbalance cooperation wheel 64 of symmetry, counterbalance cooperation wheel 64 with cooperation groove 79 counterbalance roll cooperation is connected, it is fan-shaped structure to hold the chamber 13.

Advantageously, wherein the outer surface of said connecting cylinder 11 is rotatably provided with a rotating housing 18, an open loading inner cavity 17 is arranged in the rotating shell 18, a falling cavity 16 is communicated with one side of the loading inner cavity 17, the inner side of the rotating shell 18 is provided with a connecting gear ring 75, one side of the connecting cylinder 11 is provided with a side lug 68, a top motor 67 is arranged in the side lug 68, one side of the top motor 67 is dynamically connected with a driving connecting gear 66, the driving connecting gear 66 is engaged with the connecting gear ring 75, the outer surface of the connecting column 11 is rotatably provided with a rotating connecting plate 71, one side of the rotating connecting plate 71 is provided with a sliding plate 31, the sliding plate 31 is abutted against the loading inner cavity 17, a power device for transmitting the power of the rotation of the connecting gear ring 75 to the rotation of the rotating connecting plate 71 is arranged on one side of the connecting column 11.

Advantageously, the power device comprises a matching toothed ring 69 arranged on the lower side of the rotating connecting plate 71, a connecting fixing block 73 is arranged on one side of the connecting column 11, an intermediate connecting shaft 74 is arranged in the connecting fixing block 73 in a rotating mode, a side connecting gear 72 is arranged on one side of the intermediate connecting shaft 74, the side connecting gear 72 is arranged in a meshing mode with the matching toothed ring 69, a bottom side gear 77 is arranged on one side of the intermediate connecting shaft 74, and the bottom side gear 77 is arranged in a meshing mode with the connecting toothed ring 75.

Advantageously, wherein a side fixing box 29 is provided on the top of the connecting column 11, four slide-out holes 28 are provided in the side fixing box 29, the sliding holes 28 are annularly distributed in the side fixed box body 29, the sliding cylinders 24 are arranged in the sliding holes 28 in a sliding manner, a bottom clamping shell 15 is arranged on one side of the sliding barrel 24, a lower barrel cavity 35 is arranged in the bottom clamping shell 15, a top clamping shell 21 is arranged in the lower side cylinder cavity 35 in a sliding way, a telescopic driving device which can lead the sliding cylinder 24 at the periphery to perform telescopic movement is arranged in the side fixed box body 29, a clamping device which can still clamp one side of the top clamping shell 21 and the bottom clamping shell 15 with the gear after the top clamping shell 21 extends out is arranged between the bottom clamping shell 15 and the top clamping shell 21.

Advantageously, the telescopic driving device comprises a transmission connection inner cavity 53 arranged in the side fixing box body 29, a bevel gear driving motor 52 is arranged at the top of the side fixing box body 29, a driving bevel gear 51 is arranged on one side of an output shaft of the bevel gear driving motor 52, symmetrical side meshing bevel gears 54 are arranged on two sides of the driving bevel gear 51 in a meshing mode, a rotating threaded rod 27 is arranged on one side of the side meshing bevel gear 54, the rotating threaded rod 27 is in rotating fit connection with the sliding hole 28, and the rotating threaded rod 27 is in threaded fit connection with the internal matching threaded cavity 25 in the sliding barrel 24.

Advantageously, wherein the clamping means comprise an internal slide chamber 23 arranged inside said top clamping housing 21, a threaded connection hole 22 is formed in the top clamp housing 21 at the center of the internal slide cavity 23, a plurality of side connecting grooves 38 which are symmetrical up and down are arranged in the end wall of the inner sliding cavity 23, an extruding cylinder 37 is arranged in the side connecting grooves 38 in a sliding way, a matching connection spring 39 is elastically arranged between the extruding cylinder 37 and the side connection groove 38, an inner elastic cavity 44 is arranged in the extruding cylinder 37, a telescopic connecting block 45 is arranged in the inner elastic cavity 44 in a sliding way, a spring is elastically arranged between the telescopic connecting block 45 and the inner elastic cavity 44, one side of the telescopic connecting block 45 is provided with a matching inclined plane 36, a telescopic abutting component is arranged in the bottom clamping shell 15, and the top clamping shell 21 can enable the extrusion cylinder 37 to extend out to abut against the inside of the gear when in telescopic movement.

Beneficially, the telescopic abutting component includes a lower side cylinder cavity 35 disposed in the bottom clamping housing 15, an inner driving motor 42 is disposed in a lower end wall of the lower side cylinder cavity 35, a side output rod 34 is disposed in a power connection on one side of the inner driving motor 42, the lower side cylinder cavity 35 is connected with the top clamping housing 21 in a sliding fit manner, the side output rod 34 is connected with the threaded connection hole 22 in a threaded fit manner, a sliding rod 40 is disposed in an end wall of the lower side cylinder cavity 35, a lifting driving motor 43 is disposed in an end wall of the lower side cylinder cavity 35, a transmission threaded rod 33 is disposed in a power connection on one side of the lifting driving motor 43, an extending ring cylinder 32 is slidably disposed on an outer surface of the sliding rod 40, the extending ring cylinder 32 is connected with the transmission threaded rod 33 in a threaded fit manner, and the extending ring cylinder 32 slidably extends into the inner sliding cavity 23, the extending ring cylinder 32 is disposed against the matching inclined surface 36.

When the device is in an initial state, the device, the assembly and the structure are in a stop working state, the device can clamp gears of various specifications, the contact surface can be kept more to increase the clamping stability when the gears with different thicknesses are clamped, the device can also collect and regularly clean scraps in a centralized manner, and the scraps can be discharged by linkage sliding after being downwards accumulated.

When the equipment works, firstly, when the equipment is clamped according to gears of different specifications, firstly, the bevel gear driving motor 52 works to drive the driving bevel gear 51 to rotate, the driving bevel gear 51 is meshed with the side meshing bevel gear 54, so that the driving bevel gear 51 drives the side meshing bevel gear 54 to rotate, the rotating threaded rod 27 rotates, the rotating threaded rod 27 is in threaded fit connection with the internal matching threaded cavity 25, the sliding cylinder 24 performs telescopic movement in the sliding hole 28, the sliding cylinder 24 can drive the bottom clamping shell 15 and the top clamping shell 21 to perform telescopic movement, the bottom clamping shell 15 and the top clamping shell 21 are in abutting clamping with the inside of the gear, and the internal driving motor 42 works to drive the side output rod 34 to rotate in the process, because the side output rod 34 is in threaded fit connection with the threaded connection hole 22, and the top clamping shell 21 is in sliding fit connection with the bottom clamping shell 15, the bottom clamping shell 15 and the top clamping shell 21 can be fully abutted against and clamped on the end surface of a gear from the upper side and the lower side, in the process, the extrusion cylinder 37 in the top clamping shell 21 can extend out of the top clamping shell 21 to abut against the inside of the gear, in the process, the lifting drive motor 43 drives the transmission threaded rod 33 to rotate after working, so that the extension ring cylinder 32 slides in the lower side cylinder cavity 35 and the inner sliding cavity 23, the extension ring cylinder 32 can be pushed upwards and contacted with the fit inclined plane 36, and the extension connecting block 45 in the bottom clamping shell 15 firstly pushes the extension connecting block 45 and then retracts the extension connecting block 45 into the inner elastic cavity 44 and the inner elastic cavity 44 The spring in the sexual cavity 44 is compressed, the telescopic connecting block 45 positioned outside the bottom clamping shell 15 is extruded and stretched by the extending ring cylinder 32, the telescopic connecting block 45 can push the extruding cylinder 37 under the action of the spring in the internal elastic cavity 44, and the spring in the side connecting groove 38 is extruded, because the telescopic connecting block 45 pushes the extruding cylinder 37, the extruding cylinder 37 is abutted against the inner wall of the gear, and the spring in the internal elastic cavity 44 is pre-compressed, the pre-tightening degree of the extruding cylinder 37 at one side of the top clamping shell 21 against the inner wall of the gear is improved, the firmness degree of clamping the gear by the top clamping shell 21 and the bottom clamping shell 15 is improved, when the gear is machined by machining equipment in an external space, chips can be generated to be retained in the loading inner cavity 17, and the falling cavity 16 is a falling hole, however, the falling chamber 16 does not occupy the whole of the loading inner chamber 17, but only occupies a part of the area below the loading inner chamber 17, so that the sliding plate 31 and the rotating housing 18 are required to rotate relatively to make the debris in the loading inner chamber 17 uniformly distributed in the containing chamber 13 to avoid excessive accumulation and influence on the cleaning effect and further processing of the gears, then the top motor 67 is operated to drive the driving connecting gear 66 to rotate, so that the driving connecting gear 66 drives the rotating housing 18 to rotate through the connecting toothed ring 75, on the other hand, because the bottom gear 77 is meshed with the connecting toothed ring 75, the bottom gear 77 drives the intermediate connecting shaft 74 to rotate, and because the intermediate connecting shaft 74 rotates and then the side connecting gear 72 rotates, the rotating connecting plate 71 is rotated synchronously by the rotation of the side connecting gear 72 to drive the engaging gear ring 69 to rotate, the rotating connecting plate 71 can drive the sliding plate 31 to slide in the loading inner cavity 17, so that the scraps in the loading inner cavity 17 can be sufficiently dumped out from the falling cavity 16 and retained in the containing cavity 13, and when the scraps in the containing cavity 13 are cleared, the driving gear 61 is operated to drive the telescopic rack 62 to slide back and forth in the inner engaging cavity 78 and the containing cavity 13, on one hand, because the pushing sliding plate 63 side is connected with the side groove 14 in a sliding fit manner through the sliding convex plate 81, because the containing cavity 13 is of a fan-shaped structure, because the abutting engaging wheel 64 is connected with the engaging groove 79 in a rolling fit manner, the side protruding plates 65 and the abutting matching wheels 64 can be driven to indirectly enable the pushing sliding plates 63 to slide with each other after the pushing sliding plates 63 are telescopically moved in the process of telescopic movement of the telescopic rack 62, the pushing sliding plates 63 can abut against the front and rear end walls of the containing cavity 13 to enable the pushing sliding plates 63 to push out the scraps, and the design is designed to fully push out the scraps in the containing cavity 13 when the scraps are removed.

The above description is only an embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope defined by the claims.

Claims (7)

1. The gear processing equipment comprises a bottom plate, wherein a connecting cylinder is arranged at the top of the bottom plate, symmetrical containing cavities are arranged at the top of the bottom plate, symmetrical side grooves are communicated and arranged in front and rear end walls of the containing cavities, sliding convex plates are arranged in the side grooves in a sliding manner, a pushing sliding plate is arranged at one side of each sliding convex plate, containing cavities are arranged at the lower sides of the pushing sliding plates, the containing cavities at the front and rear sides are connected in a sliding fit manner, open matching grooves are formed in the pushing sliding plates, an internal matching cavity is formed in the connecting cylinder, symmetrical driving gears are arranged in the internal matching cavity and driven by a motor to rotate, telescopic racks are arranged between the connecting cylinders in a meshing manner, the telescopic racks penetrate through the internal matching cavity and the connecting cylinder in a sliding manner, and the driving gears extend into the containing cavities, the telescopic rack is characterized in that symmetrical side convex plates are arranged on two sides of the telescopic rack, symmetrical abutting matching wheels are rotationally arranged in the side convex plates, the abutting matching wheels are connected with the matching grooves in an abutting rolling matching mode, and the containing cavity is of a fan-shaped structure.

2. The gear processing apparatus of claim 1, wherein: the connecting cylinder body is provided with a rotating shell in a rotating mode, an open loading inner cavity is formed in the rotating shell, one side of the loading inner cavity is communicated with a falling cavity, a connecting toothed ring is arranged on the inner side of the rotating shell, a side protruding block is arranged on one side of the connecting cylinder body, a top side motor is arranged in the side protruding block, a driving connecting gear is arranged on one side of the top side motor in a power connection mode, the driving connecting gear is meshed with the connecting toothed ring, a rotating connecting plate is arranged on the outer surface of the connecting cylinder body in a rotating mode, a sliding plate is arranged on one side of the rotating connecting plate and abuts against the loading inner cavity, and a power device which enables the rotating connecting plate to rotate is arranged on one side of the connecting cylinder body in a transmission mode.

3. The gear processing apparatus of claim 2, wherein: the power device comprises a matching toothed ring arranged on the lower side of the rotating connecting plate, a connecting fixed block is arranged on one side of the connecting cylinder, an intermediate connecting shaft is arranged in the connecting fixed block in a rotating mode, a side connecting gear is arranged on one side of the intermediate connecting shaft, the side connecting gear is meshed with the matching toothed ring, a bottom side gear is arranged on one side of the intermediate connecting shaft, and the bottom side gear is meshed with the connecting toothed ring.

4. The gear processing apparatus of claim 3, wherein: connect the cylinder top and be provided with the fixed box of side, be provided with four slide holes in the fixed box of side, slide hole ring type distribution in the fixed box of side, the downthehole gliding slide that is provided with of slide, slide one side is provided with bottom dress card casing, be provided with downside barrel cavity in the bottom dress card casing, the gliding top centre gripping casing that is provided with in downside barrel cavity, be provided with in the fixed box of side and make all around the slide section of thick bamboo carries out the flexible drive arrangement that removes, be provided with between bottom dress card casing and the top centre gripping casing can still make after the top centre gripping casing stretches out top centre gripping casing one side and bottom dress card casing carry out the clamping device of centre gripping with the gear.

5. The gear processing apparatus of claim 4, wherein: the telescopic driving device comprises a transmission connecting inner cavity arranged in the side fixing box body, a bevel gear driving motor is arranged at the top of the side fixing box body, a driving bevel gear is arranged on one side of an output shaft of the bevel gear driving motor, symmetrical side-meshing bevel gears are arranged on two sides of the driving bevel gear in a meshed mode, a rotating threaded rod is arranged on one side of the side-meshing bevel gear, the rotating threaded rod is connected with the sliding-out hole in a rotating matched mode, and the rotating threaded rod is connected with an internal matching threaded cavity in the sliding barrel in a threaded matched mode.

6. The gear processing apparatus of claim 4, wherein: the clamping device comprises an internal sliding cavity arranged in a top clamping shell, a threaded connecting hole located in the center of the internal sliding cavity is formed in the top clamping shell, a plurality of vertically symmetrical side connecting grooves are formed in the end wall of the internal sliding cavity, an extruding cylinder is arranged in the side connecting grooves in a sliding mode, a matching connecting spring is elastically arranged between the extruding cylinder and the side connecting grooves, an internal elastic cavity is formed in the extruding cylinder, a telescopic connecting block is arranged in the internal elastic cavity in a sliding mode, a spring is elastically arranged between the telescopic connecting block and the internal elastic cavity, a matching inclined surface is arranged on one side of the telescopic connecting block, and a telescopic abutting component which abuts against the inside of a gear can be made when the top clamping shell moves telescopically.

7. The gear processing apparatus of claim 6, wherein: the flexible subassembly that offsets including set up in downside barrel cavity in the bottom dress card casing, be provided with inside driving motor in the end wall under the downside barrel cavity, inside driving motor one side power connection is provided with the side delivery rod, downside barrel cavity with top centre gripping casing sliding fit connects, the side delivery rod with threaded connection hole screw-thread fit connects, be provided with the slide bar in the downside barrel cavity end wall, be provided with lift driving motor in the downside barrel cavity end wall, lift driving motor one side power connection is provided with the transmission threaded rod, the gliding being provided with of slide bar surface stretches into the ring section of thick bamboo, stretch into the ring section of thick bamboo with transmission threaded rod screw-thread fit connects, stretch into the gliding of ring section of thick bamboo and stretch into in the inside sliding cavity, stretch into the ring section of thick bamboo with the setting is offset to the cooperation inclined plane.

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