CN114290068A - Device for manufacturing gears in batches - Google Patents

Abstract

The present invention relates to a manufacturing apparatus, and more particularly, to a device for manufacturing gears in batch. The invention aims to provide a device for manufacturing gears in batches with high working efficiency without consuming much time and labor. The utility model provides a batched manufacturing installation of gear, is connected with linking frame on the protective frame including protective frame, linking frame, lead screw, stamping die, transport mechanism, feeding mechanism etc. and the slidingtype of evenly arranging about linking frame's both sides all is connected with two at least lead screws, and one side of lead screw all is equipped with stamping die, is equipped with the transport mechanism of transportable gear on the protective frame, is equipped with the feeding mechanism of transportable material on the protective frame. The staff just can realize gear moulding-die through control motor to the gear and the surplus material that will make are moved the transportation to the left side automatically, and easy operation is convenient and work efficiency is high.

Description

Device for manufacturing gears in batches

Technical Field

The present invention relates to a manufacturing apparatus, and more particularly, to a device for manufacturing gears in batch.

Background

In mechanical equipment, often can use the gear, therefore the preparation of gear is indispensable, but the preparation gear is generally comparatively troublesome, needs to make the suitable blank of size earlier, then draws out the profile of tooth pattern on the blank, then uses cutting means to carry out the punching a design according to the profile of tooth pattern, and the shaping of polishing is carried out to instruments such as use file at last again, consequently normally makes gear work efficiency low, and need consume more time and manpower, is unfavorable for the big batch preparation of gear.

Therefore, it is necessary to design a mass manufacturing apparatus for gears which does not require much time and labor and has high work efficiency.

Disclosure of Invention

In order to overcome the defects that the normal manufacturing of gears is low in working efficiency, needs to consume more time and labor and is not beneficial to the mass manufacturing of the gears, the invention aims to provide a device for manufacturing the gears in batches, which does not need to consume more time and labor and has high working efficiency.

The technical scheme is as follows: the utility model provides a batchization manufacturing installation of gear, including the bearer frame, link up the frame, the lead screw, stamping die, transport mechanism, feeding mechanism, intermittent type pushes down complementary unit and fixed establishment, be connected with linking frame on the bearer frame, the slidingtype of align to grid about linking both sides all is connected with two at least lead screws, one side of lead screw all is equipped with stamping die, be equipped with the transport mechanism of transportable gear on the bearer frame, be equipped with the feeding mechanism that can carry the material on the bearer frame, be equipped with between lead screw and the feeding mechanism and drive stamping die and carry out the intermittent type of moulding-die and push down complementary unit, the last fixed establishment that is equipped with fixable material of feeding mechanism.

As the improvement of above-mentioned scheme, transport mechanism is including first support frame, carry axle, conveyer belt, motor and first drive assembly, and the both sides of bearer bar all are connected with two at least first support frames, and equal rotary type is connected with between the first support frame of homonymy and carries the axle, carries and is connected with the conveyer belt between the axle, is equipped with the motor on the bearer bar, is connected with first drive assembly between the output shaft of motor and the transport axle of one side.

As an improvement of the proposal, the feeding mechanism comprises a second supporting frame, a first rotating shaft, a second rotating shaft, a first gear, a second transmission component, a third rotating shaft, a second gear, a first missing tooth, a second missing tooth, a third gear, a third transmission component, a fourth gear, a fifth gear, a conveying wheel, a fourth transmission component, a fifth transmission component, a first fixing frame and a sixth transmission component, wherein the second supporting frame is connected on the protective frame, the first rotating shaft is rotationally connected on the second supporting frame, the second rotating shaft is rotationally connected on the second supporting frame, the first gear is connected on both sides of the first rotating shaft, the third rotating shaft is rotationally connected on the protective frame, the second transmission component is connected between the third rotating shaft and both sides of the first rotating shaft, the second gear is connected on both sides of the third rotating shaft, the first missing tooth is connected on both sides of the second rotating shaft, the second missing tooth is connected on both sides of the second rotating shaft, the second missing teeth are all positioned at the outer side of the first missing teeth, the first missing teeth are matched with the first gear at the same side, the second supporting frame is rotatably connected with a first rotating rod, the first rotating rod is connected with a third gear, the third gear is matched with the second missing teeth at the front side, both sides of the connecting frame are respectively connected with a first fixing frame, the first fixing frame at one side is rotatably connected with a fourth gear, a third transmission assembly is connected between the fourth gear and the first rotating rod, at least two conveying wheels are rotatably connected on the first fixing frame at uniform intervals, the conveying wheel of one of them is connected with the fifth gear, and fifth gear and fourth gear meshing, the equal spaced rotary type all is connected with two at least second bull sticks on the first mount, all is connected with fourth transmission assembly between the conveying wheel of second bull stick and homonymy, all is connected with fifth transmission assembly between two adjacent second bull sticks, carries to be connected with sixth transmission assembly between axle and the second pivot.

As the improvement of above-mentioned scheme, the intermittent type pushes down complementary unit is including the rack, first spring, nut and fixed plate, the equal slidingtype in both sides that links up the frame is connected with the rack, the both sides that link up the frame all are equipped with the fixed plate, all be connected with first spring between rack and the homonymy fixed plate, the both sides that link up the frame all evenly spaced rotary type is connected with two at least nuts, the outside of nut all is equipped with the insection, the insection with all with homonymy rack toothing, the nut all cup joints on corresponding the lead screw through the screw thread.

As the improvement of the scheme, the fixing mechanism comprises a second fixing frame, second springs, a first pressing block, a third spring and a second pressing block, wherein the two sides of the first fixing frame are connected with the second fixing frame, the second fixing frame is rotatably connected with the first pressing block, the third spring is connected between the first pressing block and the second fixing frame, the second fixing frame is connected with the upper second springs and the lower second springs, and the second pressing block is connected between the upper second springs and the lower second springs.

As the improvement of the scheme, the cutting device comprises a cutting mechanism, wherein the cutting mechanism comprises a supporting seat, a convex block, a sixth gear, a seventh transmission assembly and a cutter, the supporting seat is connected to the protective frame, the convex block is connected to the supporting seat in a rotating mode, the sixth gear is connected to the first supporting frame on one side in a rotating mode, the seventh transmission assembly is connected between the sixth gear and the convex block, the cutter is connected to the supporting seat in a sliding mode, and the cutter is matched with the convex block.

As an improvement of the scheme, the polishing device comprises a polishing mechanism, the polishing mechanism comprises a third support frame, a conveying frame, a seventh gear, an eighth transmission component, a first bevel gear frame, a second bevel gear frame, a ninth transmission component and a polisher, the third support frame is connected to a protection frame, the conveying frame is connected to the third support frame, the seventh gear is connected to the leftmost conveying shaft, the sixth gear is matched with the seventh gear, the first bevel gear frame is connected to the support seat in a rotating mode, the eighth transmission component is connected between the first bevel gear frame and the conveying shaft, the second bevel gear frame is arranged on the third support frame in a rotating mode, the polisher is located on the front side of the second bevel gear frame, and the ninth transmission component is connected between the polisher and the second bevel gear frame.

As the improvement of the scheme, the lower side of the first pressing block is connected with the roller in a rotating mode.

The invention has the following advantages: 1. the staff just can realize gear moulding-die through control motor to the gear and the surplus material that will make are moved the transportation to the left side automatically, and easy operation is convenient and work efficiency is high.

2. When placing the material piece on the second support frame, make first briquetting push down the material piece automatically because of the resilience force of third spring, still can make the second briquetting clip the material piece because of the resilience force of second spring simultaneously to slightly fix the material piece, and then prevent when the moulding-die, the material piece removes and leads to the moulding-die effect not good.

3. The motor is started, and the sander can be driven to operate, so that the gear which is pressed out of the die can be contacted with the sander when being transported to the left side, and the surface of the gear is automatically sanded.

4. The motor is started, and the cutter can be driven to move up and down continuously, so that the material blocks can be cut up and recovered automatically when the residual materials are transported to the left side.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a third perspective view of the present invention.

Fig. 4 is a schematic diagram of a fourth three-dimensional structure according to the present invention.

Fig. 5 is a schematic perspective view of a first embodiment of the transfer mechanism of the present invention.

Fig. 6 is a schematic perspective view of a second embodiment of the conveying mechanism of the present invention.

Fig. 7 is a schematic perspective view of a first feeding mechanism of the present invention.

Fig. 8 is a schematic perspective view of a second feeding mechanism of the present invention.

Fig. 9 is a schematic perspective view of the intermittent pressing auxiliary mechanism of the present invention.

Fig. 10 is a first perspective view of the fixing mechanism of the present invention.

Fig. 11 is a schematic perspective view of a second fixing mechanism of the present invention.

Fig. 12 is a schematic perspective view of a first cutting mechanism according to the present invention.

Fig. 13 is a schematic perspective view of a second cutting mechanism according to the present invention.

Fig. 14 is a schematic perspective view of a first polishing mechanism according to the present invention.

Fig. 15 is a schematic perspective view of a second grinding mechanism according to the present invention.

In the above drawings: 1: protective frame, 2: linking frame, 3: screw rod, 4: stamping die, 5: transport mechanism, 51: first support bracket, 52: conveying shaft, 53: conveyor belt, 54: motor, 55: first transmission assembly, 6: feeding mechanism, 61: second support frame, 62: first rotating shaft, 63: second rotating shaft, 64: first gear, 65: second transmission assembly, 66: third rotating shaft, 67: second gear, 68: first missing tooth, 69: second missing tooth, 610: third gear, 611: third transmission assembly, 612: fourth gear, 613: fifth gear, 614: delivery wheel, 615: fourth transmission assembly, 616: fifth transmission assembly, 617: first mount, 618: sixth transmission assembly, 7: intermittent press-down assist mechanism, 71: rack, 72: first spring, 73: nut, 74: fixing plate, 8: fixing mechanism, 81: second fixing frame, 82: second spring, 83: first briquette, 84: third spring, 85: second briquette, 9: cutting mechanism, 91: supporting seat, 92: bump, 93: sixth gear, 94: seventh transmission assembly, 95: a cutter, 10: grinding machanism, 101: third support, 102: carriage, 103: seventh gear, 104: eighth transmission assembly, 105: first cone carrier, 106: second bevel carrier, 107: ninth transmission assembly, 108: a sander.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Example 1

The utility model provides a batched manufacturing installation of gear, as shown in fig. 1-11, including the bearer bar 1, link up frame 2, lead screw 3, stamping die 4, transport mechanism 5, feeding mechanism 6, intermittent type pushes down complementary unit 7 and fixed establishment 8, the feed inlet has been opened on the bearer bar 1 right side, the upside of bearer bar 1 is connected with links up frame 2, the slidingtype of evenly arranging about both sides all is connected with four lead screws 3 around linking up frame 2, stamping die 4 all is equipped with to the downside of lead screw 3, be equipped with transport mechanism 5 on the bearer bar 1, be equipped with feeding mechanism 6 on the bearer bar 1, be equipped with intermittent type and push down complementary unit 7 between lead screw 3 and the feeding mechanism 6, be equipped with fixed establishment 8 on the feeding mechanism 6.

When the gears need to be manufactured in batches, the material block is placed on the feeding mechanism 6 through the feeding hole on the right side of the protective frame 1, the material block is located below the stamping die 4, meanwhile, the fixing mechanism 8 can slightly fix the material block, so that the situation that the stamping die effect is poor due to the movement of the material block in the stamping process is prevented, then, the transmission mechanism 5 can be controlled to operate, the transmission mechanism 5 can drive the intermittent pressing auxiliary mechanism 7 to operate firstly, the intermittent pressing auxiliary mechanism 7 can drive the screw rod 3 to move downwards, the stamping die 4 can move downwards, the material block can be stamped, further, the gears are manufactured, meanwhile, the gears after being stamped can fall on the transmission mechanism 5, the transmission mechanism 5 can output the manufactured gears to the left side out of the protective frame 1, and then the intermittent pressing auxiliary mechanism 7 is driven to automatically and reversely operate and reset, lead screw 3 and stamping die 4 can the rebound reset, and transport mechanism 5 just can drive feeding mechanism 6 and operate this moment, and then drives the material piece that the moulding-die was accomplished and move to the left side, and then can place next material piece, and then the device can repeat above-mentioned operation, and then carries out the mass production to the gear, and after the gear carries out the mass production completion, control transport mechanism 5 stop the operation can.

The conveying mechanism 5 comprises a first supporting frame 51, a conveying shaft 52, a conveying belt 53, a motor 54 and a first transmission assembly 55, three first supporting frames 51 are connected to the front side and the rear side of the interior of the protective frame 1, the conveying shaft 52 is rotatably connected between the upper sides of the first supporting frames 51 on the same longitudinal side, the conveying belt 53 is wound between the conveying shafts 52 through conveying rollers, the motor 54 is arranged on the front side of the lower right portion of the protective frame 1, the first transmission assembly 55 is connected between the output shaft of the motor 54 and the front side of the rightmost conveying shaft 52, the first transmission assembly 55 is respectively composed of two belt pulleys and a flat belt, one belt pulley is installed on the output shaft of the motor 54, the other belt pulley is installed on the front side of the rightmost conveying shaft 52, and the flat belt is wound between the two belt pulleys.

The feeding mechanism 6 comprises a second support frame 61, a first rotating shaft 62, a second rotating shaft 63, a first gear 64, a second transmission assembly 65, a third rotating shaft 66, a second gear 67, a first missing tooth 68, a second missing tooth 69, a third gear 610, a third transmission assembly 611, a fourth gear 612, a fifth gear 613, a conveying wheel 614, a fourth transmission assembly 615, a fifth transmission assembly 616, a first fixing frame 617 and a sixth transmission assembly 618, the middle part of the inner side of the protection frame 1 is connected with the second support frame 61, the right side of the second support frame 61 is rotatably connected with the first rotating shaft 62, the right part of the second support frame 61 is rotatably connected with the second rotating shaft 63, the second rotating shaft 63 is positioned at the lower left side of the first rotating shaft 62, the front side and the rear side of the first rotating shaft 62 are both connected with the first gear 64, the right upper side of the inner part of the protection frame 1 is rotatably connected with the third rotating shaft 66, the second transmission assembly 65 is connected between the third rotating shaft 66 and the front side and the rear side of the first rotating shaft 62, the second transmission assemblies 65 are also respectively composed of two belt pulleys and a flat belt, wherein one belt pulley is respectively arranged on a third rotating shaft 66, the other belt pulley is respectively arranged on the first rotating shaft 62, the flat belt is respectively wound between the two belt pulleys on the same longitudinal side, the front side and the rear side of the third rotating shaft 66 are respectively connected with a second gear 67, the front side and the rear side of the second rotating shaft 63 are respectively connected with a first gear notch 68, the front side and the rear side of the second rotating shaft 63 are respectively connected with a second gear notch 69, the second gear notch 69 is respectively positioned at the outer side of the first gear notch 68, the first gear notch 68 is matched with the first gear 64 on the same side, the left front side of the second supporting frame 61 is rotatably connected with a first rotating rod, the front side of the first rotating rod is connected with a third gear 610, the third gear 610 is matched with the second gear notch 69 on the front side, the front side and the rear side of the lower part of the linking frame 2 are respectively connected with a first fixing frame 617, the right lower front side of the first fixing frame 617 on the front side is rotatably connected with a fourth gear 612, a third transmission assembly 611 is connected between the fourth gear 612 and the first rotating rod, the third transmission assembly 611 is composed of two belt pulleys with different sizes and a flat belt, a small belt pulley is installed at the front side of the fourth gear 612, a large belt pulley is installed on the first rotating rod, the flat belt is wound between the two belt pulleys, five conveying wheels 614 are rotatably connected at the lower side of the first fixing frame 617 at even intervals, a fifth gear 613 is connected to the conveying wheel 614 at the front side of the right part, the fifth gear 613 is engaged with the fourth gear 612, five second rotating rods are rotatably connected at even intervals at the upper side of the first fixing frame 617, a fourth transmission assembly 615 is connected between the second rotating rods and the conveying wheel 614 at the same side in the longitudinal direction, the fourth transmission assembly 615 is composed of two belt pulleys and a flat belt, one belt pulley is installed on the second rotating rod, the other belt pulley is installed on the conveying wheel 614, the flat belt is wound between two belt pulleys on the same longitudinal side, a fifth transmission component 616 is connected between every two adjacent second rotating rods, the fifth transmission component 616 is composed of two belt pulleys and the flat belt, the belt pulleys are respectively installed on the two adjacent second rotating rods, the flat belt is wound between the two adjacent belt pulleys, a sixth transmission component 618 is connected between the front side of the conveying shaft 52 and the front side of the second rotating shaft 63, the sixth transmission component 618 is composed of two belt pulleys and the flat belt, one belt pulley is installed on the front side of the conveying shaft 52, the other belt pulley is installed on the front side of the second rotating shaft 63, and the flat belt is wound between the two belt pulleys.

Intermittent type pushes down complementary unit 7 including rack 71, first spring 72, nut 73 and fixed plate 74, link up the equal sliding type in both sides and have rack 71 around the upper portion of frame 2, rack 71 and the meshing of second gear 67, both sides all are equipped with fixed plate 74 around the upper left portion of linking up frame 2, all be connected with first spring 72 between the left side of rack 71 and the left side of homonymy fixed plate 74, link up the equal spaced rotary type in both sides around the upper portion of frame 2 and be connected with four nuts 73, the outside of nut 73 all is equipped with the insection, insection and all mesh with homonymy rack 71, nut 73 all cup joints on corresponding lead screw 3 through the screw.

The fixing mechanism 8 includes a second fixing frame 81, a second spring 82, a first pressing block 83, a third spring 84 and a second pressing block 85, the left side and the right side of the lower portion of the first fixing frame 617 are connected with the second fixing frame 81, the inner side of the upper portion of the second fixing frame 81 is rotatably connected with the first pressing block 83, the lower side of the first pressing block 83 is rotatably connected with a roller, the outer side of the first pressing block 83 is connected with the inner side of the second fixing frame 81 through the third spring 84, the inner side of the second fixing frame 81 is connected with the upper second spring 82 and the lower second spring 82, and the inner sides of the upper second spring 82 and the lower second spring 82 are connected with the second pressing block 85.

When the gears need to be manufactured in batch, the material blocks are placed on the second supporting frame 61 through the feeding hole at the right side of the protective frame 1, the material blocks are dragged by the second supporting frame 61, so that the material block is pushed to be positioned below the stamping die 4, and at the same time, the material block is contacted with the first pressing block 83, so that the first pressing block 83 rotates anticlockwise, the third spring 84 deforms, and the first pressing piece 83 presses the material block due to the restoring force of the third spring 84, and simultaneously contacts with the second pressing piece 85, so that the second pressing piece 85 moves outwards, the second spring 82 is compressed, and the second pressing block 85 clamps the material block due to the resilient force of the second spring 82, thereby slightly fixing the material block, therefore, the situation that the pressing effect is poor due to the fact that the material blocks move when the pressing die is used is avoided, and meanwhile, the roller wheels are arranged below the first pressing block 83, so that the material blocks cannot be scraped due to friction force; then, the motor 54 is started, and the motor 54 drives the rightmost conveying shaft 52 to rotate through the first transmission assembly 55, so that the conveyor belt 53 operates; when the rightmost delivery shaft 52 rotates, the second rotating shaft 63 is driven to rotate by the sixth transmission assembly 618, thereby driving the first missing tooth 68 and the second missing tooth 69 to rotate, the first missing tooth 68 will be engaged with the first gear 64 first, thereby driving the first gear 64 and the first rotating shaft 62 to rotate, and then the second transmission assembly 65 drives the third rotating shaft 66 to rotate, so that the second gear 67 rotates, the second gear 67 rotates to drive the rack 71 to move to the right, the first spring 72 is compressed, the rack 71 moves to the right and also drives the nut 73 to rotate through the insections, and then the screw rod 3 is driven to move downwards through the screw thread, so that the stamping die 4 moves downwards, thus, the material block is subjected to die pressing to manufacture the gear, the die-pressed gear falls on the conveyor belt 53, and the conveyor belt 53 conveys the manufactured gear to the left; then, the first missing tooth 68 continuously rotates to separate from the first gear 64, at this time, the first spring 72 rebounds to drive the rack 71 to move and reset to the left, so that the screw rod 3 and the stamping die move and reset to the upper side, and at the same time, the second missing tooth 69 is meshed with the third gear 610, so as to drive the third gear 610 and the first rotating rod to rotate, so as to drive the fourth gear 612 to rotate through the third transmission component 611, and the fourth gear 612 rotates to drive the fifth gear 613 to rotate, so as to rotate the right-side conveying wheel 614, so as to drive the right-side second rotating rod to rotate through the fourth transmission component 615, so as to drive all the second rotating rods to rotate through the fifth transmission component 616, and further drive all the conveying wheels 614 to rotate through the fourth transmission component 615, so as to transport the material blocks after stamping to the left side due to friction force, the next block of material can then be placed and the apparatus repeated to mass produce the gear, and once the gear has been mass produced, the motor 54 is turned off.

Example 2

On the basis of embodiment 1, as shown in fig. 2, 12, 13, 14 and 15, the protection frame further includes a cutting mechanism 9, the cutting mechanism 9 includes a support base 91, a projection 92, a sixth gear 93, a seventh transmission assembly 94 and a cutter 95, the support base 91 is connected to the left side inside the protection frame 1, the projection 92 is rotatably connected to the right upper rear side of the support base 91, the sixth gear 93 is rotatably connected to the upper side of the first support frame 51 at the left rear side, the seventh transmission assembly 94 is connected between the sixth gear 93 and the projection 92, the seventh transmission assembly 94 is composed of two pulleys and a flat belt, one of the pulleys is mounted on the sixth gear 93, the other pulley is mounted at the rear side of the projection 92, the flat belt is wound between the two pulleys, the cutter 95 is slidably connected to the right portion of the support base 91, and the cutter 95 is engaged with the projection 92.

The polishing machine comprises a polishing mechanism 10, wherein the polishing mechanism 10 comprises a third supporting frame 101, a conveying frame 102, a seventh gear 103, an eighth transmission component 104, a first bevel gear frame 105, a second bevel gear frame 106, a ninth transmission component 107 and a polisher 108, the third supporting frame 101 is connected to the left side in the protection frame 1, the conveying frame 102 is connected to the upper portion of the third supporting frame 101, the seventh gear 103 is connected to the rear side of the leftmost conveying shaft 52, the sixth gear 93 is matched with the seventh gear 103, the first bevel gear frame 105 is rotatably connected to the left side of the supporting seat 91, the eighth transmission component 104 is connected between the rear side of the first bevel gear frame 105 and the rear side of the conveying shaft 52, the eighth transmission component 104 consists of two belt pulleys and a flat belt, one belt pulley is installed at the rear side of the first bevel gear frame 105, the other belt is installed at the rear side of the conveying shaft 52, and the flat belt is wound between the two belt pulleys, the upper side of the third supporting frame 101 is rotatably provided with a second cone carrier 106, the upper side of the third supporting frame 101 is rotatably provided with a sander 108, the sander 108 is positioned at the front side of the second cone carrier 106, a ninth transmission assembly 107 is connected between the sander 108 and the second cone carrier 106, the ninth transmission assembly 107 is composed of two belt pulleys and a flat belt, one belt pulley is arranged at the lower side of the second cone carrier 106, the other belt pulley is arranged at the upper side of the sander 108, and the flat belt is wound between the two belt pulleys.

The motor 54 is started, so that the conveying shaft 52 rotates, the eighth transmission assembly 104 drives the first bevel gear rack 105 to rotate, the second bevel gear rack 106 rotates, the ninth transmission assembly 107 drives the sander 108 to rotate, the stamped gears fall on the conveyor belt 53, the gears are conveyed to the left side and then enter the conveying rack 102, and then are gradually pushed into the third supporting rack 101, so that the gears are in contact with the sander 108, and the surfaces of the gears are automatically polished; carry axle 52 to rotate simultaneously and still can drive seventh gear 103 and rotate, and then can drive sixth gear 93 and rotate, thereby can drive lug 92 through seventh transmission assembly 94 and rotate, thereby make lug 92 can contact with cutter 95, make cutter 95 rebound, when lug 92 is rotatory to break away from with cutter 95, cutter 95 just can the downstream reset because of the action of gravity, thereby accomplish the back at material fast-pressing mould, the material piece is to the left side removal, can be chopped up by cutter 95, and fall into in the supporting seat 91, thereby can cut up the material piece automatically and retrieve.

The above-mentioned embodiments are merely preferred embodiments of the present invention, which are not intended to limit the scope of the present invention, and therefore, all equivalent changes made by the contents of the claims of the present invention should be included in the claims of the present invention.

Claims (8)

1. A gear batch manufacturing device is characterized by comprising a protective frame (1), a connecting frame (2), a screw rod (3) and a stamping die (4), transport mechanism (5), feeding mechanism (6), intermittent type pushes down complementary unit (7) and fixed establishment (8), be connected with linking frame (2) on bearer bar (1), the slidingtype of align to grid about linking the both sides of frame (2) is all connected with two at least lead screws (3), one side of lead screw (3) all is equipped with stamping die (4), be equipped with transport gear's transport mechanism (5) that can transport the gear on bearer bar (1), be equipped with on bearer bar (1) and carry material feeding mechanism (6), be equipped with between lead screw (3) and feeding mechanism (6) and drive stamping die (4) and carry out intermittent type pushing down complementary unit (7) of moulding-die, be equipped with fixed establishment (8) of fixable material on feeding mechanism (6).

2. The gear mass manufacturing device according to claim 1, wherein the transfer mechanism (5) comprises first support frames (51), conveying shafts (52), a conveyor belt (53), a motor (54) and first transmission assemblies (55), at least two first support frames (51) are connected to both sides of the protective frame (1), the conveying shafts (52) are rotatably connected between the first support frames (51) on the same side, the conveyor belt (53) is connected between the conveying shafts (52), the motor (54) is arranged on the protective frame (1), and the first transmission assemblies (55) are connected between output shafts of the motor (54) and the conveying shafts (52) on one side.

3. The device for manufacturing gears in batches according to claim 2, wherein the feeding mechanism (6) comprises a second supporting frame (61), a first rotating shaft (62), a second rotating shaft (63), a first gear (64), a second transmission assembly (65), a third rotating shaft (66), a second gear (67), a first missing tooth (68), a second missing tooth (69), a third gear (610), a third transmission assembly (611), a fourth gear (612), a fifth gear (613), a conveying wheel (614), a fourth transmission assembly (615), a fifth transmission assembly (616), a first fixing frame (617) and a sixth transmission assembly (618), the second supporting frame (61) is connected to the protective frame (1), the first rotating shaft (62) is rotatably connected to the second supporting frame (61), the second rotating shaft (63) is rotatably connected to the second supporting frame (61), the two sides of the first rotating shaft (62) are connected with first gears (64), the protective frame (1) is rotatably connected with a third rotating shaft (66), a second transmission assembly (65) is connected between the third rotating shaft (66) and the two sides of the first rotating shaft (62), the two sides of the third rotating shaft (66) are connected with second gears (67), the two sides of the second rotating shaft (63) are connected with first missing teeth (68), the two sides of the second rotating shaft (63) are connected with second missing teeth (69), the second missing teeth (69) are positioned on the outer sides of the first missing teeth (68), the first missing teeth (68) are matched with the first gears (64) on the same side, the second supporting frame (61) is rotatably connected with first rotating rods, the first rotating rods are connected with third gears (610), the third gears (610) are matched with the second missing teeth (69) on the front side, the two sides of the connecting frame (2) are connected with first fixing frames (617), a fourth gear (612) is rotatably connected to the first fixing frame (617) on one side, a third transmission assembly (611) is connected between the fourth gear (612) and the first rotating rod, at least two conveying wheels (614) are rotatably connected to the first fixing frame (617) at uniform intervals, a fifth gear (613) is connected to one of the conveying wheels (614), the fifth gear (613) is meshed with the fourth gear (612), at least two second rotating rods are rotatably connected to the first fixing frame (617) at uniform intervals, a fourth transmission assembly (615) is connected between the second rotating rods and the conveying wheels (614) on the same side, a fifth transmission assembly (616) is connected between every two adjacent second rotating rods, and a sixth transmission assembly (618) is connected between the conveying shaft (52) and the second rotating shaft (63).

4. A gear mass manufacturing apparatus according to claim 3, wherein the intermittent pressing auxiliary mechanism (7) comprises a rack (71), a first spring (72), a nut (73) and a fixing plate (74), the racks (71) are slidably connected to both sides of the connecting frame (2), the fixing plates (74) are disposed on both sides of the connecting frame (2), the first spring (72) is connected between the rack (71) and the fixing plate (74) on the same side, at least two nuts (73) are rotatably connected to both sides of the connecting frame (2) at uniform intervals, insections are disposed on outer sides of the nuts (73), the insections are engaged with the racks (71) on the same side, and the nuts (73) are respectively sleeved on the corresponding screw rods (3) through threads.

5. The device for manufacturing gears in batches as claimed in claim 4, wherein the fixing mechanism (8) comprises a second fixing frame (81), a second spring (82), a first pressing block (83), a third spring (84) and a second pressing block (85), the second fixing frame (81) is connected to both sides of the first fixing frame (617), the first pressing block (83) is rotatably connected to the second fixing frame (81), the third spring (84) is connected between the first pressing block (83) and the second fixing frame (81), the upper and lower second springs (82) are connected to the second fixing frame (81), and the second pressing block (85) is connected between the upper and lower second springs (82).

6. The gear batch manufacturing device according to claim 5, further comprising a cutting mechanism (9), wherein the cutting mechanism (9) comprises a support seat (91), a protrusion (92), a sixth gear (93), a seventh transmission assembly (94) and a cutter (95), the support seat (91) is connected to the protection frame (1), the protrusion (92) is rotatably connected to the support seat (91), the sixth gear (93) is rotatably connected to the first support frame (51) on one side, the seventh transmission assembly (94) is connected between the sixth gear (93) and the protrusion (92), the cutter (95) is slidably connected to the support seat (91), and the cutter (95) is matched with the protrusion (92).

7. The gear batch manufacturing device according to claim 6, further comprising a grinding mechanism (10), wherein the grinding mechanism (10) comprises a third supporting frame (101), a conveying frame (102), a seventh gear (103), an eighth transmission assembly (104), a first bevel gear frame (105), a second bevel gear frame (106), a ninth transmission assembly (107) and a grinder (108), the protective frame (1) is connected with the third supporting frame (101), the conveying frame (102) is connected to the third supporting frame (101), the seventh gear (103) is connected to the leftmost conveying shaft (52), the sixth gear (93) is matched with the seventh gear (103), the first bevel gear frame (105) is rotatably connected to the supporting seat (91), the eighth transmission assembly (104) is connected between the first bevel gear frame (105) and the conveying shaft (52), the second bevel gear frame (106) is rotatably arranged on the third supporting frame (101), a sander (108) is rotatably arranged on the third support frame (101), the sander (108) is positioned on the front side of the second bevel gear frame (106), and a ninth transmission assembly (107) is connected between the sander (108) and the second bevel gear frame (106).

8. A gear mass manufacturing apparatus according to claim 5, wherein the lower side of the first pressing block (83) is rotatably connected with a roller.

Images