CN210648182U - Dislocation-preventing feeding device for mechanical die - Google Patents

Abstract

The utility model discloses a mechanical die is with preventing dislocation material feeding unit, including end supporting layer board, the bottom surface of end supporting layer board is close to the perpendicular downward welding of four corners and has the support cylinder, end supporting layer board upwards is connected with the side riser perpendicularly being close to one end both sides limit bolt, the welding has the feeding box body in the one end slant of side riser, position level is pegged graft between the side riser and is had the driving roll axle, the intermediate position of driving roll axle has cup jointed the silica gel roll cover, the side end that the driving roll axle runs through the side riser has cup jointed initiative drive gear, outside limit tooth has connect supplementary drive gear between the initiative drive gear, the one end welding of driving roll axle has main drive motor, position level joint has the direction arc strip between the driving roll axle. The device of the utility model is simple in design, full automation operation, convenient operation is swift, and accurate pay-off manufacturing procedure carries out for further improvement of work efficiency and qualification rate also improve greatly.

Description

Dislocation-preventing feeding device for mechanical die

Technical Field

The utility model relates to a mould processing technology field especially relates to a mechanical die is with preventing dislocation material feeding unit.

Background

A die machine is a tool used to form an article, the tool being made up of various parts, different dies being made up of different parts. The processing of the appearance of an article is realized mainly through the change of the physical state of a formed material. The tool is used for making a blank into a finished piece with a specific shape and size under the action of external force in blanking, forming stamping, die forging, cold heading, extrusion, powder metallurgy part pressing, pressure casting and the forming processing of compression molding or injection molding of products such as engineering plastics, rubber, ceramics and the like.

Present mechanical die needs artificial the mesa of processing of physically placing adding man-hour, carry out the punching press shaping, this mode action danger can injure staff's limbs, some mechanized material feeding unit has appeared after the development of science and technology, can present material feeding unit can not carry out the automation mechanized operation, still need work under artificial auxiliary adjustment, and the precision is not high when the pay-off, the material percent of pass that has caused stamping forming is low, certain loss has been brought for the enterprise.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a dislocation-preventing feeding device for mechanical die, simple through the design, full automation mechanized operation, convenient operation is swift, and accurate pay-off manufacturing procedure carries on for further improvement of work efficiency and qualification rate also improve greatly.

According to the utility model, the utility model aims to provide a dislocation-preventing feeding device for mechanical die, which comprises a bottom supporting plate, wherein a supporting cylinder is vertically welded downwards near four corners on the bottom surface of the bottom supporting plate, a side vertical plate is vertically upwards connected with a bolt near two side edges at one end of the bottom supporting plate, a feeding box body is welded upwards at one end of the side vertical plate in an inclined way, a driving rolling shaft is horizontally inserted between the side vertical plates, a silica gel rolling sleeve is sleeved at the middle position of the driving rolling shaft, a driving transmission gear is sleeved at the side end of the driving rolling shaft penetrating through the side vertical plate, an auxiliary transmission gear is engaged at the outer side between the driving transmission gears, a main transmission motor is welded at one end of the driving rolling shaft, a guiding arc-shaped strip is horizontally clamped at the position between the driving rolling shafts, a guiding conducting strip is horizontally clamped at one side far away from the feeding box body between the driving rolling shafts, the side level has seted up the adjustment channel between the direction conduction strip, the end support layer board has welded the U-shaped supporting shoe perpendicularly upwards at the one end top surface of keeping away from the side riser, the top surface of end support layer board is close to both sides limit and has welded the support fixed block perpendicularly upwards, the side is pegged graft perpendicularly between the support fixed block and has been had the rotation axostylus axostyle, the rotation axostylus axostyle has welded the upset motor in the one end that runs through the support fixed block, the both ends symmetry that the rotation axostylus axostyle is being close to between the support fixed block has vertically cup jointed the pay-off propelling movement pole, the butt joint channel has been seted up to the side of pay-off propelling movement pole.

Further, the number of support cylinder is four, and all parallel each other, and four support cylinders are the adjustable body of rod, and the number of side riser is two, and is parallel to each other between two side risers.

Further, the number of driving roll-in axle is a plurality of, and the mutually parallel perpendicular grafting is in the position between the side riser between many driving roll-in axles, and many driving roll-in axles are two sets of stack from top to bottom and arrange, and the one end butt joint of feeding box body is in the position between two sets of driving roll-in axles.

Furthermore, the number of the silica gel rolling sleeves keeps consistent with the number of the transmission rolling shafts, the outer side edges of the silica gel rolling sleeves at the upper end and the lower end are mutually butted, and the silica gel rolling sleeves are narrowed from width to width in the opposite direction from the feeding box body.

Furthermore, the number of the driving transmission gears is consistent with that of the transmission rolling shafts, and the driving transmission gears arranged at the upper end and the lower end are in tooth joint with each other.

Furthermore, the output end of the main drive motor is welded at one end of a drive rolling shaft close to the feeding box body.

Furthermore, the number of the guide arc-shaped strips is two, the two guide arc-shaped strips are symmetrically and horizontally arranged between the transmission rolling shafts, and one ends of the guide arc-shaped strips, far away from the feeding box body, are butted at one ends of the guide strips.

Furthermore, the number of the feeding push rods is two, the same side ends of the two feeding push rods are sleeved at the two ends of the rotating insertion shaft rod, and one end of the feeding push rod, which is far away from the rotating insertion shaft rod, is butted at the position end, between the guide strip and the transmission rolling shaft, of the guide transmission strip.

Furthermore, the two ends of the pushing ejector rod are movably clamped on the inner side edge of the butt joint channel, and the output end of the pushing motor is vertically welded in the middle of the outer side edge of the pushing ejector rod.

Compared with the prior art, the utility model beneficial effect who has is:

1. the materials are placed in the feeding box body, so that the materials slide down to the position between the vertically arranged transmission rolling shafts between the side vertical plates along the feeding box body, then the driving transmission gear rotates under the action of the main transmission motor to drive the auxiliary transmission gear to rotate together, so that the vertically arranged transmission rolling shafts rotate reversely, the materials clamped in the middle are transmitted under the action of the silica gel rolling sleeve, the direction of the materials is adjusted while the materials are transmitted under the action of the guide arc-shaped strip, and finally the materials enter the adjusting channel in the middle of the guide transmission strip, the materials are quickly transmitted and fully automatically adjusted, then the materials in the adjusting channel enter the butt joint channel in the feeding pushing rod under the thrust of the silica gel rolling sleeve, the rotating insertion rod rotates under the action of the turnover motor, and the feeding pushing rod rotates together, thereby completing the turnover of the material to the processing table of the die.

2. Through make under push motor's effect push away the material that the material ejector pin will dock the inside of channel and release, accurate propelling movement is processed to the mould mesa that carries out processing, and the device design is simple, full automation mechanized operation, and convenient operation is swift, and accurate pay-off manufacturing procedure that carries on for further improvement of work efficiency and qualification rate also improve greatly.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic perspective view of a dislocation-preventing feeding device for a mechanical die according to the present invention;

fig. 2 is a schematic front view of a detail structure of the dislocation-preventing feeding device for a mechanical die according to the present invention;

fig. 3 is a schematic view of the detail structure of the driving roller pressing shaft of the dislocation-preventing feeding device for the mechanical die in the top view;

fig. 4 is the utility model provides a feeding push rod overlooking detail structure schematic diagram of dislocation-preventing feeding device for mechanical die.

In the figure: 1-bottom supporting plate, 2-supporting cylinder, 3-side vertical plate, 4-feeding box body, 5-driving rolling shaft, 6-silica gel rolling sleeve, 7-driving transmission gear, 8-auxiliary transmission gear, 9-main transmission motor, 10-guiding arc strip, 11-guiding transmission strip, 12-adjusting channel, 13-U-shaped supporting block, 14-supporting fixed block, 15-rotating inserted shaft rod, 16-turning motor, 17-feeding push rod, 18-butt joint channel, 19-pushing ejector rod and 20-pushing motor.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, a dislocation-preventing feeding device for a mechanical mold comprises a bottom supporting plate 1, supporting cylinders 2 are vertically and downwardly welded on the bottom surface of the bottom supporting plate 1 near four corners, the number of the supporting cylinders 2 is four, and the supporting cylinders are parallel to each other, the four supporting cylinders 2 are adjustable rod bodies, the number of the side vertical plates 3 is two, and the two side vertical plates 3 are parallel to each other, the bottom supporting plate 1 is vertically and upwardly connected with the side vertical plates 3 by bolts near two sides of one end, one end of each side vertical plate 3 is obliquely and upwardly welded with a feeding box body 4, transmission rolling shafts 5 are horizontally inserted between the side vertical plates 3, the number of the transmission rolling shafts 5 is several, the transmission rolling shafts 5 are vertically inserted between the side vertical plates 3 in parallel to each other, the transmission rolling shafts 5 are arranged in an up-down overlapping manner, one end of the feeding box body 4 is butted between the two transmission rolling shafts 5, the middle position of the driving rolling shaft 5 is sleeved with a silica gel rolling sleeve 6, the number of the silica gel rolling sleeves 6 is consistent with that of the driving rolling shafts 5, the outer side edges of the silica gel rolling sleeves 6 at the upper end and the lower end are mutually butted, the silica gel rolling sleeves 6 are narrowed from width to width in opposite directions from the feeding box body 4, the side edge end of the driving rolling shaft 5 penetrating through the side vertical plate 3 is sleeved with a driving transmission gear 7, the number of the driving transmission gears 7 is consistent with that of the driving rolling shafts 5, the driving transmission gears 7 arranged at the upper end and the lower end are mutually toothed, the outer side edge between the driving transmission gears 7 is toothed with an auxiliary transmission gear 8, one end of the driving rolling shaft 5 is welded with a main transmission motor 9, the output end of the main transmission motor 9 is welded at one end of one driving rolling shaft 5 close to the position of the feeding box body 4, and a guide arc-shaped strip 10 is horizontally, the number of the guide arc-shaped strips 10 is two, the two guide arc-shaped strips 10 are symmetrically and horizontally arranged between the transmission rolling shafts 5, one end of each guide arc-shaped strip 10 far away from the feeding box body 4 is butted at one end of each guide transmission strip 11, one side of each transmission rolling shaft 5 far away from the feeding box body 4 is horizontally clamped with each guide transmission strip 11, an adjusting channel 12 is horizontally arranged at the side edge between the guide transmission strips 11, a U-shaped supporting block 13 is vertically and upwards welded on the top surface of one end of the bottom supporting plate 1 far away from the side vertical plate 3, supporting fixed blocks 14 are vertically and upwards welded on the top surface of the bottom supporting plate 1 close to the two side edges, a rotating insertion shaft rod 15 is vertically inserted between the supporting fixed blocks 14, a turnover motor 16 is welded at one end penetrating through the supporting fixed blocks 14 by the rotating insertion shaft rod 15, and feeding push rods 17 are symmetrically and vertically sleeved at the two ends, the number of the feeding push rods 17 is two, the same side ends of the two feeding push rods 17 are sleeved at the two end positions of the rotating insertion shaft rod 15, one end, far away from the rotating insertion shaft rod 15, of each feeding push rod 17 is in butt joint with the position end, extending out of the transmission rolling shaft 5, of each guide transmission strip 11, the side edge of each feeding push rod 17 is provided with a butt joint channel 18, a pushing ejector rod 19 is vertically clamped on the inner side surface of each butt joint channel 18, the two ends of each pushing ejector rod 19 are movably clamped on the inner side edge of each butt joint channel 18, the output end of each pushing motor 20 is vertically welded at the middle position of the outer side edge of each pushing ejector rod 19, and the pushing motors 20 are vertically welded at the.

When in use, materials are placed in the feeding box body 4, the materials slide down to the positions between the vertically arranged transmission rolling shafts 5 between the side vertical plates 3 along the feeding box body 4, then the driving transmission gear 7 is rotated under the action of the main transmission motor 9 to drive the auxiliary transmission gear 8 to rotate together, so that the vertically arranged transmission rolling shafts 5 rotate reversely, the materials clamped in the middle are transmitted under the action of the silica gel rolling sleeve 6, meanwhile, the materials are subjected to direction adjustment while being transmitted under the action of the guide arc-shaped strip 10 and finally enter the adjusting channel 12 in the middle of the guide transmission strip 11, the materials are quickly transmitted and automatically adjusted, then the materials in the adjusting channel 12 enter the butt joint channel 18 in the material conveying pushing rod 17 under the thrust of the silica gel rolling sleeve 6, and the rotating insertion shaft rod 15 is rotated under the action of the overturning motor 16, the feeding push rod 17 is rotated together, so that the material is turned to the die processing table, the material push rod 19 pushes out the material in the butt joint channel 18 under the action of the push motor 20, and the material is accurately pushed to the die table for processing.

The details of the present invention are well known to those skilled in the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides a dislocation preventing material feeding unit for mechanical die, includes end support layer board (1), its characterized in that: the bottom surface of the bottom supporting plate (1) is vertically welded with supporting cylinders (2) downwards near four corners, the bottom supporting plate (1) is vertically upwards connected with side vertical plates (3) by bolts near two side edges at one end, one end of each side vertical plate (3) is obliquely upwards welded with a feeding box body (4), driving rolling shafts (5) are horizontally inserted between the side vertical plates (3), a silica gel rolling sleeve (6) is sleeved at the middle position of each driving rolling shaft (5), driving transmission gears (7) are sleeved at the side ends of the driving rolling shafts (5) penetrating through the side vertical plates (3), auxiliary transmission gears (8) are in gear connection with the outer sides between the driving transmission gears (7), a main transmission motor (9) is welded at one end of each driving rolling shaft (5), and guiding arc-shaped strips (10) are horizontally clamped between the driving rolling shafts (5), a guide conduction strip (11) is horizontally clamped at one side, far away from the feeding box body (4), of the position between the transmission rolling shafts (5), an adjusting channel (12) is horizontally arranged at the side edge between the guide conduction strips (11), a U-shaped supporting block (13) is vertically welded upwards on the top surface of one end, far away from the side vertical plate (3), of the bottom supporting plate (1), supporting fixed blocks (14) are vertically welded upwards on the top surface of the bottom supporting plate (1) close to the two side edges, a rotating inserted shaft rod (15) is vertically inserted between the supporting fixed blocks (14), a turnover motor (16) is welded at one end penetrating through the supporting fixed blocks (14) of the rotating inserted shaft rod (15), feeding push rods (17) are symmetrically and vertically sleeved at the two ends, close to the supporting fixed blocks (14), of the feeding push rods (17), and butt joint channels (18) are arranged at the side edges of the feeding push rods (, the inner side surface of the butt joint channel (18) is vertically clamped with a material pushing ejector rod (19), and the middle position of the outer side edge of the rotary insert shaft rod (15) is vertically welded with a pushing motor (20).

2. The dislocation-preventing feeding device for the mechanical die as set forth in claim 1, wherein: the number of support cylinder (2) is four, and all parallel each other, and four support cylinder (2) are the adjustable body of rod, and the number of side riser (3) is two, and is parallel each other between two side risers (3).

3. The dislocation-preventing feeding device for the mechanical die as set forth in claim 1, wherein: the number of driving roll axle (5) is a plurality of, and is parallel to each other between many driving roll axles (5) and pegs graft perpendicularly and position between side riser (3), and many driving roll axles (5) are two sets of stack from top to bottom and arrange, and the one end butt joint of feeding box body (4) is in position between two sets of driving roll axles (5).

4. The dislocation-preventing feeding device for the mechanical die as set forth in claim 1, wherein: the number of the silica gel rolling sleeves (6) is consistent with that of the transmission rolling shafts (5), the outer side edges of the silica gel rolling sleeves (6) at the upper end and the lower end are mutually butted, and the silica gel rolling sleeves (6) are narrowed from width to width in opposite directions from the feeding box body (4).

5. The dislocation-preventing feeding device for the mechanical die as set forth in claim 1, wherein: the number of the active transmission gears (7) is consistent with that of the transmission rolling shafts (5), and the active transmission gears (7) arranged at the upper end and the lower end are in tooth joint with each other.

6. The dislocation-preventing feeding device for the mechanical die as set forth in claim 1, wherein: the output end of the main transmission motor (9) is welded at one end of a transmission rolling shaft (5) close to the feeding box body (4).

7. The dislocation-preventing feeding device for the mechanical die as set forth in claim 1, wherein: the number of the guide arc-shaped strips (10) is two, the two guide arc-shaped strips (10) are symmetrically and horizontally arranged between the transmission rolling shafts (5), and one ends of the guide arc-shaped strips (10) far away from the feeding box body (4) are butted at one ends of the guide strips (11).

8. The dislocation-preventing feeding device for the mechanical die as set forth in claim 1, wherein: the number of the feeding push rods (17) is two, the same side ends of the two feeding push rods (17) are sleeved at the two ends of the rotating insertion shaft rod (15), and one end, far away from the rotating insertion shaft rod (15), of each feeding push rod (17) is butted at a position end, extending out of the transmission rolling shaft (5), of the guide strip (11).

9. The dislocation-preventing feeding device for the mechanical die as set forth in claim 1, wherein: the two ends of the pushing ejector rod (19) are movably clamped on the inner side edge of the butt joint channel (18), and the output end of the pushing motor (20) is vertically welded in the middle of the outer side edge of the pushing ejector rod (19).

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