CN210412390U - Full-automatic unloading forging and pressing equipment - Google Patents

Abstract

The utility model belongs to the technical field of production facility, especially, relate to a full-automatic unloading forging and pressing equipment. The utility model discloses, including forging press mechanism and the automatic feeding mechanism who is used for giving forging press mechanism material loading, one side intercommunication of automatic feeding mechanism has blank mechanism, still be equipped with graphite stirring coating unit between forging press mechanism and the blank mechanism, conveying mechanism one end is linked together with blank mechanism, and the other end is linked together with graphite stirring coating unit. The utility model discloses in be equipped with the graphite stirring coating unit who is used for bar copper surface graphite coating specially, compare in the operation of traditional artifical coating, production efficiency is higher, is applicable to mechanized production, and, the utility model discloses an automatic feeding mechanism realizes the transport of bar through the rotation of stirring dish, and the transport stroke is short, mechanical structure is compact.

Description

Full-automatic unloading forging and pressing equipment

Technical Field

The utility model belongs to the technical field of production facility, especially, relate to a full-automatic unloading forging and pressing equipment.

Background

The specific processing method of the red punching process is that a brass bar is heated to red and then placed into a hot punching die of a punch press for one-time extrusion forming, in order to prevent the surface of the brass bar from blackening in the processing process, the processing steps of coating graphite on the surface of the brass bar are arranged in the processing process, and in the prior art, the graphite coating is carried out by adopting a manual operation method, the brass bar is placed into a basket filled with graphite for mixed coating, and the method is time-consuming and labor-consuming, has low production efficiency and cannot be used in mechanized production.

For example, the chinese invention patent application discloses a full-automatic vertical red punching apparatus [ application number: 201810601250.9], the invention comprises a feeding rack assembly for conveying workpieces, a raw material transmission device, a raw material pushing device and a raw material feeding device; the raw material transmission device is positioned at the upper end of the feeding frame assembly; the raw material pushing device corresponds to the raw material feeding device in position; the raw material pushing device and the raw material feeding device are positioned at the end part of the raw material transmission device; the device also comprises a red punching raw material heating furnace, a chute device, a conveying and conveying mechanism and a processing mechanism which are connected in sequence.

In the application of the invention, a graphite stirring and coating device special for coating graphite is not arranged, and the problems of time and labor waste, low production efficiency and unsuitability for mechanized production lattices exist in a manual coating mode in the production process.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the above-mentioned problem, a full-automatic unloading forging and pressing equipment is provided.

In order to achieve the above purpose, the utility model adopts the following technical proposal:

the utility model provides a full-automatic unloading forging and pressing equipment, includes forging mechanism and is used for the automatic feeding mechanism for forging mechanism material loading, one side intercommunication of automatic feeding mechanism has the blank mechanism, still be equipped with graphite stirring coating unit between forging mechanism and the blank mechanism, conveying mechanism one end is linked together with the blank mechanism, and the other end is linked together with graphite stirring coating unit.

In foretell full-automatic unloading forging equipment, graphite stirring coating unit includes the frame, and feeding component and graphite entry all set up in the frame, feeding component is linked together with conveying mechanism, still be equipped with frame pivoted one-way ejection of compact mixing mechanism relatively in the frame, one-way ejection of compact mixing mechanism and feeding component and graphite entry homogeneous phase intercommunication, if and only when one-way ejection of compact mixing mechanism along clockwise or anticlockwise rotation, material in the one-way ejection of compact mixing mechanism can the landing to the forging press in the mechanism.

In foretell full-automatic unloading forging equipment, one-way ejection of compact mixing mechanism is including setting up the shell body in the frame, have the hybrid cavity that communicates with feeding component and graphite entry homogeneous phase in the shell body, fixed connection has the ejection of compact track at shell body internal surface in the hybrid cavity, the ejection of compact track extends along shell body axial lead direction spiral, still includes that one end is linked together with ejection of compact track, and the other end extends to the outside discharge gate of hybrid cavity.

In foretell full-automatic unloading forging equipment, the ejection of compact track includes a plurality of outstanding guide rib in the shell body internal surface that arrange in proper order, the guide rib extends along shell body axial lead direction spiral, has the direction passageway between two adjacent guide rib along shell body axial lead direction or between guide rib and the shell body, the direction passageway is linked together with the discharge gate.

In foretell full-automatic unloading forging equipment, the discharge gate includes the play flitch with shell body fixed connection, goes out the upper surface and the ejection of compact track of flitch and is linked together, it separates the baffle to go out flitch to be close to mixed cavity one side border fixedly connected with.

In foretell full-automatic unloading forging equipment, graphite stirring coating unit still includes fixed connection in the frame, and can drive one-way ejection of compact mixing mechanism and take place rotatory actuating mechanism, actuating mechanism includes the ring gear of fixed connection two-way rotating electrical machines in the frame and fixed cover establishment at one-way ejection of compact mixing mechanism surface, fixedly connected with drive gear on the output shaft of two-way rotating electrical machines, drive gear meshes with the ring gear mutually.

In foretell full-automatic unloading forging equipment, forging mechanism includes that inside is equipped with the casing assembly of forging and pressing station, casing assembly one side is equipped with the feed mechanism who is linked together with the forging and pressing station, feed mechanism is linked together with graphite stirring coating device.

In foretell full-automatic unloading forging equipment, automatic feeding mechanism includes material loading frame and rotates the main shaft of being connected with material loading frame, is equipped with at least one tilting pan on the main shaft and along the axial of main shaft, tilting pan on be equipped with the turn-down mouth, material loading frame is last and is equipped with the branch work or material rest at the lateral part of main shaft, the branch work or material rest keep away from one side of main shaft and be provided with the material storage frame, material storage frame and branch work or material rest between be equipped with the lifting machine that is used for communicateing material storage frame and branch work or material rest, branch work or material rest and material storage frame highly reduce to the one end that is close to the main shaft by the one end of keeping away.

In foretell full-automatic unloading forging equipment, blank mechanism includes the outer frame of fixed connection on automatic feeding mechanism, be equipped with the cutting machine in the outer frame, the cutting machine is linked together through the driving chain with automatic feeding mechanism, blank mechanism is still including setting up the splint between cutting machine and automatic feeding mechanism, splint are located the driving chain top.

In foretell full-automatic unloading forging equipment, conveying mechanism includes the feed inlet that is linked together with blank mechanism and the feed opening that is linked together with graphite stirring coating unit, the feed opening highly is higher than the feed inlet height in vertical side, is equipped with the track between feed inlet and the feed opening, and driving motor is connected with the track drive, track fixed surface is connected with a plurality of defeated material board, and the interval between two adjacent defeated material boards equals.

Compared with the prior art, the utility model has the advantages of:

1. the utility model discloses in be equipped with the graphite stirring coating unit who is used for bar copper surface graphite coating specially, compare in the operation of traditional artifical coating, production efficiency is higher, is applicable to mechanized production.

2. The utility model discloses usable one-way ejection of compact mixing mechanism realizes the coating of bar copper surface graphite and the ejection of compact of the bar copper that the coating was accomplished, and degree of automation is higher, easily controls the diffusion of graphite simultaneously in mixing process, compares in prior art manual operation and leads to the graphite unrestrained to the operation scene condition everywhere, and is safer environmental protection more.

3. The utility model discloses an automatic feeding mechanism realizes the transport of bar through the rotation of stirring dish, and the transport stroke is short, and mechanical structure is compact.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

FIG. 2 is a schematic structural diagram of a discharge process of a graphite stirring coating device;

FIG. 3 is a schematic structural diagram of a mixing process of a graphite stirring coating device;

FIG. 4 is a schematic structural view of a part of the structure of a graphite stirring and coating apparatus;

FIG. 5 is a schematic structural view of an automatic feeding mechanism and a blanking mechanism;

FIG. 6 is a schematic structural view from another perspective of the automatic feeding mechanism and the blanking mechanism;

FIG. 7 is a schematic structural view of the forging mechanism;

FIG. 8 is a schematic view of the structure of the conveying mechanism;

in the figure: forging and pressing mechanism a, automatic feeding mechanism b, cutting mechanism c, graphite stirring and coating device d, conveying mechanism e, frame 1, feeding assembly 2, graphite inlet 3, unidirectional discharging and mixing mechanism 4, driving mechanism 5, roller assembly 6, feeding hopper 21, vibrator 22, feeding channel 23, feeding control assembly 24, driving air cylinder 25, rotating arm 26, rotating rod 27, rotating partition plate 28, outer shell 41, mixing cavity 42, discharging track 43, discharging port 44, guide rib 45, guide channel 46, discharging plate 47, partition plate 48, bidirectional rotating motor 51, gear ring 52, transmission gear 53, rolling rod 61, bearing 62, roller 63, forging station 71, shell assembly 72, feeding mechanism 73, feeding frame 81, main shaft 82, material turning disc 83, material turning port 84, material dividing frame 85, material storing frame 86, elevator outer frame 87, 91 and cutting machine 92, The device comprises a transmission chain 93, a clamping plate 94, a feed inlet 101, a feed outlet 102, a crawler belt 103, a driving motor 104 and a material conveying plate 105.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

As shown in figure 1, the full-automatic blanking forging and pressing equipment comprises a forging mechanism a and an automatic feeding mechanism b used for feeding the forging mechanism a, wherein one side of the automatic feeding mechanism b is communicated with a cutting mechanism c, a graphite stirring and coating device d is further arranged between the forging mechanism a and the cutting mechanism c, one end of a conveying mechanism e is communicated with the cutting mechanism c, and the other end of the conveying mechanism e is communicated with the graphite stirring and coating device d.

The utility model discloses, during the use, the bar is by automatic feeding mechanism b material loading to through blank mechanism c cutting become the bar copper of predetermineeing length, the bar copper is carried to graphite stirring coating unit d by conveying mechanism e in, carries out the graphite coating to the bar copper surface, gets into to forging mechanism an after the coating is accomplished, and the forging and pressing obtains the finished product, so the utility model discloses in be equipped with the graphite stirring coating unit b who is used for the coating of bar copper surface graphite specially, compare in the operation of traditional artifical coating, production efficiency is higher, is applicable to mechanized production.

As shown in fig. 2, the graphite stirring and coating device d comprises a frame 1, a feeding assembly 2 and a graphite inlet 3 are arranged on the frame 1, the feeding component 2 is communicated with the conveying mechanism e, the rack 1 is also provided with a unidirectional discharging and mixing mechanism 4 which can rotate relative to the rack 1, the unidirectional discharging and mixing mechanism 4 is communicated with the feeding component 2 and the graphite inlet 3, if and only if the unidirectional discharging and mixing mechanism 4 rotates clockwise or anticlockwise, the copper bar in the unidirectional discharging and mixing mechanism 4 can slide into the forging mechanism a, that is, when the unidirectional discharging and mixing mechanism 4 rotates along one direction, for example, anticlockwise rotating, the copper rod in the unidirectional discharging and mixing mechanism 4 can realize discharging, but rotate reversely, that is, the unidirectional discharging and mixing mechanism 4 rotates clockwise, and the copper rod in the unidirectional discharging and mixing mechanism 4 can only realize mixing but cannot discharge.

During the use, the bar copper of predetermined length is cut into, is added to one-way ejection of compact mixing mechanism 4 through feeding subassembly 2 by conveying mechanism e in, graphite passes through graphite entry 3 and adds to one-way ejection of compact mixing mechanism 4 in, rotates the mixture of one-way ejection of compact mixing mechanism 4 realization bar copper and graphite for the bar copper surface is coated to graphite, and the coating is accomplished the back, and one-way ejection of compact mixing mechanism 4 is rotated towards opposite direction, in order to accomplish the ejection of compact, so the utility model discloses usable one-way ejection of compact mixing mechanism 4 constructs the ejection of compact of the bar copper of realizing the coating of bar copper surface graphite and coating completion, degree of automation is higher.

As shown in fig. 2, the unidirectional discharging mixing mechanism 4 includes an outer casing 41 disposed on the frame 1, a mixing cavity 42 communicating with both the feeding assembly 2 and the graphite inlet 3 is disposed in the outer casing 41, a discharging track 43 fixedly connected to the inner surface of the outer casing 41 is disposed in the mixing cavity 42, the discharging track 43 extends spirally along the axial line direction of the outer casing 41, and a discharging port 44 having one end communicating with the discharging track 43 and the other end extending to the outside of the mixing cavity 42, preferably, the discharging port 44 extends spirally along the discharging track 43, and the discharging port 44 is disposed at one end of the outer casing 41 away from the feeding assembly 2 and the graphite inlet 3, so as to facilitate discharging.

During the use, in bar copper and graphite added to mixing cavity 42, shell body 41 rotated along the same spiral direction with ejection of compact track 43 for bar copper and graphite misce bene accomplish the coating, change shell body 41 rotation direction, make shell body 41 rotate along the opposite spiral direction with ejection of compact track 43, and the ejection of compact is accomplished through discharge gate 44 to the bar copper.

Specifically, the discharging track 43 includes a plurality of guiding ribs 45 protruding from the inner surface of the outer shell 41, the guiding ribs 45 are arranged in sequence, the guiding channels 46 are arranged between two adjacent guiding ribs 45 along the axial direction of the outer shell 41 or between the guiding ribs 45 and the outer shell 41, and the guiding channels 46 are communicated with the discharging port 44, which is just an example of a specific structure of the discharging track 43, the discharging track 43 can also be realized by replacing the guiding ribs 45 with guiding plates fixedly connected to the inner surface of the outer shell 41 and spirally extending along the axial direction of the outer shell 41 or other specific structures in the prior art, as long as the discharging track 43 can play a discharging role when the outer shell 41 rotates along a spiral direction opposite to the discharging track 43.

Preferably, shell body 41 both ends are equipped with the apron that can close mixing cavity 42, and like this in mixing process, usable apron keeps apart mixing cavity 42 and external, so the utility model discloses easily control the diffusion of graphite in mixing process, compare in prior art manual operation and lead to the unrestrained condition everywhere to the operation scene of graphite, safety ring protects more.

As shown in fig. 2, the discharge hole 44 includes a discharge plate 47 fixedly connected to the outer shell 41, an upper surface of the discharge plate 47 is communicated with the discharge rail 43, a baffle 48 is fixedly connected to a side edge of the discharge plate 47 near the mixing cavity 42, the copper rod completes the discharge along the discharge plate 47, and the baffle 48 can prevent the copper rod from falling back into the mixing cavity 42 in the process of finding the discharge, so as to improve the discharge rate.

As shown in fig. 2 and fig. 3, the graphite stirring and coating device d further includes a driving mechanism 5 fixedly connected to the frame 1 and capable of driving the unidirectional discharging and mixing mechanism 4 to rotate, wherein the driving mechanism 5 includes a bidirectional rotating motor 51 fixedly connected to the frame 1 and a gear ring 52 fixedly sleeved on the outer surface of the unidirectional discharging and mixing mechanism 4, that is, the gear ring 52 can rotate synchronously with the unidirectional discharging and mixing mechanism 4, the bidirectional rotating motor 51 can conveniently drive the outer shell 41 of the unidirectional discharging and mixing mechanism 4 to rotate in two directions, a transmission gear 53 is fixedly connected to an output shaft of the bidirectional rotating motor 51, the transmission gear 53 is engaged with the gear ring 52, and when the graphite stirring and coating device d is used, the bidirectional rotating motor 51 drives the gear ring 52 to rotate through the transmission gear 53, and the gear ring 52 drives the unidirectional discharging and mixing mechanism 4 to.

As shown in fig. 4, the feeding assembly 2 includes a feeding hopper 21 disposed on the frame 1 and a vibrator 22 fixedly connected to the bottom surface of the feeding hopper 21, the feeding hopper 21 is communicated with the unidirectional discharging mixing mechanism 4 through a feeding channel 23, and further includes a feeding control assembly 24 connected to the frame 1, the feeding channel 23 can be opened or cut off by rotating the feeding control assembly 24, the feeding control assembly 24 includes a driving cylinder 25 fixedly connected to the frame 1, an output shaft of the driving cylinder 25 is rotatably connected with a rotating arm 26, one end of the rotating arm 26 far away from the driving cylinder 25 is fixedly connected with a rotating rod 27, both ends of the rotating rod 27 are rotatably connected with the frame 1, the rotating rod 27 is further fixedly connected with a rotating partition plate 28, and the rotating rod 27 can make the rotating partition plate 28 fit with the upper surface of the feeding channel 23 or form a gap with the upper surface, wherein, the gap width is less than the bar copper diameter, just so can play the effect of stopping the bar copper and getting into one-way ejection of compact mixing mechanism 4.

During the use, vibrator 22 vibrates feeder hopper 21, make the bar copper of treating coating graphite in the feeder hopper 21 pass through feedstock channel 23 and get into one-way ejection of compact mixing mechanism 4, after the bar copper addition reached suitable volume, drive actuating cylinder 25 drive swinging boom 26, make swinging boom 26 drive rotary rod 27 take place to rotate, rotate baffle 28 and take place synchronous rotational motion, make feedstock channel 23 cut off, accomplish the ejection of compact back, it rotates baffle 28 to drive actuating cylinder 25 secondary drive rotation, make feedstock channel 23 opened, the bar copper of treating coating graphite in the feeder hopper 21 gets into one-way ejection of compact mixing mechanism 4.

The graphite inlet 3 can adopt a structure similar to that of the feeding component 2, and can also adopt a concrete structure that a feeding funnel is communicated with a feeding pipeline which is communicated with the one-way discharging mixing mechanism 4.

As shown in fig. 4, a roller assembly 6 is further disposed between the unidirectional discharging mixing mechanism 4 and the frame 1, the roller assembly 6 is rotatably connected with the frame 1, the cross section of the unidirectional discharging mixing mechanism 4 is circular, the unidirectional discharging mixing mechanism 4 is pressed on the roller assembly 6 and is in rolling connection with the roller assembly 6, the roller assembly 6 includes a rolling rod 61 rotatably connected with the frame 1 through a bearing 62, two ends of the rolling rod 61 are respectively and fixedly connected with a roller 63, and the unidirectional discharging mixing mechanism 4 is pressed on the roller 63 and is in rolling connection with the roller 63, so that the unidirectional discharging mixing mechanism 4 only generates rolling friction force in the rotating process, the rotating resistance of the unidirectional discharging mixing mechanism 4 is reduced, and the energy consumption is saved.

Preferably, two roller assemblies 6 are arranged and symmetrically arranged at two sides of the unidirectional discharging and mixing mechanism 4, so that the stability of the placement of the unidirectional discharging and mixing mechanism 4 can be ensured.

Preferably, the end of the roller 63 is further fixedly connected with a limiting plate pressed at two ends of the unidirectional discharging and mixing mechanism 4, so that the unidirectional discharging and mixing mechanism 4 can be prevented from sliding along the axial lead direction in the mixing process.

The utility model discloses do not do the restriction to the concrete structure of conveying mechanism e as long as can play the effect of realizing carrying the bar copper to graphite stirring coating unit d from blank mechanism c, conveying mechanism e can be the conveyer belt among the prior art, also can be as shown in figure 8, conveying mechanism e includes feed inlet 101 and the feed opening 102 that is linked together with graphite stirring coating unit d that is linked together with blank mechanism c, feed opening 102 is higher than feed inlet 101 is high on vertical direction, be equipped with track 103 between feed inlet 101 and feed opening 102, driving motor 104 and track 103 drive are connected, track 103 fixed surface is connected with a plurality of defeated material board 105, during the use, the bar copper after the cutting gets into in feed inlet 101, start driving motor 104, driving motor 104 drives track 103 and rotates, the bar copper in the feed inlet 101 transports to the feed opening 102 under the drive of defeated material board 105, and then enters a graphite stirring coating device d.

Preferably, the intervals between two adjacent material conveying plates 105 are equal, so that the uniform material conveying speed of the copper bar can be ensured.

Referring to fig. 1 and 7, the forging mechanism a includes a housing assembly 72 having a forging station 71 therein, a feeding mechanism 73 communicating with the forging station 71 is disposed on one side of the housing assembly 72, the feeding mechanism 73 is communicated with a graphite stirring and coating device d, the copper rod coated with graphite is forged and molded at the forging station 71 to obtain a finished product, the forging mechanism a may also adopt a structure of a forging press commonly used in the prior art, and a specific structure similar to that of the conveying mechanism e may be adopted between the forging mechanism a and the graphite stirring and coating device d to achieve communication therebetween.

Referring to fig. 1 and 5, the automatic feeding mechanism b includes a feeding frame 81 and a spindle 82 rotatably connected to the feeding frame 81, at least one material turning disc 83 is disposed on the spindle 82 along an axial direction of the spindle 82, a material turning port 84 is disposed on the material turning disc 83, a material distributing frame 85 is disposed on the feeding frame 81 and on a side portion of the spindle 82, a material storing frame 86 is disposed on one side of the material distributing frame 85 away from the spindle 82, a lifting machine 87 for communicating the material storing frame 86 with the material distributing frame 85 is disposed between the material storing frame 86 and the material distributing frame 85, heights of the material distributing frame 85 and the material storing frame 86 in a vertical direction are gradually reduced from one end away from the spindle 82 to one end close to the spindle 82, so that the bar stock can automatically roll to a designated position due to gravity.

During the use, the bar on the stock shelf 86 promotes to the branch work or material rest 85 through the lifting machine 87 on, because the slope of branch work or material rest 85 sets up, so the bar on the branch work or material rest 85 can take place to be close to the roll of stirring dish 83, and main shaft 82 drives a plurality of stirring dish 83 and rotates in step, treats that stirring mouth 84 rotates when being close to branch work or material rest 85 one side, and in the bar card goes into stirring mouth 84, stirring dish 83 continued to rotate for the bar shifts to the work or material rest 81 on, so the utility model discloses an automatic feeding mechanism b realizes the transport of bar through the rotation of stirring dish 83, and the transport stroke is short, and mechanical structure is compact.

Referring to fig. 1 and 6, the material cutting mechanism c includes an outer frame 91 fixedly connected to the automatic feeding mechanism b, a cutting machine 92 is arranged in the outer frame 91, the cutting machine 92 is communicated with the automatic feeding mechanism b through a transmission chain 93, the material cutting mechanism c further includes a clamping plate 94 arranged between the cutting machine 92 and the automatic feeding mechanism b, the clamping plate 94 is located above the transmission chain 93, when the automatic feeding mechanism c is used, a bar material on the material feeding frame 81 is conveyed to the lower side of the cutting machine 92 through the transmission chain 93 and is cut into copper bars with a certain length, and the clamping plate 94 can be used for clamping and fixing.

The utility model discloses a theory of operation is: when the device is used, the bars on the material storage rack 86 are lifted to the material distribution rack 85 through the lifting machine 87, the bars on the material distribution rack 85 roll close to the material turning disks 83 due to the inclined arrangement of the material distribution rack 85, the main shaft 82 drives the material turning disks 83 to synchronously rotate, when the material turning ports 84 rotate to one side close to the material distribution rack 85, the bars are clamped into the material turning ports 84, the material turning disks 83 continuously rotate, so that the bars are transferred to the material loading rack 81, the bars on the material loading rack 81 are conveyed to the lower part of the cutting machine 92 through the transmission chain 93 and are cut into copper bars with certain length, the clamping plates 94 can be used for clamping and fixing, the cut copper bars enter the material inlet 101, the driving motor 104 is started, the driving motor 104 drives the track 103 to rotate, the copper bars in the material inlet 101 are conveyed to the material outlet 102 under the driving of the material conveying plate 105 and then enter the material feeding hopper 21, the vibrator 22 vibrates the material feeding hopper 21, so that the copper bars to be coated with graphite in the material, after the adding amount of the copper rod reaches a proper amount, the driving cylinder 25 drives the rotating arm 26, so that the rotating arm 26 drives the rotating rod 27 to rotate, the rotating partition plate 28 synchronously rotates, the feeding channel 23 is cut off, graphite is added into the mixing cavity 42 through the graphite inlet 3, at the moment, the bidirectional rotating motor 51 drives the gear ring 52 to rotate through the transmission gear 53, the gear ring 52 drives the outer shell 41 to rotate, at the moment, the outer shell 41 rotates along the same spiral direction as the discharging track 43, so that the copper rod and the graphite are uniformly mixed, after coating is completed, the driving direction of the bidirectional rotating motor 51 is changed, so that the rotating direction of the outer shell 41 is changed, the outer shell 41 rotates along the spiral direction opposite to the discharging track 43, the copper rod completes discharging through the discharging port 44, after discharging is completed, the driving cylinder 25 drives the rotating partition plate 28 to rotate again, so, in the feeder hopper 21 treat that the bar copper of coating graphite gets into mixed cavity 42, carries out the graphite coating of next batch bar copper, the bar copper that the coating has graphite finally forges and presses on forging and pressing station 71 and makes the finished product, so the utility model discloses in be equipped with the graphite stirring coating unit b that is used for bar copper surface graphite coating specially, compare in the operation of traditional artifical coating, production efficiency is higher, is applicable to mechanized production.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Although the forging mechanism a, the automatic feeding mechanism b, the cutting mechanism c, the graphite stirring and coating device d, the conveying mechanism e, the frame 1, the feeding component 2, the graphite inlet 3, the one-way discharging and mixing mechanism 4, the driving mechanism 5, the roller component 6, the feeding hopper 21, the vibrator 22, the feeding channel 23, the feeding control component 24, the driving cylinder 25, the rotating arm 26, the rotating rod 27, the rotating partition plate 28, the outer shell 41, the mixing cavity 42, the discharging track 43, the discharging port 44, the guide rib 45, the guide channel 46, the discharging plate 47, the partition plate 48, the two-way rotating motor 51, the gear ring 52, the transmission gear 53, the rolling rod 61, the bearing 62, the roller 63, the forging station 71, the shell assembly 72, the feeding mechanism 73, the feeding rack 81, the main shaft 82, the material turning disk 83, the material turning port 84, the material dividing rack 85, the material storing rack 86, the lifter 87, The terms outer frame 91, cutter 92, drive chain 93, clamp plate 94, feed inlet 101, feed outlet 102, caterpillar 103, drive motor 104, feed conveyor 105, etc., but do not exclude the possibility of using other terms. These terms are used merely to more conveniently describe and explain the nature of the present invention; they are to be construed in a manner that is inconsistent with the spirit of the invention.

Claims (10)

1. The utility model provides a full-automatic unloading forging equipment, includes forging mechanism (a) and is used for automatic feeding mechanism (b) for forging mechanism (a) material loading, one side intercommunication of automatic feeding mechanism (b) has blank mechanism (c), its characterized in that: and a graphite stirring and coating device (d) is also arranged between the forging mechanism (a) and the cutting mechanism (c), one end of the conveying mechanism (e) is communicated with the cutting mechanism (c), and the other end of the conveying mechanism (e) is communicated with the graphite stirring and coating device (d).

2. The full-automatic blanking forging apparatus of claim 1, wherein: graphite stirring coating unit (d) includes frame (1), and feeding subassembly (2) and graphite entry (3) all set up on frame (1), feeding subassembly (2) are linked together with conveying mechanism (e), still be equipped with frame (1) pivoted one-way ejection of compact hybrid mechanism (4) relatively on frame (1), one-way ejection of compact hybrid mechanism (4) and feeding subassembly (2) and graphite entry (3) homogeneous phase intercommunication, when and only when one-way ejection of compact hybrid mechanism (4) along clockwise or anticlockwise rotation, material in one-way ejection of compact hybrid mechanism (4) can slide to in forging press mechanism (a).

3. The full-automatic blanking forging apparatus of claim 2, wherein: one-way ejection of compact mixing mechanism (4) is including setting up shell body (41) in frame (1), have in shell body (41) with mixed cavity (42) of feeding subassembly (2) and graphite entry (3) homogeneous phase intercommunication, discharge track (43) of fixed connection at shell body (41) internal surface have in mixed cavity (42), discharge track (43) are followed shell body (41) axial lead direction spiral extension, still include that one end is linked together with discharge track (43), and the other end extends to mixed cavity (42) outside discharge gate (44).

4. The full-automatic blanking forging apparatus of claim 3, wherein: the discharging track (43) comprises a plurality of guide ribs (45) which are arranged in sequence and protrude out of the inner surface of the outer shell (41), the guide ribs (45) extend spirally along the axial lead direction of the outer shell (41), a guide channel (46) is arranged between two adjacent guide ribs (45) along the axial lead direction of the outer shell (41) or between the guide ribs (45) and the outer shell (41), and the guide channel (46) is communicated with the discharging port (44).

5. The full-automatic blanking forging apparatus of claim 3, wherein: the discharge port (44) comprises a discharge plate (47) fixedly connected with the outer shell (41), the upper surface of the discharge plate (47) is communicated with the discharge rail (43), and a baffle plate (48) is fixedly connected to the edge of one side, close to the mixing cavity (42), of the discharge plate (47).

6. The full-automatic blanking forging apparatus of claim 2, wherein: graphite stirring coating unit (d) still includes fixed connection in frame (1), and can drive one-way ejection of compact mixing mechanism (4) and take place rotatory actuating mechanism (5), actuating mechanism (5) are established ring gear (52) at one-way ejection of compact mixing mechanism (4) surface including two-way rotating electrical machines (51) of fixed connection in frame (1) and fixed cover, fixedly connected with drive gear (53) on the output shaft of two-way rotating electrical machines (51), drive gear (53) mesh mutually with ring gear (52).

7. The full-automatic blanking forging apparatus of claim 1, wherein: the forging mechanism (a) comprises a shell assembly (72) with a forging station (71) arranged inside, a feeding mechanism (73) communicated with the forging station (71) is arranged on one side of the shell assembly (72), and the feeding mechanism (73) is communicated with the graphite stirring and coating device (d).

8. The full-automatic blanking forging apparatus of claim 1, wherein: the automatic feeding mechanism (b) comprises a feeding frame (81) and a main shaft (82) rotatably connected with the feeding frame (81), at least one turning plate (83) is arranged on the main shaft (82) along the axial direction of the main shaft (82), a turning hole (84) is formed in the turning plate (83), a material distributing frame (85) is arranged on the feeding frame (81) and on the side portion of the main shaft (82), a material storing frame (86) is arranged on one side, away from the main shaft (82), of the material distributing frame (85), a lifting machine (87) used for communicating the material storing frame (86) and the material distributing frame (85) is arranged between the material storing frame (86) and the material distributing frame (85), and the material distributing frame (85) and the material storing frame (86) are gradually reduced from one end, away from the main shaft (82), in the vertical direction, of one end of the material distributing frame (85) and one end, away from.

9. The full-automatic blanking forging apparatus of claim 1, wherein: blank mechanism (c) are including outer frame (91) of fixed connection on automatic feeding mechanism (b), be equipped with cutting machine (92) in outer frame (91), cutting machine (92) are linked together through driving chain (93) with automatic feeding mechanism (b), blank mechanism (c) still is including setting up splint (94) between cutting machine (92) and automatic feeding mechanism (b), splint (94) are located driving chain (93) top.

10. The full-automatic blanking forging apparatus of claim 1, wherein: conveying mechanism (e) include feed inlet (101) that are linked together with blank mechanism (c) and feed opening (102) that are linked together with graphite stirring coating device (d), feed opening (102) highly are higher than feed inlet (101) height in vertical direction, are equipped with track (103) between feed inlet (101) and feed opening (102), and driving motor (104) are connected with track (103) drive, track (103) fixed surface is connected with a plurality of material conveying plate (105), and the interval between two adjacent material conveying plate (105) equals.

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