CN217800677U

CN217800677U - High-efficient automatic burnishing machine device

Info

Publication number: CN217800677U
Application number: CN202221045521.5U
Authority: CN
Inventors: 龚伦勇
Original assignee: Jiangxi Ruimei Machinery Equipment Co ltd
Current assignee: Huizhou Jingrui Zhixiang Machinery Technology Development Co.,Ltd.
Priority date: 2022-04-29
Filing date: 2022-04-29
Publication date: 2022-11-15
Anticipated expiration: 2032-04-29

Abstract

The utility model provides a high-efficiency automatic polishing machine device, relating to the technical field of automatic equipment; the automatic feeding device comprises a slicing feeding mechanism, a supporting base, a transfer assembly line, a feeding and discharging mechanical arm, a workpiece processing mechanism and a slicing discharging mechanism; the fragment feeding mechanism and the fragment blanking mechanism are respectively positioned at two sides of the supporting base, the transfer assembly line penetrates through the supporting base, and two ends of the transfer assembly line are respectively positioned in the fragment feeding mechanism and the fragment blanking mechanism; the feeding and discharging mechanical arm and the workpiece processing mechanism are arranged on the supporting base, and the feeding and discharging mechanical arm is positioned above the transfer assembly line; the utility model has the advantages that: the full-automatic processing and automatic feeding and discharging of the glass workpiece can be realized, and the labor and the cost are saved while the processing efficiency is greatly improved.

Description

High-efficient automatic burnishing machine device

Technical Field

The utility model relates to an automation equipment technical field, more specifically the utility model relates to a high-efficient automatic burnishing machine device.

Background

The demand on polishing machines in the existing market is continuously rising, when glass materials such as intelligent wearable cover plates and glass panels are polished, in order to polish multiple pieces of glass simultaneously to improve polishing efficiency, the existing market mostly adopts manual slicing of personnel and stacking of multiple pieces of glass together, the glass is fixed up and down by controlling a jig, and after an operator places the jig on polishing equipment, polishing wheels on the polishing equipment simultaneously contact the edges of the multiple pieces of glass from two sides of the jig, so that the multiple pieces of glass are polished simultaneously; according to the operation method, the phenomena of edge burning, uneven polishing and the like can occur, the polishing quality cannot be guaranteed, the glass is taken piece by piece through the operation of a person after polishing is finished, the glass is separated, and the processed glass workpiece is placed into the appointed material frame through the operator.

SUMMERY OF THE UTILITY MODEL

In order to overcome the not enough of prior art, the utility model provides a high-efficient automatic burnishing machine device can realize the automatic polishing processing of glass work piece and the automatic unloading of work piece, improves machining efficiency, avoids artifical unloading to easily cause industrial accident scheduling problem simultaneously.

The utility model provides a technical scheme that its technical problem adopted is: the improvement of the efficient automatic polisher device is that the efficient automatic polisher device comprises a slicing feeding mechanism, a supporting base, a transfer production line, a feeding and discharging mechanical arm, a workpiece processing mechanism and a slicing discharging mechanism;

the slicing feeding mechanism and the slicing blanking mechanism are respectively positioned at two sides of the supporting base, the transfer assembly line penetrates through the supporting base, and two ends of the transfer assembly line are respectively positioned in the slicing feeding mechanism and the slicing blanking mechanism;

the feeding and discharging mechanical arm and the workpiece processing mechanism are arranged on the supporting base, the feeding and discharging mechanical arm is located above the transfer assembly line, the feeding and discharging mechanical arm is used for transferring a workpiece to be processed into the workpiece processing mechanism from the assembly line, and transferring the processed workpiece to the transfer assembly line from the workpiece processing mechanism.

In the structure, the workpiece processing mechanism comprises a processing jig, an X-axis motion module, a Y-axis motion module, a Z1-axis motion module and a Z2-axis motion module;

the Y-axis movement module is arranged on the supporting base, the machining jig is arranged on the Y-axis movement module, and the machining jig is driven by the Y-axis movement module to reciprocate in the Y-axis direction;

the X-axis movement module is arranged above the processing jig, the Z1-axis movement module and the Z2-axis movement module are both arranged on the X-axis movement module, and the Z1-axis movement module and the Z2-axis movement module both comprise polishing discs for processing workpieces on the processing jig.

In the above structure, the Z1-axis motion module and the Z2-axis motion module each include a spindle dragging plate, a spindle motor, and a polishing wheel;

the spindle motor is fixed on the side wall of the spindle carriage, the polishing wheel is fixedly installed at the top end of a motor shaft of the spindle motor, and the polishing disc is installed below the polishing wheel.

In the structure, the support base is provided with the machine body inner cover, the processing jig is positioned inside the machine body inner cover, and the bottom of the machine body inner cover is provided with a plurality of water leakage holes.

In the structure, the slicing and blanking mechanism comprises a blanking platform, a driving module and a blanking driving assembly, wherein the blanking driving assembly is positioned above the working platform, the driving module is arranged on the blanking platform, and the driving module is used for driving the blanking driving assembly to move in the X-axis and Z-axis directions;

the blanking driving assembly comprises a blanking side vertical plate, a material pushing assembly and a workpiece rotating assembly, the workpiece rotating assembly comprises a rotating cylinder, a sucker mounting plate and a plurality of suckers arranged on the sucker mounting plate, the rotating cylinder is fixed on one side of the blanking side vertical plate, the sucker mounting plate is connected with a cylinder rod of the rotating cylinder, and the sucker mounting plate is driven by the rotating cylinder to realize switching between a horizontal state and a vertical state;

the material pushing assembly is arranged on the blanking side vertical plate and is positioned above the rotary cylinder, and the material pushing assembly is used for realizing blanking of workpieces on the sucker.

In the structure, the blanking driving assembly further comprises a workpiece limiting assembly, and the workpiece limiting assembly comprises a limiting cylinder, a limiting push plate, a left supporting plate, a left movable guide plate, a right supporting plate and a right movable guide plate;

the left supporting plate and the right supporting plate are relatively fixed on the blanking side vertical plate, the limiting cylinder is fixed on the blanking side vertical plate and positioned between the left supporting plate and the right supporting plate, and the limiting push plate is fixed at the top end of a cylinder rod of the limiting cylinder;

the left movable guide plate is fixedly connected with the limiting push plate, the right movable guide plate is fixed on the right support plate, the left movable guide plate and the right movable guide plate are arranged oppositely and are respectively positioned on two sides of the sucker mounting plate so as to clamp a workpiece on the sucker.

In the structure, the opposite side walls of the left movable guide plate and the right movable guide plate are respectively provided with an inwards concave strip-shaped groove.

In the structure, the cylinder rod of the limiting cylinder penetrates through the left support plate, the limiting push plate is located on the outer side of the left support plate, a plurality of guide rods are fixedly mounted on the limiting push plate, the left support plate is provided with a corresponding number of guide sleeves, and one ends of the guide rods are inserted into the guide sleeves.

In the structure, the slicing and blanking mechanism further comprises a processed glass material frame, and the processed glass material frame is arranged on the working platform and is positioned below the blanking driving assembly.

In the structure, the driving module comprises a blanking mechanism X-axis motion module, a blanking mechanism Z-axis motion module and a blanking mechanism Y-axis motion module;

the blanking mechanism Y-axis movement module is arranged on the blanking platform, and the processed glass material frame is arranged on the blanking mechanism Y-axis movement module and driven by the Y-axis movement module to reciprocate in the Y-axis direction;

the blanking platform is fixedly provided with a blanking mechanism support, the blanking mechanism X-axis movement module is arranged on the blanking mechanism support, and the blanking mechanism Z-axis movement module is arranged on the blanking mechanism X-axis movement module.

The utility model has the advantages that: the utility model discloses a high-efficient automatic polisher device, burst feed mechanism carry on automatic burst and automatic feeding action, equip transfer assembly line treat process glass and processed glass's automatic circulation action, equip burst unloading mechanism carry on independent unloading action; the full-automatic processing and automatic feeding and discharging of the glass workpiece can be realized, and the labor and the cost are saved while the processing efficiency is greatly improved.

Drawings

Fig. 1 is a schematic diagram of an external structure of an efficient automatic polisher device according to the present invention.

Fig. 2 is a schematic diagram of the internal structure of the high-efficiency automatic polishing machine device of the present invention.

Fig. 3 is a top view of the high-efficiency automatic polishing machine device of the present invention.

Fig. 4 is a schematic view of a first partial structure of a Z1 axis movement module of the high-efficiency automatic polisher device according to the present invention.

Fig. 5 is a second partial structural schematic diagram of the Z1 axis movement module of the high-efficiency automatic polishing machine device of the present invention.

Fig. 6 is a schematic perspective view of the slicing and blanking mechanism of the present invention.

Fig. 7 is a schematic structural view of the blanking driving assembly of the burst blanking mechanism of the present invention.

Fig. 8 to 11 are schematic structural views of the slicing feeding mechanism of the present invention.

Detailed Description

The present invention will be further explained with reference to the drawings and examples.

The conception, the specific structure, and the technical effects produced by the present invention will be clearly and completely described below in conjunction with the embodiments and the accompanying drawings to fully understand the objects, the features, and the effects of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and other embodiments obtained by those skilled in the art without inventive labor based on the embodiments of the present invention all belong to the protection scope of the present invention. In addition, all the connection/connection relations referred to in the patent do not mean that the components are directly connected, but mean that a better connection structure can be formed by adding or reducing connection auxiliary components according to specific implementation conditions. The utility model discloses each technical feature in the creation can the interactive combination under the prerequisite that does not contradict conflict each other.

Referring to fig. 1, 2 and 3, the present invention discloses a high efficiency automatic polishing machine device, which comprises a slicing feeding mechanism 20, a supporting base 30, a transfer assembly line 40, a feeding and discharging manipulator 50, a workpiece processing mechanism 60 and a slicing discharging mechanism 10; the piece feeding mechanism 20 and the piece blanking mechanism 10 are respectively positioned at two sides of the supporting base 30, the transfer line 40 penetrates through the supporting base 30, and two ends of the transfer line 40 are respectively positioned inside the piece feeding mechanism 20 and the piece blanking mechanism 10; it can be understood that the piece-separating feeding mechanism 20 is used for automatically feeding the glass workpiece to be processed and transferring the glass workpiece from the material frame to the transfer assembly line 40, the piece-separating discharging mechanism 10 is used for automatically discharging the processed glass workpiece, and the transfer assembly line 40 is used for automatically transferring the glass workpiece; the whole process does not need manual participation.

Referring to fig. 2 and 3, the loading and unloading robot 50 and the workpiece processing mechanism 60 are both disposed on the supporting base 30, the loading and unloading robot 50 is located above the transfer line 40, the glass workpiece to be processed is transferred to the workpiece processing mechanism 60 through the loading and unloading robot 50, and the glass workpiece processed by the loading and unloading robot 50 is transferred from the workpiece processing mechanism 60 to the transfer line 40. In addition, a positioning mechanism 70 is further disposed between the loading and unloading manipulator 50 and the workpiece processing mechanism 60, and when the loading and unloading manipulator 50 loads the glass workpiece, the positioning mechanism 70 is used for positioning the glass workpiece, so as to improve the processing precision of the glass workpiece.

As for the workpiece processing mechanism 60, referring to fig. 2 and 3, the workpiece processing mechanism 60 includes a processing jig 601, an X-axis motion module 602, a Y-axis motion module 603, a Z1-axis motion module 604, and a Z2-axis motion module 605, the Y-axis motion module 603 is disposed on the supporting base 30, the processing jig 601 is disposed on the Y-axis motion module 603, and the processing jig 601 reciprocates in the Y-axis direction by being driven by the Y-axis motion module 603; the X-axis motion module 602 is disposed above the processing fixture 601, the Z1-axis motion module 604 and the Z2-axis motion module 605 are disposed on the X-axis motion module 602, and the Z1-axis motion module 604 and the Z2-axis motion module 605 each include a polishing disc 6041 for processing a workpiece on the processing fixture 601.

Because the Z1 axis motion module 604 and the Z2 axis motion module 605 have the same structure, as shown in fig. 4 and 5, taking the structure of the Z1 axis motion module 604 as an example, the present invention provides a specific embodiment, the Z1 axis motion module 604 includes a spindle carriage 6042, a spindle motor 6043 and a polishing wheel 6044; the spindle motor 6043 is fixed on the side wall of the spindle carriage 6042, the polishing wheel 6044 is fixedly mounted at the top end of a motor shaft of the spindle motor 6043, and the polishing disc 6041 is mounted below the polishing wheel 6044, so that the glass workpiece is polished by the polishing disc 6041. In this embodiment, a Z-axis shield 6045 is further mounted on the spindle carriage 6042, and the spindle motor 6043 is located inside the Z-axis shield 6045; a water spray head 6046 is mounted to the lower portion of the Z-axis shield 6045.

In addition, as shown in fig. 2, the inner casing 301 is disposed on the supporting base 30, the processing fixture 601 is disposed inside the inner casing 301, water leakage holes are disposed at the bottom of the inner casing 301, and a grid-shaped funnel is disposed in the water leakage holes. As shown in fig. 1 and fig. 2, a body housing 302 is further disposed on the supporting base 30, and when the body housing 302 is used for preventing water, dust and debris, the overall appearance is cleaner and more beautiful, and the problem that sewage splashes outwards during product processing can be prevented. One side of the fuselage housing 302 is provided with a test through window 303, the other side is provided with a system cabinet 304, the top of the fuselage housing 302 is also provided with a signal lamp 305, and the front of the fuselage housing 302 is provided with a sliding door 306.

In the above embodiment, for the burst blanking mechanism 10, the utility model provides a specific embodiment, as shown in fig. 6 and 7, through this burst blanking mechanism 10, realize the automatic blanking of processed glass work piece, in this embodiment, burst blanking mechanism 10 includes blanking platform 101, drive module and blanking drive assembly 102, blanking drive assembly 102 be located the top of work platform, the drive module sets up on blanking platform 101, this drive module is used for driving the removal of blanking drive assembly 102 in X axle and Z axle direction; for the driving module, in this embodiment, the driving module includes a blanking mechanism X-axis moving module 103, a blanking mechanism Z-axis moving module 104, and a blanking mechanism Y-axis moving module 105, a processed glass frame 107 for receiving the glass workpiece is further disposed on the blanking platform 101, and the processed glass frame 107 is located below the blanking driving component 102, so as to facilitate receiving the glass workpiece 106. The blanking mechanism Y-axis motion module 105 is arranged on the blanking platform 101, and the processed glass material frame 107 is arranged on the blanking mechanism Y-axis motion module 105 and reciprocates in the Y-axis direction under the driving of the Y-axis motion module; the blanking platform 101 is fixedly provided with a blanking mechanism support 108, the blanking mechanism X-axis movement module 103 is arranged on the blanking mechanism support 108, and the blanking mechanism Z-axis movement module 104 is arranged on the blanking mechanism X-axis movement module 103.

Referring to fig. 6, the blanking driving component 102 is mounted on the blanking mechanism Z-axis movement module 104, so that the blanking driving component 102 reciprocates in the Z-axis direction under the driving of the blanking mechanism Z-axis movement module 104. In this embodiment, the X-axis movement module 103, the Z-axis movement module 104, and the Y-axis movement module 105 of the blanking mechanism all adopt motor lead screw modules, and the structures thereof belong to a very mature technical solution in the prior art, so detailed structures of the X-axis movement module 103, the Z-axis movement module 104, and the Y-axis movement module 105 of the blanking mechanism are not described in this embodiment.

As for the blanking driving assembly 102, as shown in fig. 6 and 7, the present invention provides a specific embodiment, the blanking driving assembly 102 includes a blanking side vertical plate 1021, a pushing assembly, and a workpiece rotating assembly, the workpiece rotating assembly includes a rotating cylinder 1022, a suction cup mounting plate 1023, and a plurality of suction cups (not shown in the figures) disposed on the suction cup mounting plate 1023, and the suction of the glass workpiece 106 is realized through the suction cups; the rotary cylinder 1022 is fixed on one side of the blanking side vertical plate 1021 through a rotary cylinder mounting block 1035, the suction cup mounting plate 1023 is connected with a cylinder rod of the rotary cylinder 1022, and the suction cup mounting plate 1023 realizes switching between a horizontal state and a vertical state under the driving of the rotary cylinder 1022; in this way, when the glass workpiece 106 is located on the conveyor belt and is in a horizontal state, the glass workpiece 106 can be switched to a vertical state by first achieving suction through the suction cup and then driving through the rotating cylinder 1022. In addition, the pushing assembly is arranged on the blanking side vertical plate 1021 and is positioned above the rotating cylinder 1022, the pushing assembly is used for realizing blanking of workpieces on the sucker, and in the scheme, the pushing assembly is used for pushing the vertical glass workpieces 106 into the processed glass frame 107; specifically, referring to fig. 2, the pushing assembly includes a pushing cylinder 1024, a cylinder mounting plate 1025, and a pressing block 1026; the pushing cylinder 1024 is fixedly arranged at one end of the cylinder mounting plate 1025, the other end of the cylinder mounting plate 1025 is fixed on the blanking side vertical plate 1021, and the pressing block 1026 is fixedly arranged at the top end of a cylinder rod of the pushing cylinder 1024. The pressing block 1026 is reciprocated in the vertical direction by the action of the pushing cylinder 1024, and in fig. 2, when the pressing block 1026 moves downward, the glass workpiece 106 is pushed out into the processed glass frit frame 107.

As a preferred embodiment, referring to fig. 7, the blanking driving assembly 102 further includes a workpiece limiting assembly, and the workpiece limiting assembly is used for clamping the glass workpiece 106 after the suction cup adsorbs the glass workpiece 106; in addition, the limit of the glass workpiece 106 in the blanking process is realized, so that the accuracy in blanking is improved. The workpiece limiting assembly comprises a limiting cylinder 1027, a limiting push plate 1028, a left supporting plate 1029, a left movable guide plate 1030, a right supporting plate 1031 and a right movable guide plate 1032; the left supporting plate 1029 and the right supporting plate 1031 are relatively fixed on the blanking side vertical plate 1021, and in order to reduce the whole weight, the left supporting plate 1029 and the right supporting plate 1031 are both in a frame shape; the limiting cylinder 1027 is fixed on the blanking side vertical plate 1021 and is positioned between the left supporting plate 1029 and the right supporting plate 1031, and the limiting push plate 1028 is fixed at the top end of a cylinder rod of the limiting cylinder 1027; in this embodiment, the spacing cylinder 1027 is transversely disposed and fixed on the blanking side vertical plate 1021 via a spacing cylinder fixing block 1033.

Further, the left movable guide plate 1030 is fixedly connected with the limiting push plate 1028, the right movable guide plate 1032 is fixed on the right support plate 1031, and the left movable guide plate 1030 and the right movable guide plate 1032 are oppositely arranged and respectively located on two sides of the suction cup mounting plate 1023 to clamp the glass workpiece 106 on the suction cup. In this embodiment, the side walls opposite to the left movable guide plate 1030 and the right movable guide plate 1032 are provided with inward recessed strip-shaped grooves, which are convenient for clamping the glass workpiece 106 on one hand, and play a good role in guiding when the pressing block 1026 pushes the glass workpiece 106 into the processed glass frit frame 107 on the other hand, so that the glass workpiece 106 can be accurately placed in a predetermined position of the processed glass frit frame 107. In addition, as shown in fig. 2, the left movable guide plate 1030 and the right movable guide plate 1032 are fixed through the kidney-shaped holes, and the distance between the left movable guide plate 1030 and the right movable guide plate 1032 can be adjusted, so that the glass cover plate is suitable for glass cover plates with different sizes, the applicability of the glass cover plate is improved, and blanking of glass workpieces with any size can be realized.

Furthermore, in the above embodiment, the cylinder rod of the limiting cylinder 1027 passes through the left supporting plate 1029, the limiting push plate 1028 is located outside the left supporting plate 1029, a plurality of guide rods 1034 are fixedly mounted on the limiting push plate 1028, a corresponding number of guide sleeves are arranged on the left supporting plate 1029, and one ends of the guide rods 1034 are inserted into the guide sleeves. Through this kind of structure, spacing cylinder 1027 is in the drive spacing push pedal 1028 reciprocating motion in-process, through the cooperation of guide arm 1034 and guide pin bushing, and the guide effect that plays that can be fine avoids spacing push pedal 1028 and the removal of left side movable guide plate 1030 to appear the deviation, improves the accurate nature of left side movable guide plate 1030 and right side movable guide plate 1032 to the centre gripping of glass work piece 106.

Combine foretell structure, we are right the utility model discloses a work process of burst unloading mechanism explains, at first under the cooperation of unloading mechanism X axle motion module 103 and unloading mechanism Z axle motion module 104, unloading drive assembly 102 moves to the glass work piece 106 top of treating the unloading, and sucking disc mounting panel 1023 is the level form this moment to realize the absorption to glass work piece 106 through the sucking disc. Then, under the coordination of the X-axis movement module 103 of the blanking mechanism, the Z-axis movement module 104 of the blanking mechanism and the Y-axis movement module 105 of the blanking mechanism, the glass workpiece 106 is moved to the upper part of the processed glass frame 107, meanwhile, in the process, the rotary cylinder 1022 drives the glass workpiece 106 to rotate, so that the glass workpiece 106 is in a vertical state, the limiting cylinder 1027 drives the left movable guide plate 1030 to retract, and the glass workpiece 106 is clamped in the strip-shaped grooves of the left movable guide plate 1030 and the right movable guide plate 1032. During the blanking process, the cylinder rod of the pushing cylinder 1024 extends, the pressing block 1026 is located right above the glass workpiece 106, and the glass workpiece 106 is transferred to the processed glass frit frame 107 along the strip-shaped grooves of the left movable guide plate 1030 and the right movable guide plate 1032 under the action of the pushing cylinder 1024. In order to facilitate the transfer of the glass workpiece 106, the limiting cylinder 1027 can drive the left and right movable guide plates to move towards the direction far away from the glass workpiece 106, and by controlling the movement amount, the two sides of the glass workpiece 106 are always in the strip-shaped grooves, and meanwhile, the situation that blanking cannot be performed due to the fact that the friction force between the left movable guide plate 1030 and the right movable guide plate 1032 is too large and the glass workpiece 106 is too large is avoided.

Therefore, the utility model discloses burst unloading mechanism can realize glass work's automatic unloading, and automatic shifts glass work to the glass material frame from the conveyer belt, and whole journey need not artifical the participation, has improved unloading efficiency, reduces the cost of labor. And, because the structural design of the spacing subassembly of work piece, can realize the accurate unloading of glass work piece, avoid glass work piece to appear colliding with in the unloading process, improved the accuracy nature and the product yield of unloading.

To burst feed mechanism 20, it is shown with reference to fig. 8 to 11, the utility model provides a specific embodiment, burst feed mechanism 20 includes automatic burst structure, glass frame 13 and is used for placing glass's loading board 14, loading board 14 is located glass frame 13, automatic burst structure sets up between loading board 14 and glass frame 13, automatic burst structure is used for adjusting the size of loading board 14 in glass frame 13.

When feeding is carried out, the glass slicing module separates the stacked glass, then the glass driving component 16 can drive the glass adsorption component 15 to adsorb the separated glass, and the glass adsorption structure is driven to convey the glass to a processing position. Because the glass is vertically placed on the bearing plate 14, the supporting edge of the glass frame 13 on the Y axis is close to the size of the glass, so that the glass can be stably supported, but for the multilayer glass stacked in the X axis direction, the distance of the glass frame 13 on the X axis determines the stability of the glass in the frame and whether the glass is convenient to take and place. And the size of the bearing plate 14 in the glass frame 13 can be adjusted by the arranged automatic slicing structure, namely, the size of the glass frame 13 in the X-axis direction is adjusted, so that the stability of placing the glass when the glass is not taken can be ensured, and the easiness of taking the glass can be ensured.

Referring to fig. 10 and 11, the automatic sheet separating structure includes a pushing assembly 12 and a sliding assembly 11, a frame bottom plate 31 is disposed at the bottom of the glass frame 13, the pushing assembly 12 is used for pushing the bearing plate 14 and the glass placed on the bearing plate 14, and the sliding assembly 11 is used for sliding between the bearing plate 14 and the frame bottom plate 31.

The sliding assembly 11 comprises a sliding bearing 111 arranged on the frame bottom plate 31 and a slideway 112 arranged on the bearing plate 14, and the sliding bearing 111 is arranged in the slideway 112 in a sliding way; the pushing assembly 12 comprises an elastic pushing member and a direct pushing member, the direct pushing member is a gas blowing rod 122 arranged on the glass frame 13, and the gas blowing rod 122 is fixedly connected with one end, corresponding to the vertical surface of the glass, of the glass frame 13 through a fixing block. The sliding bearings 111 are provided in plurality, and a plurality of groups of sliding bearings 111 are uniformly arranged on two sides of the frame bottom plate 31, and the slide rails 112 are arranged at the bottom of the bearing plate 14 and correspond to the sliding bearings 111; the elastic pushing part is a spring 121 connected with the bottom of the bearing plate 14 and the frame bottom plate 31, and the bearing plate 14 and the frame bottom plate 31 are both provided with a spring 121 movable groove and a spring 121 mounting buckle.

When the glass needs to be taken out, the blowing rods 122 arranged on the glass frame 13 blow the glass arranged in front of the blowing rods 122, and the glass which is impacted moves backwards due to the fact that the glass is arranged on the bearing plate 14, so that the bearing plate 14 is driven to move backwards. At this time, a distance is left between the carrying plate 14 and the side of the glass frame 13 where the blowing rod 122 is disposed, and the suction assembly of the plate taking device can suck the first glass in the left space to take the plate. After the glass is taken away, the blowing rod 122 stops blowing, at this time, the stress on the glass disappears, the tension on the spring 121 arranged between the bearing plate 14 and the frame bottom plate 31 disappears, the spring 121 rebounds, and the bearing plate 14 drives the glass to return to the position where the glass is in contact with the edge of the glass frame 13, so that the stability of the glass when the glass is not taken away is ensured.

Referring to fig. 9, the automatic slicing structure is further provided with a glass adsorption component 15 and a glass driving component 16 for driving the glass adsorption component 15, the glass adsorption component 15 is used for adsorbing glass in the slicing structure, and the glass driving component 16 is used for driving the slicing structure; when feeding is carried out, the glass slicing module separates the stacked glass, then the glass driving component 16 can drive the glass adsorption component 15 to adsorb the separated glass, and the glass adsorption structure is driven to convey the glass to a processing position.

The automatic feeding structure saves manpower and material resources, increases the feeding efficiency of glass, can control the position isoparametric of the glass when the glass is sucked and placed, ensures the feeding accuracy and is convenient for the polishing machine to further process the glass.

The utility model discloses a high-efficient automatic burnishing machine device, burst feed mechanism 20 carries out automatic burst and automatic feeding action, is equipped with independent last feeding mechanical arm 50 and carries out automatic feeding and unloading action, is equipped with transfer assembly line 40 and treats machine glass and machine glass's automatic circulation action, is equipped with burst unloading mechanism 10 and carries out independent unloading action, has increased the application scope of burnishing machine, can realize actions such as automatic feeding, burst, processing, unloading of full-automatic glass work piece. When polishing the work piece, the multiunit goes on simultaneously, and polishing precision is high, efficient, long-term stability in use is good, and fuselage inner cover 301 below still is equipped with the water drainage tank of concentrated drainage blowdown, can realize the full automated processing and the automatic unloading of glass work piece of going up, has practiced thrift manpower and cost when very big improvement machining efficiency.

While the preferred embodiments of the present invention have been described, the present invention is not limited to the above embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present invention, and such equivalent modifications or substitutions are intended to be included within the scope of the present invention as defined by the appended claims.

Claims

1. An efficient automatic polisher device is characterized by comprising a slicing feeding mechanism, a supporting base, a transfer assembly line, a feeding and discharging manipulator, a workpiece processing mechanism and a slicing discharging mechanism;

the fragment feeding mechanism and the fragment blanking mechanism are respectively positioned at two sides of the supporting base, the transfer assembly line penetrates through the supporting base, and two ends of the transfer assembly line are respectively positioned in the fragment feeding mechanism and the fragment blanking mechanism;

2. The apparatus of claim 1, wherein the workpiece processing mechanism comprises a processing fixture, an X-axis motion module, a Y-axis motion module, a Z1-axis motion module, and a Z2-axis motion module;

the Y-axis movement module is arranged on the supporting base, the processing jig is arranged on the Y-axis movement module, and the processing jig reciprocates in the Y-axis direction under the driving of the Y-axis movement module;

3. A high efficiency automatic polisher device as in claim 2 wherein each of the Z1 and Z2 axis motion modules comprises a spindle carriage, a spindle motor and a polishing wheel;

4. The automatic polisher device as claimed in claim 2, wherein the support base has an inner housing, the processing fixture is located inside the inner housing, and the inner housing has a plurality of water leakage holes at its bottom.

5. The automatic polishing machine device according to claim 1, wherein the slicing and blanking mechanism comprises a blanking platform, a driving module and a blanking driving assembly, the blanking driving assembly is located above the working platform, the driving module is arranged on the blanking platform, and the driving module is used for driving the blanking driving assembly to move in the X-axis direction and the Z-axis direction;

6. A high-efficiency automatic polishing machine device as recited in claim 5, wherein said feeding drive assembly further comprises a workpiece limiting assembly, said workpiece limiting assembly comprising a limiting cylinder, a limiting push plate, a left support plate, a left movable guide plate, a right support plate and a right movable guide plate;

7. A high efficiency automatic polisher device as claimed in claim 6 wherein the opposing side walls of the left and right movable guides are provided with inwardly recessed strip grooves.

8. A high efficiency automatic polisher device as claimed in claim 6 wherein the cylinder rod of the spacing cylinder passes through the left support plate, the spacing push plate is located outside the left support plate, the spacing push plate is fixedly mounted with a plurality of guide rods, the left support plate is provided with a corresponding number of guide sleeves, and one end of the guide rod is inserted into the guide sleeve.

9. A high efficiency automatic polisher apparatus as claimed in claim 5 wherein the slice blanking mechanism further comprises a processed frit frame disposed on the work platform and below the blanking drive assembly.

10. The apparatus of claim 9, wherein the driving module comprises a feeding mechanism X-axis motion module, a feeding mechanism Z-axis motion module, and a feeding mechanism Y-axis motion module;

the blanking mechanism Y-axis movement module is arranged on the blanking platform, and the processed glass frame is arranged on the blanking mechanism Y-axis movement module and driven by the Y-axis movement module to reciprocate in the Y-axis direction;