CN116571456A - Automatic thickness measurement and grading system for optical glass - Google Patents

Abstract

The invention discloses an automatic thickness measurement and grading system for optical glass, which comprises a feeding mechanism, a transferring mechanism and a discharging mechanism; four station grooves matched with the plastic suction boxes for the optical glass are uniformly formed in the second turntable; the bottom of the station tank is symmetrically provided with a lifting assembly matched with the plastic sucking box; a plastic suction box feeding assembly, the material taking assembly, a thickness measuring assembly and a discharging assembly close to the discharging mechanism are sequentially arranged above the four station grooves; and a blanking assembly is arranged between the transfer mechanism and the blanking mechanism. The feeding mechanism, the transferring mechanism and the discharging mechanism are matched, and the discharging assembly, the lifting assembly and the discharging assembly are matched; the automatic sorting machine can sort in bin assemblies according to different thicknesses, is high in automation degree and detection efficiency, reduces human influence and production cost, and improves measurement accuracy.

Description

Automatic thickness measurement and grading system for optical glass

Technical Field

The invention relates to the field of optical glass equipment, in particular to an automatic thickness measuring and grading system for optical glass.

Background

The optical glass can change the propagation direction of light and can change the glass of the relative spectral distribution of ultraviolet, visible or infrared light. The narrow definition of optical glass refers to colorless optical glass; the broad sense optical glass also includes colored optical glass, laser glass, quartz optical glass, radiation-resistant glass, ultraviolet-infrared optical glass, fiber optical glass, acousto-optic glass, magneto-optic glass, and photochromic glass. The optical glass can be used for manufacturing lenses, prisms, reflectors, windows and the like in optical instruments. The component made of optical glass is a critical element in optical instruments.

In the processing process of the optical glass, the surface thickness requirement on the glass is particularly strict, the surface thickness is required to be uniform, the thickness of the optical glass is required to be measured, the optical glass is required to be cleaned before measurement, the cleaned optical glass is measured, in the actual use process, the optical glass is cleaned manually, and then the cleaned optical glass is placed in a measuring position to measure the thickness, the measuring efficiency is low in the process, secondary pollution is caused to the optical glass due to human factors after cleaning, and the measuring precision is further influenced. And the optical glass with different thickness is required to be graded and fed after measurement, in the actual use process, the working efficiency is low through manual grading, and human factors can damage the optical glass, so that the production cost is increased.

Disclosure of Invention

In order to solve the technical problems, the invention provides a device which is matched with a feeding mechanism, a transferring mechanism and a discharging mechanism, and is matched with a discharging assembly, a lifting assembly and the discharging assembly; the automatic sorting machine can sort in bin assemblies according to different thicknesses, is high in automation degree and detection efficiency, reduces human influence and production cost, and improves measurement accuracy.

In order to solve the technical problems, the invention is realized by the following technical scheme:

an automatic thickness measurement and grading system for optical glass comprises a feeding mechanism, wherein the feeding mechanism comprises a first rotary table, a plurality of discharging frame components and a material taking component, the discharging frame components are arranged on the first rotary table, and the material taking component is erected through a vertical frame; the transferring mechanism comprises a second turntable; the blanking mechanism comprises a rotary table III and a plurality of bin assemblies which are all arranged on the rotary table III; four station grooves matched with the plastic suction boxes for the optical glass are uniformly formed in the second turntable; the bottom of the station tank is symmetrically provided with a lifting assembly matched with the plastic sucking box; a plastic suction box feeding assembly, the material taking assembly, a thickness measuring assembly and a discharging assembly close to the discharging mechanism are sequentially arranged above the four station grooves; and a blanking assembly is arranged between the transfer mechanism and the blanking mechanism. The material discharging frame component is used for placing optical glass, through a plurality of settings, the optical glass can be transferred between different stations under the action of the first rotary disk, the cleanliness of the optical glass before measurement is ensured, the thickness measurement is accurate, through the setting of the material feeding component of the plastic sucking box, the plastic sucking box is placed in the station groove, the plastic sucking box is lifted through the lifting component, under the rotation of the second rotary disk, the placed plastic sucking box is transferred to the lower part of the material taking component, under the action of the material taking component, the cleaned optical glass is grabbed to the plastic sucking box, under the action of the second rotary disk, the optical glass to be measured is transferred to the lower part of the thickness measuring component for thickness measurement, thickness data are obtained after the measurement is completed, the second rotary disk is rotated, the measured optical glass is rotated to the lower part of the material discharging component, under the action of the material discharging component, the plastic sucking box carries the measured optical glass to the material bin component in the material discharging mechanism through the action of the material discharging component, and the corresponding plastic sucking box is rotated to the upper part of the material sucking box and the material discharging component according to different thickness values; the measuring precision is guaranteed, the measuring efficiency is improved, and different optical glasses are classified according to the vertical measurement, so that the automatic classification is convenient for subsequent use.

Further, the thickness measuring assembly comprises a transverse frame erected above the station groove, a sliding rail arranged on the transverse frame, a sliding block which moves back and forth on the sliding rail through a driving motor, a suspension frame arranged at the bottom of the sliding block and a sensor group arranged on the suspension frame. The sensor group can move in horizontal position, can measure a plurality of places for optical glass, ensures measurement accuracy, and has simple structure and convenient use.

Further, the lifting assembly comprises a mounting block arranged at the bottom of the turntable, a connecting rod inserted in the mounting block through an elastic element, a lifting block arranged at the free end of the connecting rod, a guide rod with one end connected with the lifting block and the other end penetrating through the mounting block, and a control block arranged at the end part of the guide rod. Through controlling above-mentioned control block, can drive above-mentioned guide arm and slide on above-mentioned installation piece, and then drive the removal of above-mentioned lifting block, realize the operation of lifting and placing the plastic uptake box, when unclamping above-mentioned control block, above-mentioned lifting block resumes the plastic uptake box and lifts the state under the effect of above-mentioned elastic component and above-mentioned connecting rod, simple structure, and is practical convenient.

Further, the discharging component comprises a hanging plate fixedly arranged on the vertical frame, a transverse plate suspended at the end part of the hanging plate through a first telescopic cylinder and a discharging plate which is arranged at the two ends of the transverse plate through a second telescopic cylinder and is matched with the control block. The transverse plate moves downwards through the expansion of the first expansion cylinder, when the discharge plate moves to the side of the control block, the second expansion cylinder is driven to expand the two discharge plates outwards, the control block is driven by the discharge plate to realize the opening and closing of the lifting block, the control of the plastic suction box is realized, and the plastic suction box is simple in structure and reliable in control.

Further, the blanking assembly comprises a rotating plate arranged at the bottoms of the second rotating plate and the third rotating plate through a rotating assembly, a pushing cylinder arranged at the bottom of the rotating plate and a pushing plate arranged on the pushing cylinder; storage grooves matched with the plastic sucking boxes are symmetrically formed in two ends of the rotating plate; the storage groove is provided with a through hole matched with the pushing plate. The storage groove is used for placing the plastic sucking box, the measured optical glass is located in the plastic sucking box, the rotating plate rotates between the transferring mechanism and the discharging mechanism through the rotation of the rotating component, the material pushing plate below the transferring mechanism ascends to push the plastic sucking box under the action of the material pushing cylinder, the plastic sucking box is taken out through the discharging component, the material pushing plate moves downwards until the plastic sucking box falls into the storage groove, the rotating plate rotates, the plastic sucking box is transferred to the lower part of the discharging mechanism, and the plastic sucking box is pushed into the storage bin component through the material pushing plate below the discharging mechanism to be stored.

Further, the plastic uptake box material loading subassembly includes that one erects in carousel two tops and be equipped with one with the mounting bracket of the material loading export of plastic uptake box looks adaptation, vertical setting are in the pole setting of material loading export week side, symmetry setting are in the material loading piece on the mounting bracket of material loading export both sides and set up the kicking block of material loading export below. Through the setting of above-mentioned pole setting, surround into a storage space of depositing the plastic uptake box, in this storage space, above-mentioned plastic uptake box stacks together from top to bottom, when needs plastic uptake box, above-mentioned kicking block upwards withstands the plastic uptake box in the pole setting under the effect of cylinder, above-mentioned material loading piece is opened no longer under the effect of cylinder and is supported the plastic uptake box this moment, under the effect of above-mentioned kicking block, with the plastic uptake box of bottommost through above-mentioned material loading export, penultimate plastic uptake box still is located above-mentioned material loading piece, the material loading piece of drive both sides this moment, with the plastic uptake box separation of bottommost, and move down to the material loading operation of accomplishing the plastic uptake box on the lifting subassembly under the effect of above-mentioned kicking block.

Compared with the prior art, the invention has the advantages that: can carry out the classification according to different thickness in feed bin subassembly, degree of automation is high, and detection efficiency is high, and has reduced artificial influence and manufacturing cost, has improved measurement accuracy.

Drawings

FIG. 1 is a three-dimensional schematic of the present invention.

Fig. 2 is an enlarged view at a in fig. 1.

Fig. 3 is an enlarged view at B in fig. 1.

Fig. 4 is a three-dimensional schematic diagram of the feeding mechanism of the present invention.

Fig. 5 is a three-dimensional schematic of a transfer mechanism of the present invention.

Fig. 6 is an enlarged view at C in fig. 5.

Fig. 7 is an enlarged view of D in fig. 5.

Fig. 8 is another angular three-dimensional schematic of fig. 5.

Fig. 9 is an enlarged view at E in fig. 8.

Fig. 10 is a three-dimensional schematic view of the blanking mechanism of the present invention.

Fig. 11 is an enlarged view of F in fig. 10.

In the figure:

1. a feeding mechanism; 2. a transfer mechanism; 3. a blanking mechanism; 4. a first turntable; 5. a discharging frame component; 6. a vertical frame; 7. a material taking assembly; 8. a second turntable; 9. a turntable III; 10. a bin assembly; 11. a plastic suction box; 12. an optical glass; 13. a station groove; 14. a lifting assembly; 15. a plastic suction box feeding component; 16. a thickness measuring assembly; 17. a discharge assembly; 18. a blanking assembly; 19. a cross frame; 20. a slide rail; 21. a driving motor; 22. a slide block; 23. a suspension; 24. a sensor group; 25. a mounting block; 26. a connecting rod; 27. a lifting block; 28. a guide rod; 29. a control block; 30. a suspension plate; 31. a telescopic cylinder I; 32. a cross plate; 33. a telescopic cylinder II; 34. a discharge plate; 35. a rotating assembly; 36. a rotating plate; 37. a pushing cylinder; 38. a pushing plate; 39. a storage tank; 40. a through hole; 41. a feeding outlet; 42. a mounting frame; 43. a vertical rod; 44. feeding a material block; 45. a top block; 46. a riser; 47. a support rod; 48. a limit rod; 49. a limiting block; 50. and a transverse groove.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present invention, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; may be mechanically connected, may be electrically connected or may be in communication with each other; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

Referring to fig. 1-11, in this embodiment of an automatic thickness measuring and grading system for optical glass according to the present invention, the system includes a loading mechanism 1, a transferring mechanism 2 and a discharging mechanism 3, where the loading mechanism 1 includes a first turntable 4, a first discharging frame assembly 5 is uniformly disposed on the first turntable 4, in this embodiment, the first discharging frame assembly 5 is provided with four groups corresponding to placement, cleaning, draining and material taking of the optical glass 12, respectively, when in use, the optical glass 12 to be cleaned is placed in one group of the first discharging frame assemblies 5, the placed optical glass 12 is rotated to a cleaning position by rotation of the first turntable 4, after cleaning, the drained optical glass 12 is continuously rotated to a draining position for draining, and finally the drained optical glass 12 is rotated to a lower part of an assembly 7, after the cleaned optical glass 12 is transferred to the transferring mechanism 2 for measurement, the cleaned optical glass 12 is continuously rotated to an initial position for placement, and the four groups of the first discharging frame assemblies are disposed, thereby ensuring that the material taking efficiency is improved; in this embodiment, the discharging frame assembly 5 includes a stopper 49 disposed on the first turntable 4, a vertical plate 46 symmetrically disposed between the stoppers 49, a supporting rod 47 sandwiched between the bottoms of the vertical plates 46, and two limiting rods 48 sandwiched between the tops of the vertical plates 46, and by disposing the supporting rod 47 and the limiting rods 48, a space for placing the optical glass 12 is formed between the supporting rod 47 and the limiting rods 48, transverse grooves 50 are symmetrically disposed on the vertical plates 46, screws adapted to the transverse grooves 50 and nuts for fixing the screws are disposed on both ends of the supporting rod 47 and the limiting rods 48, and the diameters of the parts of the supporting rod 47 and the limiting rods 48, which are in contact with the optical glass 12, are larger than the longitudinal dimension of the transverse grooves 50, by this arrangement, the vertical rods are abutted in the stopper 49, so that the installation is convenient, and the selection of different vertical plate 46 dimensions can be flexibly used according to different optical glass 12 dimensions; the screw and the nut are fixed, so that the screw and the nut are convenient to use, and in other embodiments, the screw and the nut can be arranged in other forms, and the description is omitted here; the transfer mechanism 2 comprises a second turntable 8, four station grooves 13 are uniformly formed in the second turntable 8, the station grooves 13 are matched with the plastic suction boxes 11 for the optical glass 12, and lifting assemblies 14 matched with the plastic suction boxes 11 are symmetrically arranged at the bottoms of the station grooves 13; a plastic suction box feeding component 15, the material taking component 7, a thickness measuring component 16 and a discharging component 17 close to the discharging mechanism 3 are sequentially arranged above the four station grooves 13; a blanking component 18 is arranged between the transfer mechanism 2 and the blanking mechanism 3, the plastic sucking box 11 is placed in the station groove 13 by the plastic sucking box feeding component 15, the plastic sucking box is rotated to the lower part of the material taking component 7 under the action of the rotary disc II 8, the optical glass 12 taken out of the material taking component 7 by the material feeding mechanism 1 is placed on the plastic sucking box 11, the rotary disc II 8 is continuously rotated, the plastic sucking box 11 is rotated to the lower part of the thickness measuring component 16 to measure the thickness, and finally the plastic sucking box is rotated to the lower part of the discharging component 17, the plastic sucking box is transported to the feed bin component 10 of the blanking mechanism 3 through the blanking component 18, and the different feed bin components 10 are rotated to the upper part of the blanking component 18 to be blanked according to the optical glass 12 with different thicknesses, so that the measurement accuracy is ensured, the measurement efficiency is improved, the different optical glass 12 is classified according to the vertical measurement, and the automatic classification is convenient to use.

Referring to fig. 5, 6, 8 and 9, in the present embodiment, the thickness measuring assembly 16 includes a cross frame 19 installed above the station slot 13, a rail 20 provided on the cross frame 19, a slider 22 reciprocally moved on the rail 20 by a driving motor 21, a hanger 23 provided at the bottom of the slider 22, and a sensor group 24 provided on the hanger 23. The sensor group 24 can move horizontally, can measure a plurality of places on the optical glass 12, ensures measurement accuracy, has a simple structure and is convenient to use, and in the embodiment, the sensor group 24 is provided with three groups, and three measurements are performed during measurement, namely, nine-point thickness measurement is performed on the optical glass 12, thereby ensuring measurement accuracy.

Referring to fig. 1, 5, 7, 8 and 9, the lifting assembly 14 includes a mounting block 25 disposed at the bottom of the turntable 8, a connecting rod 26 inserted into the mounting block 25 through an elastic member, a lifting block 27 disposed at a free end of the connecting rod 26, a guide rod 28 having one end connected to the lifting block 27 and the other end penetrating the mounting block 25, and a control block 29 disposed at an end of the guide rod 28, wherein the control block 29 is controlled to drive the guide rod 28 to slide on the mounting block 25 and further drive the lifting block 27 to move, thereby realizing the operation of lifting and placing the suction box 11, and the lifting block 27 restores the lifting state of the suction box 11 under the action of the elastic member and the connecting rod 26 when the control block 29 is released; in this embodiment, the discharging assembly 17 includes a suspension board 30 fixed on the stand 6, a transverse board 32 suspended at an end of the suspension board 30 by a first telescopic cylinder 31, and a discharging board 34 arranged at two ends of the transverse board 32 and adapted to the control block 29 by a second telescopic cylinder 33, the transverse board 32 is moved downward by the telescopic cylinder 31, and when the discharging board 34 moves to the side of the control block 29, the second telescopic cylinder 33 is driven to open the two discharging boards 34 outwards, and the control block 29 is driven by the discharging board 34 to open and close the lifting block 27, so as to control the plastic suction box 11.

Referring to fig. 1, 10 and 11, in the present embodiment, the discharging assembly 18 includes a rotating plate 36 disposed at the bottom of the second and third turntables 8 and 9 via a rotating assembly 35, a pushing cylinder 37 disposed at the bottom of the rotating plate 36, and a pushing plate 38 disposed on the pushing cylinder 37; storage grooves 39 matched with the plastic suction box 11 are symmetrically formed at two ends of the rotating plate 36; the storage groove 39 is provided with a through hole 40 adapted to the pushing plate 38. The storage groove 39 is used for placing the plastic sucking box 11, the measured optical glass 12 is positioned in the plastic sucking box 11, the rotating plate 36 rotates between the transferring mechanism 2 and the blanking mechanism 3 through the rotation of the rotating assembly 35, the material pushing plate 38 below the transferring mechanism 2 ascends under the action of the material pushing cylinder 37 to push the plastic sucking box 11, the plastic sucking box 11 is taken out through the discharging assembly 17, the material pushing plate 38 moves downwards until the plastic sucking box 11 falls into the storage groove 39, the rotating plate 36 rotates to transfer the plastic sucking box 11 below the blanking mechanism 3, and the plastic sucking box 11 is pushed into the storage bin assembly 10 through the material pushing plate 38 below the blanking mechanism 3 to be stored.

Referring to fig. 1, 3, 5, 8 and 9, in this embodiment, the feeding assembly 15 of the plastic suction box includes a mounting frame 42 mounted above the second turntable 8 and provided with a feeding outlet 41 adapted to the plastic suction box 11, vertical rods 43 vertically disposed at the periphery of the feeding outlet 41, feeding blocks 44 symmetrically disposed on the mounting frame 42 at two sides of the feeding outlet 41, and a top block 45 disposed below the feeding outlet 41. Through the setting of pole setting 43, surround into the storage space of depositing plastic uptake box 11, in this storage space, above-mentioned plastic uptake box 11 stacks together from top to bottom, when needs plastic uptake box 11, above-mentioned kicking block 45 upwards withstands the plastic uptake box 11 in the pole setting 43 under the effect of cylinder, above-mentioned material loading piece 44 opens no longer to the plastic uptake box 11 under the effect of cylinder at this moment, under the effect of above-mentioned kicking block 45, with the plastic uptake box 11 of bottommost through above-mentioned material loading export 41, penultimate plastic uptake box 11 still is located above-mentioned material loading piece 44, the material loading piece 44 of drive both sides at this moment, with the plastic uptake box 11 separation of bottommost, and move down to the material loading operation of carrying on the subassembly 14 under the effect of above-mentioned kicking block 45 and accomplish the plastic uptake box 11.

The above embodiments are merely illustrative embodiments of the present invention, but the technical features of the present invention are not limited thereto, and any changes or modifications made by those skilled in the art within the scope of the present invention are included in the scope of the present invention.

Claims (10)

1. An automatic thickness measurement and grading system for optical glass is characterized in that: comprising

The feeding mechanism comprises a first rotary table, a plurality of discharging frame components and a material taking component, wherein the discharging frame components are arranged on the first rotary table, and the material taking component is erected through a vertical frame;

the transferring mechanism comprises a second turntable;

the blanking mechanism comprises a rotary table III and a plurality of bin assemblies which are all arranged on the rotary table III;

four station grooves matched with the plastic suction boxes for the optical glass are uniformly formed in the second turntable; the bottom of the station tank is symmetrically provided with a lifting assembly matched with the plastic sucking box; a plastic suction box feeding assembly, the material taking assembly, a thickness measuring assembly and a discharging assembly close to the discharging mechanism are sequentially arranged above the four station grooves; and a blanking assembly is arranged between the transfer mechanism and the blanking mechanism.

2. The automatic thickness measurement and grading system for optical glass according to claim 1, wherein: the thickness measuring assembly comprises a transverse frame erected above the station groove, a sliding rail arranged on the transverse frame, a sliding block which reciprocates on the sliding rail through a driving motor, a suspension frame arranged at the bottom of the sliding block and a sensor group arranged on the suspension frame.

3. The automatic thickness measurement and grading system for optical glass according to claim 1 or 2, characterized in that: the lifting assembly comprises a mounting block arranged at the bottom of the turntable, a connecting rod inserted in the mounting block through an elastic element, a lifting block arranged at the free end of the connecting rod, a guide rod with one end connected with the lifting block and the other end penetrating through the mounting block, and a control block arranged at the end part of the guide rod.

4. The automatic thickness measuring and grading system for optical glass according to claim 3, wherein: the discharging component comprises a hanging plate fixedly arranged on the vertical frame, a transverse plate suspended at the end part of the hanging plate through a telescopic cylinder I and a discharging plate arranged at the two ends of the transverse plate through a telescopic cylinder II and matched with the control block.

5. The automatic thickness measurement and grading system for optical glass according to claim 1 or 2, characterized in that: the blanking assembly comprises a rotating plate arranged at the bottoms of the second rotating plate and the third rotating plate through a rotating assembly, a pushing cylinder arranged at the bottom of the rotating plate and a pushing plate arranged on the pushing cylinder; storage grooves matched with the plastic sucking boxes are symmetrically formed in two ends of the rotating plate; the storage groove is provided with a through hole matched with the pushing plate.

6. The automatic thickness measuring and grading system for optical glass according to claim 3, wherein: the blanking assembly comprises a rotating plate arranged at the bottoms of the second rotating plate and the third rotating plate through a rotating assembly, a pushing cylinder arranged at the bottom of the rotating plate and a pushing plate arranged on the pushing cylinder; storage grooves matched with the plastic sucking boxes are symmetrically formed in two ends of the rotating plate; the storage groove is provided with a through hole matched with the pushing plate.

7. The automatic thickness measuring and grading system for optical glass according to claim 4, wherein: the blanking assembly comprises a rotating plate arranged at the bottoms of the second rotating plate and the third rotating plate through a rotating assembly, a pushing cylinder arranged at the bottom of the rotating plate and a pushing plate arranged on the pushing cylinder; storage grooves matched with the plastic sucking boxes are symmetrically formed in two ends of the rotating plate; the storage groove is provided with a through hole matched with the pushing plate.

8. The automatic thickness measurement and grading system for optical glass according to claim 1 or 2, characterized in that: the plastic uptake box material loading subassembly includes that one erects in carousel two tops and be equipped with one with the mounting bracket of the material loading export of plastic uptake box looks adaptation, vertical setting are in the pole setting of material loading export week side, symmetry setting are in the material loading piece on the mounting bracket of material loading export both sides and set up the kicking block of material loading export below.

9. The automatic thickness measuring and grading system for optical glass according to claim 3, wherein: the plastic uptake box material loading subassembly includes that one erects in carousel two tops and be equipped with one with the mounting bracket of the material loading export of plastic uptake box looks adaptation, vertical setting are in the pole setting of material loading export week side, symmetry setting are in the material loading piece on the mounting bracket of material loading export both sides and set up the kicking block of material loading export below.

10. The automatic thickness measuring and grading system for optical glass according to claim 5, wherein: the plastic uptake box material loading subassembly includes that one erects in carousel two tops and be equipped with one with the mounting bracket of the material loading export of plastic uptake box looks adaptation, vertical setting are in the pole setting of material loading export week side, symmetry setting are in the material loading piece on the mounting bracket of material loading export both sides and set up the kicking block of material loading export below.