CN210082131U - Lens cutting impurity recovery device - Google Patents

Abstract

The utility model discloses a lens cutting impurity recovery device, which comprises a workbench and a positioning plate arranged on the workbench; the positioning plate is provided with a guide plate for placing waste materials, one side end face of the guide plate is hinged to the positioning plate, the workbench is provided with a first air cylinder, and the first air cylinder is used for pushing the guide plate to rotate relative to the positioning plate; a first baffle is arranged at one end of the guide plate, a push plate is arranged above one end, close to the first baffle, of the guide plate, the side, provided with the push plate, of the guide plate is an input side, the side, opposite to the push plate, of the guide plate is an output side, a second air cylinder is arranged on the first baffle, and the second air cylinder is used for pushing the push plate to move above the guide plate along the direction perpendicular to the length direction of the positioning plate; the worktable is provided with a storage groove.

Description

Lens cutting impurity recovery device

Technical Field

The utility model relates to a lens cutting impurity recovery unit.

Background

Optical lenses are classified as convex, concave, biconvex, biconcave, plano-convex, Regenada, and the like. The optical lens processing requires processes such as cutting, rough grinding, polishing, coating and the like. The blank is cut on a cutting machine, the two end faces of the two lenses are cut to be closer to the target spherical radius, no pits exist on the cut surfaces, and the like, so that preparation is made for subsequent steps of rough grinding, polishing, and the like. Cutting impurities are generated in the cutting process, the impurities are accumulated on a cutting machine, and the impurities are attached to the surface of a blank material to cause cutting defects.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a lens cutting impurity recovery unit utilizes can relative pivoted deflector, realizes the directional propelling movement of cutting impurity, and what make things convenient for the push pedal can concentrate will cut impurity to putting thing groove direction propelling movement, avoid scattering.

The lens cutting impurity recovery device comprises a workbench and a positioning plate arranged on the workbench;

the positioning plate is provided with a guide plate for placing waste materials, one side end face of the guide plate is hinged to the positioning plate, the workbench is provided with a first air cylinder, and the first air cylinder is used for pushing the guide plate to rotate relative to the positioning plate;

a first baffle is arranged at one end of the guide plate, a push plate is arranged above one end, close to the first baffle, of the guide plate, one side, provided with the push plate, of the guide plate is an input side, the side, opposite to the push plate, of the guide plate is an output side, a second air cylinder is arranged on the first baffle, and the second air cylinder is used for pushing the push plate to move above the guide plate along the direction perpendicular to the length direction of the positioning plate;

the workbench is provided with a storage groove which is arranged below the output side of the guide plate;

the push plate pushes the waste above the guide plate to move towards the object placing groove along the direction perpendicular to the length direction of the positioning plate, so that the waste falls into the object placing groove.

The utility model has the advantages that: the guide plate is arranged to rotate relative to the workbench, so that cutting impurities can be concentrated to one side of the positioning plate in a manner of rotating the guide plate relative to the positioning plate after the cutting impurities are conveyed to the guide plate; through the push pedal promotes the cutting impurity to putting the thing groove orientation and removes, can conveniently concentrate output cutting impurity, avoids scattering.

Optionally, a guide post parallel to the length direction of the positioning plate is arranged on the first baffle plate;

the second cylinder is arranged on the outer side of the guide plate, a second baffle is arranged at the tail end of a telescopic rod of the second cylinder, one end of the guide post penetrates through the first baffle and is connected with the push plate, and the other end of the guide post is connected with the second baffle.

Optionally, a guide plate is arranged on the upper end face of the guide plate;

the guide plate is arranged on the output side of the guide plate;

the guide plates are symmetrically arranged, a guide groove is formed between the two guide plates, and the width of the guide groove is gradually reduced from the input side to the output side of the guide plate.

Optionally, a cover plate over the baffle;

the cover plate seals the upper part of the guide groove.

Optionally, a third baffle is arranged at one end, far away from the first baffle, of the cover plate;

one end of the third baffle is hinged to the cover plate;

the cover plate is provided with a motor, and the motor is used for driving the third baffle to rotate relative to the cover plate, so that one end, far away from the first baffle, of the guide groove is closed by the third baffle.

Drawings

Fig. 1 is a top view of a lens cutting magazine recycling apparatus according to an embodiment of the present invention;

fig. 2 is a front view of fig. 1.

Wherein: 10. the automatic storage device comprises a workbench, 11. a first cylinder, 13. a positioning plate, 14. a storage groove, 20. a guide plate, 21. a first baffle, 22. a push plate, 23. a guide post, 24. a second baffle, 25. a guide plate, 26. a guide groove, 27. a cover plate, 28. a third baffle and 29. a second cylinder.

Detailed Description

The invention will be described in further detail with reference to the following drawings and detailed description:

referring to fig. 1 and 2, fig. 1 is a top view of a lens cutting magazine recycling apparatus according to an embodiment of the present invention, and fig. 2 is a front view of fig. 1, the present invention discloses an apparatus, which includes a worktable 10 and a positioning plate 13 disposed on the worktable 10; the positioning plate 13 is provided with a guide plate 20 for placing waste materials, one side end face of the guide plate 20 is hinged to the positioning plate 13, the workbench 10 is provided with a first air cylinder 11, and the first air cylinder 11 is used for pushing the guide plate 20 to rotate relative to the positioning plate 13; a first baffle plate 21 is arranged at one end of the guide plate 20, a push plate 22 is arranged above one end, close to the first baffle plate 21, of the guide plate 20, one side, on which the push plate 22 is arranged, of the guide plate 20 is an input side, and the side, opposite to the push plate 22, of the guide plate is an output side, a second air cylinder 29 is arranged on the first baffle plate 21, and the second air cylinder 29 is used for pushing the push plate 22 to move above the guide plate 20 along the length direction perpendicular to the positioning plate 13; the worktable 10 is provided with an object placing groove 14, and the object placing groove 14 is arranged below the output side of the guide plate 20; the push plate 22 pushes the scraps above the guide plate 20 along a direction perpendicular to the length direction of the positioning plate 13 to move toward the storage slot 14, so that the scraps fall into the storage slot 14. The positioning plate 13 is a long strip-shaped plate-shaped structure, and the positioning plate 13 is perpendicular to the upper end surface of the workbench 10, so that the guide plate 20 is hinged on the side wall of the positioning plate 13 facing one side of the workbench 10. The length direction of the positioning plate 13 is the direction from the input side to the output side of the guide plate 20.

Cutting impurities formed after cutting a blank fall onto the guide plate 20 from the input side of the guide plate 20, at this time, the first air cylinder 11 is started, the first air cylinder 11 pushes the lower end face of the side, away from the positioning plate 13, of the guide plate 20, so that the guide plate 20 rotates relative to the positioning plate 13, and at this time, the cutting impurities on the guide plate 20 are concentrated towards the side of the positioning plate 13 under the action of gravity. When a large amount of cutting impurities are concentrated on one side of the positioning plate 13, the second cylinder 29 is started, so that the second cylinder 29 pushes the push plate 22, the push plate 22 moves towards the output side of the guide plate 20, and the push plate 22 pushes the cutting impurities on the guide plate 20 to move towards the output side of the guide plate 20 until the cutting impurities fall into the storage slot 14 from the guide plate 20.

During the process that the second air cylinder 29 pushes the push plate 22 to move, the first air cylinder 11 can be started to reduce the relative inclination angle of the guide plate 20, so as to avoid the phenomenon that a large amount of cutting impurities are concentrated on one side of the positioning plate 13, and the cutting impurities are scattered from one side of the positioning plate 13.

The article holding groove 14 may be fixedly connected to the worktable 10 or may be a detachable structure, and the article holding groove 14 is used for holding cutting impurities. When the push plate 22 pushes the cutting impurities from the input side to the output side of the guide plate 20, the storage compartment 14 is always kept in an open state.

The opening of the storage compartment 14 is preferably formed in a long shape, and the longitudinal direction thereof coincides with the longitudinal direction of the output side of the guide plate 20, so that the cut foreign materials falling from the guide plate 20 can be completely taken into the storage compartment 14.

Because this scheme will cut impurity and carry behind on the deflector 20, deflector 20 can rotate relatively for cut impurity can be in deflector 20 one side is concentrated, can make things convenient for this moment push pedal 22 is concentrated pushes away cut impurity, avoids the problem that cut impurity scatters.

Optionally, the first baffle 21 is provided with a guide post 23 parallel to the length direction of the positioning plate 13; the second cylinder 29 is arranged on the outer side of the guide plate 20, a second baffle 24 is arranged at the tail end of an expansion link of the second cylinder 29, one end of the guide column 23 penetrates through the first baffle 21 and is connected with the push plate 22, and the other end of the guide column 23 is connected with the second baffle 24. The first baffle plate 21 is provided with a through hole, the axial direction of the through hole is parallel to the length direction of the positioning plate 13, one end of the guide post 23 is fixedly connected to the second baffle plate 24, and when the second cylinder 29 drives the second baffle plate 24 to reciprocate, the second baffle plate 24 pushes the guide post 23 to reciprocate synchronously, so that the push plate 22 moves towards or away from the first baffle plate 21.

Because the second baffle 24 and the second cylinder 29 are arranged outside the first baffle 21, the second cylinder 29 can be prevented from occupying the space above the guide plate 20, and the working range of the push plate 22 can be enlarged.

When cutting impurities need to be input to the input side of the guide plate 20, one end of the push plate 22, facing the first baffle plate 21, is attached to the first baffle plate 21, so that the cutting impurities are prevented from being scattered between the push plate 22 and the first baffle plate 21.

Optionally, a guide plate 25 is arranged on the upper end surface of the guide plate 20; the guide plate 25 is arranged on the output side of the guide plate 20; the two guide plates 25 are symmetrically arranged, a guide groove 26 is formed between the two guide plates 25, and the width of the guide groove 26 is gradually reduced from the input side to the output side of the guide plate 20. Both of the guide plates 25 are perpendicular to the plane of the upper end surface of the guide plate 20, so that a guide groove 26 with a gradually reduced width is formed between the guide plates 25.

From the input side to the output side of the guide plate 20, the height of the guide groove 26 is gradually reduced, so that the cutting impurities can intensively move to the middle part above the object placing groove 14 after entering the guide groove 26, and the cutting impurities are prevented from scattering from the tail end of the guide groove 26.

After the cutting impurities are placed on the guide plate 20, the first cylinder is started to rotate the guide plate 20, the cutting impurities are concentrated to one side of the positioning plate 13, at the moment, the second cylinder 29 is started to enable the push plate 22 to push the cutting impurities to move to one side of the guide groove 26, the cutting impurities are concentrated in the guide groove 26 and move along a track with the width of the guide groove gradually reduced, the width of an output point is gradually reduced in the conveying process of the cutting impurities, and the concentrated fixed-point conveying to the article placing groove 14 is realized.

After the cutting impurities inputted to the guide plate 20 are collected to one side of the positioning plate 13, the first cylinder may be activated to make the guide plate 20 in a horizontal state, and at this time, the cutting impurities are collectively pushed to the guide groove 26, thereby preventing the cutting impurities from scattering.

The utility model discloses optionally, apron 27 above the guide plate 25; the cover plate 27 closes the guide groove 26 upward. The cover plate 27 is used for closing the upper end surface of the guide groove 26, so that a channel is formed inside the guide groove 26 to prevent cutting impurities from scattering from the upper side of the guide groove 26.

When the storage tank 14 needs to be replaced, in order to avoid the problem of scattering caused by continuously conveying cutting impurities, the utility model optionally provides a third baffle 28 at one end of the cover plate 27 away from the first baffle 21; one end of the third baffle 28 is hinged on the cover plate 27; the cover plate 27 is provided with a motor, and the motor is used for driving the third baffle 28 to rotate relative to the cover plate 27, so that the third baffle 28 seals one end of the guide groove 26 away from the first baffle 21. When the motor drives the third baffle 28 to rotate, after the third baffle 28 covers the guide groove 26, the third baffle 28 closes the guide groove 26, and at this time, the cut impurities cannot be continuously output, and after the storage groove 14 is replaced, the motor drives the cover plate 17 to rotate, so that the cover plate 17 is removed from the guide groove 26, and the guide groove 26 is unblocked. And then conveniently after the thing groove 14 is full, when in time changing the thing groove 14, avoid the cutting impurity to scatter.

The above only is the preferred embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structure changes made by the contents of the specification and the drawings under the inventive concept of the present invention, or the direct/indirect application in other related technical fields are included in the patent protection scope of the present invention.

Claims (5)

1. The utility model provides a lens cutting impurity recovery unit which characterized in that: comprises a workbench and a positioning plate arranged on the workbench;

the positioning plate is provided with a guide plate for placing waste materials, one side end face of the guide plate is hinged to the positioning plate, the workbench is provided with a first air cylinder, and the first air cylinder is used for pushing the guide plate to rotate relative to the positioning plate;

a first baffle is arranged at one end of the guide plate, a push plate is arranged above one end, close to the first baffle, of the guide plate, one side, provided with the push plate, of the guide plate is an input side, the side, opposite to the push plate, of the guide plate is an output side, a second air cylinder is arranged on the first baffle, and the second air cylinder is used for pushing the push plate to move above the guide plate along the direction perpendicular to the length direction of the positioning plate;

the workbench is provided with a storage groove which is arranged below the output side of the guide plate;

the push plate pushes the waste above the guide plate to move towards the object placing groove along the direction perpendicular to the length direction of the positioning plate, so that the waste falls into the object placing groove.

2. The lens cutting foreign material recycling apparatus of claim 1, wherein the first blocking plate is provided with a guide post parallel to a length direction of the positioning plate;

the second cylinder is arranged on the outer side of the guide plate, a second baffle is arranged at the tail end of a telescopic rod of the second cylinder, one end of the guide post penetrates through the first baffle and is connected with the push plate, and the other end of the guide post is connected with the second baffle.

3. The lens cutting foreign material recovery apparatus of claim 1, wherein a guide plate is provided on an upper end surface of the guide plate;

the guide plate is arranged on the output side of the guide plate;

the guide plates are symmetrically arranged, a guide groove is formed between the two guide plates, and the width of the guide groove is gradually reduced from the input side to the output side of the guide plate.

4. The lens cutting foreign material recovery apparatus of claim 3, wherein the baffle upper cover plate;

the cover plate seals the upper part of the guide groove.

5. The lens cutting impurity recycling device of claim 4, wherein a third baffle is arranged at one end of the cover plate away from the first baffle;

one end of the third baffle is hinged to the cover plate;

the cover plate is provided with a motor, and the motor is used for driving the third baffle to rotate relative to the cover plate, so that one end, far away from the first baffle, of the guide groove is closed by the third baffle.

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