CN220839842U - Clamping tool for processing split optical parts - Google Patents

Abstract

The utility model discloses a clamping tool for processing split optical parts, which comprises a base, wherein a T-shaped guide rail is fixedly connected to the upper surface of the base, two sliding blocks are connected to the surface of the guide rail in a sliding manner, upright posts are fixedly connected to the upper surfaces of the two sliding blocks, grooves are formed in the top ends of the upright posts, rotating arms are rotatably connected to the inside of the grooves, and cavities are formed in the top ends of the rotating arms. According to the utility model, the two sliding blocks, the upright posts, the rotating arms, the clamping structures and the adjusting structures of the guide rail are arranged, the two optical parts which are separated can be respectively clamped and fixed through the two clamping structures, the horizontal state and the vertical state of the clamped optical parts can be respectively adjusted through the rotating arms and the adjusting structures, the clamped parts can be conveniently processed in the vertical state, and the two optical parts can be spliced in a manner of moving the upright posts in the horizontal state, so that the processing effect can be checked in the processing process.

Description

Clamping tool for processing split optical parts

Technical Field

The utility model relates to the technical field of optical part machining, in particular to a clamping tool for split optical part machining.

Background

Optical parts, also known as optical elements, are the basic constituent units of optical systems. Most optical components function as imaging, such as lenses, prisms, mirrors, etc. There are also parts that play a special role in optical systems (e.g., splitting, image transmission, filtering, etc.), such as reticles, filters, gratings, etc., for optical fiber elements.

The split optical part is a part formed by splicing two or more optical parts, and at present, the part is clamped and fixed by using a separate clamping tool when in machining, so that the two parts can not be spliced while being machined in the machining process so as to test the machining effect, and the existing clamping tool has certain limitation. Secondly, the existing clamping tool is relatively dead, the workpiece after clamping cannot be rotated or adjusted in angle, and the degree of freedom is relatively low. Therefore, the utility model provides a clamping tool for processing a split optical part.

Disclosure of utility model

The utility model aims to solve the defects in the prior art and provides a clamping tool for processing a split optical part.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: the utility model provides a clamping tool for processing of components of a whole that can function independently optics part, includes the base, the guide rail of base upper surface fixedly connected with T type, guide rail surface sliding connection has two sliders, two equal fixedly connected with stand of slider upper surface, the stand top is seted up flutedly, the inside rotation of recess is connected with the rotor arm, the cavity has been seted up on the rotor arm top, the inside rotation of cavity is connected with the center pin, the one end fixedly connected with clamping structure that the center pin is located the cavity outside, the inside regulation structure that is provided with the drive center pin and rotates of cavity.

Further, two the slider lateral walls all run through and the screw thread rotates to be connected with and supports tight bolt.

Further, the clamping structure comprises a transverse plate fixed at the top of the central shaft, the interior of the transverse plate is hollow, a strip-shaped opening is formed in the top wall of the transverse plate, two symmetrical sliding rods are connected in a sliding mode in the strip-shaped opening, and clamping plates are fixedly connected to the tops of the two sliding rods.

Further, the inside rotation of diaphragm is connected with two-way lead screw, two-way lead screw runs through two slide bars and rotates with two slide bar screw thread and be connected, two-way lead screw one end passes diaphragm lateral wall fixedly connected with hexagonal nut.

Further, the adjusting structure comprises a rotating shaft rotationally connected with the side wall of the cavity and a second bevel gear fixed on the surface of the central shaft, one end of the rotating shaft, which is positioned in the cavity, is fixedly connected with a first bevel gear, the first bevel gear is meshed with the second bevel gear, and one end of the rotating shaft, which is positioned outside the cavity, is fixedly connected with a knob.

Further, the groove is internally provided with a first baffle plate which is positioned below the rotating arm, and the side wall of the groove is close to the first baffle plate and is penetrated through and connected with a first locking bolt in a threaded rotating manner.

Further, the inside one side fixedly connected with second baffle that just keeps away from first baffle of recess, recess lateral wall just is close to second baffle department and runs through and screw thread rotation is connected with the second locking bolt.

The utility model has the beneficial effects that:

When the clamping tool for machining the split optical parts is used, the two sliding blocks, the upright posts, the rotating arms, the clamping structures and the adjusting structures of the guide rail are arranged, the two split optical parts can be respectively clamped and fixed through the two clamping structures, the horizontal state and the vertical state of the clamped optical parts can be respectively adjusted through the rotating arms and the adjusting structures, the clamped parts can be conveniently machined in the vertical state, and the two optical parts can be spliced in a mode of moving the upright posts in the horizontal state, so that the machining effect can be inspected in the machining process. Secondly, the rotation of the part can be regulated through the regulating structure, so that the degree of freedom of part machining is higher.

Drawings

In order to more clearly illustrate the technical solutions of the present utility model, the drawings that are needed in the description of the specific embodiments will be briefly described below, it being obvious that the drawings in the following description are only some examples of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1: the overall schematic of the utility model;

Fig. 2: the clamping structure of the utility model is a cross-sectional view;

Fig. 3: an enlarged view of the utility model at a in fig. 1;

Fig. 4: the utility model relates to a column perspective view.

The reference numerals are as follows:

1. A base; 2. a guide rail; 3. a slide block; 4. a column; 5. a groove; 6. a rotating arm; 7. a cavity; 8. a central shaft; 9. a clamping structure; 91. a cross plate; 92. a strip-shaped opening; 93. a slide bar; 94. a clamping plate; 95. a two-way screw rod; 96. a hexagonal nut; 10. an adjustment structure; 101. a rotating shaft; 102. a first bevel gear; 103. a knob; 104. a second bevel gear; 11. a first baffle; 12. a second baffle; 13. a first locking bolt; 14. and a second locking bolt.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-4, relate to a clamping tool for processing split optical parts, including base 1, base 1 upper surface fixedly connected with T type guide rail 2, guide rail 2 surface sliding connection has two sliders 3, two sliders 3 equal fixedly connected with stand 4 on the upper surface, recess 5 has been seted up on stand 4 top, recess 5 inside rotates and is connected with rotor arm 6, cavity 7 has been seted up on rotor arm 6 top, cavity 7 inside rotates and is connected with center pin 8, the one end fixedly connected with clamping structure 9 that center pin 8 is located outside cavity 7, cavity 7 inside is provided with the rotatory adjusting structure 10 of drive center pin 8.

As shown in fig. 1, the side walls of the two sliding blocks 3 penetrate through, and the two sliding blocks are connected with a tightening bolt in a threaded rotation mode.

The slide 3 can move along the guide rail 2, so as to drive the upright 4 at the top and the clamping structure 9 to move, and the two optical parts clamped are conveniently butted, so that the machining effect is checked. After the slider 3 is moved, the slider 3 may be fixed by tightening the abutment bolt.

As shown in fig. 1-2, the clamping structure 9 includes a transverse plate 91 fixed on the top of the central shaft 8, and the interior of the transverse plate 91 is hollow, a strip-shaped opening 92 is provided on the top wall of the transverse plate 91, two symmetrical sliding rods 93 are slidably connected in the strip-shaped opening 92, and clamping plates 94 are fixedly connected to the top ends of the two sliding rods 93.

Thus, the two clamping plates 94 can follow the two sliding rods 93 to move along the strip-shaped opening 92, and the optical parts can be clamped and fixed when the two clamping plates 94 are close to each other. In this embodiment, the clamping plate 94 is L-shaped, and the bending portion of the L-shaped clamping plate 94 does not exceed 5mm, so that the area of the clamping part is ensured to be smaller, and the influence on processing is avoided.

The inside rotation of diaphragm 91 is connected with two-way lead screw 95, and two-way lead screw 95 runs through two slide bars 93 and is connected with two slide bar 93 screw thread rotations, and two-way lead screw 95 one end passes diaphragm 91 lateral wall fixedly connected with hexagonal nut 96.

After the bi-directional screw rod 95 is rotated by the hexagonal nut 96, the bi-directional screw rod 95 drives the two slide bars 93 to approach or separate from each other, so as to drive the two clamping plates 94 to move synchronously.

As shown in fig. 1 and 3, the adjusting structure 10 includes a rotating shaft 101 rotatably connected to a side wall of the cavity 7, and a second bevel gear 104 fixed to a surface of the central shaft 8, one end of the rotating shaft 101 located inside the cavity 7 is fixedly connected with a first bevel gear 102, the first bevel gear 102 is meshed with the second bevel gear 104, and one end of the rotating shaft 101 located outside the cavity 7 is fixedly connected with a knob 103.

In the processing process, the central shaft 8 can be driven to rotate under the transmission action of the first bevel gear 102 and the second bevel gear 104 by rotating the knob 103, and finally, the clamping structure 9 is rotated, so that the clamped part can be conveniently rotated and adjusted.

As shown in fig. 1 and 4, a first baffle 11 is fixedly connected inside the groove 5 and below the rotating arm 6, and a first locking bolt 13 penetrates through the side wall of the groove 5 near the first baffle 11 and is in threaded rotation connection with the side wall.

The first baffle 11 in the recess 5 of two stand 4 tops is located adjacent one side, when two centre gripping parts need to splice, can rotate the rotor arm 6 to first baffle 11, until rotor arm 6 and first baffle 11 laminating, rotor arm 6 is in the horizontality this moment, rotates first locking bolt 13 and supports tightly at rotor arm 6 surface afterwards, can realize the locking fixed to rotor arm 6, is favorable to later removal slider 3 to splice two parts.

The inside of recess 5 just keeps away from one side fixedly connected with second baffle 12 of first baffle 11, and recess 5 lateral wall just is close to second baffle 12 department and runs through and screw thread rotation is connected with second lock bolt 14.

When the optical part is processed, the rotating arm 6 can be rotated towards the second baffle 12, the rotating arm 6 is in a completely vertical state when the rotating arm 6 is attached to the second baffle 12, and the second locking bolt 14 is rotated to be abutted against the surface of the rotating arm 6, so that the fixing of the rotating arm 6 in the vertical state can be realized.

Working principle: the split rear optical parts are respectively placed between clamping plates 94 of two clamping structures 9, and the two parts are respectively clamped and fixed by the two clamping structures 9. During processing, the rotating arm 6 can be attached to the second baffle 12, and parts are guaranteed to face upwards, so that the processing is facilitated. When two parts need to be spliced, the rotating arm 6 can be rotated to be attached to the first baffle 11, so that the two parts are opposite, and the two workpieces can be spliced by moving the sliding block 3, so that the machining effect can be checked.

The preferred embodiments of the utility model disclosed above are intended only to assist in the explanation of the utility model. The preferred embodiments are not intended to be exhaustive or to limit the utility model to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, to thereby enable others skilled in the art to best understand and utilize the utility model. The utility model is limited only by the claims and the full scope and equivalents thereof.

Claims (7)

1. The utility model provides a clamping fixture is used in processing of components of a whole that can function independently optics part, includes base (1), its characterized in that: the novel multifunctional portable electric power tool is characterized in that the upper surface of the base (1) is fixedly connected with a T-shaped guide rail (2), the surface of the guide rail (2) is slidably connected with two sliding blocks (3), two sliding blocks (3) are fixedly connected with an upright post (4) on the upper surface, a groove (5) is formed in the top end of the upright post (4), a rotating arm (6) is connected to the inner portion of the groove (5) in a rotating mode, a cavity (7) is formed in the top end of the rotating arm (6), a central shaft (8) is connected to the inner portion of the cavity (7) in a rotating mode, one end of the central shaft (8) located outside the cavity (7) is fixedly connected with a clamping structure (9), and an adjusting structure (10) for driving the central shaft (8) to rotate is arranged inside the cavity (7).

2. The clamping tool for machining of split optical parts according to claim 1, wherein: the side walls of the two sliding blocks (3) penetrate through each other, and the two sliding blocks are connected with a tight supporting bolt in a threaded rotation mode.

3. The clamping tool for machining of split optical parts according to claim 1, wherein: the clamping structure (9) comprises a transverse plate (91) fixed at the top of a central shaft (8), the interior of the transverse plate (91) is hollow, a strip-shaped opening (92) is formed in the top wall of the transverse plate (91), two symmetrical sliding rods (93) are connected in the strip-shaped opening (92) in a sliding mode, and clamping plates (94) are fixedly connected to the tops of the two sliding rods (93).

4. The clamping tool for machining of split optical parts according to claim 3, wherein: the novel cross plate is characterized in that a bidirectional screw rod (95) is connected to the inside of the cross plate (91) in a rotating mode, the bidirectional screw rod (95) penetrates through the two sliding rods (93) and is in threaded rotation connection with the two sliding rods (93), and one end of the bidirectional screw rod (95) penetrates through the side wall of the cross plate (91) and is fixedly connected with a hexagonal nut (96).

5. The clamping tool for machining of split optical parts according to claim 1, wherein: the adjusting structure (10) comprises a rotating shaft (101) rotationally connected with the side wall of the cavity (7) and a second bevel gear (104) fixed on the surface of the central shaft (8), one end of the rotating shaft (101) positioned in the cavity (7) is fixedly connected with a first bevel gear (102), the first bevel gear (102) is meshed with the second bevel gear (104), and one end of the rotating shaft (101) positioned outside the cavity (7) is fixedly connected with a knob (103).

6. The clamping tool for machining of split optical parts according to claim 1, wherein: the novel anti-theft lock is characterized in that a first baffle (11) is fixedly connected inside the groove (5) and below the rotating arm (6), and a first locking bolt (13) penetrates through the side wall of the groove (5) close to the first baffle (11) and is in threaded rotation connection.

7. The clamping tool for machining split optical parts according to claim 6, wherein: the groove (5) is internally provided with a second baffle (12) and is fixedly connected with one side far away from the first baffle (11), and the side wall of the groove (5) is penetrated near the second baffle (12) and is in threaded rotation connection with a second locking bolt (14).