CN220426932U - Vertical milling machine for producing shock insulation support - Google Patents

Abstract

The utility model discloses a vertical milling machine for producing a shock insulation support, which belongs to the technical field of vertical milling machines and comprises a base; a lifting assembly is fixedly connected above the base; a longitudinal moving assembly is connected above the lifting assembly; a transverse moving assembly is connected above the longitudinal moving assembly; the clamp assembly is connected to the transverse moving assembly; and the upper parts of the transverse moving assembly and the clamp assembly are respectively connected with a foldable chip shielding device. Through the mode, the preliminary fixing of the workpiece in the longitudinal and transverse directions can be completed simultaneously by only one motor; the clamping and fixing can be further carried out on workpieces with different shapes and sizes; the scraps in the processing process of the workpiece can not fall into the slide rail, so that the trouble of subsequent cleaning can be saved.

Description

Vertical milling machine for producing shock insulation support

Technical Field

The utility model relates to the technical field of vertical milling machines, in particular to a vertical milling machine for producing a shock insulation support.

Background

A vertical milling machine is a device for cutting a workpiece with a milling cutter. During the machining process, a fixture is required to fix the workpiece. In the prior art, flat tongs are commonly used as clamps. The shock insulation support is formed by processing a cylindrical workpiece like a spherical crown lining plate, and the flat tongs are difficult to be attached to the outer part of the cylindrical workpiece. By the mode, in the machining process, the workpiece is easy to shake, so that the machining quality is affected.

Patent CN202222616359.4 discloses a circular work fixture for a vertical milling machine: through the cooperation setting of mounting panel, recess, push pedal and lug, can be quick change the push pedal to select the push pedal that accords with the outside radian of work piece, make the better and work piece laminating of push pedal, improve the stability when fixed.

The solution also has the problems of: when the workpiece is fixed, the clamping devices in the several directions need to be independently controlled, and the operation is troublesome; the device for preventing the scraps from falling into the sliding rail is absent, and the subsequent cleaning of the sliding rail is time-consuming and labor-consuming.

Based on the above, the utility model designs a vertical milling machine for producing the shock insulation support to solve the problems.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model provides a vertical milling machine for producing a shock insulation support.

In order to achieve the above purpose, the utility model is realized by the following technical scheme:

the vertical milling machine for producing the shock insulation support comprises a base;

a lifting assembly is fixedly connected above the base;

a longitudinal moving assembly is connected above the lifting assembly;

a transverse moving assembly is connected above the longitudinal moving assembly;

the clamp assembly is connected to the transverse moving assembly;

the upper parts of the transverse moving assembly and the clamp assembly are connected with a foldable chip shielding device;

the fixture assembly comprises a fixture table, a second chute, a coarse adjusting assembly and a fine adjusting assembly which are convenient to operate; the left end and the right end of the bottom of the clamp table are connected with the transverse moving assembly through bolts; the second chute is arranged on the clamp table; the second sliding groove is respectively provided with one in the front-back direction and the left-right direction; the coarse adjusting component is convenient to operate, is positioned in the second chute and is connected with the clamp table; the fine adjusting component is connected with the coarse adjusting component which is convenient to operate.

Further, the lifting assembly comprises a hydraulic cylinder, a guide rod and a lifting plate; the bottom of the hydraulic cylinder is fixedly connected with the base; the bottom of the guide rod is fixedly connected with the base; the guide rod passes through the lifting plate and is connected with the lifting plate in a sliding way; the bottom of the lifting plate is fixedly connected with the output end of the hydraulic cylinder; and a longitudinal moving assembly is fixedly connected above the lifting plate.

Furthermore, the bottom of the hydraulic cylinder is fixedly connected with the base.

Further, the longitudinal moving assembly comprises a sliding table, a first sliding groove, a first motor and a first screw rod; the sliding table is fixedly connected with the lifting plate; the sliding table is provided with a first sliding groove in the front-back direction; the front side of the sliding table is fixedly connected with a first motor; the first screw is positioned in the first chute; the front end of the first screw rod passes through the front side of the sliding table and is fixedly connected with the output end of the first motor; the rear end of the first screw is spliced with the rear side of the sliding table; the first screw rod penetrates through the bottom of the transverse moving assembly and is in threaded connection with the bottom of the transverse moving assembly.

Further, the transverse moving assembly comprises a sliding base, a sliding rail, a second screw, a second motor and two first sliding blocks; the sliding rail is fixedly connected with the top of the sliding base; the second screw is positioned in the sliding rail; the right end of the second screw rod passes through the right end of the sliding rail and is fixedly connected with the output end of the second motor; the left end of the second screw rod is spliced with the left end of the sliding rail; the second motor is fixedly connected with the right end of the sliding rail; the first sliding block on the left side is in sliding connection with the second screw rod; the first sliding block on the right side is in threaded connection with the second screw rod; and a clamp assembly is fixedly connected above the first sliding block.

Further, the sliding base is in threaded connection with the first screw.

Further, the coarse adjustment assembly convenient to operate comprises a third motor, a third screw, a fourth screw, a first bevel gear, a second bevel gear and four second sliding blocks; the third motor is fixedly connected with the right end of the clamp table; the right end of the third screw rod passes through the right end of the clamp table and is fixedly connected with the output end of the third motor; the left end of the third screw is spliced with the left end of the clamp table; the fourth screw is spliced with the front end and the rear end of the clamp table; the third screw rod and the fourth screw rod are two-way threaded rods; the position, close to the middle part, of the third screw rod is fixedly connected with a first bevel gear; the position, close to the middle part, of the fourth screw rod is fixedly connected with a second bevel gear; the first bevel gear is connected with the second bevel gear in a meshed manner; the second sliding blocks at the left end and the right end are in threaded connection with the third screw rod; the second sliding blocks at the front end and the rear end are in threaded connection with the fourth screw rod; the lower end of the second sliding block is positioned in the second sliding groove; the upper end of the second sliding block is higher than the top of the second sliding groove.

Further, the fine adjustment assembly comprises an electric push rod, a push plate and a clamping plate; one end of the electric push rod is fixedly connected with one side of the second sliding block, which is close to the center point of the clamp table; the other end of the electric push rod is fixedly connected with one side of the push plate; the other side of the push plate is clamped with one side of the clamping plate, which is far away from the workpiece.

Furthermore, the shape of one side of the clamping plate close to the workpiece is matched with the outer side of the workpiece.

Further, the foldable chip shielding device comprises a chip shielding device which is folded above the sliding rail and a chip shielding device which is folded above the sliding groove; one end of the folding chip shielding device above the sliding rail is fixedly connected with one side of the sliding rail, which is far away from the clamp assembly; the other end of the folding chip shielding device above the sliding rail is fixedly connected with the first sliding block; the chip shielding device is fixedly connected with the clamp table, the coarse adjusting component and the fine adjusting component which are convenient to operate.

Advantageous effects

The third motor drives the third screw rod to rotate; the third screw rod rotates to drive the first bevel gear to rotate; the first bevel gear rotates to drive the second bevel gear to rotate; the second bevel gear rotates to drive the fourth screw rod to rotate; the third screw and the fourth screw can simultaneously rotate to drive the left, right, front and back four second sliding blocks to simultaneously approach or separate from the center point of the clamp table; through the mode, when the workpiece is round or square, the preliminary fixing of the workpiece in the longitudinal and transverse directions can be finished simultaneously only by starting the third motor;

the electric push rod controls the push plate to be close to or far away from a workpiece; the clamping plate and the pushing plate are close to or far away from the workpiece together; when clamping workpieces with different shapes, different clamping plates can be switched; by the mode, workpieces with different shapes and sizes can be further clamped and fixed;

the first fixing plate is fixed along with the side, away from the clamp assembly, of the sliding rail; the second fixed plate moves along with the first sliding block; in the moving process, the folding dust cover tightly covers the sliding rail in the whole process; through the mode, scraps in the workpiece machining process can not fall into the sliding rail, and the trouble of subsequent cleaning can be omitted.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is evident that the drawings in the following description are only some embodiments of the present utility model and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a perspective view of a main body structure of a vertical milling machine for producing a shock insulation support;

FIG. 2 is a front view of a vertical milling machine structure for producing a shock insulation support according to the present utility model;

FIG. 3 is a left side view of a vertical milling machine structure for producing a shock insulation support of the present utility model;

FIG. 4 is a perspective view of a main body structure of a vertical milling machine for producing a shock insulation support according to the present utility model;

FIG. 5 is a cross-sectional view taken along the direction A-A of FIG. 3;

FIG. 6 is an enlarged view at B in FIG. 5;

fig. 7 is an enlarged view at C in fig. 5.

Reference numerals in the drawings represent respectively:

1. a base; 2. a lifting assembly; 21. a hydraulic cylinder; 22. a guide rod; 23. a lifting plate; 3. a longitudinally moving assembly; 31. a sliding table; 32. a first chute; 33. a first motor; 34. a first screw; 4. a lateral movement assembly; 41. a sliding base; 42. a slide rail; 43. a second screw; 44. a second motor; 45. a first slider; 5. a clamp assembly; 51. a clamp table; 52. a second chute; 53. the coarse adjustment assembly is convenient to operate; 531. a third motor; 532. a third screw; 533. a fourth screw; 534. a first bevel gear; 535. a second bevel gear; 536. a second slider; 54. a fine adjustment assembly; 541. an electric push rod; 542. a push plate; 543. a clamping plate; 6. a foldable chip shielding device; 61. a chip shielding device is folded above the slide rail; 611. a first fixing plate; 612. a second fixing plate; 613. folding the dust cover; 62. the chip shielding device is folded above the chute.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. 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.

The utility model is further described below with reference to examples.

Example 1

In some embodiments, referring to fig. 1-7 of the specification, a vertical milling machine for producing a shock insulation support comprises a base 1;

a lifting assembly 2 is fixedly connected above the base 1;

a longitudinal moving assembly 3 is connected above the lifting assembly 2;

a transverse moving assembly 4 is connected above the longitudinal moving assembly 3;

the clamp assembly 5 is connected to the transverse moving assembly 4;

the upper parts of the transverse moving assembly 4 and the clamp assembly 5 are respectively connected with a foldable chip shielding device 6;

the lifting assembly 2 comprises a hydraulic cylinder 21, a guide rod 22 and a lifting plate 23; the bottom of the hydraulic cylinder 21 is fixedly connected with the base 1; the bottom of the guide rod 22 is fixedly connected with the base 1; the guide rod 22 passes through the lifting plate 23 and is in sliding connection with the lifting plate 23; the bottom of the lifting plate 23 is fixedly connected with the output end of the hydraulic cylinder 21; a longitudinal moving component 3 is fixedly connected above the lifting plate 23;

the hydraulic cylinder 21 drives the lifting plate 23 to lift; the guide rod 22 guides and limits the lifting of the lifting plate 23; in the above manner, the lifting plate 23 can stably lift, so as to drive the longitudinal moving assembly 3 and the assembly above the longitudinal moving assembly to lift, and finally, the workpiece is lifted;

the longitudinal moving assembly 3 comprises a sliding table 31, a first sliding groove 32, a first motor 33 and a first screw 34; the sliding table 31 is fixedly connected with the lifting plate 23; the sliding table 31 is provided with a first sliding groove 32 in the front-rear direction; the front side of the sliding table 31 is fixedly connected with a first motor 33; the first screw 34 is positioned in the first chute 32; the front end of the first screw 34 passes through the front side of the sliding table 31 and is fixedly connected with the output end of the first motor 33; the rear end of the first screw 34 is spliced with the rear side of the sliding table 31; the first screw 34 penetrates the bottom of the transverse moving assembly 4 and is in threaded connection therewith;

the first motor 33 drives the first screw 34 to rotate; the first screw 34 rotates to drive the transverse moving assembly 4 to move back and forth along the first chute 32 on the sliding table 31; by the mode, the transverse moving component 4 and the component above the transverse moving component can be driven to move in the front-back direction, and finally the workpiece can be moved in the front-back direction;

the transverse moving assembly 4 comprises a sliding base 41, a sliding rail 42, a second screw 43, a second motor 44 and two first sliding blocks 45; the sliding base 41 is in threaded connection with the first screw 34; the sliding rail 42 is fixedly connected with the top of the sliding base 41; the second screw 43 is positioned in the slide rail 42; the right end of the second screw 43 passes through the right end of the sliding rail 42 and is fixedly connected with the output end of the second motor 44; the left end of the second screw 43 is spliced with the left end of the sliding rail 42; the second motor 44 is fixedly connected with the right end of the sliding rail 42; the first slider 45 on the left side is slidably connected with the second screw 43; the first sliding block 45 on the right side is in threaded connection with the second screw 43; a clamp assembly 5 is fixedly connected above the first sliding block 45;

the second motor 44 drives the second screw 43 to rotate; the second screw 43 rotates to drive the two first sliding blocks 45 to move left and right along the sliding rail 42; by the mode, the clamp assembly 5 can be driven to move left and right, and finally the workpiece can be moved left and right;

the clamp assembly 5 comprises a clamp table 51, a second chute 52, a coarse adjustment assembly 53 and a fine adjustment assembly 54 for facilitating operation; the left and right ends of the bottom of the clamp table 51 are fixedly connected with the first slide block 45 through bolts; the second chute 52 is formed on the jig table 51; the second slide grooves 52 are each provided with one in the front-rear and left-right directions; the coarse adjustment assembly 53 is positioned in the second chute 52 and is connected to the clamp stand 51; the fine adjustment assembly 54 is connected to the coarse adjustment assembly 53 for ease of operation;

the rough adjusting component 53 is convenient to operate to perform preliminary adjustment on the clamp along the second chute 52; the fine adjustment assembly 54 further adjusts the clamp; the rough adjusting component 53 is convenient to operate, and the fine adjusting component 54 can further adjust the clamp;

the easy-to-operate coarse adjustment assembly 53 includes a third motor 531, a third screw 532, a fourth screw 533, a first bevel gear 534, a second bevel gear 535, and four second sliders 536; the third motor 531 is fixedly connected with the right end of the clamp table 51; the right end of the third screw 532 passes through the right end of the fixture table 51 and is fixedly connected with the output end of the third motor 531; the left end of the third screw 532 is spliced with the left end of the clamp table 51; the fourth screw 533 is inserted into the front end and the rear end of the clamp table 51; third screw 532 and fourth screw 533 are bi-directional threaded rods; a first bevel gear 534 is fixedly connected to the third screw 532 near the middle; a second bevel gear 535 is fixedly connected to the fourth screw 533 near the middle; the first bevel gear 534 and the second bevel gear 535 are in meshed connection; the second slider 536 at the left and right ends is screw-coupled to the third screw 532; the second sliding blocks 536 at the front end and the rear end are in threaded connection with the fourth screw 533; the lower end of the second sliding block 536 is positioned in the second sliding groove 52; the upper end of the second sliding block 536 is higher than the top of the second sliding groove 52;

third motor 531 drives third screw 532 to rotate; third screw 532 rotates to drive first bevel gear 534 to rotate; the first bevel gear 534 rotates to drive the second bevel gear 535 to rotate; the second bevel gear 535 rotates to drive the fourth screw 533 to rotate; the third screw 532 and the fourth screw 533 rotate simultaneously to drive the left, right, front and rear second sliders 536 to approach or separate from the center point of the clamp table 51 simultaneously; through the mode, when the workpiece is round or square, the preliminary fixing of the workpiece in the longitudinal and transverse directions can be finished simultaneously only by starting the third motor 531;

the fine adjustment assembly 54 includes an electric push rod 541, a push plate 542, and a clamping plate 543; one end of the electric push rod 541 is fixedly connected with one side of the second slider 536, which is close to the center point of the clamp table 51; the other end of the electric push rod 541 is fixedly connected with one side of the push plate 542; the other side of the push plate 542 is clamped with one side of the clamping plate 543 away from the workpiece;

preferably, the shape of one side of the clamping plate 543 close to the workpiece is matched with the outer side of the workpiece;

the electric push rod 541 controls the push plate 542 to approach or depart from the workpiece; the clamping plate 543 and the push plate 542 together are moved toward or away from the workpiece; when clamping workpieces with different shapes, different clamping plates 543 can be switched; by the mode, workpieces with different shapes and sizes can be further clamped and fixed.

Example 2

In some embodiments, as shown in fig. 1-7, as a preferred embodiment of the present utility model, the foldable chip shielding device 6 includes a slide-rail-top folding chip shielding device 61 and a slide-rail-top folding chip shielding device 62; one end of the slide rail upper folding chip shielding device 61 is fixedly connected with one side of the slide rail 42 away from the clamp assembly 5; the other end of the slide rail upper folding chip shielding device 61 is fixedly connected with the first sliding block 45; the chip shielding device 62 is fixedly connected with the clamp table 51, the coarse adjusting component 53 and the fine adjusting component 54 which are convenient to operate;

one end of the slide rail upper folding chip shielding device 61 is fixed along with one side of the slide rail 42 away from the clamp assembly 5; the other end of the slide rail upper folding chip shielding device 61 moves along with the movement of the first sliding block 45; the sliding rail 42 can be tightly covered in the whole moving process of the sliding rail upper folding chip covering device 61; one end of the chute upper folding chip shielding device 62 is fixed along with the clamp table 51; the other end of the chute upper folding chip shielding device 62 moves along with the coarse adjusting component 53 and the fine adjusting component 54 which are convenient to operate; the second chute 52 can be tightly covered in the whole moving process of the chute upper folding and chip covering device 62; in this way, scraps in the processing process of the workpiece do not fall into the slide rail 42 and the second slide groove 52, so that the trouble of subsequent cleaning can be avoided.

Example 3

In some embodiments, as shown in fig. 1-7, as a preferred embodiment of the present utility model, the above-rail folding and dust-shielding device 61 includes a first fixing plate 611, a second fixing plate 612, and a folding and dust-shielding cover 613; the first fixing plate 611 is fixedly connected with one side of the sliding rail 42 away from the clamp assembly 5; the second fixing plate 612 is fixedly connected with the first sliding block 45; one end of the folding dust cover 613 is fixedly connected with the first fixed plate 611; the other end of the folding dust cover 613 is fixedly connected with the second fixing plate 612;

the first fixing plate 611 is fixed along with the side of the sliding rail 42 away from the clamp assembly 5; the second stationary plate 612 moves with the first slider 45; during the moving process, the folding dust cover 613 tightly covers the sliding rail 42 in the whole process; in this way, scraps in the processing process of the workpiece can not fall into the slide rail 42, so that the trouble of subsequent cleaning can be omitted.

The above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (10)

1. The vertical milling machine for producing the shock insulation support comprises a base (1); the method is characterized in that:

a lifting assembly (2) is fixedly connected above the base (1);

a longitudinal moving assembly (3) is connected above the lifting assembly (2);

a transverse moving assembly (4) is connected above the longitudinal moving assembly (3);

the transverse moving assembly (4) is connected with a clamp assembly (5);

the upper parts of the transverse moving assembly (4) and the clamp assembly (5) are respectively connected with a foldable chip shielding device (6);

the clamp assembly (5) comprises a clamp table (51), a second sliding groove (52), a rough adjusting assembly (53) and a fine adjusting assembly (54) which are convenient to operate; the left end and the right end of the bottom of the clamp table (51) are connected with the transverse moving assembly (4) through bolts; the second chute (52) is arranged on the clamp table (51); the second sliding groove (52) is respectively provided with one in the front-back direction and the left-right direction; the rough adjusting component (53) is positioned in the second chute (52) and is connected with the clamp table (51); the fine adjustment assembly (54) is connected to the coarse adjustment assembly (53) for ease of operation.

2. Vertical milling machine for the production of shock-insulating supports according to claim 1, characterized in that the lifting assembly (2) comprises a hydraulic cylinder (21), a guide rod (22) and a lifting plate (23); the bottom of the guide rod (22) is fixedly connected with the base (1); the guide rod (22) passes through the lifting plate (23) and is in sliding connection with the lifting plate (23); the bottom of the lifting plate (23) is fixedly connected with the output end of the hydraulic cylinder (21); the upper part of the lifting plate (23) is fixedly connected with a longitudinal moving assembly (3).

3. Vertical milling machine for the production of shock-insulating supports according to claim 2, characterized in that the bottom of the hydraulic cylinder (21) is fixedly connected with the base (1).

4. The vertical milling machine for producing the shock insulation support according to claim 2, wherein the longitudinal moving assembly (3) comprises a sliding table (31), a first sliding chute (32), a first motor (33) and a first screw (34); the sliding table (31) is fixedly connected with the lifting plate (23); the sliding table (31) is provided with a first sliding groove (32) in the front-back direction; the front side of the sliding table (31) is fixedly connected with a first motor (33); the first screw (34) is positioned in the first chute (32); the front end of the first screw rod (34) passes through the front side of the sliding table (31) and is fixedly connected with the output end of the first motor (33); the rear end of the first screw rod (34) is spliced with the rear side of the sliding table (31); a first screw (34) extends through the bottom of the transverse moving assembly (4) and is threaded therewith.

5. The vertical milling machine for producing the shock insulation support according to claim 4, wherein the lateral movement assembly (4) comprises a sliding base (41), a sliding rail (42), a second screw (43), a second motor (44) and two first sliders (45); the sliding rail (42) is fixedly connected with the top of the sliding base (41); the second screw rod (43) is positioned in the sliding rail (42); the right end of the second screw rod (43) passes through the right end of the sliding rail (42) and is fixedly connected with the output end of the second motor (44); the left end of the second screw rod (43) is spliced with the left end of the sliding rail (42); the second motor (44) is fixedly connected with the right end of the sliding rail (42); the first sliding block (45) on the left side is in sliding connection with the second screw rod (43); the first sliding block (45) on the right side is in threaded connection with the second screw rod (43); and a clamp assembly (5) is fixedly connected above the first sliding block (45).

6. Vertical milling machine for the production of shock-insulating supports according to claim 5, characterized in that said sliding base (41) is screwed with the first screw (34).

7. The vertical milling machine for producing the shock insulation support according to claim 6, wherein the easy-to-operate coarse adjustment assembly (53) comprises a third motor (531), a third screw (532), a fourth screw (533), a first bevel gear (534), a second bevel gear (535), and four second sliders (536); the third motor (531) is fixedly connected with the right end of the clamp table (51); the right end of the third screw rod (532) passes through the right end of the clamp table (51) and is fixedly connected with the output end of the third motor (531); the left end of the third screw rod (532) is spliced with the left end of the clamp table (51); the fourth screw rod (533) is inserted into the front end and the rear end of the clamp table (51); the third screw (532) and the fourth screw (533) are bidirectional threaded rods; a first bevel gear (534) is fixedly connected to the position, close to the middle part, of the third screw rod (532); a second bevel gear (535) is fixedly connected to the position, close to the middle part, of the fourth screw rod (533); the first bevel gear (534) is in meshed connection with the second bevel gear (535); the second sliding blocks (536) at the left end and the right end are in threaded connection with the third screw rod (532); the second sliding blocks (536) at the front end and the rear end are in threaded connection with the fourth screw rod (533); the lower end of the second sliding block (536) is positioned in the second sliding groove (52); the upper end of the second sliding block (536) is higher than the top of the second sliding groove (52).

8. The vertical milling machine for producing the shock insulation support according to claim 7, wherein the fine adjustment assembly (54) comprises an electric push rod (541), a push plate (542) and a clamping plate (543); one end of the electric push rod (541) is fixedly connected with one side of the second sliding block (536) close to the center point of the clamp table (51); the other end of the electric push rod (541) is fixedly connected with one side of the push plate (542); the other side of the push plate (542) is clamped with one side of the clamping plate (543) away from the workpiece.

9. The vertical milling machine for producing the shock-insulating support according to claim 8, wherein the clamping plate (543) is adapted to the outer side of the workpiece in shape close to the workpiece.

10. The vertical milling machine for producing the shock insulation support according to claim 5, wherein the foldable chip shielding device (6) comprises a slide rail upper folding chip shielding device (61) and a slide groove upper folding chip shielding device (62); one end of the slide rail upper folding chip shielding device (61) is fixedly connected with one side of the slide rail (42) away from the clamp assembly (5); the other end of the folding chip shielding device (61) above the sliding rail is fixedly connected with the first sliding block (45); the chip shielding device (62) is fixedly connected with the clamp table (51), the coarse adjusting component (53) and the fine adjusting component (54) which are convenient to operate.