CN211681084U

CN211681084U - Eight-claw clamp mechanism for inner support or outer clamp of numerical control lathe

Info

Publication number: CN211681084U
Application number: CN202020180547.5U
Authority: CN
Inventors: 杨建平
Original assignee: Dongguan Baifangjianhang Machinery Parts Co ltd
Current assignee: Dongguan Baifangjianhang Machinery Parts Co ltd
Priority date: 2020-02-18
Filing date: 2020-02-18
Publication date: 2020-10-16
Anticipated expiration: 2030-02-18

Abstract

The utility model discloses an eight-jaw clamp mechanism for inner support or outer clamp of a numerical control lathe, which comprises an end seat connected with a main shaft of the numerical control lathe, wherein a connecting sleeve connected with a pull rod of the numerical control lathe is embedded in the end seat, the connecting sleeve is fixedly connected with an elastic end cover, the elastic end cover is fixedly connected with the end seat, the elastic end cover is provided with elastic clamping flaps with even number of flaps capable of radially retracting or radially expanding outwards, a replaceable eight-jaw chuck is movably assembled on the elastic end cover, the eight-jaw chuck is provided with elastic clamping support flaps matched with the number of the elastic clamping flaps, and when the eight-jaw chuck is assembled on the elastic end cover, the elastic clamping support flaps are fixedly connected with the matched elastic clamping flaps and can follow the elastic clamping flaps to radially retract or radially expand outwards; when a workpiece is clamped, a pull rod of the numerical control machine pulls or pushes the connecting sleeve to move axially and drive the elastic clamping flap to radially contract inwards or expand outwards, and the eight-jaw chuck is matched to clamp the workpiece outwards or clamp the workpiece inwards.

Description

Eight-claw clamp mechanism for inner support or outer clamp of numerical control lathe

Technical Field

The utility model belongs to the technical field of the equipment technique of machining and specifically relates to a numerical control lathe internal stay or outer clamp are with eight claw anchor clamps mechanism.

Background

The numerically controlled lathe is one of the widely used numerically controlled machines at present. The cutting tool is mainly used for cutting and processing inner and outer cylindrical surfaces of shaft parts or disc parts, inner and outer conical surfaces with any taper angles, complex rotary inner and outer curved surfaces, cylindrical threads, conical threads and the like, and can perform grooving, drilling, reaming, boring and the like.

In a numerical control lathe, an eight-claw clamp is used as a fixing clamp which plays an important role in fixing one of workpieces; if the sizes and specifications of parts for processing are different, the surfaces and positions of the parts through processing operation are different, so that the octagonal clamps required to be supported and clamped are different; for example: when the outer diameter of a workpiece needs to be clamped, an external clamp needs to be used, so that the inner diameter and the hole can be conveniently machined; when the inner hole needs to be clamped when a workpiece is machined, the inner support clamp needs to be used, so that the outer diameter of the workpiece is convenient to machine. However, the existing clamp for clamping the workpiece part of the numerically controlled lathe has the defects that an external clamping head or an internal supporting head is single, namely the clamp can only complete clamping and fixing with a single function. The outer clamp can only be used for the outer clamp, the inner support can only be used for the inner support, and the outer clamp can only be used for the outer clamp. The prior art is provided with few clamps which are provided with replaceable external clamping heads and internal supporting clamping heads; the replaceable chuck is arranged, the stress of the outer chuck and the stress of the inner support chuck are uneven, when a workpiece is clamped, all stress units interfere with each other, the deviation between the initial position of the clamped workpiece and the preset position is directly influenced, and then a defective product is generated when the numerical control lathe carries out processing operation.

In the related art, a better technical scheme is still lacked.

SUMMERY OF THE UTILITY MODEL

To the problem among the above-mentioned prior art, the utility model provides a numerical control lathe internal stay or outer clamp are with eight claw anchor clamps mechanism, this claw anchor clamps mechanism structure retrencies, changes the dress simple and convenient, anchor clamps are with low costs, the clamping work piece is reliable and stable.

In order to solve the technical problem, the utility model adopts the following technical scheme that the numerical control lathe inner support or outer clamp eight-jaw clamp mechanism comprises an end seat used for being connected with a main shaft of the numerical control lathe, wherein the end seat is internally embedded with a connecting sleeve used for being connected with a pull rod of the numerical control lathe, the connecting sleeve is fixedly connected with an elastic end cover, the elastic end cover is fixedly connected with the end seat, the elastic end cover is provided with elastic clamping flaps with even number of flaps capable of radially retracting or radially expanding outwards, the elastic end cover is movably provided with a replaceable eight-jaw chuck, the eight-jaw chuck is provided with elastic clamping supporting flaps matched with the number of the elastic clamping flaps, and when the eight-jaw chuck is assembled on the elastic end cover, the elastic clamping flaps are fixedly connected with the matched elastic clamping flaps and can follow the elastic clamping flaps to radially retract or radially expand outwards; when a workpiece is clamped, a pull rod of the numerical control machine pulls or pushes the connecting sleeve to move axially and drive the elastic clamping flap to radially contract inwards or expand outwards, and the eight-jaw chuck is matched to clamp the workpiece outwards or clamp the workpiece inwards.

As a further elaboration of the above technical solution:

in the technical scheme, the end seat is a flange seat, an interface connected with a spindle of the numerically controlled lathe is formed on the flange seat, and the flange seat is fixedly arranged at a flange opening of the spindle of the numerically controlled lathe through a fastener.

In the above technical solution, the fastening member is a fastening nut or a fastening bolt.

In the technical scheme, the end seat is provided with an embedded space, the connecting sleeve is embedded in the embedded space, and the connecting sleeve is further in threaded connection with a pull rod of the numerically controlled lathe, which axially penetrates through the end seat and extends into the embedded space.

In the above technical solution, the elastic clip flaps are arch-shaped elastic clip flaps, each arch-shaped elastic clip flap is provided with a protruding clip, the protruding clip flaps are folded to form a clip platform, the clip platform is provided with a matching clip groove, the inside of the eight-jaw collet is buckled with the clip groove or the outside of the eight-jaw collet is buckled with the clip platform, and the elastic clip support flaps and the elastic clip flaps are detachably connected through a first fastener to match with each other, so that the eight-jaw collet is assembled on the elastic end cover.

In the above technical scheme, each elastic end cover further comprises a side cover fixedly connected with one end of the elastic clamping flap and a push rod fixedly connected with the other end of the elastic clamping flap, the side cover is fixedly connected with the end base through a second fastener in a locking manner, the push rod is embedded in a shaft hole formed in the connecting sleeve and is in threaded connection with the connecting sleeve, and the elastic end cover is matched with the end base and the connecting sleeve.

In the above technical scheme, the system has two lamella axisymmetric settings on the elasticity end cover elasticity card lamella, perhaps, the system has four lamella circumference equipartitions to set up on the elasticity end cover elasticity card lamella, perhaps, the system has eight lamella circumference equipartitions to set up on the elasticity end cover elasticity card lamella.

In the above technical scheme, the elastic clip supporting petals are further elastically connected through an O-shaped connecting portion, and the O-shaped connecting portion is used for providing the elastic force for radially inward contraction or radially outward expansion of the elastic clip supporting petals.

In the technical scheme, the eight-claw chuck is an outer clamping chuck, the elastic clamp supporting petals are outer clamping petals, and the outer clamping chuck is also provided with tenon protrusions matched with the clamping grooves; the tenon is clamped into the clamping groove, the outer clamping clack is fixedly connected with the elastic clamping clack, and the outer clamping chuck can be assembled on the elastic end cover; the elastic end cover is driven to move by a connecting sleeve pulled by a pull rod of a numerical control machine tool and can drive the outer clamping clacks of the outer clamping chuck to clamp a workpiece when the elastic clamping clacks are radially retracted inwards.

In the technical scheme, the eight-claw chuck is an inner support chuck, the elastic clamp support petal is an inner support petal, and the inner support chuck is also provided with a mortise matched with the clamping table; the outer part of the mortise is buckled on the clamping table, the inner supporting petal is fixedly connected with the elastic clamping petal, and the inner supporting chuck can be assembled on the elastic end cover; the elastic end cover is driven to move by pushing the connecting sleeve by a pull rod of a numerical control machine tool and enables the elastic clamping flap to radially expand outwards, the inner supporting flap of the inner supporting chuck can be driven to be internally supported in an inner hole of a workpiece and is internally supported to clamp and fix the workpiece.

Compared with the prior art, the utility model has the advantages that the eight-claw clamp is provided with the replaceable external chuck or the replaceable internal support chuck, and can be replaced and externally clamp or internally support the fixed workpiece according to the requirement; the elastic clamping clacks are arranged on the elastic end covers and are linked with the elastic clamp supporting clacks of the outer clamp chuck or the inner supporting chuck through the elastic clamping clacks, so that the elastic clamp supporting clacks of the outer clamp chuck or the inner supporting chuck are driven to radially contract inwards or expand outwards to match with the outer clamp or the inner supporting to fix the workpiece; the elastic clamp supporting petals of the outer clamp chuck or the inner support chuck of the utility model are equally divided into even numbers and are circumferentially and evenly distributed and connected through the O-shaped connecting part, so that when the outer clamp chuck or the inner support chuck clamps parts, all the elastic clamp supporting petals are synchronously carried out, and the stress of all the elastic clamp supporting petals does not interfere; the utility model discloses an eight claw chucks simple manufacture, it is simple and convenient to change the outfit, and use cost is low, and the clamping is reliable and stable.

Drawings

Fig. 1 is a perspective view of the present invention;

fig. 2 is a perspective view of an embodiment of the present invention;

FIG. 3 is a cross-sectional view of FIG. 2;

fig. 4 is a perspective view of another embodiment of the present invention;

fig. 5 is a cross-sectional view of fig. 4.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The embodiments described by referring to the drawings are exemplary and intended to be used for explaining the present application and are not to be construed as limiting the present application. In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and thus should not be considered limiting. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise. In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral connections; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate. In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact of the first and second features, or may comprise contact of the first and second features not directly but through another feature in between. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly above and obliquely above the second feature, or simply meaning that the first feature is at a lesser level than the second feature.

FIG. 1 is a perspective view of the utility model of an eight-claw clamp mechanism for inner support or outer clamp of a numerically controlled lathe. The illustrated eight-claw clamp mechanism for the inner support or the outer clamp of the numerical control lathe can be replaced and used for clamping or supporting a workpiece externally or internally according to requirements by being provided with a replaceable external chuck or an internal support chuck; meanwhile, the elastic clamping flaps are arranged on the elastic end cover and are linked with the elastic clamp supporting flaps of the outer clamp chuck or the inner supporting chuck through the elastic clamping flaps, so that the elastic clamp supporting flaps of the outer clamp chuck or the inner supporting chuck are driven to contract or expand radially and outwards to match with the outer clamp or the inner support to fix the workpiece; furthermore, the elastic clamp supporting petals of the outer clamp chuck or the inner support chuck are equally divided into even numbers, are uniformly distributed in the circumferential direction and are connected through an O-shaped connecting part, so that when the outer clamp chuck or the inner support chuck clamps a part, all the elastic clamp supporting petals are synchronously carried out, and the stress of all the elastic clamp supporting petals is not interfered; finally, the eight-claw chuck of the eight-claw clamp mechanism for the inner support or the outer clamp of the numerical control lathe is simple to manufacture, easy and convenient to replace, low in use cost and stable and reliable in clamping.

Referring to fig. 1-5, the eight-claw clamping mechanism for inner support or outer clamp of a numerically controlled lathe according to the present invention includes an end seat 100 for connecting with a main shaft (not shown in the drawings) of the numerically controlled lathe, wherein a connecting sleeve 200 for connecting with a pull rod (not shown in the drawings) of the numerically controlled lathe is embedded in the end seat 100, the connecting sleeve 200 is fixedly connected with an elastic end cap 300, and the elastic end cap 300 is further fixedly connected with the end seat 100; in practice, the elastic end cap 300 is an elastic end cap with a "T" shaped structure, the "T" shaped upper portion of the elastic end cap 300 is fixedly connected with the end base 100, and the "T" shaped vertical portion thereof is connected with the connecting sleeve 200; the elastic end cover 300 is provided with elastic clamping flaps 31 with even number of flaps capable of radially contracting inwards or radially expanding outwards, the elastic end cover 300 is movably assembled with a replaceable eight-jaw chuck 400, the eight-jaw chuck 400 is provided with elastic clamp supporting flaps 41 with the number matched with that of the elastic clamping flaps 31, and when the eight-jaw chuck 400 is assembled on the elastic end cover 300, the elastic clamp supporting flaps 41 are fixedly connected with the matched elastic clamping flaps 31 and can radially contract inwards or radially expand outwards along with the elastic clamping flaps 31; when a workpiece is clamped, a pull rod of the numerical control machine pulls or pushes the connecting sleeve 200 to move axially and drive the elastic clamping flap 31 to drive the elastic clamping supporting flap 41 to contract radially inwards or expand radially outwards, and the eight-jaw chuck is matched to clamp the workpiece outwards or clamp the workpiece inwards. It should be noted that, the radial inward contraction and radial outward expansion means that when the connecting sleeve 200 is driven by the pull rod to move axially, the connecting sleeve 200 drives the elastic end cap 300 to move axially, but because the elastic end cap 300 is fixed to the end seat 100, the elastic end cap 300 cannot move integrally, and only part of the connection between the elastic end cap 300 and the connecting sleeve 300 and the connection between the elastic end cap 300 and the end seat 100 is stretched and moved elastically, that is, bent and stretched, and in the process of bending and stretching, the part of the elastic clamping flap 31 that is arched is radially inward contracted or outward expanded in a matching manner.

The eight-claw clamp mechanism can be used for external clamping or internal bracing clamping according to requirements, so that the eight-claw clamp mechanism is suitable for external diameter clamping or internal bracing clamping of workpieces with different sizes and specifications; the elastic clamping flaps 31 are arranged on the elastic end cover 300 and are linked with the elastic clamp supporting flaps 41 of the eight-jaw chuck 400 through the elastic clamping flaps 31, so that the elastic clamp supporting flaps 41 of the eight-jaw chuck 400 are radially inwards contracted or radially outwards expanded to match with an external clamp or an internal support to fix a workpiece.

It is understood that in one embodiment, referring to fig. 1-5, the end seat 100 is a flange seat, and the flange seat is provided with an interface 11 for connecting a spindle of a numerically controlled lathe, and in practice, the flange seat in this embodiment is fixed at a position of a flange port (not shown in the drawings) of the spindle of the numerically controlled lathe through a fastener 500 by snapping the interface 11 onto the spindle of the numerically controlled lathe. So set up, can install the eight claw anchor clamps mechanism in this embodiment on the numerical control main shaft of various different models, in order to satisfy the assembly demand, only need to change the size of flange seat interface can.

It is understood that in other embodiments, the fastener 500 of this embodiment may be adapted to meet the requirements of the end seat 100 and the spindle of the cnc lathe. For example, nuts, bolts, screws, pins and other cylindrical connectors may be selected. Meanwhile, the fastening member 500 may be a screw-type, self-tapping, snap-in, etc. assembling type connecting member.

It can be understood that, in one embodiment, referring to fig. 3 or 5, the end seat 100 is provided with an embedded space 12, the connecting sleeve 200 is embedded in the embedded space 12, the connecting sleeve 200 is further in threaded connection with a pull rod of a numerically controlled lathe axially penetrating the end seat 100 and extending into the embedded space 12, and in this embodiment, the pull rod is in threaded connection with the connecting sleeve 200.

With the arrangement, while the end seat 100 is used for assembling the eight-claw clamp mechanism on the main shaft of the numerically controlled lathe, the pull rod of the numerically controlled lathe can be connected with the connecting sleeve 200, and power transmission of the pull rod can be realized.

It is understood that, in one embodiment, in order to enable the elastic clamping flaps 31 to be radially retracted or radially expanded, the elastic clamping flaps are arched elastic clamping flaps, each arched elastic clamping flap is externally protruded with a clamping protrusion 32, a plurality of clamping protrusions 32 are folded to form a clamping platform 33, a clamping groove 34 is formed on the clamping platform 33 in a matching manner, the eight-jaw chuck 400 is internally buckled in the clamping groove 34 (corresponding to an external chuck) or externally buckled in the clamping platform 33 (corresponding to an internal supporting chuck), and the elastic clamping flaps 41 and the elastic clamping flaps 31 are detachably connected through a first fastener 600 in a matching manner, so that the eight-jaw chuck 400 is assembled on the elastic end cap 300.

Referring to fig. 2-3, in an alternative embodiment of this embodiment, in order to clamp the outer diameter of the workpiece, the eight-jaw collet 400 is an outer collet 400-1, the resilient clip supporting petals 41 are outer clamping petals 41-1, and the outer collet 400-1 is further formed with the tenon protrusions 42 adapted to the clamping grooves 34; the tenon 42 is clamped in the clamping groove 34 and fixedly connected with the outer clamping flap 41-1 and the elastic clamping flap 31, so that the outer clamping head 400-1 can be assembled on the elastic end cover 300; the elastic end cover 300 is driven by a connecting sleeve 200 drawn by a pull rod of a numerical control machine tool to move and can drive the outer clamping flap 41-1 of the outer clamping head 400-1 to clamp a workpiece when the elastic clamping flap 31 is radially retracted inwards.

Referring to fig. 3-5, in another alternative embodiment of this embodiment, referring to fig. 2-3, in order to clamp the inner hole of the workpiece by the inner support, the eight-jaw chuck 400 is an inner support chuck 400-2, the resilient clamp support flap 41 is an inner support flap 41-2, and the inner support chuck 400-1 is further provided with a mortise 43 adapted to the clamping platform 32; the mortise 43 is externally buckled on the clamping platform 32, the inner support petal 41-2 is fixedly connected with the elastic clamping petal 31, and the inner support chuck 400-2 can be assembled on the elastic end cover 300; the elastic end cover 300 is driven by a pull rod of a numerical control machine to push the connecting sleeve 200 to move and enable the elastic clamping flap 31 to radially expand outwards, so that the inner supporting flap 41-2 of the inner supporting chuck 400-2 can be driven to be internally supported in an inner hole of a workpiece and can be internally supported and clamped to fix the workpiece.

It is understood that in other embodiments, the first fastening member 600 of the present embodiment is suitable for the first fastening member 600 satisfying the requirement of connecting the elastic clip supporting flap 41 and the elastic clip flap 31. For example, nuts, bolts, screws, pins and other cylindrical connectors may be selected. Meanwhile, the first fastening member 600 may be a screw-type, self-tapping, snap-in, or other assembly type connecting member.

It can be understood that, in one embodiment, in order to meet the requirement that the elastic end cap 300 is connected with the connecting sleeve 200 and the end cap 100 and simultaneously ensure that the elastic clamping flap 31 can radially contract inwards or expand outwards, each of the elastic end caps 300 further includes a side cap 35 fixedly connected with one end of the elastic clamping flap 31 and a push rod 36 fixedly connected with the other end of the elastic clamping flap 31, the side cap 35 is fixedly locked with the end base 100 through a second fastening member 700, and the push rod 36 is embedded in the shaft hole 21 formed in the connecting sleeve 200 and is screwed with the connecting sleeve 200 to match the elastic end cap 300 to be connected with the end base 100 and the connecting sleeve 200.

It is understood that in other embodiments, the second fastener 700 of this embodiment is suitable for the second fastener 700 required for connecting the edge cover 35 to the end seat 100. For example, nuts, bolts, screws, pins and other cylindrical connectors may be selected. Meanwhile, the second fastening member 700 may be a screw-type, self-tapping, snap-in, or other assembly type connection member.

It can be understood that, in one embodiment, the elastic end cap 300 is provided with the two elastic clamping flaps 31 which are axisymmetrically arranged, or the elastic end cap 300 is provided with the four elastic clamping flaps 31 which are circumferentially and uniformly arranged, or the elastic end cap 300 is provided with the eight elastic clamping flaps 31 which are circumferentially and uniformly arranged.

It will be appreciated that in one embodiment, in order to allow the eight-jaw collet 400 to clamp or clamp a part while each spring clip support flap 41 is in synchronization, the spring clip support flaps 41 are subjected to force without interference, the spring clip support flaps 41 are also elastically connected by an O-shaped connection 44, and the O-shaped connection 44 is used for providing elastic force for radially contracting or expanding the spring clip support flaps 41.

The above is not intended to limit the technical scope of the present invention, and any modifications, equivalent changes and modifications made to the above embodiments according to the technical spirit of the present invention are all within the scope of the technical solution of the present invention.

Claims

1. The eight-claw fixture mechanism for the inner support or the outer clamp of the numerical control lathe is characterized by comprising an end seat used for being connected with a main shaft of the numerical control lathe, wherein a connecting sleeve used for being connected with a pull rod of the numerical control lathe is embedded in the end seat, the connecting sleeve is fixedly connected with an elastic end cover, the elastic end cover is also fixedly connected with the end seat, an elastic clamping flap with even number of flaps capable of radially retracting inwards or radially expanding outwards is manufactured on the elastic end cover, a replaceable eight-claw chuck is movably assembled on the elastic end cover, the eight-claw chuck is provided with elastic clamping support flaps matched with the number of the elastic clamping flaps, and when the eight-claw chuck is assembled on the elastic end cover, the elastic clamping support flaps are fixedly connected with the matched elastic clamping flaps and can radially retract inwards or radially expand outwards along with the elastic clamping flaps; when a workpiece is clamped, a pull rod of the numerical control machine pulls or pushes the connecting sleeve to move axially and drive the elastic clamping flap to radially contract inwards or expand outwards, and the eight-jaw chuck is matched to clamp the workpiece outwards or clamp the workpiece inwards.

2. The eight-claw clamp mechanism for the inner support or the outer clamp of the numerical control lathe according to claim 1, wherein the end seat is a flange seat, an interface for connecting a main shaft of the numerical control lathe is formed on the flange seat, and the flange seat is fixedly arranged at a flange opening of the main shaft of the numerical control lathe through a fastener.

3. The numerical control lathe internal stay or external clamp eight-claw clamp mechanism of claim 2, wherein the fastener is a fastening nut or a fastening bolt.

4. The eight-claw clamp mechanism for the inner support or the outer clamp of the numerically controlled lathe according to claim 1, wherein the end seat is provided with an embedded space, the connecting sleeve is embedded in the embedded space, and the connecting sleeve is further in threaded connection with a pull rod of the numerically controlled lathe which axially penetrates through the end seat and extends into the embedded space.

5. The eight-jaw clamping mechanism for the inner support or the outer clamp of the numerical control lathe according to any one of claims 1 to 4, wherein the elastic clamping flaps are arc-shaped elastic clamping flaps, each arc-shaped elastic clamping flap is provided with a clamping protrusion in a protruding manner, a plurality of clamping protrusions are folded to form a clamping platform, the clamping platforms are matched to form clamping grooves, the eight-jaw chuck is internally buckled on the clamping grooves or externally buckled on the clamping platforms, and the elastic clamping flaps are matched to be detachably connected through first fasteners so that the eight-jaw chuck is assembled on the elastic end cover in a matching manner.

6. The numerical control lathe inner support or outer clamp eight-claw clamp mechanism as defined in claim 5, wherein each elastic end cap further comprises a side cap fixedly connected with one end of the elastic clamping flap and a push rod fixedly connected with the other end of the elastic clamping flap, the side cap is fixedly locked with the end seat through a second fastener, the push rod is embedded in a shaft hole formed in the connecting sleeve and is in threaded connection with the connecting sleeve, and the elastic end cap is matched and connected with the end seat and the connecting sleeve.

7. The eight-jaw clamping mechanism for the inner support or the outer clamp of the numerical control lathe according to claim 6, wherein the elastic end cover is provided with two elastic clamping flaps which are axially symmetrically arranged, or four elastic clamping flaps which are circumferentially and uniformly distributed are arranged on the elastic end cover, or eight elastic clamping flaps which are circumferentially and uniformly distributed are arranged on the elastic end cover.

8. The eight-jaw clamping mechanism for the inner support or the outer clamp of the numerical control lathe according to claim 6, wherein the elastic clamp supporting petals are also elastically connected through an O-shaped connecting part, and the O-shaped connecting part is used for providing elastic force for radially contracting or radially expanding the elastic clamp supporting petals.

9. The numerical control lathe internal support or external clamp eight-jaw clamp mechanism according to claim 8, wherein the eight-jaw chuck is an external clamp chuck, the elastic clamp support petal is an external clamp petal, and the external clamp chuck is further provided with a tenon protrusion matched with the clamping groove; the tenon is clamped into the clamping groove, the outer clamping clack is fixedly connected with the elastic clamping clack, and the outer clamping chuck can be assembled on the elastic end cover; the elastic end cover is driven to move by a connecting sleeve pulled by a pull rod of a numerical control machine tool and can drive the outer clamping clacks of the outer clamping chuck to clamp a workpiece when the elastic clamping clacks are radially retracted inwards.

10. The numerical control lathe inner support or outer clamp eight-jaw clamp mechanism as claimed in claim 8, wherein the eight-jaw chuck is an inner support chuck, the elastic clamp support petal is an inner support petal, and the inner support chuck is further provided with a mortise adapted to the clamping table; the outer part of the mortise is buckled on the clamping table, the inner supporting petal is fixedly connected with the elastic clamping petal, and the inner supporting chuck can be assembled on the elastic end cover; the elastic end cover is driven to move by pushing the connecting sleeve by a pull rod of a numerical control machine tool and enables the elastic clamping flap to radially expand outwards, the inner supporting flap of the inner supporting chuck can be driven to be internally supported in an inner hole of a workpiece and is internally supported to clamp and fix the workpiece.