CN219113107U - Wire feeding frame structure of wire cutting machine - Google Patents

Abstract

The utility model relates to a wire feeding frame structure of a wire cutting machine, which comprises a frame and is characterized in that: the frame is provided with a wire barrel and a bearing frame; the wire cylinder is movably arranged on the frame, and electrode wires are wound on the wire cylinder; the bearing frame is fixedly arranged on the frame, and a wire feeding frame device for feeding wire is movably arranged on the bearing frame; the upper wire frame device comprises an upper frame X shaft seat, an upper frame Y shaft seat and an upper frame Z shaft seat; drive components are respectively arranged between the upper frame X shaft seat and the upper frame Y shaft seat, between the upper frame Y shaft seat and the upper frame Z shaft seat, and between the upper frame Z shaft seat and the bearing frame, and left-right, up-down, front-back movable matching is respectively realized through the drive components; an upper traction wheel set, an upper wire guide wheel set, a connection sleeve device and a wire cutting and connection device are arranged on the upper frame X shaft seat. The structure can improve the threading and connection accuracy of the electrode wire, and simultaneously can lead the whole wire feeding frame device to realize wire feeding, disconnection and connection of the electrode wire so as to meet the continuous processing requirement of a wire cutting machine.

Description

Wire feeding frame structure of wire cutting machine

Technical Field

The utility model relates to the technical field of wire cutting machines, in particular to a wire feeding frame structure of a wire cutting machine.

Background

The Chinese patent document No. CN203679463U discloses a machine head of a wire cutting machine tool provided with a wire threading device on the day 7 and 2 in 2014, and the machine head comprises an upper dragging plate, a wire cylinder base, a wire cylinder motor, a stand column, an upper wire frame, a lower wire frame, a U/V shaft taper head, an upper wire frame front guide wheel seat, an upper wire frame rear guide wheel seat, a lower wire frame guide wheel seat and a water nozzle plate, and also comprises an upper rodless cylinder, an upper traction arm, a lower rodless cylinder and a lower traction plate, wherein the upper rodless cylinder comprises an upper cylinder tube, an upper piston, an upper sliding block and an upper cylinder fixing seat, and a through fixing hole of the lower threading traction plate is positioned below the lower wire guide wheel. The wire feeding frame with the structure can only realize movement in a single direction, and cannot accurately feed and connect the wire electrode, so that the wire electrode threading quality is affected, the wire electrode is easy to break during working, the wire electrode feeding frame cannot be cut off and connected, the production efficiency is low, and the processing cost is high.

Therefore, further improvements are needed.

Disclosure of Invention

The utility model aims to provide a wire feeding frame structure of a wire cutting machine, which overcomes the defects in the prior art.

According to the line frame structure of line cutting machine of this purpose design, including the frame, its characterized in that: a wire cylinder and a bearing frame are arranged on the frame; the wire cylinder is movably arranged on the frame, and electrode wires are wound on the wire cylinder; the bearing frame is fixedly arranged on the frame, and a wire feeding frame device for feeding the electrode wires is movably arranged on the bearing frame; the upper wire frame device comprises an upper frame X shaft seat, an upper frame Y shaft seat and an upper frame Z shaft seat.

Drive components are respectively arranged between the upper frame X shaft seat and the upper frame Y shaft seat, between the upper frame Y shaft seat and the upper frame Z shaft seat, and between the upper frame Z shaft seat and the bearing frame, and the left-right, up-down, front-back movable fit is respectively realized by the drive components.

The upper frame X axle seat is also provided with an upper traction wheel set, an upper wire guide wheel set, a connection sleeve device and a wire cutting and connection device.

An upper frame X-axis driving assembly is arranged between the upper frame X-axis seat and the upper frame Y-axis seat, and comprises an upper frame X-axis ball screw bearing and an upper frame X-axis servo driving motor.

The upper frame X-axis ball screw bearing is arranged between the upper frame X-axis seat and the upper frame Y-axis seat; the upper frame X-axis servo driving motor is fixedly arranged on the upper frame X-axis seat or the upper frame Y-axis seat, and the power output end of the upper frame X-axis servo driving motor is in driving connection with the upper frame X-axis ball screw bearing.

An upper frame X-axis guide rail and an upper frame X-axis sliding block are further arranged between the upper frame X-axis seat and the upper frame Y-axis seat, and are in guiding left-right movable fit with each other through the upper frame X-axis guide rail and the upper frame X-axis sliding block.

An upper frame Y-axis driving assembly is arranged between the upper frame Y-axis seat and the upper frame Z-axis seat, and comprises an upper frame Y-axis ball screw bearing and an upper frame Y-axis servo driving motor.

The upper frame Y-axis ball screw bearing is arranged between the upper frame Y-axis seat and the upper frame Z-axis seat; the upper frame Y-axis servo driving motor is fixedly arranged on the upper frame Y-axis seat or the upper frame Z-axis seat, and the power output end of the upper frame Y-axis servo driving motor is in driving connection with the upper frame Y-axis ball screw bearing.

An upper frame Y-axis guide rail and an upper frame Y-axis sliding block are further arranged between the upper frame Y-axis seat and the upper frame Z-axis seat, and are in guide type up-down movable fit through the upper frame Y-axis guide rail and the upper frame Y-axis sliding block.

An upper frame Z-axis driving assembly is arranged between the upper frame Z-axis seat and the bearing frame and comprises an upper frame Z-axis ball screw bearing and an upper frame Z-axis servo driving motor.

The upper frame Z-axis ball screw bearing is arranged between the upper frame Z-axis seat and the bearing frame; the upper frame Z-axis servo driving motor is fixedly arranged on the upper frame Z-axis seat or the bearing frame, and the power output end of the upper frame Z-axis servo driving motor is in driving connection with the upper frame Z-axis ball screw bearing.

An upper Z-axis guide rail and an upper Z-axis sliding block are further arranged between the upper Z-axis seat and the bearing frame, and are in guide type front-back movable fit through the upper Z-axis guide rail and the upper Z-axis sliding block.

And a conductive workbench is further arranged on the rack.

The upper frame X shaft seat is positioned above the conductive workbench and is movably matched with the conductive workbench in a left-right, up-down, front-back and front-back mode.

The upper wire wheel set is arranged at the outer end of the upper frame X shaft seat; the upper frame X shaft seat is provided with an upper clamp and an upper wire driver corresponding to the upper wire wheel set; an upper wire winding and unwinding buffer group is further arranged between the upper traction wheel group and the upper wire guide wheel group; and the upper traction wheel set, the upper wire guide wheel set or the upper wire winding and unwinding buffer set is also provided with an upper wire tension detector.

The plugging sleeve device comprises a plugging sleeve frame, a plugging sleeve register and a ejector.

The connection sleeve frame is movably arranged on the upper frame X shaft seat; the connection sleeve register is disassembled and assembled on the connection sleeve frame, and a plurality of connection sleeves are stored on the connection sleeve register; the ejector is movably arranged on the connection sleeve register and pushes the connection sleeves one by one to the connection port of the connection sleeve register when moving.

The wire cutting and plugging device comprises a wire cutting and plugging frame and a wire cutting and plugging device; the cutting and connecting wire frame is movably arranged on the upper frame X shaft seat; the wire cutting and plugging device is a pneumatic cutting pliers knife and is arranged on the wire cutting and plugging frame, moves along with the wire cutting and plugging frame and is close to the plugging port.

And a cutter position and a pliers position are arranged on the wire cutting and plugging device.

The wire cutting and plugging device cuts the electrode wire through a cutter position.

The wire cutting and plugging device clamps the plugging sleeve through a clamp knife position so as to realize the broken end connection of two electrode wires in the plugging sleeve.

According to the utility model, through improvement of the structure, the driving components are respectively arranged between the upper frame X shaft seat and the upper frame Y shaft seat, between the upper frame Y shaft seat and the upper frame Z shaft seat and between the upper frame Z shaft seat and the bearing frame, and the components can be respectively movably matched left and right, up and down and front and back by utilizing the driving actions of different driving components, so that the upper frame X shaft seat provided with the upper traction wheel group, the upper wire wheel group, the connection sleeve device and the wire cutting device can move left and right, up and down and front and back relative to the conductive workbench on the frame, electrode wires positioned on the upper frame device can be close to and aligned with the workpiece wire through holes of the conductive workbench as much as possible when the electrode wires penetrate wires, the wire penetrating accuracy of the electrode wires is improved, the wire penetrating quality of the electrode wires is ensured, and the problem that the electrode wires are broken during working is avoided; moreover, the sleeve device that plugs into can deposit a plurality of sleeve that plugs into to be convenient for wire cut machine can hold a plurality of sleeves that plug into in order to accomplish the continuous work of plugging into of wire electrode, improves production efficiency, simultaneously, cuts and plugs into the silk device and can realize cutting off of wire electrode, also can mutually support with the sleeve device that plugs into, realizes that two disconnected wire electrodes plug into, and then lets whole wire feeding frame device can realize that the wire electrode walks, breaks off, plugs into pieces, in order to satisfy wire cut machine's continuous processing demand.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model.

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

Fig. 1 is a schematic diagram of an assembly structure according to an embodiment of the utility model.

Fig. 2 and 3 are schematic diagrams illustrating an assembling structure of a receiving rack and a wire feeding rack according to an embodiment of the present utility model.

Fig. 4 and 5 are schematic diagrams illustrating an exploded structure of a receiving rack and a wire feeding rack according to an embodiment of the present utility model.

Fig. 6 and fig. 7 are schematic diagrams illustrating assembly structures of an upper frame X-axis seat, a connection sleeve device and a wire cutting and plugging device according to an embodiment of the present utility model.

Fig. 8 and 9 are schematic views of an exploded structure of a connector device according to an embodiment of the present utility model.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model. The present utility model may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the utility model, whereby the utility model is not limited to the specific embodiments disclosed below.

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

Referring to fig. 1-9, the upper wire frame structure of the wire cutting machine comprises a frame 1, wherein a wire barrel and a bearing frame 11 are arranged on the frame 1; the wire cylinder is movably arranged on the frame 1, and electrode wires are wound on the wire cylinder; the bearing frame 11 is fixedly arranged on the frame 1, and a wire feeding frame device A for electrode wire feeding is movably arranged on the bearing frame; the upper wire frame device A comprises an upper frame X shaft seat 50, an upper frame Y shaft seat 51 and an upper frame Z shaft seat 52.

Drive components are respectively arranged between the upper frame X shaft seat 50 and the upper frame Y shaft seat 51, between the upper frame Y shaft seat 51 and the upper frame Z shaft seat 52 and between the upper frame Z shaft seat 52 and the bearing frame 11, and left-right, up-down, front-back movable fit is respectively realized by the drive components.

The upper frame X axle seat 50 is also provided with an upper traction wheel set 53, an upper wire guide wheel set 54, a connection sleeve device C and a wire cutting and connection device D.

The structure is provided with driving components between the upper frame X shaft seat and the upper frame Y shaft seat, between the upper frame Y shaft seat and the upper frame Z shaft seat and between the upper frame Z shaft seat and the bearing frame respectively, and the driving functions of different driving components are utilized to respectively realize left-right, up-down and front-back movable fit between the components, so that finally, the upper frame X shaft seat 50 provided with the upper traction wheel group 53, the upper wire wheel group 54, the connection sleeve device C and the wire shearing and connection device D can move left-right, up-down and front-back relative to a conductive workbench on the frame 1, electrode wires positioned on the upper frame device A can approach as close as possible and align with workpiece wire penetrating holes of the conductive workbench when penetrating wires, thereby improving the wire penetrating and connection accuracy of the electrode wires, ensuring the wire penetrating quality of the electrode wires and avoiding the problem of breakage of the electrode wires during working; moreover, the connection sleeve device C can store a plurality of connection sleeves 34, so that the wire cutting machine can conveniently hold a plurality of connection sleeves 34 to complete continuous connection work of electrode wires, the production efficiency is improved, meanwhile, the wire cutting and connection device D can realize cutting of the electrode wires, and can also be matched with the connection sleeve device C to realize connection of two disconnected electrode wires, and then the whole wire feeding frame device A can realize wire feeding, disconnection and connection of the electrode wires so as to meet the continuous processing requirement of the wire cutting machine.

The driving assembly at least comprises a driver, and the driver is a servo driving motor or a pneumatic driver.

The preferred driver for this embodiment is a servo drive motor.

Specifically, an upper frame X-axis driving assembly is disposed between the upper frame X-axis seat 50 and the upper frame Y-axis seat 51, and the upper frame X-axis driving assembly includes an upper frame X-axis ball screw bearing 57 and an upper frame X-axis servo driving motor 58.

The upper frame X-axis ball screw bearing 57 is arranged between the upper frame X-axis seat 50 and the upper frame Y-axis seat 51; the upper frame X-axis servo driving motor 58 is fixedly arranged on the upper frame X-axis seat 50 or the upper frame Y-axis seat 51, and the power output end of the upper frame X-axis servo driving motor is in driving connection with the upper frame X-axis ball screw bearing 57.

An upper frame X-axis guide rail 59 and an upper frame X-axis sliding block 60 are also arranged between the upper frame X-axis seat 50 and the upper frame Y-axis seat 51, and are in guide type left-right movable fit with each other through the upper frame X-axis guide rail 59 and the upper frame X-axis sliding block 60.

The upper frame X-axis servo driving motor 58 of this embodiment is fixedly disposed on the upper frame Y-axis seat 51, the upper frame X-axis guide rail 59 is disposed on one side of the upper frame Y-axis seat 51, the upper traction wheel set 53, the upper wire guide wheel set 54, and the wire cutting and plugging device D are respectively disposed on one side of the upper frame X-axis seat 50, and the upper frame X-axis slider 60 and the plugging sleeve device C are disposed on the other side of the upper frame X-axis seat 50. The upper frame X shaft seat 50 can move left and right on the upper frame Y shaft seat 51 in a guiding manner through the cooperation of an upper frame X shaft ball screw bearing 57, an upper frame X shaft servo driving motor 58, an upper frame X shaft guide rail 59 and an upper frame X shaft sliding block 60.

An upper frame Y-axis driving assembly is arranged between the upper frame Y-axis seat 51 and the upper frame Z-axis seat 52, and comprises an upper frame Y-axis ball screw bearing 61 and an upper frame Y-axis servo driving motor 62.

The upper frame Y-axis ball screw bearing 61 is arranged between the upper frame Y-axis seat 51 and the upper frame Z-axis seat 52; the upper frame Y-axis servo driving motor 62 is fixedly arranged on the upper frame Y-axis seat 51 or the upper frame Z-axis seat 52, and the power output end of the upper frame Y-axis servo driving motor is in driving connection with the upper frame Y-axis ball screw bearing 61.

An upper frame Y-axis guide rail 63 and an upper frame Y-axis slide block 64 are also arranged between the upper frame Y-axis seat 51 and the upper frame Z-axis seat 52, and are in guide type up-down movable fit with each other through the upper frame Y-axis guide rail 63 and the upper frame Y-axis slide block 64.

The upper frame Y-axis servo driving motor 62 of this embodiment is fixedly disposed on the upper frame Z-axis seat 52, the upper frame Y-axis guide rail 63 is disposed on one side of the upper frame Z-axis seat 52, and the upper frame Y-axis slider 64 is disposed on the other side of the upper frame Y-axis seat 51. The upper frame Y shaft seat 51 can move up and down on the upper frame Z shaft seat 52 in a guiding manner through the cooperation of an upper frame Y shaft ball screw bearing 61, an upper frame Y shaft servo driving motor 62, an upper frame Y shaft guide rail 63 and an upper frame Y shaft sliding block 64.

An upper frame Z-axis driving assembly is arranged between the upper frame Z-axis seat 52 and the bearing frame 11, and comprises an upper frame Z-axis ball screw bearing 65 and an upper frame Z-axis servo driving motor 66.

The upper frame Z-axis ball screw bearing 65 is arranged between the upper frame Z-axis seat 52 and the bearing frame 11; the upper frame Z-axis servo driving motor 66 is fixedly arranged on the upper frame Z-axis seat 52 or the bearing frame 11, and the power output end of the upper frame Z-axis servo driving motor is in driving connection with the upper frame Z-axis ball screw bearing 65.

An upper frame Z-axis guide rail 67 and an upper frame Z-axis slide block 68 are also arranged between the upper frame Z-axis seat 52 and the bearing frame 11, and are in guiding front-back movable fit with each other through the upper frame Z-axis guide rail 67 and the upper frame Z-axis slide block 68.

The upper frame Z-axis servo drive motor 66 of this embodiment is fixedly disposed on the receiving frame 11, the upper frame Z-axis guide rail 67 is disposed on the top of the receiving frame 11, and the upper frame Z-axis slider 68 is disposed at the bottom of the upper frame Z-axis seat 52. The upper frame Z shaft seat 52 can move forward on the bearing frame 11 in a guiding manner through the cooperation of an upper frame Z shaft ball screw bearing 65, an upper frame Z shaft servo driving motor 66, an upper frame Z shaft guide rail 67 and an upper frame Z shaft sliding block 68.

The frame 1 is also provided with a conductive table (not shown in the figure, above which a workpiece 29 is arranged, the conductive table resembling a frame).

The upper frame X shaft seat 50 is positioned above the conductive workbench and is movably matched with the conductive workbench in a left-right, up-down, front-back and front-back mode.

That is, the upper frame X-axis seat 50 can move left and right, up and down, and back and forth, and the conductive work table can also be movably arranged on the frame 1 left and right, up and down, and back and forth.

The conductive workbench of the embodiment is fixedly arranged, a workpiece is placed on the conductive workbench, and a workpiece threading hole is drilled in the workpiece. The electrode wire can move towards the direction of the wire through hole of the workpiece through the cooperation of the upper traction wheel group 53 and the upper wire guide wheel group 54. Because the upper frame X shaft seat 50 can move left and right, up and down and front and back, the electrode wire can also move left and right, up and down and front and back relative to the workpiece wire threading hole, so that the electrode wire can be close to and aligned to the upper part of the workpiece wire threading hole as much as possible when threading, the problem that the electrode wire is bent and deformed when entering the workpiece wire threading hole is avoided, and the electrode wire can accurately enter the workpiece wire threading hole is ensured.

The upper wire wheel set 54 is arranged at the outer end of the upper frame X shaft seat 50; the upper frame X axle seat 50 is provided with an upper clamp and an upper wire driver corresponding to the upper wire wheel set 54; the upper clamp is configured to fix the wire electrode on the upper wire guide wheel set 54 and maintain tension of the wire electrode, and the upper wire driver is configured to drive the wire electrode on the upper wire guide wheel set 54 so that the wire electrode can move toward the wire threading hole of the workpiece.

An upper wire collecting and releasing buffer memory group 69 is arranged between the upper traction wheel group 53 and the upper wire guide wheel group 54; the upper wire winding and unwinding buffer group 69 can buffer part of the electrode wires on the upper frame X shaft seat 50 so as to facilitate the connection and use of the electrode wires.

An upper wire tension detector is also provided on the upper traction wheel set 53, the upper wire guide wheel set 54, or the upper wire winding and unwinding buffer set 69. The setting of the upper wire tension detector can carry out tension detection on the electrode wire, so that the electrode wire can ensure the tension when the electrode wire is walked on the upper traction wheel group 53, the upper wire wheel group 54 and the upper wire winding and unwinding buffer group 69, and the stability of the electrode wire when the electrode wire is walked on the upper wire frame device A is improved.

The docking cradle device C includes a docking cradle 31, a docking cradle register 32, and an ejector 33.

The connection sleeve frame 31 is movably arranged on the upper frame X shaft seat 50; the connection sleeve register 32 is disassembled and assembled on the connection sleeve frame 31, and a plurality of connection sleeves 34 are stored on the connection sleeve register; the ejector 33 is movably disposed on the socket register 32, and pushes the plurality of sockets 34 one by one onto the socket port 35 of the socket register 32 when moving.

The utilization of the connection sleeve register 32 can store a plurality of connection sleeves 34, so that the wire cutting machine can conveniently hold a plurality of connection sleeves 34 to complete continuous connection work, the production efficiency is improved, the ejector 33 on the connection sleeve register 32 can automatically push the plurality of connection sleeves 34 to the connection port 35 one by one when moving, two broken electrode wires can penetrate into two ends of the connection sleeve 34 respectively, and the wire cutting and connecting device D arranged on the wire feeding frame device A can complete two electrode wire broken end connection, so that the processing cost is low.

The wire cutting and plugging device D comprises a wire cutting and plugging frame 43 and a wire cutting and plugging device 44; the cutting and connecting wire frame 43 is movably arranged on the upper frame X shaft seat 50; the wire cutting and plugging device 44 is a pneumatic cutting and plugging pliers knife, is arranged on the wire cutting and plugging frame 43, moves along with the wire cutting and plugging frame 43 and is close to the plugging port 35.

The wire cutting and plugging device 44 is provided with a cutting tool position and a clamping tool position, wherein the cutting tool position is positioned at the rear side of the clamping tool position.

The wire cutting device 44 cuts the wire by the cutter position.

The wire cutting and plugging device 44 clamps the plugging sleeve 34 through a clamp knife position so as to realize the broken end connection of two electrode wires positioned in the plugging sleeve 34.

That is, the wire cutting and plugging device 44 can not only cut off the wire, but also be matched with the plugging sleeve device C to realize plugging of two disconnected wires.

The foregoing is a preferred embodiment of the utility model showing and describing the general principles, features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, which have been described in the foregoing embodiments and description merely illustrates the principles of the utility model, and that various changes and modifications may be effected therein without departing from the spirit and scope of the utility model as defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a wire frame structure of wire cutting machine, includes frame (1), its characterized in that: a wire cylinder and a bearing frame (11) are arranged on the frame (1); the wire cylinder is movably arranged on the frame (1) and is wound with electrode wires; the bearing frame (11) is fixedly arranged on the frame (1) and is movably provided with a wire feeding frame device (A) for the wire electrode to move; the upper wire frame device (A) comprises an upper frame X shaft seat (50), an upper frame Y shaft seat (51) and an upper frame Z shaft seat (52);

a driving assembly is respectively arranged between the upper frame X shaft seat (50) and the upper frame Y shaft seat (51), between the upper frame Y shaft seat (51) and the upper frame Z shaft seat (52), and between the upper frame Z shaft seat (52) and the bearing frame (11), and the left-right, up-down, front-back movable fit is respectively realized by the driving assembly;

the upper frame X axle seat (50) is also provided with an upper traction wheel set (53), an upper wire guide wheel set (54), a connection sleeve device (C) and a wire cutting and connection device (D).

2. The wire feeding frame structure of a wire cutting machine according to claim 1, wherein: an upper frame X-axis driving assembly is arranged between the upper frame X-axis seat (50) and the upper frame Y-axis seat (51), and comprises an upper frame X-axis ball screw bearing (57) and an upper frame X-axis servo driving motor (58);

the upper frame X-axis ball screw bearing (57) is arranged between the upper frame X-axis seat (50) and the upper frame Y-axis seat (51); the upper frame X-axis servo driving motor (58) is fixedly arranged on the upper frame X-axis seat (50) or the upper frame Y-axis seat (51), and the power output end of the upper frame X-axis servo driving motor is in driving connection with the upper frame X-axis ball screw bearing (57).

3. The wire feeding frame structure of a wire cutting machine according to claim 2, wherein: an upper frame X-axis guide rail (59) and an upper frame X-axis sliding block (60) are further arranged between the upper frame X-axis seat (50) and the upper frame Y-axis seat (51), and are in guiding left-right movable fit through the upper frame X-axis guide rail (59) and the upper frame X-axis sliding block (60).

4. The wire feeding frame structure of a wire cutting machine according to claim 1, wherein: an upper frame Y-axis driving assembly is arranged between the upper frame Y-axis seat (51) and the upper frame Z-axis seat (52), and comprises an upper frame Y-axis ball screw bearing (61) and an upper frame Y-axis servo driving motor (62);

the upper frame Y-axis ball screw bearing (61) is arranged between the upper frame Y-axis seat (51) and the upper frame Z-axis seat (52); the upper frame Y-axis servo driving motor (62) is fixedly arranged on the upper frame Y-axis seat (51) or the upper frame Z-axis seat (52), and the power output end of the upper frame Y-axis servo driving motor is in driving connection with the upper frame Y-axis ball screw bearing (61).

5. The wire feeding frame structure of a wire cutting machine according to claim 4, wherein: an upper frame Y-axis guide rail (63) and an upper frame Y-axis sliding block (64) are further arranged between the upper frame Y-axis seat (51) and the upper frame Z-axis seat (52), and are in guiding type up-down movable fit through the upper frame Y-axis guide rail (63) and the upper frame Y-axis sliding block (64).

6. The wire feeding frame structure of a wire cutting machine according to claim 1, wherein: an upper frame Z-axis driving assembly is arranged between the upper frame Z-axis seat (52) and the bearing frame (11), and comprises an upper frame Z-axis ball screw bearing (65) and an upper frame Z-axis servo driving motor (66);

the upper frame Z-axis ball screw bearing (65) is arranged between the upper frame Z-axis seat (52) and the bearing frame (11); the upper frame Z-axis servo driving motor (66) is fixedly arranged on the upper frame Z-axis seat (52) or the bearing frame (11), and the power output end of the upper frame Z-axis servo driving motor is in driving connection with the upper frame Z-axis ball screw bearing (65).

7. The wire feeding frame structure of a wire cutting machine according to claim 6, wherein: an upper frame Z-axis guide rail (67) and an upper frame Z-axis sliding block (68) are further arranged between the upper frame Z-axis seat (52) and the bearing frame (11), and are in guide type front-back movable fit through the upper frame Z-axis guide rail (67) and the upper frame Z-axis sliding block (68).

8. The wire feeding frame structure of a wire cutting machine according to claim 1, wherein: a conductive workbench is further arranged on the frame (1);

the upper frame X shaft seat (50) is positioned above the conductive workbench and is movably matched with the conductive workbench in a left-right, up-down, front-back and front-back mode.

9. The wire feeding frame structure of a wire cutting machine according to claim 1, wherein: the upper wire wheel set (54) is arranged at the outer end of the upper frame X shaft seat (50); the upper frame X shaft seat (50) is provided with an upper clamp and an upper wire driver corresponding to the upper wire wheel set (54); an upper wire collecting and releasing buffer memory group (69) is arranged between the upper traction wheel group (53) and the upper wire guide wheel group (54); and an upper wire tension detector is further arranged on the upper traction wheel set (53), the upper wire guide wheel set (54) or the upper wire winding and unwinding buffer memory set (69).

10. The wire feeding frame structure of a wire cutting machine according to claim 1, wherein: the connection sleeve device (C) comprises a connection sleeve frame (31), a connection sleeve register (32) and an ejector (33);

the connecting sleeve frame (31) is movably arranged on the upper frame X shaft seat (50); the connection sleeve register (32) is disassembled and assembled on the connection sleeve frame (31), and a plurality of connection sleeves (34) are stored on the connection sleeve register; the ejector (33) is movably arranged on the connection sleeve register (32) and pushes a plurality of connection sleeves (34) to connection ports (35) of the connection sleeve register (32) one by one when moving;

the wire cutting and connecting device (D) comprises a wire cutting and connecting frame (43) and a wire cutting and connecting device (44); the cutting and connecting wire frame (43) is movably arranged on the upper frame X shaft seat (50); the wire cutting and plugging device (44) is a pneumatic cutting pliers knife and is arranged on the wire cutting and plugging frame (43), and moves along with the wire cutting and plugging frame (43) and is close to the plugging port (35);

a cutter position and a pliers position are arranged on the wire cutting and plugging device (44);

the wire cutting and plugging device (44) cuts the electrode wire through a cutter position;

the wire cutting and plugging device (44) clamps the plugging sleeve (34) through a clamp knife position so as to realize the broken end connection of two electrode wires in the plugging sleeve (34).

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