CN114260511A

CN114260511A - Nano-reinforced high-strength high-conductivity copper alloy manufacturing equipment and manufacturing method thereof

Info

Publication number: CN114260511A
Application number: CN202111604702.7A
Authority: CN
Inventors: 赵美; 刘莹; 王建平; 曹宇飞; 陈菁菁
Original assignee: Yingkou Institute of Technology
Current assignee: Yingkou Institute of Technology
Priority date: 2021-12-24
Filing date: 2021-12-24
Publication date: 2022-04-01

Abstract

The invention relates to a nanometer reinforced high-strength high-conductivity copper alloy manufacturing device and a manufacturing method thereof, wherein the manufacturing method comprises the following steps: the first servo motor drives the connected rod body to rotate, and then the rod body drives the connected C-shaped frame to move, so that the clamped and fixed copper alloy block can rotate; the electric hydraulic push rod drives the cutting knife to vertically move downwards, so that the cutting knife can cut the rotating copper alloy block; produced cutting piece falls into to connecing the silo through leading to the groove in the manufacturing process, drives helical blade rotation through the motor for helical blade drives the piece and advances and fall into to the unloading pipeline in, collects the piece that falls down by the unloading pipeline through the collecting box at last. In the process of manufacturing the copper alloy, the processing scraps generated in the manufacturing and processing of the copper alloy can be effectively collected, so that the processing scraps cannot influence the manufacturing of the copper alloy, the labor intensity of cleaning a workbench by people is greatly reduced, and the copper alloy is convenient for people to use.

Description

Nano-reinforced high-strength high-conductivity copper alloy manufacturing equipment and manufacturing method thereof

Technical Field

The invention relates to the technical field of copper alloy manufacturing equipment, in particular to nano-reinforced high-strength high-conductivity copper alloy manufacturing equipment and a manufacturing method thereof.

Background

The copper alloy is an alloy formed by adding one or more other elements into pure copper serving as a matrix. Pure copper is purple red, also known as red copper. Commonly used copper alloys are classified into brass, bronze, cupronickel 3 categories. The non-alloy copper includes high-purity copper, tough pitch copper, deoxidized copper, oxygen-free copper, etc., and conventionally, the non-alloy copper is called red copper or pure copper, also called red copper, while other copper alloys belong to alloy copper. China and Russia classify copper alloys into brass, bronze and cupronickel, and then classify the copper alloys into smaller ones in the larger category. In the process of manufacturing the copper alloy, the copper alloy needs to be cut, so that the copper alloy can be manufactured into a required shape, however, at present, in the process of manufacturing and processing the copper alloy, the chips generated in the processing process are difficult to be effectively collected, so that the processing chips are scattered on a processing table board, the normal manufacturing of the copper alloy is influenced, the workload of manually cleaning the working table board is increased subsequently, the inconvenience is brought to the use of people, and in order to overcome the problems, a nano-reinforced high-strength high-conductivity copper alloy manufacturing device and a manufacturing method thereof are provided.

Disclosure of Invention

The invention provides a device and a method for manufacturing a nano-reinforced high-strength high-conductivity copper alloy, which solve the technical problems in the prior art.

The scheme for solving the technical problems is as follows: a nanometer reinforced high-strength high-conductivity copper alloy manufacturing device and a manufacturing method thereof comprise a workbench, wherein a vertical frame is connected onto the workbench, a control panel is connected onto the side wall of the vertical frame, a strip-shaped long groove is transversely formed in the top of the vertical frame in a penetrating mode, a through groove is transversely formed in the top of the workbench in a penetrating mode, a material receiving groove is connected to the position, corresponding to the through groove, of the bottom of the workbench, a rotating shaft is rotatably connected into the material receiving groove through a first bearing, a plurality of spiral blades are transversely and uniformly arranged on the periphery of the rotating shaft, a driving motor is connected onto the side wall of the material receiving groove, an output shaft of the driving motor penetrates through the material receiving groove and is connected with the end portion of the rotating shaft, a material discharging pipeline is communicated with one side of the bottom of the material receiving groove, a collecting box is arranged below the material discharging pipeline, a fastening device is arranged at the top of the workbench, and a cutting assembly is arranged above the workbench, the bottom of the workbench is fixedly connected with a supporting underframe.

On the basis of the technical scheme, the invention can be further improved as follows.

Further, fastener includes unable adjustment base and removal base, just unable adjustment base is bilateral symmetry with removal base and sets up, be equipped with motor-driven subassembly on the removal base, all be connected with the mount pad on unable adjustment base and the top surface of removal base, and one of them be connected with first servo motor, two on the outer wall of mount pad the looks remote site of mount pad all is connected with the bearing frame, every the inner chamber of bearing frame all pegs graft and is fixed with the body of rod, just the body of rod passes through the bearing frame and rotates with the mount pad that corresponds to be connected, two the looks remote site of the body of rod all is connected with C type frame, every the equal fixedly connected with first electronic jar in bottom of C type frame inner chamber, the one end that C type frame was kept away from to first electronic jar is connected with the clamp splice.

Further, the fixed base is fixedly connected to the top surface of the workbench, the movable base is movably attached to the top surface of the workbench, the output shaft of the first servo motor penetrates through the corresponding mounting seat, and the output shaft of the first servo motor is fixedly connected with the end portion of the rod body.

Further, the motor-driven component comprises two longitudinal plates, one of the longitudinal plates is connected with a second servo motor on the outer wall of each longitudinal plate, the longitudinal plates are arranged in a bilateral symmetry mode, a screw rod is arranged between the longitudinal plates, the two ends of the screw rod are connected between the longitudinal plates in a rotating mode through a second bearing, a screw rod sleeve matched with the screw rod in an operation mode is sleeved on the periphery of the screw rod in a movable mode, an output shaft of the second servo motor penetrates through the corresponding longitudinal plates and is connected with the end portions of the screw rod, the bottom ends of the longitudinal plates are fixedly connected to the top face of the workbench, and the screw rod sleeve is connected with the top face of the movable base.

Further, the cutting assembly comprises a cutting knife, a knife fixing seat is fixedly connected to the top of the cutting knife, an electric hydraulic push rod is connected to the top of the knife fixing seat, a bar-shaped sliding block which is matched with the bar-shaped long groove to operate is fixedly connected to the top of the electric hydraulic push rod, a second electric cylinder is connected to the bar-shaped sliding block, a cushion block is connected to the bottom of the second electric cylinder, the cushion block is fixedly connected to the top of the vertical frame, the top end of the bar-shaped sliding block penetrates through the bar-shaped long groove and is connected with the second electric cylinder, and the cutting knife is located above the through groove.

Furthermore, driving motor, first electronic jar, first servo motor, second servo motor, electronic hydraulic push rod all with control panel wireless connection.

Furthermore, the front end face and the rear end face of the workbench are both connected with slide rails, the front end face and the rear end face of the movable base are both fixedly connected with end plates, two opposite faces of the end plates are both connected with guide sliding blocks matched with the slide rails for operation, and each guide sliding block is respectively movably arranged in the corresponding inner cavity of the slide rail.

Furthermore, the clamping blocks are connected with anti-skid mats for skid resistance, and the anti-skid mats are made of elastic rubber materials.

Furthermore, the collecting box is arranged at the bottom of the inner cavity of the supporting chassis, and the bottom surface of the collecting box is attached to the bottom surface of the inner cavity of the supporting chassis.

The manufacturing method of the nano reinforced high-strength high-conductivity copper alloy manufacturing equipment comprises the following steps:

step one S1: placing a copper alloy block to be cut in front of the two C-shaped frames, controlling a second servo motor to be started through a control panel, driving a lead screw to rotate by the second servo motor, driving a moving base to move towards a fixed base by a lead screw sleeve when the lead screw rotates, and controlling the second servo motor to be closed by the control panel when the left end and the right end of the copper alloy block are respectively positioned in the inner cavities of the two C-shaped frames;

step two S2: the control panel controls the two first electric cylinders to extend, so that the two first electric cylinders drive the clamping blocks connected with the two first electric cylinders to clamp and fix the copper alloy block;

step three S3: then, the control panel controls the first servo motor to be started, the first servo motor drives the connected rod body to rotate, and the rod body drives the connected C-shaped frame to move, so that the clamped and fixed copper alloy block can rotate;

step four S4: the control panel controls the electric hydraulic push rod to extend, the electric hydraulic push rod drives the cutting knife to vertically move downwards, so that the cutting knife can cut the rotating copper alloy block, when the cutting knife cuts the copper alloy block, the electric hydraulic push rod drives the cutting knife to vertically move, so that the cutting depth of the copper alloy block is adjusted, and the second electric cylinder drives the cutting knife to transversely move, so that the cutting position of the cutting knife on the copper alloy block can be adjusted according to actual manufacturing requirements;

step five S5: produced cutting piece falls into to connecing the silo through leading to the groove in the manufacturing process, is opened by control panel control driving motor again, drives helical blade rotation by the pivot for helical blade drives the piece and advances and fall into to the unloading pipeline in, collects the piece that falls down by the unloading pipeline through the collecting box at last.

The invention has the beneficial effects that: the invention provides a nano-reinforced high-strength high-conductivity copper alloy manufacturing device and a manufacturing method thereof, and the device has the following advantages:

1. in the process of manufacturing the copper alloy, the processing scraps generated in the manufacturing and processing of the copper alloy can be effectively collected, so that the processing scraps cannot influence the manufacturing of the copper alloy, the labor intensity of cleaning a workbench by people is greatly reduced, and the copper alloy is convenient for people to use;

2. before the copper alloy is manufactured and processed, one end of the copper alloy to be manufactured and processed is inserted into the inner cavity of the left C-shaped frame, the other C-shaped frame is driven by the motor assembly to move towards the other end of the copper alloy, and the clamping block is driven by the first electric cylinder to clamp and fix the end part of the copper alloy, so that the copper alloy manufacturing and processing device is suitable for manufacturing and processing operations of copper alloys with different sizes and is wide in application range.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical solutions of the present invention more clearly understood and to implement them in accordance with the contents of the description, the following detailed description is given with reference to the preferred embodiments of the present invention and the accompanying drawings. The detailed description of the present invention is given in detail by the following examples and the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

fig. 1 is a schematic structural diagram of a device for manufacturing a nano-reinforced high-strength and high-conductivity copper alloy according to an embodiment of the present invention;

FIG. 2 is a schematic top view of the apparatus for manufacturing a nano-reinforced high-strength and high-conductivity copper alloy shown in FIG. 1;

fig. 3 is a schematic side view of the apparatus for manufacturing a nano-reinforced high-strength high-conductivity copper alloy shown in fig. 1.

In the drawings, the components represented by the respective reference numerals are listed below:

1. a work table; 2. a material receiving groove; 3. a drive motor; 4. a fixed base; 5. moving the base; 6. a mounting seat; 7. a bearing seat; 8. a C-shaped frame; 9. a first electric cylinder; 10. a clamping block; 11. a cutting blade; 12. a bar-shaped slider; 13. a second electric cylinder; 14. a first servo motor; 15. longitudinally arranging a plate; 16. a lead screw; 17. a screw sleeve; 18. an end plate; 19. a second servo motor; 20. a support chassis; 21. a slide rail; 22. erecting a frame; 23. a control panel; 24. a blanking pipeline; 25. a collection box; 26. a helical blade; 27. an electric hydraulic push rod; 28. and (6) guiding the sliding block.

Detailed Description

The principles and features of the present invention are described below in conjunction with the accompanying fig. 1-3, which are provided by way of example only to illustrate the present invention and not to limit the scope of the present invention. The invention is described in more detail in the following paragraphs by way of example with reference to the accompanying drawings. Advantages and features of the present invention will become apparent from the following description and from the claims. It is to be noted that the drawings are in a very simplified form and are not to precise scale, which is merely for the purpose of facilitating and distinctly claiming the embodiments of the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

As shown in figures 1-3, the invention provides a nano-reinforced high-strength high-conductivity copper alloy manufacturing device and a manufacturing method thereof, the nano-reinforced high-strength high-conductivity copper alloy manufacturing device comprises a workbench 1, a vertical frame 22 is connected on the workbench 1, a control panel 23 is connected on the side wall of the vertical frame 22, a strip-shaped long groove is transversely penetrated and arranged on the top of the vertical frame 22, a through groove is transversely penetrated and arranged on the top of the workbench 1, a material receiving groove 2 is connected on the bottom of the workbench 1 corresponding to the through groove, a rotating shaft is rotatably connected in the material receiving groove 2 through a first bearing, a plurality of spiral blades 26 are transversely and uniformly arranged on the periphery of the rotating shaft, a driving motor 3 is connected on the side wall of the material receiving groove 2, an output shaft of the driving motor 3 penetrates through the material receiving groove 2 and is connected with the end part of the rotating shaft, a discharging pipeline 24 is communicated with one side of the bottom of the material receiving groove 2, a collecting box 25 is arranged below the discharging pipeline 24, and a fastening device is arranged on the top of the workbench 1, a cutting assembly is arranged above the workbench 1, and the bottom of the workbench 1 is fixedly connected with a supporting underframe 20.

Preferably, fastener includes unable adjustment base 4 and removes base 5, and unable adjustment base 4 is bilateral symmetry with removing base 5 and sets up, be equipped with motor-driven subassembly on removing base 5, all be connected with mount pad 6 on unable adjustment base 4 and the top surface of removing base 5, and be connected with first servo motor 14 on the outer wall of one of them mount pad 6, the looks remote site of two mount pads 6 all is connected with bearing frame 7, the inner chamber of every bearing frame 7 is all pegged graft and is fixed with the body of rod, and the body of rod passes through bearing frame 7 and rotates with the mount pad 6 that corresponds to be connected, the looks remote site of two bodies of rod all is connected with C type frame 8, the equal first electronic jar 9 of fixedly connected with in bottom of the 8 inner chambers of every C type frame, the one end that first electronic jar 9 kept away from connected C type frame 8 is connected with clamp splice 10.

Preferably, the fixed base 4 is fixedly connected to the top surface of the workbench 1, the movable base 5 is movably attached to the top surface of the workbench 1, the output shaft of the first servo motor 14 penetrates through the corresponding mounting seat 6, and the output shaft of the first servo motor 14 is fixedly connected to the end of the rod body.

Preferably, the maneuvering assembly comprises two longitudinal plates 15, a second servo motor 19 is connected to the outer wall of one of the longitudinal plates 15, the two longitudinal plates 15 are arranged in a bilateral symmetry manner, a screw 16 is arranged between the two longitudinal plates 15, two ends of the screw 16 are rotatably connected between the two longitudinal plates 15 through a second bearing, a screw sleeve 17 matched with the screw 16 is movably sleeved on the periphery of the screw 16, an output shaft of the second servo motor 19 penetrates through the corresponding longitudinal plate 15 and is connected with the end portion of the screw 16, the bottom ends of the two longitudinal plates 15 are fixedly connected to the top surface of the workbench 1, and the screw sleeve 17 is connected with the top surface of the movable base 5.

Preferably, the cutting assembly comprises a cutting knife 11, a knife fixing seat is fixedly connected to the top of the cutting knife 11, an electric hydraulic push rod 27 is connected to the top of the knife fixing seat, a bar-shaped slide block 12 which is matched with the bar-shaped long groove for operation is fixedly connected to the top of the electric hydraulic push rod 27, a second electric cylinder 13 is connected to the bar-shaped slide block 12, a cushion block is connected to the bottom of the second electric cylinder 13, the cushion block is fixedly connected to the top of the vertical frame 22, the top end of the bar-shaped slide block 12 penetrates through the bar-shaped long groove and is connected with the second electric cylinder 13, and the cutting knife 11 is located above the through groove.

Preferably, the driving motor 3, the first electric cylinder 9, the first servo motor 14, the second servo motor 19 and the electric hydraulic push rod 27 are all wirelessly connected with the control panel 23.

Preferably, the front and rear end faces of the workbench 1 are both connected with slide rails 21, the front and rear end faces of the movable base 5 are both fixedly connected with end plates 18, the opposite faces of the two end plates 18 are both connected with guide sliding blocks 28 cooperating with the slide rails 21, and each guide sliding block 28 is movably arranged in the inner cavity of the corresponding slide rail 21.

Preferably, the clamping block 10 is connected with a non-slip mat for preventing slipping, and the non-slip mat is made of elastic rubber material.

Preferably, the collecting box 25 is arranged at the bottom of the inner cavity of the supporting chassis 20, and the bottom surface of the collecting box 25 is attached to the bottom surface of the inner cavity of the supporting chassis 20.

step one S1: placing a copper alloy block to be cut in front of the two C-shaped frames 8, controlling a second servo motor 19 to be started through a control panel 23, driving a lead screw 16 to rotate by the second servo motor 19, driving a moving base 5 to move towards a fixed base 4 by a lead screw sleeve 17 when the lead screw 16 rotates, and controlling the second servo motor 19 to be closed by the control panel 23 when the left end and the right end of the copper alloy block are respectively positioned in the inner cavities of the two C-shaped frames 8;

step two S2: the control panel 23 controls the two first electric cylinders 9 to extend, so that the two first electric cylinders 9 drive the clamping blocks 10 connected with each other to clamp and fix the copper alloy block;

step three S3: then, the control panel 23 controls the first servo motor 14 to be started, the first servo motor 14 drives the connected rod body to rotate, and the connected C-shaped frame 8 is driven by the rod body to move, so that the clamped and fixed copper alloy block can rotate;

step four S4: the control panel 23 controls the electric hydraulic push rod 27 to extend, the electric hydraulic push rod 27 drives the cutting knife 11 to vertically move downwards, so that the cutting knife 11 can cut a rotating copper alloy block, when the cutting knife 11 cuts the copper alloy block, the electric hydraulic push rod 27 drives the cutting knife 11 to vertically move, so that the cutting depth of the copper alloy block is adjusted, the second electric cylinder 13 drives the cutting knife 11 to transversely move, and the cutting position of the cutting knife 11 on the copper alloy block can be adjusted according to actual manufacturing requirements;

step five S5: produced cutting piece falls into to connecing the silo 2 in through leading to the groove in the manufacturing process, is opened by control panel 23 control driving motor 3 again, drives helical blade 26 by the pivot and rotates for helical blade 26 drives the piece and advances and fall into to unloading pipeline 24 in, collects the piece that falls down by unloading pipeline 24 through collecting box 25 at last.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. The electrical components presented therein are all electrically connected to the 220V mains. Those not described in detail in this specification are within the skill of the art.

The foregoing is merely a preferred embodiment of the invention and is not intended to limit the invention in any manner; the present invention may be readily implemented by those of ordinary skill in the art as illustrated in the accompanying drawings and described above; however, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the scope of the invention as defined by the appended claims; meanwhile, any changes, modifications, and evolutions of the equivalent changes of the above embodiments according to the actual techniques of the present invention are still within the protection scope of the technical solution of the present invention.

Claims

1. The utility model provides a copper alloy preparation equipment is led to nanometer intensive height, includes workstation (1), its characterized in that, be connected with grudging post (22) on workstation (1), be connected with control panel (23) on the lateral wall of grudging post (22), the top of grudging post (22) transversely runs through and has seted up the bar elongated slot, the top of workstation (1) transversely runs through and has seted up logical groove, the bottom of workstation (1) is connected with logical groove position correspondence and connects silo (2), connect and be connected with the pivot through first bearing rotation in the silo (2), the periphery of pivot transversely evenly is equipped with a plurality of helical blade (26), be connected with driving motor (3) on the lateral wall of silo (2), and the output shaft of driving motor (3) runs through and connects silo (2) and be connected with the tip of pivot, connect one side intercommunication of silo (2) bottom to have unloading pipeline (24), the blanking device is characterized in that a collecting box (25) is arranged below the blanking pipeline (24), a fastening device is arranged at the top of the workbench (1), a cutting assembly is arranged above the workbench (1), and a supporting bottom frame (20) is fixedly connected to the bottom of the workbench (1).

2. The nanometer reinforced high-strength high-conductivity copper alloy manufacturing equipment according to claim 1, wherein the fastening device comprises a fixed base (4) and a movable base (5), the fixed base (4) and the movable base (5) are arranged in bilateral symmetry, a motorized component is arranged on the movable base (5), the top surfaces of the fixed base (4) and the movable base (5) are connected with mounting seats (6), the outer wall of one of the mounting seats (6) is connected with a first servo motor (14), the opposite ends of the two mounting seats (6) are connected with bearing seats (7), the inner cavity of each bearing seat (7) is fixedly inserted with a rod body, the rod body is rotatably connected with the corresponding mounting seat (6) through the bearing seat (7), the opposite ends of the two rod bodies are connected with C-shaped frames (8), every the equal fixedly connected with first electronic jar (9) in bottom of C type frame (8) inner chamber, the one end that first electronic jar (9) kept away from connected C type frame (8) is connected with clamp splice (10).

3. The apparatus for manufacturing a copper alloy with nano-reinforcement, high strength and high conductivity according to claim 2, wherein the fixed base (4) is fixedly connected to the top surface of the workbench (1), the movable base (5) is movably attached to the top surface of the workbench (1), the output shaft of the first servo motor (14) penetrates through the corresponding mounting seat (6), and the output shaft of the first servo motor (14) is fixedly connected to the end of the rod body.

4. The apparatus for manufacturing nano-reinforced high-strength high-conductivity copper alloy according to claim 1, wherein the motorized assembly comprises two longitudinal plates (15), and the outer wall of one of the longitudinal plates (15) is connected with a second servo motor (19), the two longitudinal plates (15) are arranged in bilateral symmetry, a screw rod (16) is arranged between the two longitudinal plates (15), and the two ends of the screw rod (16) are rotationally connected between the two longitudinal plates (15) through a second bearing, the periphery of the screw rod (16) is movably sleeved with a screw rod sleeve (17) which is matched with the screw rod (16) for operation, the output shaft of the second servo motor (19) penetrates through the corresponding longitudinal plates (15) and is connected with the end part of the lead screw (16), the bottom ends of the two longitudinal plates (15) are fixedly connected to the top surface of the workbench (1), and the lead screw sleeve (17) is connected with the top surface of the movable base (5).

5. The nanometer reinforced high-strength high-conductivity copper alloy manufacturing equipment according to claim 4, characterized in that the cutting assembly comprises a cutting knife (11), a knife fixing seat is fixedly connected to the top of the cutting knife (11), an electric hydraulic push rod (27) is connected to the top of the knife fixing seat, a bar-shaped slide block (12) which is matched with the bar-shaped long groove for operation is fixedly connected to the top of the electric hydraulic push rod (27), a second electric cylinder (13) is connected to the bar-shaped slide block (12), a cushion block is connected to the bottom of the second electric cylinder (13), the cushion block is fixedly connected to the top of the stand (22), the top end of the bar-shaped slide block (12) penetrates through the bar-shaped long groove and is connected with the second electric cylinder (13), and the cutting knife (11) is located above the through groove.

6. The nanometer reinforced high-strength high-conductivity copper alloy manufacturing equipment according to claim 4, wherein the driving motor (3), the first electric cylinder (9), the first servo motor (14), the second servo motor (19) and the electric hydraulic push rod (27) are all in wireless connection with the control panel (23).

7. The nanometer strengthening high-strength high-conductivity copper alloy manufacturing equipment according to claim 4, wherein the front end face and the rear end face of the workbench (1) are both connected with slide rails (21), the front end face and the rear end face of the movable base (5) are both fixedly connected with end plates (18), the opposite faces of the two end plates (18) are both connected with guide sliding blocks (28) which are matched with the slide rails (21) for operation, and each guide sliding block (28) is respectively and movably arranged in the inner cavity of the corresponding slide rail (21).

8. The equipment for manufacturing the nano reinforced high-strength high-conductivity copper alloy as claimed in claim 4, wherein the clamping block (10) is connected with an anti-slip mat, and the anti-slip mat is made of elastic rubber.

9. The equipment for manufacturing the nano-reinforced high-strength high-conductivity copper alloy as claimed in claim 1, wherein the collection box (25) is located at the bottom of the inner cavity of the support chassis (20), and the bottom surface of the collection box (25) is attached to the bottom surface of the inner cavity of the support chassis (20).

10. The manufacturing method of the nano-reinforced high-strength high-conductivity copper alloy manufacturing equipment according to any one of claims 1 to 9, comprising the following steps of:

step one S1: placing a copper alloy block to be cut in front of two C-shaped frames (8), controlling a second servo motor (19) to be started through a control panel (23), driving a lead screw (16) to rotate by the second servo motor (19), driving a moving base (5) to move towards a fixed base (4) by a lead screw sleeve (17) when the lead screw (16) rotates, and controlling the second servo motor (19) to be closed by the control panel (23) when the left end and the right end of the copper alloy block are respectively positioned in the inner cavities of the two C-shaped frames (8);

step two S2: the control panel (23) controls the two first electric cylinders (9) to extend, so that the two first electric cylinders (9) drive the clamping blocks (10) connected with each other to clamp and fix the copper alloy block;

step three S3: then, the control panel (23) controls the first servo motor (14) to be started, the first servo motor (14) drives the connected rod body to rotate, and the connected C-shaped frame (8) is driven to move through the rod body, so that the clamped and fixed copper alloy block can rotate;

step four S4: the control panel (23) is used for controlling the electric hydraulic push rod (27) to extend, the electric hydraulic push rod (27) is used for driving the cutting knife (11) to vertically move downwards, so that the cutting knife (11) can cut a rotating copper alloy block, when the cutting knife (11) is used for cutting the copper alloy block, the electric hydraulic push rod (27) is used for driving the cutting knife (11) to move in the vertical direction, the cutting depth of the copper alloy block is adjusted, and the second electric cylinder (13) is used for driving the cutting knife (11) to transversely move, so that the cutting position of the cutting knife (11) on the copper alloy block can be adjusted according to actual manufacturing requirements;

step five S5: produced cutting piece falls into to connecing silo (2) in through leading to the groove in the manufacturing process, is opened by control panel (23) control driving motor (3) again, drives helical blade (26) rotation by the pivot for helical blade (26) drive piece advance and fall into to unloading pipeline (24) in, collect the piece that falls down by unloading pipeline (24) through collecting box (25) at last.