CN113103096B

CN113103096B - Production equipment and processing technology of novel nanoscale silicon carbide copper-based alloy material

Info

Publication number: CN113103096B
Application number: CN202110368126.4A
Authority: CN
Inventors: 贺雨慧
Original assignee: Hubei Jingyi High Precision Copper Plastics & Strips Co ltd
Current assignee: Hubei Jingyi High Precision Copper Plastics & Strips Co ltd
Priority date: 2021-04-06
Filing date: 2021-04-06
Publication date: 2024-04-19
Anticipated expiration: 2041-04-06
Also published as: CN113103096A

Abstract

The invention discloses production equipment and a processing technology of a novel nanoscale silicon carbide copper-based alloy material, and belongs to the field of alloy production equipment. A production device of a new nano-scale silicon carbide copper-based alloy material, comprising: conveying structure, polishing structure, pressing mechanism and workbench; the polishing mechanism is arranged on the workbench; the conveying mechanisms are symmetrically arranged on the two sides of the polishing mechanism on the workbench; the pressing mechanism is arranged on the polishing mechanism; the conveying mechanism comprises a pair of conveying belts with adjustable intervals; the polishing mechanism comprises a double-degree-of-freedom polishing machine; the conveying mechanism is connected with the polishing mechanism through a gear; the pressing mechanism comprises an up-down adjustable roller; the pressing mechanism is connected with the polishing mechanism through a gear; the pressing mechanism comprises a transmission assembly; the conveying mechanism is connected with the pressing mechanism through the transmission assembly.

Description

Production equipment and processing technology of novel nanoscale silicon carbide copper-based alloy material

Technical Field

The invention relates to the field of alloy production equipment, in particular to equipment for producing a novel nanoscale silicon carbide copper-based alloy material and a processing technology thereof.

Background

New materials refer to some materials that have been recently developed or being developed that have superior properties over traditional materials. The new material technology is a technology for creating a new material capable of meeting various requirements through a series of research processes such as physical research, material design, material processing, test evaluation and the like according to the will of people. Copper-based alloys are alloys based on copper with a certain amount of other elements added. The copper alloy has moderate strength, easy processing, fatigue resistance and beautiful color, and is an alloy which is formed by adding a certain amount of other elements based on copper. The copper alloy has moderate strength, easy processing, fatigue resistance, beautiful color, good electric conductivity, thermal conductivity and corrosion resistance, and is an important branch in heavy nonferrous metal materials.

The existing copper-based alloy is essentially required to be polished in the molding production process. Chinese patent discloses a copper pipe surface polishing device (CN 202021419162.6), which is applicable to polishing of surfaces of pipeline materials with different diameters, but has different polishing efficiencies due to different contact areas of polishing sheets when aiming at pipelines with different diameters because of different diameters of pipelines; moreover, the equipment can work only by manual clamping, and the working efficiency is greatly influenced.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides production equipment and a processing technology of a novel nanoscale silicon carbide copper-based alloy material.

The aim of the invention can be achieved by the following technical scheme:

A production device of a new nano-scale silicon carbide copper-based alloy material, comprising: the device comprises a conveying mechanism, a polishing mechanism, a pressing mechanism and a workbench;

The polishing mechanism is arranged on the workbench; the conveying mechanisms are symmetrically arranged on the two sides of the polishing mechanism on the workbench; the pressing mechanism is arranged on the polishing mechanism; the conveying mechanism comprises a pair of conveying belts with adjustable intervals; the polishing mechanism comprises a double-degree-of-freedom polishing machine; the conveying mechanism is connected with the polishing mechanism through a gear; the pressing mechanism comprises an up-down adjustable roller; the pressing mechanism is connected with the polishing mechanism through a gear; the pressing mechanism comprises a transmission assembly; the conveying mechanism is connected with the pressing mechanism through the transmission assembly.

Further, the conveying mechanism comprises a vertical plate, a first screw rod, a first motor, a first fixing seat and a second fixing seat; two first fixing seats are arranged on the workbench; the second fixing seat and the second fixing seat are symmetrically arranged on the workbench; the first fixing seat and the second fixing seat are both rotationally connected with a first screw rod; a fixing seat III is arranged between the fixing seat I and the fixing seat II; the fixing seat III is rotationally connected with a first connecting shaft; the first connecting shaft is fixedly provided with a first bevel gear; one end of the first screw rod, which is close to the first connecting shaft, is fixedly provided with a second bevel gear; the bevel gear I is meshed with the bevel gear II; the first screw rod of the same side face is connected with a vertical plate through threads; the motor I is fixedly arranged at one end, far away from the polishing mechanism, of the vertical plate; a fixing seat IV is fixedly arranged at one end, close to the polishing mechanism, of the vertical plate; the motor I is fixedly provided with a connecting shaft II, and the fixing seat IV is rotationally connected with a connecting shaft III; the second connecting shaft and the third connecting shaft are driven by the conveyor belt; guide blocks are uniformly distributed on the conveyor belt; one end of the guide block, which is close to the bevel gear I, is inclined; the guide blocks are fixedly provided with friction blocks.

Further, the polishing mechanism comprises a mounting frame, a connecting seat, a movable block, a movable plate and a polishing machine; the mounting frame is fixedly arranged with the workbench; the connecting seats are symmetrically arranged at the lower end of the mounting frame; the connecting seats are all rotationally connected with transmission shafts; the transmission shaft is fixedly provided with a straight gear I and a bevel gear III, and the first screw rods close to the transmission shaft are fixedly provided with a straight gear II; the first spur gear is meshed with the second spur gear; the mounting frame is symmetrically and vertically connected with a second screw in a rotating way; the screw II is fixedly provided with a bevel gear IV; the bevel gear III is meshed with the bevel gear IV; the mounting frame is fixedly provided with sliding rails at one side of the two screw rods II; the movable plate is connected with the sliding rail in a sliding way; the movable plate is rotationally connected with the two second screws; the upper end of the movable plate is symmetrically and fixedly provided with a first mounting seat; the first mounting shaft is rotatably connected with the first mounting seat; one end of the sliding rail, which is close to the third spur gear, is fixedly provided with a first rack; one end of the first mounting shaft, which is close to the first rack, is fixedly provided with a third spur gear; the third spur gear is meshed with the first rack; one end of the movable plate, which is close to the first mounting seat, is fixedly provided with a second mounting seat; the second mounting seat is rotationally connected with a second mounting shaft; the first installation shaft and the second installation shaft are fixedly provided with a spur gear IV which is meshed with each other; the movable plate is symmetrically provided with a third mounting seat between the first mounting seats; a mounting seat IV is arranged in front of the mounting seat III; two movable blocks are symmetrically arranged between the mounting seat IV and the two mounting seats III; the movable block is connected with the movable plate in a sliding way; the lower ends of the movable blocks are fixedly provided with the grinding machine; the mounting seat IV and the two mounting seats III are respectively and rotatably connected with a screw rod III; the third screw rod is in threaded connection with one movable block; one end of the screw rod III, which is close to the mounting seat I, is fixedly provided with a bevel gear V; the second mounting shaft is fixedly provided with a bevel gear six; the bevel gear V is meshed with the bevel gear V.

Further, the pressing mechanism comprises a screw four, a screw five, a movable column, a roller seat and a driving assembly; the screw rod IV and the screw rod V are both rotationally connected with the mounting frame; the screw IV is connected with the screw V through a chain; the screw four and the screw five are symmetrically distributed on the mounting frame; the screw four and the screw five are in threaded connection with one movable column; the roller seats are fixedly arranged at one ends of the movable columns, which are close to the conveying mechanism; the roller seats are all connected with roller frames in a sliding manner; the roller frame is rotationally connected with the roller, and a first spring is connected between the roller frame and the roller seat; the screw rod IV is rotationally connected with a spur gear V, and the lower end of the spur gear V forms a circular ring; the circular ring forms a first through hole in the radial direction, and a first limiting block is fixedly arranged in the first through hole by the screw rod IV; one end of the screw rod II, which is close to the spur gear V, is fixedly provided with a spur gear V; the spur gear nine is meshed with the spur gear five;

Further, the driving components are symmetrically and fixedly arranged on the mounting frame; the driving assembly comprises a first driving shaft, a second driving shaft, a driving plate, a driving rod, a turntable, a second rack, a sixth spur gear and a fixing plate; the fixing plate is arranged at the lower end of the screw rod IV; the upper end of the fixed plate is connected with the second rack in a sliding manner; the screw rod IV is fixedly arranged with the spur gear six; the second rack is matched with the straight gear six; the rack II is connected with the mounting rack through a spring II;

The first driving shaft is horizontally and rotatably connected with the mounting frame; the second driving shaft is arranged in the first driving shaft; the first driving shaft is rotationally connected with the second driving shaft, and the first driving shaft is slidingly connected with the second driving shaft; the driving plate is fixedly arranged on the first driving shaft; the driving plate comprises two side plates and a connecting plate; the side plates are connected through the connecting plates; the second driving shaft is in sliding connection with the two side plates; the second driving shaft is rotationally connected with the driving rod; the side plate forms a through hole II; the driving rod is rotationally connected with the second through hole; the driving rod is fixedly provided with a supporting rod in the second through hole; a limiting plate is fixedly arranged on one side, close to the driving rod, of the second driving shaft; a third spring is arranged between the limiting plate and the side plate;

The mounting frame is fixedly provided with a mounting box at one side far away from the driving plate; the second driving shaft is rotationally connected with a rotating block in the mounting box, and the rotating block is rotationally connected with the swing rod; the swing rod is rotationally connected with the mounting box; a driving seat is fixedly arranged at one end of the mounting box, which is close to the swing rod; the driving seat is rotationally connected with a driving shaft III; the turntable is fixedly arranged at one end of the driving shaft III, which is close to the swing rod; an arc block is fixedly arranged at one end of the turntable, which is close to the swing rod; inclined planes are formed at two ends of the arc block; a push rod is fixedly arranged at one end of the swing rod, which is close to the arc block; the mounting frame is provided with a driving shaft IV below the driving shaft I; the driving shaft IV is connected with the driving shaft I and the driving shaft III through chain wheels; the driving shaft is connected with the conveying mechanism through the transmission assembly.

Further, the transmission assembly comprises a hollow shaft, a transmission block, a sector gear and an arc tooth block; the hollow shaft is rotationally connected with the mounting frame; the hollow shaft is provided with a through hole III in the diameter direction; the transmission block is fixedly arranged in the through hole III of the connecting shaft III; the sector gear is fixedly arranged with the hollow shaft; one end of the mounting frame, which is close to the hollow shaft, is rotatably connected with two first rotating shafts; the first rotating shafts are fixedly provided with straight gears seven; the spur gear seven is meshed; one of the spur gears seven is meshed with the sector gear; two circular arc tooth blocks are symmetrically and fixedly arranged at the upper end of the straight gear seven; the radian of the arc tooth block is 90 degrees; one end, close to the first rotating shaft, of the mounting frame is rotatably connected with a second rotating shaft; a spur gear eight is fixedly arranged on the second rotating shaft; the spur gear eight is meshed with the circular arc tooth block in a staggered manner; ; the mounting frame is rotatably connected with a third rotating shaft; the second rotating shaft is in gear transmission with the second rotating shaft, and the third rotating shaft is in chain transmission with the first driving shaft.

Further, a storage box is arranged at one end, close to the conveying mechanism, of the workbench; the storage box is provided with an inclined guide plate.

Further, an adjustable supporting rod is arranged at the bottom of the workbench; the universal wheels are fixedly arranged at the lower ends of the supporting rods.

Further, the workbench is provided with a through hole IV at the lower end of the mounting frame; a fan is arranged below the fourth through hole.

The invention has the beneficial effects that:

The novel nanoscale silicon carbide copper-based alloy material production equipment can polish alloy pipes with different pipe diameters, and meanwhile, the pressing mechanism is arranged, so that the alloy pipes can be clamped and simultaneously the conveying of the alloy pipes is not affected.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view of the present application;

FIG. 2 is an enlarged schematic view of a portion of FIG. 1 at A;

FIG. 3 is an enlarged partial schematic view of FIG. 1 at B;

FIG. 4 is an enlarged partial schematic view of FIG. 1 at C;

FIG. 5 is a schematic top view of the sanding drive of the present application;

Fig. 6 is a schematic view of the inside of the mounting box of the present application.

Detailed Description

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

In the description of the present invention, it should be understood that the terms "open," "upper," "lower," "thickness," "top," "middle," "length," "inner," "peripheral," and the like indicate orientation or positional relationships, merely for convenience in describing the present invention and to simplify the description, and do not indicate or imply that the components or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

As shown in fig. 1 to 6, an apparatus for producing a new material of a copper-based alloy of silicon carbide of a nano-scale type, comprising: a conveying mechanism 3, a polishing mechanism 2, a pressing mechanism 4 and a workbench 1;

The polishing mechanism 2 is arranged on the workbench 1; the workbench 1 is symmetrically provided with conveying mechanisms 3 at two sides of the polishing mechanism 2; the pressing mechanism 4 is arranged on the polishing mechanism 2; the conveying mechanism 3 comprises a pair of conveying belts 13 with adjustable spacing; the polishing mechanism 2 comprises a double-degree-of-freedom polishing machine; the conveying mechanism 3 is connected with the polishing mechanism 2 through a gear; the pressing mechanism 4 comprises a roller 34 which can be adjusted up and down; the pressing mechanism 4 is connected with the polishing mechanism 2 through a gear; the pressing mechanism 4 comprises a transmission component; the conveying mechanism 3 is connected with the pressing mechanism 4 through a transmission assembly.

Further, the conveying mechanism 3 comprises a vertical plate 10, a first screw rod 7, a first motor 11, a first fixing seat 5 and a second fixing seat 6; two fixing seats I5 are arranged on the workbench 1; the second fixing seat 6 and the second fixing seat 6 are symmetrically arranged on the workbench 1; the first fixing seat 5 and the second fixing seat 6 are both rotationally connected with a first screw rod 7; a third fixing seat is arranged between the first fixing seat 5 and the second fixing seat 6; the fixing seat III is rotationally connected with a first connecting shaft; the first connecting shaft is fixedly provided with a bevel gear 8; one end of the first screw rod 7, which is close to the first connecting shaft, is fixedly provided with a bevel gear II 9; the bevel gear I8 is meshed with the bevel gear II 9; the first screws 7 on the same side face are connected with vertical plates 10 in a threaded manner; one end of the vertical plate 10 far away from the polishing mechanism 2 is fixedly provided with a motor I11; a fixing seat IV is fixedly arranged at one end of the vertical plate 10 close to the polishing mechanism 2; the motor I11 is fixedly provided with a connecting shaft II, and the fixing seat IV is rotationally connected with a connecting shaft III 12; the second connecting shaft and the third connecting shaft 12 are driven by a conveyor belt 13; guide blocks 14 are uniformly distributed on the conveyor belt 13; one end of the guide block 14, which is close to the bevel gear I8, is inclined; the guide blocks 14 are fixedly provided with friction blocks.

The polishing mechanism 2 comprises a mounting frame 20, a connecting seat, a movable block 26, a movable plate 22 and a polishing machine; the mounting frame 20 is fixedly arranged with the workbench 1; the lower end of the mounting frame 20 is symmetrically provided with connecting seats; the connecting seats are all rotationally connected with a transmission shaft 15; the transmission shaft 15 is fixedly provided with a straight gear I and a bevel gear III 17, and the screw rods I7 close to the transmission shaft 15 are fixedly provided with straight gears II; the straight gear I is meshed with the straight gear II; the mounting frame 20 is symmetrically and vertically connected with a second screw rod 19 in a rotating way; the screw II 19 is fixedly provided with a bevel gear IV 21; bevel gear III 17 is meshed with bevel gear IV 21; the mounting frame 20 is fixedly provided with a sliding rail 16 at one side of the two screw rods II 19; the movable plate 22 is in sliding connection with the slide rail 16; the movable plate 22 is rotationally connected with the two second screws 19; the upper end of the movable plate 22 is symmetrically and fixedly provided with a first mounting seat; the first mounting shaft is rotatably connected with the mounting seat; one end of the sliding rail 16, which is close to the third spur gear 24, is fixedly provided with a first rack 23; one end of the first mounting shaft, which is close to the first rack 23, is fixedly provided with a third spur gear 24; the third spur gear 24 is meshed with the first rack 23; one end of the movable plate 22, which is close to the first mounting seat, is fixedly provided with a second mounting seat; the second mounting seat is rotationally connected with a second mounting shaft; the first mounting shaft and the second mounting shaft are fixedly provided with a fourth spur gear 25, and the fourth spur gear 25 is meshed; the movable plate 22 is symmetrically provided with a third mounting seat between the first two mounting seats; a fourth mounting seat is arranged in front of the third mounting seat; two movable blocks 26 are symmetrically arranged between the mounting seat IV and the mounting seats III; the movable block 26 is in sliding connection with the movable plate 22; the lower ends of the movable blocks 26 are fixedly provided with grinding machines; the mounting seat IV and the mounting seats III are respectively and rotatably connected with a screw rod III 27; the third screw rod 27 is in threaded connection with a movable block 26; one end of the screw three 27, which is close to the first mounting seat, is fixedly provided with a bevel gear five 28; the second mounting shaft is fixedly provided with a bevel gear six 29; bevel gear five 28 meshes with bevel gear six 29.

Further, the pressing mechanism 4 comprises a screw four 30, a screw five 31, a movable column 32, a roller seat 33 and a driving component; the screw four 30 and the screw five 31 are both in rotary connection with the mounting frame 20; screw four 30 is connected with screw five 31 through the chain; the screw four 30 and the screw five 31 are symmetrically distributed on the mounting frame 20; the screw four 30 and the screw five 31 are both in threaded connection with a movable column 32; the roller seat 33 is fixedly arranged at one end of the movable column 32, which is close to the conveying mechanism 3; the roller seats 33 are all connected with roller frames in a sliding manner; the roller frame is rotatably connected with a roller 34, and a first spring is connected between the roller frame and the roller seat 33; the screw rod IV 30 is rotationally connected with a spur gear V35, and the lower end of the spur gear V35 forms a circular ring 36; the circular ring 36 forms a first through hole in the radial direction, and the screw four 30 is fixedly provided with a first limiting block 37 in the first through hole; one end of the screw rod II 19, which is close to the spur gear V35, is fixedly provided with a spur gear V; the spur gear nine is meshed with the spur gear five 35;

The driving components are symmetrically and fixedly arranged on the mounting frame 20; the driving assembly comprises a first driving shaft 41, a second driving shaft 42, a driving plate 43, a driving rod 44, a turntable 52, a second rack 38, a sixth spur gear 39 and a fixing plate; the fixed plate is arranged at the lower end of the screw rod IV 30; the upper end of the fixed plate is connected with a second rack 38 in a sliding way; screw four 30 and straight gear six 39 are fixedly installed; the second rack 38 is matched with the sixth spur gear 39; the second rack 38 is connected with the mounting frame 20 through a second spring 40;

The first driving shaft 41 is horizontally and rotatably connected with the mounting frame 20; the second drive shaft 42 is arranged inside the first drive shaft 41; the first driving shaft 41 is rotationally connected with the second driving shaft 42, and the first driving shaft 41 is slidably connected with the second driving shaft 42; the first driving shaft 41 is fixedly provided with a driving plate 43; the drive plate 43 includes two side plates and a connecting plate; the side plates are connected through a connecting plate; the second driving shaft 42 is in sliding connection with the two side plates; the second driving shaft 42 is rotatably connected with the driving rod 44; the side plate forms a through hole II; the driving rod 44 is rotatably connected with the second through hole; the driving rod 44 is fixedly provided with a supporting rod 45 in the second through hole; a limiting plate 46 is fixedly arranged on one side, close to the driving rod 44, of the driving shaft II 42; a third spring 47 is arranged between the limiting plate 46 and the side plate;

The mounting frame 20 is fixedly provided with a mounting box 48 at a side far from the driving plate 43; the second driving shaft 42 is rotatably connected with a rotating block 49 in the mounting box 48, and the rotating block 49 is rotatably connected with a swing rod 50; the swing rod 50 is in rotary connection with the mounting box 48; a driving seat is fixedly arranged at one end of the mounting box 48, which is close to the swing rod 50; the driving seat is rotationally connected with a driving shaft III 51; a turntable 52 is fixedly arranged at one end, close to the swing rod 50, of the driving shaft III 51; an arc block 53 is fixedly arranged at one end of the turntable 52, which is close to the swing rod 50; inclined surfaces are formed at two ends of the arc block 53; a push rod 54 is fixedly arranged at one end of the swing rod 50, which is close to the arc block 53; the mounting frame 20 is provided with a fourth drive shaft 55 below the first drive shaft 41; the driving shaft IV 55 is connected with the driving shaft I41 and the driving shaft III 51 through chain wheels; the fourth drive shaft 55 is connected to the conveying mechanism 3 via a transmission assembly.

Further, the transmission assembly includes a hollow shaft 56, a transmission block 57, a sector gear 58 and a circular arc tooth block 60; hollow shaft 56 is rotatably coupled to mounting frame 20; the hollow shaft 56 forms a through hole III in the diameter direction; the third connecting shaft 12 is fixedly provided with a transmission block 57 in the through hole III; the sector gear 58 is fixedly mounted with the hollow shaft 56; one end of the mounting frame 20, which is close to the hollow shaft 56, is rotatably connected with two first rotating shafts; a spur gear seven 59 is fixedly arranged on the first rotating shafts; seven 59 straight gears are meshed; a spur gear seven 59 is meshed with the sector gear 58; two circular arc tooth blocks 60 are symmetrically and fixedly arranged at the upper end of the straight gear seven 59; the arc of the circular arc tooth block 60 is 90 degrees; one end of the mounting frame 20, which is close to the first rotating shaft, is rotatably connected with a second rotating shaft; the second rotating shaft is fixedly provided with a spur gear eight 61; the spur gear eight 61 is meshed with the circular arc tooth block 60 in a staggered way; the mounting frame 20 is rotatably connected with a third rotating shaft; the second rotating shaft and the second rotating shaft are driven by gears, and the third rotating shaft and the first driving shaft 41 are driven by chains.

Before polishing, the screw rod I7 is driven to rotate by a motor or manually, the screw rod I7 is driven to rotate by the bevel gear I8 and the bevel gear II 9, and then the screw rod I7 on the other side is driven to rotate by the bevel gear I8 and the bevel gear II 9, so that two vertical plates 10 move in opposite directions or move in opposite directions, and then an alloy pipe is placed on the guide blocks 14 of the conveyor belt 13 by a feeding mechanism or manually; the grinding mechanism 2 is meshed with the second finger of the first screw 7 through the first spur gear of the transmission shaft 15 while the first screw 7 rotates, then the transmission shaft 15 drives the second screw 19 to rotate through the bevel gear, the second screw 19 drives the movable plate 22 to move through threads after rotating, then the movable plate 22 moves while the first spur gear is meshed with the rack to rotate, so that the first mounting shaft rotates through the rotation of the first mounting shaft driven by the gear, the first mounting shaft drives the third screw 27 to rotate through the bevel gear, so that the movable block 26 moves, and the moving directions of the movable blocks 26 on the two sides are different due to different turning directions of the first spur gear on the two sides, so that the movable block 26 moves relatively when the movable plate 22 falls down, the movable block 26 moves back when the movable plate 22 rises, the movable block 26 can be driven to move when the conveying belt is adjusted through the mode, the grinding machine is positioned on the two horizontal sides of the alloy pipe, the alloy pipe is quickly ground through the two grinding machines, and the manual adjustment time is saved;

Further, in order to prevent the phenomenon that the alloy pipe turns sideways due to the lack of constraint of the upper end when the alloy pipe is polished, a pressing mechanism 4 is arranged on the mounting frame 20, and the screw II 19 drives the screw IV 30 to rotate through a spur gear, so that the movable column 32 and the movable plate 22 are driven to synchronously move up and down, and the roller 34 props against the upper end of the alloy pipe; the strength of the roller 34 against the alloy pipe is increased by arranging a spring, so that the alloy pipe is prevented from shaking severely; however, when one alloy tube is finished, the spring moves the driving roller 34 downwards, and the next alloy tube is blocked at this time;

the lower end of the fifth spur gear 35 is provided with a circular ring 36, and the fifth spur gear 35 is rotationally connected with the fourth screw 30 instead; the screw rod IV 30 is provided with a first limiting block 37 in a first through hole of the circular ring 36, the spur gear V35 can drive the screw rod IV 30 to rotate through driving the first limiting block 37, then the conveying belt 13 rotates, the connecting shaft III 12 drives the hollow shaft 56 to rotate through the transmission block 57, and the hollow shaft 56 drives the spur gear V59 to transmit through the sector gear 58; the arc of the sector gear 58 is set so that when the conveyor belt 13 rotates half a turn, the spur gear seven 59 rotates half a turn; because the circular arc tooth block 60 is arranged on the straight gear seven 59, the four circular arcs can realize eight 61-90-degree reciprocating rotation of the straight gear meshed with the circular arc tooth block 60; the second rotating shaft transmits the motion of the spur gear eight 61 to the third rotating shaft and the first driving shaft 41 through the chain wheel; when the first driving shaft 41 rotates, the second driving shaft 42, the third driving shaft 51 and the fourth driving shaft 55 are driven to rotate; the arc block 53 on the disc of the driving shaft three 51 pushes the ejector rod 54 to enable the swing rod 50 to push the driving shaft two 42 in the rotating process, and at the moment, the driving plate 43 on the driving shaft one 41 is close to the rack two 38; after the driving shaft II 42 moves, the driving rod 44 rotates, the driving rod 44 drives the supporting rod 45 to extend outwards, so that the supporting rod 45 moves against the rack II 38, the rack II 38 moves and simultaneously drives the spur gear II 39 to rotate, so that the screw rod IV 30 is driven to rotate, and the movable column 32 moves upwards, and because the spur gear IV 35 drives the screw rod IV 30 to rotate by driving the limiting block I37 at the moment, when the screw rod IV 30 rotates, the limiting block I37 rotates from the through hole I to the other end, and the spur gear IV 35 is not driven to rotate; at this time, the alloy pipe can be continuously conveyed through the roller 34, and after the alloy pipe moves, the rack II 38 and the driving shaft II 42 are reset through springs respectively; when the alloy pipe moves to the second roller 34, the movable column 32 also moves upwards at the moment due to the reciprocating rotation of the spur gear eight 61, and the alloy pipe can continue to move; through the arrangement, the alloy pipe is clamped, the alloy pipe is continuously conveyed by the conveying belt 13, the manual adjustment time of the clamping mechanism is saved, and the working efficiency is improved.

Further, a storage box is arranged at one end of the workbench 1 close to the conveying mechanism 3; the receiver is provided with the deflector of slope, conveniently collects the alloy pipe that finishes of processing.

Further, an adjustable supporting rod is arranged at the bottom of the workbench 1; the universal wheels are fixedly arranged at the lower ends of the supporting rods, so that the equipment is convenient to adjust.

Further, the table 1 forms a through hole four at the lower end of the mount 20; a fan is arranged below the fourth through hole, so that dust generated by processing can be absorbed.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims.

Claims

1. The production equipment of the new nano-grade silicon carbide copper-based alloy material is characterized by comprising the following components: the polishing device comprises a conveying mechanism (3), a polishing mechanism (2), a pressing mechanism (4) and a workbench (1);

The polishing mechanism (2) is arranged on the workbench (1); the workbench (1) is symmetrically provided with the conveying mechanisms (3) at two sides of the polishing mechanism (2); the pressing mechanism (4) is arranged on the polishing mechanism (2); the conveying mechanism (3) comprises a pair of conveying belts (13) with adjustable spacing; the polishing mechanism (2) comprises a dual-freedom-degree polishing machine; the conveying mechanism (3) is connected with the polishing mechanism (2) through a gear; the pressing mechanism (4) comprises an up-down adjustable roller (34); the pressing mechanism (4) is connected with the polishing mechanism (2) through a gear; the pressing mechanism (4) comprises a transmission assembly; the conveying mechanism (3) is connected with the pressing mechanism (4) through the transmission assembly;

The conveying mechanism (3) comprises a vertical plate (10), a first screw rod (7), a first motor (11), a first fixing seat (5) and a second fixing seat (6); two first fixing seats (5) are arranged on the workbench (1); the second fixing seat (6) and the second fixing seat (6) are symmetrically arranged on the workbench (1); the first fixing seat (5) and the second fixing seat (6) are both rotationally connected with a first screw rod (7); a third fixing seat is arranged between the first fixing seat (5) and the second fixing seat (6); the fixing seat III is rotationally connected with a first connecting shaft; the first connecting shaft is fixedly provided with a first bevel gear (8); one end of the first screw rod (7) close to the first connecting shaft is fixedly provided with a second bevel gear (9); the bevel gear I (8) is meshed with the bevel gear II (9); the first screw rods (7) on the same side face are all in threaded connection with a vertical plate (10); one end, far away from the polishing mechanism (2), of the vertical plate (10) is fixedly provided with a motor I (11); a fixing seat IV is fixedly arranged at one end, close to the polishing mechanism (2), of the vertical plate (10); the motor I (11) is fixedly provided with a connecting shaft II, and the fixing seat IV is rotationally connected with a connecting shaft III (12); the second connecting shaft and the third connecting shaft (12) are driven by the conveyor belt (13); guide blocks (14) are uniformly distributed on the conveyor belt (13); one end of the guide block (14) close to the bevel gear I (8) is inclined; the friction blocks are fixedly arranged on the guide blocks (14);

the polishing mechanism (2) comprises a mounting frame (20), a connecting seat, a movable block (26), a movable plate (22) and a polishing machine; the mounting frame (20) is fixedly arranged with the workbench (1); the connecting seats are symmetrically arranged at the lower end of the mounting frame (20); the connecting seats are all rotationally connected with a transmission shaft (15); the transmission shaft (15) is fixedly provided with a straight gear I and a bevel gear III (17), and the screw rods I (7) close to the transmission shaft (15) are fixedly provided with straight gears II; the first spur gear is meshed with the second spur gear; the mounting frame (20) is symmetrically and vertically connected with a screw rod II (19) in a rotating way; the screw II (19) is fixedly provided with a bevel gear IV (21); the bevel gear III (17) is meshed with the bevel gear IV (21); the mounting frame (20) is fixedly provided with sliding rails (16) at one side of the two screw rods (19); the movable plate (22) is in sliding connection with the sliding rail (16); the movable plate (22) is rotationally connected with the two screw rods (19); the upper end of the movable plate (22) is symmetrically and fixedly provided with a first mounting seat; the first mounting shaft is rotatably connected with the first mounting seat; one end of the sliding rail (16) close to the spur gear III (24) is fixedly provided with a rack I (23); one end of the first mounting shaft, which is close to the first rack (23), is fixedly provided with the third spur gear (24); the spur gear III (24) is meshed with the rack I (23); one end of the movable plate (22) close to the first mounting seat is fixedly provided with a second mounting seat; the second mounting seat is rotationally connected with a second mounting shaft; the first mounting shaft and the second mounting shaft are fixedly provided with a fourth spur gear (25), and the fourth spur gear (25) is meshed; the movable plate (22) is symmetrically provided with a third mounting seat between the first two mounting seats; a mounting seat IV is arranged in front of the mounting seat III; two movable blocks (26) are symmetrically arranged between the mounting seat IV and the two mounting seats III; the movable block (26) is in sliding connection with the movable plate (22); the lower ends of the movable blocks (26) are fixedly provided with the grinding machine; the mounting seat IV and the mounting seats III are respectively and rotatably connected with a screw rod III (27); the screw rods III (27) are in threaded connection with one movable block (26); one end, close to the first mounting seat, of the screw rod III (27) is fixedly provided with a bevel gear V (28); the second mounting shaft is fixedly provided with a bevel gear six (29); the bevel gear V (28) is meshed with the bevel gear V (29).

2. The production equipment of the new nano-scale silicon carbide copper-based alloy material according to claim 1, wherein the pressing mechanism (4) comprises a screw four (30), a screw five (31), a movable column (32), a roller seat (33) and a driving assembly; the screw four (30) and the screw five (31) are both rotationally connected with the mounting frame (20); the screw four (30) is connected with the screw five (31) through a chain; the screw four (30) and the screw five (31) are symmetrically distributed on the mounting frame (20); the screw four (30) and the screw five (31) are both in threaded connection with one movable column (32); the roller seats (33) are fixedly arranged at one ends of the movable columns (32) close to the conveying mechanism (3); the roller seats (33) are all connected with roller frames in a sliding manner; the roller frame is rotatably connected with the roller (34), and a first spring is connected between the roller frame and the roller seat (33); the screw rod IV (30) is rotationally connected with a spur gear V (35), and the lower end of the spur gear V (35) forms a circular ring (36); the circular ring (36) forms a first through hole in the radial direction, and the screw rod IV (30) is fixedly provided with a first limiting block (37) in the first through hole; one end of the second screw rod (19) close to the fifth spur gear (35) is fixedly provided with a ninth spur gear; the spur gear nine is meshed with the spur gear five (35).

3. The production plant of new nano-sized silicon carbide copper-based alloy materials according to claim 2, characterized in that said driving assemblies are symmetrically and fixedly mounted on said mounting frame (20); the driving assembly comprises a first driving shaft (41), a second driving shaft (42), a driving plate (43), a driving rod (44), a rotary table (52), a second rack (38), a sixth spur gear (39) and a fixed plate; the fixing plate is arranged at the lower end of the screw rod IV (30); the upper end of the fixed plate is connected with the second rack (38) in a sliding way; the screw four (30) is fixedly arranged with the spur gear six (39); the rack II (38) is matched with the spur gear III (39); the rack II (38) is connected with the mounting frame (20) through a spring II (40);

The first driving shaft (41) is horizontally and rotatably connected with the mounting frame (20); the second driving shaft (42) is arranged inside the first driving shaft (41); the first driving shaft (41) is rotationally connected with the second driving shaft (42), and the first driving shaft (41) is slidably connected with the second driving shaft (42); the first driving shaft (41) is fixedly provided with the driving plate (43); the drive plate (43) comprises two side plates and a connecting plate; the side plates are connected through the connecting plates; the driving shaft II (42) is in sliding connection with the two side plates; the driving shaft II (42) is rotationally connected with the driving rod (44); the side plate forms a through hole II; the driving rod (44) is rotationally connected with the second through hole; the driving rod (44) is fixedly provided with a supporting rod (45) in the second through hole; a limiting plate (46) is fixedly arranged on one side, close to the driving rod (44), of the driving shaft II (42); a spring III (47) is arranged between the limiting plate (46) and the side plate;

The mounting frame (20) is fixedly provided with a mounting box (48) at one side far away from the driving plate (43); the second driving shaft (42) is rotatably connected with a rotating block (49) in the mounting box (48), and the rotating block (49) is rotatably connected with a swing rod (50); the swing rod (50) is rotationally connected with the mounting box (48); a driving seat is fixedly arranged at one end, close to the swing rod (50), of the mounting box (48); the driving seat is rotationally connected with a driving shaft III (51); one end, close to the swing rod (50), of the driving shaft III (51) is fixedly provided with the rotary disc (52); an arc block (53) is fixedly arranged at one end of the rotary disc (52) close to the swing rod (50); inclined planes are formed at two ends of the arc block (53); an ejector rod (54) is fixedly arranged at one end, close to the arc block (53), of the swing rod (50); a fourth driving shaft (55) is arranged below the first driving shaft (41) on the mounting frame (20); the driving shaft IV (55) is connected with the driving shaft I (41) and the driving shaft III (51) through chain wheels; the driving shaft IV (55) is connected with the conveying mechanism (3) through the transmission assembly.

4. The apparatus for producing a new material of nano-sized silicon carbide copper base alloy according to claim 3, wherein the transmission assembly comprises a hollow shaft (56), a transmission block (57), a sector gear (58) and a circular arc tooth block (60); the hollow shaft (56) is rotationally connected with the mounting frame (20); the hollow shaft (56) is provided with a through hole III in the diameter direction; the third connecting shaft (12) is fixedly provided with the transmission block (57) in the third through hole; the sector gear (58) is fixedly arranged with the hollow shaft (56); one end of the mounting frame (20) close to the hollow shaft (56) is rotatably connected with two first rotating shafts; a spur gear seven (59) is fixedly arranged on the first rotating shafts; the spur gear seven (59) is meshed; -one of said spur gears seven (59) is in mesh with said sector gear (58); two circular arc tooth blocks (60) are symmetrically and fixedly arranged at the upper end of the straight gear seven (59); the radian of the arc tooth block (60) is 90 degrees; one end, close to the first rotating shaft, of the mounting frame (20) is rotatably connected with a second rotating shaft; a spur gear eight (61) is fixedly arranged on the second rotating shaft; the spur gear eight (61) is meshed with the circular arc tooth block (60) in a staggered manner; the mounting frame (20) is rotatably connected with a third rotating shaft; the second rotating shaft and the second rotating shaft are driven by gears, and the third rotating shaft and the first driving shaft (41) are driven by chains.

5. The production equipment of the new nano-scale silicon carbide copper-based alloy material according to claim 1, wherein a storage box is arranged at one end of the workbench (1) close to the conveying mechanism (3); the storage box is provided with an inclined guide plate.

6. The production equipment of the new nano-scale silicon carbide copper-based alloy material according to claim 1, wherein an adjustable supporting rod is arranged at the bottom of the workbench (1); the universal wheels are fixedly arranged at the lower ends of the supporting rods.

7. The production equipment of new nano-scale silicon carbide copper base alloy material according to claim 1, characterized in that the workbench (1) forms a through hole four at the lower end of the mounting rack (20); a fan is arranged below the fourth through hole.