CN118081860A

CN118081860A - Metal foil cutting device for electromechanical engineering

Info

Publication number: CN118081860A
Application number: CN202410501272.3A
Authority: CN
Inventors: 李霞; 杨芳; 王倩; 刘小峰; 轩见涛; 刘明岗; 马艳杰
Original assignee: Xinxiang Dasheng Machinery Manufacturing Co ltd
Current assignee: Xinxiang Dasheng Machinery Manufacturing Co ltd
Priority date: 2024-04-25
Filing date: 2024-04-25
Publication date: 2024-05-28
Anticipated expiration: 2044-04-25
Also published as: CN118081860B

Abstract

The invention relates to the technical field of electromechanical engineering cutting equipment, in particular to a metal foil cutting device for electromechanical engineering, which aims at the problems that a user is easy to be injured when metal foils are manually cut, time and labor are wasted, and comprises a main bottom plate, wherein a detachable metal coil is arranged on a secondary bottom plate; conveying mechanisms matched with the metal rolls are respectively arranged on two sides of the upper end of the main bottom plate, each conveying mechanism comprises two rotatable driving rollers, and the driving rollers can form a structure that the metal rolls are unfolded and moved along a designated path when rotating; the cutting device comprises two L-shaped driving plates capable of synchronously moving, and the L-shaped driving plates can form a structure that the cutting plates move downwards to cut the metal coil and move back and forth to polish the metal foil after moving to the bottom end when moving leftwards; the metal foil can be cut, manual operation of a user is replaced, and the metal foil can be polished after the cutting is finished, so that the worker is prevented from being injured during construction.

Description

Metal foil cutting device for electromechanical engineering

Technical Field

The invention relates to the technical field of electromechanical engineering cutting equipment, in particular to a metal foil cutting device for electromechanical engineering.

Background

The electromechanical installation engineering refers to the installation of equipment, lines and pipelines in common industrial and public civil construction projects; the specific working contents of the manufacturing and the installation of the nonstandard steel components comprise purchase, installation, debugging and the like of boilers, ventilation air conditioners, refrigeration, electric devices, meters, motors, compressor units, broadcast movies, television broadcasting control and other devices; along with the acceleration of modern construction pace, the requirements for electromechanical installation engineering are more and more increased, for example, metal foils are used in various fields of building decoration, automobile manufacturing, food packaging processing, outdoor power operation and the like, at present, when the metal foils are cut, the metal foils are usually cut by manually holding scissors, on one hand, the metal foils are sharp and easy to hurt users, on the other hand, the metal foils have certain hardness, and the manual cutting is time-consuming and labor-consuming; for this purpose, a metal foil cutting device for electromechanical engineering is designed to solve the above-mentioned problems.

Disclosure of Invention

Aiming at the problems that a user is easy to be injured when the metal foil is manually cut, time and labor are wasted, the invention provides the metal foil cutting device for the electromechanical engineering, which can cut the metal foil to replace manual operation of the user, and can polish the metal foil after the cutting is finished, thereby preventing the worker from being injured during construction and effectively solving the problems in the prior art.

The technical scheme adopted by the invention for solving the problems is as follows:

The metal foil cutting device for the electromechanical engineering comprises a main bottom plate, wherein the front end of the main bottom plate is provided with a sub bottom plate, and a detachable metal coil is arranged on the sub bottom plate; conveying mechanisms matched with the metal rolls are respectively arranged on two sides of the upper end of the main bottom plate, each conveying mechanism comprises two rotatable driving rollers, and the driving rollers can form a structure that the metal rolls are unfolded and moved along a designated path when rotating; the middle part of the upper end of the main bottom plate is provided with a cutting device, the cutting device comprises two L-shaped driving plates capable of synchronously moving, the cutting device further comprises a cutting plate, and the L-shaped driving plates can form a structure that the cutting plate moves downwards to cut a metal coil and moves back and forth to polish a metal foil after moving to the bottom end when moving leftwards.

The middle part of the upper end surface of the main bottom plate is provided with a cutting seat, the left side and the right side of the upper end surface of the cutting seat are respectively provided with a cutting table matched with a cutting plate, the front end surface and the rear end surface of the cutting seat are respectively fixedly connected with side seats, the cutting plates are respectively and slidably connected to the inner walls of the two side seats, the front end surface and the rear end surface of the cutting plate are respectively fixedly connected with a long pin, and the lower end of the cutting plate is provided with a cutting edge; the front side and the back side of the surface of the upper end of the main bottom plate are respectively fixedly connected with driving telescopic rods, L-shaped driving plates are respectively fixedly connected on the corresponding driving telescopic rods, the L-shaped driving plates are respectively and slidably connected on the front side and the back side of the surface of the upper end of the main bottom plate, and the upper ends of the L-shaped driving plates are respectively provided with first track grooves matched with the long pins.

The cutting table sliding connection is in cutting seat upper end surface left and right sides, and both sides are respectively rigid coupling has the leading truck about the cutting board, and both ends surface rigid coupling has the guide pin respectively around the cutting table, has seted up respectively on the leading truck with guide pin matched with guide slot, both ends surface is equipped with the board of polishing about the cutting board respectively, and two cutting table inner walls are equipped with the clamp plate of polishing that can inwards remove respectively.

The upper side and the lower side of the inner walls of the left end and the right end of the cutting table are respectively and slidably connected with a second guide rod, the polishing pressing plates are respectively and fixedly connected to the inner side end faces of the corresponding second guide rods, and second springs matched with the polishing plates are respectively sleeved on the outer surfaces of the second guide rods.

The cutting seat is connected to the upper end surface of the main bottom plate in a sliding manner, the front end surface and the rear end surface of the lower side of the cutting seat are fixedly connected with extension seats respectively, the inner walls of the extension seats are fixedly connected with driving pins respectively, and driving grooves matched with the driving pins are formed in the inner sides of the upper end surfaces of the L-shaped driving plates respectively.

The middle part of the upper end surface of the auxiliary base is provided with a rotatable disc, the front side and the rear side of the upper end surface of the auxiliary base plate are respectively fixedly connected with a blanking seat, the inner wall of the center of the metal coil is provided with a winding roller, the upper end of the blanking seat is respectively provided with a pressing block matched with the winding roller, and the disc can form a structure that the pressing block moves outwards to detach the winding roller when rotating.

The non-centre of a circle department of disc lower extreme surface articulates there are two centrosymmetric first connecting rods, and two first connecting rod outside ends are articulated respectively have with unloading seat sliding connection's pull rod, briquetting sliding connection is at unloading seat upper end surface respectively, and both sides respectively rigid coupling has first guide arm about two unloading seat outside terminal surface, and equal sliding connection has a roof on two first guide arm surfaces, the briquetting is the rigid coupling respectively on the roof that corresponds, still overlaps respectively on the first guide arm surface has the first spring with roof matched with.

Two U-shaped seats are fixedly connected to the left side and the right side of the upper end surface of the main bottom plate respectively, the conveying mechanism is arranged on the inner walls of the corresponding two U-shaped seats respectively, a rotatable bidirectional threaded rod is further arranged at the upper end of the main bottom plate, and a structure that the auxiliary bottom plate moves rightwards and the conveying mechanism moves downwards to enable the device to be folded can be formed when the bidirectional threaded rod rotates.

The conveying mechanism further comprises a U-shaped frame, wherein a first motor is fixedly connected to one side end surface of the U-shaped frame respectively, a first rotating shaft is fixedly connected to the output end of the first motor respectively, a first bevel gear is connected to the upper end of the outer surface of the first rotating shaft respectively in a sliding manner, a second bevel gear is meshed with the upper end of the first bevel gear respectively, an inner seat is connected to the inner wall of the U-shaped frame respectively in a sliding manner, the driving roller comprises a first driving roller and a second driving roller, the first driving roller is connected to the inner wall of the corresponding inner seat in a rotating manner and is fixedly connected with a corresponding third bevel gear in a coaxial manner, a fourth bevel gear is meshed to the lower end of the third bevel gear respectively, and the second driving roller is connected to the inner wall of the lower end of the corresponding U-shaped frame in a rotating manner and is fixedly connected with a corresponding fourth bevel gear in a coaxial manner; the inner wall of the upper end of the inner seat is respectively connected with a first threaded rod in a rotating way, and the first threaded rods are respectively connected with the inner walls of the corresponding U-shaped frames in a threaded way.

The front end and the rear end of the left side of the upper end surface of the main bottom plate are respectively hinged with a scissor type expansion bracket, the outer sides of the left ends of the two scissor type expansion brackets are respectively hinged on the auxiliary bottom plate, the inner sides of the left ends of the two scissor type expansion brackets are respectively connected with the auxiliary bottom plate in a sliding mode, the inner sides of the right ends of the two scissor type expansion brackets are respectively hinged with a threaded cylinder in threaded connection with a bidirectional threaded rod, the front side and the rear side of the upper end surface of the auxiliary bottom plate are respectively fixedly connected with guide plates in sliding connection with the main bottom plate, the U-shaped brackets are respectively connected with the inner walls of corresponding U-shaped seats in a sliding mode, special-shaped grooves are respectively formed in the guide plates, the inner walls of the special-shaped grooves are respectively meshed with first sliding pins, and the first sliding pins are respectively fixedly connected on the corresponding U-shaped brackets.

Compared with the prior art, the invention has the following advantages:

When the metal coil cutting machine is used, one end of the metal coil passes through the two driving rollers, the metal coil can be unfolded for a specified length when the driving rollers rotate, the metal coil passes through the two groups of driving rollers through the two conveying mechanisms, and the metal coil can be unfolded when the conveying mechanisms work, namely the two groups of rotating rollers rotate, so that the metal coil moves along a specified position, namely the metal coil is unfolded and moved to one side at the lower end position of the cutting plate; through the cutting device, when the L-shaped driving plate moves leftwards, the cutting plate can move downwards to cut the metal coil to replace manual cutting of workers, and the cutting plate moves back and forth after moving to the bottom end, so that the cut metal foil can be polished, and the workers are prevented from being injured by the cutting plate during construction; the workman can cut the material according to required length to can evenly polish to the metal foil again after drawing materials, prevent deckle edge stabbing the user, whole substitution manual operation, use manpower sparingly resource, safe and reliable.

Drawings

Fig. 1 is a first perspective view of a metal foil cutting device for electro-mechanical engineering according to the present invention.

Fig. 2 is a second isometric view of a metal foil cutting device for electro-mechanical engineering according to the present invention.

Fig. 3 is a schematic diagram showing the disc installation of the metal foil cutting device for the electromechanical engineering.

Fig. 4 is a sectional view of a blanking seat of a metal foil cutting device for electro-mechanical engineering according to the present invention.

Fig. 5 is a schematic view of the installation of a scissor-type expansion bracket of the metal foil cutting device for the electromechanical engineering.

Fig. 6 is a schematic view of the installation of a U-shaped frame of the metal foil cutting device for electro-mechanical engineering according to the present invention.

Fig. 7 is a schematic view illustrating the installation of an inner seat of a metal foil cutting device for electro-mechanical engineering according to the present invention.

Fig. 8 is a schematic view illustrating the installation of a cutting seat of a metal foil cutting device for electro-mechanical engineering according to the present invention.

Fig. 9 is a schematic diagram of an L-shaped driving plate structure of a metal foil cutting device for electro-mechanical engineering according to the present invention.

Fig. 10 is a schematic view showing the installation of a cutting plate of the metal foil cutting device for electro-mechanical engineering according to the present invention.

Fig. 11 is a schematic structural view of a guide frame of a metal foil cutting device for electro-mechanical engineering according to the present invention.

Fig. 12 is a sectional view of a cutting table of a metal foil cutting device for electro-mechanical engineering according to the present invention.

Reference numerals in the drawings: 1-auxiliary bottom plate, 2-foot brake moving wheel, 3-main bottom plate, 4-first handle, 5-disc, 6-first connecting rod, 7-pull rod, 8-blanking seat, 9-winding roller, 10-top plate, 11-first guide rod, 12-first spring, 13-first baffle, 14-press block, 15-bidirectional threaded rod, 16-threaded cylinder, 17-scissor type telescopic frame, 18-limit seat, 19-limit pin, 20-guide plate, 21-U-shaped seat, 22-U-shaped frame, 23-first sliding pin, 24-long chute, 25-long transverse slot, 26-connecting rod, 27-first motor, 28-first rotating shaft, 29-first bevel gear, 30-second bevel gear 31-third bevel gear, 32-fourth bevel gear, 33-first driving roller, 34-second driving roller, 35-inner seat, 36-first threaded rod, 37-second handle, 38-drive telescopic rod, 39-L-shaped drive plate, 40-long pin, 41-short chute, 42-short transverse slot, 43-cutting seat, 44-side seat, 45-cutting plate, 46-blade, 47-sanding plate, 48-guide frame, 49-first vertical slot, 50-first chute, 51-second vertical slot, 52-guide pin, 53-sanding platen, 54-second guide rod, 55-second spring, 56-cutting table, 57-drive pin, 58-second transverse slot, 59-wave slot.

Detailed Description

The following are specific embodiments of the present invention, and the technical solutions of the present invention are further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1-12, the invention provides a metal foil cutting device for electromechanical engineering, which comprises a main bottom plate 3, wherein the front end of the main bottom plate 3 is provided with a sub-bottom plate 1, and a detachable metal coil is arranged on the sub-bottom plate 1; conveying mechanisms matched with the metal rolls are respectively arranged on two sides of the upper end of the main bottom plate 3, each conveying mechanism comprises two rotatable driving rollers, and the driving rollers can form a structure that the metal rolls are unfolded and moved along a designated path when rotating; the middle part of the upper end of the main bottom plate 3 is provided with a cutting device, the cutting device comprises two L-shaped driving plates 39 capable of synchronously moving, the cutting device also comprises a cutting plate 45, and when the L-shaped driving plates 39 move leftwards, a structure that the cutting plate 45 moves downwards to cut a metal coil and moves to the bottom end and then moves back and forth to polish a metal foil can be formed.

As shown in fig. 1-8, the lower ends of the main bottom plate 3 and the auxiliary bottom plate 1 are respectively provided with a plurality of foot brake movable wheels 2, and as shown in fig. 2, the foot brake movable wheels 2 can enable the device to move to a designated position, have a braking function, enable the device to be fixed after reaching the designated position, and enable the device to work normally; the auxiliary bottom plate 1 is used for supporting and limiting the metal coil, the metal coil can be detachably arranged on the auxiliary bottom plate 1, when the metal coil is used up, a new metal coil can be replaced, and the metal coil forms a metal foil after being unfolded and cut; the metal coil can be unfolded for a specified length by passing one end of the metal coil through the two driving rollers, namely, the two driving rollers rotate, and can be unfolded to move along a specified position by passing the metal coil through the two groups of driving rollers under the operation of the conveying mechanisms, namely, the two groups of rotating rollers rotate, namely, the metal coil is unfolded to move to one side at the lower end of the cutting plate 45; through the cutting device, when the L-shaped driving plate 39 moves leftwards, the cutting plate 45 can be made to move downwards to cut the metal coil instead of manually cutting by workers, and the cutting plate 45 moves back and forth after moving to the bottom end, so that the cut metal foil can be polished, and the workers are prevented from being injured by the cutting plate during construction; the workman can cut the material according to required length to can evenly polish to the metal foil again after drawing materials, prevent deckle edge stabbing the user, whole substitution manual operation, use manpower sparingly resource, safe and reliable.

The middle part of the upper end surface of the main bottom plate 3 is provided with a cutting seat 43, the left side and the right side of the upper end surface of the cutting seat 43 are respectively provided with a cutting table 56 matched with a cutting plate 45, the front end surface and the rear end surface of the cutting seat 43 are respectively fixedly connected with side seats 44, the cutting plates 45 are respectively and slidably connected to the inner walls of the two side seats 44, the front end surface and the rear end surface of the cutting plate 45 are respectively fixedly connected with a long pin 40, and the lower end of the cutting plate 45 is provided with a cutting edge 46; the front and back sides of the upper end surface of the main bottom plate 3 are fixedly connected with driving telescopic rods 38 respectively, L-shaped driving plates 39 are fixedly connected to the corresponding driving telescopic rods 38 respectively, the L-shaped driving plates 39 are connected to the front and back sides of the upper end surface of the main bottom plate 3 in a sliding mode respectively, and first track grooves matched with the long pins 40 are formed in the upper ends of the L-shaped driving plates 39 respectively.

As shown in fig. 8-11, the cutting seat 43 can be slidably connected to the inner wall of the main bottom plate 3, and the cutting seat 43 is used for supporting the parts such as the cutting table 56, the cutting plate 45, the side seat 44, etc.; the cutting plate 45 can be connected to the inner wall of the side seat 44 in an up-and-down sliding way, and the limiting cutting plate 45 can only move up and down; the L-shaped driving plate 39 can be connected to the upper end surface of the main bottom plate 3 in a left-right sliding manner, the driving telescopic rod 38 and the L-shaped telescopic rod are installed and shaped as shown in fig. 9, the driving telescopic rod 38 can drive the L-shaped telescopic rod to move leftwards or rightwards when the telescopic rod stretches, the driving telescopic rod 38 can be an electric telescopic rod, a hydraulic telescopic rod or a pneumatic telescopic rod, and the driving telescopic rod 38 is of the prior art and is not repeated; the installation and the shape of the first track groove and the long pin 40 are as shown in fig. 9, the long pin 40 can move back and forth on the inner wall of the first track groove, and the front and back movement of the cutting plate 45 is not affected, so that the metal foil is polished; the first track groove comprises a short transverse groove 42 and a short chute 41, when the L-shaped driving plate 39 moves leftwards, the long pin 40 and the cutting plate 45 can move downwards under the meshing of the short chute 41 and the long pin 40, when the L-shaped driving plate 39 moves leftwards to enable the long pin 40 to enter the inner wall of the short transverse groove 42, the long pin 40 and the cutting plate 45 move downwards to the bottommost position at the moment, namely the L-shaped driving plate 39 continues to move leftwards and does not drive the long pin 40 and the cutting plate 45 to move downwards any more at the moment, namely the height of the cutting plate 45 is in a stable state at the moment; the metal coil can pass through the space of the lower end position of the cutting plate 45 at the upper end position of the cutting table 56 and move under the transportation of the conveying mechanism, when the metal coil is required to be cut, the two L-shaped driving plates 39 can move leftwards by starting the driving telescopic rods 38 to work, and when the L-shaped driving plates 39 move leftwards, the corresponding long pins 40, the cutting plates 45 and the cutting edges 46 can be driven to move downwards through the meshing of the short chute 41 and the long pins 40, when the cutting edges 46 move downwards to squeeze the metal coil at the upper end of the cutting table 56, the metal coil can be cut off, and when the L-shaped driving plates 39 move rightwards, the metal coil can be reset, and the metal coil cutting device is not repeated.

The cutting table 56 is slidably connected to the left and right sides of the upper end surface of the cutting seat 43, the front and rear sides of the left and right end surfaces of the cutting board 45 are respectively and fixedly connected with a guide frame 48, the front and rear end surfaces of the cutting table 56 are respectively and fixedly connected with guide pins 52, guide grooves matched with the guide pins 52 are respectively formed in the guide frames 48, polishing boards 47 are respectively arranged on the left and right end surfaces of the cutting board 45, and polishing pressing boards 53 capable of moving inwards are respectively arranged on the inner walls of the two cutting tables 56.

As shown in fig. 11 to 12, a cutting table 56 is slidably coupled to the upper end surface of the cutting seat 43 in a left-right direction; the installation and the shape of the guide frame 48, the guide grooves and the guide pins 52 are as shown in fig. 11, the guide frame 48 is fixedly connected on the cutting plate 45 through bolts, the guide grooves comprise a first vertical groove 49, a first chute 50 and a second vertical groove 51, when the cutting plate 45 and the guide frame 48 move downwards, the corresponding two guide pins 52 are in the innermost end state under the meshing of the guide pins 52 and the second vertical groove 51, namely, the corresponding two cutting tables 56 are in the state that the innermost ends are in close contact with each other, when the cutting plate 45 moves downwards continuously to enable the cutting edge 46 to contact and cut off a metal coil, the cutting edge 46 contacts the upper end surface position of the cutting table 56, the cutting plate 45 and the guide frame 48 move downwards continuously, the corresponding guide pins 52 enter the inner wall of the first chute 50, the cutting plate 45 and the guide frame 48 move downwards continuously to enable the corresponding two guide pins 52 to move outwards, namely, when the cutting plate 45 and the guide frame 48 move downwards to enable the guide pins 52 to enter the inner wall of the first vertical groove 49, the corresponding two cutting tables 56 move outwards, and when the cutting plate 45 and the guide frame 48 move downwards to enable the guide pins 52 to enter the inner wall of the cutting table 49 to enter the cutting table 56, the cutting table 56 to move downwards, namely, the cutting table 56 moves downwards to the top surface to the cutting table 56 and does not move outwards, and the cutting table 56 moves downwards to the cutting table 52 slightly to the top surface to the cutting table 56 is more than the cutting table 52 moves outwards; when the cutting plate 45 continues to move downwards, the cutting plate 45 moves to the inner side positions of the two cutting tables 56, at this time, when the cutting plate 45 continues to move downwards, the end faces of the metal coil just cut are pressed down to the inner side positions of the two cutting tables 56, the installation and the shape of the polishing pressing plate 53 are as shown in fig. 11, when the cutting plate 45 moves downwards to the bottommost end position, namely, the polishing plate 47 contacts with the polishing pressing plate 53, at this time, the end faces of the metal coil after cutting are positioned at the middle positions of the two corresponding polishing plates 47 and the polishing pressing plate 53 under the driving of the cutting plate 45, when the polishing plate 47 and the polishing pressing plate 53 move forwards and backwards, polishing treatment can be carried out on the end faces of the metal coil just cut, and the polishing pressing plate 53 has inward driving force, and friction force can be increased during polishing, so that polishing effect is improved; polishing papers are respectively stuck on the polishing plate 47 and the polishing pressing plate 53 and used for polishing the end surfaces of the metal coil; the guide frame 48 lower extreme still is equipped with the open slot, can make guide pin 52 and guide slot break away from mutually through the open slot that sets up, is convenient for change the paper of polishing of clamp plate 53 upper end, when needs change the paper of polishing, through dismantling guide frame 48 and upwards moving, can dismantle guide frame 48, two cutting tables 56 outside slide at this moment can change the paper of polishing on clamp plate 53.

The upper and lower sides of the inner walls of the left and right ends of the cutting table 56 are respectively and slidably connected with a second guide rod 54, the polishing pressing plates 53 are respectively and fixedly connected to the inner side end surfaces of the corresponding second guide rods 54, and the outer surfaces of the second guide rods 54 are respectively sleeved with a second spring 55 matched with the polishing plate 47.

As shown in fig. 12, the second guide rod 54 can be slidably connected on the inner wall of the cutting table 56, the outer end surfaces of the second guide rod 54 are respectively and fixedly connected with a cylindrical pad, the cylindrical pad can be slidably connected on the inner wall of the cutting table 56, the cylindrical pad can prevent the second guide rod 54 from being separated from the cutting table 56, and the second spring 55 has an inward driving force for pushing the polishing pressing plate 53; when the cutting tables 56 move outwards, the corresponding polishing pressing plates 53, the second guide rods 54 and the like are driven to move outwards synchronously, when the two cutting tables 56 move outwards to the top end position, the corresponding two polishing pressing plates 53 move outwards to the top end position and are separated from contact, when the cutting plates 45 move downwards at this time, the section of the metal coil is contacted with the corresponding polishing pressing plates 53 and the polishing plates 47, and the polishing pressing plates 53 are extruded by the second springs 55 to tightly contact the metal coil and the polishing plates 47, so that polishing effect is improved.

The cutting seat 43 is slidably connected to the upper end surface of the main bottom plate 3, the front and rear end surfaces of the lower side of the cutting seat 43 are respectively and fixedly connected with extension seats, the inner walls of the extension seats are respectively and fixedly connected with driving pins 57, and driving grooves matched with the driving pins 57 are respectively formed in the inner sides of the upper end surfaces of the L-shaped driving plates 39.

As shown in fig. 9-10, the cutting seat 43 can slide back and forth on the upper end surface of the main bottom plate 3, the extension seat is used for supporting the driving pin 57, the driving pin 57 and the driving groove are installed and shaped as shown in fig. 9, the driving groove comprises a second transverse groove 58 and a wave groove 59, the second transverse groove 58 is aligned with the short chute 41 left and right, and the wave groove 59 is aligned with the short transverse groove 42 left and right; when the L-shaped driving plate 39 moves leftwards, the corresponding driving pin 57 is not moved forwards and backwards by the engagement of the second transverse groove 58 and the driving pin 57, namely, the corresponding cutting seat 43 is not moved forwards and backwards, and the intermittent stop is performed for a period of time at a designated position; when the L-shaped driving plate 39 moves leftwards to enable the driving pins 57 to enter the wave grooves 59, the L-shaped driving plate 39 moves leftwards continuously to enable the corresponding driving pins 57 and the cutting seat 43 to move forwards and backwards, and when the cutting seat 43 moves forwards and backwards reciprocally, the corresponding cutting table 56, the cutting plate 45 and the like are driven to move forwards and backwards reciprocally, so that the polishing plate 47 and the polishing pressing plate 53 polish the metal coil; under the engagement of the driving grooves and the driving pins 57 and the first track grooves and the long pins 40, when the L-shaped driving plate 39 moves leftwards, the corresponding cutting plate 45 can move downwards firstly, when the cutting plate 45 moves downwards, the metal coil is cut off, when the cutting plate 45 continues to move downwards to the bottom end position, the polishing plate 47 and the polishing pressing plate 53 are contacted with the section of the metal coil, at the moment, the cutting plate 45 moves downwards to the bottom end position, at the moment, the L-shaped driving plate 39 continues to move leftwards, the corresponding long pins 40 enter the inner wall of the short transverse grooves 42, namely, the cutting plate 45 does not move downwards any more and stops intermittently at the designated position, the corresponding driving pins 57 enter the inner wall of the wave grooves 59, and the cutting seat 43, the cutting table 56, the cutting plate 45 and the like are made to reciprocate leftwards and rightwards to oscillate, so that the end surface of the metal coil is polished; when the L-shaped driving plate 39 moves rightwards, each part can be reset, and the description is omitted.

The middle part of the upper end surface of the auxiliary base is provided with a rotatable disc 5, the front side and the rear side of the upper end surface of the auxiliary base plate 1 are respectively fixedly connected with a blanking seat 8, the inner wall of the center of the metal coil is provided with a winding roller 9, the upper end of the blanking seat 8 is respectively provided with a pressing block 14 matched with the winding roller 9, and the disc 5 can form a structure that the pressing block 14 moves outwards to detach the winding roller 9 when rotating.

As shown in fig. 3-4, the metal foil is uniformly wound on the winding roller 9, the upper end of the blanking seat 8 is provided with an arc groove, the winding roller 9 is placed on the inner wall of the arc groove, the winding roller 9 can rotate on the inner wall of the arc groove, the installation and the shape of the pressing block 14 are as shown in fig. 4, and when the pressing block 14 is at the innermost end, the pressing block 14 can limit the upward movement of the winding roller 9, so that the winding roller 9 is prevented from being separated from the arc groove; when the disc 5 rotates, the corresponding two pressing blocks 14 can be driven to move outwards, and when the pressing blocks 14 move outwards to the top end position, limiting and blocking are not carried out on the winding roller 9 any more, and at the moment, the winding roller 9 can be removed and replaced.

The non-centre of a circle department of disc 5 lower extreme surface articulates there are two centrosymmetric first connecting rod 6, and two first connecting rod 6 outside ends are articulated respectively have with unloading seat 8 sliding connection's pull rod 7, briquetting 14 sliding connection respectively in unloading seat 8 upper end surface, and both sides respectively rigid coupling has first guide arm 11 about two unloading seat 8 outside terminal surface, all sliding connection has a roof 10 on two first guide arm 11 surfaces, briquetting 14 rigid coupling respectively on corresponding roof 10, still overlaps respectively on the first guide arm 11 surface has with roof 10 matched with first spring 12.

As shown in fig. 3-4, the upper end of the disc 5 is coaxially and fixedly connected with a first handle 4, the first handle 4 is convenient for driving the disc 5 to rotate, when the first handle 4 is driven to rotate, the disc 5 can be driven to rotate, and the disc 5 is rotationally connected to the sub-base plate 1 through a rotating shaft; the pull rod 7 penetrates through the corresponding blanking seat 8 and can be connected to the inner wall of the blanking seat 8 in a front-back sliding manner; the top plate 10 can be connected on the outer surface of the first guide rod 11 in a front-back sliding way, a first baffle 13 is fixedly connected on the outer end surface of the first guide rod 11, one end of a first spring 12 is fixedly connected on the first baffle 13, the other end of the first spring 12 is fixedly connected on the top plate 10, the first spring 12 always has inward driving force on the top plate 10, so that the top plate 10 and a pressing block 14 have always inward driving force, namely the pressing block 14 is at the innermost end in a normal state, and the pressing block 14 can be connected on the upper end surface of the blanking seat 8 in a front-back sliding way; when the first handle 4 is driven, the corresponding disc 5 can be driven to rotate, when the disc 5 rotates, the inner ends of the corresponding two first connecting rods 6 are driven to rotate circumferentially, when the outer ends of the first connecting rods 6 are driven to move outwards, the pull rods 7 are driven to move outwards, when the pull rods 7 move outwards, the top plate 10 is driven to move outwards, the first springs 12 are compressed, and the pressing blocks 14 are driven to move outwards, so that the winding roller 9 is not blocked any more when the pressing blocks 14 move outwards, and after the first handle 4 is released, all parts can be reset to an initial state under the elasticity of the first springs 12.

Two U-shaped seats 21 are fixedly connected to the left and right sides of the upper end surface of the main bottom plate 3 respectively, the conveying mechanisms are respectively arranged on the inner walls of the corresponding two U-shaped seats 21, the upper end of the main bottom plate 3 is also provided with a rotatable bidirectional threaded rod 15, and a structure that the auxiliary bottom plate 1 moves rightwards and the conveying mechanisms move downwards to enable the device to be folded can be formed when the bidirectional threaded rod 15 rotates.

As shown in fig. 5-6, the U-shaped seat 21 is used for supporting a conveying mechanism corresponding to limit, the front and rear ends of the outer surface of the bidirectional threaded rod 15 are respectively and fixedly connected with bearing seats, the bottom ends of the bearing seats are respectively and fixedly connected with the upper end surface of the main bottom plate 3, and the limit bidirectional threaded rod 15 can only rotate; the upper end surface of the main bottom plate 3 is fixedly connected with a motor, the bidirectional threaded rod 15 is fixedly connected with the output end of the motor, and the motor is used for providing a rotating force for the bidirectional threaded rod 15; when the bidirectional threaded rod 15 rotates, the corresponding auxiliary bottom plate 1 can be driven to move rightwards, and the conveying mechanism moves downwards, so that the device is in a folded state, and does not occupy space when in idle storage.

The conveying mechanism further comprises a U-shaped frame 22, a first motor 27 is fixedly connected to one side end surface of the U-shaped frame 22 respectively, a first rotating shaft 28 is fixedly connected to the output end of the first motor 27 respectively, a first bevel gear 29 is connected to the upper end of the outer surface of the first rotating shaft 28 in a sliding manner respectively, a second bevel gear 30 is meshed to the upper end of the first bevel gear 29 respectively, an inner seat 35 is also connected to the inner wall of the U-shaped frame 22 in a sliding manner respectively, the driving rollers respectively comprise a first driving roller 33 and a second driving roller 34, the first driving rollers 33 are respectively connected to the inner wall of the corresponding inner seat 35 in a rotating manner and are fixedly connected with a corresponding third bevel gear 31 in a coaxial manner, a fourth bevel gear 32 is meshed to the lower end of the third bevel gear 31 respectively, and the second driving rollers 34 are respectively connected to the inner wall of the lower end of the corresponding U-shaped frame 22 in a rotating manner and are fixedly connected with a corresponding fourth bevel gear 32 in a coaxial manner; the inner walls of the upper ends of the inner seats 35 are respectively and rotatably connected with first threaded rods 36, and the first threaded rods 36 are respectively and threadedly connected with the inner walls of the corresponding U-shaped frames 22.

As shown in fig. 7, the upper ends of the outer surfaces of the first threaded rods 36 are fixedly connected with second handles 37 respectively, and the second handles 37 are used for conveniently driving the first threaded rods 36 to rotate; the first motor 27 is used for providing a rotating force for the first rotating shaft 28, and is not described in detail in the prior art; bearing seats are respectively and rotatably connected to the outer surfaces of the first rotating shafts 28, the bottom ends of the bearing seats are respectively and fixedly connected to the inner walls of the U-shaped frames 22, and the first rotating shafts 28 can only rotate in a limiting manner; the first bevel gear 29 and the first rotating shaft 28 are in spline connection, when the first rotating shaft 28 rotates, the corresponding first bevel gear 29 can be driven to rotate, and the first bevel gear 29 can move up and down on the outer surface of the first rotating shaft 28; the lower ends of the outer surfaces of the first bevel gears 29 are respectively and rotatably connected with right-angle bearing seats, the other ends of the right-angle bearing seats are respectively and rotatably connected with the second bevel gears 30, and the first bevel gears 29 and the second bevel gears 30 can be limited to be always in a meshed state through the right-angle bearing seats and cannot be separated; the inner seat 35 is connected to the inner wall of the U-shaped frame 22 in an up-down sliding manner; under the threaded connection of the first threaded rod 36 and the U-shaped frame 22, when the first threaded rod 36 rotates, the inner seat 35, the first driving roller 33, the first bevel gear 29 and the second bevel gear 30 can be driven to move upwards or downwards, the distance between the first driving roller 33 and the second driving roller 34 can be adjusted according to the thickness of the metal coil, the first driving roller 33 and the second driving roller 34 can be contacted with the metal coil and move when rotating, and when the first threaded rod 36 does not rotate, the positions of the corresponding inner seat 35 and the corresponding first driving roller 33 are limited and fixed due to the fact that the U-shaped frame 22 is in threaded connection, even if the distance between the first driving roller 33 and the second driving roller 34 is fixed; the first driving roller 33 and the inner wall of the second bevel gear 30 are coaxially and fixedly connected with a rotating shaft, the rotating shaft is rotatably connected with the inner wall of the inner seat 35, the center of the second driving roller 34 and the center of the fourth bevel gear 32 are coaxially and fixedly connected with the rotating shaft, and the rotating shaft is rotatably connected with the inner wall of the U-shaped frame 22; when the first motor 27 is driven, the first bevel gear 29, the second bevel gear 30, the third bevel gear 31, the fourth bevel gear 32, the first driving roller 33 and the second driving roller 34 can be driven to synchronously rotate, so that the metal coil moves, when the second handle 37 is driven, the first threaded rod 36 can be driven to rotate, when the first threaded rod 36 rotates, the inner seat 35, the first driving roller 33 and the like can be driven to move upwards or downwards, and the distance between the two driving rollers can be adjusted according to the thickness of the metal coil.

The front end and the rear end of the left side of the upper end surface of the main bottom plate 3 are respectively hinged with a scissor type expansion bracket 17, the outer sides of the left ends of the two scissor type expansion brackets 17 are respectively hinged on the auxiliary bottom plate 1, the inner sides of the left ends of the two scissor type expansion brackets 17 are respectively connected with the auxiliary bottom plate 1 in a sliding mode, the inner sides of the right ends of the two scissor type expansion brackets 17 are respectively hinged with a threaded cylinder 16 in threaded connection with a bidirectional threaded rod 15, the front side and the rear side of the upper end surface of the auxiliary bottom plate 1 are respectively fixedly connected with a guide plate 20 in sliding connection with the main bottom plate 3, the U-shaped brackets 22 are respectively connected with the inner walls of corresponding U-shaped seats 21 in a sliding mode, the guide plates 20 are respectively provided with special-shaped grooves, the inner walls of the special-shaped grooves are respectively meshed with first sliding pins 23, and the first sliding pins 23 are respectively fixedly connected on the corresponding U-shaped brackets 22.

As shown in fig. 5-6, the guide plate 20 can be slidably connected on the upper end surface of the main bottom plate 3, the scissor type expansion bracket 17 and the bidirectional threaded rod 15 are installed and shaped as shown in fig. 5, threads with the same thread pitch and different rotation directions at the two ends are respectively arranged at the left and right ends of the outer surface of the bidirectional threaded rod 15, and when the bidirectional threaded rod 15 rotates, the corresponding two threaded cylinders 16 can synchronously move inwards or outwards; the inner side of the left end of the scissor type expansion bracket 17 is respectively provided with a limiting pin 19, the limiting pins 19 are respectively connected on the upper end surface of the auxiliary bottom plate 1 in a front-back sliding way, namely, the inner side of the left end of the limiting scissor type expansion bracket 17 can only slide back and forth on the auxiliary bottom plate 1, the inner side of the right end of the scissor type expansion bracket 17 is respectively hinged with a limiting seat 18, the limiting seats 18 are respectively connected on the upper end surface of the main bottom plate 3 in a front-back sliding way, and the inner side of the right end of the limiting scissor type expansion bracket 17 can only move back and forth; the U-shaped frames 22 are respectively connected to the inner wall of the U-shaped seat 21 in an up-down sliding way, the front end and the rear end of the inner side end surfaces of the two U-shaped frames 22 are respectively fixedly connected with a connecting rod 26, and the connecting rods 26 are used for driving the two U-shaped frames 22 to synchronously move or move downwards; the installation and the shape of the guide plate 20, the special-shaped sliding groove and the first sliding pin 23 are as shown in fig. 6, the special-shaped sliding groove comprises a long chute 24 and a long transverse groove 25, when the auxiliary bottom plate 1 and the guide plate 20 move rightwards to close the device, the first sliding pin 23 is not moved downwards under the engagement with the long transverse groove 25, and when the guide plate 20 moves rightwards to enable the first sliding pin 23 to enter the long chute 24, the guide plate 20 continues to move rightwards to enable the corresponding first sliding pin 23 and the U-shaped frame 22 to move downwards, namely the conveying mechanism moves downwards to be folded; when the bidirectional threaded rod 15 rotates, the corresponding threaded cylinder 16 can be driven to synchronously move inwards or outwards, so that the corresponding scissor type expansion bracket 17 folds inwards or outwards, namely the corresponding sub-bottom plate 1 is driven to move leftwards or rightwards, the sub-bottom plate 1 moves leftwards or rightwards, the corresponding guide plate 20 is driven to move leftwards or rightwards, namely the corresponding sub-bottom plate 1 moves rightwards, the conveying mechanism can be downwards moved, the device is in a folded state, and the conveying mechanism can be upwards moved when the sub-bottom plate 1 moves leftwards, so that the device is in an unfolded state; the device has a self-locking function under the threaded connection of the bidirectional threaded rod 15 and the threaded cylinder 16, namely, the device can be in a stable state when being unfolded or folded; under the meshing of the long transverse groove 25 and the long chute 24 with the first sliding pin 23, when the device is unfolded leftwards, namely when the corresponding sub-bottom plate 1 moves leftwards, under the meshing of the long chute 24 and the first sliding pin 23, the device can be unfolded quickly, namely the corresponding conveying mechanism moves upwards quickly, when the guide plate 20 moves forwards to enable the first sliding pin 23 to enter the inner wall of the long transverse groove 25, namely the corresponding conveying mechanism moves upwards to the topmost state, the sub-bottom plate 1 does not drive the conveying mechanism to move upwards any more when continuing to move leftwards, and at the moment, the corresponding position of the sub-bottom plate 1 can be adjusted according to the size of a metal coil, so that the occupied space of the device can be reduced when in use.

When the metal coil cutting machine is used, one end of the metal coil passes through the two driving rollers, the metal coil can be unfolded for a specified length when the driving rollers rotate, the metal coil passes through the two groups of driving rollers through the two conveying mechanisms, and the metal coil can be unfolded when the conveying mechanisms work, namely the two groups of rotating rollers rotate, so that the metal coil moves along a specified position, namely the metal coil is unfolded and moved to one side at the lower end position of the cutting plate 45; through the cutting device, when the L-shaped driving plate 39 moves leftwards, the cutting plate 45 can be made to move downwards to cut the metal coil instead of manually cutting by workers, and the cutting plate 45 moves back and forth after moving to the bottom end, so that the cut metal foil can be polished, and the workers are prevented from being injured by the cutting plate during construction; the workman can cut the material according to required length to can evenly polish to the metal foil again after drawing materials, prevent deckle edge stabbing the user, whole substitution manual operation, use manpower sparingly resource, safe and reliable.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the invention. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions, without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims

1. The utility model provides a metal foil cutting device for electromechanical engineering, includes main bottom plate (3), its characterized in that: the front end of the main bottom plate (3) is provided with a sub bottom plate (1), and a detachable metal coil is arranged on the sub bottom plate (1); conveying mechanisms matched with the metal coil are respectively arranged on two sides of the upper end of the main bottom plate (3), each conveying mechanism comprises two rotatable driving rollers, and the driving rollers can form a structure that the metal coil is unfolded and moved along a designated path when rotating; the middle part of the upper end of the main bottom plate (3) is provided with a cutting device, the cutting device comprises two L-shaped driving plates (39) capable of synchronously moving, the cutting device further comprises a cutting plate (45), and when the L-shaped driving plates (39) move leftwards, the cutting plate (45) can form a structure for cutting a metal coil by moving downwards and reciprocating back and forth after moving to the bottom end so as to polish a metal foil.

2. A metal foil cutting device for electro-mechanical engineering according to claim 1, wherein: the middle part of the upper end surface of the main bottom plate (3) is provided with a cutting seat (43), the left side and the right side of the upper end surface of the cutting seat (43) are respectively provided with a cutting table (56) matched with a cutting plate (45), the front end surface and the rear end surface of the cutting seat (43) are respectively fixedly connected with side seats (44), the cutting plate (45) is respectively and slidably connected with the inner walls of the two side seats (44), the front end surface and the rear end surface of the cutting plate (45) are respectively fixedly connected with a long pin (40), and the lower end of the cutting plate (45) is provided with a cutting edge (46); the front side and the rear side of the upper end surface of the main bottom plate (3) are respectively fixedly connected with a driving telescopic rod (38), L-shaped driving plates (39) are respectively fixedly connected to the corresponding driving telescopic rods (38), the L-shaped driving plates (39) are respectively and slidably connected to the front side and the rear side of the upper end surface of the main bottom plate (3), and the upper ends of the L-shaped driving plates (39) are respectively provided with first track grooves matched with the long pins (40).

3. A metal foil cutting device for electro-mechanical engineering according to claim 2, wherein: cutting board (56) sliding connection is in cutting seat (43) upper end surface left and right sides, both sides are respectively rigid coupling around cutting board (45) both ends surface has leading truck (48), both ends surface rigid coupling has guide pin (52) around cutting board (56) respectively, set up respectively on leading truck (48) with guide pin (52) matched with guide way, both ends surface is equipped with respectively about cutting board (45) and polishes board (47), two cutting board (56) inner walls are equipped with respectively and can inwards remove clamp plate (53) of polishing.

4. A metal foil cutting device for electro-mechanical engineering according to claim 3, wherein: the upper side and the lower side of the inner walls of the left end and the right end of the cutting table (56) are respectively and slidably connected with a second guide rod (54), the polishing pressing plates (53) are respectively and fixedly connected to the inner side end faces of the corresponding second guide rods (54), and second springs (55) matched with the polishing plates (47) are respectively sleeved on the outer surfaces of the second guide rods (54).

5. A metal foil cutting device for electro-mechanical engineering according to claim 3, wherein: the cutting seat (43) is slidably connected to the upper end surface of the main bottom plate (3), the front end surface and the rear end surface of the lower side of the cutting seat (43) are fixedly connected with extension seats respectively, the inner walls of the extension seats are fixedly connected with driving pins (57) respectively, and driving grooves matched with the driving pins (57) are formed in the inner sides of the upper end surfaces of the L-shaped driving plates (39) respectively.

6. A metal foil cutting device for electro-mechanical engineering according to claim 1, wherein: the middle part of the upper end surface of the auxiliary base is provided with a rotatable disc (5), the front side and the rear side of the upper end surface of the auxiliary base plate (1) are respectively fixedly connected with a blanking seat (8), the inner wall of the center of the metal coil is provided with a winding roller (9), the upper end of the blanking seat (8) is respectively provided with a pressing block (14) matched with the winding roller (9), and the disc (5) can form a structure that the pressing block (14) moves outwards to detach the winding roller (9) when rotating.

7. A metal foil cutting device for electro-mechanical engineering according to claim 6, wherein: the utility model discloses a disc (5) lower extreme surface non-centre of a circle department articulates there are two centrosymmetric first connecting rod (6), and two first connecting rod (6) outside ends are articulated respectively have pull rod (7) with unloading seat (8) sliding connection, briquetting (14) sliding connection respectively in unloading seat (8) upper end surface, and both sides have first guide arm (11) respectively about two unloading seat (8) outside terminal surface rigid coupling respectively, and equal sliding connection has a roof (10) on two first guide arm (11) surface, briquetting (14) rigid coupling respectively on roof (10) that correspond, still overlap respectively on first guide arm (11) surface have with roof (10) matched with first spring (12).

8. A metal foil cutting device for electro-mechanical engineering according to claim 1, wherein: two U-shaped seats (21) are fixedly connected to the left side and the right side of the upper end surface of the main bottom plate (3) respectively, the conveying mechanisms are respectively arranged on the inner walls of the corresponding two U-shaped seats (21), a rotatable bidirectional threaded rod (15) is further arranged at the upper end of the main bottom plate (3), and a structure that the auxiliary bottom plate (1) moves rightwards and the conveying mechanisms move downwards to enable the device to be folded can be formed when the bidirectional threaded rod (15) rotates.

9. A metal foil cutting device for electro-mechanical engineering according to claim 8, wherein: the conveying mechanism further comprises U-shaped frames (22), a first motor (27) is fixedly connected to one side end face of each U-shaped frame (22), a first rotating shaft (28) is fixedly connected to the output end of each first motor (27), a first bevel gear (29) is slidably connected to the upper end of the outer surface of each first rotating shaft (28), a second bevel gear (30) is meshed with the upper end of each first bevel gear (29), an inner seat (35) is slidably connected to the inner wall of each U-shaped frame (22), each driving roller comprises a first driving roller (33) and a second driving roller (34), the first driving rollers (33) are rotatably connected to the inner wall of the corresponding inner seat (35) and are coaxially fixedly connected with a corresponding third bevel gear (31), a fourth bevel gear (32) is meshed with the lower end of each third bevel gear (31), and the second driving rollers (34) are rotatably connected to the inner wall of the lower end of the corresponding U-shaped frame (22) and are coaxially fixedly connected with the corresponding fourth bevel gear (32); the inner wall of the upper end of the inner seat (35) is respectively connected with a first threaded rod (36) in a rotating way, and the first threaded rods (36) are respectively connected with the inner wall of the corresponding U-shaped frame (22) in a threaded way.

10. A metal foil cutting device for electro-mechanical engineering according to claim 9, wherein: the utility model discloses a novel structure of a double-sided hydraulic lifting device, including main bottom plate (3), upper end surface left side front and back both ends are articulated respectively have scissor type expansion brackets (17), two scissor type expansion brackets (17) left end outsides are articulated respectively on auxiliary bottom plate (1), two scissor type expansion brackets (17) left end insides are sliding connection respectively on auxiliary bottom plate (1), two scissor type expansion brackets (17) right-hand member insides are articulated respectively have screw thread section of thick bamboo (16) with two-way threaded rod (15) threaded connection respectively, both sides still fixedly connected respectively have deflector (20) with main bottom plate (3) sliding connection around auxiliary bottom plate (1) upper end surface, U-shaped frame (22) sliding connection has offered the special-shaped groove on deflector (20) respectively at U-shaped seat (21) inner wall that corresponds respectively, special-shaped groove inner wall has meshed first slide pin (23) respectively, first slide pin (23) rigid coupling is on corresponding U-shaped frame (22) respectively.