CN112570804A

CN112570804A - Electromechanical device for rounding metal sheet

Info

Publication number: CN112570804A
Application number: CN202110020394.7A
Authority: CN
Inventors: 付岩强
Original assignee: Shanghai Nanxiao Intelligent Technology Co ltd
Current assignee: Shanghai Nanxiao Intelligent Technology Co ltd
Priority date: 2021-01-07
Filing date: 2021-01-07
Publication date: 2021-03-30
Anticipated expiration: 2041-01-07
Also published as: CN112570804B

Abstract

The invention discloses electromechanical equipment for rounding a metal sheet, which comprises an engine body, wherein a cutting cavity is arranged in the engine body, a feeding mechanism is arranged at the upper part of the cutting cavity, a support mechanism is arranged at the lower part of the cutting cavity, and a cutting mechanism is arranged at the left part of the cutting cavity.

Description

Electromechanical device for rounding metal sheet

Technical Field

The invention relates to the technical field of electromechanical equipment, in particular to electromechanical equipment for rounding a metal sheet.

Background

When the metal plate is cut and formed, a general device can drive a cutting tool to move along the cutting edge of the metal plate so as to process the metal plate, the whole volume of the device needs to be larger than the maximum range of the processed shape, so a mode of rotating a raw material by fixing a cutter to cut the raw material can be adopted, the raw material used by the cutting mode needs to be the size which is convenient for the device to move and can not interfere with the device, and the large metal plate can not be directly used for cutting.

Disclosure of Invention

In view of the technical shortcomings, the invention provides an electromechanical device for rounding a metal sheet, which can overcome the defects.

The invention relates to electromechanical equipment for rounding a metal sheet, which comprises an engine body, wherein a cutting cavity is arranged in the engine body, a feeding mechanism is arranged at the upper part of the cutting cavity, a support mechanism is arranged at the lower part of the cutting cavity, a cutting mechanism is arranged at the left part of the cutting cavity, the support mechanism comprises a lifting seat which is arranged at the lower part of the cutting cavity in a vertical sliding manner, a rotating seat is rotatably arranged in the lifting seat, a driving spline sleeve is fixedly arranged on the rotating seat in a self-testing manner, a lifting spring is connected between the rotating seat and the bottom surface of the cutting cavity, two pressure rods are fixedly arranged at the lower side of the lifting seat in a bilateral symmetry manner, two transmission cavities which are arranged at the lower wall of the cutting cavity in a bilateral symmetry manner are arranged in the lower wall of the cutting cavity, the lower ends of the pressure rods are vertically slidably, the middle part of the conversion lever close to the pressure rod is rotatably arranged in the transmission cavity, a lifting pile is slidably arranged in the other end of the conversion lever, the lifting pile is fixedly arranged on the front side of the right end of the reversing lever, the middle part of the reversing lever is rotatably arranged in the transmission cavity, a connecting pile is slidably arranged at the other end of the reversing lever, the connecting pile is fixedly arranged on the front side of the lower end of a pull rod, the pull rod is vertically and slidably arranged in the transmission cavity and the lower part of the cutting cavity, the lower end of the pull rod is provided with a resistance spring connected with the bottom surface of the transmission cavity, the upper end of the pull rod is fixedly provided with a backing plate, the left wall and the right wall of the lower part of the cutting cavity are symmetrically provided with two supporting blocks in a vertical sliding manner, the lower sides of the supporting blocks are provided with supporting springs connected with the bottom, the cutting device is characterized in that a push-out spring connected with the machine body is arranged on the left side of the push block, a bolt which is arranged in the left part of the cutting cavity in a front-back sliding mode is arranged on the rear side of the push block, a plug-in spring connected with the machine body is arranged on the rear side of the bolt, a slot into which the bolt is inserted is formed in the rear portion of the push block, and a push block is fixedly arranged on the upper side of the supporting block.

Preferably, the feeding mechanism comprises a lower pressing plate which is vertically and slidably installed on the upper portion of the cutting cavity, a lower pressing connecting rod is hinged to the upper side of the middle of the lower pressing plate, the left end of the lower pressing connecting rod is hinged to the lower end of a threaded sliding block, the threaded sliding block is horizontally and slidably installed in the upper wall of the cutting cavity, the threaded sliding block is installed on a threaded shaft in a threaded mode, and the threaded shaft extends leftwards and rightwards and is rotatably installed in the upper wall of the cutting cavity.

Preferably, the cutting mechanism including from top to bottom slidable mounting in the cutting piece in the cutting chamber left wall, the cutting piece downside be provided with the buffer spring that the organism is connected, slidable mounting has linking slider from top to bottom in the cutting piece left part below, linking slider upside be provided with the linking spring that the cutting piece is connected, rotate in the linking slider and install the output spline housing, fixed mounting has linking bevel gear on the output spline housing, rotate in the cutting piece and install the output shaft that extends right, output shaft left end fixed mounting can with linking bevel gear's output bevel gear, output shaft right-hand member fixed mounting has the saw wheel.

Preferably, a motor is arranged in the lower wall of the left part of the cutting cavity, a power shaft is connected to the left side of the motor, a power bevel gear is fixedly mounted on the power shaft, a transmission bevel gear capable of being meshed with the power bevel gear is arranged on the upper side of the power bevel gear, the transmission bevel gear is fixedly mounted at the lower end of a transmission spline sleeve, the upper end of the transmission spline sleeve is rotatably mounted in a separation sliding block, the separation sliding block is vertically and slidably mounted in the left wall of the cutting cavity, and a separation spring connected with the machine body is arranged on the upper side of the separation sliding block.

Preferably, the transmission integral key shaft that extends from top to bottom is installed in the rotation in the cutting chamber left wall, the spline is installed on the transmission integral key shaft the transmission integral key case with the output integral key case, transmission integral key shaft lower extreme is connected with the driving spline shaft through belt drive, the driving integral key shaft rotate install in rotate the seat below in the cutting chamber diapire, the driving integral key shaft can with driving integral key case splined connection, transmission integral key shaft upper end through bevel gear pair with threaded shaft connects.

Preferably, a pressing block is fixedly mounted on the lower side of the middle of the lower pressing plate, a driven rotating block is rotatably mounted at the lower end of the pressing block, a cutting knife is fixedly mounted on the lower side of the right portion of the lower pressing plate, a mounting block is fixedly mounted on the lower side of the rear portion of the lower pressing plate, a turning plate is rotatably mounted in the mounting block, and a feeding wheel is rotatably mounted in the right wall of the cutting cavity.

The beneficial effects are that: when the metal plate is cut, a raw material can be separated from the whole metal plate, then the middle of the metal plate is clamped and then driven to rotate, the saw wheel is enabled to cut the metal plate into round plates with equal size, when the metal plate is sent into a cutting cavity, a base plate at the lower part of the cutting cavity is equal in height to a rotating seat, the phenomenon that the edge of the metal plate falls down and cannot be clamped correctly can be prevented, and the base plate descends below the rotating seat after being pressed down, so that the working space of the saw wheel is saved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic diagram of an electromechanical device for rounding a metal sheet according to the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

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

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

fig. 5 is a schematic diagram of the structure of D-D in fig. 1.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-5, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The electromechanical device for rounding a metal sheet comprises a machine body 10, wherein a cutting cavity 11 is arranged in the machine body 10, a feeding mechanism capable of cutting off a standby material from a raw material plate and fixing the standby material is arranged at the upper part of the cutting cavity 11, a support mechanism capable of placing the standby material and driving the standby material to rotate is arranged at the lower part of the cutting cavity 11, a cutting mechanism capable of cutting a rotating metal plate into a round shape by using a saw wheel is arranged at the left part of the cutting cavity 11, the support mechanism comprises a lifting seat 33 which is vertically and slidably arranged at the lower part of the cutting cavity 11, a rotating seat 31 is rotatably arranged in the lifting seat 33, a driving spline sleeve 30 is fixedly arranged on the rotating seat 31 by self-measuring, a lifting spring 32 is connected between the rotating seat 31 and the bottom surface of the cutting cavity 11, two pressure rods 34 are symmetrically and fixedly arranged at the left side and the lower side of, the lower wall of the cutting cavity 11 is provided with two bilaterally symmetrical transmission cavities 12, the lower end of a pressure lever 34 is vertically and slidably mounted in the transmission cavity 12, the front side of the lower end of the pressure lever 34 is fixedly provided with a pressure pile 35, the pressure pile 35 is slidably mounted at one end of a conversion lever 36, the middle part of the conversion lever 36 close to the pressure lever 34 is rotatably mounted in the transmission cavity 12, the other end of the conversion lever 36 is slidably mounted with a lifting pile 37, the lifting pile 37 is fixedly mounted at the front side of the right end of a reversing lever 38, the middle part of the reversing lever 38 is rotatably mounted in the transmission cavity 12, the other end of the reversing lever 38 is slidably mounted with a connecting pile 39, the connecting pile 39 is fixedly mounted at the front side of the lower end of a pull rod 40, the pull rod 40 is vertically and slidably mounted in the transmission cavity 12 and the lower part of the cutting cavity 11, the lower end of, a backing plate 42 is fixedly installed at the upper end of the pull rod 40, the backing plate 42 can prevent the metal plate from falling down when being conveyed leftwards in the cutting cavity 11, the backing plate 42 is equal to the rotating seat 31 in a normal state, when the rotating seat 31 is pressed down, the backing plate 42 is lower than the rotating seat 31, two supporting blocks 22 are symmetrically installed on the left and right walls of the lower part of the cutting cavity 11 in an up-and-down sliding mode, a supporting spring 23 connected with the bottom surface of the cutting cavity 11 is arranged on the lower side of the supporting block 22, a push block 20 is installed in the left part of the cutting cavity 11 in a left-and-right sliding mode, a push spring 21 connected with the machine body 10 is arranged on the left side of the push block 20, a plug pin 25 installed in the left part of the cutting cavity 11 in a front-and-back sliding mode is arranged on the rear side of the plug pin 25, a plug-in spring 26 connected with the machine body 10 is arranged, the upper side of the supporting block 22 is fixedly provided with a top block 24, and the top block 24 ascends to push the plugging spring 26 to slide backwards.

Advantageously, the feeding mechanism comprises a lower pressing plate 54 which is vertically and slidably mounted on the upper portion of the cutting cavity 11, a lower pressing link 53 is hinged on the upper side of the middle portion of the lower pressing plate 54, the left end of the lower pressing link 53 is hinged on the lower end of a threaded slider 52, the threaded slider 52 is horizontally and slidably mounted in the upper wall of the cutting cavity 11, the threaded slider 52 is threadedly mounted on a threaded shaft 51, and the threaded shaft 51 is horizontally and rotatably mounted in the upper wall of the cutting cavity 11 in an extending manner.

Beneficially, the cutting mechanism includes a cutting block 45 slidably mounted in the left wall of the cutting cavity 11 up and down, a buffer spring 61 connected to the machine body 10 is disposed on the lower side of the cutting block 45, an engaging slider 44 is slidably mounted on the lower side of the left portion of the cutting block 45 up and down, an engaging spring 46 connected to the cutting block 45 is disposed on the upper side of the engaging slider 44, an output spline housing 43 is rotatably mounted in the engaging slider 44, an engaging bevel gear 47 is fixedly mounted on the output spline housing 43, an output shaft 49 extending rightward is rotatably mounted in the cutting block 45, an output bevel gear 48 capable of meshing with the engaging bevel gear 47 is fixedly mounted on the left end of the output shaft 49, and a saw wheel 50 is fixedly mounted on the right end of the output shaft 49.

Beneficially, a motor 13 is arranged in the lower wall of the left portion of the cutting cavity 11, a power shaft 14 is connected to the left side of the motor 13, a power bevel gear 15 is fixedly mounted on the power shaft 14, a transmission bevel gear 16 capable of meshing with the power bevel gear 15 is arranged on the upper side of the power bevel gear 15, the transmission bevel gear 16 is fixedly mounted at the lower end of a transmission spline housing 17, the upper end of the transmission spline housing 17 is rotatably mounted in a separation slider 18, the separation slider 18 is slidably mounted in the left wall of the cutting cavity 11 up and down, a separation spring 19 connected with the machine body 10 is arranged on the upper side of the separation slider 18, and the push block 20 can push the separation slider 18 to slide down when sliding leftwards.

Beneficially, a transmission spline shaft 28 extending up and down is rotatably mounted in the left wall of the cutting cavity 11, the transmission spline shaft 28 is splined with the transmission spline housing 17 and the output spline housing 43, the lower end of the transmission spline shaft 28 is connected with a drive spline shaft 29 through belt transmission, the drive spline shaft 29 is rotatably mounted in the bottom wall of the cutting cavity 11 below the rotating base 31, the drive spline shaft 29 can be splined with the drive spline housing 30, and the upper end of the transmission spline shaft 28 is connected with the threaded shaft 51 through a bevel gear pair.

Advantageously, a pressing block 55 is fixedly mounted on the lower side of the middle of the lower pressing plate 54, a driven rotating block 56 is rotatably mounted at the lower end of the pressing block 55, the driven rotating block 56 can press the metal plate onto the rotating seat 31 and rotate along with the metal plate, a cutting knife 57 is fixedly mounted on the lower side of the right portion of the lower pressing plate 54, the cutting knife 57 can cut the metal plate entering the cutting cavity 11, the cutting block 45 can be pressed downwards by the left side of the lower pressing plate 54, a mounting block 58 is fixedly mounted on the lower side of the rear portion of the lower pressing plate 54, a turning plate 59 is rotatably mounted in the mounting block 58, the turning plate 59 can be turned upwards, a feeding wheel 60 is rotatably mounted in the right wall of the cutting cavity 11, and the metal plate can be fed into the cutting cavity 11 by the feeding wheel 60 from below.

In an initial state, a metal plate is inserted into the cutting cavity 11 and pushes the push block 20 to the left, the push-out spring 21 is compressed, the separation spring 19 is stretched, the transmission bevel gear 16 is meshed with the power bevel gear 15, the driving spline shaft 29 is not connected with the driving spline housing 30, the plug-in spring 26 is in a compressed state, and the engagement bevel gear 47 is not meshed with the output bevel gear 48;

at the start of operation, the motor 13 is started to rotate the power shaft 14, so that the transmission spline housing 17 is rotated by the meshing transmission of the power bevel gear 15 and the transmission bevel gear 16, so that the transmission spline shaft 28 is rotated by the spline connection, so that the threaded shaft 51 is rotated by the bevel gear meshing transmission, so that the threaded slider 52 is slid rightward by the threaded connection, so that the hold-down link 53 is rotated, so that the hold-down plate 54 is slid downward, so that the driven rotating block 56 is lowered by the press block 55 to be in contact with and hold down the metal plate, and the cut-off knife 57 cuts off the metal plate, and the mount block 58 is turned over and moved below the metal plate while passing through the metal plate, so that the driven rotating block 56 lowers the lifting base 33 to drive the press rod 34 to be lowered to drive the conversion lever 36 to rotate by the press pile 35, so that the reversing lever 38 is rotated by the pile 37, thereby driving the pull rod 40 to descend through the connecting pile 39, and the pull rod 40 descends to drive the press rod 34, thereby causing the backing plate 42 to descend to a position lower than the rotary seat 31, the support block 22 can be pressed down when the metal plate of the rotary seat 31 is pressed down, thereby driving the top block 24 to descend, thereby causing the plug pin 25 to slide under the action of the plugging spring 26 and be inserted into the slot 27, locking the push block 20, the driving spline housing 30 is connected with the driving spline shaft 29 after the rotary seat 31 descends to the bottom, thereby causing the driving spline shaft 28 to drive the driving spline shaft 29 to rotate through belt transmission, thereby causing the rotary seat 31 to rotate through the spline connection with the driving spline housing 30, thereby driving the metal plate to rotate, and also pressing the cutting block 45 downwards when the lower press plate 54 descends, thereby causing the engaging slide block 44 to be lifted, thereby causing the engaging bevel gear 47 to engage with the output bevel gear 48, thereby causing the driving spline housing 28 to drive the output spline housing, so that the output shaft 49 is driven to rotate by the meshing transmission of the engaging bevel gear 47 and the output bevel gear 48, and the saw wheel 50 is driven to rotate, thereby cutting the rotating metal plate.

When the cutting is completed, the motor 13 is reversed, so that the lower pressing plate 54 is lifted, the driving spline housing 30 is separated from the driving spline shaft 29, the engaging bevel gear 47 is separated from the output bevel gear 48, the supporting block 22 drives the ejector block 24 to lift when lifted, so that the plug pins 25 are pushed to slide backwards and be pulled out of the slots 27, the push block 20 is still blocked by the metal plate, the turning plate 59 is driven to lift when the lower pressing plate 54 is lifted, so that the rear side of the metal plate is driven to lift through the mounting block 58, the cut metal plate and the waste material slide forwards, and the push block 20 slides rightwards under the action of the push spring 21, so that the separating slide block 18 slides upwards under the action of the separating spring 19, and the transmission bevel gear 16 is separated from the power bevel gear 15.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. An electromechanical device for rounding a metal sheet comprises a machine body, and is characterized in that: a cutting cavity is arranged in the machine body, a feeding mechanism is arranged at the upper part of the cutting cavity, a support mechanism is arranged at the lower part of the cutting cavity, and a cutting mechanism is arranged at the left part of the cutting cavity;

the support mechanism comprises a lifting seat which is arranged at the lower part of the cutting cavity in a vertical sliding manner, a rotating seat is rotatably arranged in the lifting seat, a driving spline sleeve is fixedly arranged on the rotating seat in a self-testing manner, a lifting spring is connected between the rotating seat and the bottom surface of the cutting cavity, two pressure rods are fixedly arranged on the lower side of the lifting seat in a bilateral symmetry manner, two transmission cavities which are arranged in a bilateral symmetry manner are arranged in the lower wall of the cutting cavity, the lower ends of the pressure rods are vertically and slidably arranged in the transmission cavities, a pressure pile is fixedly arranged on the front side of the lower end of each pressure rod and is slidably arranged at one end of a conversion lever, the middle part of the conversion lever close to the pressure rods is rotatably arranged in the transmission cavities, a lifting pile is slidably arranged in the other end of the conversion lever, the lifting pile is fixedly, the other end of the reversing lever is slidably provided with a connecting pile, the connecting pile is fixedly arranged on the front side of the lower end of a pull rod, the pull rod is vertically slidably arranged in the transmission cavity and the lower part of the cutting cavity, the lower end of the pull rod is provided with a resistance spring connected with the bottom surface of the transmission cavity, the upper end of the pull rod is fixedly provided with a base plate, the left wall and the right wall of the lower part of the cutting cavity are bilaterally and symmetrically provided with two supporting blocks in an up-and-down sliding manner, the lower sides of the supporting blocks are provided with supporting springs connected with the bottom surface of the cutting cavity, the left part of the cutting cavity is provided with a push block in a left-and-right sliding manner, the left side of the push block is provided with a push spring connected with the machine body, the rear side of the push block is provided with a plug pin which is slidably arranged in, and the upper side of the supporting block is fixedly provided with a top block.

2. Electromechanical device for sheet metal rounding according to claim 1, characterized in that: the feeding mechanism comprises a lower pressing plate which is arranged on the upper portion of the cutting cavity in a vertically sliding mode, a lower pressing connecting rod is hinged to the upper side of the middle of the lower pressing plate, the left end of the lower pressing connecting rod is hinged to the lower end of a threaded sliding block, the threaded sliding block is arranged in the upper wall of the cutting cavity in a horizontally sliding mode, the threaded sliding block is installed on a threaded shaft in a threaded mode, and the threaded shaft extends left and right to be installed in the upper wall of the cutting cavity in a rotating mode.

3. Electromechanical device for sheet metal rounding according to claim 2, characterized in that: cutting mechanism including from top to bottom slidable mounting in cutting the cutting piece in the left wall of cutting chamber, the cutting piece downside be provided with the buffer spring that the organism is connected, slidable mounting has the linking slider about the cutting piece left part below, linking slider upside be provided with the linking spring that the cutting piece is connected, rotate in the linking slider and install the output spline cover, fixed mounting has linking bevel gear on the output spline cover, rotate in the cutting piece and install the output shaft that extends right, output shaft left end fixed mounting can with linking bevel gear meshed output bevel gear, output shaft right-hand member fixed mounting has the saw wheel.

4. Electromechanical device for sheet metal rounding according to claim 3, characterized in that: the cutting machine is characterized in that a motor is arranged in the lower wall of the left part of the cutting cavity, a power shaft is connected to the left side of the motor, a power bevel gear is fixedly mounted on the power shaft, a transmission bevel gear capable of being meshed with the power bevel gear is arranged on the upper side of the power bevel gear, the transmission bevel gear is fixedly mounted at the lower end of a transmission spline sleeve, the upper end of the transmission spline sleeve is rotatably mounted in a separation sliding block, the separation sliding block is vertically and slidably mounted in the left wall of the cutting cavity, and a separation spring connected with the machine body is arranged on.

5. Electromechanical device for sheet metal rounding according to claim 4, characterized in that: the utility model discloses a cutting chamber, including cutting chamber, transmission spline shaft, drive spline shaft upper spline and output spline housing, the transmission spline shaft lower extreme passes through belt drive and drive spline shaft connection in the cutting chamber left wall, drive spline shaft rotate install in rotate the seat below in the cutting chamber diapire, drive spline shaft can with drive spline housing splined connection, transmission spline shaft upper end through bevel gear pair with threaded shaft connects.

6. Electromechanical device for sheet metal rounding according to claim 5, characterized in that: the cutting device is characterized in that a pressing block is fixedly mounted on the lower side of the middle of the lower pressing plate, a driven rotating block is rotatably mounted at the lower end of the pressing block, a cutting knife is fixedly mounted on the lower side of the right portion of the lower pressing plate, a mounting block is fixedly mounted on the lower side of the rear portion of the lower pressing plate, a turning plate is rotatably mounted in the mounting block, and a feeding wheel is rotatably mounted in the right wall of the cutting cavity.