阅读说明：本技术 一种不锈钢固定式等离子切割装置 (Fixed plasma cutting device of stainless steel ) 是由 程沛芳 于 2019-11-19 设计创作，主要内容包括：本发明公开的一种不锈钢固定式等离子切割装置,包括壳体,所述壳体内设有工作腔,所述工作腔上侧内壁设有焊箱滑槽,所述焊箱滑槽上设有切割组件,所述切割组件包括滑动连接于所述焊箱滑槽上的焊箱滑块,设置于所述焊箱滑块下端的带齿焊箱,本发明采用了扇形齿轮,实现了切割步骤以及废料移除工序只需要一个动力源,采用了运输轮,实现了不锈钢待加工板按顺序到右侧进行切割工作,采用了反向齿轮、定序齿轮以及槽盘,实现了不同动作的实现顺序,改善了目前大部分不锈钢等离子切割装置在上料、去除多余废料,甚至是切割时都需要人工操作完成,这不仅浪费了大量的人力,而且质量也无法保障的现状。(The invention discloses a stainless steel fixed plasma cutting device, which comprises a shell, wherein a working cavity is arranged in the shell, a welding box chute is arranged on the inner wall of the upper side of the working cavity, a cutting assembly is arranged on the welding box chute, the cutting assembly comprises a welding box sliding block connected to the welding box chute in a sliding manner, and a toothed welding box arranged at the lower end of the welding box sliding block, the invention adopts a sector gear, only one power source is needed for realizing the cutting step and the waste material removing process, a transport wheel is adopted, the stainless steel plate to be processed is cut to the right side in sequence, a reverse gear, a sequencing gear and a fluted disc are adopted, the realizing sequence of different actions is realized, the material loading, the removal of redundant waste materials and even manual operation during cutting of most of the existing stainless steel plasma cutting devices are improved, and a large amount of manpower is wasted, and the quality cannot be guaranteed.)

1. A stainless steel fixed plasma cutting device comprises a shell, wherein a working cavity is arranged in the shell, a welding box sliding groove is formed in the inner wall of the upper side of the working cavity, and a cutting assembly is arranged on the welding box sliding groove;

the cutting assembly comprises a welding box sliding block, a toothed welding box and a welding head, wherein the welding box sliding block is connected to the welding box sliding groove in a sliding mode, the toothed welding box is arranged at the lower end of the welding box sliding block, the welding head is arranged at the lower end of the toothed welding box, and a connecting sliding block is arranged on the inner wall of the right side of the working cavity;

the connecting sliding block is provided with a waste removing assembly, the waste removing assembly comprises a connecting sliding chute which is connected to the connecting sliding block in a sliding mode, a horizontal support arranged at the left end of the connecting sliding chute and an adjustable baffle plate arranged on the horizontal support, and a conveying rotating shaft is rotatably connected to the inner wall of the rear side of the working cavity;

the material conveying assembly is arranged on the conveying rotating shaft and comprises a conveying wheel arranged on the conveying rotating shaft and conveying grooves which are arranged on the conveying wheel and are bilaterally symmetrical, conveying gears are arranged on the conveying rotating shaft, the inner wall of the front side of the working cavity is rotatably connected with a linkage rotating shaft, a linkage gear is arranged on the linkage rotating shaft, a grooved disc shaft is rotatably connected to the inner wall of the rear side of the working cavity, and a grooved disc is arranged on the grooved disc shaft;

be equipped with the motion sequencing subassembly on the slot dish, the motion sequencing subassembly include with the slot dish rotate connect and ninety degree annular array three sequencing pivot, set up in sequencing epaxial sequencing gear, with the slot dish rotate connect and be located the highest reverse pivot of sequencing pivot upper end, set up in reverse epaxial reverse gear.

2. The stationary plasma cutting apparatus of claim 1, wherein: the horizontal bracket is riveted with the adjustable baffle.

3. The stationary plasma cutting apparatus of claim 1, wherein: the utility model discloses a conveying belt wheel, including working chamber, conveyer belt wheel, working chamber rear side inner wall, conveyer belt wheel, working chamber rear side inner wall rotates and is connected with and is located the vice pivot of conveying on main pivot right side, the vice pivot front end tip of conveyer is equipped with conveyer belt wheel, conveyer belt wheel with be connected with the conveyer belt track between the conveyer belt wheel, just conveyer belt upper surface with the track upper surface is in on the same water flat line, be equipped with in the main pivot of conveyer belt wheel front end and with the conveying gear that linkage gear meshing is connected, on the working chamber front side inner wall with be equipped with on the working chamber rear side inner wall.

4. The stationary plasma cutting apparatus of claim 1, wherein: the cutting assembly further comprises a welding box spring connected between the inner wall of the front side of the working cavity and the welding box with the teeth.

5. The stationary plasma cutting apparatus of claim 1, wherein: the waste material removing assembly further comprises a rack arranged at the upper end of the connecting sliding groove, a rack spring is connected between the rack and the inner wall of the rear side of the working cavity, and the rack spring can drive the adjustable baffle plate to reset after the waste material is removed.

6. The stationary plasma cutting apparatus of claim 1, wherein: the material transportation subassembly still include with the driven rotation shaft of working chamber rear side inner wall rotation connection, be equipped with on the driven rotation shaft from the driving wheel, the working chamber rear side inner wall is embedded to have a motor, motor power is connected with the motor shaft, be equipped with the action wheel on the motor shaft, the action wheel with from driving wheel lug connection has the track, on the working chamber front side inner wall with be equipped with on the working chamber rear side inner wall symmetry and with the baffle of track upper surface parallel and level, just interval between the baffle is greater than the stainless steel and treats the processing board slightly.

7. The stationary plasma cutting apparatus of claim 1, wherein: the motion sequencing component further comprises a matching gear arranged at the rear end of the reversing gear, a sequencing transmission gear meshed with the matching gear is arranged on the sequencing rotating shaft, four driven grooves distributed in an annular array are arranged on the groove disc, a disc shaft is rotatably connected to the inner wall of the front side of the working cavity, a disc capable of being abutted against the groove disc is arranged at the tail end of the rear end of the disc shaft, an auxiliary belt wheel positioned on the front side of the disc is arranged on the disc shaft, a salient point capable of being in sliding connection with the driven grooves is arranged at the tail end of the rear end of the disc shaft, the groove disc can be driven to rotate ninety degrees when the salient point is in sliding connection with the driven grooves, an auxiliary transmission rotating shaft positioned on the upper side of the disc shaft is rotatably connected to the inner wall of the front end of the working cavity, an auxiliary transmission wheel is arranged on the auxiliary transmission rotating shaft, and a belt is connected between the auxiliary transmission, the auxiliary transmission rotating shaft is provided with a common gear which is positioned on the rear side of the auxiliary transmission wheel and is meshed and connected with the sequencing gear, the inner wall of the rear side of the working cavity is rotatably connected with a main belt wheel shaft positioned on the left side of the motor, the main belt wheel shaft is provided with a gear meshed and connected with the driving wheel, the main belt wheel shaft is provided with a main belt wheel positioned on the front side of the gear, and a transmission belt is connected between the main belt wheel and the auxiliary belt wheel.

Technical Field

The invention relates to the field of plasma cutting, in particular to a stainless steel fixed plasma cutting device.

Background

Plasma cutting, as a processing mode of stainless steel plates, is well appreciated by people in the industry due to the advantages of wide cutting field, high cutting speed, high efficiency, high precision and the like, and is generally applied to the current stainless steel processing industry at present, but most of the current stainless steel plasma cutting devices need manual operation for loading, removing redundant waste materials and even cutting, so that a large amount of manpower is wasted, the quality cannot be guaranteed, and the device capable of solving the problems is disclosed by the invention.

Disclosure of Invention

The technical problem is as follows:

at present most stainless steel plasma cutting device at material loading, get rid of unnecessary waste material, all need manual operation to accomplish even when cutting, this not only has wasted a large amount of manpowers, and the quality also can't be ensured in addition.

In order to solve the problems, the embodiment designs a fixed plasma cutting device for stainless steel, which comprises a shell, wherein a working cavity is arranged in the shell, a welding box chute is arranged on the inner wall of the upper side of the working cavity, a cutting assembly is arranged on the welding box chute, the cutting assembly comprises a welding box sliding block which is connected on the welding box chute in a sliding manner, a toothed welding box which is arranged at the lower end of the welding box sliding block, and a welding head which is arranged at the lower end of the toothed welding box, a connecting sliding block is arranged on the inner wall of the right side of the working cavity, a waste removing assembly is arranged on the connecting sliding block, the waste removing assembly comprises a connecting chute which is connected on the connecting sliding block in a sliding manner, a horizontal bracket which is arranged at the left end of the connecting chute, and an adjustable baffle which is arranged on the horizontal, the material transportation subassembly including set up in transportation change epaxial transport wheel, set up in transport wheel is last and bilateral symmetry's transportation groove be equipped with the transportation gear in the transportation pivot, the working chamber front side inner wall rotates and is connected with the linkage pivot, be equipped with the linkage gear in the linkage pivot, rotate on the working chamber rear side inner wall and connect slotted dish axle, the epaxial groove dish that is equipped with of groove dish, be equipped with the motion sequencing subassembly on the groove dish, the motion sequencing subassembly include with the groove dish rotate connect and ninety degrees three sequencing pivot that annular array distributes, set up in sequencing pivot epaxial sequencing gear, with the groove dish rotates to connect and is located the highest sequencing pivot upper end reverse rotation shaft, set up in reverse epaxial reverse gear.

Preferably, the horizontal bracket is riveted with the adjustable baffle.

Preferably, the working chamber rear side inner wall rotates and is connected with the main pivot of conveying, be equipped with the main belt wheel of conveying in the main pivot of conveying, the working chamber rear side inner wall rotates and is connected with and is located the vice pivot of conveying on main pivot right side, the vice pivot front end tip of conveying is equipped with the vice pulley of conveying, the vice pulley of conveying with be connected with the conveying track between the main belt wheel of conveying, just the conveying track upper surface with the track upper surface is in on the same water flat line, be equipped with in the main pivot of conveying be located the main belt wheel front end of conveying and with the conveying gear that the linkage gear meshing is connected, on the working chamber front side inner wall with be equipped with on the working chamber rear side inner wall symmetry and with the conveying baffle of conveying upper surface parallel and level.

The cutting assembly further comprises a welding box spring connected between the inner wall of the front side of the working cavity and the welding box with the teeth.

The waste removing assembly further comprises a rack arranged at the upper end of the connecting chute, a rack spring is connected between the rack and the inner wall of the rear side of the working cavity, and the rack spring can drive the adjustable baffle plate to reset after the waste is removed.

Wherein, the material transportation subassembly still include with the driven rotation shaft of working chamber rear side inner wall rotation connection, be equipped with on the driven rotation shaft from the driving wheel, the working chamber rear side inner wall is embedded to have a motor, motor power is connected with the motor shaft, be equipped with the action wheel on the motor shaft, the action wheel with from driving wheel lug connection has the track, on the working chamber front side inner wall with be equipped with on the working chamber rear side inner wall symmetry and with the baffle of track upper surface parallel and level, just interval between the baffle is greater than the stainless steel and treats the processing board slightly.

Wherein, the motion sequencing component also comprises a matching gear arranged at the rear end of the reverse gear, a sequencing transmission gear meshed with the matching gear is arranged on the sequencing rotating shaft, four driven grooves distributed in an annular array are arranged on the groove disc, the inner wall of the front side of the working cavity is rotationally connected with a disc shaft, the rear end of the disc shaft is provided with a disc capable of being abutted against the groove disc, an auxiliary belt wheel positioned at the front side of the disc is arranged on the disc shaft, a salient point capable of being in sliding connection with the driven groove is arranged on the disc shaft at the rear end of the disc shaft, and when the salient point is in sliding connection with the driven groove, the groove disc can be driven to rotate ninety degrees, an auxiliary transmission rotating shaft positioned at the upper side of the disc shaft is rotationally connected on the inner wall of the front end of the working cavity, an auxiliary transmission wheel is arranged on the auxiliary transmission rotating shaft, and a belt is connected between the auxiliary transmission wheel and, the auxiliary transmission rotating shaft is provided with a common gear which is positioned on the rear side of the auxiliary transmission wheel and is meshed and connected with the sequencing gear, the inner wall of the rear side of the working cavity is rotatably connected with a main belt wheel shaft positioned on the left side of the motor, the main belt wheel shaft is provided with a gear meshed and connected with the driving wheel, the main belt wheel shaft is provided with a main belt wheel positioned on the front side of the gear, and a transmission belt is connected between the main belt wheel and the auxiliary belt wheel.

The invention has the beneficial effects that: the invention adopts the sector gear, realizes that only one power source is needed for the cutting step and the waste material removing process, adopts the transport wheel, realizes that the stainless steel plate to be processed is cut to the right side in sequence, adopts the reverse gear, the sequencing gear and the trough plate, realizes the realization sequence of different actions, improves the current situation that most stainless steel plasma cutting devices need manual operation for loading, removing the redundant waste materials and even cutting, wastes a large amount of manpower, and cannot ensure the quality.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic diagram of the overall structure of a stainless steel stationary plasma cutting apparatus according to the present invention;

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

FIG. 3 is a schematic view of the structure in the direction "B-B" of FIG. 1;

FIG. 4 is a schematic view of the structure at the position where the mating gears are arranged;

FIG. 5 is a schematic view of the structure in the direction "D-D" of FIG. 1;

FIG. 6 is a schematic view of the structure in the direction "E-E" of FIG. 1;

FIG. 7 is an enlarged view schematically showing the structure of "F" in FIG. 1;

FIG. 8 is an enlarged view of the structure of "G" of FIG. 1;

fig. 9 is a schematic view of the structure in the "H" direction of fig. 8.

Detailed Description

The invention will now be described in detail with reference to fig. 1-9, for ease of description, the orientations described below will now be defined as follows: 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 invention relates to a stainless steel fixed plasma cutting device, which is mainly applied to the plasma cutting process, and the invention is further explained by combining the attached drawings of the invention:

the invention relates to a stainless steel fixed plasma cutting device, which comprises a shell 11, wherein a working cavity 12 is arranged in the shell 11, a welding box sliding groove 19 is arranged on the inner wall of the upper side of the working cavity 12, a cutting assembly 901 is arranged on the welding box sliding groove 19, the cutting assembly 901 comprises a welding box sliding block 20 connected to the welding box sliding groove 19 in a sliding manner, a toothed welding box 17 arranged at the lower end of the welding box sliding block 20, a welding head 21 arranged at the lower end of the toothed welding box 17, and a connecting sliding block 26 is arranged on the inner wall of the right side of the working cavity 12 to move the welding head 21 back and forth to realize the cutting function of a stainless steel plate to be processed, a waste removing assembly 902 is arranged on the connecting sliding block 26, the waste removing assembly 902 comprises a connecting sliding groove 27 connected to the connecting sliding block 26 in a sliding manner, a horizontal bracket 28 arranged at the left end of, remove adjustable baffle 29 backward, realize removing to the waste material, it is connected with transportation pivot 65 to rotate on the inner wall of working chamber 12 rear side, be equipped with material transportation subassembly 903 on transportation pivot 65, material transportation subassembly 903 including set up in transportation pivot 65 is last transport wheel 13, set up in transport wheel 13 is last and bilateral symmetry's transport tank 61, when the material gets into left side transport tank 61, rotate transport wheel 13, drive the material to the right side, realize the transportation of material, be equipped with transportation gear 14 on the transportation pivot 65, working chamber 12 front side inner wall rotates and is connected with linkage pivot 66, be equipped with linkage gear 32 on the linkage pivot 66, rotate on the inner wall of working chamber 12 rear side and connect slotted dish axle 52, be equipped with slotted dish 51 on the dish axle 52, be equipped with motion sequencing subassembly 904 on the slotted dish 51, motion sequencing subassembly 904 include with ninety degree annular array distribution's three sequencing pivot 47, go to rotate and ninety degree annular array distribution of slotted dish 51, The sequencing gear 46 is arranged on the sequencing rotating shaft 47, the reverse rotating shaft 48 is rotatably connected with the slot disc 51 and positioned at the upper end of the highest sequencing rotating shaft 47, and the reverse gear 50 is arranged on the reverse rotating shaft 48, so that the sequencing functions of different motions are realized by judging whether the three sequencing gears 46 are meshed with the linkage gear 32 or not and judging whether the reverse gear 50 is meshed with the transport gear 14 or not.

Advantageously, the horizontal support 28 is riveted to the adjustable flap 29 and the relative position of the adjustable flap 29 can be varied according to the cutting position.

Advantageously, a main transmission shaft 64 is rotatably connected to the inner wall of the rear side of the working chamber 12, a main transmission belt pulley 31 is provided on the main transmission shaft 64, a transmission auxiliary rotating shaft 63 positioned at the right side of the transmission main rotating shaft 64 is rotatably connected with the inner wall at the rear side of the working cavity 12, a secondary transmission pulley 30 is provided at the tip of the secondary transmission shaft 63, a transmission crawler 62 is connected between the secondary transmission pulley 30 and the primary transmission pulley 31, and the upper surface of the conveyor track 62 is level with the upper surface of the track 36, the transmission main rotating shaft 64 is provided with a transmission gear 15 which is positioned at the front end of the transmission main belt wheel 31 and is meshed and connected with the linkage gear 32, on the inner wall of working chamber 12 front side with be equipped with on the inner wall of working chamber 12 rear side symmetry and with the conveying baffle 16 of conveying track 62 upper surface parallel and level has ensured the stable transmission of stainless steel board of treating processing.

According to an embodiment, the cutting assembly 901 is described in detail below, the cutting assembly 901 further includes a welding box spring 18 connected between the inner wall of the front side of the working chamber 12 and the welding box 17 with teeth, and the welding box spring 18 can drive the welding head 21 to return after cutting, so as to facilitate the next cutting.

According to the embodiment, the waste removing assembly 902 is described in detail below, the waste removing assembly 902 further includes a rack 25 disposed at the upper end of the connecting chute 27, a rack spring 39 is connected between the rack 25 and the inner wall of the rear side of the working chamber 12, and the rack spring 39 can drive the adjustable baffle 29 to return after the waste is removed, so as to facilitate the next waste removal.

According to the embodiment, the following is explained in detail material transportation subassembly 903, material transportation subassembly 903 still include with the driven shaft 40 that the rear side inner wall of working chamber 12 rotates to be connected, be equipped with on the driven shaft 40 from driving wheel 37, the embedded motor 49 that has of rear side inner wall of working chamber 12, motor 49 power is connected with motor shaft 41, be equipped with action wheel 35 on the motor shaft 41, action wheel 35 with from driving wheel 37 lug connection have track 36, on the inner wall of working chamber 12 front side with be equipped with on the inner wall of working chamber 12 rear side the symmetry and with the baffle 38 of track 36 upper surface parallel and level, just interval between the baffle 38 is greater than the stainless steel and treats the processing board slightly, has ensured that the stainless steel can not excessively slide when treating the processing board transportation.

According to the embodiment, the following detailed description will be made on the motion sequencing assembly 904, the motion sequencing assembly 904 further includes a mating gear 42 disposed at the rear end of the reversing gear 50, a sequencing transmission gear 43 engaged with the mating gear 42 is disposed on the sequencing rotation shaft 47, four driven slots 68 distributed in an annular array are disposed on the slot disc 51, a disc shaft 57 is rotatably connected to the inner wall of the front side of the working chamber 12, a disc 54 capable of abutting against the slot disc 51 is disposed at the rear end of the disc shaft 57, a secondary pulley 55 disposed at the front side of the disc 54 is disposed on the disc shaft 57, a protruding point 53 capable of slidably connecting with the driven slot 68 is disposed on the disc 54 at the rear end of the disc shaft 57, and when the protruding point 53 is slidably connected with the driven slot 68, the slot disc 51 is driven to rotate ninety degrees, a secondary transmission rotation shaft 59 disposed at the upper side of the disc shaft 57 is rotatably connected to the inner wall of the front end of the working chamber 12, an auxiliary transmission wheel 60 is arranged on the auxiliary transmission rotating shaft 59, a belt 58 is connected between the auxiliary transmission wheel 60 and the main transmission wheel 56, a common gear 45 which is positioned at the rear side of the auxiliary transmission wheel 60 and is meshed and connected with the sequencing gear 46 is arranged on the auxiliary transmission rotating shaft 59, a main belt wheel shaft 69 which is positioned at the left side of the motor 49 is rotatably connected on the inner wall of the rear side of the working cavity 12, a gear 70 which is meshed and connected with the driving wheel 35 is arranged on the main belt wheel shaft 69, a main belt wheel 34 which is positioned at the front side of the gear 70 is arranged on the main belt wheel shaft 69, and a transmission belt 33 is connected between the main belt wheel 34 and the auxiliary belt wheel 55 to provide power for the motion.

The following will describe in detail the use steps of a stainless steel stationary plasma cutting apparatus herein with reference to fig. 1 to 8:

initial state: the sector gear 24 is in meshing connection with the toothed soldering box 17, the counter gear 50 is in meshing connection with the transport gear 14, the toothed soldering box 17 is at the rearmost end, and the rack 25 is at the foremost end.

When a stainless steel plate to be processed is placed on the upper surface of the crawler belt 36, the motor 49 is started, the motor shaft 41 rotates clockwise, so that the crawler belt 36 is driven by the driving wheel 35 to transmit clockwise, the stainless steel plate to be processed is driven to move rightwards to the left side transportation groove 61, at the moment, the driving wheel 35 drives the main belt wheel 34 to rotate anticlockwise through the gear 70 and the main belt wheel shaft 69 in sequence, the auxiliary driving wheel 60 is driven by the main driving wheel 56 and the belt 58 to rotate anticlockwise, the sequencing gear 46 is driven by the auxiliary driving rotating shaft 59 and the common gear 45 to rotate clockwise, the sequencing gear 46 rotates clockwise through the sequencing rotating shaft 47, the sequencing transmission gear 43, the matching gear 42 and the reverse rotating shaft 48 in sequence, the reverse gear 50 rotates anticlockwise, and the left side transportation groove 61 is driven to rotate to the right side through the transportation gear 14, the transportation rotating shaft 65 and the transportation wheel 13, at this time, the salient points 53 are connected with the driven grooves 68 in a sliding manner, the slot plates 51 are driven to rotate ninety degrees clockwise, the reversing gear 50 is no longer connected with the transport gear 14 in a meshing manner, the sequencing gear 46 is connected with the linkage gear 32 in a meshing manner, the sequencing gear 46 rotating clockwise drives the linkage gear 32 to rotate anticlockwise, the linkage gear 32 rotating anticlockwise drives the transmission gear 15 to rotate clockwise, and drives the transmission caterpillar track 62 to transmit clockwise sequentially through the transmission main rotating shaft 64 and the transmission main belt wheel 31, the stainless steel plate to be processed is driven to the adjustable baffle 29, at this time, the salient points 53 are connected with the driven grooves 68 in a sliding manner, the slot plates 51 are driven to rotate ninety degrees clockwise, the sequencing gear 46 is no longer connected with the linkage gear 32 in a meshing manner, at this time, the transmission caterpillar track 62 stops transmitting, the motor 22 is started at the same time, the motor shaft 23 drives the, further, the welding head 21 is enabled to cut the stainless steel plate to be processed forward, at the moment, the welding box spring 18 accumulates elastic potential energy, when the sector gear 24 is not meshed with the toothed welding box 17 any more and the sector gear 24 is meshed with the rack 25, the welding box spring 18 releases the elastic potential energy to drive the toothed welding box 17 to restore to the initial state, the sector gear 24 drives the rack 25 to move backwards, the sector gear 24 further drives the adjustable baffle 29 to move backwards through the connecting chute 27 and the horizontal bracket 28, the waste material plate is moved backwards, the rack spring 39 accumulates the elastic potential energy, in the process, the salient point 53 is connected with the driven groove 68 in a sliding mode again to drive the grooved disc 51 to rotate ninety degrees clockwise, the second sequencing gear 46 is meshed with the linkage gear 32 to be connected, the sequencing gear 46 rotating clockwise drives the linkage gear 32 to rotate anticlockwise, the linkage gear 32 rotating anticlockwise drives the transmission gear 15 to rotate clockwise, the conveying main rotating shaft 64 and the conveying main belt wheel 31 sequentially drive the conveying crawler 62 to transmit clockwise, the machined stainless steel plate is driven to move out, the sector gear 24 is not meshed with the rack 25 any more along with the rotation of the sector gear 24, the rack spring 39 releases elastic potential energy, the rack spring 39 drives the rack 25 to restore the initial state, when the salient points 53 are connected with the driven grooves 68 in a sliding mode again, the groove disc 51 is driven to rotate ninety degrees clockwise, the device restores the initial state, and the next cutting operation is facilitated.

The invention has the beneficial effects that: the invention adopts the sector gear, realizes that only one power source is needed for the cutting step and the waste material removing process, adopts the transport wheel, realizes that the stainless steel plate to be processed is cut to the right side in sequence, adopts the reverse gear, the sequencing gear and the trough plate, realizes the realization sequence of different actions, improves the current situation that most stainless steel plasma cutting devices need manual operation for loading, removing the redundant waste materials and even cutting, wastes a large amount of manpower, and cannot ensure the quality.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.