CN112658793A - Device for removing waste scraps and liquid in milling area according to machining tool path - Google Patents

Abstract

The invention discloses a device for removing waste scraps and liquid in a milling area according to a processing cutter path, which comprises a movable box, a treatment cavity with a forward opening is arranged in the movable box, four concave positioning blocks are connected on the rear wall of the treatment cavity in a sliding manner, the four concave positioning blocks are distributed and arranged in a vertical and horizontal symmetrical manner by taking the central line of the treatment cavity as a symmetrical center, the front end of the concave positioning block is provided with a tooth socket with a forward opening, the rear wall of the tooth socket rotates and is connected with a moving shaft in a sliding way, the invention can be installed on a workbench of a numerical control milling machine in a free magnetic adsorption way, through carrying out the automatic check of milling the in-process to processing tool path thereby remove, and the automatic sweeps and the waste liquid that will produce are absorb thereby discharge in the milling process region in carrying out the milling process, prevent because sweeps and waste liquid are too much in the milling process region accumulation and lead to milling the in-process work piece by the fish tail or damage.

Description

Device for removing waste scraps and liquid in milling area according to machining tool path

Technical Field

The invention relates to the relevant field of milling, in particular to a device for removing waste scraps and liquid waste in a milling area according to a processing cutter path.

Background

When a general numerical control milling machine carries out milling processing, a large amount of scraps and waste liquid generated by milling cannot be discharged out of a milling processing area in time, so that the scraps and the waste liquid scratch a workpiece undergoing milling processing or damage the outer surface of the workpiece, and accidental cutter collision of various milling cutters can be caused due to untimely discharge of the scraps and the waste liquid.

Disclosure of Invention

In order to solve the problems, the embodiment designs a device for removing waste liquid in a milling area according to a processing cutter path, the device for removing waste liquid in the milling area according to the processing cutter path comprises a moving box, a processing cavity with a forward opening is arranged in the moving box, four concave positioning blocks are connected on the rear wall of the processing cavity in a sliding manner, the four concave positioning blocks are distributed and arranged in a vertical and horizontal symmetrical manner by taking the center line of the processing cavity as a symmetrical center, a tooth socket with a forward opening is arranged at the front end of each concave positioning block, a moving shaft is rotationally and slidably connected in the rear wall of the tooth socket, a moving gear is fixedly connected on the outer peripheral surface of the moving shaft, the outer peripheral surface of the moving gear is meshed and connected on the inner wall of the tooth socket, a crushing box is rotationally connected on the outer peripheral surface of the moving shaft, a fixer is fixedly connected at the front end, the crushing device is characterized in that six crushing needles are fixedly connected to the outer peripheral surface of the crushing rod, a crushing cavity with a forward opening is arranged in the crushing box, the crushing cavity is mutually far away from the side openings with two opposite openings in the side wall from top to bottom and from left to right, an opening and closing shaft is rotatably connected to the inner wall of the side opening and closing shaft, an opening and closing torsion spring is fixedly connected to the outer peripheral surface of the opening and closing torsion spring, an opening and closing plate is rotatably connected to the outer peripheral surface of the opening and closing torsion spring, a suction pipe is fixedly connected to one end of the crushing cavity, which is far away from the crushing cavity from the top to bottom and from left to right, opposite-opening suction ports are arranged in the suction pipe, the suction port is communicated with the crushing cavity and the treatment cavity, a suction pump is fixedly connected to the inner wall of the suction port, four backward-opening, the front end of the semicircular moving wheel is fixedly connected with a front shaft, the outer peripheral surface of the front shaft is fixedly connected with a fixed rod, a cavity with back-to-back openings is arranged in the fixed rod, the inner wall of the cavity is connected with a T-shaped rod in a sliding manner, one end of the T-shaped rod, which is far away from the T-shaped rod, is fixedly connected between the concave positioning blocks, a front belt pulley is fixedly connected on the outer peripheral surface of the front shaft, an inclined belt is rotatably connected between the front belt pulleys, a placing cavity with an upward opening is arranged in the lower wall of the treatment cavity, a driving motor is fixedly connected on the inner wall of the placing cavity, the front end of the driving motor is in power connection with a main driving shaft, a driving belt pulley is fixedly connected on the outer peripheral surface of the main driving shaft, a driving belt is rotatably connected between the driving belt, at this time, the driving motor is started to drive the main driving shaft and the driving belt pulley to rotate, so as to drive the driving belt to rotate, so as to drive the front belt pulley to rotate, so as to drive the front shaft and the inclined belt to rotate, so as to drive the semi-circular moving wheel to rotate, so as to drive the moving box to move integrally according to a milling tool path, so that the front shaft drives the rear bevel gear to rotate, so as to drive the front bevel gear to rotate, so as to drive the driving shaft and the driving bevel gear to rotate, so as to drive the fixed rod and the T-shaped rod to move correspondingly to a milling position, and the T-shaped rod further drives the concave positioning block to slide on the rear wall of the processing cavity, so as to drive the moving gear and the moving shaft to slide and rotate on the inner wall of the tooth socket, and then drive broken case carries out corresponding removal, and then drives the fixer broken pole broken needle rotates, and starts this moment the suction pump, and then will mill the sweeps and the waste liquid suction of production the suction inlet with broken intracavity, the rethread broken pole broken needle's rotation, and then carry out crushing treatment to the sweeps, this moment the opening and closing board is kept away from each other and is opened, and then drives the opening and closing axle the torsional spring that opens and shuts rotates, and broken pole with broken behind the breaking treatment to sweeps and waste liquid through the side opening with the fixer discharges outside the treatment chamber.

Preferably, the treatment cavity is internally provided with eight discharge ports with back-to-back openings in the side walls which are far away from each other from the upper side and the lower side, the eight discharge ports are distributed and arranged in a vertically and horizontally symmetrical manner by taking the center line of the treatment cavity as a symmetrical center, the treatment cavity is rotationally connected with four drive shafts in the side walls which are far away from each other from the upper side and the lower side, the four drive shafts are distributed and arranged in a vertically and horizontally symmetrical manner by taking the center line of the treatment cavity as a symmetrical center, the lower end of the drive shaft on the lower side is rotationally connected in the upper end face of the drive motor, when a large amount of waste chips and waste liquid generated in a milling area need to be discharged in time, the drive shaft rotates to move.

Preferably, one end of the driving shaft close to each other is fixedly connected with a front end bevel gear, the front end of the front shaft is fixedly connected with a rear end bevel gear, the rear end of the front end bevel gear is meshed with the rear end bevel gear, a driving bevel gear is fixedly connected on the peripheral surface of the driving shaft, eight conveying driven shafts are rotationally connected with the upper side, the lower side, the left side and the right side of the treatment cavity, which are far away from the side wall, and are symmetrically distributed on the upper side, the lower side and the left side of the center line of the treatment cavity, when milling is performed and it is necessary to remove the shavings and waste liquid from the machining area, the drive shaft is rotated, thereby driving the front bevel gear to rotate and further driving the rear bevel gear and the front shaft to rotate, and then the driving bevel gear is driven to rotate, and further the driven bevel gear and the transportation driven shaft are driven to rotate, so that the waste chips and the waste liquid are discharged.

Preferably, one end of the transportation driven shaft, which is close to the left and right, is fixedly connected with a driven bevel gear, one end of the driven bevel gear, which is close to the left and right, is meshed with the driving bevel gear, the main driving shaft is fixedly connected to the outer peripheral surface of the transportation driven shaft, and an embedding shaft is rotatably connected between the inner walls of the discharge ports.

Preferably, fixedly connected with embedding belt pulley on the embedding axle outer peripheral face, the embedding belt pulley with it is connected with the conveyor belt to rotate between the main drive axle, the wall internal rotation is connected with the chuck behind the treatment chamber, when needs mill the blank man-hour, presss from both sides the blank this moment between the chuck, and need mill the sweeps and the waste liquid that produce and discharge extremely when outside the treatment chamber, this moment the embedding axle rotates and then drives the embedding belt pulley main drive axle the conveyor belt rotates.

The invention has the beneficial effects that: can free magnetic force adsorption installation on numerically controlled fraise machine's workstation, thereby remove through the automated inspection to processing tool path at the in-process that mills, and mill thereby the automatic sweeps and the waste liquid absorption that will produce and discharge in milling process region, prevent because sweeps and waste liquid are too much at milling process region accumulation and lead to milling process in-process work piece by fish tail or damage.

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.

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic overall structure diagram of an apparatus for removing waste fluid in a milling area according to a processing tool path.

Fig. 2 is an enlarged schematic view of a in fig. 1.

Fig. 3 is an enlarged schematic view of B in fig. 1.

Fig. 4 is an enlarged schematic view of C in fig. 1.

Fig. 5 is an enlarged schematic view of D in fig. 1.

FIG. 6 is a schematic diagram of the structure of E-E in FIG. 2.

Fig. 7 is a schematic view of the structure of F-F in fig. 3.

Detailed Description

The invention will now be described in detail with reference to fig. 1-7, wherein for ease of description the orientations described below are now 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 device for removing waste scraps and liquid in a milling area according to a processing cutter path, which comprises a moving box 11, wherein a processing cavity 12 with a forward opening is arranged in the moving box 11, the rear wall of the processing cavity 12 is connected with four concave positioning blocks 13 in a sliding manner, the four concave positioning blocks 13 are symmetrically distributed up and down and left and right by taking the center line of the processing cavity 12 as a symmetric center, the front end of each concave positioning block 13 is provided with a tooth groove 14 with a forward opening, the rear wall of the tooth groove 14 is connected with a moving shaft 22 in a rotating and sliding manner, the outer peripheral surface of the moving shaft 22 is fixedly connected with a moving gear 32, the outer peripheral surface of the moving gear 32 is engaged and connected with the inner wall of the tooth groove 14, the outer peripheral surface of the moving shaft 22 is connected with a crushing box 21 in a rotating manner, the front end of the, the crushing device is characterized in that six crushing needles 27 are fixedly connected to the outer peripheral surface of the crushing rod 23, a crushing cavity 31 with a forward opening is arranged in the crushing box 21, two side openings 52 with opposite openings are arranged in the side wall of the crushing cavity 31, which is far away from each other from the upper side, the lower side, the left side and the right side, of the crushing cavity, an opening and closing shaft 28 is rotatably connected to the rear wall of the side opening 52, an opening and closing torsion spring 29 is fixedly connected to the outer peripheral surface of the opening and closing shaft 28, an opening and closing plate 19 is rotatably connected to the outer peripheral surface of the opening and closing torsion spring 29, a suction pipe 25 is fixedly connected to one end, far away from each other from the upper side, the left side and the right side, of the crushing cavity 31, a suction port 24 with opposite openings is arranged in the suction pipe 25, the suction port 24 is communicated with the crushing cavity 31 and the treatment cavity 12, the inner wall of the sliding port 38 is rotatably connected with a semicircular moving wheel 34, the front end of the semicircular moving wheel 34 is fixedly connected with a front shaft 44, the outer peripheral surface of the front shaft 44 is fixedly connected with a fixed rod 45, a cavity 39 with an opposite opening is arranged in the fixed rod 45, the inner wall of the cavity 39 is slidably connected with a T-shaped rod 46, one end, away from each other, of the T-shaped rod 46 is fixedly connected between the concave positioning blocks 13, the outer peripheral surface of the front shaft 44 is fixedly connected with a front belt pulley 43, an inclined belt 15 is rotatably connected between the front belt pulleys 43, a placing cavity 49 with an upward opening is arranged in the lower wall of the treatment cavity 12, a driving motor 47 is fixedly connected on the inner wall of the placing cavity 49, the front end of the driving motor 47 is dynamically connected with a main driving shaft 51, a driving belt pulley 50 is fixedly connected on the outer peripheral surface of the main driving shaft 51, and a, when milling is performed, the waste chips and waste liquid generated by milling are discharged, the driving motor 47 is started to drive the main driving shaft 51 and the driving belt pulley 50 to rotate, and further drive the driving belt 48 to rotate, and further drive the front belt pulley 43 to rotate, and further drive the front shaft 44 and the inclined belt 15 to rotate, and further drive the semicircular moving wheel 34 to rotate, and further drive the moving box 11 to move integrally according to the tool path of milling, and the front shaft 44 drives the rear bevel gear 42 to rotate, and further drives the front bevel gear 41 to rotate, and further drives the driving shaft 37 and the driving bevel gear 36 to rotate, and further drives the fixing rod 45 and the T-shaped rod 46 to move corresponding milling positions, and the T-shaped rod 46 further drives the concave positioning block 13 to slide on the rear wall of the processing cavity 12, the movable gear 32 and the movable shaft 22 are further driven to slide and rotate on the inner wall of the tooth socket 14, so that the crushing box 21 is driven to move correspondingly, the fixing device 30, the crushing rod 23 and the crushing needle 27 are further driven to rotate, the suction pump 26 is started at the moment, waste chips and waste liquid generated by milling are further sucked into the suction port 24 and the crushing cavity 31, then the crushing rod 23 and the crushing needle 27 rotate to crush the waste chips, the opening and closing plate 19 is mutually separated and opened at the moment, so that the opening and closing shaft 28 and the opening and closing torsion spring 29 are driven to rotate, and the crushing rod 23 and the crushing needle 27 discharge the waste chips and the waste liquid outside the treatment cavity 12 through the side opening 52 and the fixing device 30 after crushing treatment.

Beneficially, eight discharge ports 17 with opposite openings are arranged in the side walls of the processing chamber 12, which are away from each other vertically and horizontally, the eight discharge ports 17 are distributed and arranged vertically and horizontally symmetrically with the center line of the processing chamber 12 as the symmetric center, four drive shafts 37 are rotationally connected to the side walls of the processing chamber 12, which are away from each other vertically and horizontally, the four drive shafts 37 are distributed and arranged vertically and horizontally symmetrically with the center line of the processing chamber 12 as the symmetric center, the lower ends of the drive shafts 37 at the lower side are rotationally connected to the upper end face of the drive motor 47, when a large amount of waste chips and waste liquid generated in a milling area need to be discharged in time, the drive shafts 37 rotate to move the whole mobile box 11, and the waste chips and waste liquid generated by milling are discharged to the outside of.

Advantageously, a front end bevel gear 41 is fixedly connected to one end of the driving shaft 37 close to each other, a rear end bevel gear 42 is fixedly connected to the front end of the front shaft 44, the rear end of the front end bevel gear 41 is engaged with the rear end bevel gear 42, a driving bevel gear 36 is fixedly connected to the outer peripheral surface of the driving shaft 37, eight transportation driven shafts 20 are rotatably connected to the upper, lower, left and right sides of the treatment chamber 12 far away from the side wall, and the eight transportation driven shafts 20 are symmetrically distributed on the upper, lower, left and right sides of the central line of the treatment chamber 12, so that when the milling is performed and waste chips and waste liquid are required to be discharged from the processing area, the driving shaft 37 rotates to drive the front end bevel gear 41 to rotate, and further drive the rear end bevel gear 42 and the front shaft 44 to rotate, and further drive the driving bevel gear 36 to rotate, the transport driven shaft 20 rotates, and then discharges the scraps and the waste liquid.

Beneficially, one end of the transportation driven shaft 20, which is close to each other in the vertical and horizontal directions, is fixedly connected with a driven bevel gear 35, one end of the driven bevel gear 35, which is close to each other in the horizontal and vertical directions, is engaged with the driving bevel gear 36, the outer peripheral surface of the transportation driven shaft 20 is fixedly connected with a driving shaft 51, and an embedding shaft 53 is rotatably connected between the inner walls of the discharge ports 17, so that when waste chips and waste liquid generated by milling are required to be transported and discharged, at the moment, the driving bevel gear 36 rotates to drive the driven bevel gear 35 and the transportation driven shaft 20 to rotate, further drive the driving shaft 51 and the embedding shaft 53 to rotate, and further discharge the waste chips and the waste.

Advantageously, an embedded belt pulley 54 is fixedly connected to the outer peripheral surface of the embedded shaft 53, a transport belt 18 is rotatably connected between the embedded belt pulley 54 and the main drive shaft 51, a chuck 16 is rotatably connected to the rear wall of the processing chamber 12, when a blank is milled, the blank is clamped between the chucks 16, and waste chips and waste liquid generated by milling are discharged to the outside of the processing chamber 12, the embedded shaft 53 rotates to drive the embedded belt pulley 54, the main drive shaft 51 and the transport belt 18 to rotate.

The following describes in detail the use steps of an apparatus for removing waste fluid from milling area according to machining tool path, with reference to fig. 1 to 7:

initially, the suction pump 26 and the drive motor 47 are in a closed state, the crushing tank 21 is in an arbitrary position in the tooth grooves 14, and the opening plate 19 is in a closed state.

When the milling machine is used, waste chips and waste liquid generated by milling are discharged, the driving motor 47 is started to drive the main driving shaft 51 and the driving belt pulley 50 to rotate, the driving belt 48 to rotate, the front belt pulley 43 to rotate, the front shaft 44 and the inclined belt 15 to rotate, the semicircular moving wheel 34 to rotate, the whole moving box 11 to move according to the milling tool path, the front shaft 44 to drive the rear bevel gear 42 to rotate, the front bevel gear 41 to rotate, the driving shaft 37 and the driving bevel gear 36 to rotate, the fixing rod 45 and the T-shaped rod 46 to move corresponding milling positions, the T-shaped rod 46 to drive the concave positioning block 13 to slide on the rear wall of the processing cavity 12, and the moving gear 32 and the moving shaft 22 to slide and rotate on the inner wall of the tooth groove 14, and then drive broken case 21 and carry out corresponding removal, and then drive fixer 30, broken pole 23, broken needle 27 rotates, and start suction pump 26 this moment, and then will mill the sweeps and the waste liquid that produce and inhale in suction inlet 24 and broken chamber 31, rethread broken pole 23, the rotation of broken needle 27, and then carry out crushing treatment to the sweeps, open-close plate 19 keeps away from each other this moment and opens, and then drive opening and closing shaft 28, torsional spring 29 rotates that opens and shuts, and broken pole 23 and broken needle 27 carry out the crushing treatment to sweeps and waste liquid after discharge outside the treatment chamber 12 through side opening 52 and fixer 30.

When milling regional production a large amount of sweeps and waste liquid and need in time discharge, thereby drive shaft 37 rotates and remove removal box 11 is whole this moment, and the sweeps and the waste liquid that mill the production discharge outside treatment chamber 12 through discharge port 17, when milling and need carry out sweeps and waste liquid to the processing region in, drive shaft 37 rotates this moment, and then drive front end bevel gear 41 rotates, and then drive rear end bevel gear 42, leading axle 44 rotates, and then drive bevel gear 36 and rotate, and then drive driven bevel gear 35, transportation driven shaft 20 rotates, and then discharge sweeps and waste liquid.

When the sweeps and the waste liquid that produce milling need be transported and discharged, drive bevel gear 36 rotates this moment, and then drive driven bevel gear 35, transportation driven shaft 20 rotates, and then drive main drive axle 51, embedding axle 53 rotates, and then handle the discharge of sweeps and waste liquid on next step, when needing to mill the blank man-hour, press from both sides the blank between chuck 16 this moment, and need to mill the sweeps and the waste liquid that produce and when discharging outside processing chamber 12, embedding axle 53 rotates this moment and then drives embedding belt pulley 54, main drive axle 51, transportation belt 18 rotates.

The invention has the beneficial effects that: the automatic detection device can be freely and magnetically adsorbed and installed on a workbench of a numerical control milling machine, the machining tool path is automatically detected in the milling process so as to move, and the generated waste chips and waste liquid are automatically absorbed and discharged in the milling process so as to prevent the workpiece from being scratched or damaged in the milling process due to excessive accumulation of the waste chips and the waste liquid in the milling area.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides a get rid of device that mills regional sweeps waste liquid according to processing tool path, includes the removal case, its characterized in that: the movable box is internally provided with a treatment cavity with a forward opening, the rear wall of the treatment cavity is connected with four concave positioning blocks in a sliding manner, the four concave positioning blocks are distributed and arranged in a vertical and horizontal symmetrical manner by taking the central line of the treatment cavity as a symmetrical center, the front end of each concave positioning block is provided with a tooth socket with a forward opening, the rear wall of the tooth socket is connected with a movable shaft in a rotating and sliding manner, the outer peripheral surface of the movable shaft is fixedly connected with a movable gear, the outer peripheral surface of the movable gear is meshed and connected onto the inner wall of the tooth socket, the outer peripheral surface of the movable shaft is connected with a crushing box in a rotating manner, the front end of the movable shaft is fixedly connected with a fixer, the outer peripheral surface of the fixer is fixedly connected with five crushing rods, the outer peripheral surface of each crushing rod is fixedly connected with six crushing needles, the opening and closing shaft is rotationally connected in the rear wall of the side opening, an opening and closing torsion spring is fixedly connected on the outer peripheral surface of the opening and closing torsion spring, an opening and closing plate is rotationally connected on the outer peripheral surface of the opening and closing torsion spring, a suction pipe is fixedly connected at one end of the crushing cavity, which is far away from the crushing cavity in the vertical and horizontal directions, a suction port with opposite openings is arranged in the suction pipe, the suction port is communicated with the crushing cavity and the treatment cavity, a suction pump is fixedly connected on the inner wall of the suction port, four sliding ports with backward openings are arranged in the rear wall of the treatment cavity, the four sliding ports are symmetrically distributed in the vertical and horizontal directions by taking the center line of the treatment cavity as a symmetric center, a semicircular moving wheel is rotationally connected on the inner wall of the sliding port, the front end of the semicircular moving wheel is fixedly connected with, t shape pole keep away from one end fixed connection each other in between the spill locating piece, the leading belt pulley of fixedly connected with on the leading epaxial peripheral face, it is connected with oblique belt to rotate between the leading belt pulley, be equipped with the ascending chamber of placing of opening in the treatment chamber lower wall, place fixedly connected with driving motor on the intracavity wall, driving motor front end power is connected with the main drive axle, fixedly connected with driving pulley on the main drive axle peripheral face, driving pulley and downside rotate between the leading belt pulley and be connected with driving belt.

2. The apparatus for removing waste fluid from milling area according to machining route of claim 1, wherein: the processing chamber is kept away from the lateral wall about from each other from about, and is equipped with eight discharge ports that open side by side, eight the discharge port use the processing chamber central line sets up as symmetry center bilateral symmetry about from about, the processing chamber is kept away from the lateral wall internal rotation about from about and is connected with four drive shafts, four the drive shaft with the processing chamber central line sets up as symmetry center bilateral symmetry about from about, the downside the drive shaft lower extreme rotate connect in the driving motor up end, when milling the regional a large amount of sweeps and waste liquid of producing and need in time discharge, at this moment the drive shaft rotates thereby right the mobile box wholly removes, and the sweeps and the waste liquid that mill the production pass through the discharge port discharge extremely outside the processing chamber.

3. The apparatus for removing waste fluid from milling area according to machining route of claim 2, wherein: the conveying device is characterized in that a front-end bevel gear is fixedly connected to one end, close to each other, of the driving shaft, a rear-end bevel gear is fixedly connected to the front end of the front shaft, the rear end of the front-end bevel gear is meshed with the rear-end bevel gear, a driving bevel gear is fixedly connected to the outer peripheral surface of the driving shaft, eight conveying driven shafts are rotatably connected to the upper portion, the lower portion, the left portion and the right portion of the treatment cavity, the side wall of the treatment cavity is far away from the upper portion and the left.

4. A device for removing waste fluid from a milling area according to a machining path as claimed in claim 3, wherein: one end, close to each other, of the transportation driven shaft is fixedly connected with a driven bevel gear, one end, close to each other, of the driven bevel gear is meshed with the driving bevel gear, a main driving shaft is fixedly connected to the outer peripheral surface of the transportation driven shaft, and an embedded shaft is rotatably connected between the inner walls of the discharge ports.

5. The apparatus for removing waste fluid from milling area according to machining route of claim 4, wherein: fixedly connected with embedding belt pulley on the embedding axle outer peripheral face, embedding belt pulley with it is connected with the transportation belt to rotate between the main drive axle, the rotation is connected with the chuck in the treatment chamber back wall.

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