CN114083311A - Cutting device is used in processing of inductor shell - Google Patents

Abstract

The invention discloses a cutting device for machining an inductor shell, which relates to the technical field of machinery and comprises a workbench, a cutting device, a lifting mechanism, a supporting mechanism and an auxiliary mechanism, wherein the lifting mechanism is arranged in one side of the workbench, the cutting device is arranged on the other side of the workbench, the supporting mechanism and the auxiliary mechanism are respectively arranged on the upper end and the lower end of the lifting mechanism, the working end of the supporting mechanism corresponds to the working end of the auxiliary mechanism up and down, and the working end of the cutting device corresponds to the working end of the supporting mechanism horizontally; the problem of among the prior art because the uncertainty of leftover bits position on the shell can lead to the shell to need continuous removal angle of adjustment when carrying out the processing operation to carry out the operation among the prior art to can make the shell cause to reduce work efficiency when processing man-hour, increase the processing cost is solved.

Description

Cutting device is used in processing of inductor shell

Technical Field

The invention relates to the technical field of machinery, in particular to a cutting device for machining an inductor shell.

Background

The icing sensor is one of sensors, which are classified into a plurality of categories, and can be classified into: the optical type is used for detecting icing according to different optical properties of ice, water and air, and mainly detects the thickness of icing on the surface of objects such as airplanes, power transmission lines and buildings and converts icing signals into electrical signals capable of being directly detected.

In the processing process of the inductor, the shell of the inductor is used as an important component for protecting internal parts, the shell can be stably placed at a position where the shell needs to be placed, but most of the shells are formed by welding or dies, leftover materials remained in the forming process are remained on the outer surface of the shell in any mode, in order to achieve the smoothness and the aesthetic property of the shell, the leftover materials of the shell need to be removed, in the prior art, the leftover materials are mostly removed manually or in a grinding or cutting mode, but the shell is greatly stressed during grinding or cutting, therefore, the stability is poor, most of the parts are fixed through a fixing device, but the shell needs to be continuously moved to adjust the angle for operation due to the uncertainty of the position of the leftover materials, so that the working efficiency is reduced, and the processing cost is increased.

Disclosure of Invention

The embodiment of the invention provides a cutting device for machining a sensor shell, which aims to solve the problems in the background technology.

The embodiment of the invention adopts the following technical scheme: the utility model provides a cutting device is used in processing of inductor shell, includes workstation, cutting equipment, elevating system, supporting mechanism and complementary unit, elevating system sets up in one side of workstation, cutting equipment sets up on the opposite side of workstation, supporting mechanism and complementary unit set up respectively on elevating system's upper and lower both ends, supporting mechanism's work end corresponds from top to bottom with complementary unit's work end, cutting equipment's work end corresponds with supporting mechanism's work end level.

Further, the workbench comprises a placing frame, a bottom plate and a fixed support frame, the fixed support frame and the placing frame are respectively located on two sides of the bottom plate, the bottom plate is located at the bottom ends of the fixing frame and the placing frame, and placing holes are formed in the placing frame. The rack is used for placing and fixing the elevating system, the fixed support frame is used for placing the cutting equipment, the bottom plate is used for connecting and placing the rack and the fixed support frame, and the bottom plate can also be used for the elevating system to support the auxiliary mechanism when the machine stops working, so that the auxiliary mechanism can be prevented from continuously supporting the lifting mechanism in a suspended manner when the machine stops working, and the service life of the elevating system can be shortened.

Furthermore, the lifting mechanism comprises a first placing box, a first motor, a first threaded rod, a first moving block, a second moving block, a first supporting plate, a second supporting plate, a fixing frame and a rotating frame, the first placing box is placed in the placing hole, the first motor is arranged at the top end of the first placing box, the first threaded rod is arranged in the first placing box, the output end of the first motor is connected with the first threaded rod, the first moving block and the second moving block are both in threaded connection with the threaded rod, the first supporting plate is arranged on the first moving block, the second supporting plate is arranged on the second moving block, the fixing frame is arranged on the first supporting plate, and the rotating frame is rotatably arranged above the second supporting plate.

Furthermore, the supporting mechanism comprises a driving part and a limiting part, the driving part is arranged on the rotating frame, the limiting part is provided with six groups, the six groups of limiting parts are sequentially distributed around the driving part, and the six groups of limiting parts are all connected with the working end of the driving part.

Further, the driving component comprises a second placing box, a placing platform, a second motor, a first bevel gear set, a second threaded rod, a connecting plate, lifting plates and a first connecting shaft, the second placing box is placed on the rotating frame, the placing platform is arranged on the second placing box, six movable grooves are formed in the second placing box and the placing platform, each movable groove corresponds to one group of limiting components, the second motor is arranged at the bottom end in the second placing box, the output end of the second motor is connected with one end of the first bevel gear set, the other end of the first bevel gear set is connected with the bottom end of the second threaded rod, the connecting plate is connected onto the second threaded rod in a threaded mode, the two lifting plates are arranged, one side of the two lifting plates is arranged on two sides of the connecting plate respectively, and the first connecting shaft is arranged on the other three sides of each lifting plate, the first connecting shafts are rotatably arranged on the lifting plate.

Further, every group spacing part all includes fixed limiting plate, axis of rotation, spacing, second connecting axle and gangboard, fixed limiting plate is equipped with two, two fixed limiting plate all sets up in the below of blowing platform, and two fixed limiting plate symmetric position is in the below of a movable groove, the axis of rotation sets up between two fixed limiting plates, spacing intermediate position rotates and sets up in the axis of rotation, spacing top is located the top of blowing platform, the second connecting axle sets up on spacing bottom, the gangboard is equipped with two, two the one end of gangboard is rotated respectively and is set up on the both ends of second connecting axle, two the other end of gangboard rotates respectively and sets up on the both ends of first connecting axle.

Further, the auxiliary mechanism comprises a fixed part and a rotating part, the fixed part is arranged in the fixed frame, the rotating part is arranged on the fixed part, and the fixed part is connected with the working end of the rotating part.

Further, the fixed part is including bearing frame, third motor, second bevel gear group, third threaded rod, first spacing, threaded sleeve and rolling disc, the setting of bearing the frame is in the mount, the third motor sets up the one side of bearing the frame, second bevel gear group sets up inside bearing the frame, the output of third motor is connected with second bevel gear group's one end, the top and the other end of second bevel gear group of third threaded rod are connected, the bottom of third threaded rod runs through the bottom of bearing the frame and extends, the rolling disc is connected with the bottom of third threaded rod, the threaded sleeve cover is established on the third threaded rod, and threaded sleeve's bottom and rolling disc swing joint, first spacing setting is in the below of bearing the frame, first spacing cover is established on the threaded sleeve.

Further, rotary part includes fourth motor, first belt axle, fixed column, second belt axle, first connecting belt and telescopic link, the fourth motor sets up on the opposite side that bears the frame, the output and the first belt axle of fourth motor are connected, the fixed column sets up on the bottom that bears the frame, the second belt axle sleeve is established on the fixed column, and fixed column and second belt axle all do not all are connected with the threaded rod, the both ends of first connecting belt are established respectively and are established on first belt axle and second belt axle, the telescopic link is equipped with four, four the one end evenly distributed of telescopic link is in the below of second belt axle, and four the other end of telescopic link all is connected with the rolling disc, the bottom and the blowing part of rolling disc are connected.

The embodiment of the invention adopts at least one technical scheme which can achieve the following beneficial effects:

in the invention, the shell is placed on the supporting mechanism, the bottom end of the shell is fixed through the supporting mechanism, the top end of the shell is limited through the operation of the auxiliary mechanism, the shell can be stably fixed on the supporting mechanism, the shell is processed through the operation of the cutting equipment, the shell can be driven to rotate on the supporting mechanism through the auxiliary mechanism during processing, the contact position of the shell and the cutting equipment can be adjusted, the supporting mechanism, the auxiliary mechanism and the shell can be synchronously lifted through the lifting mechanism, the high contact position between the shell and the cutting equipment can be adjusted, the cutting equipment can conveniently process leftover materials on different directions on the shell through the matching of the lifting mechanism, the auxiliary mechanism and the supporting mechanism, and therefore, the problem that in the prior art, the position of the leftover materials on the shell can be continuously moved and adjusted during processing operation due to the uncertainty of the position of the leftover materials on the shell in the prior art is solved The angle is used for operation, so that the working efficiency is reduced and the processing cost is increased when the shell is processed.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

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

FIG. 2 is a partial mechanical schematic of the present invention;

FIG. 3 is a perspective sectional view of the elevating mechanism of the present invention;

FIG. 4 is a schematic perspective view of the supporting mechanism of the present invention;

FIG. 5 is a partial schematic structural view of the support mechanism of the present invention;

FIG. 6 is an enlarged view taken at A in FIG. 5;

fig. 7 is a schematic perspective view of the auxiliary mechanism of the present invention.

Reference numerals: a workbench 1, a placing rack 11, a bottom plate 12, a fixed supporting frame 13, a placing hole 14,

The cutting device 2, the lifting mechanism 3, the first placing box 31, the first motor 32, the first threaded rod 33, the first moving block 34, the second moving block 35, the first supporting plate 36, the second supporting plate 37, the fixing frame 38, the rotating frame 39, the supporting mechanism 4, the driving part 41, the second placing box 411, the placing platform 412, the second motor 413, the first bevel gear set 414, the second threaded rod 415, the connecting plate 416, the lifting plate 417, the first connecting shaft 418, the limiting part 42, the fixed limiting plate 421, the rotating shaft 422, the limiting frame 423, the second connecting shaft 424, the linkage plate 425, the auxiliary mechanism 5, the fixed part 51, the bearing frame 511, the third motor 512, the second bevel gear set 513, the third threaded rod 514, the first limiting frame 515, the threaded sleeve 516, the rotating disc 517, the rotating part 52, the fourth motor 521, the first belt shaft 522, the fixed column 523, the second belt shaft 524, the first connecting belt 525, the second bevel gear set, the third threaded rod set, the second supporting plate 415, the fixed column 516, the threaded rod, the rotating disc 517, the rotating part 52, the second belt 524, the second belt set, the third connecting belt set, the third belt set, and the second rotating part, A telescoping rod 526.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the specific embodiments of the present invention and the accompanying drawings. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The technical solutions provided by the embodiments of the present invention are described in detail below with reference to the accompanying drawings.

Referring to fig. 1 to 7, an embodiment of the present invention provides a cutting device for machining a sensor housing, including a workbench 1, a cutting device 2, a lifting mechanism 3, a supporting mechanism 4, and an auxiliary mechanism 5, where the lifting mechanism 3 is disposed in one side of the workbench 1, the cutting device 2 is disposed on the other side of the workbench 1, the supporting mechanism 4 and the auxiliary mechanism 5 are respectively disposed on the upper and lower ends of the lifting mechanism 3, the working end of the supporting mechanism 4 vertically corresponds to the working end of the auxiliary mechanism 5, and the working end of the cutting device 2 horizontally corresponds to the working end of the supporting mechanism 4.

In the invention, the shell is placed on the supporting mechanism 4, the bottom end of the shell is fixed through the supporting mechanism 4, the top end of the shell is limited through the operation of the auxiliary mechanism 5, so that the shell can be stably fixed on the supporting mechanism 4, then the shell is processed through the operation of the cutting equipment 2, in addition, the shell can be driven to rotate on the supporting mechanism 4 through the auxiliary mechanism 5 during processing, in this way, the contact position of the shell and the cutting equipment 2 can be adjusted, the supporting mechanism 4, the auxiliary mechanism 5 and the shell can be synchronously lifted through the lifting mechanism 3, in this way, the high contact position between the shell and the cutting equipment 2 can be adjusted, the cutting equipment 2 can conveniently process leftover materials on different directions on the shell through the matching among the lifting mechanism 3, the auxiliary mechanism 5 and the supporting mechanism 4, and therefore, the problem that the uncertainty of the position of the leftover materials on the shell in the prior art can be caused by the uncertainty of the position of the leftover materials on the shell in the prior art is solved When the machining operation is carried out, the angle needs to be continuously moved and adjusted to carry out the operation, so that the working efficiency is reduced when the shell is machined, and the machining cost is increased.

Specifically, referring to fig. 2, the workbench 1 is composed of a placing frame 11, a bottom plate 12 and a fixing support frame 13, the fixing support frame 13 and the placing frame 11 are respectively located at two sides of the bottom plate 12, the bottom plate 12 is located at the bottom ends of a fixing frame 38 and the placing frame 11, and a placing hole 14 is formed in the placing frame 11. Rack 11 is used for placing and fixed elevating system 3, and fixed support frame 13 is used for placing cutting equipment 2, and bottom plate 12 is used for connecting and places rack 11 and fixed support frame 13, and bottom plate 12 can also be used for elevating system 3 to support complementary unit 5 when the stop work, can prevent like this that equipment is in the stop work complementary unit 5 need last through elevating system 3 holding power unsettled, can reduce elevating system 3's life like this.

Specifically, referring to fig. 3, the lifting mechanism 3 includes a first placing box 31, a first motor 32, a first threaded rod 33, a first moving block 34, a second moving block 35, a first supporting plate 36, a second supporting plate 37, a fixing frame 38 and a rotating frame 39, the first placing box 31 is placed in the placing hole 14, the first motor 32 is disposed at the top end of the first placing box 31, the first threaded rod 33 is disposed in the first placing box 31, the output end of the first motor 32 is connected to the first threaded rod 33, both the first moving block 34 and the second moving block 35 are screwed on the threaded rod, the first supporting plate 36 is disposed on the first moving block 34, the second supporting plate 37 is disposed on the second moving block 35, the fixing frame 38 is disposed on the first supporting plate 36, and the rotating frame 39 is rotatably disposed above the second supporting plate 37.

The first threaded rod 33 can be driven to rotate by the driving of the first motor 32, the first threaded rod 33 can synchronously move up and down through the first moving block 34 and the second moving block 35 when rotating, the first supporting plate 36 and the second supporting plate 37 are driven to synchronously move up and down through the first moving block 34 and the second moving block 35, the fixing frame 38 is used for fixing the auxiliary mechanism 5, and the rotating frame 39 is used for placing the supporting mechanism 4.

Specifically, referring to fig. 4 to 6, the supporting mechanism 4 includes a driving part 41 and a limiting part 42, the driving part 41 is disposed on the rotating frame, six sets of the limiting part 42 are disposed, the six sets of the limiting part 42 are sequentially distributed around the driving part 41, and the six sets of the limiting part 42 are all connected to the working end of the driving part 41.

Specifically, referring to fig. 4 to 6, the driving unit 41 includes a second placing box 411, a placing platform 412, a second motor 413, a first bevel gear set 414, a second threaded rod 415, a connecting plate 416, a lifting plate 417 and a first connecting shaft 418, the second placing box 411 is placed on the rotating frame, the placing platform 412 is disposed on the second placing box 411, six movable slots are respectively disposed on the second placing box 411 and the placing platform 412, each movable slot corresponds to one set of limiting members 42, the second motor 413 is disposed at the bottom end inside the second placing box 411, an output end of the second motor 413 is connected to one end of the first bevel gear set 414, the other end of the first bevel gear set 414 is connected to the bottom end of the second threaded rod 415, the connecting plate 416 is screwed to the second threaded rod 415, two lifting plates 417 are disposed, one side of each of the two lifting plates 417 is disposed on two sides of the connecting plate 416, and the other three sides of each of the two lifting plates 417 are disposed with a first connecting shaft 418, and the first connecting shafts 418 are rotatably disposed on the lifting plates 417.

Specifically, referring to fig. 4-6, each set of the limiting component 42 includes a fixed limiting plate 421, a rotating shaft 422, a limiting frame 423, a second connecting shaft 424 and a linkage plate 425, two fixed limit plates 421 are provided, both of the two fixed limit plates 421 are arranged below the discharging platform 412, and the two fixed limit plates 421 are symmetrically located below one movable slot, the rotating shaft 422 is arranged between the two fixed limit plates 421, the middle position of the limiting frame 423 is rotatably arranged on the rotating shaft 422, the top end of the limiting frame 423 is positioned above the discharging platform 412, the second connecting shaft 424 is arranged at the bottom end of the limiting frame 423, two linkage plates 425 are arranged, one ends of the two linkage plates 425 are respectively rotatably arranged at two ends of the second connecting shaft 424, and the other ends of the two linkage plates 425 are respectively rotatably arranged at two ends of the first connecting shaft 418.

The working principle of the supporting mechanism 4 in the invention is as follows: the first bevel gear set 414 is driven by the second motor 413 to operate, the first bevel gear set 414 can drive the second threaded rod 415 to rotate when operating, the second threaded rod 415 can drive the connecting plate 416 to enable the two lifting plates 417 to lift synchronously when rotating, the two lifting plates 417 can drive the six groups of limiting components 42 to operate synchronously when moving, the limiting frame 423 can rotate angularly along with the lifting of the lifting plates 417 along the rotating shaft 422 through the matching of the linkage plates 425 and the second linkage shafts in each group of limiting components 42, and therefore the limiting frame 423 is fixed to the shell on the discharging platform 412.

Specifically, referring to fig. 7, the auxiliary mechanism 5 includes a fixed member 51 and a rotating member 52, the fixed member 51 is disposed in the fixing frame 38, the rotating member 52 is disposed on the fixed member 51, and the fixed member 51 is connected to a working end of the rotating member 52.

Specifically, referring to fig. 7, the fixing component 51 includes a bearing frame 511, a third motor 512, a second bevel gear set 513, a third threaded rod 514, a first limiting frame 515, a threaded sleeve 516 and a rotating disc 517, the bearing frame 511 is disposed in the fixing frame 38, the third motor 512 is disposed on one side of the bearing frame 511, the second bevel gear set 513 is disposed inside the bearing frame 511, an output end of the third motor 512 is connected to one end of the second bevel gear set 513, a top end of the third threaded rod 514 is connected to the other end of the second bevel gear set 513, a bottom end of the third threaded rod 514 penetrates through the bottom of the bearing frame 511 and extends out, the rotating disc 517 is connected to a bottom end of the third threaded rod 514, the threaded sleeve 516 is sleeved on the third threaded rod 514, and a bottom end of the threaded sleeve 516 is movably connected to the rotating disc 517, the first limiting frame 515 is disposed below the bearing frame 511, the first limiting frame 515 is sleeved on the threaded sleeve 516.

Specifically, referring to fig. 7, the rotating component 52 includes a fourth motor 521, a first belt shaft 522, a fixed column 523, a second belt shaft 524, a first connecting belt 525 and a telescopic rod 526, the fourth motor 521 is arranged on the other side of the bearing frame 511, the output end of the fourth motor 521 is connected with the first belt shaft 522, the fixing post 523 is arranged at the bottom end of the loading frame 511, the second belt shaft 524 is sleeved on the fixing post 523, and the fixed column 523 and the second belt shaft 524 are not connected with the threaded rod, both ends of the first connecting belt 525 are respectively sleeved on the first belt shaft 522 and the second belt shaft 524, four telescopic rods 526 are arranged, one ends of the four telescopic rods 526 are uniformly distributed below the second belt shaft 524, the other ends of the four telescopic rods 526 are connected with a rotary disc 517, and the bottom end of the rotary disc 517 is connected with a material placing component.

During operation, the second bevel gear set 513 can drive the third threaded rod 514 to rotate through the driving of the third motor 512, and the third threaded rod 514 can enable the threaded sleeve 516 to vertically move when rotating, so that the threaded sleeve 516 can drive the rotating disc 517 to synchronously move when moving, and the first limiting frame 515 can support the threaded sleeve 516; the first belt shaft 522 can be rotated by the driving of the fourth motor 521, the first belt shaft 522 drives the second belt shaft 524 to rotate through the first connecting belt 525 when rotating, and the second belt shaft 524 drives the rotating disc 517 to rotate through the four telescopic rods 526.

The above description is only an example of the present invention, and is not intended to limit the present invention. Various modifications and alterations to this invention will become apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (9)

1. The utility model provides a cutting device is used in processing of inductor shell, includes cutting equipment (2), its characterized in that still includes workstation (1), elevating system (3), supporting mechanism (4) and complementary unit (5), elevating system (3) set up in one side of workstation (1), cutting equipment (2) set up on the opposite side of workstation (1), supporting mechanism (4) and complementary unit (5) set up respectively on the upper and lower both ends of elevating system (3), the work end of supporting mechanism (4) corresponds from top to bottom with the work end of complementary unit (5), the work end of cutting equipment (2) corresponds with the work end level of supporting mechanism (4).

2. The cutting device for machining the inductor shell according to claim 1, wherein the workbench (1) comprises a placing frame (11), a bottom plate (12) and a fixing support frame (13), the fixing support frame (13) and the placing frame (11) are respectively located on two sides of the bottom plate (12), the bottom plate (12) is located at the bottom ends of a fixing frame (38) and the placing frame (11), and a placing hole (14) is formed in the placing frame (11).

3. The cutting device for machining the inductor shell as claimed in claim 2, wherein the lifting mechanism (3) comprises a first placing box (31), a first motor (32), a first threaded rod (33), a first moving block (34), a second moving block (35), a first supporting plate (36), a second supporting plate (37), a fixed frame (38) and a rotating frame (39), the first placing box (31) is placed in the placing hole (14), the first motor (32) is arranged at the top end of the first placing box (31), the first threaded rod (33) is arranged in the first placing box (31), the output end of the first motor (32) is connected with the first threaded rod (33), the first moving block (34) and the second moving block (35) are both screwed on the threaded rod, the first supporting plate (36) is arranged on the first moving block (34), the second supporting plate (37) is arranged on the second moving block (35), the fixed frame (38) is arranged on the first supporting plate (36), and the rotating frame (39) is rotatably arranged above the second supporting plate (37).

4. The cutting device for machining the inductor shell as claimed in claim 3, wherein the supporting mechanism (4) comprises a driving part (41) and limiting parts (42), the driving part (41) is arranged on the rotating frame, six groups of limiting parts (42) are arranged, the six groups of limiting parts (42) are sequentially distributed around the driving part (41), and the six groups of limiting parts (42) are all connected with the working end of the driving part (41).

5. The cutting device for processing the inductor shell as claimed in claim 4, wherein the driving component (41) comprises a second placing box (411), a placing platform (412), a second motor (413), a first bevel gear set (414), a second threaded rod (415), a connecting plate (416), a lifting plate (417) and a first connecting shaft (418), the second placing box (411) is placed on the rotating frame, the placing platform (412) is arranged on the second placing box (411), six movable slots are respectively arranged on the second placing box (411) and the placing platform (412), each movable slot corresponds to one group of limiting components (42), the second motor (413) is arranged at the bottom end in the second placing box (411), and the output end of the second motor (413) is connected with one end of the first bevel gear set (414), the other end of first bevel gear group (414) is connected with the bottom of second threaded rod (415), connecting plate (416) spiro union is on second threaded rod (415), lifter plate (417) are equipped with two, two one side of lifter plate (417) sets up respectively on the both sides of connecting plate (416), and all is equipped with first connecting axle (418) on the other three sides of every lifter plate (417), first connecting axle (418) all rotate the setting on lifter plate (417).

6. The cutting device for processing the inductor shell as claimed in claim 5, wherein each group of the limiting members (42) comprises two fixed limiting plates (421), two rotating shafts (422), two limiting frames (423), two second connecting shafts (424) and two linkage plates (425), the two fixed limiting plates (421) are arranged below the discharging platform (412), the two fixed limiting plates (421) are symmetrically arranged below one movable groove, the rotating shaft (422) is arranged between the two fixed limiting plates (421), the middle position of each limiting frame (423) is rotatably arranged on the rotating shafts (422), the top end of each limiting frame (423) is arranged above the discharging platform (412), the second connecting shaft (424) is arranged at the bottom end of each limiting frame (423), and the linkage plates (425) are provided in number of two, one ends of the two linkage plates (425) are respectively and rotatably arranged at two ends of the second connecting shaft (424), and the other ends of the two linkage plates (425) are respectively and rotatably arranged at two ends of the first connecting shaft (418).

7. The cutting device for machining the inductor housing as claimed in claim 6, wherein the auxiliary mechanism (5) comprises a fixed part (51) and a rotating part (52), the fixed part (51) is arranged in the fixed frame (38), the rotating part (52) is arranged on the fixed part (51), and the fixed part (51) is connected with the working end of the rotating part (52).

8. The cutting device for machining the sensor housing as claimed in claim 7, wherein the fixing member (51) comprises a bearing frame (511), a third motor (512), a second bevel gear set (513), a third threaded rod (514), a first limiting frame (515), a threaded sleeve (516) and a rotating disc (517), the bearing frame (511) is arranged in the fixing frame (38), the third motor (512) is arranged at one side of the bearing frame (511), the second bevel gear set (513) is arranged in the bearing frame (511), an output end of the third motor (512) is connected with one end of the second bevel gear set (513), a top end of the third threaded rod (514) is connected with the other end of the second bevel gear set (513), a bottom end of the third threaded rod (514) penetrates through the bottom of the bearing frame (511) and extends out, and the rotating disc (517) is connected with a bottom end of the third threaded rod (514), the threaded sleeve (516) is sleeved on the third threaded rod (514), the bottom end of the threaded sleeve (516) is movably connected with the rotating disc (517), the first limiting frame (515) is arranged below the bearing frame (511), and the first limiting frame (515) is sleeved on the threaded sleeve (516).

9. The cutting device for processing the inductor shell as claimed in claim 8, wherein the rotating component (52) comprises a fourth motor (521), a first belt shaft (522), a fixed column (523), a second belt shaft (524), a first connecting belt (525) and four telescopic rods (526), the fourth motor (521) is arranged on the other side of the bearing frame (511), the output end of the fourth motor (521) is connected with the first belt shaft (522), the fixed column (523) is arranged on the bottom end of the bearing frame (511), the second belt shaft (524) is sleeved on the fixed column (523), the fixed column (523) and the second belt shaft (524) are not connected with threaded rods, two ends of the first connecting belt (525) are respectively sleeved on the first belt shaft (522) and the second belt shaft (524), and four telescopic rods (526) are arranged, one end evenly distributed of four telescopic link (526) is in the below of second belt shaft (524), and four the other end of telescopic link (526) all is connected with rolling disc (517), the bottom and the blowing part of rolling disc (517) are connected.

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