CN111958533A

CN111958533A - Fixed disassembling device for machining hard diamond material

Info

Publication number: CN111958533A
Application number: CN202010802096.9A
Authority: CN
Inventors: 王春莉
Original assignee: Bochuang Machinery Factory Qixing Street Xinchang County
Current assignee: Shimen Hongyan Super Hard Material Co.,Ltd.
Priority date: 2020-08-11
Filing date: 2020-08-11
Publication date: 2020-11-20
Anticipated expiration: 2040-08-11
Also published as: CN111958533B

Abstract

The invention provides a fixed disassembling device for machining hard diamond materials, relates to the technical field of diamond material machining, and solves the problems that clamping mechanisms on a machining and disassembling platform for diamond raw materials are fixed in number, the position adjustable range is small, and the clamping mechanisms cannot be selected in proper number and the angle can not be adjusted horizontally according to different shapes of the diamond raw materials. The utility model provides a fixed detaching device of stereoplasm diamond material processing, includes fixed establishment, actuating mechanism is installed to the fixed establishment left end. According to the invention, according to different shapes of hard diamond raw materials, an appropriate number of clamping mechanisms can be selected according to clamping requirements and are slidably arranged on the top end surface of the square workbench, the clamping mechanisms can be slidably adjusted along the annular sliding groove and the arc-shaped sliding groove according to appropriate clamping positions of the hard diamond raw materials, and the hard diamond raw materials can be clamped together through the square clamping blocks in the multiple groups of clamping mechanisms during clamping, so that the subsequent disassembling operation is facilitated.

Description

Fixed disassembling device for machining hard diamond material

Technical Field

The invention belongs to the technical field of diamond material processing, and particularly relates to a fixed disassembling device for processing a hard diamond material.

Background

Diamond, which is a mineral composed of carbon elements and is an allotrope of graphite, is the hardest substance naturally occurring in nature, and is used in a wide variety of applications, such as: artware, cutting tools in industry.

For example, application No.: CN201810732669.8 the invention discloses a diamond processing platform with omnibearing fine grinding function, the structure of which comprises a fine grinding mechanism, a control panel, a control switch, an operation turntable, a speed regulator, an electric cabinet, a processing sucker, a stop block and a processing platform, the invention enables the diamond processing platform to have the function of rotation through the arrangement of a rotation adjusting mechanism and a dust adsorption mechanism, avoids the problem that the position can be adjusted only after the fixing by manual rotation, avoids crushing and gravel influencing the processing precision of the diamond, effectively avoids the pollution of dust and gravel to the working environment, utilizes a sliding plate to move the diamond to the lower part of a cutting knife, greatly saves manpower and material resources, improves the working efficiency, drives a second motor to start through the control panel on the electric cabinet after the diamond is fixed by a pressing block, and controls the lifting of a hydraulic telescopic rod, so that the cutting knife rotating at high speed slowly approaches the diamond, and the cutting knife cuts the diamond at the moment.

Based on the search of the above patent and the discovery of the equipment in the prior art, the platform for processing and disassembling the raw material of the diamond has the following defects in practical application: the shapes of diamond raw materials are different, the number of the clamping mechanisms on the diamond raw material processing and disassembling platform is fixed, the position adjustable range is small, and the clamping mechanisms with proper number and any horizontal adjusting angle cannot be selected according to the different shapes of the diamond raw materials; when the diamond raw material is processed and disassembled, after a part is processed and disassembled to a certain degree, the position is moved manually, the part corresponding to the part is processed and disassembled on the diamond raw material is moved, and then the processing and disassembling efficiency is influenced.

Disclosure of Invention

In order to solve the technical problems, the invention provides a fixed disassembling device for machining hard diamond materials, which aims to solve the problems that the shapes of diamond raw materials are different, the number of clamping mechanisms on a diamond raw material machining disassembling platform is fixed, the position adjustable range is small, and the clamping mechanisms with proper number and any horizontal adjusting angle cannot be selected according to the different shapes of the diamond raw materials; when the diamond raw material is processed and disassembled, after a part is processed and disassembled to a certain degree, the position is moved manually, the part corresponding to the part is processed and disassembled on the diamond raw material is moved, and then the processing and disassembling efficiency is affected.

The invention relates to a fixed disassembling device for processing hard diamond material, which is realized by the following specific technical means:

a fixed disassembling device for machining hard diamond materials comprises a fixing mechanism, wherein a driving mechanism is installed at the left end of the fixing mechanism, and a rotating mechanism is rotatably installed at the top end of the fixing mechanism; the rotating mechanism is in meshing transmission with the driving mechanism; the rotating mechanism is fixedly connected with the disassembling and assembling mechanism; the top end of the rotating mechanism is connected with a clamping mechanism in a sliding manner, the number of the clamping mechanisms is not limited to one group, and the number of the clamping mechanisms can be increased or decreased; clamping mechanism is including square protruding piece, screw thread through-hole B, stop screw, spherical arch, ball, and the symmetry form is personally submitted to the arc piece periphery and is provided with two square protruding pieces altogether, and square protruding piece top face has seted up a screw thread through-hole B, and screw thread through-hole B female connection has stop screw, and square protruding piece bottom is personally submitted the symmetry form and is provided with two spherical archs altogether, and every spherical arch outer peripheral face all is each embedded rotation of evenly distributed form and installs three balls.

Further, the fixing mechanism comprises a square bottom plate, a square top plate, a right side supporting plate, a left side supporting plate, a bearing A, L-shaped mounting seat A and a bearing B, the middle parts of the side end faces at four positions of the square bottom plate are fixedly connected with an L-shaped mounting seat A, a mounting hole site is arranged on the long end face of the L-shaped mounting seat A, a square top plate is arranged right above the square bottom plate, a right side supporting plate is fixedly connected to the right side of the bottom end face of the square top plate, the bottom end surface of the right supporting plate is fixedly connected with the top end surface of the square bottom plate, a left supporting plate is fixedly connected to the left side of the bottom end surface of the square top plate, and the bottom end face of the left supporting plate is fixedly connected with the top end face of the square bottom plate, a bearing A is embedded in the center of the left end face of the left supporting plate, and a bearing B is embedded in the center of the top end face of the square top plate.

Furthermore, actuating mechanism is including motor, pivot A, drive bevel gear, the key connection has a drive bevel gear on the pivot A of motor, motor fixed mounting is on left side backup pad left end face, pivot A rotates with bearing A and is connected, drive bevel gear is located left side backup pad right side position.

Further, slewing mechanism is including square workstation, annular spout, square notch, L shape mount pad B, mounting hole, driven bevel gear, pivot B, a department annular spout has been seted up to square workstation top face, and annular spout cross-sectional structure is the major arc circle structure, a prescription shape breach has been seted up to square workstation top face lower right corner position, square workstation bottom surface is for the equal fixedly connected with L shape mount pad B of two terminal surface positions of square notch, L shape mount pad B long end corresponds to the square notch position, and has seted up the mounting hole on the long terminal surface of L shape mount pad B, square workstation bottom surface central point fixedly connected with a pivot B, and there is a driven bevel gear key-type connection pivot B bottom.

Furthermore, pivot B rotates with bearing B and is connected, and square workstation bottom end face is located square roof top face upper side position, and driven bevel gear is located square roof downside position, and driven bevel gear and the meshing transmission of initiative bevel gear.

Further, dismouting mechanism is including square board, arc spout, double-screw bolt A, nut, square board structure is unanimous with square notch structure, a department's arc spout has been seted up to square board top face, and arc spout cross-sectional structure is major arc circle structure, two double-screw bolts A of symmetry form looks fixedly connected with are personally submitted to square board bottom, and threaded connection has the nut on the double-screw bolt A, under square board and the square notch installation cooperation state, two double-screw bolts A pass two mounting holes respectively and via nut locking fixed, arc spout and annular spout are in same axle center position rather than the phase-match.

Further, clamping mechanism is including arc piece, cylindric arch, screw thread through-hole A, double-screw bolt B, bearing C, the square tight piece that presss from both sides, arc piece outer peripheral face center part is provided with a cylindric arch, and cylindric protruding axle center part sets up a screw thread through-hole A that link up the arc piece, screw thread through-hole A female connection has a double-screw bolt B, and double-screw bolt B right-hand member rotates through bearing C and is connected with a square tight piece that presss from both sides, double-screw bolt B left end fixedly connected with knob.

Further, under the installation state of the clamping mechanism and the rotating mechanism, the arc-shaped structure of the arc-shaped block and the annular chute are in the coaxial state, the spherical bulge is connected in the annular chute in a sliding mode, the spherical bulge is connected with the inner peripheral surface of the annular chute in a sliding mode through the balls, and the bottom end of the limiting screw is tightly attached to the top end face of the square workbench in a threaded locking state along the threaded through hole B.

Compared with the prior art, the invention has the following beneficial effects:

according to the invention, according to different shapes of hard diamond raw materials, an appropriate number of clamping mechanisms can be selected according to clamping requirements and are slidably arranged on the top end surface of the square workbench, when the hard diamond raw materials need to be clamped, the clamping mechanisms can be slidably adjusted along the annular sliding groove and the arc-shaped sliding groove according to appropriate clamping positions of the hard diamond raw materials, and the hard diamond raw materials can be clamped together through the square clamping blocks in the multiple groups of clamping mechanisms during clamping, so that the subsequent disassembling operation is convenient.

In the disassembling operation process, the motor can be started to drive the driving bevel gear to rotate according to the disassembling requirement through the control button electrically connected with the motor, the driving bevel gear is synchronously meshed with and drives the driven bevel gear to rotate, so that the hard diamond raw material clamped on the square workbench through the clamping mechanism is driven to horizontally rotate along with the driving bevel gear, and a worker can horizontally rotate and adjust the hard diamond raw material to a proper disassembling position without moving the position of the worker.

Drawings

Fig. 1 is a schematic structural diagram in a split state of the present invention.

Fig. 2 is a schematic top end axial view of the present invention in an assembled state.

Fig. 3 is a schematic front view of the present invention in an assembled state.

Fig. 4 is a schematic axial view of the bottom end of the assembled state of the present invention.

Fig. 5 is a top axial view of the fastening mechanism of the present invention.

Fig. 6 is a bottom axial view of the fastening mechanism of the present invention.

Fig. 7 is a schematic view of the driving mechanism of the present invention.

Fig. 8 is a top axial view of the turning mechanism of the present invention.

Fig. 9 is a bottom axial view of the rotating mechanism of the present invention.

Figure 10 is a top axial view of the mechanism of the present invention.

Figure 11 is a bottom axial view of the mechanism of the invention.

Fig. 12 is a schematic structural view of the clamping mechanism of the present invention in a disassembled state.

Fig. 13 is a bottom axial view of the arcuate block of the present invention.

FIG. 14 is a schematic view of the arcuate block structure of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a fixing mechanism; 101. a square bottom plate; 102. a square top plate; 103. a right support plate; 104. a left support plate; 105. a bearing A; 106. an L-shaped mounting seat A; 107. a bearing B; 2. a drive mechanism; 201. a motor; 202. a rotating shaft A; 203. a drive bevel gear; 3. a rotating mechanism; 301. a square work table; 302. an annular chute; 303. a square notch; 304. an L-shaped mounting base B; 305. mounting holes; 306. a driven bevel gear; 307. a rotating shaft B; 4. a disassembly and assembly mechanism; 401. a square plate; 402. an arc-shaped chute; 403. a stud A; 404. a nut; 5. a clamping mechanism; 501. an arc-shaped block; 502. a cylindrical protrusion; 503. a threaded through hole A; 504. a square bump; 505. a threaded through hole B; 506. a limiting screw; 507. a stud B; 508. a bearing C; 509. a square clamping block; 5010. a spherical bulge; 5011. a ball bearing;

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 14:

the invention provides a fixed disassembling device for processing hard diamond material, which comprises: the left end of the fixing mechanism 1 is provided with a driving mechanism 2, and the top end of the fixing mechanism 1 is rotatably provided with a rotating mechanism 3; the rotating mechanism 3 is in meshing transmission with the driving mechanism 2; the rotating mechanism 3 is fixedly connected with the disassembling and assembling mechanism 4; the top end of the rotating mechanism 3 is connected with a clamping mechanism 5 in a sliding way, and the number of the clamping mechanisms 5 is not limited to one group and can be increased or decreased; the clamping mechanism 5 comprises square protruding blocks 504, threaded through holes B505, limiting screws 506, spherical protrusions 5010 and balls 5011, the periphery of each arc-shaped block 501 is symmetrically provided with two square protruding blocks 504, the top end face of each square protruding block 504 is provided with one threaded through hole B505, the threaded through holes B505 are in threaded connection with the limiting screws 506, the bottom end of each square protruding block 504 is symmetrically provided with two spherical protrusions 5010, and the peripheral face of each spherical protrusion 5010 is uniformly distributed and is embedded with three balls 5011 in a rotating mode.

Wherein, the fixing mechanism 1 comprises a square bottom plate 101, a square top plate 102, a right side supporting plate 103, a left side supporting plate 104, a bearing A105, an L-shaped mounting seat A106 and a bearing B107, the middle parts of the four side end surfaces of the square bottom plate 101 are fixedly connected with the L-shaped mounting seat A106, a mounting hole is arranged on the long end face of the L-shaped mounting seat A106, a square top plate 102 is arranged right above the square bottom plate 101, a right side supporting plate 103 is fixedly connected to the right side of the bottom end face of the square top plate 102, the bottom end surface of the right supporting plate 103 is fixedly connected with the top end surface of the square bottom plate 101, the left side of the bottom end surface of the square top plate 102 is fixedly connected with a left supporting plate 104, the bottom end face of the left supporting plate 104 is fixedly connected with the top end face of the square bottom plate 101, a bearing A105 is embedded in the center of the left end face of the left supporting plate 104, and a bearing B107 is embedded in the center of the top end face of the square top plate 102.

The driving mechanism 2 comprises a motor 201, a rotating shaft A202 and a drive bevel gear 203, the rotating shaft A202 of the motor 201 is connected with the drive bevel gear 203 in a key mode, the motor 201 is fixedly installed on the left end face of the left supporting plate 104, the rotating shaft A202 is rotatably connected with a bearing A105, and the drive bevel gear 203 is located on the right side portion of the left supporting plate 104.

Wherein, the rotating mechanism 3 comprises a square workbench 301, an annular chute 302, a square notch 303, an L-shaped mounting seat B304, a mounting hole 305, a driven bevel gear 306 and a rotating shaft B307, the top end face of the square workbench 301 is provided with the annular chute 302, the cross-sectional structure of the annular chute 302 is a major arc circular structure, the lower right corner of the top end face of the square workbench 301 is provided with the square notch 303, the bottom end face of the square workbench 301 is fixedly connected with the L-shaped mounting seat B304 relative to the two end face parts of the square notch 303, the long end of the L-shaped mounting seat B304 corresponds to the square notch 303, the long end face of the L-shaped mounting seat B304 is provided with the mounting hole 305, the center part of the bottom end face of the square workbench 301 is fixedly connected with the rotating shaft B307, and the bottom key of the rotating shaft B307 is connected.

The rotating shaft B307 is rotatably connected with the bearing B107, the bottom end face of the square workbench 301 is located at the upper side part of the top end face of the square top plate 102, the driven bevel gear 306 is located at the lower side part of the square top plate 102, and the driven bevel gear 306 is in meshing transmission with the drive bevel gear 203.

Wherein, dismouting mechanism 4 is including square board 401, arc spout 402, double-screw bolt A403, nut 404, square board 401 structure is unanimous with square breach 303 structure, square board 401 top terminal surface has seted up one and has located arc spout 402, and arc spout 402 cross-sectional structure is major arc circle structure, two double-screw bolt A403 of symmetry form altogether fixedly connected with are personally submitted to square board 401 bottom, and threaded connection has nut 404 on the double-screw bolt A403, under square board 401 and the installation of square breach 303 cooperation state, two double-screw bolt A403 pass two mounting holes 305 respectively and via nut 404 locking fixed, arc spout 402 is in same axle center position rather than the phase-match with annular chute 302.

The clamping mechanism 5 comprises an arc-shaped block 501, a cylindrical protrusion 502, a thread through hole A503, a stud B507, a bearing C508 and a square clamping block 509, wherein the center of the outer peripheral surface of the arc-shaped block 501 is provided with the cylindrical protrusion 502, the axis of the cylindrical protrusion 502 is provided with the thread through hole A503 penetrating through the arc-shaped block 501, the thread through hole A503 is internally threaded with the stud B507, the right end of the stud B507 is rotatably connected with the square clamping block 509 through the bearing C508, and the left end of the stud B507 is fixedly connected with a knob.

When the clamping mechanism 5 and the rotating mechanism 3 are installed, the arc structure of the arc block 501 and the annular chute 302 are in a coaxial state, the spherical protrusion 5010 is slidably connected in the annular chute 302, the spherical protrusion 5010 is slidably connected with the inner circumferential surface of the annular chute 302 through the ball 5011, and the bottom end of the limit screw 506 is tightly attached to the top end surface of the square workbench 301 when the limit screw 506 is in a thread locking state along the thread through hole B505.

When in use:

placing hard diamond raw materials to be processed and disassembled on the top end face of the square workbench 301, and meanwhile, selecting a proper number of clamping mechanisms 5 to be slidably mounted on the top end face of the square workbench 301 according to different shapes of the hard diamond raw materials and clamping requirements by workers; when the clamping mechanism 5 is installed in a sliding manner, the nut 404 is disassembled through a tool, so that the stud A403 can be separated from the installation hole 305, the dismounting mechanism 4 is dismounted from the square notch 303 part of the square workbench 301, at the moment, the clamping mechanism 5 can be installed in the annular chute 302 in a sliding manner relative to the square notch 303 part through the spherical protrusions 5010 and the balls 5011, and after the corresponding number of clamping mechanisms 5 are selected and installed in a sliding manner, the dismounting mechanism 4 only needs to be fixedly installed at the square notch 303 part of the square workbench 301 through the matching of the nut 404 and the stud A403, and the sliding installation operation of the clamping mechanism 5 is completed;

when the hard diamond raw material needs to be clamped, the clamping mechanism 5 can be adjusted in a sliding mode along the annular sliding groove 302 and the arc-shaped sliding groove 402 according to the appropriate clamping position of the hard diamond raw material, the spherical bulge 5010 is connected with the inner circumferential surface of the annular sliding groove 302 in a sliding mode through the balls 5011, so that smooth and unimpeded sliding is guaranteed when the clamping mechanism is adjusted in a sliding mode along the annular sliding groove 302 and the arc-shaped sliding groove 402, after the position is adjusted, the limiting screw 506 can be locked downwards along the threaded through hole B505 through a tool, the bottom end of the limiting screw 506 is tightly attached to the top end face of the square workbench 301, and the clamping mechanism 5 after the current position is adjusted is; during clamping, the stud B507 can be screwed tightly along the thread through hole A503, and the bearing C508 converts the rotary motion of the stud B507 into linear motion, so that the square clamping block 509 is driven to gradually approach the hard diamond raw material, and the hard diamond raw material is clamped by the square clamping block 509 in other clamping mechanisms 5 together, so as to facilitate subsequent disassembling operation;

in the disassembling operation process, the motor 201 is started to drive the driving bevel gear 203 to rotate according to the disassembling requirement by a control button electrically connected with the motor 201, the driving bevel gear 203 synchronously engages with the driven bevel gear 306 to drive the hard diamond raw material clamped on the square workbench 301 through the clamping mechanism 5 to horizontally rotate therewith, and the worker does not need to move the position of the worker to horizontally rotate and adjust the hard diamond raw material to a proper disassembling position.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims

1. A fixed detaching device for processing hard diamond material is characterized in that: the device comprises a fixing mechanism (1), wherein a driving mechanism (2) is installed at the left end of the fixing mechanism (1), and a rotating mechanism (3) is rotatably installed at the top end of the fixing mechanism (1); the rotating mechanism (3) is in meshing transmission with the driving mechanism (2); the rotating mechanism (3) is fixedly connected with the disassembling and assembling mechanism (4); the top end of the rotating mechanism (3) is connected with a clamping mechanism (5) in a sliding manner, the number of the clamping mechanisms (5) is not limited to one group, and the number can be increased or decreased; clamping mechanism (5) is including square protruding piece (504), screw thread through-hole B (505), stop screw (506), the ball is protruding (5010), ball (5011), arc piece (501) periphery is personally submitted the symmetry and is provided with two square protruding pieces (504) altogether, and square protruding piece (504) top face has seted up one screw thread through-hole B (505), screw thread through-hole B (505) female connection has stop screw (506), square protruding piece (504) bottom is personally submitted the symmetry and is provided with two ball-type protrudingly (5010) altogether, three ball (5011) are installed in each embedded rotation of each ball-type protrudingly (5010) outer peripheral face of evenly distributed form.

2. A fixed dismantling device for machining hard diamond material as claimed in claim 1, wherein: the fixing mechanism (1) comprises a square bottom plate (101), a square top plate (102), a right side supporting plate (103), a left side supporting plate (104), a bearing A (105), an L-shaped mounting seat A (106) and a bearing B (107), wherein the middle part of the four side end faces of the square bottom plate (101) is fixedly connected with the L-shaped mounting seat A (106), the long end face of the L-shaped mounting seat A (106) is provided with a mounting hole position, the square top plate (102) is arranged right above the square bottom plate (101), the right side of the bottom end face of the square top plate (102) is fixedly connected with the right side supporting plate (103), the bottom end face of the right side supporting plate (103) is fixedly connected with the top end face of the square bottom plate (101), the left side of the bottom end face of the square top plate (102) is fixedly connected with the left side supporting plate (104), and the bottom end face of the, a bearing A (105) is embedded in the center of the left end face of the left side supporting plate (104), and a bearing B (107) is embedded in the center of the top end face of the square top plate (102).

3. A fixed dismantling device for machining hard diamond material as claimed in claim 1, wherein: the driving mechanism (2) comprises a motor (201), a rotating shaft A (202) and a driving bevel gear (203), the rotating shaft A (202) of the motor (201) is connected with the driving bevel gear (203) in a key mode, the motor (201) is fixedly installed on the left end face of the left side supporting plate (104), the rotating shaft A (202) is connected with a bearing A (105) in a rotating mode, and the driving bevel gear (203) is located on the right side portion of the left side supporting plate (104).

4. A fixed dismantling device for machining hard diamond material as claimed in claim 1, wherein: the rotating mechanism (3) comprises a square workbench (301), an annular sliding groove (302), a square notch (303), an L-shaped mounting seat B (304), a mounting hole (305), a driven bevel gear (306) and a rotating shaft B (307), wherein the top end surface of the square workbench (301) is provided with the annular sliding groove (302), the cross-sectional structure of the annular sliding groove (302) is of a U-arc circular structure, the lower right corner of the top end surface of the square workbench (301) is provided with the square notch (303), the bottom end surface of the square workbench (301) is fixedly connected with the L-shaped mounting seat B (304) relative to the two end surface parts of the square notch (303), the long end of the L-shaped mounting seat B (304) corresponds to the square notch (303), the long end surface of the L-shaped mounting seat B (304) is provided with the mounting hole (305), the central part of the bottom end surface of the square workbench (301) is fixedly connected with the rotating shaft B (307), and the bottom end key of the rotating shaft B (307) is connected with a driven bevel gear (306).

5. A fixed dismantling device for machining hard diamond material as claimed in claim 4, wherein: the rotating shaft B (307) is rotatably connected with the bearing B (107), the bottom end face of the square workbench (301) is located at the upper side part of the top end face of the square top plate (102), the driven bevel gear (306) is located at the lower side part of the square top plate (102), and the driven bevel gear (306) is in meshing transmission with the driving bevel gear (203).

6. A fixed dismantling device for machining hard diamond material as claimed in claim 1, wherein: dismouting mechanism (4) are unanimous including square board (401), arc spout (402), double-screw bolt A (403), nut (404), square board (401) structure is unanimous with square notch (303) structure, one arc spout (402) have been seted up to square board (401) top terminal surface, and arc spout (402) cross-sectional structure is major arc circle structure, two double-screw bolts A (403) of symmetry form common fixedly connected with are personally submitted to square board (401) bottom, and threaded connection has nut (404) on double-screw bolt A (403), under square board (401) and square notch (303) installation cooperation state, two double-screw bolt A (403) pass two mounting holes (305) respectively and via nut (404) locking fixed, arc spout (402) are in same axle center position rather than the phase-match with annular chute (302).

7. A fixed dismantling device for machining hard diamond material as claimed in claim 1, wherein: clamping mechanism (5) is including arc piece (501), cylindric arch (502), screw thread through-hole A (503), double-screw bolt B (507), bearing C (508), square clamp block (509), arc piece (501) outer peripheral face central point is provided with a cylindric arch (502), and cylindric arch (502) axle center part sets up one and link up screw thread through-hole A (503) of arc piece (501), screw thread through-hole A (503) female connection has a double-screw bolt B (507), and double-screw bolt B (507) right-hand member is connected with a square clamp block (509) through bearing C (508) rotation, double-screw bolt B (507) left end fixedly connected with knob.

8. A fixed dismantling device for machining hard diamond material as claimed in claim 1, wherein: under the installation state of the clamping mechanism (5) and the rotating mechanism (3), the arc structure of the arc block (501) and the annular sliding groove (302) are in a coaxial state, the spherical protrusion (5010) is connected in the annular sliding groove (302) in a sliding mode, the spherical protrusion (5010) is connected with the inner circumferential surface of the annular sliding groove (302) in a sliding mode through the ball (5011), and the bottom end of the limiting screw (506) is tightly attached to the top end face of the square workbench (301) along the threaded through hole B (505) in a threaded locking state.