CN113334116A - Double-inclined-surface workpiece and machining method of clamp body thereof - Google Patents
Double-inclined-surface workpiece and machining method of clamp body thereof Download PDFInfo
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- CN113334116A CN113334116A CN202110721812.5A CN202110721812A CN113334116A CN 113334116 A CN113334116 A CN 113334116A CN 202110721812 A CN202110721812 A CN 202110721812A CN 113334116 A CN113334116 A CN 113334116A
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23Q—DETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
- B23Q3/00—Devices holding, supporting, or positioning work or tools, of a kind normally removable from the machine
- B23Q3/02—Devices holding, supporting, or positioning work or tools, of a kind normally removable from the machine for mounting on a work-table, tool-slide, or analogous part
- B23Q3/06—Work-clamping means
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23Q—DETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
- B23Q11/00—Accessories fitted to machine tools for keeping tools or parts of the machine in good working condition or for cooling work; Safety devices specially combined with or arranged in, or specially adapted for use in connection with, machine tools
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Abstract
The invention discloses a machining method of a double-inclined-surface clamp body, a double-inclined-surface workpiece clamp body and a machining method of a double-inclined-surface workpiece. Firstly, fitting and installing a process positioning reference surface of a fixture body with a machine tool workbench to enable the top surfaces of all front positioning pieces and the top surfaces of all rear positioning pieces to be coplanar and ensure the verticality between the front side surface of the rear positioning piece and the top surface of the rear positioning piece; then, positioning and clamping the standard sample piece on the fixture body, and grinding a process positioning reference surface of the bottom plate to ensure the parallelism between the bottom surface of the bottom plate and a machine tool workbench; turning over the clamp body to enable the bottom surface of the clamp body to be attached to a machine tool workbench, grinding the front side surface of the front positioning piece to ensure the parallelism between the front side surface of the front positioning piece and the front side surface of the standard sample piece or the front end surface of the front flange, and measuring the distance between the front side surface of the standard sample piece and the distance between the front end surface of the front flange and the front side surface of the front positioning piece; therefore, the clamp body produced by the standard sample piece can meet the processing requirement of the double-inclined-plane workpiece.
Description
Technical Field
The invention relates to the technical field of machining, in particular to a double-inclined-surface workpiece and a machining method of a clamp body of the double-inclined-surface workpiece.
Background
Fig. 1 is a schematic structural diagram of a workpiece with double inclined surfaces. The double-bevel workpiece comprises a workpiece body 1, wherein the upper parts of a front side surface 2 and a rear side surface 3 of the workpiece body 1 are respectively provided with a front flange 4 and a rear flange 5 which extend outwards. The front side surface 2 of the workpiece body 1 is provided with an upper groove 6 and a lower groove 7, and the front side surface 2 and the front end surface 4a of the front flange 4 are arranged obliquely with respect to the rear side surface 3. The top surface 8 and the bottom surface 9 of the workpiece body are obliquely arranged. For the double-inclined-plane workpiece, if machine tool equipment is directly adopted for machining, because the inclination angle between the front side surface 2 and the rear side surface 3 and the inclination angles of the top surface and the bottom surface are difficult to position, the error angle of the machined double-inclined-plane workpiece is caused, and the consistency of the product is poor.
Disclosure of Invention
In view of the above, the present invention provides a double-bevel workpiece and a machining method for a fixture body thereof, in which the produced fixture body is used to clamp a double-bevel workpiece to be machined, so as to realize machining and positioning of double bevels and ensure machining accuracy and product consistency.
In order to achieve the purpose, the invention provides the following technical scheme:
the invention firstly provides a processing method of a double-inclined-plane clamp body, wherein the clamp body comprises a bottom plate, and a front positioning component in positioning fit with the front side surface of a double-inclined-plane workpiece, a rear positioning component in positioning fit with the rear side surface of the double-inclined-plane workpiece and a side positioning component in positioning fit with the left side surface or the right side surface of the double-inclined-plane workpiece are arranged on the bottom plate;
the front positioning assembly comprises a front positioning unit, the front positioning unit comprises a front positioning column and a front positioning piece arranged on the rear side of the top of the front positioning column, the rear side surface of the front positioning piece is used for positioning and matching with the front side surface of the double-inclined-plane workpiece, and the top surface of the front positioning piece is used for positioning and matching with the bottom surface of the front flange of the double-inclined-plane workpiece;
the rear positioning assembly comprises a rear positioning unit, the rear positioning unit comprises a rear positioning column and a rear positioning piece arranged on the front side of the top of the rear positioning column, the front side surface of the rear positioning piece is used for positioning and matching with the rear side surface of the double-inclined-plane workpiece, and the top surface of the rear positioning piece is used for positioning and matching with the bottom surface of the rear flange of the double-inclined-plane workpiece;
a process positioning reference surface is arranged on the bottom surface of the bottom plate;
the method comprises the following steps:
the method comprises the following steps: mounting the technological positioning reference surface of the fixture body on a machine tool workbench;
11) grinding the top surfaces of all the front positioning pieces and the top surfaces of all the rear positioning pieces to enable the top surfaces of all the front positioning pieces and the top surfaces of all the rear positioning pieces to be coplanar, wherein the flatness error between the plane where the top surfaces of the front positioning pieces and the top surfaces of the rear positioning pieces are located and the process positioning reference plane is smaller than or equal to a set threshold value;
12) grinding the front side surface of the rear positioning piece to enable the perpendicularity error between the front side surface of the rear positioning piece and a plane where the top surface of the front positioning piece and the top surface of the rear positioning piece are located to be smaller than or equal to a set threshold value;
step two: positioning and mounting a standard sample piece of a double-inclined-surface workpiece on the fixture body, so that the front side surface of the standard sample piece is in positioning fit with the rear side surface of the front positioning piece, and the bottom surface of the front flange is in positioning fit with the top surface of the front positioning piece; positioning and matching the rear side surface of the standard sample piece and the front side surface of the rear positioning piece, positioning and matching the bottom surface of the rear flange and the top surface of the rear positioning piece, and positioning and matching the left side surface or the right side surface of the standard sample piece and the side positioning component;
21) positioning and matching the top surface of the standard sample piece with a machine tool workbench, and polishing the bottom surface of the clamp body to ensure that the parallelism error between the bottom surface of the clamp body and the machine tool workbench is less than or equal to a set threshold value;
22) installing the ground bottom surface of the fixture body on a machine tool workbench, enabling the front side surface of the standard sample piece or the front end surface of the front flange to be parallel to the moving direction of the machine tool workbench, grinding the front side surface of the front positioning piece, and enabling the parallelism error between the front side surface of the front positioning piece and the front side surface of the standard sample piece or the front end surface of the front flange to be smaller than or equal to a set threshold value; and simultaneously measuring and recording the distance between the front side surface of the standard sample piece, the front end surface of the front flange and the front side surface of the front positioning piece.
Furthermore, the front positioning piece is also provided with a measuring reference surface parallel to the top surface of the front positioning piece, and the measuring reference surface is positioned on the lower side and the front side of the top surface; and in the second step, the method further comprises a step 23) of polishing the measuring reference surface of the front positioning piece, and measuring and recording the distance between the measuring reference surface of the front positioning piece and the top surface of the standard sample piece.
The invention also provides a double-inclined-surface clamp body which is obtained by processing the double-inclined-surface clamp body by the processing method.
Further, the front positioning assembly comprises at least two front positioning units which are arranged at intervals.
Further, the rear positioning assembly comprises at least two rear positioning units arranged at intervals.
Furthermore, the side positioning assembly comprises a side positioning column, and a positioning pin used for being matched with the left side surface or the right side surface of the double-inclined-surface workpiece in a positioning mode is arranged on the side positioning column.
The invention also provides a machining method of the double-inclined-surface workpiece, which comprises the following steps:
the method comprises the following steps: installing the clamp body according to any one of claims 3 to 6, installing the bottom surface of the clamp body on a machine tool workbench and attaching the bottom surface of the clamp body to the machine tool workbench, and enabling the parallelism error between the front side surface of the front positioning piece and the moving direction of the machine tool workbench to be smaller than a set threshold value;
step two: clamping a double-inclined-surface workpiece for substitute machining on the fixture body, so that the front side surface of the double-inclined-surface workpiece is in positioning fit with the rear side surface of the front positioning piece, and the bottom surface of the front flange is in positioning fit with the top surface of the front positioning piece; positioning and matching the rear side surface of the double-inclined-surface workpiece with the front side surface of the rear positioning piece, positioning and matching the bottom surface of the rear flange with the top surface of the rear positioning piece, and positioning and matching the left side surface or the right side surface of the double-inclined-surface workpiece with the side surface positioning component;
processing the top surface of the double-bevel workpiece to ensure that the parallelism error between the workpiece and a machine tool worktable is less than a set threshold value;
processing the front side surface of the double-bevel workpiece to ensure that the parallelism error between the front side surface of the double-bevel workpiece and the front side surface of the front positioning piece is less than or equal to a set threshold value, and the error of the distance between the front side surface of the double-bevel workpiece and the front side surface of the front positioning piece is in a set error range based on a recorded numerical value;
and machining the front end face of the front flange of the double-bevel workpiece to enable the parallelism error between the front end face and the front side face of the front positioning piece to be less than or equal to a set threshold value and enable the error of the distance between the front end face and the front side face of the front positioning piece to be within a set error range based on a recorded numerical value.
Furthermore, the top of the front positioning piece is also provided with a measuring reference surface parallel to the top surface of the front positioning piece, and the measuring reference surfaces are positioned on the lower side and the front side of the top surface;
and machining the top surface of the double-inclined-surface workpiece to enable the error of the distance between the top surface of the double-inclined-surface workpiece and the measuring reference surface of the front positioning piece to be within a set error range based on the recorded data.
The invention has the beneficial effects that:
the processing method of the double-inclined-plane clamp body comprises the steps of firstly, fitting and installing a process positioning reference surface of the clamp body with a machine tool workbench, grinding a positioning surface which needs to be matched with a double-inclined-plane workpiece in a positioning mode in the clamp body, enabling the top surfaces of all front positioning pieces and the top surfaces of all rear positioning pieces to be coplanar, and meanwhile guaranteeing the perpendicularity between the front side surface of each rear positioning piece and the top surface of each rear positioning piece so as to realize positioning and clamping of a standard sample piece of the double-inclined-plane workpiece; after the standard sample piece is positioned and clamped on the clamp body, the top surface of the standard sample piece is attached to a machine tool workbench, and then a process positioning reference surface of the bottom plate is polished to ensure the parallelism between the bottom surface of the bottom plate and the machine tool workbench; then turning over the clamp body to enable the bottom surface of the clamp body to be attached to a machine tool workbench, wherein the front side surface of the standard sample piece or the front end surface of the front flange is parallel to the moving direction of the machine tool workbench, grinding the front side surface of the front positioning piece to ensure the parallelism between the front side surface of the front positioning piece and the front side surface of the standard sample piece or the front end surface of the front flange, and then measuring the distances between the front side surface of the standard sample piece and the front end surface of the front flange and the front side surface of the front positioning piece to serve as the size positioning reference for subsequent double-inclined-plane workpiece processing; therefore, the clamp body for clamping the double-inclined-surface workpiece is produced by using the standard sample piece, the machining requirement of the double-inclined-surface workpiece can be met, the error between the machined double-inclined-surface workpiece and the standard sample piece can be controlled within a set threshold value, and the machining precision and the product consistency can be ensured.
Drawings
In order to make the object, technical scheme and beneficial effect of the invention more clear, the invention provides the following drawings for explanation:
FIG. 1 is a schematic view of a workpiece having dual bevel surfaces;
fig. 2-4 are schematic structural views of the double-bevel clamp body when the clamp body is processed in the first step of the processing method of the invention, wherein fig. 2 is a front view; FIG. 3 is a right side view; FIG. 4 is a top view;
fig. 5-7 are schematic structural views of the double-bevel clamp body when the clamp body is processed in step two of the processing method of the invention, wherein fig. 5 is a front view; FIG. 6 is a top view; FIG. 7 is a left side view;
FIGS. 8 to 10 are schematic structural views illustrating the processing of a double-bevel workpiece by a fixture in the method for processing a double-bevel workpiece according to the present invention; wherein, fig. 8 is a front view; FIG. 9 is a right side view; fig. 10 is a plan view.
Description of reference numerals:
1-a workpiece body; 2-front side; 3-rear side; 4-a front flange; 4 a-front end face; 5-rear flange; 6-upper groove; 7-lower groove; 8-top surface; 9-bottom surface;
10-a base plate; 10 a-a process positioning datum plane; 11-front locating posts; 12-a front positioning element; 12 a-the rear side; 12 b-top surface; 12 c-front side; 12 d-measuring the datum level; 13-rear positioning column; 14-rear positioning element; 14 a-front side; 14 b-top surface; 15-side locating posts; 16-a locating pin; 17-a platen; 18-standard sample; 19-double bevel workpiece.
Detailed Description
The present invention is further described with reference to the following drawings and specific examples so that those skilled in the art can better understand the present invention and can practice the present invention, but the examples are not intended to limit the present invention.
The fixture body of the embodiment comprises a bottom plate 10, wherein a front positioning component matched with the front side surface 2 of the double-inclined-surface workpiece in a positioning mode, a rear positioning component matched with the rear side surface 3 of the double-inclined-surface workpiece and a side positioning component matched with the left side surface or the right side surface of the double-inclined-surface workpiece in a positioning mode are arranged on the bottom plate 10.
The front positioning assembly comprises a front positioning unit, the front positioning unit comprises a front positioning column 11 and a front positioning piece 12 installed on the rear side of the top of the front positioning column 11, the rear side face 12a of the front positioning piece 12 is used for being in positioning fit with the front side face 2 of the double-inclined-plane workpiece, and the top face 12b of the front positioning piece is used for being in positioning fit with the bottom face of the front flange 4 of the double-inclined-plane workpiece. Preferably, the front positioning member 12 of the present embodiment is further provided with a measuring reference surface 12d parallel to the top surface 12b thereof, and the measuring reference surface 12d is located at the lower side and the front side of the top surface 12 b.
The rear positioning assembly comprises a rear positioning unit, the rear positioning unit comprises a rear positioning column 13 and a rear positioning piece 14 arranged on the front side of the top of the rear positioning column 13, the front side surface 14a of the rear positioning piece 14 is used for being in positioning fit with the rear side surface 3 of the double-inclined-plane workpiece, and the top surface 14b of the rear positioning piece is used for being in positioning fit with the bottom surface of the rear flange 5 of the double-inclined-plane workpiece.
The bottom surface of the base plate 10 is provided with a process positioning reference surface 10 a.
The machining method of the double-bevel clamp body comprises the following steps:
the method comprises the following steps: the process positioning reference surface 10a of the fixture body is mounted on the machine table as shown in fig. 2-4.
11) The top surfaces 12a of all the front positioning pieces 12 and the top surfaces 14b of the rear positioning pieces 14 are polished to make the top surfaces 12a of all the front positioning pieces 12 and the top surfaces 14b of the rear positioning pieces 14 coplanar, and the flatness error between the plane where the top surface 12a of the front positioning piece 12 and the top surface 14b of the rear positioning piece 14 are located and the process positioning reference surface 10a is less than or equal to a set threshold, and the flatness error between the plane where the top surface 12a of the front positioning piece 12 and the top surface 14b of the rear positioning piece 14 are located and the process positioning reference surface 10a is less than or equal to 0.002mm in the embodiment.
The front side surface 14a of the rear positioning piece 14 is ground by the grinding tool 12, so that the verticality error between the front side surface 14a of the rear positioning piece 14 and a plane A where the top surface 12a of the front positioning piece 12 and the top surface 14b of the rear positioning piece 14 are smaller than or equal to a set threshold value. The error in the perpendicularity between the front side surface 14a of the rear positioning member 14 and the plane a in which the top surface 12a of the front positioning member 12 and the top surface 14b of the rear positioning member 14 lie is 0.005mm or less in this embodiment.
Step two: positioning and mounting a standard sample piece of a double-inclined-surface workpiece on a fixture body, so that a front side surface 2 of the standard sample piece is in positioning fit with a rear side surface 12a of a front positioning piece 12, and the bottom surface of a front flange 4 is in positioning fit with a top surface 12b of the front positioning piece 12; the rear side 3 of the master piece is positioned in registration with the front side 14a of the rear locating member 14, the bottom surface of the rear flange 5 is positioned in registration with the top surface 14b of the rear locating member 14, and either the left or right side of the master piece is positioned in registration with the side locating component, see fig. 5-7.
21) And (3) positioning and matching the top surface 8 of the standard sample piece with a machine tool workbench, grinding the bottom surface 10 of the clamp body to enable the parallelism error between the bottom surface 10 of the clamp body and the machine tool workbench to be less than or equal to a set threshold value, namely grinding a process positioning reference surface 10a on the bottom surface of the bottom plate 10 to enable the parallelism error between the bottom surface of the bottom plate 10 and the machine tool workbench to be less than or equal to 0.002 mm.
22) Installing the ground bottom surface 10 of the fixture body on a machine tool workbench, enabling the front side surface 2 of the standard sample or the front end surface 4a of the front flange 4 to be parallel to the moving direction of the machine tool workbench, grinding the front side surface 12c of the front positioning piece 12, and enabling the parallelism error between the front side surface 12c of the front positioning piece 12 and the front side surface 2 of the standard sample or the front end surface 4a of the front flange 4 to be less than or equal to a set threshold value; the distance between the front side 2 of the standard sample and the front end face 4a of the front flange 4 and the front side 12c of the front positioning element 12 is measured and recorded at the same time. Since the front side surface 2 of the master sample or the front end surface 4a of the front flange 4 are parallel to each other, the front side surface 2 of the master sample or the front end surface 4a of the front flange 4 may be used as a positioning reference surface parallel to the moving direction of the machine tool table. In the embodiment, the front end face 4a of the front flange 4 of the standard sample is used as a positioning reference surface, and the parallelism between the front end face 4a of the front flange 4 of the standard sample and the moving direction of the machine tool workbench is measured and corrected by a dial indicator, so that the parallelism error between the front end face 4a of the front flange 4 of the standard sample and the moving direction of the machine tool workbench is less than or equal to 0.002 mm.
23) And grinding the measuring reference surface 12d of the front positioning piece 12, and measuring and recording the distance between the measuring reference surface 12d of the front positioning piece 12 and the top surface 8 of the standard sample piece, wherein the distance is mainly used for limiting the grinding thickness of the top surface 8 of the double-bevel workpiece.
The processing method of the double-inclined-plane clamp body comprises the steps of firstly, fitting a process positioning reference surface of the clamp body with a machine tool workbench, grinding a positioning surface which needs to be matched with a double-inclined-plane workpiece in a positioning mode in the clamp body, enabling the top surfaces of all front positioning pieces and the top surfaces of all rear positioning pieces to be coplanar, and meanwhile guaranteeing the verticality between the front side surface of each rear positioning piece and the top surface of each rear positioning piece to achieve positioning and clamping of a standard sample piece of the double-inclined-plane workpiece; after the standard sample piece is positioned and clamped on the clamp body, the top surface of the standard sample piece is attached to a machine tool workbench, and then a process positioning reference surface of the bottom plate is polished to ensure the parallelism between the bottom surface of the bottom plate and the machine tool workbench; then turning over the clamp body to enable the bottom surface of the clamp body to be attached to a machine tool workbench, wherein the front side surface of the standard sample piece or the front end surface of the front flange is parallel to the moving direction of the machine tool workbench, grinding the front side surface of the front positioning piece to ensure the parallelism between the front side surface of the front positioning piece and the front side surface of the standard sample piece or the front end surface of the front flange, and then measuring the distances between the front side surface of the standard sample piece and the front end surface of the front flange and the front side surface of the front positioning piece to serve as the size positioning reference for subsequent double-inclined-plane workpiece processing; therefore, the clamp body for clamping the double-inclined-plane workpiece is produced by the standard sample piece, the machining requirement of the double-inclined-plane workpiece can be met, the error between the machined double-inclined-plane workpiece and the standard sample piece can be controlled within a set threshold value, and machining precision and product consistency can be guaranteed.
The embodiment also provides the double-inclined-surface clamp body processed by the processing method of the double-inclined-surface clamp body. Specifically, the front positioning assembly of the double-bevel clamp body of the embodiment comprises at least two front positioning units arranged at intervals; the rear positioning assembly comprises at least two rear positioning units arranged at intervals. The front positioning assembly of the embodiment comprises two front positioning units which are arranged at intervals; the rear positioning assembly comprises two rear positioning units arranged at intervals. The side positioning component of the double-inclined-plane fixture body of the embodiment comprises a side positioning column 15, and a positioning pin 16 used for being matched with the left side surface or the right side surface of the double-inclined-plane workpiece in a positioning mode is arranged on the side positioning column 15.
The embodiment also provides a method for processing the double-bevel workpiece based on the double-bevel clamp body processed by the processing method of the double-bevel clamp body. Specifically, the method for machining the double-bevel workpiece of the embodiment includes the following steps:
the method comprises the following steps: and (3) mounting the clamp body, namely mounting the bottom surface 10 of the clamp body on a machine tool workbench and attaching the clamp body to the machine tool workbench, so that the parallelism error between the front side surface 12c of the front positioning piece 12 and the moving direction of the machine tool workbench is smaller than a set threshold value. Specifically, after the bottom surface 10 of the clamp body is attached to a machine tool workbench, the clamp body is pressed by a pressing plate 17 and is not pressed at first; and then, the front side surface 12c of the front positioning piece 12 is aligned by a dial indicator to be parallel to the moving direction of the workbench, the parallelism error is less than or equal to 0.002mm, after the pressing plate is properly pressed, the parallelism error of the front side surface 12c of the front positioning piece 12 is again ensured to be still less than 0.002mm, the clamp body is pressed, after the parallelism error between the front side surface 12c of the front positioning piece 12 and the moving direction of the machine tool workbench is confirmed again to be less than 0.002mm, the clamp body is finally fixed on the machine tool workbench, and the fixation of the clamp body is completed.
Step two: clamping a double-bevel workpiece for substitute machining on a fixture body, so that the front side surface of the double-bevel workpiece is in positioning fit with the rear side surface 12a of the front positioning piece 12, and the bottom surface of the front flange 4 is in positioning fit with the top surface 12b of the front positioning piece 12; the rear side surface of the double-inclined-surface workpiece is in positioning fit with the front side surface 14a of the rear positioning piece 14, the bottom surface of the rear flange 5 is in positioning fit with the top surface 14b of the rear positioning piece 14, and the left side surface or the right side surface of the double-inclined-surface workpiece is in positioning fit with the side positioning component, the left side surface of the double-inclined-surface workpiece is in positioning fit with the side positioning component in the embodiment, and specifically, the left side surface of the double-inclined-surface workpiece is in contact fit with the positioning pin 16.
Machining the top surface 8 of the double-bevel workpiece to ensure that the parallelism error between the workpiece and the machine tool worktable is less than a set threshold value; specifically, the top of the front positioning member 12 is further provided with a measuring reference surface 12d parallel to the top surface 12b thereof, and the measuring reference surface 12d is located on the front side of the top surface 12 b. Machining the top surface 8 of the double-bevel workpiece to a distance L from the measuring reference surface 12d of the front positioning member 121Within a set error range based on the recorded data, the present embodiment allows the distance L between the top surface 8 of the double-bevel workpiece and the measuring reference surface 12d of the front positioning piece 121The maximum error range of (2) is 0.005 mm.
Machining the front side surface 2 of the double-bevel workpiece so that the parallelism error between the front side surface 2 and the front side surface 12c of the front positioning piece 12 is less than or equal to a set threshold value, and the distance L between the front side surface 12c of the front positioning piece 12 and the front side surface2Is within a set error range based on the recorded values. The error of parallelism between the front side surface 2 of the double-bevel workpiece and the front side surface 12c of the front positioning piece 12 is less than or equal to 0.002mm, and the distance L between the front side surface 2 of the double-bevel workpiece and the front side surface 12c of the front positioning piece 122The maximum error range of (2) is 0.005 mm.
Machining the front end face 4a of the front flange 4 of the double-bevel workpiece to make the parallelism error between the front end face and the front side face 12c of the front positioning piece 12 less than or equal to a set threshold value and to make the distance L between the front end face and the front side face 12c of the front positioning piece 123Within a set error range based on the recorded values. The error of parallelism between the front end face 4a of the front flange 4 of the double-bevel workpiece and the front side face 12c of the front positioning piece 12 is less than or equal to 0.002mm, and the distance L between the front end face 4a of the front flange 4 of the double-bevel workpiece and the front side face 12c of the front positioning piece 12 is less than or equal to 0.002mm3The maximum error range of (2) is 0.005 mm.
The above-mentioned embodiments are merely preferred embodiments for fully illustrating the present invention, and the scope of the present invention is not limited thereto. The equivalent substitution or change made by the technical personnel in the technical field on the basis of the invention is all within the protection scope of the invention. The protection scope of the invention is subject to the claims.
Claims (8)
1. A processing method of a double-bevel clamp body is characterized in that: the fixture body comprises a bottom plate (10), wherein a front positioning component in positioning fit with the front side surface (2) of the double-inclined-surface workpiece, a rear positioning component in positioning fit with the rear side surface (3) of the double-inclined-surface workpiece and a side positioning component in positioning fit with the left side surface or the right side surface of the double-inclined-surface workpiece are arranged on the bottom plate (10);
the front positioning assembly comprises a front positioning unit, the front positioning unit comprises a front positioning column (11) and a front positioning piece (12) arranged on the rear side of the top of the front positioning column (11), the rear side surface (12a) of the front positioning piece (12) is used for being in positioning fit with the front side surface (2) of the double-inclined-plane workpiece, and the top surface (12b) of the front positioning piece is used for being in positioning fit with the bottom surface of a front flange (4) of the double-inclined-plane workpiece;
the rear positioning assembly comprises a rear positioning unit, the rear positioning unit comprises a rear positioning column (13) and a rear positioning piece (14) arranged on the front side of the top of the rear positioning column (13), the front side surface (14a) of the rear positioning piece (14) is used for being in positioning fit with the rear side surface (3) of the double-inclined-surface workpiece, and the top surface (14b) of the rear positioning piece is used for being in positioning fit with the bottom surface of a rear flange (5) of the double-inclined-surface workpiece;
a process positioning reference surface (10a) is arranged on the bottom surface of the bottom plate (10);
the method comprises the following steps:
the method comprises the following steps: mounting a process positioning reference surface (10a) of the fixture body on a machine tool workbench;
11) grinding the top surfaces (12a) of all the front positioning pieces (12) and the top surfaces (14b) of all the rear positioning pieces (14) to enable the top surfaces (12a) of all the front positioning pieces (12) and the top surfaces (14b) of all the rear positioning pieces (14) to be coplanar, wherein the flatness error between the plane where the top surfaces (12a) of the front positioning pieces (12) and the top surfaces (14b) of the rear positioning pieces (14) are located and the process positioning reference surface (10a) is smaller than or equal to a set threshold value;
12) grinding the front side surface (14a) of the rear positioning piece (14) to enable the perpendicularity error between the front side surface (14a) of the rear positioning piece (14) and a plane where the top surface (12a) of the front positioning piece (12) and the top surface (14b) of the rear positioning piece (14) are located to be smaller than or equal to a set threshold value;
step two: positioning and mounting a standard sample piece of a double-inclined-surface workpiece on the fixture body, so that the front side surface of the standard sample piece is in positioning fit with the rear side surface (12a) of the front positioning piece (12), and the bottom surface of the front flange (4) is in positioning fit with the top surface (12b) of the front positioning piece (12); positioning and matching the rear side surface of the standard sample piece with the front side surface (14a) of the rear positioning piece (14), positioning and matching the bottom surface of the rear flange (5) with the top surface (14b) of the rear positioning piece (14), and positioning and matching the left side surface or the right side surface of the standard sample piece with the side positioning component;
21) positioning and matching the top surface of the standard sample piece with a machine tool workbench, and polishing the bottom surface (10) of the clamp body to ensure that the parallelism error between the bottom surface (10) of the clamp body and the machine tool workbench is less than or equal to a set threshold value;
22) installing the ground bottom surface (10) of the fixture body on a machine tool workbench, enabling the front side surface (2) or the front end surface (4a) of the front flange (4) of the standard sample piece to be parallel to the moving direction of the machine tool workbench, grinding the front side surface (12c) of the front positioning piece (12), and enabling the parallelism error between the front side surface (12c) of the front positioning piece (12) and the front end surface (4a) of the front side surface (2) or the front flange (4) of the standard sample piece to be smaller than or equal to a set threshold value; and simultaneously measuring and recording the distance between the front side surface (2) of the standard sample piece and the front end surface (4a) of the front flange (4) and the front side surface (12c) of the front positioning piece (12).
2. The machining method of the double-bevel clamp body according to claim 1, characterized in that: the front positioning piece (12) is also provided with a measuring reference surface (12d) parallel to the top surface (12b), and the measuring reference surface (12d) is positioned on the lower side and the front side of the top surface (12 b); and in the second step, the method further comprises a step 23 of grinding the measuring reference surface (12d) of the front positioning piece (12), and measuring and recording the distance between the measuring reference surface (12d) of the front positioning piece (12) and the top surface (8) of the standard sample piece.
3. The utility model provides a double inclined plane anchor clamps body which characterized in that: the double-bevel clamp is machined by the machining method of the double-bevel clamp body as claimed in claim 1 or 2.
4. The double bevel clamp body of claim 3, wherein: the front positioning assembly comprises at least two front positioning units which are arranged at intervals.
5. The double bevel clamp body of claim 3, wherein: the rear positioning assembly comprises at least two rear positioning units arranged at intervals.
6. The double bevel clamp body of claim 3, wherein: the side positioning assembly comprises a side positioning column (15), and a positioning pin (16) used for being in positioning fit with the left side surface or the right side surface of the double-inclined-surface workpiece is arranged on the side positioning column (15).
7. A machining method of a double-bevel workpiece is characterized by comprising the following steps: the method comprises the following steps:
the method comprises the following steps: installing the clamp body according to any one of claims 3 to 6, installing the bottom surface (10) of the clamp body on and in abutment with a machine tool table, so that the error in parallelism between the front side surface (12c) of the front positioning piece (12) and the direction of movement of the machine tool table is less than a set threshold;
step two: clamping a double-bevel workpiece for substitute machining on the fixture body, so that the front side surface of the double-bevel workpiece is in positioning fit with the rear side surface (12a) of the front positioning piece (12), and the bottom surface of the front flange (4) is in positioning fit with the top surface (12b) of the front positioning piece (12); positioning and matching the rear side surface of the double-inclined-surface workpiece with the front side surface (14a) of the rear positioning piece (14), positioning and matching the bottom surface of the rear flange (5) with the top surface (14b) of the rear positioning piece (14), and positioning and matching the left side surface or the right side surface of the double-inclined-surface workpiece with the side positioning component;
machining the top surface (8) of the double-bevel workpiece to ensure that the parallelism error between the workpiece and the machine tool worktable is less than a set threshold value;
machining the front side surface (2) of the double-bevel workpiece to enable the parallelism error between the front side surface (12c) of the front positioning piece (12) and the front side surface to be less than or equal to a set threshold value and enable the error of the distance between the front side surface (12c) of the front positioning piece (12) and the front side surface to be within a set error range based on a recorded numerical value;
and machining the front end surface (4a) of the front flange (4) of the double-bevel workpiece to enable the parallelism error between the front end surface and the front side surface (12c) of the front positioning piece (12) to be less than or equal to a set threshold value, and enabling the error of the distance between the front end surface and the front side surface (12c) of the front positioning piece (12) to be within a set error range based on a recorded numerical value.
8. The method of claim 7, wherein: the top of the front positioning piece (12) is also provided with a measuring reference surface (12d) parallel to the top surface (12b), and the measuring reference surface (12d) is positioned on the lower side and the front side of the top surface (12 b);
machining the top surface (8) of the double-bevel workpiece so that the error of the distance between the top surface and the measuring reference surface (12d) of the front positioning piece (12) is within a set error range based on recorded data.
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CN114654277B (en) | 2023-04-11 |
CN114654277A (en) | 2022-06-24 |
CN113334116B (en) | 2022-06-03 |
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