CN211805570U - Curve feeding mechanism - Google Patents

Abstract

The utility model relates to the technical field of ultra-precision machining machinery, in particular to a curve feeding mechanism, which comprises a machine base, a clamping component and a curve feeding component, wherein the top of the machine base is provided with a horizontal machining platform, the clamping component is arranged on the machining platform along the Z-axis direction in a penetrating way, the top of the clamping component is arranged above the machining platform and is used for clamping and positioning a workpiece for machining, the curve feeding component is arranged on the machine base and is arranged below the machining platform and drives the workpiece clamped on the clamping component to move and feed along a curve on the horizontal plane where the X-axis and the Y-axis are positioned, an eccentric feeding component is arranged on the clamping component for clamping the workpiece, the eccentric feeding component is utilized to drive the clamping component to rotate, the clamping component replaces the existing linear feeding mode along the curve feeding, and in the curve feeding process, the inclination angle between a curve path and a machining cutter is formed, the technical problem of stress concentration when a workpiece touches a machining cutter is solved.

Description

Curve feeding mechanism

Technical Field

The utility model relates to a super precision machining machinery technical field specifically is a curve feed mechanism.

Background

In the working process of the superfinishing machine, a workpiece is clamped on a clamping tool, then the workpiece is fed to a tool bit or a grinding head of a machining tool for machining the workpiece in a linear manner through the movement of the clamping work, the machining tool and the machining surface of the workpiece are subjected to frequently reciprocating collision machining in a linear sliding manner, on one hand, a bearing on an electric spindle which respectively drives the workpiece and the machining tool to rotate is stressed in the collision process, the stress point on the bearing is invariable all the time, the stress is excessively concentrated, the bearing is abraded, the service life is shortened sharply, the stability in the working process of the electric spindle is reduced, the machining precision is reduced, on the other hand, the linear contact between the machining tool and the workpiece directly causes the stress concentration on the contact surface of the machining tool in the contact process of the machining tool, and the abrasion of the machining tool is intensified, and the processing precision of the workpiece is reduced.

Patent document CN201410797974.7 discloses a grinding machine for numerical control twin columns vertical grinding machine workstation base bearing guide surface, the headstock matches with numerical control twin columns vertical grinding machine workstation base spindle hole, the main shaft up end has the via hole that matches with the screw hole on the numerical control twin columns vertical grinding machine workstation base, the main shaft is connected in the headstock, the reducing gear box is connected on the headstock, the crossbeam is connected on the reducing gear box left side, the headstock is connected on the crossbeam guide rail, be connected with the slide on the headstock, bistrique longitudinal connection is under the slide.

However, the technical solution provided in the above patent does not solve the above mentioned technical problem that the workpiece is linearly fed to the processing tool, resulting in a reduction of the processing precision.

SUMMERY OF THE UTILITY MODEL

To above problem, the utility model provides a curve feed mechanism, it sets up the eccentric subassembly of feeding through the utilization on going on pressing from both sides tight clamp material subassembly to the work piece, utilize the eccentric subassembly of feeding to drive and press from both sides the material subassembly and carry out eccentric rotation, realize that the clamp material subassembly feeds the mode of replacing current sharp feeding along the curve, feed the in-process through the curve, the bearing stress point takes place to change all the time and the inclination that exists between curve route and the processing cutter, stress concentration's technical problem when solving the touching between work piece and the processing cutter.

In order to achieve the above object, the utility model provides a following technical scheme:

the utility model provides a curve feed mechanism, includes the frame, and the top of this frame is provided with horizontally processing platform, still includes:

the clamping assembly penetrates through the processing platform along the Z-axis direction, the top of the clamping assembly is positioned above the processing platform, and the clamping assembly is used for clamping and positioning a workpiece to be processed; and

and the curve feeding assembly is arranged on the machine base, is positioned below the machining platform and drives the workpiece clamped on the clamping assembly to move and feed along a curve on a horizontal plane where the X axis and the Y axis are positioned.

As a refinement, the curve feed assembly comprises:

the eccentric shell is eccentrically sleeved on the material clamping assembly, and when the eccentric shell rotates along the axial direction of the eccentric shell, the material clamping assembly is driven to move along a curve on a horizontal plane; and

and the rotating unit is adjacently arranged on one side of the eccentric shell and drives the eccentric shell to rotate around the axial direction of the eccentric shell.

As an improvement, an inner ring of the eccentric shell is provided with a first step protruding inwards, the first step is used for bearing a first bearing sleeved on the material clamping assembly, the first bearing enables the material clamping assembly to rotate relative to the eccentric shell, a back cap limiting the first bearing is arranged above the first step, and the back cap is mounted on the eccentric shell in a threaded fit mode.

As an improvement, the rotation unit includes:

the driven gear is coaxially sleeved on the eccentric shell, and the eccentric shell rotates synchronously with the driven gear;

the driving gear is adjacent to the driven gear and is meshed with the driven gear; and

and the driver drives the driving gear to rotate, so that the driven gear is driven to rotate.

As a refinement, the curve feed assembly further comprises:

the fixed plate is horizontally and fixedly arranged below the processing platform, and a sliding groove is formed in the fixed plate along the X-axis direction; and

the sliding plate is arranged along the sliding groove in a sliding mode, a waist groove is formed in the sliding plate in the Y-axis direction, the clamping component penetrates through the waist groove, the clamping component is arranged in an abutting mode with the edge of the waist groove, a step is arranged at the bottom of the waist groove, and the step is used for supporting and sleeving a second bearing outside the clamping component.

As an improvement, a second step protruding outwards is arranged on the outer ring of the eccentric shell, a third bearing is sleeved on the second step, the outer ring of the third bearing is mounted on the fixed plate, and the third bearing enables the eccentric shell to be arranged in a rotating mode relative to the fixed plate.

As an improvement, the clamping assembly sequentially comprises a chuck unit and an electric spindle from top to bottom along the Z-axis direction, the chuck unit is located above the processing platform, the workpiece is clamped by the chuck unit, the upper end of the electric spindle penetrates through the processing platform and drives the chuck unit to rotate along the Z-axis direction.

As an improvement, the chuck unit comprises a three-jaw chuck for clamping the workpiece and a magnetic chuck for connecting the three-jaw chuck and the electric spindle.

As an improvement, the diameter of the penetrating position of the electric spindle and the processing platform is phi 1, the aperture for the electric spindle to penetrate through is phi 2, and the relation between phi 1 and phi 2 satisfies: phi 1 is less than phi 2.

As an improvement, a transition disc is covered at the position where the upper end part of the electric spindle is matched with the machining platform in a penetrating mode.

The beneficial effects of the utility model reside in that:

(1) the utility model discloses a utilize and set up the eccentric feeding subassembly on the clamp material subassembly that presss from both sides tightly the work piece, utilize the eccentric feeding subassembly to drive the clamp material subassembly and carry out eccentric rotation, realize that the clamp material subassembly feeds along the curve and replaces the mode of current straight line feeding, through the curve in the feeding process, on the stress concentration contact point when avoiding touching between work piece and the processing cutter, improve the precision in the processing process;

(2) the utility model discloses a set up eccentric casing, with eccentric casing cover establish drive work piece rotatory electric main shaft, later drive eccentric casing through the rotary unit and rotate around Z axle direction for electric main shaft feeds along the curve on the horizontal plane, contradicts with the processing cutter and processes, wherein rotary unit preferred is gear drive unit, the transmission is accurate, efficient, the reliability is high;

(3) the utility model discloses set up the transition dish that the cover was established in the position department that electric main shaft and processing platform wore to establish, cover the hole that is used for wearing to establish electric main shaft on the processing platform, avoided the impurity in the course of working, the metal fillings fall into, keep the clean and tidy of eccentric feeding subassembly inside, avoid impurity, metal fillings to influence the transmission precision of rotary unit;

(4) the utility model discloses a set up fixed plate and sliding plate, utilize the sliding plate to support electric main shaft on the one hand, on the other hand for electric main shaft and work piece are carrying out the in-process that the curve fed, utilize the cooperation of electric main shaft and sliding plate, make the sliding plate slide along the spout on the fixed plate, feed the curve of work piece and provide the direction, improve the stability of eccentric feeding subassembly, improve the machining precision.

To sum up, the utility model has the advantages of machining precision is high, stability is high, long service life, is particularly useful for super precision machining machinery technical field.

Drawings

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

FIG. 2 is a schematic view of a partial three-dimensional structure of the present invention;

FIG. 3 is a schematic top view of the eccentric housing of the present invention;

fig. 4 is a schematic view of the initial state of the eccentric housing of the present invention;

FIG. 5 is a schematic view of the eccentric housing rotating curve feeding state of the present invention;

FIG. 6 is a schematic cross-sectional view of the material clamping assembly of the present invention;

FIG. 7 is an enlarged view of the structure at B in FIG. 6;

fig. 8 is a schematic sectional view of the eccentric housing of the present invention;

FIG. 9 is a schematic side view of the rotary unit of the present invention;

FIG. 10 is a schematic top view of the sliding plate of the present invention;

fig. 11 is a schematic sectional view of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

Example 1:

as shown in fig. 1 to 3, a curve feeding mechanism includes a base 1, a horizontal processing platform 11 is disposed on the top of the base 1, and the curve feeding mechanism further includes:

the clamping component 2 penetrates through the processing platform 11 along the Z-axis direction, the top of the clamping component 2 is positioned above the processing platform 11, and the clamping component is used for clamping and positioning a workpiece 10 to be processed; and

and the curve feeding assembly 3 is arranged on the machine base 1, is positioned below the processing platform 11 and drives the workpiece 10 clamped on the clamping assembly 2 to move and feed along a curve on a horizontal plane where the X axis and the Y axis are positioned.

Further, the curve feeding assembly 3 comprises:

the eccentric shell 31 is eccentrically sleeved on the material clamping component 2, and when the eccentric shell 31 rotates along the axial direction of the eccentric shell 31, the material clamping component 2 is driven to move along a curve on a horizontal plane; and

and the rotating unit 32 is arranged at one side of the eccentric shell 31 in an adjacent mode, and drives the eccentric shell 31 to rotate around the axial direction of the eccentric shell 31.

The inner ring of the eccentric shell 31 is provided with a first step 311 protruding inwards, the first step 311 is used for bearing a first bearing 201 sleeved on the material clamping assembly 2, the first bearing 201 enables the material clamping assembly 2 to rotate relative to the eccentric shell 31, a back cap 202 for limiting the first bearing 201 is arranged above the first step 311, and the back cap 202 is mounted on the eccentric shell 31 through thread fit.

As shown in fig. 6 to 8, it should be noted that, during the feeding process, the eccentric housing 31 is driven to rotate around its own axial direction by the rotation of the rotating unit 32, during the rotation process, the clamping assembly 2 clamping the workpiece 10 moves eccentrically around the axis of the eccentric housing 31, so that the workpiece 10 approaches the machining tool in a curved feeding path on a horizontal plane, and as the machining tool and the workpiece 10 approach each other, the inclination angle α between the machining tool and the workpiece 10 gradually decreases, and at the moment when the machining tool collides with the workpiece 10, the acting force between the machining tool and the workpiece 10 is weakened by the setting of the inclination angle α, so that the stress between the machining tool 1 and the workpiece 10 is reduced, the existence of stress concentration points is avoided, the abrasion of the bearing is reduced, the stability of the clamping assembly 2 is improved, and the machining precision of the workpiece 10 is improved.

It is further described that, by providing the first bearing 201, the clamping assembly 2 and the eccentric shell 31 can rotate relatively, so that when the eccentric shell 31 rotates automatically, the clamping assembly 2 is driven to move eccentrically, and when the workpiece 10 needs to rotate automatically, the clamping assembly 2 can also rotate automatically when the workpiece 10 needs to rotate automatically.

It should be further noted that the structure of the curve feeding assembly 3 in the present application is not limited to the arrangement structure of the eccentric shell 31, and all structures that can drive the clamping assembly 2 to perform the eccentric movement belong to the protection scope of the present application.

Example 2:

fig. 9 is a schematic structural diagram of embodiment 2 of a curve feeding mechanism according to the present invention; as shown in fig. 9, in which the same or corresponding components as those in embodiment 1 are denoted by the same reference numerals as those in embodiment 1, only the points of difference from embodiment one will be described below for the sake of convenience. This embodiment 2 differs from the embodiment 1 shown in fig. 1 in that:

as shown in fig. 9, the rotating unit 42 includes:

the driven gear 421, the driven gear 421 is coaxially sleeved on the eccentric housing 41, and the eccentric housing 41 rotates synchronously with the driven gear 421;

a driving gear 422, wherein the driving gear 422 is adjacent to the driven gear 421 and is meshed with the driven gear 421; and

and the driver 423 drives the driving gear 422 to rotate, so as to drive the driven gear 421 to rotate.

It should be noted that, in the present embodiment, the rotating unit 42 is preferably a gear transmission unit, and by utilizing the characteristics of accurate transmission, high efficiency and high reliability of the gear transmission unit, in the process of driving the driving gear 422 to rotate through the driver 423, the driving gear 422 drives the driven gear 421 to rotate, so that the eccentric housing 41 rotates.

It is further explained that all the mechanical structures that satisfy the present invention and drive the eccentric housing 41 to rotate all belong to the protection scope of the rotating unit 42 of the present invention.

Example 3:

fig. 10 is a schematic structural view of embodiment 3 of a curve feeding mechanism according to the present invention; as shown in fig. 10, in which the same or corresponding components as those in embodiment 1 are denoted by the same reference numerals as those in embodiment 1, only points different from embodiment 1 will be described below for the sake of convenience. This embodiment 3 differs from embodiment 1 shown in fig. 1 in that:

as shown in fig. 10, the eccentric feed assembly 3 further includes:

a fixing plate 33, wherein the fixing plate 33 is horizontally and fixedly installed below the processing platform 11, and a sliding groove 331 is arranged on the fixing plate 33 along the X-axis direction; and

the sliding plate 34 is arranged along the sliding groove 331 in a sliding manner, a waist groove 341 is formed in the sliding plate 34 along the Y-axis direction, the clamping component 2 is arranged in the waist groove 341 in a penetrating manner, the clamping component 2 is arranged in an abutting manner with the edge of the waist groove 341, a step 342 is formed in the bottom of the waist groove 341, and the step 342 is used for supporting and sleeving the second bearing 203 arranged outside the clamping component 2.

Further, a second step 312 protruding outward is disposed on an outer ring of the eccentric housing 31, a third bearing 204 is sleeved on the second step 312, an outer ring of the third bearing 204 is mounted on the fixed plate 33, and the third bearing 204 enables the eccentric housing 31 to rotate relative to the fixed plate 33.

It should be noted that, in order to improve the stability of the clamping assembly 2 in the moving process, the eccentric feeding assembly 3 is further provided with a fixed plate 33 and a sliding plate 34, in the process of the curved movement of the clamping assembly 2, the sliding plate 34 supports a bearing sleeved outside the clamping assembly 2 through a step 342, and further supports the clamping assembly 2, so as to improve the stability of the clamping assembly 2 in the curved movement process, and through the cooperation between the waist groove 341 on the sliding plate 34 and the clamping assembly 2, in the process of the curved movement of the clamping assembly 2, the sliding plate 34 also synchronously slides along the sliding groove 331 on the fixed plate 33 to guide the clamping assembly 2, so that the clamping assembly 2 moves more stably, and the grinding precision of the workpiece 10 is improved.

It is further noted that the outer ring of the eccentric housing 31 is mounted and connected to the fixed plate 33 through the third bearing 204, so that the eccentric housing 31 can rotate with respect to the fixed plate 33.

Example 4:

fig. 11 is a schematic structural diagram of embodiment 4 of a curve feeding mechanism according to the present invention; as shown in fig. 11, in which the same or corresponding components as those in embodiment 1 are denoted by the same reference numerals as those in embodiment 1, only points different from embodiment 1 will be described below for the sake of convenience. This embodiment 4 differs from the embodiment 1 shown in fig. 1 in that:

as shown in fig. 11, the material clamping assembly 2 sequentially includes a chuck unit 21 and an electric spindle 22 coaxially disposed from top to bottom along the Z-axis direction, the chuck unit 21 is located above the processing platform 11, the workpiece 10 is clamped by the chuck unit, and an upper end of the electric spindle 22 penetrates through the processing platform 11 and drives the chuck unit 21 to rotate along the Z-axis direction.

Further, the chuck unit 21 includes a three-jaw chuck 211 for gripping the workpiece 10 and a magnetic chuck 212 for connecting the three-jaw chuck 211 and the electric spindle 22.

Furthermore, the diameter of the penetrating portion of the electric spindle 22 and the processing platform 11 is phi 1, the processing platform 11 has an aperture phi 2 through which the electric spindle 22 penetrates, and the relationship between phi 1 and phi 2 satisfies: phi 1 is less than phi 2.

In addition, a transition disc 221 is covered at the position where the upper end of the electric spindle 22 is in fit with the machining platform 11 in a penetrating manner.

It should be noted that, in this embodiment, the clamping assembly 2 preferably employs the three-jaw chuck 211 to clamp the workpiece 10, and the magnetic chuck 212 is used to connect the electric spindle 22 and the three-jaw chuck 211, and the electric spindle 22 drives the workpiece 10 to rotate, and in addition, the transition disk 221 is disposed at the penetrating position of the electric spindle 22 and the processing platform 11 to cover the hole formed by the power supply spindle 22 on the processing platform 11, so as to prevent the generated dust and sweeps from falling into the eccentric feeding assembly 3 and damaging the eccentric feeding assembly 3 during the grinding process.

It is further explained that, by forming a hole on the machining platform 11, the power supply spindle 22 moves in a curved manner on the machining platform 11, thereby avoiding interference between the machining platform 11 and the power supply spindle 22.

The working process is as follows:

initially, the workpiece 10 is clamped by the three-jaw chuck 211, then the driver 323 is started, the driven gear 321 coaxially arranged with the eccentric shell 31 is matched with the driving gear 322 installed on the driver 323 to drive the eccentric shell 31 to rotate, and in the process of rotating the eccentric shell 31, the clamping assembly 2 moves along a curve on a horizontal plane to drive the workpiece 10 to feed to the machining cutter, and finally the workpiece 10 is abutted against the machining cutter, and the machining cutter grinds the workpiece 10.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The utility model provides a curve feed mechanism, includes frame (1), and the top of this frame (1) is provided with horizontally processing platform (11), its characterized in that still includes:

the clamping assembly (2) penetrates through the processing platform (11) along the Z-axis direction, the top of the clamping assembly (2) is positioned above the processing platform (11), and the clamping assembly is used for clamping and positioning a workpiece (10) for processing; and

the curve feeding assembly (3) is installed on the machine base (1), is located below the machining platform (11) and drives the workpiece (10) clamped on the clamping assembly (2) to move and feed along a curve on a horizontal plane where an X axis and a Y axis are located.

2. The curve feed mechanism according to claim 1, characterized in that the curve feed assembly (3) comprises:

the eccentric shell (31) is eccentrically sleeved on the material clamping component (2), and when the eccentric shell (31) rotates along the axial direction of the eccentric shell, the material clamping component (2) is driven to move along a curve on a horizontal plane; and

the rotating unit (32) is arranged on one side of the eccentric shell (31) in an adjacent mode, and drives the eccentric shell (31) to rotate around the axial direction of the eccentric shell.

3. The curve feeding mechanism according to claim 2, wherein a first step (311) protruding inwards is arranged on an inner ring of the eccentric housing (31), the first step (311) is used for bearing a first bearing (201) sleeved on the clamping assembly (2), the first bearing (201) enables the clamping assembly (2) to be rotatably arranged relative to the eccentric housing (31), a back cap (202) for limiting the first bearing (201) is arranged above the first step (311), and the back cap (202) is mounted on the eccentric housing (31) through threaded fit.

4. Curve feeding mechanism according to claim 2, characterized in that the rotating unit (32) comprises:

the driven gear (321), the driven gear (321) is coaxially sleeved on the eccentric shell (31), and the eccentric shell (31) rotates synchronously with the driven gear (321);

a drive gear (322), wherein the drive gear (322) is adjacent to the driven gear (321), and is meshed with the driven gear (321); and

the driver (323), the driver (323) drive the driving gear (322) and rotate, and then drive the driven gear (321) to rotate.

5. The curve feed mechanism according to claim 2, characterized in that the curve feed assembly (3) further comprises:

the fixing plate (33), the said fixing plate (33) is fixed and mounted below the said processing platform (11) horizontally, there are chutes (331) on it along the direction of X-axis; and

the sliding plate (34) is arranged along the sliding groove (331) in a sliding mode, a waist groove (341) is formed in the sliding plate (34) along the Y-axis direction, the clamping component (2) penetrates through the waist groove (341), the clamping component (2) is arranged in a mode of abutting against the edge of the waist groove (341), a step (342) is arranged at the bottom of the waist groove (341), and the step (342) is used for supporting and sleeving a second bearing (203) outside the clamping component (2).

6. The curve feeding mechanism according to claim 5, characterized in that a second step (312) protruding outwards is provided on the outer ring of the eccentric housing (31), a third bearing (204) is sleeved on the second step (312), the outer ring of the third bearing (204) is mounted on the fixed plate (33), and the third bearing (204) enables the eccentric housing (31) to be rotatably arranged relative to the fixed plate (33).

7. The curve feeding mechanism according to claim 1, wherein the clamping assembly (2) comprises a chuck unit (21) and an electric spindle (22) coaxially arranged from top to bottom in sequence along the Z-axis direction, the chuck unit (21) is located above the processing platform (11) and clamps the workpiece (10), and an upper end of the electric spindle (22) penetrates through the processing platform (11) and drives the chuck unit (21) to rotate along the Z-axis direction.

8. The curve feeding mechanism according to claim 7, characterized in that the collet unit (21) comprises a three-jaw chuck (211) for gripping the workpiece (10) and a magnetic chuck (212) for connecting the three-jaw chuck (211) with the electric spindle (22).

9. The curve feeding mechanism according to claim 7, wherein the diameter of the penetration portion of the electric spindle (22) and the processing platform (11) is Φ 1, the processing platform (11) has a hole diameter of Φ 2 for the electric spindle (22) to penetrate, and the relationship between Φ 1 and Φ 2 satisfies: phi 1 is less than phi 2.

10. The curve feeding mechanism according to claim 7, wherein a transition disc (221) is covered at a position where the upper end of the electric spindle (22) is in penetrating fit with the processing platform (11).

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