CN116352480A - High-precision intelligent positioning and punching device for precision element machining - Google Patents

Abstract

A high-precision intelligent positioning and punching device for precision element processing belongs to the technical field of positioning and punching, and aims to solve the problem that the concentricity of an existing clamp can be ensured only by manually correcting the clamp for a plurality of times after the clamp clamps the element, so that the working efficiency is affected; according to the invention, the clamping blocks are driven by the limiting blocks to clamp and fix the element, the probes contact the surface of the element, the sliding cylinder is promoted to retract and compress the second spring, hydraulic oil in the sliding groove flows back into the storage cavity under the action of pressure, when the element is not positioned at the right center of the top of the rotating disc, the positions of the four groups of weight balls are different from the center of the top of the rotating disc, centrifugal force is generated when the rotating disc rotates, the weight balls stretch the first spring, the sliding plate slides in the movable inner cavity until the weight balls contact the pressure sensor, at the moment, the eccentricity can be calculated according to an eccentricity force calculation formula, and then the element can be positioned at the center of the top of the rotating disc through controlling the four groups of adjusting mechanisms and the clamping blocks.

Description

High-precision intelligent positioning and punching device for precision element machining

Technical Field

The invention relates to the technical field of positioning and punching, in particular to a high-precision intelligent positioning and punching device for precision element processing.

Background

In the existing metal element processing and punching process, most of clamping of parts or workpieces is performed in an outer clamping mode, most of common clamping devices are three-point clamping or four-point clamping, and some high-precision elements need to be guaranteed to be positioned at the center of a chuck when punching is performed.

The accuracy of the chuck cannot meet the requirements no matter the chuck is clamped at three points or four points, so that the chuck is required to be adjusted after the chuck is clamped in advance, the punching part of the chuck is positioned at the center part of a workpiece, the conventional means is to correct the chuck after detection through a dial indicator, and manual correction often needs to be debugged for a plurality of times, so that the processing efficiency is affected.

To solve the above problems. Therefore, a high-precision intelligent positioning and punching device for precision element processing is provided.

Disclosure of Invention

The invention aims to provide a high-precision intelligent positioning and punching device for precision element processing, which solves the problem that the concentricity of an existing clamp can be ensured only by manually correcting the clamp for a plurality of times after the clamp clamps the element in the background art, so that the working efficiency is affected.

In order to achieve the above purpose, the present invention provides the following technical solutions: the high-precision intelligent positioning and punching device for machining the precise element comprises a workbench, a rotary disc rotationally arranged on the workbench, a clamp movably arranged on the rotary disc, a drilling machine arranged at the top of the workbench and used for punching the center position of the element, four groups of clamps radially distributed, and a detection mechanism arranged in the clamp block, wherein the clamps are used for positioning and clamping the element and comprise an adjusting mechanism arranged on the rotary disc and further comprise a clamp block movably arranged on the rotary disc and a detection mechanism arranged in the clamp block;

the clamp splice is used for carrying out the centre gripping to the component, adjustment mechanism is used for carrying out the adjustment on the position to the clamp splice, detection mechanism is used for detecting the eccentricity, detection mechanism includes the sliding tube of sliding connection in the clamp splice, the one end fixedly connected with probe of sliding tube, the needle end and the component outer wall contact of probe, the second spring is installed to the other end of sliding tube, the inside of sliding tube is provided with pressure sensor and counter weight ball, the counter weight ball is used for extruding pressure sensor under centrifugal force effect when the rotary disk is rotatory, pressure sensor is used for detecting the pressure value that receives.

Further, the drive assembly includes the driving motor who installs in the workstation, and driving motor output fixedly connected with first gear, and drive assembly still is including rotating the axis of rotation of connecting in the workstation top, installs the bearing between axis of rotation and the workstation, and the outer fringe below of axis of rotation is provided with the tooth's socket, and first gear and tooth's socket meshing are connected, and axis of rotation fixed connection is at the bottom positive center of rotary disk.

Further, the drive assembly still includes fixed connection at the first spool between axis of rotation and the rotary disk, and the inside below of workstation is provided with high-speed sliding ring, and the top of high-speed sliding ring is provided with the second spool, and second spool fixed connection is in the axis of rotation below, and the one end of first spool extends to the inside of axis of rotation and is linked together with first gear.

Further, the top of rotary disk is provided with the spacing groove, and the side of rotary disk is provided with the mounting groove.

Further, adjustment mechanism includes the second motor of fixed mounting in the mounting groove inside, and second motor output fixedly connected with second gear, adjustment mechanism still includes the stopper of sliding connection in the mounting groove inside, threaded connection has the lead screw on the stopper, and the lead screw rotates the inside of connecting at the rotary disk, and the one end fixedly connected with third gear of lead screw, third gear and second gear meshing are connected.

Further, the clamp splice includes fixed block at stopper top fixed connection, and the one end fixedly connected with chuck that the fixed block is close to the rotary disk center, and the inboard of chuck is provided with the probe, and the gasket is arranged in preventing to lead to the fact the damage to the component in the centre gripping.

Further, the inside of fixed block and chuck is provided with the sliding tray, is provided with horizontal link up the groove in chuck and the gasket, link up the one end and the sliding tray intercommunication of groove, link up the groove other end and external intercommunication.

Further, the sliding cylinder is in sliding connection in the inside of sliding tray, and the outer wall of sliding cylinder is laminated with the inner wall of sliding tray, and the probe extends to the external world from the groove that link up, and the inside of sliding cylinder is provided with movable inner chamber.

Further, the pressure sensor is fixedly connected to the inner wall of one side of the movable inner cavity, the pressure sensor is connected with a connecting wire, the connecting wire is connected with the high-speed sliding ring through a first wire pipe, the inner wall of the other side of the movable inner cavity is fixedly connected with a first spring, the other end of the first spring is fixedly connected with a sliding plate, and the sliding plate is fixedly connected with the counterweight ball.

Further, the second spring is fixedly connected to the inner wall of the sliding groove, the detection mechanism further comprises a storage barrel fixedly connected to the top of the fixed block, a storage cavity is formed in the storage barrel, a communication groove is formed between the storage cavity and the sliding groove, a valve is arranged on the storage barrel, and hydraulic oil is filled in the storage cavity and the sliding groove.

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

according to the high-precision intelligent positioning punching device for machining the precise element, the second motor is started, the screw rod can be driven to rotate under the engagement of the second gear and the third gear, the clamping block can be driven to clamp and fix the element through the limiting block, the probe contacts the surface of the element, the sliding cylinder is promoted to retract and compress the second spring, hydraulic oil in the sliding groove flows back into the storage cavity under the action of pressure, when the element is not positioned at the center of the top of the rotating disc, the weight balls of four groups are different from the center of the top of the rotating disc, centrifugal force is generated when the rotating disc rotates, the weight balls stretch the first spring, the sliding plate slides in the movable inner cavity until the weight balls contact the pressure sensor, at the moment, the eccentricity can be calculated according to the calculation formula of the eccentricity, and then the element is positioned at the center of the top of the rotating disc through the adjusting mechanism and the clamping block by controlling the four groups, so that the element can be directly aligned to the center of the element during punching, the operation is simple and intelligent, and the working efficiency is high.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a split view of the overall structure of the present invention;

FIG. 3 is a split view of the rotary disk, drive assembly and clamp structure of the present invention;

FIG. 4 is a schematic view of a rotary disk structure according to the present invention;

FIG. 5 is a schematic view of a driving assembly according to the present invention;

FIG. 6 is a schematic view of a clamp structure according to the present invention;

FIG. 7 is a cross-sectional view of the clamp structure of the present invention;

fig. 8 is an exploded view of the clamp structure of the present invention.

In the figure: 1. a work table; 2. a drilling machine; 3. a rotating disc; 31. a limit groove; 32. a mounting groove; 4. a drive assembly; 41. a driving motor; 411. a first gear; 42. a rotating shaft; 421. tooth slots; 422. a bearing; 43. a first conduit; 432. a connecting wire; 44. a high-speed slip ring; 441. a second conduit; 5. a clamp; 51. an adjusting mechanism; 511. a second motor; 512. a second gear; 513. a limiting block; 514. a third gear; 515. a screw rod; 52. clamping blocks; 521. a fixed block; 522. a chuck; 523. a gasket; 524. a sliding groove; 525. a through groove; 526. a communication groove; 53. a detection mechanism; 531. a sliding cylinder; 5311. a movable inner cavity; 532. a probe; 533. a first spring; 534. a sliding plate; 535. a weight ball; 536. a pressure sensor; 537. a second spring; 538. a storage cylinder; 5381. a storage chamber; 539. and (3) a valve.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In order to solve the technical problem that the concentricity of the existing clamp can be ensured only by manually correcting the clamp for a plurality of times after clamping the element, and further the working efficiency is affected, as shown in fig. 1-8, the following preferable technical scheme is provided:

the high-precision intelligent positioning and punching device for machining the precise element comprises a workbench 1, a rotary disc 3 rotatably arranged on the workbench 1, a clamp 5 movably arranged on the rotary disc 3, a drilling machine 2 arranged at the top of the workbench 1, four groups of clamps 5 radially distributed on the drill 2 and used for positioning and clamping the element, and the clamp 5 comprises an adjusting mechanism 51 arranged on the rotary disc 3, a clamping block 52 movably arranged on the rotary disc 3 and a detection mechanism 53 arranged in the clamping block 52;

the clamp splice 52 is used for carrying out the centre gripping to the component, adjustment mechanism 51 is used for carrying out the adjustment on the position to the clamp splice 52, detection mechanism 53 is used for detecting the eccentricity, detection mechanism 53 includes sliding tube 531 of sliding connection in the clamp splice 52, the one end fixedly connected with probe 532 of sliding tube 531, the needle end and the component outer wall contact of probe 532, second spring 537 is installed to the other end of sliding tube 531, the inside of sliding tube 531 is provided with pressure sensor 536 and counter weight ball 535, counter weight ball 535 is used for pressing pressure sensor 536 under centrifugal force effect when rotary disk 3 is rotatory, pressure sensor 536 is used for detecting the pressure value that receives, judge its eccentricity after comparing through the pressure value that four sets of pressure sensor 536 received.

The driving assembly 4 comprises a driving motor 41 arranged in the workbench 1, the output end of the driving motor 41 is fixedly connected with a first gear 411, the driving assembly 4 further comprises a rotating shaft 42 rotatably connected above the workbench 1, a bearing 422 is arranged between the rotating shaft 42 and the workbench 1, tooth grooves 421 are arranged below the outer edge of the rotating shaft 42, the first gear 411 is meshed with the tooth grooves 421, the rotating shaft 42 is fixedly connected to the right center of the bottom of the rotating disc 3, the driving motor 41 is started, the driving motor 41 can drive the rotating shaft 42 to rotate through the tooth grooves 421 meshed with the first gear 411 so as to drive the rotating disc 3 to rotate, and if an element is positioned at the right center of the top of the rotating disc 3, the centrifugal force of the element in all directions is the same when the rotating disc 3 rotates.

The driving assembly 4 further comprises a first spool 43 fixedly connected between the rotating shaft 42 and the rotating disc 3, a high-speed slip ring 44 is arranged below the inside of the workbench 1, a second spool 441 is arranged above the high-speed slip ring 44, the second spool 441 is fixedly connected below the rotating shaft 42, and one end of the first spool 43 extends to the inside of the rotating shaft 42 and is communicated with the first gear 411.

The top of rotary disk 3 is provided with spacing groove 31, and the side of rotary disk 3 is provided with mounting groove 32.

The adjustment mechanism 51 comprises a second motor 511 fixedly arranged in the mounting groove 32, the output end of the second motor 511 is fixedly connected with a second gear 512, the adjustment mechanism 51 further comprises a limiting block 513 which is slidably connected in the mounting groove 32, a screw rod 515 is connected to the limiting block 513 in a threaded mode, the screw rod 515 is rotatably connected to the inside of the rotating disc 3, one end of the screw rod 515 is fixedly connected with a third gear 514, the third gear 514 is meshed with the second gear 512, the second motor 511 drives the screw rod 515 to rotate under the meshing of the second gear 512 and the third gear 514, and then the position of the limiting block 513 can be adjusted.

The clamping block 52 comprises a fixed block 521 fixedly connected to the top of the limiting block 513, a chuck 522 is fixedly connected to one end of the fixed block 521, which is close to the center of the rotating disk 3, a probe 532 is arranged on the inner side of the chuck 522, and a gasket 523 is used for preventing damage to elements during clamping.

The fixed block 521 and the collet 522 are internally provided with a sliding groove 524, the collet 522 and the washer 523 are internally provided with a transverse through groove 525, one end of the through groove 525 is communicated with the sliding groove 524, and the other end of the through groove 525 is communicated with the outside.

The sliding cylinder 531 is slidably connected to the inside of the sliding groove 524, the outer wall of the sliding cylinder 531 is attached to the inner wall of the sliding groove 524, the probe 532 extends from the through groove 525 to the outside, and a movable cavity 5311 is provided in the sliding cylinder 531.

The pressure sensor 536 is fixedly connected to the inner wall of one side of the movable cavity 5311, the pressure sensor 536 is connected with a connecting wire 432, the connecting wire 432 is connected with the high-speed sliding ring 44 through the first wire pipe 43, the inner wall of the other side of the movable cavity 5311 is fixedly connected with a first spring 533, the other end of the first spring 533 is fixedly connected with a sliding plate 534, and the sliding plate 534 is fixedly connected with the counterweight ball 535.

The second spring 537 is fixedly connected to the inner wall of the sliding groove 524, the detection mechanism 53 further comprises a storage cylinder 538 fixedly connected to the top of the fixed block 521, a storage cavity 5381 is arranged in the storage cylinder 538, a communication groove 526 is formed between the storage cavity 5381 and the sliding groove 524, a valve 539 is arranged on the storage cylinder 538, the valve 539 is optionally an electromagnetic valve, hydraulic oil is filled in the storage cavity 5381 and the sliding groove 524, after the adjusting mechanism 51 drives the clamping block 52 to clamp the element, the sliding cylinder 531 approaches to the center of the rotating disk 3 under the action of the second spring 537 until the needle end of the probe 532 is attached to the outer wall of the element, then the valve 539 is closed, so that the cavity between the sliding cylinder 531 and the inner wall of the sliding groove 524 is filled with hydraulic oil, at this time, the position of the pressure sensor 536 is fixed, if the element is in the center position, the rotating disk 3 rotates, the weight ball 535 is subjected to centrifugal force and is pressed on the pressure sensor 536, and the values of the four groups of pressure sensors 536 are the same.

Specifically, firstly, the component is placed in the middle position of the top of the rotating disc 3, then the second motor 511 is started, the screw rod 515 can be driven to rotate under the engagement of the second gear 512 and the third gear 514, then the clamping block 52 can be driven to clamp and fix the component through the limiting block 513, after the gasket 523 is attached to the component, the probe 532 extending from the through groove 525 contacts the surface of the component, the sliding cylinder 531 is prompted to retract and compress the second spring 537, hydraulic oil in the sliding groove 524 flows back into the storage cavity 5381 under the action of pressure, then the valve 539 is closed, because of incompressibility of the liquid, the position of the sliding cylinder 531 is in a fixed state, then the driving motor 41 is started, the first gear 411 is meshed with the tooth slot 421 to drive the rotation shaft 42 to rotate so as to drive the rotation disk 3 to rotate, if the element is located at the center of the top of the rotation disk 3, when the rotation disk 3 rotates, centrifugal forces in all directions of the element are the same, if the element is not located at the center of the top of the rotation disk 3, the positions of the four groups of weight balls 535 are different from the center of the top of the rotation disk 3, centrifugal forces are generated when the rotation disk 3 rotates, the weight balls 535 stretch the first spring 533, so that the sliding plate 534 slides in the movable inner cavity 5311 until the weight balls 535 contact the pressure sensor 536, at the moment, the eccentricity can be calculated according to an eccentricity force calculation formula, and then the element is located at the center of the top of the rotation disk 3 through controlling the four groups of adjusting mechanisms 51 and the clamping blocks 52.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should be covered by the protection scope of the present invention by making equivalents and modifications to the technical solution and the inventive concept thereof.

Claims (10)

1. The utility model provides a precision elements processing is with high accuracy intelligence location perforating device, includes workstation (1) and rotates rotary disk (3) that set up on workstation (1), still including activity anchor clamps (5) that set up on rotary disk (3), the top of workstation (1) still is provided with drilling machine (2), its characterized in that: the drilling machine (2) is used for punching the center position of the element, four groups of clamps (5) are radially distributed, the clamps (5) are used for positioning and clamping the element, the clamps (5) comprise an adjusting mechanism (51) arranged on the rotating disc (3), clamping blocks (52) movably arranged on the rotating disc (3) and a detecting mechanism (53) arranged in the clamping blocks (52);

the clamp splice (52) is used for carrying out the centre gripping to the component, adjustment mechanism (51) are used for carrying out the adjustment on the position to clamp splice (52), detection mechanism (53) are used for detecting the eccentricity, detection mechanism (53) are including sliding connection in clamp splice (52) slide tube (531), one end fixedly connected with probe (532) of slide tube (531), the needle end and the contact of component outer wall of probe (532), second spring (537) is installed to the other end of slide tube (531), the inside of slide tube (531) is provided with pressure sensor (536) and counter weight ball (535), counter weight ball (535) are used for pressing pressure sensor (536) under centrifugal force effect when rotary disk (3) are rotatory, pressure sensor (536) are used for detecting the pressure value that receives.

2. The high-precision intelligent positioning and punching device for precision element machining as claimed in claim 1, wherein: the driving assembly (4) comprises a driving motor (41) arranged in the workbench (1), a first gear (411) is fixedly connected to the output end of the driving motor (41), the driving assembly (4) further comprises a rotating shaft (42) which is rotatably connected to the upper portion of the workbench (1), a bearing (422) is arranged between the rotating shaft (42) and the workbench (1), tooth grooves (421) are formed in the lower portion of the outer edge of the rotating shaft (42), the first gear (411) is meshed with the tooth grooves (421), and the rotating shaft (42) is fixedly connected to the right center of the bottom of the rotating disc (3).

3. The high-precision intelligent positioning and punching device for precision element machining as claimed in claim 2, wherein: the driving assembly (4) further comprises a first spool (43) fixedly connected between the rotating shaft (42) and the rotating disc (3), a high-speed slip ring (44) is arranged below the inside of the workbench (1), a second spool (441) is arranged above the high-speed slip ring (44), the second spool (441) is fixedly connected below the rotating shaft (42), and one end of the first spool (43) extends to the inside of the rotating shaft (42) and is communicated with the first gear (411).

4. A high-precision intelligent positioning and punching device for precision element processing as claimed in claim 3, wherein: the top of rotary disk (3) is provided with spacing groove (31), and the side of rotary disk (3) is provided with mounting groove (32).

5. The high-precision intelligent positioning and punching device for precision element processing as claimed in claim 4, wherein: the adjusting mechanism (51) comprises a second motor (511) fixedly installed inside the installation groove (32), the output end of the second motor (511) is fixedly connected with a second gear (512), the adjusting mechanism (51) further comprises a limiting block (513) which is slidably connected inside the installation groove (32), a screw rod (515) is connected to the limiting block (513) in a threaded mode, the screw rod (515) is rotatably connected to the inside of the rotating disc (3), one end of the screw rod (515) is fixedly connected with a third gear (514), and the third gear (514) is meshed with the second gear (512).

6. The high-precision intelligent positioning and punching device for precision element machining as claimed in claim 5, wherein: the clamp splice (52) includes fixed block (521) of fixed connection at stopper (513) top, and one end fixed block (521) are close to rotary disk (3) center fixedly connected with chuck (522), and the inboard of chuck (522) is provided with probe (532), and gasket (523) are arranged in preventing to lead to the fact the damage to the component in the centre gripping.

7. The high-precision intelligent positioning and punching device for precision element processing as claimed in claim 6, wherein: the inside of fixed block (521) and chuck (522) is provided with sliding groove (524), is provided with horizontal through groove (525) in chuck (522) and gasket (523), and the one end and the sliding groove (524) of through groove (525) communicate, and the other end and the external world of through groove (525) communicate.

8. The high-precision intelligent positioning and punching device for precision element processing as claimed in claim 7, wherein: the sliding cylinder (531) is connected in the inside of sliding tray (524) in a sliding way, and the outer wall of sliding cylinder (531) is laminated with the inner wall of sliding tray (524), and probe (532) are extended to the external world from link up groove (525), and the inside of sliding cylinder (531) is provided with movable inner chamber (5311).

9. The high-precision intelligent positioning and punching device for precision element machining as claimed in claim 8, wherein: pressure sensor (536) fixed connection is in movable inner chamber (5311) one side inner wall, is connected with connecting wire (432) on pressure sensor (536), and connecting wire (432) are connected with high-speed sliding ring (44) through first line pipe (43), and opposite side inner wall fixedly connected with first spring (533) of movable inner chamber (5311), first spring (533) other end fixedly connected with sliding plate (534), sliding plate (534) and counter weight ball (535) fixed connection.

10. The high-precision intelligent positioning and punching device for precision element machining as claimed in claim 9, wherein: the second spring (537) is fixedly connected to the inner wall of the sliding groove (524), the detection mechanism (53) further comprises a storage barrel (538) fixedly connected to the top of the fixed block (521), a storage cavity (5381) is formed in the storage barrel (538), a communication groove (526) is formed between the storage cavity (5381) and the sliding groove (524), a valve (539) is arranged on the storage barrel (538), and hydraulic oil is filled in the storage cavity (5381) and the sliding groove (524).

Images