CN112475399A - Double-side machining process of linear sliding block - Google Patents

Abstract

The invention relates to a slider side surface processing technology, and discloses a double-surface processing technology of a linear slider, wherein a first positioning mechanism is started, and two adjacent side surfaces of the linear slider to be processed respectively abut against a rear positioning plate and a side positioning plate of a positioning plate; starting a second positioning mechanism, and pushing the linear sliding block with the processing to be in close contact with the rear positioning plate; starting a pressing mechanism, and pressing a pressure head on a linear sliding block to be processed; resetting the first positioning mechanism to enable the rear positioning plate and the side positioning plate to be far away from the linear sliding block to be machined; starting the milling cutter mechanisms, and carrying out double-side processing on the linear sliding blocks to be processed by the two opposite milling cutter mechanisms; after the two opposite side surfaces of the processed linear sliding block are processed, the pressing mechanism releases pressure, and the rotating table drives the supporting seat to rotate for 90 degrees; and restarting the milling cutter mechanism until the other two side surfaces of the linear slide block are processed. When the process is used for machining the linear sliding block, the machining efficiency is high, and the positioning precision of the linear sliding block is high, so that the machining precision of the side face of the linear sliding block is also high.

Description

Double-side machining process of linear sliding block

Technical Field

The invention relates to a slider side processing technology, in particular to a double-side processing technology of a linear slider.

Background

The edge milling machine is used for processing the side surface of a workpiece, and the existing edge milling machine has low positioning precision on the workpiece to be processed, so that the processing precision of the workpiece is influenced to be low. For example, the edge milling machine of application No. 201611264129.9 is positioned by the jig 22, and the jig 22 is provided with a projection or a positioning slot corresponding to the workpiece, so that a certain gap is left between the workpiece and the jig 22, and the gap affects the processing precision of the side surface of the workpiece. The positioning mode is troublesome to feed, an operator needs to manually position and match the workpiece and the jig 22, and the working efficiency is low.

Disclosure of Invention

The invention provides a double-sided machining process of a linear sliding block, aiming at the defects of low machining precision and complicated feeding of workpieces in the prior art.

In order to solve the technical problem, the invention is solved by the following technical scheme:

the double-sided machining process of the linear sliding block comprises the following steps of:

step a, starting a first positioning mechanism, wherein the first positioning mechanism is arranged right behind a supporting seat, a positioning plate is pushed to the position above the area where the supporting seat is located by a first air cylinder, a linear sliding block to be machined is placed on the supporting seat, and two adjacent side surfaces of the linear sliding block to be machined are respectively abutted against a rear positioning plate and a side positioning plate of the positioning plate;

b, starting a second positioning mechanism, wherein the second positioning mechanism is arranged right in front of the supporting seat, a first push rod of a second air cylinder is propped against the front side surface of the linear sliding block to be processed, the linear sliding block with processing is pushed to be in close contact with a rear positioning plate, and after the linear sliding block is positioned, the second air cylinder drives the first push rod to reset;

c, starting a pressing mechanism, wherein the pressing mechanism is arranged right above the supporting seat, the cylinder body drives a lifting rod, and the lifting rod drives a press head to be pressed on the linear sliding block to be processed;

d, resetting the first positioning mechanism, wherein the first cylinder drives the positioning plate to reset, so that the rear positioning plate and the side positioning plate are far away from the linear sliding block to be processed;

step e, starting the milling cutter mechanisms, installing the milling cutter mechanisms on two sides of the supporting seat, enabling the two milling cutter mechanisms to work simultaneously, and enabling second push rods of the two opposite milling cutter mechanisms to push respective milling cutters to perform double-face machining on the linear sliding block to be machined;

step f, rotating the linear sliding block to be processed, stopping and resetting the milling cutter mechanism after the two opposite side surfaces of the linear sliding block to be processed are processed, releasing pressure by the pressing mechanism, loosening the linear sliding block to be processed by the pressing head, installing the rotating table on the moving table, and driving the supporting seat to rotate for 90 degrees by the rotating table;

and g, restarting the step e until all the mechanisms stop and reset after the other two side surfaces of the linear slide block are processed, and taking out the processed linear slide block and simultaneously putting in another linear slide block to be processed by an operator.

Preferably, in the step h, as for the step e, the moving table is started at the same time, the supporting seat and the pressing mechanism are both installed on the moving table, the moving table drives the linear sliding block in machining to move under the driving of the first motor, and the moving direction of the linear sliding block in machining is opposite to that of the milling cutter;

preferably, in the step i, as for the step e, a water spraying system is started at the same time, a water spraying hole of the water spraying system is arranged on a third guide seat of the milling cutter mechanism, and the water spraying hole sprays water to a linear sliding block in machining to reduce the temperature;

preferably, in step j, as for step e, the purging mechanisms are started simultaneously, the purging mechanisms are arranged on two sides above the supporting seat, and the air pump compresses air and sprays high-pressure air on the linear sliding block in the processing process through the air blowing pipe;

preferably, for step a, the chute opening of the linear slide to be processed is facing upwards and placed horizontally on the support base.

Preferably, in step a, a rear cushion block is mounted on the front end surface of the rear positioning plate, a side cushion block is mounted on the side surface of the side positioning plate facing the support seat, the plane of the rear cushion block is perpendicular to the plane of the side cushion block, and two adjacent side surfaces of the linear slider to be processed are respectively in contact connection with the rear cushion block and the side cushion block.

Preferably, for step c, the pressing head is pressed at the middle position of the linear slide block to be processed and pressed in the sliding chute of the linear slide block to be processed.

Due to the adoption of the technical scheme, the invention has the remarkable technical effects that:

when the process is adopted to process the linear sliding block, the milling cutter mechanism and the moving platform move simultaneously, the processing efficiency is high, and the positioning precision of the linear sliding block is high, so that the processing precision of the side surface of the linear sliding block is also high.

The supporting seat is only used for placing the linear slider to be processed during the material loading, and there is not the positioning relation between the two, and two adjacent right-angle sides of linear slider can be fixed a position to the locating plate on the first positioning mechanism, and the operator as long as support the linear slider in the material loading the locating plate can, the material loading is simple, and positioning accuracy is high.

Drawings

FIG. 1 is a schematic structural diagram of a double-sided edge milling machine used in the process of the present invention.

Fig. 2 is a partially enlarged view of a in fig. 1.

Fig. 3 is a schematic view of the structure of the upper part of the top plate in fig. 1.

The names of the parts indicated by the numerical references in the above figures are as follows: 10-a moving table, 11-a rotating table, 12-a supporting seat, 13-a support, 14-a pressing mechanism, 15-a first positioning mechanism, 16-a second guide seat, 17-a second guide rod, 18-a connecting plate, 19-a second positioning mechanism, 20-a purging mechanism, 21-a workbench, 22-a milling cutter, 23-a second push rod, 24-a third guide seat, 25-a frame, 26-a linear guide rail, 131-a top plate, 132-a rear side plate, 141-a cylinder body, 142-a lifting rod, 143-a pressure head, 151-a first cylinder, 152-a rear positioning plate, 153-a side positioning plate, 154-a rear cushion block, 155-a side cushion block, 156-a first guide rod, 191-a supporting frame, 192-a second cylinder, 201-an air pump, 202-an air blowing pipe.

Detailed Description

The invention will be described in further detail below with reference to the accompanying figures 1-3 and examples.

Example 1

The double-sided machining process of the linear sliding block comprises the following steps of:

step a, starting a first positioning mechanism 15, wherein the first positioning mechanism 15 is arranged right behind a supporting seat 12, a first air cylinder 151 pushes a positioning plate to the position above the area where the supporting seat 12 is located, a linear sliding block to be machined is placed on the supporting seat 12, and two adjacent side surfaces of the linear sliding block to be machined are respectively abutted against a rear positioning plate 152 and a side positioning plate 153 of the positioning plate;

b, starting a second positioning mechanism 19, wherein the second positioning mechanism 19 is arranged right ahead of the supporting seat 12, a first push rod of a second air cylinder 192 is abutted against the front side surface of the linear sliding block to be processed, the linear sliding block with processing is pushed to be in close contact with the rear positioning plate 152, and after positioning is completed, the second air cylinder 192 drives the first push rod to reset;

step c, starting the pressing mechanism 14, wherein the pressing mechanism 14 is started to be arranged right above the supporting seat 12, the cylinder body 141 drives the lifting rod 142, and the lifting rod 142 drives the pressing head 143 to press on the linear sliding block to be processed;

d, resetting the first positioning mechanism 15, and driving the positioning plate to reset by the first air cylinder 151, so that the rear positioning plate 152 and the side positioning plate 153 are far away from the linear slide block to be machined;

step e, starting the milling cutter mechanisms, installing the milling cutter mechanisms on both sides of the supporting seat 12, enabling the two milling cutter mechanisms to work simultaneously, and enabling second push rods 23 of the two opposite milling cutter mechanisms to push respective milling cutters 22 to perform double-sided machining on linear sliding blocks to be machined;

step f, rotating the linear sliding block to be processed, stopping and resetting the milling cutter mechanism after the two opposite side surfaces of the linear sliding block to be processed are processed, relieving the pressure of the pressing mechanism 14, loosening the linear sliding block to be processed by the pressure head 143, installing the rotating table 11 on the moving table 10, and driving the supporting seat 12 to rotate by 90 degrees by the rotating table 11;

and g, restarting the step e until all the mechanisms stop and reset after the other two side surfaces of the linear slide block are processed, and taking out the processed linear slide block and simultaneously putting in another linear slide block to be processed by an operator.

Step h, for step e, the mobile station 10 is started simultaneously, the supporting seat 12 and the pressing mechanism 14 are both installed on the mobile station 10, the mobile station 10 drives the linear slider in machining to move under the driving of the first motor, and the moving direction of the linear slider in machining is opposite to that of the milling cutter 22;

step i, as for step e, simultaneously starting a water spraying system, wherein a water spraying hole of the water spraying system is arranged on a third guide seat 24 of the milling cutter mechanism, and the water spraying hole sprays water to a linear sliding block in machining to cool;

step j, for step e, simultaneously starting the purging mechanism 20, wherein the purging mechanism 20 is arranged at two sides above the supporting seat 12, and the air pump 201 compresses air and sprays high-pressure air on the linear sliding block in the processing through the air blowing pipe 202;

for step a, the slide slot opening of the linear slide to be processed is facing upwards and placed horizontally on the support base 12.

For step a, the front end surface of the rear positioning plate 152152 is provided with a rear cushion block 154, the side surface of the side positioning plate 153153 facing the supporting seat 12 is provided with a side cushion block 155, the plane of the rear cushion block 154 is perpendicular to the plane of the side cushion block 155, and two adjacent side surfaces of the linear slider to be processed are respectively in contact connection with the rear cushion block 154 and the side cushion block 155.

For step c, the pressing head 143 presses the middle position of the linear slide to be processed and presses the slide groove of the linear slide to be processed.

Example 2

For example 1, a double-sided edge milling machine is used to machine the side surface of the linear slider, the double-sided edge milling machine comprises a workbench 21, a moving table 10 and a rotating table 11, a protective cover is mounted on the workbench 21, and the linear slider is machined in the protective cover. The mobile station 10 is slidably mounted on the workbench 21, that is, the mobile station 10 can horizontally and longitudinally move on the workbench 21, the rotary table 11 is mounted on the mobile station 10, that is, the rotary table 11 can rotate on the mobile station 10, a support seat 12 for supporting a linear slider to be processed is fixed on the rotary table 11, the linear slider on the support seat 12 is horizontally placed with a slide groove opening facing upwards, the linear slider to be processed and the support seat 12 cannot be in positioning fit, and the linear slider can be placed on the support seat 12. The mobile station 10 is provided with a support 13, a top plate 131 of the support 13 is provided with a pressing mechanism 14 for pressing the linear slider to be processed, and after the linear slider to be processed is positioned, the pressing mechanism 14 presses the linear slider to be processed on the support 12, so that the linear slider is prevented from moving in the processing process. Install the first positioning mechanism 15 that is used for fixing a position the linear slider of treating processing on the posterior lateral plate 132 of support 13, first positioning mechanism 15 includes first cylinder 151 and locating plate, first cylinder 151 passes through the bolt vertical fixation on posterior lateral plate 132, the telescopic link and the locating plate fixed connection of first cylinder 151, when the linear slider of treating processing is fixed a position to first positioning mechanism 15, the telescopic link of first cylinder 151 will promote the locating plate and move to the so-called region of supporting seat 12, during the material loading, the linear slider of treating processing can support and lean on the locating plate, the locating plate includes back locating plate 152 and side locating plate 153, side locating plate 153 vertical fixation is at the front end of back locating plate 152, the locating plate can fix a position simultaneously the adjacent both sides face of linear slider, positioning accuracy is high.

The front end surface of the rear positioning plate 152 is provided with a rear cushion block 154, the rear cushion block 154 is arranged on the rear positioning plate 152 through bolts, the side surface of the side positioning plate 153 facing the rotating platform is provided with a side cushion block 155, the side cushion block 155 is arranged on the side positioning plate 153 through bolts, and the plane of the rear cushion block 154 is vertical to the plane of the side cushion block 155. The rear cushion block 154 and the side cushion block 155 are used for increasing the wall thickness of the rear positioning plate 152 and the side positioning plate 153 respectively, the linear sliding blocks are various in types, the width and the length of the linear sliding blocks are various in sizes, and the rear cushion block 154 and the side cushion block 155 improve the universality of the first positioning mechanism 15. The rear cushion block 154 and the side cushion block 155 are used for increasing the wall thickness of the rear positioning plate 152 and the side positioning plate 153 respectively, the linear sliding blocks are various in types, the width and the length of the linear sliding blocks are various in sizes, and the rear cushion block 154 and the side cushion block 155 improve the universality of the first positioning mechanism 15.

A first guide seat is installed on the rear side plate 132, a first guide rod 156 is installed on the first guide seat, one end of the first guide rod 156 extends and retracts on the first guide seat, the other end of the first guide rod 156 is fixedly connected with the rear positioning plate 152, and the first guide rod 156 is arranged in parallel with the extension rod of the first cylinder 151. The first guide bar 156 moves in synchronization with the extension bar of the first cylinder 151, so that the positioning plate has high stability when moving. First guide bar 156 is used for assisting first cylinder 151, and first cylinder 151 is when promoting the locating plate, and first guide bar 156 has improved the stability that the locating plate removed, guarantees the straightness that hangs down of locating plate, has improved the precision of linear slider location.

The pressing mechanism 14 includes a cylinder 141, a lifting rod 142 and a pressing head 143, the cylinder 141 is fixed on the top plate 131 of the bracket 13 by bolts, one end of the lifting rod 142 extends in the cylinder 141, and the other end thereof is fixedly connected with the pressing head 143 by the top plate 131. When the pressing mechanism 14 is activated, the lifting rod 142 drives the pressing head 143 to press the groove of the linear slider on the supporting base 12. After the linear slider to be processed is positioned by the positioning plate, the pressing mechanism 14 presses the linear slider on the supporting seat 12, so that the linear slider can be conveniently processed by the milling cutter, and the linear slider is prevented from moving during processing.

A second guide seat 16 is fixed on the top plate 131, a second guide rod 17 is installed in the second guide seat 16, one end of the second guide rod 17 extends into the second guide seat 16, the other end of the second guide rod 17 penetrates through the top plate 131 to be connected with the lifting rod 142, the second guide rod 17 is parallel to the lifting rod 142, and the second guide rod 17 is connected with the lifting rod 142 through a connecting plate 18. The second guide rod 17 is used for assisting the pressing mechanism 14, the second guide rod 17 and the lifting rod 142 of the pressing mechanism 14 lift simultaneously, the second guide rod 17 improves the lifting stability of the lifting rod 142, and the linear sliding block is prevented from shifting when the pressing head 143 presses the linear sliding block.

The milling cutter mechanisms for processing the side faces of the linear sliding blocks are mounted on two sides of the moving platform 10, the two milling cutter mechanisms can process the two side faces of the linear sliding blocks simultaneously, the processing efficiency is high, the two side faces of the linear sliding blocks are processed simultaneously, the linear sliding blocks are stressed on the supporting seat 12 uniformly, namely the linear sliding blocks are stable on the supporting seat 12, and therefore the processing accuracy of the linear sliding blocks is improved. The milling cutter mechanism is slidably mounted on the workbench 21, the milling cutter mechanism comprises a milling cutter 22, a second push rod 23, a third guide seat 24 and a rack 25, the rack 25 is slidably mounted on the workbench 21, namely the milling cutter mechanism moves and processes the side surface of the linear slider when processing the linear slider, and the moving processing of the milling cutter mechanism and the moving processing of the moving platform 10 improve the processing efficiency of the side surface of the linear slider. The third guide holder 24 is installed on the rack 25 through a bolt, the second push rod 23 is installed on the rack 25 through the third guide holder 24, the outer end portion of the second push rod 23 is fixedly connected with the milling cutters 22, the supporting seat 12 is arranged between the two milling cutters 22, the third guide holder 24 is provided with a water spray hole with an opening facing the supporting seat 12, and when the milling cutter mechanism is used for machining a linear sliding block, the water spray hole can spray water to cool the linear sliding block.

The linear guide rail 26 and the first motor are installed on the workbench 21, a sliding block slides on the linear guide rail 26, the mobile station 10 is installed on the sliding block, a screw rod is installed on an output shaft of the first motor, and the screw rod is in threaded connection with the linear sliding block. The moving table 10 can horizontally and longitudinally move on the working table 21, so that the milling cutter mechanism can rapidly machine the linear slide block, and the machining efficiency is improved.

The second motor for driving the rotating platform 11 to rotate is installed on the moving platform 10, an output shaft of the second motor is connected with a speed reducer, and the speed reducer is connected with the rotating platform 11 through a connecting shaft.

Example 3

The embodiment 3 has substantially the same features as the embodiment 2, except that a second positioning mechanism 19 is further installed on the mobile station 10, the supporting seat 12 is arranged between the first positioning mechanism 15 and the second positioning mechanism 19, the second positioning mechanism 19 can push the linear slider on the supporting seat 12 to the rear positioning plate 152, so that the linear slider to be processed can be in close contact with the rear positioning plate 152, and the second positioning mechanism 19 improves the positioning accuracy of the linear slider. The second positioning mechanism 19 includes a support frame 191, a second cylinder 192 and a first push rod for pushing the linear slide block to the first positioning mechanism 15, a push head made of plastic is installed at an end of the first push rod, and the plastic material of the push head in this embodiment is polypropylene or polyethylene. The support frame 191 is fixed to the mobile station 10 by bolts, the second cylinder 192 is mounted on the support frame 191, and the first push rod is extended and contracted in the second cylinder 192.

Example 4

Embodiment 4 has substantially the same characteristics as embodiment 2, except that both ends of the lower end surface of the top plate 131 of the bracket 13 are provided with the purging mechanisms 20, the two purging mechanisms 20 which are oppositely arranged can purge the scraps on the linear slider, so as to improve the cleanliness of the linear slider, after the linear slider is machined, an operator directly takes out the linear slider without manually purging the surface of the linear slider, the purging mechanism 20 comprises an air pump 201 and an air blow pipe 202, the air pump 201 is arranged on the top plate 131, one end of the air blow pipe 202 is arranged on the air pump 201, and the air blow port at the other end of the air blow pipe faces the supporting seat 12.

Claims (7)

1. The double-sided machining process of the linear sliding block is characterized by comprising the following steps of:

step a, a first positioning mechanism (15) is started, the first positioning mechanism (15) is arranged right behind a supporting seat (12), a first air cylinder (151) pushes a positioning plate to be above an area where the supporting seat (12) is located, a linear sliding block to be machined is placed on the supporting seat (12), and two adjacent side surfaces of the linear sliding block to be machined are abutted to a rear positioning plate (152) and a side positioning plate (153) of the positioning plate respectively;

b, starting a second positioning mechanism (19), wherein the second positioning mechanism (19) is arranged right in front of the supporting seat (12), a first push rod of a second air cylinder (192) is pushed against the front side surface of a linear slide block to be processed to push the linear slide block with processing to be in close contact with the rear positioning plate (152), and after positioning is completed, the second air cylinder (192) drives the first push rod to reset;

c, starting the pressing mechanism (14), wherein the pressing mechanism (14) is started to be arranged right above the supporting seat (12), the cylinder body (141) drives the lifting rod (142), and the lifting rod (142) drives the pressure head (143) to be pressed on the linear sliding block to be processed;

d, resetting the first positioning mechanism (15), wherein the first air cylinder (151) drives the positioning plate to reset, so that the rear positioning plate (152) and the side positioning plate (153) are far away from the linear sliding block to be machined;

e, starting the milling cutter mechanisms, installing the milling cutter mechanisms on two sides of the supporting seat (12), enabling the two milling cutter mechanisms to work simultaneously, and enabling second push rods (23) of the two opposite milling cutter mechanisms to push respective milling cutters (22) to perform double-side machining on linear sliding blocks to be machined;

step f, rotating the linear sliding block to be processed, stopping and resetting the milling cutter mechanism after the two opposite side surfaces of the linear sliding block to be processed are processed, relieving pressure by the pressing mechanism (14), loosening the linear sliding block to be processed by the pressing head (143), installing the rotating table (11) on the moving table (10), and driving the supporting seat (12) to rotate for 90 degrees by the rotating table (11);

and g, restarting the step e until all the mechanisms stop and reset after the other two side surfaces of the linear slide block are processed, and taking out the processed linear slide block and simultaneously putting in another linear slide block to be processed by an operator.

2. The double-sided machining process of the linear slider according to claim 1, characterized in that: and h, for the step e, simultaneously starting the movable table (10), installing the supporting seat (12) and the pressing mechanism (14) on the movable table (10), driving the movable table (10) to drive the linear sliding block in machining to move under the driving of the first motor, wherein the moving direction of the linear sliding block in machining is opposite to that of the milling cutter (22).

3. The double-sided machining process of the linear slider according to claim 1, characterized in that: and step i, as for the step e, simultaneously starting a water spraying system, wherein a water spraying hole of the water spraying system is arranged on a third guide seat (24) of the milling cutter mechanism, and the water spraying hole sprays water to a linear sliding block in machining to reduce the temperature.

4. The double-sided machining process of the linear slider according to claim 1, characterized in that: step j, for step e, simultaneously starting the purging mechanisms (20), wherein the purging mechanisms (20) are arranged on two sides above the supporting seat (12), and the air pump (201) compresses air and sprays high-pressure air on the linear sliding block in the processing through the air blowing pipe (202).

5. The double-sided machining process of the linear slider according to claim 1, characterized in that: for the step a, the opening of the chute of the linear sliding block to be processed faces upwards and is horizontally placed on the supporting seat (12).

6. The double-sided machining process of the linear slider according to claim 1, characterized in that: and a step a, a rear cushion block (154) is arranged on the front end surface of the rear positioning plates (152) and (152), a side cushion block (155) is arranged on the side surfaces, facing the supporting seat (12), of the side positioning plates (153) and (153), the plane where the rear cushion block (154) is located is perpendicular to the plane where the side cushion block (155) is located, and two adjacent side surfaces of the linear sliding block to be machined are respectively in contact connection with the rear cushion block (154) and the side cushion block (155).

7. The double-sided machining process of the linear slider according to claim 1, characterized in that: and c, pressing the pressing head (143) at the middle position of the linear slide block to be processed and in the sliding chute of the linear slide block to be processed.

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