CN115179068A - Machining device and machining method for zinc alloy wear-resistant guide rail plate - Google Patents

Abstract

The invention relates to the technical field of guide rail plate processing, in particular to a processing device and a processing method of a zinc alloy wear-resistant guide rail plate.

Description

Machining device and machining method for zinc alloy wear-resistant guide rail plate

Technical Field

The invention relates to the technical field of guide rail plate processing, in particular to a processing device and a processing method of a zinc alloy wear-resistant guide rail plate.

Background

The zinc alloy wear-resistant guide rail plate is widely applied as a guide rail plate with better durability, and the processing of the zinc alloy wear-resistant guide rail plate usually comprises the steps of drilling, grinding, polishing and the like.

However, the inventor finds that when the conventional processing device for the zinc alloy wear-resistant guide rail plate is used for clamping the zinc alloy wear-resistant guide rail plate, the clamping effect is not ideal, the zinc alloy wear-resistant guide rail plate is easy to generate position deviation during processing, and the processing precision of the zinc alloy wear-resistant guide rail plate is greatly reduced.

Disclosure of Invention

In view of the above, the present invention provides a processing apparatus and a processing method for a zinc alloy wear-resistant guide rail plate, so as to improve the processing precision of the zinc alloy wear-resistant guide rail plate.

Based on the above purpose, the invention provides a processing device of a zinc alloy wear-resistant guide rail plate, which comprises a processing box and is characterized by comprising:

the clamping frames are arranged in the processing box, each clamping frame comprises side plates, a top plate and a bottom plate, the side plates of the two clamping frames are arranged oppositely and parallelly, the top plates of the two clamping frames are fixed to the top ends of the corresponding side plates respectively, the bottom plates of the two clamping frames are fixed to the bottom ends of the corresponding side plates respectively, and side pressure holes are formed in the side plates;

the clamping frame comprises two clamping frames, a base plate and a clamping piece, wherein the two clamping frames are fixedly arranged on the lower sides of the two clamping frames, two first rotating bases are respectively arranged on the two sides of the upper end surface of the base plate, each first rotating base is rotatably connected with a first rotating rod, the top end of each first rotating rod penetrates into the clamping frame from a side pressure hole on the same side, the end part of each first rotating rod is rotatably connected with a side pressure rod which is perpendicular to the clamping frame, the side pressure rods are parallel to the side plates, side pressure cylinders are fixedly sleeved on the side parts of the side pressure rods, second rotating rods are rotatably connected onto the side pressure rods, and the top ends of the second rotating rods are rotatably connected with the bottom end surfaces of top plates on the same side;

the guide rail plate processing mechanisms are arranged on the top wall of the processing box above the space between the two clamping frames through a plurality of first electric telescopic rods;

the lateral parts of the two sides of the base plate are respectively fixed with two first fixing plates, each first fixing plate is provided with a second electric telescopic rod, the top end of each second electric telescopic rod is fixed with a second fixing plate, and the lateral parts of the second fixing plates are fixedly connected with the lateral plates of the sides.

As an alternative embodiment, the top plate and the side plates are vertically arranged, and the two top plates are respectively arranged on the opposite side surfaces of the two side plates.

Specifically, each top plate is provided with a top pressing hole which penetrates through the top pressing plate from top to bottom, a top pressing barrel is fixed in each top pressing hole, an elastic telescopic rod is movably arranged in each top pressing barrel, the top end of each elastic telescopic rod is fixed with a first top pressing plate, the bottom end of each elastic telescopic rod penetrates out of each top pressing barrel, a second top pressing plate is fixed at the end part of each top pressing barrel, a top pressing ring is fixed at the top end in each top pressing barrel, and the upper end face of each top pressing ring is elastically connected with the bottom end face of each first top pressing plate through a plurality of pushing springs.

Furthermore, two sliding frames are fixed on one side, away from the upper end faces of the two top plates, of the processing box at the side of the two second fixing plates, two second rotating bases are arranged on the inner wall of the processing box at the side of the two second fixing plates respectively, a jacking lever is rotatably arranged on each second rotating base, one end of each jacking lever is rotatably arranged on each second rotating base, a sliding rod which is perpendicular to the side portion is fixed on the side portion of each second rotating base, the sliding rods are slidably arranged in the sliding frames at the side, and a jacking ball is fixed at the other end of each jacking lever, arranged above the first jacking plate and fixed at the end of the first jacking plate.

As an optional implementation manner, the two bottom plates are respectively fixed at the bottom ends of the opposite surfaces of the two side plates, and the bottom plates are perpendicular to the side plates.

As an optional implementation manner, the lower end face of the base plate is fixedly connected with the bottom wall of the processing box through a plurality of stand columns, and a groove is formed in the upper end face of the base plate between the two clamping frames.

Corresponding to the processing device of the zinc alloy wear-resistant guide rail plate, the embodiment of the invention also provides a processing method of the zinc alloy wear-resistant guide rail plate, wherein the processing method is applied to the processing device of the zinc alloy wear-resistant guide rail plate, the processing device of the zinc alloy wear-resistant guide rail plate is the processing device of the zinc alloy wear-resistant guide rail plate as claimed in any one of the claims 1 to 6, and the processing method comprises the following steps:

placing two ends of a zinc alloy wear-resistant guide rail plate to be processed on the two clamping frames;

simultaneously driving the two second electric telescopic rods to shorten, so that the two clamping frames simultaneously descend until the two side pressing cylinders are contacted with the side part of the zinc alloy wear-resistant guide rail plate to be processed;

simultaneously driving a plurality of first electric telescopic rods and a guide rail plate processing mechanism to process the zinc alloy wear-resistant guide rail plate to be processed;

obtaining a processed zinc alloy wear-resistant guide rail plate;

the first electric telescopic rods are driven to be shortened, and the two second electric telescopic rods are driven to be extended;

and taking out the processed zinc alloy wear-resistant guide rail plate.

According to the processing device and the processing method for the zinc alloy wear-resistant guide rail plate, two clamping frames are arranged on two sides in the processing box, two ends of the zinc alloy wear-resistant guide rail plate to be processed are placed on two bottom plates before processing, two second electric telescopic rods are driven to be shortened, the two clamping frames are enabled to descend simultaneously, under the mutual extrusion and rotation of the first rotating rod and the second rotating rod, two side pressing cylinders move relatively and contact the side portion of the zinc alloy wear-resistant guide rail plate to be processed from two sides, the zinc alloy wear-resistant guide rail plate is clamped from the side portion, then the guide rail plate processing mechanism is driven to contact the zinc alloy wear-resistant guide rail plate to be processed through the stretching action of the first electric telescopic rods, the zinc alloy wear-resistant guide rail plate is effectively prevented from being subjected to position deviation during processing, and the processing precision of the zinc alloy wear-resistant guide rail plate is greatly improved.

Drawings

In order to more clearly illustrate the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only the present invention, and those skilled in the art can also obtain other drawings according to the drawings without creative efforts.

Fig. 1 is a cross-sectional view of a processing device of a zinc alloy wear-resistant guide rail plate according to an embodiment of the invention;

FIG. 2 is a schematic view of portion A of FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a side press bar according to an embodiment of the present invention.

Labeled as:

1. a processing box; 2. a side plate; 3. a top plate; 4. a base plate; 5. side pressure holes; 6. a substrate; 7. a first rotating lever; 8. a lateral pressure lever; 9. a lateral pressing cylinder; 10. a second rotating rod; 11. a guide rail plate processing mechanism; 12. a first electric telescopic rod; 13. a second electric telescopic rod; 14. a first fixing plate; 15. a second fixing plate; 16. a top pressing cylinder; 17. an elastic telescopic rod; 18. a first top pressure plate; 19. a second top pressure plate; 20. pressing the ring; 21. a push spring; 22. a sliding frame; 23. the lever is pressed; 24. pressing the ball; 25. a column; 26. and (4) a groove.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to specific embodiments below.

It is to be noted that technical terms or scientific terms used herein should have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. The use of "first," "second," and similar terms in the present application do not denote any order, quantity, or importance, but rather the terms are used to distinguish one element from another. The word "comprising" or "comprises", and the like, means that the element or item listed before the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

Based on the above purpose, the invention provides a processing device of a zinc alloy wear-resistant guide rail plate, which comprises a processing box 1 and is characterized by comprising:

the two clamping frames are arranged in the processing box 1, each clamping frame comprises a side plate 2, a top plate 3 and a bottom plate 4, the side plates 2 of the two clamping frames are oppositely and parallelly arranged, the top plates 3 of the two clamping frames are respectively fixed at the top ends of the corresponding side plates 2, the bottom plates 4 are respectively fixed at the bottom ends of the corresponding side plates 2, and the side pressure holes 5 are formed in the side plates 2;

the base plate 6 is fixedly arranged at the lower sides of the two clamping frames, two first rotating bases are respectively arranged at two sides of the upper end surface of the base plate 6, each first rotating base is rotatably connected with a first rotating rod 7, the top end of each first rotating rod 7 penetrates into the clamping frame from a side pressure hole 5 at the same side, the end part of each first rotating rod is rotatably connected with a side pressure rod 8 which is vertical to the top end of each first rotating base, the side pressure rods 8 are parallel to the side plate 2, side pressure cylinders 9 are fixedly sleeved at the side parts of the side pressure rods 8, second rotating rods 10 are rotatably connected to the side pressure rods 8, and the top ends of the second rotating rods 10 are rotatably connected with the bottom end surfaces of the top plates 3 at the same side;

the guide rail plate processing mechanisms 11 are arranged on the top wall of the processing box 1 above the two clamping frames through a plurality of first electric telescopic rods 12 respectively;

second electric telescopic handle 13, the lateral part of base plate 6 both sides is fixed with two first fixed plates 14 respectively, all is provided with a second electric telescopic handle 13 on every first fixed plate 14, the top of second electric telescopic handle 13 is fixed with second fixed plate 15, the lateral part of second fixed plate 15 and the curb plate 2 fixed connection of side.

In the embodiment of the invention, two clamping frames are arranged on two sides in the processing box 1, two ends of a zinc alloy wear-resistant guide rail plate to be processed are placed on two bottom plates 4 before processing, two second electric telescopic rods 13 are driven to shorten, the two clamping frames are enabled to descend simultaneously, two side pressing cylinders 9 move relatively under the mutual extrusion and rotation of a first rotating rod 7 and a second rotating rod 10, the two side pressing cylinders contact the side part of the zinc alloy wear-resistant guide rail plate to be processed from two sides, the zinc alloy wear-resistant guide rail plate is clamped from the side part, and a guide rail plate processing mechanism 11 is driven to contact the zinc alloy wear-resistant guide rail plate for processing through the extension action of a first electric telescopic rod 12, so that the zinc alloy wear-resistant guide rail plate is effectively prevented from position deviation during processing, and the processing precision of the zinc alloy wear-resistant guide rail plate is greatly improved.

As an alternative embodiment, the top plate 3 is vertically disposed between the side plates 2, and the two top plates 3 are respectively disposed on opposite sides of the two side plates 2.

Specifically, each top plate 3 is provided with a top pressing hole which penetrates through the top plate from top to bottom, a top pressing barrel 16 is fixed in the top pressing hole, an elastic telescopic rod 17 is movably arranged in the top pressing barrel 16, a first top pressing plate 18 is fixed at the top end of the elastic telescopic rod 17, the bottom end of the elastic telescopic rod penetrates through the top pressing barrel 16, a second top pressing plate 19 is fixed at the end part of the elastic telescopic rod, a top pressing ring 20 is fixed at the top end in the top pressing barrel 16, and the upper end face of the top pressing ring 20 is elastically connected with the bottom end face of the first top pressing plate 18 through a plurality of pushing springs 21.

Furthermore, two sliding frames 22 are respectively fixed on one side of the upper end surfaces of the two top plates 3, which is far away from each other, two second rotating bases are respectively arranged on the inner walls of the processing box 1 beside the two second fixing plates 15, each second rotating base is rotatably provided with a jacking lever 23, one end of each jacking lever 23 is rotatably arranged on the corresponding second rotating base, the side parts of the jacking levers are fixedly provided with mutually perpendicular sliding rods, the sliding rods are slidably arranged in the sliding frames 22 on the sides, and the other end of each jacking lever 23 is arranged above the first jacking plate 18 and the end part of each jacking lever is fixedly provided with a jacking ball 24.

When the second electric telescopic rod 13 drives the two clamping frames to move downwards, the sliding frame 22 drives the jacking lever 23 to rotate, so that the jacking ball 24 at the end part moves downwards and presses the first jacking plate 18, the elastic telescopic rod 17 is driven to move downwards, the second jacking rod at the bottom end of the elastic telescopic rod 17 presses the upper end of the zinc alloy wear-resistant guide rail plate, the zinc alloy wear-resistant guide rail plate is pressed, the zinc alloy wear-resistant guide rail plate is prevented from moving in the vertical direction during processing, and the processing precision of the zinc alloy wear-resistant guide rail plate is further improved.

As an alternative embodiment, two bottom plates 4 are respectively fixed at the bottom ends of the opposite surfaces of the two side plates 2, and the bottom plates 4 are arranged perpendicular to the side plates 2.

As an alternative embodiment, the lower end surface of the base plate 6 is fixedly connected with the bottom wall of the processing box 1 through a plurality of upright posts 25, and a groove 26 is formed on the upper end surface of the base plate 6 between the two clamping frames.

The recess 26 can accommodate the drilling of a drill to prevent damage to the base plate 6 when the zinc alloy wear rail plate is drilled.

Corresponding to the processing device of the zinc alloy wear-resistant guide rail plate, the embodiment of the invention also provides a processing method of the zinc alloy wear-resistant guide rail plate, which is applied to the processing device of the zinc alloy wear-resistant guide rail plate, wherein the processing device of the zinc alloy wear-resistant guide rail plate is the processing device of the zinc alloy wear-resistant guide rail plate as described in any one of the claims 1 to 6, and the processing method comprises the following steps:

placing two ends of a zinc alloy wear-resistant guide rail plate to be processed on the two clamping frames;

simultaneously driving the two second electric telescopic rods 13 to shorten, so that the two clamping frames simultaneously descend until the two side pressing cylinders 9 are contacted with the side part of the zinc alloy wear-resistant guide rail plate to be processed;

simultaneously driving a plurality of first electric telescopic rods 12 and a guide rail plate processing mechanism 11 to process the zinc alloy wear-resistant guide rail plate to be processed;

obtaining a processed zinc alloy wear-resistant guide rail plate;

a plurality of first electric telescopic rods 12 are driven to be shortened, and two second electric telescopic rods 13 are driven to be extended;

and taking out the processed zinc alloy wear-resistant guide rail plate.

Therefore, the zinc alloy wear-resistant guide rail plate is clamped, the zinc alloy wear-resistant guide rail plate is prevented from deviating in the machining process, and the machining precision of the zinc alloy wear-resistant guide rail plate is greatly improved.

Those of ordinary skill in the art will understand that: the discussion of any embodiment above is meant to be exemplary only, and is not intended to intimate that the scope of the disclosure, including the claims, is limited to those examples; within the idea of the invention, also features in the above embodiments or in different embodiments may be combined, steps may be implemented in any order, and there are many other variations of the different aspects of the invention as described above, which are not provided in detail for the sake of brevity.

The present invention is intended to embrace all such alternatives, modifications and variances which fall within the broad scope of the appended claims. Therefore, any omissions, modifications, substitutions, improvements and the like that may be made without departing from the spirit and principles of the invention are intended to be included within the scope of the invention.

Claims (7)

1. The utility model provides a processingequipment of wear-resisting guide rail board of zinc alloy, includes the processing case, its characterized in that includes:

the clamping frames are arranged in the processing box, each clamping frame comprises side plates, a top plate and a bottom plate, the side plates of the two clamping frames are arranged oppositely and in parallel, the top plates of the two clamping frames are respectively fixed at the top ends of the corresponding side plates, the bottom plates are respectively fixed at the bottom ends of the corresponding side plates, and side pressure holes are formed in the side plates;

the clamping frame comprises two clamping frames, a base plate and a first rotating rod, wherein the two clamping frames are fixedly arranged on the lower sides of the two clamping frames, two first rotating bases are respectively arranged on two sides of the upper end surface of the base plate, each first rotating base is rotatably connected with one first rotating rod, the top end of each first rotating rod penetrates into the clamping frame from a side pressure hole on the same side, the end part of each first rotating rod is rotatably connected with a side pressure rod which is perpendicular to the top end of the corresponding first rotating rod, the side pressure rods are parallel to the side plates, side pressure cylinders are fixedly sleeved on the side parts of the side pressure rods, second rotating rods are rotatably connected on the side pressure rods, and the top ends of the second rotating rods are rotatably connected with the bottom end surfaces of top plates on the same side;

the guide rail plate processing mechanisms are arranged on the top wall of the processing box above the two clamping frames through a plurality of first electric telescopic rods respectively;

the lateral parts of the two sides of the base plate are respectively fixed with two first fixing plates, each first fixing plate is provided with a second electric telescopic rod, the top end of each second electric telescopic rod is fixed with a second fixing plate, and the lateral parts of the second fixing plates are fixedly connected with the lateral plates of the sides.

2. The processing device of the zinc alloy wear-resistant guide rail plate as claimed in claim 1, wherein the top plate and the side plates are arranged perpendicularly, and the two top plates are respectively arranged on the opposite sides of the two side plates.

3. The processing device of a zinc alloy wear-resistant guide rail plate according to claim 2, wherein each top plate is provided with a top pressing hole which penetrates through the top and the bottom, a top pressing barrel is fixed in each top pressing hole, an elastic telescopic rod is movably arranged in each top pressing barrel, a first top pressing plate is fixed at the top end of each elastic telescopic rod, a second top pressing plate is fixed at the bottom end of each elastic telescopic rod, a top pressing ring is fixed at the top end in each top pressing barrel, and the upper end face of each top pressing ring is elastically connected with the bottom end face of the corresponding first top pressing plate through a plurality of pushing springs.

4. The processing device of the zinc alloy wear-resistant guide rail plate as claimed in claim 3, wherein two sliding frames are respectively fixed on the sides of the top end surfaces of the two top plates away from each other, two second rotating bases are respectively arranged on the inner wall of the processing box beside the two second fixing plates, a pressing lever is rotatably arranged on each second rotating base, one end of the pressing lever is rotatably arranged on the second rotating base, the side part of the pressing lever is fixed with a vertical sliding rod, the sliding rod is slidably arranged in the sliding frame beside, the other end of the pressing lever is arranged above the first pressing plate, and the end part of the pressing lever is fixed with a pressing ball.

5. The processing device of the zinc alloy wear-resistant guide rail plate as claimed in claim 1, wherein two bottom plates are respectively fixed at the bottom ends of the opposite surfaces of the two side plates, and the bottom plates are arranged perpendicular to the side plates.

6. The processing device of the zinc alloy wear-resistant guide rail plate as claimed in claim 1, wherein the lower end surface of the base plate is fixedly connected with the bottom wall of the processing box through a plurality of upright posts, and a groove is formed on the upper end surface of the base plate between the two clamping frames.

7. A method for processing a zinc alloy wear-resistant guide rail plate, which is applied to a processing device for a zinc alloy wear-resistant guide rail plate, the processing device for the zinc alloy wear-resistant guide rail plate is the processing device for the zinc alloy wear-resistant guide rail plate of any one of the claims 1 to 6, and the processing method comprises the following steps:

placing two ends of a zinc alloy wear-resistant guide rail plate to be processed on the two clamping frames;

simultaneously driving the two second electric telescopic rods to shorten, so that the two clamping frames simultaneously descend until the two side pressing cylinders contact the side part of the zinc alloy wear-resistant guide rail plate to be processed;

simultaneously driving a plurality of first electric telescopic rods and a guide rail plate processing mechanism to process the zinc alloy wear-resistant guide rail plate to be processed;

obtaining a processed zinc alloy wear-resistant guide rail plate;

the first electric telescopic rods are driven to be shortened, and the two second electric telescopic rods are driven to be extended;

and taking out the processed zinc alloy wear-resistant guide rail plate.

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