CN111283243B - Machining system of cladding panel - Google Patents

Abstract

The invention relates to a machining system for a cladding panel. The machining system of clad plate includes L shape mount pad, upset wall and drilling subassembly, L shape mount pad includes processor board and vertical wall, the perpendicular protruding one side of locating the processor board of vertical wall, the horizontal groove has been seted up on the vertical wall, the length of processor board is less than the length of vertical wall so that the one end of processor board is formed with keeps away the vacancy groove, the middle part of upset wall is connected with the one end of processor board and the one end of upset wall unsettled in keeping away vacancy groove top with rotating, the adjacent elastic construction that is provided with of one end of upset wall and pop out the structure, the concave inclined groove that is equipped with of the other end of upset wall, the inclined groove extends and is located the top of keeping away the vacancy groove along the ascending direction of slope. The positioning and releasing of the machining system of the cladding panel are both simple and convenient.

Description

Machining system of cladding panel

Technical Field

The invention relates to a machining system for a cladding panel.

Background

During the handling of the cladding panels, it is often necessary to utilize the panels, and during the machining of the panels, it is often necessary to perform mechanical machining, such as drilling, to install various components. Before processing, the cover plate needs to be positioned. However, the various clamps are typically positioned in a fixed manner, and when released, require disassembly of the various clamps to release the sheathing panel. Therefore, the positioning and releasing process of the cover plate is complicated.

Disclosure of Invention

In view of the foregoing, there is a need for a system for machining panels that is convenient to position and release.

A machining system of a covering panel comprises an L-shaped mounting seat, an overturning wall and a drilling assembly, wherein the L-shaped mounting seat comprises a processing machine plate and a longitudinal wall, the longitudinal wall is perpendicularly and convexly arranged on one side of the processing machine plate, a horizontal groove is formed in the longitudinal wall, the length of the processing machine plate is smaller than that of the longitudinal wall so that a clearance groove is formed in one end of the processing machine plate, the middle of the overturning wall is rotatably connected to one end of the processing machine plate, one end of the overturning wall is suspended above the clearance groove, an elastic structure and an ejecting structure are adjacently arranged at one end of the overturning wall, an inclined groove is concavely arranged at the other end of the overturning wall, the inclined groove extends in an upward inclined direction and is positioned above the clearance groove, the covering panel is inserted into the horizontal groove and the inclined groove to force the overturning wall to rotate, so that the covering panel supports the elastic structure to descend and the ejecting structure to retract towards the overturning wall until the upper surface of the covering panel supports the bottom surface of the ejecting structure, and the lower surface of the covering plate is abutted to the upper surface of the elastic structure, the drilling assembly is installed on the turnover wall and used for drilling the covering plate, the drilling assembly comprises an installation frame, a drilling motor and a drilling main shaft, the installation frame is installed at the top of the turnover wall, the drilling motor is installed on the installation frame and located above the machining machine plate, the drilling main shaft is coaxially fixed on an output shaft of the drilling motor, and the axis of the drilling main shaft is perpendicular to the central axis of the inclined groove.

In one embodiment, the horizontal slot extends along the length of the longitudinal wall, the width of the horizontal slot being equal to the thickness of the facing sheet.

In one embodiment, the angle between the central axis of the angled slot and the surface of the machine plate is 45 degrees.

In one embodiment, the resilient structure includes a stainless steel base plate secured to the processor plate, a plurality of springs mounted in parallel to each other on the stainless steel base plate, and a lifting plate mounted on top of the plurality of springs.

In one embodiment, a strip-shaped groove is formed in one side, away from the longitudinal wall, of the processing machine plate, the strip-shaped groove is parallel to the horizontal groove, the turnover wall is rectangular plate-shaped, and the bottom of the turnover wall is movably inserted into the strip-shaped groove.

In one embodiment, the bottom of one end of the turnover wall, which is far away from the empty-avoiding groove, protrudes downwards to form a triangular plate, one end of the strip-shaped groove, which is far away from the empty-avoiding groove, extends downwards to form a triangular deep groove, and the triangular plate is inserted into the triangular deep groove.

In one embodiment, a limiting surface is formed on one side of the turnover wall facing the longitudinal wall, a step portion is formed on the upper portion of the limiting surface, one side of the lifting plate is slidably abutted against the limiting surface, and the top of the lifting plate is abutted against the bottom surface of the step portion.

In one embodiment, a top barrier strip is convexly arranged on the top of the limiting surface towards the longitudinal wall, a feeding interval is formed between the top surface of the lifting plate and the top barrier strip, and the feeding interval is aligned with one end of the bottom of the inclined groove.

In one embodiment, the longitudinal wall is provided with a through groove in a penetrating manner, the through groove is arranged above the horizontal groove in parallel, the machining system of the covering panel further comprises a scraping assembly, the scraping assembly comprises a transmission structure and a scraping roller, the transmission structure is arranged on the longitudinal wall, and the scraping roller is connected to the transmission structure.

In one embodiment, the scraping roller is perpendicular to the longitudinal wall, the scraping roller is arranged in the penetrating groove in a penetrating mode and extends to the upper portion of the processing machine plate, and one end, far away from the transmission structure, of the scraping roller is in sliding abutting contact with the surface of the top blocking strip.

When the machining system of the covering panel is used, one end of the covering panel is inserted between the longitudinal wall and the overturning wall, namely one side of the covering panel is inserted in the horizontal groove of the longitudinal wall, the other side of the covering panel passes through the ejecting structure and is inserted into the inclined groove, and because the inclined groove is arranged in an inclined mode, the inserting of the covering panel can force the overturning wall to rotate, one end of the covering panel falls into the gap avoiding groove of the machining machine plate, the covering panel abuts against the elastic structure to descend, and the ejecting structure is enabled to shrink towards the overturning wall. When the covering panel downwards crosses the pop-up structure, the pop-up structure pops up again, so that the upper surface of the covering panel is abutted against the bottom surface of the pop-up structure, and the lower surface of the covering panel is always abutted against the upper surface of the elastic structure, therefore, the lower surface of the pop-up structure is abutted against the upper surface of the covering panel and the upper surface of the elastic structure is abutted against the lower surface of the covering panel, so that the covering panel is elastically positioned. And then the drilling motor drives the drilling main shaft to rotate so as to drill the cladding panel. When the covering panel needs to be released, the covering panel is pulled out by moving backwards. Through setting up elastic construction and pop-up structure for the centre gripping location and the release of cladding panel are all comparatively simple and convenient, need not to unscrew the screw one by one, dismantle various anchor clamps in order to release the cladding panel.

Drawings

Fig. 1 is a perspective view of a machining system for a cladding panel according to an embodiment.

Fig. 2 is a perspective view of another perspective view of the machining system for the sheathing panel of fig. 1.

Fig. 3 is a perspective view of yet another view of the deck panel machining system of fig. 1.

FIG. 4 is a schematic perspective view of a pop-up block according to an embodiment.

Fig. 5 is a side view of an embodiment of a doctoring assembly.

Fig. 6 is a partially enlarged view of a portion a in fig. 5.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The invention relates to a machining system for a cladding panel. For example, the machining system of the cladding panel comprises an L-shaped mounting seat, a turnover wall and a drilling assembly, wherein the L-shaped mounting seat comprises a machining machine plate and a longitudinal wall, the longitudinal wall is vertically and convexly arranged on one side of the machining machine plate, a horizontal groove is formed in the longitudinal wall, and the length of the machining machine plate is smaller than that of the longitudinal wall so that a clearance groove is formed in one end of the machining machine plate. For example, the middle part of the turnover wall is rotatably connected to one end of the processing machine plate, one end of the turnover wall is suspended above the clearance groove, an elastic structure and an ejecting structure are adjacently arranged at one end of the turnover wall, an inclined groove is concavely arranged at the other end of the turnover wall, and the inclined groove extends along the upward direction of inclination and is positioned above the clearance groove. For example, the covering panel is inserted into the horizontal groove and the inclined groove to force the turning wall to rotate, so that the covering panel abuts against the elastic structure to descend and the pop-up structure contracts towards the turning wall until the upper surface of the covering panel abuts against the bottom surface of the pop-up structure and the lower surface of the covering panel abuts against the upper surface of the elastic structure. For example, the drilling assembly is installed on the overturning wall and used for drilling the cladding panel, the drilling assembly comprises a mounting frame, a drilling motor and a drilling spindle, the mounting frame is installed at the top of the overturning wall, and the drilling motor is installed on the mounting frame and located above the machining machine plate. For example, the drilling spindle is coaxially fixed to the output shaft of the drilling motor, and the axis of the drilling spindle is perpendicular to the central axis of the inclined groove.

Referring to fig. 1 to 6, a cladding panel machining system includes an L-shaped mounting base 20, an inverted wall 30 and a drilling assembly 50, where the L-shaped mounting base 20 includes a machine plate 21 and a longitudinal wall 22, the longitudinal wall 22 is vertically protruded at one side of the machine plate 21, the longitudinal wall 22 is opened with a horizontal groove 221 ', the length of the machine plate 21 is smaller than the length of the longitudinal wall 22 so as to form an empty-avoiding groove at one end of the machine plate 21, the middle portion of the inverted wall 30 is rotatably connected to one end of the machine plate 21, one end of the inverted wall 30 is suspended above the empty-avoiding groove, one end of the inverted wall 30 is adjacently provided with an elastic structure 33 and an ejection structure 35, the other end of the inverted wall 30 is recessed with an inclined groove 31, the inclined groove 31 extends in an obliquely upward direction and is located above the empty-avoiding groove, the cladding panel 100 is inserted in the horizontal groove 221' and the inclined groove 31 so as to force the inverted wall 30 to rotate, therefore, the covering panel 100 descends against the elastic structure 33 and the pop-up structure 35 contracts towards the turnover wall 30 until the upper surface of the covering panel 100 abuts against the bottom surface of the pop-up structure 35, the lower surface of the covering panel 100 abuts against the upper surface of the elastic structure 33, the drilling assembly 50 is mounted on the turnover wall 30 and used for drilling the covering panel 100, the drilling assembly 50 comprises a mounting frame 51, a drilling motor 52 and a drilling spindle 53, the mounting frame 51 is mounted at the top of the turnover wall 30, the drilling motor 52 is mounted on the mounting frame 51 and located above the processing machine plate 21, the drilling spindle 53 is coaxially fixed on an output shaft of the drilling motor 52, and the axis of the drilling spindle 53 is perpendicular to the central axis of the inclined groove 31.

When the machining system of the cladding panel is used, one end of the cladding panel 100 is inserted between the longitudinal wall 22 and the turnover wall 30, that is, one side of the cladding panel 100 is inserted in the horizontal groove 221' of the longitudinal wall 22, and the other side of the cladding panel passes through the ejecting structure 35 and is inserted into the inclined groove 31, because the inclined groove 31 is obliquely arranged, the insertion of the cladding panel 100 can force the turnover wall 30 to rotate, one end of the cladding panel falls into the clearance groove of the processor plate 21, and the cladding panel 100 is supported by the elastic structure 33 to descend, so that the ejecting structure 35 contracts towards the turnover wall 30. After the cover panel 100 goes down over the pop-up structure 35, the pop-up structure 35 pops up again so that the upper surface of the cover panel 100 abuts against the bottom surface of the pop-up structure 35, and the lower surface of the cover panel 100 abuts against the upper surface of the elastic structure 33, so that the lower surface of the pop-up structure 35 abuts against the upper surface of the cover panel 100 and the upper surface of the elastic structure 33 abuts against the lower surface of the cover panel 100, thereby elastically positioning the cover panel 100. Thereafter, the drilling motor 52 drives the drilling spindle 53 to rotate, so as to perform a drilling operation on the cladding panel 100. When the covering panel 100 needs to be released, the covering panel 100 is pulled back and forth. Through the arrangement of the elastic structure 33 and the pop-up structure 35, the clamping, positioning and releasing of the cover plate 100 are both simple and convenient, and the cover plate 100 is released without unscrewing the screws and disassembling various clamps one by one.

For example, in order to facilitate a more stable guiding during the turning of the turning wall 30, the horizontal groove 221 'extends in the longitudinal direction of the longitudinal wall 22, and the width of the horizontal groove 221' is equal to the thickness of the cover panel 100. The angle between the central axis of the inclined groove 31 and the surface of the machine plate 21 is 45 degrees. The elastic structure 33 includes a stainless steel base plate 331, a plurality of springs 332, and a lifting plate 333, wherein the stainless steel base plate 331 is fixed to the machine plate 21, the plurality of springs 332 are mounted in parallel to each other on the stainless steel base plate 331, and the lifting plate 333 is mounted on top of the plurality of springs 332. A strip-shaped groove is formed in one side, away from the longitudinal wall 22, of the processing machine plate 21, the strip-shaped groove is parallel to the horizontal groove 221', the turnover wall 30 is rectangular plate-shaped, and the bottom of the turnover wall 30 is movably inserted into the strip-shaped groove. The bottom of the end of the turning wall 30 far away from the empty slot is extended downwards to form a triangular plate, the end of the strip-shaped slot far away from the empty slot is extended downwards to form a triangular deep slot, and the triangular plate is inserted into the triangular deep slot. By arranging the triangular deep groove, the turnover wall 30 can be inserted into the triangular deep groove by utilizing the triangular plate after being restored to the original position, and the positioning stability is further improved.

For example, in order to facilitate the covering panel 100 to press the elastic structure 33 and the pop-up structure 35, the side of the flip wall 30 facing the longitudinal wall 22 is formed with a limiting surface 32, the upper portion of the limiting surface 32 is formed with a step portion 321, one side of the lifting plate 333 slidably abuts against the limiting surface 32, and the top of the lifting plate 333 abuts against the bottom surface of the step portion 321. A top barrier strip 322 is convexly arranged on the top of the limiting surface 32 towards the longitudinal wall 22, a feeding interval 323 is formed between the top surface of the lifting plate 333 and the top barrier strip 322, and the feeding interval 323 is aligned with one end of the bottom of the inclined groove 31. By providing the step portion 321, the maximum height of the lifting plate 333 is limited, so that the supplied material interval 323 is formed, and the cover board 100 is conveniently introduced, thereby facilitating the subsequent pressing of the elastic structure 33 and the pop-up structure 35.

For example, in order to facilitate the surface treatment of the cladding panel 100 before the drilling operation, the longitudinal wall 22 is penetrated with a through groove 221, the through groove 221 is arranged above the horizontal groove 221', the cladding panel machining system further comprises a scraping assembly 40, the scraping assembly 40 comprises a transmission structure and a scraping roller 43, the transmission structure is arranged on the longitudinal wall 22, and the scraping roller 43 is connected to the transmission structure. The scraping roller 43 is perpendicular to the longitudinal wall 22, the scraping roller 43 is disposed in the through groove 221 and extends above the machine plate 21, and an end of the scraping roller 43 away from the transmission structure is slidably abutted against the surface of the top barrier 322. Through the arrangement of the scraping assembly 40, the scraping roller 43 is driven by the transmission structure to slide along the through groove 221, so as to implement the scraping operation.

For example, the turning wall 30 is provided at a middle portion thereof with a rotating shaft, and opposite ends of the rotating shaft are rotatably inserted into opposite side walls of an end portion of the strip-shaped groove, respectively. The rotating shaft is sleeved with a torsion spring which is used for forcing the bottom surface of the turning wall 30 to keep abutting against the strip-shaped groove of the processing machine plate 21, namely for righting the turning wall 30. The drilling spindle 53 is used to vertically align the sheathing panel 100 following the inversion of the inversion wall 30 to perform a drilling operation. For example, in order to facilitate the operation of driving the scraping roller 43, the transmission structure includes a driving wheel 41, a driven wheel 42, a transmission belt 44 and a transmission motor 45, the driving wheel 41 and the driven wheel 42 are fixed on the longitudinal wall 22 and respectively adjacent to the two opposite ends of the through groove 221, the transmission belt 44 is sleeved on the driving wheel 41 and the driven wheel 42, the transmission motor 45 is installed on the longitudinal wall 22 through a bracket, and the driving wheel 41 is coaxially and fixedly sleeved on an output shaft of the transmission motor 45. The scraping assembly 40 further comprises a reversing motor 46, the housing of the reversing motor 46 is fixed on the transmission belt 44, and the scraping roller 43 is coaxially mounted on the output shaft of the reversing motor 46. By providing the transmission belt 44, the transmission motor 45 can reciprocate the scraping roller 43 to perform the scraping work.

For example, in order to guide the falling of the drilling dust, the push-and-drop plate 217 is disposed at one end of the machine plate 21, and the push-and-drop plate 217 is connected to the end of the machine plate 21 by a torsion spring and is located in the clearance groove. The upper surface of the push-down plate 217 is coplanar with the upper surface of the processor plate 21. Opposite sides of the push-down plate 217 respectively abut against the bottom surface of the turning wall 30 and the bottom surface of the longitudinal wall 22. The push-down plate 217 is rotated by the overturning wall 30 during the overturning action of the overturning wall 30 to guide the discharge of the particles generated by the drilling assembly 50. The push-and-drop plate 217 is arranged, so that the particle scraps generated by drilling can be conveniently discharged by using the push-and-drop plate 217. For example, in order to facilitate guiding the turnover of the turnover wall 30, the opposite sides of the processor board 21 are respectively provided with a rotation guide board 214 and a rotation abutting board 215 through hinges, and the rotation guide board 214 is used for rotatably fitting to the side surface of the turnover wall 30 to guide the turnover of the turnover wall 30, so that the turnover wall 30 is not easy to be displaced in the turnover process. The top of the rotary supporting plate 215 is provided with a supporting wheel 218, and the rotary supporting plate 215 is used for rotatably adhering to the side surface of the longitudinal wall 22 to support the driving belt 44 by the supporting wheel 218, so as to tension the driving belt 44 and prevent looseness.

For example, in order to facilitate the ejection structure 35 to downwardly abut against the upper surface of the cover panel 100, the ejection structure 35 includes an ejection block 351 and a compression spring, the ejection block 351 is connected to the limiting surface 32 by the compression spring, the ejection block 351 is telescopically disposed on the limiting surface 32, a height position of the ejection block 351 is flush with a height position of the lifting plate 333, and the ejection block 351 is located on a side of the elastic structure 33 facing the inclined groove 31. The top surface of the eject block 351 is formed with an inclined pressing surface 3515, and the distance between the inclined pressing surface 3515 and the stopper surface 32 gradually increases in the vertical downward direction. A holding and pressing inclined surface 3518 is formed on the bottom surface of the eject block 351, and the holding and pressing inclined surface 3518 is parallel to the central axis of the inclined groove 31. During the turning process of the turning wall 30, the bottom surface of the cover panel 100 is used for pressing and holding the inclined pressing surface 3515 of the pop-up block 351, so that the inclined pressing surface 3515 gradually moves to the side wall of the cover panel 100 and presses the pop-up block 351 to retract into the turning wall 30, and when the cover panel 100 moves downwards to the lower side of the pop-up block 351, the pop-up block 351 pops out and presses and holds the upper surface of the cover panel 100 by using the pressing and holding inclined surface 3518. Thereby achieving a holding position for the upper surface of the cover plate 100.

For example, in order to facilitate scraping operation, a baffle 39 is disposed at an end of the turnover wall 30 away from the pop-up structure 35, the baffle 39 is perpendicular to the surface of the processing machine plate 21, a flat abutting plate portion 395 is convexly formed at a lower portion of the baffle 39, a stop surface 396 is formed at a side of the flat abutting plate portion 395 facing the elastic structure 33, and the stop surface 396 is inclined with respect to the surface of the processing machine plate 21. The flat support plate portion 395 is provided with a dust falling hole 398 therethrough. The scraping roller 43 is positioned above the cover plate 100, the first scraper 431 is connected to the circumferential surface of the scraping roller 43 through an elastic member, the second scraper 432 is telescopically inserted into the first scraper 431, and the third scraper 433 is telescopically inserted into the second scraper 432. The first squeegee 431, the second squeegee 432, and the third squeegee 433 are parallel to each other and are each disposed obliquely to the surface of the cover panel 100. The end of the third scraper 433 is formed with a wedge-shaped tip 4335. The scraping roller 43 is further provided with a limiting strip 437 in a protruding manner, and the limiting strip 437 is abutted against one side above the first scraper 431 to limit the rotation of the first scraper 431. In use, the flap 39 is adapted to be tilted to an inclined angle following the tilt wall 30 such that an acute angle is formed between the upper portion of the flap 39 and the first scraper 431. The flat abutting plate portion 395 of the baffle 39 is used for stopping and positioning the end face of the cover plate 100, and the stopping surface 396 partially covers the lower portion of the end face of the cover plate 100, so that a gap 439 is formed between the upper portion of the end face of the cover plate 100 and the baffle 39. The gap 439 communicates with the dust drop hole 398. The scraping roller 43 is configured to move along the surface of the cover board 100 toward the position of the baffle 39 under the driving of the driving belt 44, so that the third scraping plate 433 continuously scrapes the surface of the cover board 100 until the wedge-shaped tip 4335 of the third scraping plate 433 abuts against the baffle 39 and is inserted into the gap 439, and the scraped dust is pushed into the gap 439 and falls onto the push-and-drop plate 217 through the dust drop hole 398 (at this time, the push-and-drop plate is disposed obliquely under the abutting of the flip wall 30, and the dust can be led out by using the inclined upper surface thereof). Under the continuous driving of the transmission belt 44 and the stopping action of the baffle 39, the third scraper 433 is used to be retracted into the second scraper 432, the second scraper 432 is retracted into the first scraper 431, and the first scraper 431 is used to rotate around the scraping roller 43 toward the side away from the limiting strip 437, so that the wedge-shaped tip 4335 of the third scraper 433 completely abuts against the upper portion of the end face of the cover plate 100. Thereafter, the turnover motor 46 is used for driving the third scraping plate 433 to rotate through the scraping roller 43 so as to completely abut against the end surface of the covering panel 100, the transmission motor 45 rotates in the reverse direction so as to drive the scraping roller 43 to retreat through the transmission belt 44, and then the third scraping plate 433 pushes the covering panel 100 to retreat, and the turnover wall 30 is straightened under the action of the torsion spring, so that the baffle 39 rotates, and all the particles on the upper surface of the flat abutting plate portion 395 fall onto the push-down plate 217.

By arranging three scrapers to cooperate with the baffle 39, on one hand, a gap 439 can be formed between the baffle 39 and the cover plate 100 to facilitate ash discharge and discharge of the particles through the inclined push-and-drop plate 217; on the other hand, the gap 439 can also allow the wedge-shaped tip 4335 of the third scraper 433 to enter, and the third scraper 433 can force the first scraper 431 to rotate relative to the scraping roller 43 after being stopped by the baffle 39, so that the wedge-shaped tip 4335 can enter into the gap 439; moreover, after the reverse rotation, the third scraping plate 433 can be used to push the cover plate 100 to exit; finally, after releasing the flip wall 30, the flap 39 can be rotated to throw away any remaining debris from the flat retaining plate portion 395. Therefore, in the present invention, the scraper roller 43 and the baffle 39 are cooperatively arranged, so that the dust discharging efficiency can be improved, and the shroud panel 100 can be reversely pushed out, thereby achieving two purposes and being very convenient.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A mechanical processing system of a covering panel is characterized by comprising an L-shaped mounting seat, a turnover wall and a drilling assembly, wherein the L-shaped mounting seat comprises a processing machine plate and a longitudinal wall, the longitudinal wall is vertically and convexly arranged on one side of the processing machine plate, a horizontal groove is formed in the longitudinal wall, the length of the processing machine plate is smaller than that of the longitudinal wall so that a clearance groove is formed in one end of the processing machine plate, the middle part of the turnover wall is rotatably connected to one end of the processing machine plate, one end of the turnover wall is suspended above the clearance groove, an elastic structure and a pop-up structure are adjacently arranged at one end of the turnover wall, an inclined groove is concavely arranged at the other end of the turnover wall, the inclined groove extends in an upward inclined direction and is positioned above the clearance groove, the covering panel is inserted into the horizontal groove and the inclined groove to force the turnover wall to rotate, so that the covering panel supports the elastic structure to descend and enables the pop-up structure to shrink towards, the upper surface of covering panel supports the bottom surface of holding pop-up structure until, and the lower surface of covering panel supports the upper surface in elastic construction, drilling subassembly install on the upset wall in order to be used for carrying out the drilling operation to the covering panel, drilling subassembly includes the mounting bracket, drilling motor and drilling main shaft, the mounting bracket is installed in the top of upset wall, the drilling motor is installed on the mounting bracket and is located the top of processor board, the drilling main shaft is coaxially fixed in on the output shaft of drilling motor, the axis of drilling main shaft is perpendicular with the axis of inclined groove.

2. The decking machining system defined in claim 1 wherein the horizontal slot extends along the length of the longitudinal wall, the horizontal slot having a width equal to the thickness of the decking.

3. The system of claim 2, wherein the angle between the central axis of the angled slot and the surface of the machine plate is 45 degrees.

4. The decking machining system defined in claim 3 wherein the resilient structure includes a stainless steel base plate secured to the machine plate, a plurality of springs mounted in parallel on the stainless steel base plate, and a lifting plate mounted on top of the plurality of springs.

5. The system of claim 4, wherein the side of the processor plate remote from the longitudinal wall is provided with a strip-shaped groove, the strip-shaped groove is parallel to the horizontal groove, the flip wall is rectangular plate-shaped, and the bottom of the flip wall is movably inserted into the strip-shaped groove.

6. The system of claim 5, wherein the bottom of the end of the turnover wall away from the cavity-avoiding groove is formed with a triangular plate protruding downward, the end of the strip-shaped groove away from the cavity-avoiding groove extends downward to form a triangular deep groove, and the triangular plate is inserted into the triangular deep groove.

7. The system of claim 6, wherein the side of the upturned wall facing the longitudinal wall is formed with a limiting surface, the upper portion of the limiting surface is formed with a step portion, one side of the lifting plate slidably abuts against the limiting surface, and the top of the lifting plate abuts against the bottom surface of the step portion.

8. The system of claim 7, wherein a top stop is provided at the top of the stop surface and protruding toward the longitudinal wall, and a feeding gap is formed between the top surface of the lifting plate and the top stop, the feeding gap being aligned with one end of the bottom of the inclined groove.

9. The panel-covered machining system according to claim 8, wherein a through groove is formed in the longitudinal wall in a penetrating manner, the through groove is arranged above the horizontal groove in parallel, the panel-covered machining system further comprises a scraping assembly, the scraping assembly comprises a transmission structure and a scraping roller, the transmission structure is arranged on the longitudinal wall, and the scraping roller is connected to the transmission structure.

10. The system of claim 9, wherein the scraping roller is perpendicular to the longitudinal wall, the scraping roller is disposed in the through groove and extends above the machine plate, and an end of the scraping roller away from the transmission structure is slidably supported on a surface of the top barrier.

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