Big data analysis type assembly building template production method
1. A big data analysis type assembly building template production method is characterized by comprising the following steps:
s1, the control system acquires the data information of the processed building template on the belt conveyor through a code scanner;
s2, the control system calls the stored big data information for processing according to the obtained model data information, and the processed template is processed;
s3, supporting a lifting receiving electric pole on a main frame to drive a longitudinal receiving frame to move downwards, driving a clamping port at the lower end of a second clamping receiving frame to push and clamp the front end of the processed template backwards by a clamping electric pole on the longitudinal receiving frame, and enabling the rear end of the processed building template to enter the clamping port at the lower end of a first clamping receiving frame;
s4, receiving the lifting electric pole to drive the receiving longitudinal frame to move upwards, and lifting the processed building template to the processing height;
s5, the cutting longitudinal electric pole on the supporting main frame adjusts the longitudinal processing position of the rotary cutting tool to the processed building template according to the data information of the control system; the cutting transverse electric pole drives a rotary cutting tool to transversely cut and process the processed template;
after cutting, resetting the rotary cutting tool;
s6, under the drive of the bearing lifting electric pole, the first bearing clamping frame and the second bearing clamping frame move the processed building template to the belt conveyor;
the bearing clamping electric pole drives the clamping port at the lower end of the second bearing clamping frame to move forwards and separate from the front end of the processed building template;
the belt conveyor drives the processed building template to move forwards, and the clamping opening at the lower end of the first bearing clamping frame is separated from the rear end of the building template;
the first bearing clamping frame and the second bearing clamping frame move upwards under the driving of the bearing lifting electric pole;
and the belt conveyor drives the processed building template to move backwards until the processed building template moves out of the tail part of the belt conveyor.
2. The big data analysis type assembly building template production method as claimed in claim 1, wherein in step S3, the retaining opening is provided with a receiving pressure detection switch to detect whether the end of the building template enters the retaining opening.
3. The method of claim 1, wherein in step S3, the proximity detection switch of the material on the support main frame detects whether the processed building template on the belt conveyor is moved into position.
4. The big data analysis type assembly building template production method as claimed in claim 1, wherein a top convex roller arranged below the belt conveyor jacks up a belt on the upper side of the belt conveyor under the action of a top convex electric pole, so that the front end of the building template is tilted.
5. The big data analysis type assembly building template production method as claimed in claim 4, wherein whether the rear end of the building template is tilted to a certain height is detected through a receiving height detection switch provided on the support main frame.
6. The big data analysis type assembly building template production method as claimed in claim 4, wherein a tail regulation roller is arranged at the tail end of the belt conveyor; the tail adjusting frame which is arranged in a back-and-forth moving mode adjusts the tightness degree of a belt of the belt conveyor through the tail adjusting roller under the action of the tail adjusting spring;
when the tail adjusting tension sensor on the tail adjusting spring detects that the tension of the tail adjusting rack reaches a certain value, the tail adjusting rod connected with the tail adjusting spring further adjusts the front and rear positions of the tail adjusting rack.
7. The method as claimed in claim 1, wherein the position of the front end of the building template to be processed on the belt conveyor is detected by a color sensor under the chucking opening of the second receiving chucking frame.
8. The method as claimed in claim 1, wherein in step S5, the longitudinal lifting position of the lifting plate to the template to be processed is adjusted by lifting the lifting vertical adjusting pole on the supporting main frame;
adjusting the transverse lifting position of the lifting plate to the processed template by lifting the transverse moving electric pole;
and the lifting plate is provided with a cutting groove corresponding to the rotary cutting tool.
9. The method as claimed in claim 8, wherein the elevation of the mast is adjusted by lifting the vertical adjustment mast, the elevation of the lateral movement mast is adjusted by lifting the vertical adjustment mast, and the elevation of the lifting plate is adjusted.
10. The method as claimed in claim 8, wherein the discharging plate is driven to extend by a discharging pole supporting a lower portion of the main frame, and the side of the building panel is stopped when the building panel is separated from the lifting plate after being processed.
Background
In order to improve the rapid construction of a building body, the prefabricated building templates in a factory are adopted to carry out splicing type construction in the prior art, and the construction efficiency is greatly improved. Because different buildings have different requirements on the size of the building template, the building template needs to be processed in advance in a factory. With the rapid development of the information era, big data information with different processing requirements is implanted into a control system in advance, and two-dimensional code model information is set on a processing model of a building template. Therefore, the building templates of different models can be processed according to preset big data information. Currently, there is a lack of such facilities for the specialized manufacture of building templates using data information.
Disclosure of Invention
The invention aims to provide a big data analysis type assembly building template production method which is used for solving the technical problem of processing building templates.
The technical scheme adopted by the invention for solving the technical problems is as follows:
a big data analysis type assembly building template production method comprises the following steps:
s1, the control system acquires the data information of the processed building template on the belt conveyor 1 through the code scanner 2;
s2, the control system calls the stored big data information for processing according to the obtained model data information, and the processed template is processed;
s3, the receiving lifting electric pole 15 on the supporting main frame 12 drives the receiving longitudinal frame 16 to move downwards, the receiving clamping electric pole 20 on the receiving longitudinal frame 16 drives the clamping opening 24 at the lower end of the second receiving clamping frame 19 to push and clamp the front end of the processed template backwards, and then the rear end of the processed building template also enters the clamping opening 24 at the lower end of the first receiving clamping frame 17;
s4, the bearing lifting electric pole 15 drives the bearing longitudinal frame 16 to move upwards, and the processed building template rises to the processing height;
s5, the cutting longitudinal electric pole 33 on the supporting main frame 12 adjusts the longitudinal processing position of the rotary cutting tool 35 to the processed building template according to the data information of the control system; the cutting transverse electric pole 34 drives a rotary cutting tool 35 to transversely cut and process the processed template;
after cutting, the rotary cutting tool 35 is reset;
s6, under the drive of the bearing lifting electric pole 15, the first bearing clamping frame 17 and the second bearing clamping frame 19 move the processed building template to the belt conveyor 1;
the bearing clamping electric pole 20 drives the clamping port 24 at the lower end of the second bearing clamping frame 19 to move forwards and separate from the front end of the processed building template;
the belt conveyor 1 drives the processed building template to move forward, and the clamping opening 24 at the lower end of the first bearing clamping frame 17 is separated from the rear end of the building template;
under the driving of the bearing lifting electric pole 15, the first bearing clamping frame 17 and the second bearing clamping frame 19 move upwards;
the belt conveyor 1 drives the processed building template to move backwards until the processed building template moves out of the tail part of the belt conveyor 1.
Further, in step S3, it is detected whether the end of the building template enters the retaining opening 24 through the receiving pressure detecting switch 21 provided in the retaining opening 24.
Further, in step S3, it is detected whether the building template to be processed on the belt conveyor 1 is moved in place by the material proximity detection switch 13 on the support main frame 12.
Further, the top convex roller 4 arranged below the belt conveyor 1 jacks up the belt on the upper side of the belt conveyor 1 under the action of the top convex electric pole 3, and then the front end of the building template is tilted.
Further, whether the rear end of the building template is tilted to a certain height or not is detected through a receiving height detection switch 14 arranged on the supporting main frame 12.
Further, a tail adjusting roller 7 is arranged at the tail end of the belt conveyor 1; the tail adjusting frame 5 which is arranged in a forward and backward moving mode adjusts the degree of tightness of a belt of the belt conveyor 1 through a tail adjusting roller 7 under the action of a tail adjusting spring 9;
when the tail adjusting tension sensor 11 on the tail adjusting spring 9 detects that the tension of the tail adjusting rack 5 reaches a certain value, the tail adjusting rod 10 connected with the tail adjusting spring 9 further adjusts the front and rear positions of the tail adjusting rack 5.
Further, the position of the front end of the building template to be processed on the belt conveyor 1 is detected by the color mark sensor 23 below the clamping opening 24 of the second receiving and clamping frame 19.
Further, in step S5, the longitudinal lifting position of the lifting plate 29 with respect to the processed template is adjusted by the lifting longitudinal adjustment pole 25 on the support main frame 12;
the transverse lifting position of the lifting plate 29 to the processed template is adjusted by lifting the transverse moving electric pole 27;
the lifting plate 29 is provided with a cutting groove 32 corresponding to the rotary cutting tool 35.
Further, the lifting height of the lifting transverse moving electric pole 27 and the lifting plate 29 is adjusted through lifting the vertical adjusting electric pole 28.
Furthermore, the unloading pole 30 supporting the lower part of the main frame 12 drives the unloading plate 31 to extend out, and when the processed building template is separated from the lifting plate 29, the side of the building template is blocked.
The effect provided in the summary of the invention is only the effect of the embodiment, not all the effects of the invention, and one of the above technical solutions has the following advantages or beneficial effects:
1. according to the technical scheme, the top convex mechanism and the tail adjusting mechanism arranged on the belt conveyor can be matched with the bearing mechanism to conveniently obtain the building template.
2. The bearing mechanism utilizes the second bearing clamping frame 19 which can longitudinally move and bear the clamping electric pole 20, and utilizes the first bearing jacking electric pole 18 to vertically adjust the first bearing clamping frame 17, thereby facilitating the clamping of two ends of the building template.
3. By utilizing the lifting mechanism for supporting the upper end of the main frame 12, the lifting mechanism can be matched with the bearing mechanism to lift the processed building template, and the processed building template is transferred to the belt conveyor in an auxiliary manner, and meanwhile, the bearing mechanism is convenient to separate from the processed building template.
4. The unloading electric pole 30 and the unloading plate 31 which are arranged at the lower end of the support main frame 12 cooperate with the transverse action of the lifting mechanism, so that the lifting mechanism is conveniently separated from the processed template.
Drawings
FIG. 1 is a schematic top view of an embodiment of the present invention;
FIG. 2 is a schematic side view of a tail trim mechanism in an embodiment of the present invention;
FIG. 3 is a schematic front view of an embodiment of the present invention;
FIG. 4 is a schematic side sectional view of the receiving mechanism according to the embodiment of the present invention;
FIG. 5 is an enlarged view of a portion A of FIG. 4;
in the figure: 1. a belt conveyor; 2. a code scanner; 3. a top convex pole; 4. a top convex roller; 5. a tail adjusting frame; 6. tail adjusting guide rails; 7. a tail adjusting roller; 8. a tail adjustment fixing frame; 9. a tail adjusting spring; 10. a tail telegraph pole; 11. a tail tension adjusting sensor; 12. supporting the main frame; 13. a material approach detection switch; 14. a reception height detection switch; 15. carrying a lifting electric pole; 16. carrying a longitudinal frame; 17. a first receiving and clamping frame; 18. the first bearing jacking electric pole; 19. a second bearing and clamping frame; 20. carrying and clamping the electric pole; 21. a receiving pressure detection switch; 22. a height detection switch for receiving the clamping; 23. a color code sensor; 24. a clamping port; 25. lifting the longitudinal adjusting electric pole; 26. lifting the longitudinal adjusting plate; 27. lifting the transverse moving electric pole; 28. lifting the vertical adjusting electric pole; 29. a lifting plate; 30. unloading the electric pole; 31. a stripper plate; 32. cutting the groove; 33. cutting the longitudinal electric pole; 34. cutting the transverse electric pole; 35. the cutting tool is rotated.
Detailed Description
As shown in fig. 1 to 5, a system for implementing a big data analysis type assembly building template production method includes a control system for storing big data and collecting production process data information, a conveying system electrically connected with the control system for carrying building templates, and a size processing system switched with the conveying system and processing the building templates.
The conveying system comprises a belt conveyor 1, a code scanner 2, a top convex mechanism and a tail adjusting mechanism; the belt conveyor 1 is used for carrying building templates; the code scanner 2 is arranged on one side of the belt conveyor 1 through a support and is used for acquiring two-dimensional code information on the processed building template, so that a control system can control related functional components according to the acquired information; the jacking mechanism is arranged below the belt conveyor 1 and used for jacking a local upper side belt of the belt conveyor 1, so that the front end of the building template is tilted when passing through the jacking mechanism, and a dimension processing system can conveniently obtain the building template; the tail adjusting mechanism is arranged at the tail of the belt conveyor 1 and used for being matched with the top protruding mechanism to adjust the tightness of a belt on the belt conveyor 1. The top-convex mechanism comprises a top-convex electric pole 3 and a top-convex roller 4, and the top-convex electric pole 3 is vertically arranged on two sides of the frame of the belt conveyor 1; the top convex roller 4 wheel is transversely arranged at the upper end of the top convex electric pole 3 through a rotating shaft in a rotatable manner and is positioned below a belt on the upper side of the belt conveyor 1. The tail adjusting mechanism comprises a tail adjusting rack 5, a tail adjusting guide rail 6, a tail adjusting roller 7, a tail adjusting fixing frame 8, a tail adjusting spring 9, a tail adjusting electric rod 10 and a tail adjusting tension sensor 11; the tail adjusting guide rails 6 are arranged on two sides of the rear part of the belt conveyor 1, the lower end of the tail adjusting rack 5 is arranged on the tail adjusting guide rails 6 in a back-and-forth movement mode through sliding shoes, the tail adjusting roller 7 is rotatably arranged at the upper end of the tail adjusting rack 5 through a rotating shaft, and the belt tail part of the belt conveyor 1 bypasses the tail adjusting roller 7; the tail adjusting fixing frame 8 is arranged behind the tail adjusting rack 5, the tail adjusting electric rod 10 is arranged along the extending direction of the belt conveyor 1, and the front end of the tail adjusting electric rod 10 is connected with the tail adjusting rack 5 through a tail adjusting spring 9; and the tail adjusting tension sensor 11 is arranged between the front end of the tail adjusting rod 10 and the tail adjusting spring 9. When the top convex mechanism jacks up the upper side belt upwards to increase the tension of the tail roller adjusting wheel 7; firstly, the tail adjusting frame 5 stretches the tail adjusting spring 9 to adapt to the forward displacement of the belt; when the tail adjusting tension sensor 11 detects that a certain tension is reached, the tail adjusting rod 10 gradually extends to cooperate with the tail adjusting spring 9 to adjust the position of the tail adjusting rack 5, and then cooperates with the top convex mechanism to act.
The size processing system comprises a processing detection supporting mechanism, a bearing mechanism, a lifting mechanism and a cutting mechanism. The processing detection supporting mechanism comprises a supporting main frame 12, a material approach detection switch 13 and a carrying height detection switch 14, wherein the supporting main frame 12 stretches across the upper part of the belt conveyor 1 and is arranged corresponding to the top-convex mechanism up and down; the material approach detection switch 13 is arranged on the support main frame 12 and is used for detecting whether the front end of the building template on the belt conveyor 1 moves to the top-convex mechanism or not so as to facilitate the top-convex mechanism to execute actions; and the bearing height detection switch 14 is also arranged on the support main frame 12 and is positioned above the material approach detection switch 13, and is used for detecting whether the front end of the building template is tilted to a certain height through the action of the top convex mechanism so as to facilitate the action of the bearing mechanism. The supporting mechanism comprises a supporting lifting electric pole 15, a supporting longitudinal frame 16, a first supporting clamping frame 17, a first supporting jacking pressure electric pole 18, a second supporting clamping frame 19, a supporting clamping electric pole 20, a supporting pressure detection switch 21, a supporting clamping height detection switch 22 and a color mark sensor 23. Accept the vertical setting of lift pole 15 and be in support the middle part upper end of body frame 12, accept indulge the frame 16 and be located the upper end below of supporting body frame 12 and be connected with the lift removal power take off who accepts lift pole 15. The first top pressure bearing electric pole 18 is vertically arranged below the rear end of the bearing longitudinal frame 16, and the first bearing clamping frame 17 is arranged on the lifting moving power output end of the first top pressure bearing electric pole 18; the lower end of the first receiving clamping frame 17 is provided with a clamping opening 24, the opening of the clamping opening faces the front, and the receiving pressure detection switch 21 is arranged in the clamping opening 24. The bearing and clamping electric pole 20 is longitudinally arranged on the bearing and clamping frame 16, and the second bearing and clamping frame 19 is vertically arranged on the longitudinal moving power output end of the bearing and clamping electric pole 20; the lower end of the second receiving clamping frame 19 is also provided with a clamping opening 24, the opening of the clamping opening 24 faces the rear, and a receiving pressure detection switch 21 is also arranged in the clamping opening 24; the color mark sensor 23 is arranged at the lower end of the clamping port 24; the receiving clamping height detection switch 22 is arranged on the second receiving clamping frame 19 and is used for detecting the height change of the building template below. The working process of the bearing mechanism is as follows: after the material approach detection switch 13 detects that the building template arrives, the belt conveyor 1 stops moving, and the top convex mechanism jacks up the upper side belt of the belt conveyor 1, namely the rear end of the building template tilts; when the receiving height detection switch 14 detects that the rear end of the building template is tilted by a certain height, the receiving clamping electric pole 20 drives the second receiving clamping frame 19 to move towards the front end, and the receiving clamping electric pole 20 stops moving until the color mark sensor 23 detects that the front end of the building template is tilted; the bearing lifting electric pole 15 drives the first bearing clamping frame 17 and the second bearing clamping frame 19 to simultaneously move downwards to the right position through the bearing longitudinal frame 16, the belt conveyor 1 is started again to drive the building template to move backwards, when the bearing pressure detection switch 21 in the clamping port 24 at the lower end of the first bearing clamping frame 17 detects that the rear end of the building template enters the clamping port 24, the first bearing top pressure electric pole 18 moves downwards to push the rear end of the building template downwards through the first bearing clamping frame 17, and the front end of the building template is enabled to be tilted up by taking the top convex roller 4 as a fulcrum; when the receiving clamping height detection switch 22 on the second receiving clamping frame 19 detects that the front end of the building template is tilted to a certain height, the receiving clamping electric pole 20 drives the second receiving clamping frame 19 to move backwards, and when the pressure sensor in the second receiving clamping frame 19 detects that the front end of the building template enters the clamping opening 24, the receiving clamping electric pole 20 stops moving; the bearing lifting electric pole 15 drives the first bearing clamping frame 17 and the second bearing clamping frame 19 to simultaneously move upwards to the proper position through the bearing longitudinal frame 16, and the lifting mechanism and the cutting mechanism are started to work.
The lifting mechanism comprises a lifting longitudinal adjusting electric pole 25, a lifting longitudinal adjusting plate 26, a lifting transverse moving electric pole 27, a lifting vertical adjusting electric pole 28, a lifting plate 29, a discharging electric pole 30 and a discharging plate 31; the lifting longitudinal adjusting electric pole 25 is longitudinally arranged on the left side of the upper part of the supporting main frame 12, the lifting position of the lifting plate 29 on the building template is adjusted according to the data information of the control system, and the lifting longitudinal adjusting plate 26 is arranged on the longitudinal moving power output end of the lifting longitudinal adjusting electric pole 25; the lifting vertical adjusting electric pole 28 is vertically arranged on the lifting longitudinal adjusting plate 26, and the lifting transverse moving electric pole 27 is positioned below the lifting longitudinal adjusting plate 26 and is connected with a vertical moving power output end of the lifting vertical adjusting electric pole 28; the lifting plate 29 is transversely arranged, and the outer end of the lifting plate 29 is connected with the transverse moving power output end of the lifting transverse moving electric pole 27. The transverse direction of the lifting plate 29 is provided with a through cutting groove 32, the cutting groove 32 divides the lifting plate 29 into a front part and a rear part, the front part and the rear part are respectively arranged corresponding to the first bearing clamping frame 17 and the second bearing clamping frame 19, and the cutting groove 32 is arranged corresponding to the cutting mechanism. The discharging pole 30 is arranged at the front and rear ends of the left side of the lower part of the supporting main frame 12, and the discharging plate 31 is arranged at the power output end of the discharging pole 30.
The cutting mechanism comprises a longitudinal electric pole 33, a transverse electric pole 34 and a rotary cutting tool 35; the cutting longitudinal electric pole 33 is longitudinally arranged on the right side of the upper part of the supporting main frame 12 and is used for adjusting the cutting position of the building template according to the data information of the control system; the horizontal pole 34 of cutting transversely sets up on the vertical removal power take off of the vertical pole 33 of cutting, rotatory cutting tool 35 through the support setting on the horizontal removal power take off of the horizontal pole 34 of cutting, rotatory cutting tool 35 with cut groove 32 phase-match on the lifting plate 29. After the rotary cutting tool 35 finishes cutting the building template and resets according to requirements, the front part of the lifting plate 29 and the second bearing and clamping frame 19 are matched with leftovers of the cut building template, and the rear part of the lifting plate 29 and the first bearing and clamping frame 17 are matched with reserved parts of the cut building template. After the rotary cutting tool 35 is reset, the lifting vertical adjusting electric pole 28 and the bearing lifting electric pole 15 are matched together to drive the building template to move downwards to the belt conveyor; the bearing clamping electric pole 20 drives the second bearing clamping frame 19 to move forwards to be separated from the front end of the building template; cutting the longitudinal electric pole 33 to drive the lifting plate 29 and the building template to move forwards to be separated from the first bearing and clamping frame 17; the discharging electric poles 30 on the two sides drive the discharging plates 31 to extend inwards, and the discharging plates 31 move to the right side of the building template; the lifting transverse moving electric pole 27 drives the lifting plate 29 to move outwards, and the lifting plate 29 is separated from the processed building template borne above under the blocking of the discharging plate 31; the lifting mechanism and the bearing mechanism are reset, the belt conveyor 1 drives the cut building template to move forwards, and a worker transfers the cut building template and the cut leftovers respectively.
The control system comprises a controller, an operation control board and a memory, wherein the controller is electrically connected with each corresponding functional component, and the memory is used for storing big data information of the building template processing.
A big data analysis type assembly building template production method comprises the following steps:
s1, the control system acquires the data information of the processed building template on the belt conveyor 1 through the code scanner 2;
s2, the control system calls the stored big data information for processing according to the obtained model data information, and the processed template is processed;
s3, the receiving lifting electric pole 15 on the supporting main frame 12 drives the receiving longitudinal frame 16 to move downwards, the receiving clamping electric pole 20 on the receiving longitudinal frame 16 drives the clamping opening 24 at the lower end of the second receiving clamping frame 19 to push and clamp the front end of the processed template backwards, and then the rear end of the processed building template also enters the clamping opening 24 at the lower end of the first receiving clamping frame 17;
s4, the bearing lifting electric pole 15 drives the bearing longitudinal frame 16 to move upwards, and the processed building template rises to the processing height;
s5, the cutting longitudinal electric pole 33 on the supporting main frame 12 adjusts the longitudinal processing position of the rotary cutting tool 35 to the processed building template according to the data information of the control system; the cutting transverse electric pole 34 drives a rotary cutting tool 35 to transversely cut and process the processed template;
after cutting, the rotary cutting tool 35 is reset;
s6, under the drive of the bearing lifting electric pole 15, the first bearing clamping frame 17 and the second bearing clamping frame 19 move the processed building template to the belt conveyor 1;
the bearing clamping electric pole 20 drives the clamping port 24 at the lower end of the second bearing clamping frame 19 to move forwards and separate from the front end of the processed building template;
the belt conveyor 1 drives the processed building template to move forward, and the clamping opening 24 at the lower end of the first bearing clamping frame 17 is separated from the rear end of the building template;
under the driving of the bearing lifting electric pole 15, the first bearing clamping frame 17 and the second bearing clamping frame 19 move upwards;
the belt conveyor 1 drives the processed building template to move backwards until the processed building template moves out of the tail part of the belt conveyor 1.
Further, in step S3, it is detected whether the end of the building template enters the retaining opening 24 through the receiving pressure detecting switch 21 provided in the retaining opening 24.
Further, in step S3, it is detected whether the building template to be processed on the belt conveyor 1 is moved in place by the material proximity detection switch 13 on the support main frame 12.
Further, the top convex roller 4 arranged below the belt conveyor 1 jacks up the belt on the upper side of the belt conveyor 1 under the action of the top convex electric pole 3, and then the front end of the building template is tilted.
Further, whether the rear end of the building template is tilted to a certain height or not is detected through a receiving height detection switch 14 arranged on the supporting main frame 12.
Further, a tail adjusting roller 7 is arranged at the tail end of the belt conveyor 1; the tail adjusting frame 5 which is arranged in a forward and backward moving mode adjusts the degree of tightness of a belt of the belt conveyor 1 through a tail adjusting roller 7 under the action of a tail adjusting spring 9;
when the tail adjusting tension sensor 11 on the tail adjusting spring 9 detects that the tension of the tail adjusting rack 5 reaches a certain value, the tail adjusting rod 10 connected with the tail adjusting spring 9 further adjusts the front and rear positions of the tail adjusting rack 5.
Further, the position of the front end of the building template to be processed on the belt conveyor 1 is detected by the color mark sensor 23 below the clamping opening 24 of the second receiving and clamping frame 19.
Further, in step S5, the longitudinal lifting position of the lifting plate 29 with respect to the processed template is adjusted by the lifting longitudinal adjustment pole 25 on the support main frame 12;
the transverse lifting position of the lifting plate 29 to the processed template is adjusted by lifting the transverse moving electric pole 27;
the lifting plate 29 is provided with a cutting groove 32 corresponding to the rotary cutting tool 35.
Further, the lifting height of the lifting transverse moving electric pole 27 and the lifting plate 29 is adjusted through lifting the vertical adjusting electric pole 28.
Furthermore, the unloading pole 30 supporting the lower part of the main frame 12 drives the unloading plate 31 to extend out, and when the processed building template is separated from the lifting plate 29, the side of the building template is blocked.
In addition to the technical features described in the specification, the technology is known to those skilled in the art.
The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
