CN106476090B - Automatic board splicing machine capable of saving energy consumption - Google Patents

Abstract

An automatic board splicing machine capable of saving energy consumption belongs to the technical field of wood processing machinery. Comprises a frame; an upper and a lower heating mechanism; a plate pressing mechanism; a material turning mechanism; pushing equipment, characteristics: the pushing mechanism comprises a pair of pushing plate acting cylinders, a pushing plate and a pair of pushing plate synchronizing devices; the upper heating mechanism comprises a group of upper heating pipes, an upper heating pipe heating medium leading-in main pipe and an upper heating pipe heating medium leading-out main pipe; the lower heating mechanism comprises a group of lower heating pipes, a lower heating pipe heating medium leading-in main pipe and a lower heating pipe heating medium leading-out main pipe; a plate moving channel is formed between the group of upper heating pipes and the group of lower heating pipes; the plate pressing mechanism comprises a supporting beam, a pair of pressing action cylinder fixing frames, a pair of grid lath leaning beams, a group of grid laths, a plate pressing strip and a pair of plate pressing strip action cylinders; the cross section of one group of grid strips is V-shaped. The invention can save the energy consumption of the plate pressing mechanism.

Description

Automatic board splicing machine capable of saving energy consumption

Technical Field

The invention belongs to the technical field of wood processing machinery, and particularly relates to an automatic plate splicing machine capable of saving energy consumption.

Background

The above-mentioned board splicing machine has the function of splicing the battens with different lengths but approximately same thickness and width, which are generated in the process of producing the wooden products in the wooden product industry, into the whole board sheet with the specification of 122 (width) × 244 (length) & gt, and is used as the board of furniture cabinets and interior decoration, and the positive significance of the board splicing machine is that precious wood resources are saved.

Technical information on a board splicing machine is disclosed in published chinese patent document, for example, publication No. CN2265880Y recommends a "board splicing machine for heating" in which a plurality of heating pipes (referred to as heat pipes) are used as upper pressing plates, support rods are provided at both ends of the heating pipes, the heating pipes are arranged on an upper portion of a machine frame (referred to as a base) in a suspended state by the support rods, roller mechanisms are provided at both ends of a table, and rollers of the roller mechanisms are in contact with inclined surfaces of guide rail plates, thereby achieving elevation adjustment of the table. In addition, the patent shows a flap mechanism (called a flap table), a pneumatic pressing mechanism, a pushing mechanism (called a pusher) and a circular saw for aligning one end of the strip. Although the technical effects of the page 1, line 6 to line 3 of the specification can be obtained, the pushing mechanism only comprises a pair of pushing plate acting cylinders (oil cylinders for patent selection) and a pushing plate connected with the tail end of a pushing plate acting cylinder column of the pushing plate acting cylinder, so that the pushing mechanism can not generate the following technical problems in the actual use process: firstly, because the material pushing plate is relatively long (usually greater than or equal to 122 cm), and the middle part of the length direction of one side of the material pushing plate, which faces the material pushing plate acting cylinder, is connected with the tail end of the material pushing plate acting cylinder post, when the material pushing plate acting cylinder post extends out of the cylinder body to drive the material pushing plate to move, the material pushing plate is in a negative mode, namely, in a passive mode, the whole movement effect of the material pushing plate is difficult to guarantee, namely, the whole synchronous movement effect of the two ends and the middle part of the whole material pushing plate is difficult to guarantee, and the balanced pushing effect of the plate entering the plate cavity on the rack is influenced; secondly, because the scraping wings are directly placed on the scraping wings platform of the frame, the friction resistance is large, the energy consumption of the scraping wings acting on the cylinder is not saved, and the scraping wings are damaged due to frequent friction between the scraping wings and the scraping wings platform of the frame. Thirdly, because the structure of the plate pressing mechanism (called as a pneumatic pressing device in the patent) is unreasonable, the plate pressing mechanism can only be suitable for pressing short materials, and because the material baffle plate (the patent does not give reference numerals) corresponding to the material turning plate is an integral flat plate without hollow, when the plate pressing mechanism presses the plate in a state that the material baffle plate is matched with the material turning plate to clamp the strip, because the two side surfaces of the plate are simultaneously and respectively contacted with the material turning plate and the material baffle plate integrally, the descending resistance is large, and the energy consumption of the plate pressing mechanism is not favorably saved.

In view of the above-mentioned prior art, there is still a need for improvement, for which the applicant has made an advantageous design, which has finally resulted in the technical solution described below, and has proved to be feasible by carrying out simulation tests in the applicant's test center with the security measures taken.

Disclosure of Invention

The invention aims to provide an automatic plate splicing machine with a material pressing function, which is beneficial to enabling a material pushing plate to show a good overall motion effect so as to push plates in a plate cavity into a plate moving channel one by one under balanced acting force, and is beneficial to obviously reducing the friction degree between the material pushing plate and a material pushing plate platform of a frame so as to protect the material pushing plate and the material pushing plate platform, save the energy consumption of a material pushing plate acting cylinder, and be beneficial to adapting to pressing on a long plate, and obviously reduce the resistance when the plate descends so as to save the energy consumption of a plate pressing mechanism.

The object of the invention is achieved in that an automatic panel splicing machine with a pressing function comprises a machine frame, the left end of which is fixed in a state of being vacated from a floor between a pair of left upright posts of the machine frame, which are arranged face to face with each other and supported on the floor in a use state, and the right end of which is also fixed in a state of being vacated from the floor between a pair of right upright posts of the machine frame, which are arranged face to face with each other and supported on the floor in a use state, and a machine frame material pushing plate platform is arranged at the left end of the machine frame, wherein: a left adjusting beam is arranged between the left stand columns of the pair of frames and in a position corresponding to the upper part of the frames in a vertically moving mode, and a right adjusting beam is arranged between the right stand columns of the pair of frames and in a position corresponding to the upper part of the frames in a vertically moving mode; the upper heating mechanism is connected with the left adjusting beam and the right adjusting beam at a position corresponding to the lower parts of the left adjusting beam and the right adjusting beam at the same time, the lower heating mechanism is fixed on the rack at a position corresponding to the lower part of the upper heating mechanism, a space between the upper heating mechanism and the lower heating mechanism is formed into a plate moving channel, a left end port of the plate moving channel is formed into a plate introducing port, the plate introducing port is communicated with a plate cavity formed at the upper part of the left end of the rack, and a right end port of the plate moving channel is formed into a plate leading-out port in a splicing mode; the plate pressing mechanism is used for pressing plates which are positioned in the plate cavity in a superposed state, and is fixed on one side of the upper heating mechanism, which is back to the lower heating mechanism, at a position corresponding to the upper part of the plate cavity; the turning mechanism is used for feeding the sheet material into the sheet material cavity and is arranged on the rack at a position corresponding to the sheet material cavity; the utility model provides a pushing equipment for inciting somebody to action the sheet material in the sheet material intracavity the sheet material introduce mouthful, this pushing equipment corresponds to the left position setting of length direction in sheet material chamber is in on the frame scraping wings platform, characteristics are: the pushing mechanism comprises a pair of pushing plate acting cylinders, a pushing plate and a pair of pushing plate synchronizing devices, the pair of pushing plate acting cylinders are fixed on the pushing plate acting cylinder seat in a horizontal state, the material pushing plate acting cylinder columns of the material pushing plate acting cylinders face the material pushing plate, the material pushing plate corresponds to the length direction of the material cavity and is in sliding fit with the material pushing plate platform of the rack, a material pushing plate connecting seat is fixed on the material pushing plate and at the position corresponding to the material pushing plate acting cylinder column, the material pushing plate connecting seat is connected with the material pushing plate acting cylinder column, a pair of material pushing plate synchronizing devices are arranged between the material pushing plates and the machine frame material pushing plate platform, the material pushing plate action cylinder seat is fixed on the left side surface of a frame material pushing plate platform in a horizontal cantilever state, and the material turning mechanism corresponds to the upper part of the material pushing plate; the upper heating mechanism comprises a group of upper heating pipes, an upper heating pipe heating medium introducing main pipe and an upper heating pipe heating medium extracting main pipe, the group of upper heating pipes are distributed at intervals in a parallel state, the left ends of the group of upper heating pipes are connected with a left adjusting cross beam at a position corresponding to the lower part of the left adjusting cross beam, the right ends of the group of upper heating pipes are connected with a right adjusting cross beam at a position corresponding to the lower part of the right adjusting cross beam, an upper heating pipe heating medium introducing interface for introducing a heating medium into an upper heating pipe cavity is respectively fixed above the left ends of the group of upper heating pipes, an upper heating pipe heating medium extracting interface for extracting the heating medium out of the upper heating pipe cavity is respectively fixed on the right end surface of the group of upper heating pipes, and the upper heating pipe heating medium introducing main pipe is fixed between the left stand columns of the pair of racks, and corresponding to one side of the left adjusting beam facing the right adjusting beam, upper heating pipe heating medium introducing main pipe interfaces with the number equal to that of the upper heating pipes are formed on the upper heating pipe heating medium introducing main pipe and at the positions corresponding to the upper heating pipe heating medium introducing interfaces, the upper heating pipe heating medium introducing main pipe interfaces are connected with the upper heating pipe heating medium introducing interfaces through first upper transition connecting pipes, the upper heating pipe heating medium leading-out main pipe is fixed between the pair of stand right columns and at the side opposite to the left adjusting beam corresponding to the right adjusting beam, upper heating pipe heating medium leading-out main pipe interfaces with the number equal to that of the upper heating pipes are formed on the upper heating pipe heating medium leading-out main pipe and at the positions corresponding to the upper heating pipe heating medium leading-out interfaces, the heating medium leading-out main pipe interface of the upper heating pipe is connected with the heating medium leading-out interface of the upper heating pipe through a second upper transition connecting pipe; the lower heating mechanism comprises a group of lower heating pipes, a lower heating pipe heating medium introducing main pipe and a lower heating pipe heating medium leading-out main pipe, the number of the group of lower heating pipes is equal to that of the group of upper heating pipes, the lower heating pipes are distributed at intervals in a parallel state, the left ends of the group of lower heating pipes are fixed with the frame at the positions corresponding to the lower parts of the upper heating pipes, the right ends of the group of lower heating pipes are also fixed with the frame at the positions corresponding to the lower parts of the upper heating pipes, lower heating pipe heating medium introducing interfaces for introducing heating media into the cavities of the lower heating pipes are respectively fixed below the left ends of the group of lower heating pipes, lower heating pipe heating medium leading-out interfaces for leading the heating media out of the cavities of the lower heating pipes are respectively fixed on the end surfaces of the right ends of the group of lower heating pipes, and the lower heating pipe heating medium introducing main pipe is fixed on the frame at the positions corresponding to the lower parts of, lower-tube heating medium introduction manifold ports equal in number to the number of lower heating tubes are formed at the lower-tube heating medium introduction manifold and at positions corresponding to the lower-tube heating medium introduction ports, the lower heating pipe heating medium leading-in main pipe interface is connected with the lower heating pipe heating medium leading-in interface through a first transition pipe, the lower heating pipe heating medium leading-out main pipe is fixed between the pair of stand right columns at the position corresponding to the lower part of the right end of the lower heating pipe and corresponds to one side of the right adjusting beam back to the left adjusting beam, the heating medium leading-out main pipe joints of the lower heating pipes with the number equal to that of the lower heating pipes are formed on the heating medium leading-out main pipe of the lower heating pipes and at the positions corresponding to the heating medium leading-out joints of the lower heating pipes, the heating medium leading-out main pipe interface of the lower heating pipe is connected with the heating medium leading-out interface of the lower heating pipe through a second transition pipe; the space between the group of upper and lower heating pipes is formed into the plate material moving channel; the plate material pressing mechanism is fixed on the upper heating pipe at a position corresponding to the upper part of the plate material cavity; the plate pressing mechanism comprises a supporting beam, a pair of pressing action cylinder fixing frames, a pair of grid plate leaning beams, a group of grid plate strips, a plate pressing strip and a pair of plate pressing strip action cylinders, wherein a first cushion block is fixed at one end of the supporting beam, a second cushion block is fixed at the other end of the supporting beam, the first cushion block is fixed with one upward side of a first upper heating pipe in the group of upper heating pipes, the second cushion block is fixed with one upward side of a last upper heating pipe in the group of upper heating pipes, the bottom of one pressing action cylinder fixing frame in the pair of pressing action cylinder fixing frames is fixed with one end of the supporting beam, the bottom of the other pressing action cylinder fixing frame in the pair of pressing action cylinder fixing frames is fixed with the other end of the supporting beam, a plate pressing strip action cylinder fixing seat is fixed at the top of each pressing action cylinder fixing frame, and one side of the pair of pressing action cylinder fixing frames, which faces the plate cavity, are fixed by the pair of grid, and the pair of grid plate strip rest beams are transversely parallel to each other, a group of grid plate strips are longitudinally fixed on one side of a pair of grid plate strip rest beams back to the pair of pressing action cylinder fixing frames at intervals, one plate pressing strip action cylinder in the pair of plate pressing strip action cylinders is fixed on the plate pressing strip action cylinder fixing seat of one pressing action cylinder fixing frame in the pair of pressing action cylinder fixing frames, the other plate pressing strip action cylinder in the pair of plate pressing strip action cylinders is fixed on the plate pressing strip action cylinder fixing seat of the other pressing action cylinder fixing frame in the pair of pressing action cylinder fixing frames, the plate pressing strip action cylinder column of the plate pressing strip action cylinders faces downwards, one end of the plate pressing strip is connected with the tail end of the plate pressing strip action cylinder column of one plate pressing strip action cylinder in the pair of plate pressing strip action cylinders, the other end of the plate pressing strip is connected with the tail end of the plate pressing strip acting cylinder column of the other plate pressing strip acting cylinder in the pair of plate pressing strip acting cylinders, and the plate pressing strip corresponds to the upper part of the plate cavity; the cross section of the group of grid plates is V-shaped.

In a specific embodiment of the present invention, a material pushing plate platform supporting strip is fixed on the frame material pushing plate platform and in a region corresponding to the length direction of the material pushing plate at intervals, a guiding slide sheet is arranged on the surface of the material pushing plate platform supporting strip on the side facing the material pushing plate, a material pushing plate guiding slide flange is formed on the downward side of the material pushing plate and in a position corresponding to the guiding slide sheet, and the material pushing plate guiding slide flange is in sliding fit with the guiding slide sheet.

In another specific embodiment of the present invention, each of the pair of ejector plate synchronizers includes a rack holder, a rack, a synchronizing gear and a synchronizing gear shaft seat, the rack holder is fixed on the rack ejector plate platform, the rack is fixed on a side of the rack holder facing the ejector plate, the synchronizing gear shaft seat is fixed on a side of the ejector plate facing the rack holder, the synchronizing gear is fixed on the synchronizing gear shaft and meshed with the rack, and the synchronizing gear shaft is rotatably supported on the synchronizing gear shaft seat.

In another specific embodiment of the present invention, the pair of material pushing plate acting cylinders and the pair of plate material pressing strip acting cylinders are oil cylinders or air cylinders.

In another specific embodiment of the present invention, the opposite sides of the pair of left stand columns of the rack are open, and both ends of the left adjusting beam extend into the left stand column cavities of the pair of left stand columns of the rack at the positions corresponding to the open ends; the opposite sides of the pair of frame right upright posts are open, two ends of the right adjusting beam extend into the frame right upright post cavities of the pair of frame right upright posts at positions corresponding to the open ends, the upper parts of the opposite sides of the pair of frame left upright posts respectively form a frame left upright post opening for enabling the frame left upright post cavities to be communicated with the outside, and the upper parts of the opposite sides of the pair of frame right upright posts respectively form a frame right upright post opening for enabling the frame right upright post cavities to be communicated with the outside; the left side adjustment crossbeam constitutes has a left side adjustment crossbeam chamber, and this left side adjustment crossbeam chamber link up to the other end from the one end of the length direction of left side adjustment crossbeam, right side adjustment crossbeam constitutes has a right side adjustment crossbeam chamber, and this right side adjustment crossbeam chamber link up to the other end from the one end of the length direction of right side adjustment crossbeam, is provided with a left side adjustment crossbeam gear shaft at left side adjustment crossbeam intracavity with rotating, and the both ends of this left side adjustment crossbeam gear shaft all are visited the accent in left side adjustment crossbeam chamber and are extended to in the frame left side stand intracavity, are provided with a right side adjustment crossbeam gear shaft in right side adjustment crossbeam intracavity with rotating, and the both ends of this right side adjustment crossbeam gear shaft all are visited the accent in right side adjustment crossbeam chamber and are extended to in the frame right side stand intracavity.

In yet another specific embodiment of the present invention, a left adjusting beam up-down adjusting mechanism is respectively disposed in the rack left column cavities of the pair of rack left columns, and the left adjusting beam up-down adjusting mechanism is connected to the left adjusting beam gear shaft disposed in the left adjusting beam cavity of the left adjusting beam; and a right adjusting beam vertical adjusting mechanism is respectively arranged in the rack right upright cavity of the pair of rack right uprights and is connected with the right adjusting beam gear shaft arranged in the right adjusting beam cavity of the right adjusting beam.

In a more specific embodiment of the present invention, the structure of the upper and lower adjustment mechanisms of the right adjustment beam is the same as the structure of the upper and lower adjustment mechanisms of the left adjustment beam.

According to the technical scheme provided by the invention, as the pair of pushing plate synchronizing devices are added to the pushing mechanism, the pushing plates can show a good overall movement effect, and the plates in the plate cavities are pushed into the plate introducing openings of the plate moving channels one by one under a balanced acting force; because the pushing plate platform supporting strips are fixed on the bracket pushing plate platform at intervals, the pushing plate platform supporting strips are provided with the guide sliding pieces, and the pushing plate guide sliding flanges which are in sliding fit with the guide sliding pieces are formed on one downward side of the pushing plate and at the positions corresponding to the guide sliding pieces, the motion resistance of the pushing plate can be obviously reduced, the pushing plate can be protected, and the energy consumption of a pair of pushing plate acting cylinders can be saved; the upper and lower heating mechanisms can simultaneously heat the upper and lower surfaces of the plates, so that the integral splicing and combining effect between the adjacent plates can be obviously improved; the plate pressing mechanism has reasonable structure, so the plate pressing mechanism can adapt to pressing of long plates, and because a group of grid bars with V-shaped cross sections are adopted, the contact area of the plates and the grid bars can be reduced, the downward resistance of the plates can be obviously reduced, and the energy consumption of a pair of plate pressing bar acting cylinders can be saved.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a detailed structure diagram of a pair of left stand columns of the rack, a left adjusting beam, a plate material pressing mechanism, a material turning mechanism, a material pushing mechanism, a material turning plate traction mechanism and an up-down adjusting mechanism of the left adjusting beam shown in fig. 1.

Fig. 3 is a detailed structure diagram of a pair of right stand columns, a right adjusting beam, an up-down adjusting mechanism of the right adjusting beam and a floating connecting device of a second upper heating pipe shown in fig. 1.

Fig. 4 is a detailed block diagram of the saw mechanism shown in fig. 1.

Fig. 5 is a detailed structural view of the floating connection device of the first upper heating pipe shown in fig. 1.

Fig. 6 is a cross-sectional view of the left adjustment beam up-down adjustment mechanism shown in fig. 1.

Detailed Description

In order to make the technical spirit and advantages of the present invention more clearly understandable to examiners of the patent office and particularly to the public, the applicant shall describe in detail below by way of examples, but the description of the examples is not a limitation of the present invention, and any equivalent changes made according to the present inventive concept, which are merely formal and insubstantial, shall be considered to be within the scope of the present invention.

In the following description, all the concepts related to up, down, left, right, front and rear are, unless otherwise specified, directed to the position state shown in fig. 1 and thus should not be construed as particularly limiting the present invention.

Referring to fig. 1, there is shown a frame 1, the left end of the frame 1 is fixed in a state of being vacated from a floor between a pair of frame left upright posts 11 which are arranged to face each other and supported on the floor in a use state, while the right end of the frame 1 is likewise fixed in an empty state on the floor between a pair of right frame uprights 12 arranged facing each other and also supported in use on the floor, a frame material pushing plate platform 13 is arranged at the left end of the frame 1, and as shown in fig. 1, a left adjusting beam 14 with a rectangular or square cross section is arranged between a pair of frame left upright posts 11 and at a position corresponding to the upper part of the frame 1 in a manner of moving up and down (i.e., being adjustable up and down), and a right adjusting beam 15 having a cross-sectional shape like that described for the left adjusting beam 14 is provided between the pair of frame right uprights 12 and also up and down (i.e., adjustable up and down) at a position corresponding to the upper side of the frame 1.

An upper heating mechanism 2 and a lower heating mechanism 3 are provided, the upper heating mechanism 2 is connected with a left adjusting beam 14 and a right adjusting beam 15 at the positions corresponding to the lower parts of the left adjusting beam 14 and the right adjusting beam 15 at the same time, the lower heating mechanism 3 is fixed on the frame 1 at the position corresponding to the lower part of the upper heating mechanism 2, the space between the upper heating mechanism 2 and the lower heating mechanism 3 is a plate moving channel 10, the left end port of the plate moving channel 10 is a plate introducing port 101, the plate introducing port 101 is communicated with a plate cavity 16 formed at the upper part of the left end of the frame 1, and the right end port of the plate moving channel 10 is spliced to form a plate leading-out port 102. For the convenience of understanding of the public, the applicant shows in fig. 1 a strip-shaped plate 30 pre-coated with an adhesive, the plate 30 enters the plate moving channel 10 from the plate cavity 16 through the plate introduction opening 101 under the pushing of the pushing mechanism 6 to be mentioned below, and in the process that the plate moving channel 10 moves towards the direction of the spliced template extraction opening 102, the adjacent plates 30 are mutually bonded together by the heating of the upper and lower heating mechanisms 2 and 3 and the pressing of the upper heating mechanism 2, when the plate is extracted from the spliced template extraction opening 102, a whole frame is formed to be used for manufacturing furniture, office supplies (such as a book cabinet and the like) and interior decorative plates, where the whole frame is a whole block, for example, a plate with a width of 122 and a length of 244, and the thickness can be determined according to the thickness change of the plate 30.

A sheet pressing mechanism 4 is provided for pressing the sheet 30 in the sheet chamber 16 in a stacked state, and the sheet pressing mechanism 4 is fixed to a side of the upper heating mechanism 2 facing away from the lower heating mechanism 3, i.e., a side of the upper heating mechanism 2 facing upward, at a position corresponding to an upper side of the sheet chamber 16. A turning mechanism 5 for feeding, i.e. turning, the sheet 30 into the sheet chamber 16 is provided, the turning mechanism 5 being arranged on the frame 1 at a position corresponding to the sheet chamber 16. A material pushing mechanism 6 for pushing the sheet materials 30 in the sheet material cavity 16 one by one (i.e. one by one) into the sheet material introducing port 101 is provided, and the material pushing mechanism 6 is arranged on the frame material pushing plate platform 13 corresponding to the left side of the length direction of the sheet material cavity 16.

Please refer to fig. 2 and still refer to fig. 1, which is a technical point of the technical solution provided by the present invention: the material pushing mechanism 6 includes a pair of material pushing plate acting cylinders 61, a material pushing plate 62 and a pair of material pushing plate synchronizing devices 63, the pair of material pushing plate acting cylinders 61 are horizontally fixed on the material pushing plate acting cylinder base 612, the material pushing plate acting cylinder posts 611 of the pair of material pushing plate acting cylinders 61 face the material pushing plate 62, the material pushing plate 62 corresponds to the left side (the left side is the position shown in fig. 1) of the length direction of the material cavity 16 and is in sliding fit with the frame material pushing plate platform 13, a material pushing plate connecting base 621 is fixed on the material pushing plate 62 and at the position corresponding to the material pushing plate acting cylinder posts 611 by using a material pushing plate connecting base fixing screw 6211, the material pushing plate connecting base 621 is connected with the material pushing plate acting cylinder posts 611, the pair of material pushing plate synchronizing devices 63 are arranged between the material pushing plate 62 and the frame material pushing plate platform 13, and engages the downwardly facing side of the ejector plate 62. The aforementioned pusher plate operating cylinder block 612 is fixed to the left side surface (for example, the position shown in fig. 1) of the frame pusher plate platform 13 in a horizontal cantilever state, and the aforementioned material reversing mechanism 5 corresponds to the upper side of the pusher plate 62.

A pusher platform retainer 131 is fixed to the frame pusher platform 13 at a distance from the area corresponding to the length direction of the pusher 62, a smooth-surfaced guide piece 1311, which may be a metal or non-metal guide piece, is provided on the surface of the pusher platform retainer 131 facing the pusher 62, i.e., on the upward-facing surface, a pusher guide flange 622 is formed on the downward-facing side of the pusher 62 at a position corresponding to the guide piece 1311, and the pusher guide flange 622 is slidably fitted to the guide piece 1311. As shown in fig. 2, since the aforementioned stripper plate platform bracket strip 131 is fixed to the frame stripper plate 13 in parallel with the short side of the frame stripper plate 13, the stripper plate platform bracket strip 131 is substantially parallel with the short side of the stripper plate 62.

The applicant needs to state that: if the structure of the guiding sheet 1311 on the supporting strip 131 of the pushing plate platform is changed into the structure of the guide rail, and the structure of the guiding flange 622 of the pushing plate is changed into the structure of the guide rail sliding block matched with the guide rail, the equivalent substitution should be regarded and still fall into the technical scope of the present disclosure. If the sliding guide plate 1311 is modified to be a raceway and the material pushing plate sliding guide flange 622 is modified to be a roller structure, the same should be considered as a form rather than a substantial equivalent substitution and fall within the technical scope of the present disclosure.

The preferred, but not absolutely limited, configuration of the pair of pusher plate synchronization devices 63 described above is as follows: each of which includes a rack fixing base 631, a rack 632, a synchronizing gear 633 and a synchronizing gear shaft base 634, the rack fixing base 631 is fixed to the rack stripper plate platform 13, the rack 632 is fixed to a side of the rack fixing base 631 facing the stripper plate 62, i.e., to a side of the rack fixing base 631 facing upward, the synchronizing gear shaft base 634 is fixed to a side of the stripper plate 62 facing the rack fixing base 631 by screws, the synchronizing gear 633 is fixed to a synchronizing gear shaft 6331 and is engaged with the rack 632, and the synchronizing gear shaft 6331 is rotatably supported on the synchronizing gear shaft base 634.

In the present embodiment, the pair of pusher plate actuating cylinders 61 described above employs oil cylinders, but if a cylinder is used instead, it should be regarded as an equivalent alternative.

When the pair of the stripper plate acting cylinders 61 are operated, for example, when the stripper plate acting cylinder posts 611 of the stripper plate acting cylinders 61 extend to the outside of the cylinders, the stripper plate 62 is driven by the stripper plate acting cylinder posts 611, so that the stripper plate 62 is displaced toward the plate cavity 16, and one plate 30 at the bottom of the plate storage cavity 40 shown in fig. 1 is pushed toward the plate introduction port 101, otherwise, in the same case, the stripper plate 62 is restored, and the plate 30 is pushed toward the plate introduction port 101 one by the stripper plate 62 due to the alternate action of the stripper plate acting cylinder posts 611. The store chamber 40, referred to here and illustrated in fig. 1, is the space (colloquially called "cocking", i.e. narrow passage) formed between the plate pressing means 4 and the turning means 5, described in more detail below.

Focusing on fig. 1, the aforementioned upper heating mechanism 2 includes a group of upper heating pipes 21, an upper heating pipe heating medium introducing header 22 and an upper heating pipe heating medium extracting header 23, the group of upper heating pipes 21 are spaced apart in parallel to each other, and left ends of the group of upper heating pipes 21 are connected to the left adjusting beam 14 at a position corresponding to a lower portion of the left adjusting beam 14, right ends of the group of upper heating pipes 21 are connected to the right adjusting beam 15 at a position corresponding to a lower portion of the right adjusting beam 15, and an upper heating pipe heating medium introducing port 212 for introducing a heating medium into an upper heating pipe cavity 211 (indicated in fig. 3) is respectively fixed to upper ends (i.e., upward facing sides) of the group of upper heating pipes 21, and an upper heating medium extracting port 213 for extracting a heating medium from the upper heating pipe cavity 211 is respectively fixed to right end surfaces of the group of upper heating pipes 21, the upper heating pipe heating medium introducing main pipe 22 is fixed between the pair of rack left uprights 11 by using a first upper fixing seat 222, and corresponds to one side of the left adjusting beam 14 facing the right adjusting beam 15, that is, one side of the pair of rack left uprights 11 facing the pair of rack right uprights 12, upper heating pipe heating medium introducing main pipe interfaces 221, the number of which is equal to that of the upper heating pipes 21, are formed on the upper heating pipe heating medium introducing main pipe 22 and at positions corresponding to the upper heating pipe heating medium introducing interfaces 212, the upper heating pipe heating medium introducing main pipe interfaces 221 are connected with the upper heating pipe heating medium introducing interfaces 212 through first upper transition connecting pipes 2211 (using hoses), the upper heating pipe heating medium introducing main pipe 23 is fixed between the pair of rack right uprights 12 by using first upper fixing seats 232, and one side of the right adjusting beam 15 facing away from the left adjusting beam 14, that is located at one side of the pair of rack right uprights 12 facing away from the pair of racks right adjusting beams 12 On one side of the left column 11, upper-tube heating medium outlet manifold ports 231, the number of which is equal to the number of the upper tubes 21, are formed at positions corresponding to the upper-tube heating medium outlet ports 213 on the upper-tube heating medium outlet manifold 23, and the upper-tube heating medium outlet manifold ports 231 are connected to the upper-tube heating medium outlet ports 213 via second upper transition connection pipes 2311 (using hoses).

Still referring to fig. 1, the lower heating mechanism 3 includes a group of lower heating pipes 31, a group of lower heating pipe heating medium introducing header pipes 32 and a group of lower heating pipe heating medium extracting header pipes 33, the number of the group of lower heating pipes 31 is equal to the number of the group of upper heating pipes 21, and the groups are spaced apart in parallel, the left ends of the group of lower heating pipes 31 are fixed to the frame 1 at positions corresponding to the lower sides (lower left ends) of the upper heating pipes 21, the right ends of the group of lower heating pipes 31 are also fixed to the frame 1 at positions corresponding to the lower sides (lower right ends) of the upper heating pipes 21, and a group of lower heating pipe heating medium introducing port heating pipes 312 for introducing the heating medium into the lower heating pipe cavity 3 (labeled in fig. 3) is fixed to the lower end surfaces of the group of lower heating pipes 31, and a group of lower heating pipe heating medium introducing port heating pipe heating medium introducing header pipes 312 for introducing the heating medium out of the lower heating pipe cavity 311 is fixed to the right end surfaces of the group A lower heating pipe heating medium introducing header pipe 32 is fixed to the rack 1 at a position corresponding to the lower portion of the left end of the lower heating pipe 31 by using a first lower fixing seat 322, lower heating pipe heating medium introducing header pipe interfaces 321 are formed on the lower heating pipe heating medium introducing header pipe 32 and at a position corresponding to the lower heating pipe heating medium introducing interface 312, the number of the lower heating pipe heating medium introducing header pipe interfaces 321 is equal to the number of the lower heating pipes 31, the lower heating pipe heating medium introducing header pipe interfaces 321 are connected to the lower heating pipe heating medium introducing interface 312 through a first transition pipe 3211 (using a hose), the lower heating pipe heating medium introducing header pipe 33 is fixed between the pair of rack right uprights 12 at a position corresponding to the lower portion of the right end of the lower heating pipe 31 by using a second lower fixing seat 332, and corresponds to the side of the right adjusting beam 15 facing away from the left adjusting beam 14, that is, that corresponds to the side of the pair of rack right uprights, a number of lower-tube heating medium outlet manifold ports 331 equal to the number of the lower heating tubes 31 are formed in the lower-tube heating medium outlet manifold 33 at positions corresponding to the lower-tube heating medium outlet ports 313, and the lower-tube heating medium outlet manifold ports 331 are connected to the lower-tube heating medium outlet ports 313 via second transition tubes 3311 (using hoses).

The space between the upper and lower heating pipes 21 and 31 constitutes the plate moving passage 10. The plate pressing mechanism 4 is fixed to the upper heating pipe 21 at a position corresponding to the upper side of the plate chamber 16.

In the present embodiment, the above-mentioned heating medium is steam, however, a thermal oil or other equivalent substance may be used as the heating medium.

As can be seen from the above description of the upper and lower heating mechanisms 2 and 3, the sheet 30 passing through the sheet moving passage 10 can be heated by the cooperation of the upper and lower heating pipes 21 and 31, so that the solvent in the adhesive coated on the sheet 30 is volatilized, and the sheets 30 are reliably bonded together. The heating principle of the heating mechanism 2 is as follows: the high-temperature heating medium (steam in this embodiment) is introduced from the upper-tube heating medium introducing header pipe interface 221 of the upper-tube heating medium introducing header pipe 22 to the upper-tube heating medium introducing interface 212 through the first upper transition connecting pipe 2211, introduced from the upper-tube heating medium introducing interface 212 into the upper-tube heating chamber 211, and introduced from the upper-tube heating medium introducing interface 213 to the upper-tube heating medium introducing header pipe 23 through the second upper transition connecting pipe 2311 and the upper-tube heating medium introducing header pipe interface 231, so as to form a circulation reflux process of the heating medium. In the process, a set of upper heating tubes 21 heat the slab 30 passing thereunder, i.e. passing through the slab travel channel 10. Since the heating principle of the lower heating mechanism 3 is the same as that of the upper heating mechanism 2, the applicant does not give any further details.

Referring to fig. 2 in conjunction with fig. 1, the plate pressing mechanism 4 includes a supporting beam 41, a pair of pressing cylinder fixing frames 42, a pair of grid rest beams 43, a set of grid bars 44, a plate pressing strip 45 and a pair of plate pressing strip acting cylinders 46, wherein a first spacer 411 is fixed at one end (the rear end in the position state shown in fig. 1) of the supporting beam 41, a second spacer 412 is fixed at the other end (the front end in the position state shown in fig. 1), the first spacer 411 is fixed to the first side of the set of upper heating pipes 21, i.e. the side facing upward, of the leftmost upper heating pipe, the second spacer 412 is fixed to the last side of the set of upper heating pipes 21, i.e. the side facing upward, of the rightmost upper heating pipe, the bottom of one of the pair of pressing cylinder fixing frames 42 is welded to one end of the supporting beam 41, the bottom of the other pressure application cylinder fixing frame in the pair of pressure application cylinder fixing frames 42 is welded and fixed with the other end of the supporting beam 41, a plate pressure application bar acting cylinder fixing seat 421 is fixed (by welding) on the top of each pressure application cylinder fixing frame 42 in a horizontal state, a pair of grid plate strip leaning beams 43 and one side of the pair of pressure application cylinder fixing frames 42 facing to the plate cavity 16 are welded and fixed, the grid plate strip leaning beams 43 are transversely parallel to each other (transversely parallel in a vertically corresponding state), a group of grid plate strips 44 are longitudinally fixed on one side of the pair of grid plate strip leaning beams 43 back to the pair of pressure application cylinder fixing frames 42 in a spaced state, one plate pressure application bar acting cylinder in the pair of plate pressure application bar acting cylinders 46 is fixed on the plate pressure application bar acting cylinder fixing seat 421 of one pressure application cylinder fixing frame in the pair of pressure application cylinder fixing frames 42, and the other plate pressing bar acting cylinder of the pair of plate pressing bar acting cylinders 46 is fixed on the plate pressing bar acting cylinder fixing seat 421 of the other pressing bar acting cylinder fixing frame of the pair of pressing acting cylinder fixing frames 42, the cylinder column 461 of the pair of the cylinder 46 for applying the pressing strip faces downwards, one end of the plate 45 for applying the pressing strip is connected with the tail end of the cylinder column 461 of one cylinder 46 for applying the pressing strip through the connecting strip connecting seat 451 by adopting a connecting seat pin shaft 4511, the other end of the plate pressing strip 45 is connected with the tail end of the plate pressing strip acting cylinder column 461 of the other plate pressing strip acting cylinder in the pair of plate pressing strip acting cylinders 46 through a strip connecting seat 451 by a connecting seat pin shaft 4511, and the plate pressing strip 45 corresponds to the upper part of the plate cavity 16.

In the present embodiment, the pair of plate pressing cylinders 46 are air cylinders, but the use of oil cylinders is not excluded. The cross-sectional shape of the aforementioned set of grid bars 44 is V-shaped.

The applicant briefly describes the working principle and the function of the plate pressing mechanism 4: when the pair of plate pressing strip acting cylinders 46 are operated, for example, when the plate pressing strip acting cylinder column 461 gradually extends from the outside of the cylinder body, the plate pressing strip 45 is driven by the plate pressing strip acting cylinder column 461 to descend, and the upper portion (the uppermost plate) of the plate 30 illustrated in fig. 1 is pressed by the plate pressing strip 45. At this time, under the operation of the pushing mechanism 6, after the plate 30 at the lowest portion enters the plate moving channel 10 from the plate introducing port 101, the material level of the plate 30 in the plate storing cavity 40 is reduced by the thickness of one plate 30, so that the plate pressing strip acting cylinder 46 is in a pressing state on the plate 30 all the time until the plate 30 in the plate storing cavity 40 is pushed out by the pushing plate 62 of the pushing mechanism 6, and the plate pressing strip acting cylinder 46 is reversely operated to make the plate pressing strip acting cylinder 461 return upwards. Therefore, the plate pressing mechanism 4 generates pressing force on the plate 30 to ensure that the pushing plate 62 of the pushing mechanism 6 pushes the plate 30.

The plate material 30 in the plate storage cavity 40 is turned in by the turning mechanism 5, namely, the plate material is fed by the turning mechanism 5.

As shown in fig. 1 and 2, the material turning mechanism 5 includes a turning cylinder 51, a turning arm 52, a turning plate shaft 53 and a material turning plate 54, the turning cylinder 51 is connected to the turning cylinder base 512 in a longitudinal state and through a connecting pin 513, the turning cylinder base 512 is fixed to a front side of a left end of the frame 1 (taking the position state shown in fig. 1 as an example), and a turning cylinder column 511 of the turning cylinder 51 faces upward, a material turning plate shaft fixing base 541 is fixed to a lower portion in a length direction of a side of the material turning plate 54 facing the material chamber 16, a middle portion in a length direction of the material turning plate shaft 53 is fixed to the material turning plate shaft fixing base 541 (fixed to the material turning plate shaft fixing base 541 in an embedded manner), both ends of the material turning plate shaft 53 protrude from the material turning plate 54 and are rotatably supported on the frame material pushing plate platform 13, one end of the turning arm 52 is fixed to the material turning plate shaft 53, the other end is hinged to the tilt cylinder column 511 by a tilt arm pin 521. As shown in fig. 1 and 2, the turning arm 52 has an arc-like shape as a whole, and more vividly, a kidney-shaped shape (may be called a banana-shaped shape).

Preferably, at least one material turning plate leg rest 132 is disposed on the frame material pushing plate platform 13, and the material turning plate 54 rests on the material turning plate leg rest 132 when the vertical state shown in fig. 1 is changed to the horizontal state shown in fig. 2.

A material turning plate traction mechanism 7 is provided on the frame material pushing plate platform 13 at positions corresponding to both ends of the material turning plate shaft 53, and both ends of the material turning plate shaft 53 are rotatably supported on the material turning plate traction mechanism 7.

In the present embodiment, the above-described roll-over cylinder 51 is an air cylinder, but an oil cylinder may be used instead of the air cylinder.

The aforementioned material overturning plate traction mechanism 7 comprises a traction plate 71 and a traction plate acting cylinder 72, the traction plate 71 is movably arranged on the aforementioned frame material pushing plate platform 13 and corresponds to the end part of the aforementioned material overturning plate shaft 53, the pulling plate 71 is provided with a material turning plate shaft supporting seat 711 and a pulling plate acting cylinder column connecting seat 712, the end part of the material turning plate shaft 53 is rotatably supported on the material turning plate shaft supporting seat 711, the pulling plate acting cylinder 72 is arranged on the frame material pushing plate platform 13 in a horizontal state, and a traction plate acting cylinder adjusting screw 721 is connected to the tail of the traction plate acting cylinder 72, the traction plate actuating cylinder adjustment screw 721 is attached to an adjustment screw mount 7211 and is defined by a limiting nut 7212, the adjustment screw mount 7211 is secured to the frame stripper plate platform 13, and the end of the traction plate actuating cylinder post 722 of the traction plate actuating cylinder 72 is attached to the traction plate actuating cylinder post attachment mount 712. A traction plate sliding groove 713 is further formed in the traction plate 71, and a traction plate stopper screw 7131 fixed to the frame stripper plate platform 13 is provided at a position corresponding to the traction plate sliding groove 713.

When the material turning plate 54 is to be changed from the state shown in fig. 2 to the state shown in fig. 1, that is, when the plate material 30 on the material turning plate 54 is to be turned over to the extent shown in fig. 1, the turning cylinder 51 is operated, the turning cylinder column 511 extends outward, that is, upward, the turning arm 52 is driven by the turning cylinder column 511, the turning plate shaft 53 is driven by the turning arm 52, and the material turning plate 54 is driven by the turning plate shaft 53 to move in the direction of the plate material pressing mechanism 4 described above until the state shown in fig. 1 is reached, in which the plate material 30 previously on the material turning plate 54 is regulated in the plate storage chamber 40 shown in fig. 1. After the material turning plate 54 is turned, that is, when the material turning plate 54 is in the state of tending to be perpendicular to the frame material pushing plate platform 131 as shown in fig. 1, the aforementioned traction plate acting cylinder 72 operates, the traction plate acting cylinder 722 is displaced outward of the cylinder body, and at the same time, the traction plate acting cylinder connecting base 712 is driven, the traction plate 71 is driven by the traction plate acting cylinder connecting base 712, the material turning plate shaft 53 is driven by the material turning plate shaft supporting base 711 on the traction plate 71, and the material turning plate 54 is forced to be kept in the aforementioned state of tending to be perpendicular to the frame material pushing plate platform 131. Since the movement of the flipper plate 54 from the fig. 1 condition to the fig. 2 condition is contrary to the foregoing and can be understood by those skilled in the art, applicant will not reiterate.

In the present embodiment, the aforementioned traction plate acting cylinder 72 is preferably a cylinder, but if a cylinder is selected, it should be regarded as an equivalent alternative.

Referring to fig. 2 and 3 and still referring to fig. 1, the opposite sides of the pair of left stand columns 11 of the rack are open, and both ends of the left adjusting beam 14 extend into the left stand column cavities 111 (shown in fig. 1 and 2) of the pair of left stand columns 11 of the rack at the positions corresponding to the open sides; the opposite sides of the pair of right stand columns 12 are open, the two ends of the right adjusting beam 15 are inserted into the right stand column cavities 121 of the pair of right stand columns 12 at the positions corresponding to the open ends, the upper parts of the opposite sides of the pair of left stand columns 11 are respectively provided with a left stand column opening 112 for communicating the left stand column cavity 111 with the outside, and the upper parts of the opposite sides of the pair of right stand columns 12 are respectively provided with a right stand column opening 122 (marked in fig. 1 and 3) for communicating the right stand column cavity 121 with the outside; the left adjusting beam 14 is formed with a left adjusting beam cavity 141, the left adjusting beam cavity 141 penetrates from one end to the other end of the length direction of the left adjusting beam 14, the right adjusting beam 15 is formed with a right adjusting beam cavity 151, the right adjusting beam cavity 151 penetrates from one end to the other end of the length direction of the right adjusting beam 15, a left adjusting beam gear shaft 142 is rotatably disposed in the left adjusting beam cavity 141, both ends of the left adjusting beam gear shaft 142 protrude out of the cavity opening of the left adjusting beam cavity 141 and extend into the rack left column cavity 111, a right adjusting beam gear shaft 152 is rotatably disposed in the right adjusting beam cavity 151, both ends of the right adjusting beam 152 protrude out of the cavity opening of the right adjusting beam cavity 151 and extend into the rack right column cavity 121.

A left adjusting beam up-down adjusting mechanism 8 is respectively arranged in the rack left upright post cavities 111 of the pair of rack left upright posts 11, and the left adjusting beam up-down adjusting mechanism 8 is connected with the left adjusting beam gear shaft 142 arranged in the left adjusting beam cavity 141 of the left adjusting beam 14, as shown in fig. 1 and 2; a right adjusting beam up-down adjusting mechanism 20 is disposed in each of the rack right column cavities 121 of the pair of rack right columns 12, and the right adjusting beam up-down adjusting mechanism 20 is connected to the right adjusting beam gear shaft 152 disposed in the right adjusting beam cavity 151 of the right adjusting beam 15, as shown in fig. 1 and 3. Preferably, the electrical control box of the automatic plate splicing machine can be arranged at the top of one rack left upright column on the front side of the pair of rack left upright columns 11.

Since the structure of the aforementioned right-adjustment cross member up-down adjustment mechanism 20 is completely the same as that of the aforementioned left-adjustment cross member up-down adjustment mechanism 8, the applicant describes in detail only the left-adjustment cross member up-down adjustment mechanism 8 below.

Referring to fig. 2 and 6 in conjunction with fig. 1, the preferred, but not absolutely limited, structure of the left adjustment beam up-down adjustment mechanism 8 is as follows: including lift effect jar 81, scale screw rod adjusting plate 82, scale screw rod 83, scale screw rod fixed plate 84, synchronous adjustment rack 85 and synchronous adjustment gear 86, lift effect jar 81 is fixed on lift effect jar seat 812 with longitudinal condition, and this lift effect jar seat 812 is fixed with the chamber wall in aforementioned frame left side stand chamber 111 to lift effect jar post 811 of lift effect jar 81 is upwards, and this lift effect jar post 811 is connected with the bottom of aforementioned left adjustment crossbeam 14, specifically is: a lifting cylinder post coupling base 144 is fixed to the bottom of the left adjustment cross member 14 at a position corresponding to the lifting cylinder post 811, and the lifting cylinder post 811 is coupled to the lifting cylinder post coupling base 144 by a pin. The scale screw adjusting plate 82 is fixed in the left column cavity 111 of the frame, the scale screw 83 is provided on the scale screw adjusting plate 82, a scale screw locking nut 831 is respectively provided on the scale screw 83 and at a position corresponding to the upper side and the lower side of the scale screw adjusting plate 82, the upper end of the scale screw 83 is fixed to the scale screw fixing plate 84, the scale screw fixing plate 84 is fixed to the bottom of the left adjusting beam 14, the lower end of the scale screw 83 extends downward of the scale screw adjusting plate 82, the synchronization adjusting rack 85 is fixed to the cavity wall of the left column cavity 111 of the frame in a longitudinal state, and the synchronization adjusting gear 86 is fixed to the end of the left adjusting beam gear shaft 142 that protrudes into the left column cavity 111 in a flat key fixing manner and meshes with the synchronization adjusting rack 85.

The scale screw 83 is provided with scale marks 832 (shown in fig. 6); the lift cylinder 81 is an oil cylinder, but an air cylinder may be used.

When the thickness of the plate 30 is changed, the height of the plate moving channel 10 needs to be changed adaptively, and changing the height of the plate moving channel 10, that is, changing the distance between a group of upper and lower heating pipes 21 and 31, is realized by adjusting the left and right adjusting cross beams 14 and 15 simultaneously. Since the adjustment of the right adjustment beam 15 by the right adjustment beam up and down adjustment mechanism 20 is exactly the same as the adjustment of the left adjustment beam 14 by the left adjustment beam up and down adjustment mechanism 8, the applicant will only describe the adjustment of the left adjustment beam 14 by the left adjustment beam up and down adjustment mechanism 8 in the following.

When the distance between the upper and lower heating pipes 21, 31 of a group is to be increased, that is, the height of the slab traveling passage 10 is increased, the scale screw locking nut 831 for locking (i.e., limiting) the scale screw 83 is firstly loosened, the lifting cylinder 81 works, the lifting cylinder 811 extends outward of the cylinder body, that is, extends upward, and since the lifting cylinder 811 is connected to the lifting cylinder connecting seat 144 fixed to the bottom of the left adjusting beam 14, the lifting cylinder 811 displaces the left adjusting beam 14 upward through the lifting cylinder connecting seat 144, in this process, the synchronous adjusting gear 86 fixed to the left adjusting beam gear shaft 142 drives the left adjusting beam 142 to rotate in a state of being meshed with the synchronous adjusting rack 85, so as to ensure the horizontal degree of the left adjusting beam gear shaft 14. When the degree of upward displacement of the left adjustment cross member 14 reaches the indication value of the scale markings 832 on the scale screw 83, the operation of the elevation cylinder 81 is stopped, and the aforementioned scale screw lock nut 831 is locked by the operator. When the distance between a set of upper and lower heating pipes 21, 31 is decreased to adapt to the processing of the reduced thickness slab 30, the adjustment process of the left adjustment beam upper and lower adjustment mechanism 8 is reversed. When the left adjusting beam up-down adjusting mechanism 8 is adjusted, the right adjusting beam up-down adjusting mechanism 20 needs to be adjusted at the same time.

A left adjusting beam gear shaft supporting base 1411 (shown in fig. 2) is fixed to one side of the left adjusting beam cavity wall of the left adjusting beam cavity 141 of the left adjusting beam 14 at intervals along the length direction of the left adjusting beam cavity wall, and the left adjusting beam gear shaft 142 is rotatably supported by the left adjusting beam gear shaft supporting base 1411; a right adjustment beam gear shaft support 1511 (shown in fig. 3) is fixed to one side of the right adjustment beam cavity wall of the right adjustment beam cavity 151 of the right adjustment beam 15 at intervals along the longitudinal direction of the right adjustment beam cavity wall, and the right adjustment beam gear shaft 152 is rotatably supported by the right adjustment beam gear shaft support 1511.

A left adjustment cross member limit clamp 113 (shown in fig. 2) is fixed to each of the left and right sides of the left adjustment cross member 14 (the left and right sides are defined in terms of the position shown in fig. 1) in the frame left-side-frame cavity 111 of the pair of frame left-side frames 11 by a set of left adjustment cross member limit clamp screws 1131; a right adjustment cross member limit clamp 123 is fixed to the frame right post cavity 121 of the pair of frame right posts 12 and at positions corresponding to the left and right sides of the right adjustment cross member 15 by a set of right adjustment cross member limit clamp screws 1231 (shown in fig. 3).

Referring to fig. 5 in conjunction with fig. 1 and 2, a first upper heating pipe floating connection device 143 is provided at lower portions of left and right sides of the left adjusting beam 14 in the longitudinal direction, for floating connection with left ends of a group of upper heating pipes 21 of the upper heating mechanism 2. Referring to fig. 3 in conjunction with fig. 1, a second upper heating pipe floating connection device 153 for floating connection with the right end of the group of upper heating pipes 21 is respectively disposed at the lower portions of the left and right sides of the right adjusting beam 15 in the length direction. The left and right sides are defined here again in terms of the position in fig. 1.

Since the structure and function of the first upper heating pipe floating connection device 143 illustrated in fig. 1, 2 and 5 are identical to those of the second upper heating pipe floating connection device 153 illustrated in detail in fig. 3, the applicant will hereinafter describe only the second upper heating pipe floating connection device 153 in detail.

Referring to fig. 3, the floating connection device 153 of the second upper heating pipe includes a U-shaped channel 1531 and adjusting screws 1532 with the same number as the group of upper heating pipes 21, the channel 1531 is welded to the lower side of the right adjusting beam 15 in the length direction, an adjusting screw hole 15311 is formed at a position corresponding to the upper heating pipe 21 in the channel 1531 at intervals, an adjusting screw 1532 is provided at the channel 1531 at a position corresponding to the adjusting screw hole 15311, and a screw ear 15321 is formed at the lower end of the adjusting screw 1532, the position of the screw ear 15321 on the adjusting screw 1532 corresponds to the lower part of the channel steel 1531, and the screw lifting lug 15321 is hinged to a group of upper heating pipes 21, a spring 15322 is further sleeved on the adjusting screw 1532, the spring 15322 is supported at its upper end on channel steel 1531 and at its lower end on screw lug 15321.

As shown in fig. 3, a screw lug coupling seat 214 is formed on each of the upper heating pipes 21 and at a position corresponding to the screw lug 15321, and the screw lug coupling seat 214 is hinged to the screw lug 15321 by a lug coupling seat pin 2141.

As can be seen from the above description of the floating connection devices 143 and 153 of the first and second upper heating pipes, the group of upper heating pipes 21 can always be in good contact with the sheet 30 in the sheet moving channel 10 under the action of the spring 15322.

Since the solvent in the adhesive applied to the sheet 30 is volatilized when the sheet 30 is heated by the upper and lower heating means 2 and 3, in order to secure the environment of the working place, a heat-insulating shield 17 for shielding the upper heating means 2 is provided on the frame 1 and in a region corresponding to the space between the left and right columns 11 and 12 of the pair of frames. The solvent generated when the upper and lower heating mechanisms 2, 3 are heated enters the heat-insulating protective cover 17 and is led out by a pipeline connected with the heat-insulating protective cover 17 for treatment, so as to avoid environmental damage. Also shown in fig. 2 is a shield frame 171 of the heat-insulating shield 17, and the shield frame 171 carries the heat-insulating shield 17 and is fixed between the pair of left and right uprights 11, 12 of the rack.

With reference to fig. 2, in the pair of left stand columns 11 of the rack, a plate end ejection cylinder 114 is disposed on one left stand column of the rack (1) at the rear side of the left end (taking the position state shown in fig. 1 as an example) and at a position corresponding to the rear end of the length direction of the plate cavity 16, and an ejection cylinder column 1141 of the plate end ejection cylinder 114 faces the plate cavity 16; a sawing mechanism 9 for cutting off redundant portions of the end of the slab is provided on the frame 1 at a position corresponding to the slab end topping cylinder 114.

The plate end knockout cylinder 114 is described above as a pneumatic cylinder, but a hydraulic cylinder could be used.

A plate end blocking limiting column 431 is fixed to the pair of grid plate leaning beams 43 and at a position corresponding to the front end of the plate cavity 16 in the length direction, the cross section of the plate end blocking limiting column 431 is L-shaped, and more specifically, L-shaped angle steel is used as the plate end blocking limiting column 431.

When the slabs 30 are located in the slab storage chamber 40 in the state shown in fig. 1, since there is no non-contact gap between the ends of adjacent slabs 30, under the operation of the slab end ejecting cylinder 114, for example, when the ejecting cylinder 1141 extends outward from the cylinder body and ejects the end of the slab 30, the ends of the adjacent slabs 30 are forced to be reliably contacted, because the front end in the length direction of the corresponding slab chamber 16 is defined by the slab end blocking stopper 431.

Referring to fig. 4 in conjunction with fig. 1, a preferred but not limiting structure of the saw mechanism 9 already mentioned above is as follows: the device comprises a motor 91, a driving wheel 92, a transmission belt 93, a driven wheel 94 and a disc saw blade 95, wherein the motor 91 is arranged at the rear side of the left end of the frame 1, the driving wheel 92 is fixed on a motor shaft 911 of the motor 9, one end of the transmission belt 93 is sleeved on the driving wheel 92, the other end of the transmission belt 93 is sleeved on the driven wheel 94, the driven wheel 94 is fixed on a driven wheel shaft 941, the driven wheel shaft 941 is rotatably supported on the driven wheel shaft 9411, and the disc saw blade 95 is fixed on the driven wheel shaft 941 and corresponds to the side part of the rear end port of the plate cavity 16 in the length direction. In the present embodiment, the driving pulley 92 and the driven pulley 94 are pulleys, and the transmission belt 93 is a transmission belt.

As can be seen from the schematic illustration of fig. 4, the end of the sheet material 30 away from the sheet material end blocking the limiting column 431, that is, the end of the sheet material end ejecting cylinder 114, is generally uneven, and the uneven portion is a redundant portion, so when the redundant portion is to be cut off, the motor 91 works, the motor shaft 911 of the motor 91 drives the driving wheel 92 and the driven wheel 94 via the transmission belt 93, and since the circular saw blade 95 is coaxial with the driven wheel shaft 941, the driven wheel 94 drives the circular saw blade 95 via the driven wheel shaft 941, and the redundant portion of the sheet material 30 is sawn off by the circular saw blade 95.

The applicant briefly describes the working process of the present invention with reference to fig. 1 to 6, an operator arranges the plates 30 (strips) to be spliced and coated with the adhesive on the splicing surface into a plate mold frame (not shown) and transfers the plates onto the material turning plate 54 of the material turning mechanism 5, then the turning action cylinder 51 of the material turning mechanism 5 works, and the material turning plate 54 is in the state shown in fig. 1 according to the applicant, that is, the plates 30 are orderly positioned in the plate storage cavity 40 in a stacked state, and the plate 30 positioned at the bottom is pushed towards the direction of the plate end blocking limiting column 431 by the material pushing action cylinder column 1141 of the plate end material pushing action cylinder 114, and then the redundant part of the end of the plate 30 is sawn by the sawing mechanism 9. Meanwhile, the plate pressing strip 45 of the plate pressing mechanism 4 presses the upper part of the plate 30, so that the plate 30 in the plate storage cavity 40 is in a pressed state. At this time, the pushing mechanism 6 works, and according to the description of the pushing mechanism 6 by the applicant, the pushing plate 62 pushes the plates 30 one by one into the plate moving channel 10, and the plate end pushing cylinder 114 works once every time one plate 30 is pushed in, so as to ensure that two ends of the plate 30 entering the plate moving channel 10 are flush.

In the process, the upper heating mechanism 2 and the lower heating mechanism 3 are in the working state, the sheet materials 30 are heated by the synergistic effect of the upper heating pipe 21 and the lower heating pipe 31, and the adjacent sheet materials 30 are reliably adhered until the sheet materials 30 are led out from the spliced sheet material outlet 102 in the form of a whole board surface and are cut according to the length of 244 cm (the width of 122 cm).

In conclusion, the technical scheme provided by the invention overcomes the defects in the prior art, the invention task is completed, the technical effects listed in the technical effect column of the applicant are objectively realized, and the technical scheme is a very technical scheme.

Claims (1)

1. The utility model provides an automatic makeup machine of energy saving, includes a frame (1), the left end of this frame (1) is fixed in a pair of setting face to face each other and between frame left side post (11) that support on the terrace under the user state in order to empty in the state of terrace, and the right-hand member of frame (1) is fixed in a pair of setting face to face each other and also is supported between frame right side post (12) on the terrace under the user state in order to empty in the state of terrace equally, be provided with a frame scraping wings platform (13) at the left end of frame (1), wherein: a left adjusting beam (14) is arranged between the pair of left stand columns (11) of the frame and in a position corresponding to the upper part of the frame (1) in a manner of moving up and down, and a right adjusting beam (15) is arranged between the pair of right stand columns (12) of the frame and in a position corresponding to the upper part of the frame (1) in a manner of moving up and down;

an upper heating mechanism (2) and a lower heating mechanism (3), wherein the upper heating mechanism (2) is connected with the left adjusting beam (14) and the right adjusting beam (15) at a position corresponding to the lower parts of the left adjusting beam (14) and the right adjusting beam (15) at the same time, the lower heating mechanism (3) is fixed on the rack (1) at a position corresponding to the lower part of the upper heating mechanism (2), a space between the upper heating mechanism (2) and the lower heating mechanism (3) forms a plate material moving channel (10), a left end port of the plate material moving channel (10) forms a plate material introducing port (101), the plate material introducing port (101) is communicated with a plate material cavity (16) formed at the upper part of the left end of the rack (1), and a right end port of the plate material moving channel (10) forms a plate material leading-out port (102) by splicing;

a plate pressing mechanism (4) for pressing the plates in the plate cavity (16) in a stacked state, wherein the plate pressing mechanism (4) is fixed on one side of the upper heating mechanism (2) opposite to the lower heating mechanism (3) at a position corresponding to the upper part of the plate cavity (16);

the turning mechanism (5) is used for feeding the sheet material into the sheet material cavity (16), and the turning mechanism (5) is arranged on the rack (1) at a position corresponding to the sheet material cavity (16);

the pushing mechanism (6) is used for pushing the plate in the plate cavity (16) into the plate introducing port (101), and the pushing mechanism (6) is arranged on the rack pushing plate platform (13) corresponding to the left position of the length direction of the plate cavity (16) and is characterized in that: the pushing mechanism (6) comprises a pair of pushing plate acting cylinders (61), a pushing plate (62) and a pair of pushing plate synchronizing devices (63), the pair of pushing plate acting cylinders (61) are fixed on a pushing plate acting cylinder seat (612) in a horizontal state, pushing plate acting cylinder posts (611) of the pair of pushing plate acting cylinders (61) face the pushing plate (62), the pushing plate (62) corresponds to the length direction of the plate cavity (16) and is in sliding fit with the rack pushing plate platform (13), a pushing plate connecting seat (621) is fixed on the pushing plate (62) and at a position corresponding to the pushing plate acting cylinder posts (611), the pushing plate connecting seat (621) is connected with the pushing plate acting cylinder posts (611), the pair of pushing plate synchronizing devices (63) are arranged between the pushing plate (62) and the rack pushing plate platform (13), the material pushing plate action cylinder seat (612) is fixed on the left side surface of a rack material pushing plate platform (13) in a horizontal cantilever state, and the material turning mechanism (5) corresponds to the upper part of the material pushing plate (62); the upper heating mechanism (2) comprises a group of upper heating pipes (21), an upper heating pipe heating medium introducing header pipe (22) and an upper heating pipe heating medium leading-out header pipe (23), the group of upper heating pipes (21) are distributed at intervals in a parallel state, the left ends of the group of upper heating pipes (21) are connected with a left adjusting cross beam (14) at a position corresponding to the lower part of the left adjusting cross beam (14), the right ends of the group of upper heating pipes (21) are connected with a right adjusting cross beam (15) at a position corresponding to the lower part of the right adjusting cross beam (15), an upper heating pipe heating medium introducing interface (212) for introducing a heating medium into an upper heating pipe cavity (211) is respectively fixed above the left ends of the group of upper heating pipes (21), an upper heating pipe heating medium leading-out interface (213) for leading the heating medium out of the upper heating pipe cavity (211) is respectively fixed on the right end surface of the group of upper heating pipes (21), an upper heating pipe heating medium introducing main pipe (22) is fixed between the pair of rack left upright posts (11), and corresponding to one side of the left adjusting beam (14) facing the right adjusting beam (15), upper heating pipe heating medium introducing main pipe interfaces (221) with the number equal to that of the upper heating pipes (21) are formed on the upper heating pipe heating medium introducing main pipe (22) and at positions corresponding to the upper heating pipe heating medium introducing interfaces (212), the upper heating pipe heating medium introducing main pipe interfaces (221) are connected with the upper heating pipe heating medium introducing interfaces (212) through first upper transition connecting pipes (2211), an upper heating pipe heating medium leading-out main pipe (23) is fixed between the pair of rack right upright posts (12) and corresponding to one side of the right adjusting beam (15) opposite to the left adjusting beam (14), upper heating pipe heating medium leading-out header pipe interfaces (231) with the number equal to that of the upper heating pipes (21) are formed on the upper heating pipe heating medium leading-out header pipe (23) and at positions corresponding to the upper heating pipe heating medium leading-out interfaces (213), and the upper heating pipe heating medium leading-out header pipe interfaces (231) are connected with the upper heating pipe heating medium leading-out interfaces (213) through second upper transition connecting pipes (2311); the lower heating mechanism (3) comprises a group of lower heating pipes (31), a lower heating pipe heating medium introducing main pipe (32) and a lower heating pipe heating medium extracting main pipe (33), the number of the group of lower heating pipes (31) is equal to that of the group of upper heating pipes (21), the lower heating pipes are distributed at intervals in a parallel state, the left ends of the group of lower heating pipes (31) are fixed with the rack (1) at positions corresponding to the lower parts of the upper heating pipes (21), the right ends of the group of lower heating pipes (31) are fixed with the rack (1) at positions corresponding to the lower parts of the upper heating pipes (21), lower heating pipe heating medium introducing interfaces (312) used for introducing a heating medium into the lower heating pipe cavities (311) are respectively fixed below the left ends of the group of lower heating pipes (31), and lower heating pipe adding interfaces (312) used for introducing the heating medium out of the lower heating pipe cavities (311) are respectively fixed on the right end faces of the group of lower heating pipes (31) A heat medium leading-out interface (313), a lower heating pipe heating medium leading-in main pipe (32) is fixed on the frame (1) at a position corresponding to the lower part of the left end of the lower heating pipe (31), lower heating pipe heating medium leading-in main pipe interfaces (321) with the number equal to that of the lower heating pipes (31) are formed on the lower heating pipe heating medium leading-in main pipe (32) and at a position corresponding to the lower heating pipe heating medium leading-in interfaces (312), the lower heating pipe heating medium leading-in main pipe interfaces (321) are connected with the lower heating pipe heating medium leading-in interfaces (312) through first transition pipes (3211), the lower heating pipe heating medium leading-out main pipe (33) is fixed between the pair of frame right upright posts (12) at a position corresponding to the lower part of the right end of the lower heating pipe (31), and corresponds to the side of the right adjusting beam (15) back to the left adjusting beam (14), lower heating tube heating medium leading-out main pipe interfaces (331) with the number equal to that of the lower heating tubes (31) are formed on the lower heating tube heating medium leading-out main pipe (33) and at positions corresponding to the lower heating tube heating medium leading-out interfaces (313), and the lower heating tube heating medium leading-out main pipe interfaces (331) are connected with the lower heating tube heating medium leading-out interfaces (313) through second transition tubes (3311); the space between the group of upper and lower heating pipes (21, 31) is formed into the plate material moving channel (10); the plate pressing mechanism (4) is fixed on the upper heating pipe (21) at a position corresponding to the upper part of the plate cavity (16); the plate pressing mechanism (4) comprises a supporting beam (41), a pair of pressing action cylinder fixing frames (42), a pair of grid plate strip leaning beams (43), a group of grid plate strips (44), a plate pressing strip (45) and a pair of plate pressing strip action cylinders (46), wherein one end of the supporting beam (41) is fixed with a first cushion block (411), the other end of the supporting beam is fixed with a second cushion block (412), the first cushion block (411) is fixed with one side, facing upwards, of the first upper heating pipe in the group of upper heating pipes (21), the second cushion block (412) is fixed with one side, facing upwards, of the last upper heating pipe in the group of upper heating pipes (21), the bottom of one of the pressing action cylinder fixing frames (42) is fixed with one end of the supporting beam (41), and the bottom of the other pressing action cylinder fixing frame in the pair of pressing action cylinder fixing frames (42) is fixed with the other end of the supporting beam (41), a plate pressing strip acting cylinder fixing seat (421) is respectively fixed at the top of the pair of pressing acting cylinder fixing frames (42), a pair of grid plate strip leaning beams (43) and one side of the pair of pressing acting cylinder fixing frames (42) facing the plate cavity (16) are fixed, the grid plate strip leaning beams (43) are transversely parallel to each other, a group of grid plate strips (44) are longitudinally fixed on one side of the grid plate strip leaning beams (43) back to the pair of pressing acting cylinder fixing frames (42) in a spaced state, one plate pressing strip acting cylinder of the pair of plate pressing strip acting cylinders (46) is fixed on the plate pressing strip acting cylinder fixing seat (421) of one pressing acting cylinder fixing frame of the pair of pressing acting cylinder fixing frames (42), and the other plate pressing strip acting cylinder of the pair of plate pressing strip acting cylinders (46) is fixed on the plate pressing strip acting cylinder of the other pressing acting cylinder of the pair of pressing acting cylinder fixing frames (42) On the fixed seat (421), the plate pressing strip acting cylinder column (461) of the pair of plate pressing strip acting cylinders (46) faces downwards, one end of the plate pressing strip (45) is connected with the tail end of the plate pressing strip acting cylinder column (461) of one of the pair of plate pressing strip acting cylinders (46), the other end of the plate pressing strip (45) is connected with the tail end of the plate pressing strip acting cylinder column (461) of the other one of the pair of plate pressing strip acting cylinders (46), and the plate pressing strip (45) corresponds to the upper part of the plate cavity (16); the cross section of the group of grid strips (44) is V-shaped;

the material turning mechanism (5) comprises a turning action cylinder (51), a turning arm (52), a material turning plate shaft (53) and a material turning plate (54), the turning action cylinder (51) is connected to a turning action cylinder base (512) in a longitudinal state through a connecting pin (513), the turning action cylinder base (512) is fixed on the front side of the left end of the rack (1), a turning action cylinder column (511) of the turning action cylinder (51) faces upwards, a material turning plate shaft fixing base (541) is fixed on the lower portion of the material turning plate (54) in the length direction of one side facing the material cavity (16), the middle portion of the material turning plate shaft (53) in the length direction is fixed with the material turning plate shaft fixing base (541), two ends of the material turning plate shaft (53) extend out of the material turning plate (54) and are rotatably supported on the rack material pushing plate platform (13), one end of the turning arm (52) is fixed with the material turning plate shaft (53), the other end is hinged with the turning cylinder column (511) through a turning arm pin shaft (521);

the material turning plate traction mechanism (7) comprises a traction plate (71) and a traction plate acting cylinder (72), the traction plate (71) is movably arranged on the frame material pushing plate platform (13) and corresponds to the end part of the material turning plate shaft (53), a material turning plate shaft supporting seat (711) and a traction plate acting cylinder connecting seat (712) are formed on the traction plate (71), the end part of the material turning plate shaft (53) is rotatably supported on the material turning plate shaft supporting seat (711), the traction plate acting cylinder (72) is arranged on the frame material pushing plate platform (13) in a horizontal state, a traction plate acting cylinder adjusting screw rod (721) is connected to the tail part of the traction plate acting cylinder (72), the traction plate acting cylinder adjusting screw rod (721) is connected to the adjusting screw rod seat (7211) and is limited by a limiting nut (7212), the adjusting screw rod seat (7211) is fixed on the frame material pushing plate platform (13), the tail end of a traction plate acting cylinder column (722) of the traction plate acting cylinder (72) is connected with the traction plate acting cylinder column connecting seat (712);

a traction plate sliding groove (713) is further formed in the traction plate (71), and a traction plate limiting screw (7131) fixed with the rack material pushing plate platform (13) is arranged in a position corresponding to the traction plate sliding groove (713); the traction plate acting cylinder (72) uses an oil cylinder.

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