阅读说明：本技术 一种智能烫画机 (Intelligent pyrography machine ) 是由 曹胜彬 杨俊伟 于 2021-08-30 设计创作，主要内容包括：本发明涉及一种智能烫画机,该烫画机包括底板、烫画机构、上料机构、控制机构,所述底板的上部设有烫画机构,所述烫画机构包括倒L形固定板,倒L形固定板上设有第一伸缩气缸,第一伸缩气缸下端连接配装板,所述配装板经弹性件连接加热板,所述上料机构设有方形围板、支撑台、滑杆、第二伸缩气缸,所述第二伸缩气缸驱动支撑台沿滑杆做直线往复运动,所述控制机构控制第一伸缩气缸、加热板以及第二伸缩气缸有序工作。与现有技术相比,本发明装置可有效降低工作人员的工作强度,能有效保证加热板的使用寿命,可适用于加工不同厚度的待印刷烫画的印刷物,可以不间断上料工作,整个工作过程自动化程度较高,可大幅提高工作效率。(The invention relates to an intelligent pyrograph machine which comprises a bottom plate, a pyrograph mechanism, a feeding mechanism and a control mechanism, wherein the pyrograph mechanism is arranged at the upper part of the bottom plate and comprises an inverted L-shaped fixed plate, a first telescopic cylinder is arranged on the inverted L-shaped fixed plate, the lower end of the first telescopic cylinder is connected with an assembly plate, the assembly plate is connected with a heating plate through an elastic piece, the feeding mechanism is provided with a square surrounding plate, a supporting table, a sliding rod and a second telescopic cylinder, the supporting table is driven by the second telescopic cylinder to do linear reciprocating motion along the sliding rod, and the control mechanism controls the first telescopic cylinder, the heating plate and the second telescopic cylinder to work in order. Compared with the prior art, the device can effectively reduce the working strength of workers, can effectively ensure the service life of the heating plate, is suitable for processing printed matters with different thicknesses and to-be-printed pyrographs, can continuously feed materials, has higher automation degree in the whole working process, and can greatly improve the working efficiency.)

1. The utility model provides an intelligence pyrograph machine which characterized in that includes:

a base plate (1);

a pyrograph area arranged on the bottom plate (1);

a pyrography mechanism (2) located above the pyrography area: the heating device comprises a first telescopic assembly capable of moving in the vertical direction, a fitting plate (206) arranged at the bottom of the first telescopic assembly, a heating plate (207) arranged below the fitting plate (206), and an elastic piece (208) positioned between the fitting plate (206) and the heating plate (207).

2. An intelligent pyrograph machine according to claim 1, characterized in that the pyrograph mechanism (2) further comprises an inverted L-shaped fixed plate (201) fixed on the base plate (1) and extending above the working position, and the first telescopic assembly is arranged on top of the inverted L-shaped fixed plate (201).

3. An intelligent pyrograph machine according to claim 2, wherein the inverted L-shaped fixing plate (201) is further provided with a guide rod (209) movably installed along the vertical direction, the bottom end of the guide rod (209) is fixedly connected with the assembling plate (206), the top end of the guide rod (209) extends out of the inverted L-shaped fixing plate (201), and a buffer spring (211) is further arranged between the top end of the guide rod (209) and the inverted L-shaped fixing plate (201).

4. An intelligent pyrograph machine according to claim 1, wherein a sleeve rod (203) is arranged at the bottom of the first telescopic assembly, a connecting rod (204) is further installed on the upper surface of the assembling plate (206), the connecting rod (204) is matched and slid into the sleeve rod (203), and a locking bolt (205) for fixing the connecting rod (204) and the sleeve rod (203) relatively is further arranged between the connecting rod (204) and the sleeve rod (203).

5. The intelligent pyrograph machine according to claim 1, wherein the elastic member (208) comprises a cylindrical shell (2081) with a hollow interior, a fixed block (2082) fixed at the top end of the cylindrical shell (2081), a guide block (2084) capable of moving up and down along the inner wall of the cylindrical shell (2081), and a return spring (2083) with two ends respectively connected with the fixed block (2082) and the guide block (2084), and a round bar (2085) extending out of the cylindrical shell (2081) and connected with the heating plate (207) is further arranged on the lower surface of the guide block (2084).

6. An intelligent pyrograph machine according to claim 1, characterized in that the intelligent pyrograph machine further comprises a feeding mechanism (3) mounted on the base plate (1), the pyrograph area being arranged on the feeding mechanism (3).

7. An intelligent pyrograph machine according to claim 6, wherein the feeding mechanism (3) comprises a support platform (303) which slides to and fro in the horizontal direction, a station (306) is arranged on the support platform (303), and the projection of the heating plate (207) on the bottom plate (1) falls on the stroke path of the support platform (303).

8. An intelligent pyrograph machine according to claim 7, wherein the bottom plate (1) is provided with a square enclosing plate (301), the inner wall of the square enclosing plate (301) is provided with a slide rod (302), the support platform (303) is slidably arranged on the slide rod (302), and the side wall of the square enclosing plate (301) is further provided with a second telescopic assembly connected with the support platform (303).

9. An intelligent pyrograph machine according to claim 8, characterized in that the intelligent pyrograph machine further comprises a control mechanism (4) which connects and controls the operation of the pyrograph mechanism (2) and the feeding mechanism (3).

10. An intelligent pyrograph machine according to claim 9, wherein the square coaming (301) is further provided with a proximity sensor (406) electrically connected with the control mechanism (4).

Technical Field

The invention belongs to the technical field of pyrograph machines, and relates to an intelligent pyrograph machine.

Background

The pyrograph machine can heat-transfer various pyrographs on fabrics such as cotton, hemp, chemical fiber and the like, can also carry out heat treatment of processes such as silk-screen printing, mucilage glue, foaming and the like, can bake color codes, portrait photos, landscape patterns and the like on porcelain plates and metal plates, is particularly suitable for manufacturing medals, commemorative cards, cultural shirts and the like, is economical and practical, and has exquisite patterns. It is replacing traditional embroidery and silk screen printing, but the cost and effect is much lower and better than general embroidery and multicolor silk screen printing.

Manual pyrograph machine among the prior art needs artifical manually operation pyrograph mechanism for staff's working strength is great, has the bad phenomenon that the violent collision takes place in the upper portion of hot plate and bottom plate simultaneously, is difficult to effectively guarantee the life of hot plate, is difficult to be applicable to the printed matter of waiting to print pyrograph of processing different thickness, and the practicality is not too good, and degree of automation is not high, adopts the material loading mode of discontinuous, seriously influences work efficiency.

Disclosure of Invention

The invention aims to provide an intelligent pyrograph machine, which solves the problems that the prior art is low in working efficiency, difficult to ensure the service life of a heating plate or difficult to be suitable for processing printed matters to be printed and pyrographed with different thicknesses and the like.

The purpose of the invention can be realized by the following technical scheme:

an intelligent pyrograph machine comprising:

a base plate (1);

a pyrograph area arranged on the bottom plate (1);

the pyrography mechanism is positioned above the pyrography area: the heating plate comprises a first telescopic assembly capable of moving in the vertical direction, an assembling plate arranged at the bottom of the first telescopic assembly, a heating plate arranged below the assembling plate, and an elastic part positioned between the assembling plate and the heating plate.

Furthermore, the pyrograph mechanism further comprises an inverted L-shaped fixing plate which is fixed on the bottom plate and extends to the upper part of the working position, and the top of the inverted L-shaped fixing plate is provided with the first telescopic assembly.

Furthermore, the L-shaped fixed plate is further provided with a guide rod movably mounted in the vertical direction, the bottom end of the guide rod is fixedly connected with the assembling plate, the top end of the guide rod extends out of the L-shaped fixed plate, and a buffer spring is further arranged between the top end of the guide rod and the L-shaped fixed plate.

Furthermore, the guide rods are symmetrically distributed on the periphery of the first telescopic assembly, and 2 guide rods can be arranged.

Furthermore, a stop block is arranged at the top end of the guide rod. Make first flexible subassembly drive hot plate action during more stable under guide bar, dog and buffer spring's cooperation to it is more stable to make this pyrograph machine operation.

Furthermore, the bottom of first flexible subassembly be equipped with the loop bar, still install the connecting rod at the upper surface of joining in marriage the dress board, the connecting rod match slide in the loop bar, still be equipped with between connecting rod and loop bar and make both relatively fixed's locking bolt, the distance between the upper portion of hot plate and bottom plate is adjusted to accessible bolt adjustment connecting rod in the inside position of loop bar.

Further, the elastic component include inside hollow cylindrical casing, fix the fixed block on cylindrical casing top, can follow the guide block that cylindrical shells inner wall reciprocated to and both ends are connected respectively the reset spring of fixed block and guide block still is equipped with at the lower surface of guide block and stretches out cylindrical casing is connected the round bar of hot plate, the elastic component can set up to 4 groups.

Furthermore, this intelligence pyrograph machine still includes the feed mechanism of installing on the bottom plate, arranges on feed mechanism pyrograph district.

Furthermore, the feeding mechanism comprises a supporting table which slides in a reciprocating manner along the horizontal direction, a station is arranged on the supporting table, and the projection of the heating plate on the bottom plate falls on the stroke path of the supporting table.

Furthermore, the bottom plate on be equipped with square bounding wall, install the slide bar on the inner wall of square bounding wall, the brace table slides and sets up on the slide bar, still install on the lateral wall of square bounding wall with the flexible subassembly of second that the brace table is connected.

Furthermore, a fixed seat is arranged at the bottom of the supporting platform, and the supporting platform is connected with the telescopic end of the second telescopic component through the fixed seat.

Furthermore, the intelligent pyrograph machine also comprises a control mechanism which is connected with and controls the pyrograph mechanism and the feeding mechanism to work.

Furthermore, the control mechanism comprises a mounting plate, a controller, a control switch and a touch display screen.

Further, the mounting panel links to each other with the one end outer wall of square bounding wall, the controller is installed on the side of mounting panel, just the controller respectively with first flexible subassembly, hot plate and the flexible subassembly electric connection of second, control switch and the equal fixed mounting of touch-control display screen is on the another side of mounting panel, and control switch and touch-control display screen all with controller electric connection.

Furthermore, a proximity sensor electrically connected with the control mechanism is arranged on the square enclosing plate. The proximity sensor is installed on the upper portion of the edge of the square enclosing plate and used for detecting the position of the supporting table to assist the controller to accurately control the first telescopic assembly and the second telescopic assembly to accurately move, and therefore the stability of the pyrograph machine is improved.

Furthermore, the first telescopic assembly and the second telescopic assembly both comprise telescopic cylinders.

Furthermore, the upper part of the supporting platform is provided with a high-temperature resistant foaming silica gel plate.

Furthermore, the heating plate is internally provided with a heating wire electrically connected with the controller to provide a heating source.

Furthermore, the surface of the heating plate is plated with an anti-sticking coating of teflon so as to prevent the surface of the heating plate from being stained with foreign matters to influence the use.

Furthermore, a reinforcing plate is further installed between the top wall and the side wall of the inverted L-shaped fixing plate, so that the supporting strength of the inverted L-shaped fixing plate is guaranteed.

Furthermore, the bottom of the bottom plate is provided with support legs.

Furthermore, a circular plate is installed at the bottom end of each supporting leg, the pyrograph machine can be stably placed under the action of the supporting legs and the circular plate, installation and use are facilitated, and the number of the supporting legs can be set to be 4.

The use method of the intelligent pyrograph machine comprises the following steps:

(1) placing a printed matter to be printed on a station deviating from the heating plate, and placing a pyrograph to be printed on the upper part of the printed matter to be printed;

(2) a control switch is pressed to input a control signal to a controller, the controller controls a second telescopic cylinder to act to drive a supporting platform to do linear motion in the square enclosing plate along a sliding rod, a printed matter to be printed on a station is pushed to the position under a heating plate, at the moment, the controller controls a first telescopic cylinder to act to drive the heating plate to press on the printed matter to be printed, a pyrograph to be printed is hot-stamped on the printed matter through heat transfer printing, then the controller controls the first telescopic cylinder to act to drive the heating plate to leave the printed matter, controls the second telescopic cylinder to act to drive the supporting table to move to drive the printed matter printed with the pyrograph to deviate from the heating plate, takes the printed matter printed with the pyrograph down, places a printed matter to be printed on the station again, and the pyrograph to be printed is placed on the upper part of the printed matter to be printed, and when the machine is to be stopped, the machine can be stopped by pressing the control switch again.

When the device is used, a printed matter to be printed with a pyrograph can be placed on the upper part of the bottom plate, then the first telescopic cylinder is used for driving the assembling plate to drive the heating plate to move towards the printed matter to be printed with the pyrograph, the pyrograph to be printed is hot-stamped on the printed matter through heat transfer printing, and the first telescopic cylinder is used for acting to replace manual operation to drive the pyrograph mechanism to work, so that the aim of semi-automation of the pyrograph machine is fulfilled, and the working intensity of workers can be effectively reduced; in addition, the elastic parts are symmetrically distributed between the assembling plate and the heating plate, and the elastic parts have better elastic telescopic performance under the mutual matching of the cylindrical shell, the fixed block, the guide block, the reset spring and the round rod, so that the heating plate can be effectively prevented from violently colliding with the upper part of the bottom plate under the action of the elastic parts, and the service life of the heating plate is effectively ensured; in addition, the distance between the heating plate and the upper part of the bottom plate can be adjusted by adjusting the position of the connecting rod in the sleeve rod through the bolt, so that the intelligent pyrograph machine can be suitable for processing printed matters to be printed and pyrographed with different thicknesses, and has better practicability; the device is also provided with a feeding mechanism, and when the device is used, the supporting table can be driven by the second telescopic cylinder to do linear reciprocating motion along the sliding rod in the square enclosing plate, so that the aim of switching two stations back and forth is fulfilled, the intelligent pyrograph machine can work uninterruptedly, and the working efficiency is effectively improved; in addition, this device still is equipped with control mechanism and controls the working process, through control switch to controller input control signal, controller control second telescopic cylinder action drive brace table is linear motion along the slide bar in the inside of square bounding wall, with the printed matter propelling movement of treating the printing on the station to the hot plate under, then the first telescopic cylinder action drive hot plate of controller control is pressed on the printed matter of treating the printing, the pyrograph that will treat the printing scalds on the printed matter through the heat-transfer seal scald, then the first telescopic cylinder action drive hot plate of controller control leaves the printed matter, the skew hot plate of printed matter that the pyrograph has been printed is driven in the removal of the flexible cylinder action drive brace table of second of controling again, action more than the repetition, can realize incessant material loading, degree of automation is higher, can improve work efficiency by a wide margin.

Compared with the prior art, the invention has the following advantages:

(1) according to the intelligent pyrograph machine, the first telescopic cylinder is used for acting to replace a manual pyrograph operation mechanism to work, so that the working strength of workers can be effectively reduced;

(2) the intelligent pyrograph machine provided by the invention can effectively prevent the heating plate from violently colliding with the upper part of the bottom plate under the action of the elastic piece, thereby effectively ensuring the service life of the heating plate;

(3) according to the intelligent pyrograph machine, the distance between the heating plate and the upper part of the bottom plate can be adjusted by adjusting the position of the connecting rod in the sleeve rod through the bolt, so that the intelligent pyrograph machine can be suitable for processing printed matters to be printed with pyrographs of different thicknesses, and is good in practicability;

(4) the intelligent pyrograph machine provided by the invention is provided with the feeding mechanism, the feeding mechanism consists of the square coaming, the slide rod, the supporting table, the fixed seat and the second telescopic cylinder, and when the intelligent pyrograph machine is used, the supporting table can be driven by the second telescopic cylinder to do linear reciprocating motion in the square coaming along the slide rod, so that the purpose of switching two stations back and forth is realized, the intelligent pyrograph machine can continuously feed, and the working efficiency is effectively improved;

(5) the intelligent pyrograph machine provided by the invention is provided with a control mechanism, the control mechanism is composed of a mounting plate, a controller, a control switch and a touch display screen, working parameters of the first telescopic cylinder, the heating plate and the second telescopic cylinder can be set by using the touch display screen, a control signal can be input to the controller through the control switch, the first telescopic cylinder, the heating plate and the second telescopic cylinder are further controlled to work orderly and stably, the automation degree of the whole working process of finishing the pyrograph is higher, and the working efficiency can be greatly improved.

Drawings

FIG. 1 is a schematic structural diagram of an intelligent pyrograph machine of the present invention;

FIG. 2 is an enlarged schematic view of a portion A of FIG. 1;

FIG. 3 is an enlarged schematic view of a portion B of FIG. 1;

FIG. 4 is a schematic view of another aspect of the intelligent pyrograph machine of the present invention;

FIG. 5 is an enlarged schematic view of a portion C of FIG. 4;

FIG. 6 is a schematic cross-sectional structural view of a feeding mechanism of the intelligent pyrograph machine of the present invention;

FIG. 7 is a second schematic view of the intelligent pyrograph machine of the present invention;

fig. 8 is a schematic sectional view of an elastic member of the intelligent pyrograph machine of the present invention.

The notation in the figure is:

1-bottom plate, 101-supporting leg, 102-circular plate, 2-pyrograph mechanism, 201-inverted L-shaped fixing plate, 202-first telescopic cylinder, 203-loop bar, 204-connecting rod, 205-bolt, 206-assembly plate, 207-heating plate, 208-elastic piece, 2081-cylindrical shell, 2082-fixing block, 2083-reset spring, 2084-guide block, 2085-circular rod, 209-guide rod, 210-stop block, 211-buffer spring, 212-reinforcing plate, 3-feeding mechanism, 301-square enclosing plate, 302-sliding rod, 303-supporting table, 304-fixing seat, 305-second telescopic cylinder, 306-station, 4-control mechanism, 401-mounting plate, 402-controller, 403-control switch, 404-touch display screen, 405-stand, 406-proximity sensor.

Detailed Description

The invention is described in detail below with reference to the figures and specific embodiments. The present embodiment is implemented on the premise of the technical solution of the present invention, and a detailed implementation manner and a specific operation process are given, but the scope of the present invention is not limited to the following embodiments.

In the following embodiments or examples, functional components or structures that are not specifically described are all conventional components or structures that are adopted in the art to achieve the corresponding functions.

In the description of the present invention, unless otherwise specified, the terms "first", "second", "third", and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In order to overcome the problems of low working efficiency, difficulty in ensuring the service life of the heating plate 207 or difficulty in being suitable for processing printed matters to be printed with pyrographs of different thicknesses and the like in the prior art, the invention provides an intelligent pyrograph machine, the structure of which is shown in figures 1-8, and the intelligent pyrograph machine comprises:

a base plate 1;

a pyrograph region disposed on the base plate 1;

the pyrography mechanism 2 located above the pyrography area: which includes a first telescopic assembly movable in a vertical direction, a fitting plate 206 installed at the bottom of the first telescopic assembly, a heating plate 207 disposed under the fitting plate 206, and an elastic member 208 between the fitting plate 206 and the heating plate 207.

In some specific embodiments, referring to fig. 1 and 3, the pyrograph mechanism 2 further includes an inverted L-shaped fixing plate 201 fixed on the bottom plate 1 and extending above the working position, and the first telescopic assembly is disposed on top of the inverted L-shaped fixing plate 201.

In a more specific embodiment, the inverted L-shaped fixing plate 201 is further provided with a guide rod 209 movably installed along the vertical direction, the bottom end of the guide rod 209 is fixedly connected with the assembling plate 206, the top end of the guide rod 209 extends out of the inverted L-shaped fixing plate 201, and a buffer spring 211 is further arranged between the top end of the guide rod 209 and the inverted L-shaped fixing plate 201.

In a more specific embodiment, there are 2 guide rods 209, and the guide rods 209 are symmetrically distributed on the periphery of the first telescopic assembly.

In a more specific embodiment, the top end of the guide rod 209 is provided with a stopper 210. Under the cooperation of the guide rod 209, the stopper 210 and the buffer spring 211, the first telescopic assembly drives the heating plate 207 to act more stably, so that the operation of the pyrograph machine is more stable.

In some embodiments, referring to fig. 3, the bottom of the first telescopic assembly is provided with a sleeve 203, a connecting rod 204 is further installed on the upper surface of the fitting plate 206, the connecting rod 204 is matched and slid into the sleeve 203, a locking bolt 205 is further provided between the connecting rod 204 and the sleeve 203 to fix the two relatively, and the distance between the heating plate 207 and the upper portion of the soleplate 1 can be adjusted by adjusting the position of the connecting rod 204 inside the sleeve 203 through the bolt 205.

In some specific embodiments, referring to fig. 8, the elastic member 208 has 4 groups, and includes a cylindrical housing 2081 with a hollow interior, a fixed block 2082 fixed on the top end of the cylindrical housing 2081, a guide block 2084 capable of moving up and down along the inner wall of the cylindrical housing 2081, and a return spring 2083 with two ends respectively connected to the fixed block 2082 and the guide block 2084, and a round bar 2085 extending out of the cylindrical housing 2081 and connected to the heating plate 207 is further disposed on the lower surface of the guide block 2084.

In some specific embodiments, referring to fig. 1, the intelligent pyrograph machine further includes a feeding mechanism 3 installed on the base plate 1, and the pyrograph area is disposed on the feeding mechanism 3.

In a more specific embodiment, the feeding mechanism 3 includes a support platform 303 that slides back and forth in the horizontal direction, 2 stations 306 are provided on the support platform 303, and the projection of the heating plate 207 on the bottom plate 1 falls on the stroke path of the support platform 303.

In a more specific embodiment, referring to fig. 6, a square enclosure 301 is disposed on the bottom plate 1, a sliding rod 302 is mounted on an inner wall of the square enclosure 301, the supporting platform 303 is slidably disposed on the sliding rod 302, and a second telescopic assembly connected to the supporting platform 303 is further mounted on a side wall of the square enclosure 301.

In a more specific embodiment, a fixing seat 304 is provided at the bottom of the supporting platform 303, and the supporting platform 303 and the telescopic end of the second telescopic assembly are connected through the fixing seat 304.

In some specific embodiments, referring to fig. 1, the intelligent pyrograph machine further includes a control mechanism 4 for connecting and controlling the operation of the pyrograph mechanism 2 and the feeding mechanism 3.

In a more specific embodiment, referring to fig. 2 and 5, the control mechanism 4 includes a mounting plate 401, a controller 402, a control switch 403, and a touch display screen 404.

In more specific embodiment, the mounting panel 401 passes through the support 405 and links to each other with the one end outer wall of square bounding wall 301, the controller 402 is installed on a side of mounting panel 401, just the controller 402 respectively with first flexible subassembly, hot plate 207 and the flexible subassembly electric connection of second, control switch 403 and the equal fixed mounting of touch-control display screen 404 is on another side of mounting panel 401, and control switch 403 and touch-control display screen 404 all with controller 402 electric connection.

In a more specific embodiment, referring to fig. 4, the square enclosure 301 is further provided with a proximity sensor 406 electrically connected to the control mechanism 4. The proximity sensor 406 is installed at the upper portion of the edge of the square surrounding plate 301, and is used for detecting the position of the supporting platform 303, so as to assist the controller 402 to accurately control the first telescopic assembly and the second telescopic assembly to accurately move, and thus the stability of the pyrograph machine is improved.

In some specific embodiments, a high temperature resistant foaming silica gel plate is mounted on the upper portion of the support platform 303.

In some embodiments, the heating plate 207 is internally provided with a heating wire electrically connected to the controller 402 to provide a heating source.

In some embodiments, the surface of the heating plate 207 is plated with an anti-adhesive teflon coating to prevent the surface of the heating plate 207 from being adhered with foreign matters to affect the use.

In some embodiments, referring to fig. 3, a reinforcing plate 212 is further installed between the top wall and the side wall of the fixing plate 201 to ensure the supporting strength of the fixing plate 201.

In some embodiments, referring to fig. 4, the bottom of the bottom plate 1 is provided with 4 legs 101.

In a more specific embodiment, a circular plate 102 is mounted at the bottom end of the leg 101, so that the pyrograph machine can be stably placed under the action of the leg 101 and the circular plate 102, and is convenient to mount and use.

The use method of the intelligent pyrograph machine comprises the following steps:

(1) placing the printed matter to be printed on a station 306 offset from the heating plate 207 and placing the pyrograph to be printed on the upper part of the printed matter to be printed;

(2) a control signal is input to the controller 402 by pressing the control switch 403, the controller 402 controls the second telescopic cylinder 305 to move to drive the supporting platform 303 to make a linear motion along the sliding rod 302 in the square enclosing plate 301, the printed matter to be printed on the station 306 is pushed to the position right below the heating plate 207, at this time, the controller 402 controls the first telescopic cylinder 202 to move to drive the heating plate 207 to press on the printed matter to be printed, the pyrograph to be printed is hot-transferred and hot-stamped on the printed matter, then the controller 402 controls the first telescopic cylinder 202 to move to drive the heating plate 207 to leave the printed matter, controls the second telescopic cylinder 305 to move to drive the supporting platform 303 to move to drive the printed matter with the pyrograph to deviate from the heating plate 207, takes the printed matter with the pyrograph printed matter printed off, places a printed matter to be printed on the station 306 again, and places the pyrograph to be printed on the upper portion of the printed matter to be printed, when the machine is to be stopped, the machine can be stopped by pressing the control switch 403 again.

When the device is used, a printed matter to be printed with a pyrograph can be placed on the upper part of the base plate 1, then the first telescopic cylinder 202 is utilized to drive the assembling plate 206 to drive the heating plate 207 to move towards the printed matter to be printed with the pyrograph, the pyrograph to be printed is hot-transferred on the printed matter, the first telescopic cylinder 202 acts to replace manual operation to drive the pyrograph mechanism 2 to work, the semi-automation purpose of the pyrograph machine is realized, and the working intensity of workers can be effectively reduced; in addition, the elastic pieces 208 are symmetrically distributed between the assembling plate 206 and the heating plate 207, and the elastic pieces 208 have better elastic expansion performance under the mutual matching of the cylindrical shell 2081, the fixed block 2082, the guide block 2084, the return spring 2083 and the round rod 2085, so that the heating plate 207 can be effectively prevented from violently colliding with the upper part of the bottom plate 1 under the action of the elastic pieces 208, and the service life of the heating plate 207 is effectively ensured; in addition, the distance between the heating plate 207 and the upper part of the base plate 1 can be adjusted by adjusting the position of the connecting rod 204 in the sleeve rod 203 through the bolt 205, so that the intelligent pyrograph machine can be suitable for processing printed matters with different thicknesses and to-be-printed pyrographs, and has good practicability; the device is also provided with a feeding mechanism 3, when the device is used, the second telescopic cylinder 305 can be utilized to drive the supporting platform 303 to do linear reciprocating motion in the square enclosing plate 301 along the sliding rod 302, and the purpose of switching the two stations 306 back and forth is realized, so that the intelligent pyrograph machine can work uninterruptedly, and the working efficiency is effectively improved; in addition, the device is also provided with a control mechanism 4 for controlling the working process, a control switch 403 is used for inputting a control signal to the controller 402, the controller 402 controls the second telescopic cylinder 305 to act to drive the supporting platform 303 to do linear motion in the square enclosing plate 301 along the sliding rod 302, the printed matter to be printed on the station 306 is pushed to the position right below the heating plate 207, then the controller 402 controls the first telescopic cylinder 202 to act to drive the heating plate 207 to press on the printed matter to be printed, the pyrograph to be printed is hot-printed on the printed matter through heat transfer, then the controller 402 controls the first telescopic cylinder 202 to operate to drive the heating plate 207 to leave the printed matter, and controls the second telescopic cylinder 305 to operate to drive the supporting table 303 to move to drive the printed matter printed with the pyrograph to deviate from the heating plate 207.

The above embodiments may be implemented individually, or in any combination of two or more.

The above embodiments will be described in more detail with reference to specific examples.

Example 1:

the intelligence pyrograph machine that this embodiment provided, as shown in fig. 1, includes: the hot-stamping picture making machine comprises a bottom plate 1, wherein the bottom plate 1 is horizontally arranged, and a hot-stamping picture mechanism 2 is arranged at the upper part of the bottom plate 1;

wherein, the pyrograph mechanism 2 comprises an inverted L-shaped fixing plate 201, a first telescopic cylinder 202, a loop bar 203, a connecting rod 204, a fitting plate 206 and a heating plate 207, the inverted L-shaped fixing plate 201 is vertically and fixedly installed at the upper part of the base plate 1, the first telescopic cylinder 202 is vertically and fixedly installed at the bottom of the inner top wall of the inverted L-shaped fixing plate 201, the loop bar 203 is vertically and fixedly installed at the telescopic end part of the first telescopic cylinder 202, the connecting rod 204 is vertically installed inside the bottom end of the loop bar 203 through a bolt 205, the fitting plate 206 is horizontally and fixedly installed at the bottom end part of the connecting rod 204, and the heating plate 207 is horizontally and fixedly installed at the bottom of the fitting plate 206 through an elastic member 208;

as shown in fig. 3, in order to ensure the supporting strength of the inverted L-shaped fixing plate 201, a reinforcing plate 212 is further fixedly installed between the top wall and the side wall of the L-shaped fixing plate 201;

wherein, as shown in fig. 3 and 8, the elastic members 208 are provided in four groups, the four groups of elastic members 208 are symmetrically distributed between the fitting plate 206 and the heating plate 207, each group of elastic pieces 208 comprises a cylindrical shell 2081, a fixed block 2082, a guide block 2084, a return spring 2083 and a round bar 2085, the cylindrical shell 2081 is vertically and fixedly installed at the bottom of the assembling plate 206, the fixed block 2082 is fixedly installed inside the cylindrical shell 2081, the guide block 2084 is slidably installed inside the cylindrical shell 2081, the return spring 2083 is installed inside the cylindrical shell 2081, one end of the return spring 2083 is abutted against the fixed block 2082, and the other end of the reset spring 2083 is inconsistent with the guide block 2084, the round bar 2085 is vertically and movably installed at the center of the bottom wall of the cylindrical shell 2081, the upper end of the round bar 2085 is fixedly connected with the bottom of the guide block 2084, and the bottom end of the round bar 2085 is fixedly connected with the upper part of the heating plate 207.

That is to say, the intelligent pyrograph machine that this embodiment provided mainly comprises bottom plate 1 and pyrograph mechanism 2, and pyrograph mechanism 2 mainly comprises shape of falling L fixed plate 201, first telescopic cylinder 202, loop bar 203, connecting rod 204, join in marriage dress board 206 and hot plate 207, when using, can place the printed matter of waiting to print the pyrograph on the upper portion of bottom plate 1, then utilize first telescopic cylinder 202 drive to join in marriage dress board 206 and drive hot plate 207 towards the printed matter motion of waiting to print the pyrograph, and will wait to print the pyrograph through the heat transfer seal scald on the printed matter, utilize first telescopic cylinder 202 action to replace artifical manual drive pyrograph mechanism 2 and carry out work, realized this pyrograph machine semi-automatization's mesh, can effectively reduce staff's working strength. In addition, the elastic members 208 are provided in four groups, the four groups of elastic members 208 are symmetrically distributed between the fitting plate 206 and the heating plate 207, each group of elastic pieces 208 consists of a cylindrical shell 2081, a fixed block 2082, a guide block 2084, a return spring 2083 and a round rod 2085, the elastic piece 208 has better elastic expansion performance under the mutual matching of the cylindrical shell 2081, the fixed block 2082, the guide block 2084, the return spring 2083 and the round rod 2085, therefore, the heating plate 207 can be effectively prevented from violently colliding with the upper portion of the base plate 1 by the elastic member 208, thereby effectively ensuring the service life of the heating plate 207, and in addition, the distance between the heating plate 207 and the upper part of the base plate 1 can be adjusted by adjusting the position of the connecting rod 204 inside the loop bar 203 through the bolt 205, therefore, the intelligent pyrograph machine is suitable for processing printed matters with different thicknesses to be printed with pyrographs, and has better practicability.

Example 2:

the difference between the present embodiment and embodiment 1 is that the upper portion of the bottom plate 1 is further provided with a feeding mechanism 3 matched with the pyrograph mechanism 2, as shown in fig. 6, the feeding mechanism 3 comprises a square enclosing plate 301, a sliding rod 302, a supporting platform 303, a fixed seat 304 and a second telescopic cylinder 305, the square enclosing plate 301 is fixedly installed on the upper portion of the bottom plate 1, the sliding rod 302 is horizontally and fixedly installed on the inner walls of the two ends of the square enclosing plate 301, and the sliding rod 302 is arranged along the length direction of the square enclosing plate 301, the supporting platform 303 is horizontally and slidably installed on the sliding rod 302, as shown in fig. 1, the upper surface of the supporting platform 303 is arranged in parallel with the upper surface of the heating plate 207, and the supporting platform 303 is located below the heating plate 207, the fixed seat 304 is fixedly installed at the bottom of the supporting platform 303, the second telescopic cylinder 305 is horizontally and fixedly installed on the inner wall of one end of the square enclosing plate 301, the telescopic end of the second telescopic cylinder 305 is fixedly connected with a side surface of the fixed seat 304, and the second telescopic cylinder 305 is used for driving the support platform 303 to do linear reciprocating motion along the slide rod 302, and the high-temperature-resistant foamed silica gel plate is fixedly installed on the upper portion of the support platform 303, as shown in fig. 4, two stations 306 are arranged on the upper portion of the high-temperature-resistant foamed silica gel plate.

That is to say, the intelligence pyrograph machine that this embodiment provided still has feed mechanism 3, and feed mechanism 3 comprises square bounding wall 301, slide bar 302, a supporting bench 303, fixing base 304 and second telescopic cylinder 305, when using, can utilize second telescopic cylinder 305 drive a supporting bench 303 to be straight reciprocating motion along slide bar 302 in the inside of square bounding wall 301, the realization is made a round trip to switch over the purpose of two stations 306, thereby realize that this intelligence pyrograph machine can uninterrupted duty, effectively improve work efficiency.

Example 3:

the difference between this embodiment and embodiment 2 is that the intelligent pyrograph machine further includes a control mechanism 4, as shown in fig. 2 and 5, the control mechanism 4 includes a mounting plate 401, a controller 402, a control switch 403, and a touch display screen 404, as shown in fig. 4, the mounting plate 401 is fixedly mounted on an outer wall of one end of the square enclosing plate 301 through a bracket 405, the controller 402 is fixedly mounted on one side surface of the mounting plate 401, the controller 402 is electrically connected to the first telescopic cylinder 202, the heating plate 207, and the second telescopic cylinder 305, the control switch 403 and the touch display screen 404 are both fixedly mounted on the other side surface of the mounting plate 401, and the control switch 403 and the touch display screen 404 are both electrically connected to the controller 402.

That is to say, the intelligent pyrograph machine provided by this embodiment further includes a control mechanism 4, and the control mechanism 4 is composed of a mounting plate 401, a controller 402, a control switch 403 and a touch display screen 404, and can set the operating parameters of the first telescopic cylinder 202, the heating plate 207 and the second telescopic cylinder 305 by using the touch display screen 404, and can input a control signal to the controller 402 through the control switch 403, so as to further control the first telescopic cylinder 202, the heating plate 207 and the second telescopic cylinder 305 to operate stably and orderly, in particular, when in use, a printed matter to be printed is placed on the two stations 306, a pyrograph to be printed is placed on the upper portion of the printed matter to be printed, then a control signal is input to the controller 402 by pressing the control switch, the controller 402 controls the second telescopic cylinder 305 to operate to drive the supporting platform 303 to move linearly along the sliding rod 302 in the square enclosing plate 301, the printed matter to be printed on the station 306 is pushed to the position under the heating plate 207, at the moment, the controller 402 controls the first telescopic cylinder 202 to move to drive the heating plate 207 to press on the printed matter to be printed, the pyrograph to be printed is hot-stamped on the printed matter through heat transfer printing, then the controller 402 controls the first telescopic cylinder 202 to move to drive the heating plate 207 to leave the printed matter, then the second telescopic cylinder 305 is controlled to move to drive the supporting table 303 to move to drive the printed matter which is printed with the pyrograph to deviate from the heating plate 207, the above actions are repeated, feeding can be carried out when one of the stations 306 deviates from the heating plate 207, and therefore uninterrupted feeding is achieved, the automation degree of the whole working process of finishing the pyrograph printing and the pyrograph by the pyrograph machine is high, and the working efficiency can be greatly improved.

Example 4:

the difference between this embodiment and embodiment 3 is that the control mechanism 4 further includes two proximity sensors 406, as shown in fig. 4, the two proximity sensors 406 are respectively and fixedly mounted on the upper portions of the end walls at both ends of the square enclosing plate 301, the two proximity sensors 406 are used for detecting the position of the support platform 303, and both the two proximity sensors 406 are electrically connected to the controller 402.

That is to say, the intelligent pyrograph machine provided by the embodiment further has two proximity sensors 406, and the two proximity sensors 406 are used for detecting the position of the support platform 303 so as to assist the controller 402 to accurately control the first telescopic cylinder 202 and the second telescopic cylinder 305 to accurately operate, thereby improving the stability of the pyrograph machine.

Example 5:

the present embodiment is different from embodiment 4 in that a heating wire electrically connected to the controller 402 is embedded in the heating plate 207, and the surface of the heating plate 207 is plated with an anti-sticking teflon coating.

That is to say, the intelligent pyrograph machine that this embodiment provided, wherein, the heating wire is used for providing the heating source for hot plate 207, and indisputable freon anti-sticking coating can prevent that the surface of hot plate 207 from gluing the foreign matter and influencing the use.

Example 6:

the difference between this embodiment and embodiment 5 lies in that the pyrograph mechanism 2 further includes two guide rods 209, as shown in fig. 3, two guide rods 209 are all vertically and movably installed on the top wall of the inverted L-shaped fixing plate 201, two guide rods 209 are symmetrically distributed on the periphery of the first telescopic cylinder 202, and the bottom ends of two guide rods 209 are all fixedly connected with the upper portion of the fitting plate 206, a stopper 210 is fixedly installed at the upper end of each guide rod 209, and a buffer spring 211 is sleeved on each guide rod 209, one end of the buffer spring 211 is abutted against the top wall of the inverted L-shaped fixing plate 201, and the other end of the buffer spring 211 is abutted against the bottom of the stopper 210.

That is to say, the intelligent pyrograph machine provided by the embodiment is more stable when the first telescopic cylinder 202 drives the heating plate 207 to act under the cooperation of the guide rod 209, the stopper 210 and the buffer spring 211, so that the operation of the pyrograph machine is more stable.

Example 7:

the difference between this embodiment and embodiment 6 is that four legs 101 are vertically and fixedly installed at the bottom of the bottom plate 1, as shown in fig. 7, the four legs 101 are symmetrically arranged, and the circular plate 102 is fixedly installed at the bottom ends of the four legs 101.

That is to say, the intelligent pyrograph machine provided by the embodiment enables the pyrograph machine to be stably placed under the action of the four legs 101 and the circular plate 102, and is convenient for enterprises to install and use.

The use method of the intelligent pyrograph machine provided by the invention comprises the following steps:

step one, placing a printed matter to be printed on a station 306 deviated from a heating plate 207, and placing a pyrograph to be printed on the upper part of the printed matter to be printed;

step two, inputting a control signal to the controller 402 by pressing the control switch 403, controlling the second telescopic cylinder 305 to move by the controller 402 to drive the supporting platform 303 to make a linear motion along the sliding rod 302 in the square enclosing plate 301, pushing the printed matter to be printed on the station 306 to be under the heating plate 207, controlling the first telescopic cylinder 202 to move by the controller 402 to drive the heating plate 207 to press on the printed matter to be printed, burning the pyrograph to be printed on the printed matter by thermal transfer printing, controlling the first telescopic cylinder 202 to move by the controller 402 to drive the heating plate 207 to leave the printed matter, controlling the second telescopic cylinder 305 to move to drive the supporting platform 303 to move to drive the printed matter with the pyrograph printed to deviate from the heating plate 207, taking the printed matter with the pyrograph printed matter printed off, placing a printed matter to be printed on the station 306 again, and placing the pyrograph to be printed on the upper portion of the printed matter to be printed, when the machine is to be stopped, the machine can be stopped by pressing the control switch 403 again.

It is noted that the controller 402 may be a PLC controller, and the proximity sensor 406 may be a laser sensor or an infrared sensor.

In general, the intelligent pyrograph machine provided by the invention can replace a manual pyrograph mechanism 2 to work, can effectively reduce the working strength of workers, can effectively prevent the heating plate from violently colliding with the upper part of the bottom plate, can effectively ensure the service life of the heating plate, can be suitable for processing printed matters to be printed and pyrographed with different thicknesses, has better practicability, can continuously feed materials, has higher automation degree in the whole working process of finishing the pyrograph, and can greatly improve the working efficiency.

The embodiments described above are described to facilitate an understanding and use of the invention by those skilled in the art. It will be readily apparent to those skilled in the art that various modifications to these embodiments may be made, and the generic principles described herein may be applied to other embodiments without the use of the inventive faculty. Therefore, the present invention is not limited to the above embodiments, and those skilled in the art should make improvements and modifications within the scope of the present invention based on the disclosure of the present invention.