Abstract:
The invention relates to a non-stop printing processing system with a plurality of stations, comprising a first processing unit and second processing unit; each of the processing units comprises a set of film supply devices, a pressure roller, a stripped roller and a cured device; the pressure roller, the stripped roller and the cured device are mounted by a lift type; the system comprises an impression barrel, when a substrate is processed, the impression barrel is positioned under the substrate, a processed substrate is positioned between a processing unit processing the substrate and the impression barrel. The invention also relates to a non-stop printing process with a plurality of stations. The invention utilizes one or more film supply devices of a processing device to alternately supply a film to achieve the effect of automatic roll change and simulation positioning.

Description:
TECHNICAL FIELD 
     The present invention relates to the field of machinery equipment for printing-packaging and material processing, and specifically relates to a multi-station non-stop printing processing system and processing technology. 
     BACKGROUND 
     At present, in the field of printing-packaging and material processing, there are many technologies for surface processing, including glossing, hot stamping and the like. The basic definition of glossing is to cover the printed surface with a transparent material so as to fulfill the purpose of protecting and strengthening the decoration effect. There are various glossing technical means, for example, a calendaring technology for heating and pressing the dried coating surface in order to improve the smoothness of the surface, a technology for coating the surface with a matte effect in order to improve the elegant effect, and even a technology in which a mold must be made additionally, and embossing and casting devices are used in cooperation to perform embossing and casting on the surface of a printed object, in order to realize fine embossing and transparent holographic processing on the surface of a material. These technologies have respective characteristics, and can protect materials or printed images or enhance the visual effect. In addition, the hot stamping technology is extensively used in the industries of packaging, printing and the like, and is often used on presswork or packages by multiple processing procedures. Thus, the glossing and hot stamping technologies are widely applied to surface processing of presswork of packaging decoration, albums, large decorative pictorial posters and the like. However, in the surface processing process, when the entire surface or a specified area of a material or a printed surface is processed with a specific coating by a specific coating procedure (e.g., offset printing, gravure printing, flexible printing, screen printing, etc.), a substantially consistent surface effect may appear, an entirely “Matte surface” or entirely “bright surface” effect. If a granular or embossed surface effect appears, even if the granular or embossed effect is not completely identical, it substantially can still be regarded as a random effect that the same texture instead of a positioning image appears in the specified area. In the print surface processing technologies pointed out in Chinese patent applications 01142655.1, 200410024849.9, 200420023306 and 200420071245.5, equipment can only achieve the surface effect of the same random texture on the different specified areas of a base material by single procedure as mentioned above. Moreover, in the aspect of cold stamping, the disclosed patents including Chinese patent applications 200610006830.0, 200620060491.X, 201110137504.4, 201110378502.4, 201310128775.2, 01242885.X, 200710075411.7 and 201010231830.7. British patent application GB2368313, U.S. Pat. No. 5,603,259 and the like do not disclose any content of stretching and positioning embossed or stamped films to meet the requirement for accurate positioning. 
     In the past, if more than one positioning glossing or hot stamping effect is to be achieved on the surface of the same material by surface processing, the specified areas of the surface of the material must be processed by the procedures corresponding to the effects in number. For example, the surface of the same base material must achieve three different effects including a bright surface effect, a matte effect and a holographic effect. Or, the surface of the same base material must have three different effects including gold stamping, silver stamping and laser stamping. For this problem, the disclosed Chinese patent application 200710044182.2 achieves accurate positioning by adopting a film stretching device and an electric eye positioning device, in view of the limitation of the above technology or the material itself and the problem that more than one station is needed for carrying out more than one processing procedure to achieve more than one different effect, so that the purpose of continuous glossing or hot stamping is achieved. Meanwhile, the problems that the current equipment or system, whether for glossing or hot stamping, available on the market has only a single function and each has more than one defect are solved. 
     Although the disclosed Chinese patent application 200710044182.2 can reduce the procedures by using the positioning function, the problems of time and material waste caused by stop and labor waste caused by reel change are still present. In today&#39;s increasingly fiercer competition, the costs of labor and materials are increasingly higher as time is very precious. Therefore, it is very necessary to develop an invention capable of solving the problems of low production efficiency, high production cost, high rejection rate and the like caused by stop for reel change. 
     SUMMARY OF THE INVENTION 
     An object of the present invention is to overcome the shortcomings of the prior art, combine the technologies of different fields of processing machinery, automatic control and the like, and provide a multi-station non-stop printing processing system and processing technology. The processing system can cast or cold-stamp the texture or evaporated layer of a film onto a base material without stop to save labor, reduce the loss and improve the efficiency; equipment, due to its small size, can be combined with and incorporated to the current single-piece or web-fed printing equipment or glossing machine production line to achieve the advantages of reducing procedures, reducing the production cost and time and improving the production efficiency; in addition, the processing system also has a positioning processing function. 
     The present invention solves the technical problems by adopting the following technical solutions: 
     A multi-station non-stop printing processing system includes a first processing unit, a second processing unit and an impression cylinder, wherein each processing unit includes an independent set of a film supply device, a pressure roller, a stripping roller and a curing device, each film supply device includes a reeling device and an unreeling device which are independently driven and can rotate forwardly and reversely, and the pressure roller, the stripping roller and the curing device are installed in a lifting manner; when a base material is processed, the impression cylinder is located below the base material, and the processed base material is located between the processing units for processing the base material and the impression cylinder. 
     Further, in the printing processing system described above, the number of the impression cylinder is one, and the first processing unit and the second processing unit share the impression cylinder. 
     Further, in the printing processing system described above, the impression cylinder includes a first impression cylinder and a second impression cylinder, the first processing unit uses the first impression cylinder, and the second processing unit uses the second impression cylinder. 
     Further, in the printing processing system described above, each processing unit further includes a main wallboard and a secondary wallboard, the secondary wallboard can move on the main wallboard, and the pressure roller, the stripping roller and the curing device in each processing unit are all installed on the respective secondary wallboard. 
     Further, in the printing processing system described above, a slide rail is arranged between the main wallboard and the secondary wallboard, and the secondary wallboard moves up and down by means of a lifting control device in cooperation with the slide rail, so that the film processed by each independent processing unit and the impression cylinder can conveniently run in different directions without rubbing because the secondary wallboard can move up and the film can thus be separated from the impression cylinder. 
     Further, in the printing processing system described above, the curing device is fixedly installed on the secondary wallboard. 
     Further, in the printing processing system described above, each processing unit further includes a pressure roller lifting control device and a stripping roller lifting control device, and through the pressure roller lifting control device and the stripping roller lifting control device, the pressure roller and the stripping roller can be respectively installed on the secondary wallboard in a lifting manner. 
     Further, in the printing processing system described above, each lifting control device can be a cylinder, a mechanical cam or an electronic cam. 
     Further, in the printing processing system described above, the film supply device in each processing unit is provided with a positioning stretching device between the pressure roller and the reeling device and a positioning stretching device between the pressure roller and the unreeling device to ensure the stable tension of films in the reeling and unreeling directions. 
     Further, in the printing processing system described above, the first processing unit is provided with at least one positioning stretching device for a film with a recognizable positioning mark or/and a different texture, and the at least one positioning stretching device forms a positioning processing system. 
     Further, in the printing processing system described above, the second processing unit is provided with at least one positioning stretching device for a film with a recognizable positioning mark or/and a different texture, and the at least one positioning stretching device forms a positioning processing system. 
     Further, in the printing processing system described above, the positioning stretching device includes a first electric eye device, a first group of self-powered compaction rollers and a second group of self-powered compaction rollers, wherein the first electric eye device is a positioning or electric eye device capable of detecting the recognizable positioning mark and the edge of the film, the two compaction rollers in the first group press against each other and rotate at the velocity smaller than or equal to the linear velocity of the impression cylinder, and the two compaction rollers in the second group press against each other. 
     Further, in the printing processing system described above, each processing unit is installed through connection with one or more web-fed printing devices, single-piece printing devices or coating unit devices. 
     Further, in the printing processing system described above, when the processing unit is connected with one single-piece printing device, the gripping teeth on the impression cylinder of the processing unit adopt the ones with vacuum negative pressure adsorption devices. 
     Further, the printing processing system described above is configured to work according to the following steps: 1, the first processing unit is thrown on to the impression cylinder for processing, at the moment, the unreeling device of the first processing unit unreels and the reeling device of the first processing unit reels, and the second processing unit is thrown off the impression cylinder and stands by; step 2, the first processing unit is still thrown on to the impression cylinder for processing, at the moment, the unreeling device of the second processing unit unreels, the reeling device of the second processing unit reels, and the second processing unit is prepared to be thrown on to the impression cylinder; step 3, the second processing unit is thrown on to the impression cylinder for processing, the unreeling device of the second processing unit unreels and the reeling device of the second processing unit reels, the first processing unit is thrown off the impression cylinder and re-reels, and the reeling device of the first processing unit unreels and the unreeling device reels at the moment: step 4, the second processing unit is still thrown on to, the impression cylinder for processing, at the moment, the unreeling device of the first processing unit unreels, the reeling device of the first processing unit reels, and the first processing unit is prepared to be thrown on to the impression cylinder; step 5, the first processing unit is thrown on to the impression cylinder for processing, the unreeling device of the first processing unit unreels and the reeling device of the first processing unit reels, the second processing unit is thrown off the impression cylinder and re-reels, and the reeling device of the second processing unit unreels and the unreeling device of the second processing unit reels at the moment; and steps 1 to 5 are repeated cyclically. 
     Further, the printing processing system described above is configured as follows: in step 2, when the unreeling, device in the first processing unit is to unreel to the proximity of the axis and the reeling device is to fully reel, the unreeling device and the reeling device in the second processing unit are accelerated, until the second processing unit is thrown on to the impression cylinder when the linear velocity of the film is same as that of the revolving speed of the impression cylinder; and in step 4, when the unreeling device in the second processing unit is to unreel to the proximity of the axis and the reeling device is to fully reel, the unreeling device and the reeling device in the first processing unit are accelerated, until the first processing unit is thrown on to the impression cylinder when the linear velocity of the film is same as that of the revolving speed of the impression cylinder. 
     Further, the printing processing system described above is configured to work in the following manner: a base material is conveyed or dragged to the first processing unit, the pressure roller of the first processing unit comes into fit with the impression cylinder, that is, the first processing unit is thrown on to the impression cylinder, the film supplied by the unreeling device of the first processing unit comes into fit with the base material at the rotating junction of the pressure roller of the first processing unit and the impression cylinder, and the reeling device in the first processing unit strips the film off the surface of the base material and rolls back; when the unreeling device in the first processing unit is to unreel to the proximity of the axis and the reeling device is to fully reel, the unreeling device and the reeling device in the second processing unit are accelerated, and when the linear velocity of the film is same as that of the revolving speed of the impression cylinder, the pressure roller, the stripping roller and the curing device fixed on the secondary wallboard of the second processing unit simultaneously descend, so that the pressure roller comes into fit with the impression cylinder, that is, the second processing unit is thrown on to the impression cylinder; at the moment, the pressure roller, the stripping roller and the curing device fixed on the secondary wallboard of the first processing unit simultaneously ascend; when the secondary wallboard of the first processing unit moves till the straight line between the bottoms of the pressure roller and the stripping roller is higher than the highest point of the impression cylinder, the unreeling device of the first processing unit at the moment accomplishes reeling before unreeling of the unreeling device of the second processing unit is accomplished, and rests and waits for the unreeling device in the second processing unit; and when the unreeling device in the second processing unit is to unreel to the proximity of the axis and the reeling device is to fully reel, the unreeling device of the first processing unit starts unreeling again, so that the processing units cyclically work between the above two phases. 
     Further, in the printing processing system described above, the film supplied by each film supply device has respective different conveying line. 
     A multi-station non-stop printing processing technology includes: providing a first processing unit and a second processing unit, wherein each of the provided processing units includes an independent set of a film supply device, a pressure roller, a stripping roller and a curing device; each of the provided film supply devices includes a reeling device and an unreeling device which are independently driven and can rotate forwardly and reversely; installing the provided pressure roller, stripping roller and curing device in a lifting manner; and providing an impression cylinder which is configured such that when a base material is processed, the impression cylinder is located below the base material, and the processed base material is located between the processing units for the base material and the impression cylinder. 
     Further, the printing processing technology described above further includes: installing the pressure roller, the stripping roller and the curing device in each processing unit onto a secondary wallboard capable of moving on a main wallboard; and providing a slide rail between the main wallboard and the secondary wallboard, so that the secondary wallboard moves up and down by means of a lifting control device in cooperation with the slide rail installed on the main wallboard, and thus, the film processed by each independent processing unit and the impression cylinder can conveniently run in different directions without rubbing because the secondary wallboard can move up and then the film can be separated from the impression cylinder. 
     Further, the printing processing technology described above further includes: step 1, the first processing unit is thrown on to the impression cylinder for processing, at the moment, the unreeling device of the first processing unit unreels and the reeling device of the first processing unit reels, and the second processing emit is thrown off the impression cylinder and stands by; step 2, the first processing unit is still thrown on to the impression cylinder for processing, at the moment, the unreeling device of the second processing unit unreels, the reeling device of the second processing unit reels, and the second processing unit is prepared to be thrown on to the impression cylinder; step 3, the second processing unit is thrown on to the impression cylinder for processing, the unreeling device of the second processing unit unreels and the reeling device of the second processing unit reels, the first processing unit is thrown off the impression cylinder and re-reels, and the reeling device of the first processing unit unreels and the unreeling device reels at the moment; step 4, the second processing unit is still thrown on to the impression cylinder for processing, at the moment, the unreeling device of the first processing unit unreels, the reeling device of the first processing unit reels, and the first processing unit is prepared to be thrown on to the impression cylinder; step 5, the first processing unit is thrown on to the impression cylinder for processing, the unreeling device of the first processing unit unreels and the reeling device of the first processing unit reels, the second processing unit is thrown off the impression cylinder and re-reels, and the reeling device of the second processing unit unreels and the unreeling device of the second processing unit reels at the moment: and steps 1 to 5 are repeated cyclically. 
     Further, the printing processing technology described above further includes: in step 2, when the unreeling device in the first processing unit is to unreel to the proximity of the axis and the reeling device is to fully reel, the unreeling device and the reeling device in the second processing unit are accelerated, until the second processing unit is thrown on to the impression cylinder when the linear velocity of the film is same as that of the revolving speed of the impression cylinder; and in step 4, when the unreeling device in the second processing unit is to unreel to the proximity of the axis and the reeling device is to fully reel, the unreeling device and the reeling device in the first processing unit are accelerated, until the first processing unit is thrown on to the impression cylinder when the linear velocity of the film is same as that of the revolving speed of the impression cylinder. 
     The present invention further relates to a multi-station non-stop printing processing technology, including the following steps: (1) a base material with an uncured coating is conveyed or dragged to the first processing unit, a film material with a surface texture supplied by the unreeling device of the first processing unit comes into fit with the base material completely at the rotating junction of the pressure roller and the impression cylinder, and the first processing unit is located at a position thrown on to the impression cylinder at the moment; and (2) after the plastic film with the surface texture and the base material with the uncured coating pass through the rotating junction of the pressure roller and the impression cylinder, complete fitting of the base station and the film is ensured, the fitted film and base material are conveyed to a position below the curing device, the coating on the base material is cured by the curing device via the plastic film, and the cured coating at the moment is presented on the base material in a manner reverse to the surface texture of the film; then the reeling device in the first processing unit strips the plastic film of the surface of the base material and rolls back; and finally, the base material is conveyed to a device and the base material after surface treatment is conveyed to a reception unit. 
     The present invention further relates to a multi-station non-stop printing processing technology, including the following steps: (I) a base material with uncured adhesive is conveyed or dragged to the first processing unit by a conveying device or a dragging device, the hot-stamped film supplied by the unreeling device of the first processing unit comes into fit with the base material completely at the rotating junction of the pressure roller and the impression cylinder, and the first processing unit is located at a position thrown on to the impression cylinder at the moment; and (2) after the hot-stamped film and the base material with uncured adhesive pass through the rotating junction of the pressure roller and the impression cylinder, complete fitting of the base station and the hot-stamped film is ensured, the fitted film and base material are conveyed to a position below the curing device, the adhesive on the base material is cured by the curing device via the hot-stamped film, and the cured adhesive at the moment is combined with a sprayed aluminum layer on the surface of the film; then the reeling device in the first processing unit strips the hot-stamped film off the surface of the base material and rolls back, and the sprayed aluminum layer with metal feeling is presented at the original position of the adhesive on the base material at the same time; and finally, the base material is conveyed to a device and the base material after surface treatment is conveyed to a reception unit. 
     Further, the technology also includes the following steps: when the unreeling device in the first processing unit is to unreel to the proximity of the axis and the reeling device is to fully reel, the system accelerates the unreeling device and the reeling device in the second processing unit by operation of a computer or control of a sensor switch, and when the linear velocity of the film is same as that of the revolving speed of the impression cylinder, the pressure roller, the stripping roller and the curing device fixed on the secondary wallboard of the second processing unit simultaneously descend, so that the pressure roller comes into fit with the impression cylinder, that is, the second processing unit is thrown on to the impression cylinder; at the moment, the pressure roller, the stripping roller and the curing device fixed on the secondary wallboard of the first processing unit simultaneously ascend; when the secondary wallboard till the straight line between the bottoms of the pressure roller and the stripping roller is higher than the highest point of the impression cylinder, the unreeling device of the first processing unit at the moment accomplishes reeling before unreeling of the unreeling device of the second processing unit is accomplished, and rests and waits for the unreeling device in the second processing unit; and when the second processing unit is to accomplish unreeling, the first processing unit starts unreeling again, so that the processing units cyclically work. 
     Further, the technology also includes the following step: when the base material is too thick so that the pressure roller jumps when the leading edge of the base material enters the junction, the pressure roller can be lifted to the height equivalent to the thickness of the base material under the operation of the computer or the control of the sensor switch before the base material enters the film supply device. 
     Further, the technology also includes the following step: the processing technology is used in combination with a web-fed printing device, a single-piece printing device or a glossing unit device. 
     Further, the technology also includes the following step: the first processing unit and the second processing unit share one impression cylinder to interactively perform the above procedures. 
     Further, the technology also includes the following step: the first processing unit and the second processing unit use respective impression cylinders to interactively perform the above procedures. 
     In addition to the contents disclosed in other parts of the specification and the contents that those skilled in the art can understand after reading the specification, the advantages and beneficial effects of the present invention at least further include all of or any of the following contents: 
     1. The multi-station non-stop printing processing system of the present invention has two (more than one) processing units which operate independently, each processing unit has an unreeling device and a reeling device, and each of the reeling and unreeling devices has a respective independent driving mechanism, so that the reeling and unreeling devices can operate independently and rotate forwardly and reversely, and thus functional conversion of unreeling and reeling is realized. The prior art does not give such enlightenment, for example, the existing Chinese patent applications 200910037225.3, 200910037193.7, 200820147297.4, 200810026337.4 and 200420071245.5, and Chinese patent applications 200620041821, 200410015978.1 and 200710044182.2 only involve one unreeling device and one reeling device, the reeling device is only used for reeling, the unreeling device is only used for unreeling, and the driving way of the above reeling and unreeling devices is not mentioned, although Chinese patent application 201120026325.9 mentions a double-station unreeling device and a double-station reeling device, however in two unreeling devices, after the first roll of paper unreels completely, the second roll of paper still travels along the way where the first roll of paper runs, that is, there is only one conveying line, while the present invention differs in that the film in each film supply device has a respective conveying line, so that uninterrupted printing processing is realized, and the present invention is fundamentally different in design thought and makes a geometric level of progress on the technical effects. 
     2. In the multi-station non-stop printing processing system of the present invention, the pressure rollers, the stripping rollers and the curing devices are all lifting mechanisms and can move up and down, so that automatic reel change is realized without stop. Chinese patent application 200910037225.3 already discloses a clearance adjusting mechanism for adjusting a clearance between a stripping guide roller and a lower throw-on cylinder according to the specific thickness of a printed material and the thickness of a pressed film, but it is used for solving the quality problem in the stripping process. In Chinese Patent application 200710044182.2, a pressure roller can be installed on a secondary wallboard module which can move up till the straight line between the bottoms of the pressure roller and a stripping roller is higher than the highest point of an impression cylinder, but it is intended to solve the problem of avoiding waste or scratch on the uncured part of the surface of the base material when the system is not used or throwing on is not needed, which is different from the intention of the present invention to exchange the rotating directions of the reeling device and the unreeling device and avoiding rubbing between the film and the impression cylinder after the secondary wallboard ascends. 
     3. hi the multi-station non-stop processing system and processing technology disclosed by the present invention, films are alternatively supplied by the film supply device of more than one processing unit, so that an effect of automatic reel change is realized without stop; moreover, the effect of simulative positioning is provided, thereby solving the problem of time, material and labor waste caused by stop for reel change, reducing the production cost and the rejection rate, and improving the production efficiency; therefore, the system and the technology can be applied to various products with high added values. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a structural schematic diagram of the present invention illustrating the first processing unit is thrown on for processing, the second processing unit is thrown off and stands by, and the first processing unit and the second processing unit share one impression cylinder; 
         FIG. 2  is a structural schematic diagram of the present invention illustrating the first processing unit is thrown on and its unreeling is nearly completed, the second processing unit is thrown on at the same speed, and the first processing unit and the second processing unit share one impression cylinder; 
         FIG. 3  is a structural schematic diagram of the present invention illustrating the second processing unit is thrown on for processing, the first processing unit is thrown off and re-reels at a high speed, and the first processing unit and the second processing unit share one impression cylinder; 
         FIG. 4  is a structural schematic diagram of the present invention illustrating the first processing unit is thrown on for processing, the second processing unit is thrown off and re-reels at a high speed, and the first processing unit and the second processing unit share one impression cylinder; 
         FIG. 5  is a structural schematic diagram of the present invention illustrating the first processing unit is thrown on for processing, the second processing unit is thrown off and stands by, and the first processing unit and the second processing unit use respective impression cylinders; 
         FIG. 6  is a structural schematic diagram of the present invention illustrating the first processing unit is thrown on and its unreeling is nearly completed, the second processing unit is thrown on at the same speed, and the first processing unit and the second processing unit use respective impression cylinders; 
         FIG. 7  is a structural schematic diagram of the present invention illustrating the second processing unit is thrown on for processing, the first processing unit is thrown off and re-reels at a high speed, and the first processing unit and the second processing unit use respective impression cylinders; 
         FIG. 8  is a structural schematic diagram of the present invention illustrating the first processing unit is thrown on for processing, the second processing unit is thrown off and re-reels at a high speed, and the first processing unit and the second processing unit use respective impression cylinders; 
         FIG. 9  is a structural schematic diagram of the present invention with a positioning stretching function, illustrating the first processing unit is thrown on for processing, the second processing unit is thrown off and stands by, and the first processing unit and the second processing unit use respective impression cylinders; 
         FIG. 10  is a structural schematic diagram of the present invention with a positioning stretching function, illustrating the first processing unit is thrown on and its unreeling is nearly completed, the second processing unit is thrown on at the same speed, and the first processing unit and the second processing unit use respective impression cylinders. 
         FIG. 11  is a structural schematic diagram of the present invention with a positioning stretching function, illustrating the second processing unit is thrown on for processing, the first processing unit is thrown off and re-reels at a high speed, and the first processing unit and the second processing unit use respective impression cylinders; 
         FIG. 12  is a structural schematic diagram of the present invention with a positioning stretching function, illustrating the first processing unit is thrown on for processing, the second processing unit is thrown off and re-reels at a high speed, and the first processing unit and the second processing unit use respective impression cylinders; 
         FIG. 13  is a structural schematic diagram of an embodiment of the present invention illustrating a coating unit is configured between the first processing unit and the second processing unit, and the first processing unit and the second processing unit use respective impression cylinders; 
         FIG. 14  is a structural schematic diagram of a processing system of the present invention for surface processing in the combination of the processing units and an offset printing machine; 
         FIG. 15  is an enlarged view of locations of a pressure roller, a stripping roller and a curing device in a processing unit of the present invention. 
     
    
    
     LIST OF REFERENCE SIGNS 
       1 —film unreeling device of first processing unit,  2 —film reeling device of first processing unit,  3 —curing device of first processing unit.  4 —pressure roller of first processing unit,  5 —stripping roller of first processing unit,  6 —impression cylinder,  7 —base material with uncured coating,  8 —film unreeling device of second processing unit,  9 —film reeling device of second processing unit,  10 —curing device of second processing unit.  11 —pressure roller of second processing unit.  12 —stripping roller of second processing unit,  13 —second impression cylinder,  14 —A group of compaction rollers of first processing unit.  15 —first electric eye device of first processing unit,  16 —B group of compaction rollers of first processing unit,  18 —A group of compaction rollers of second processing unit,  19 —first electric eye device of second processing unit,  20 —B group of compaction rollers of second processing unit.  22 —coating unit,  23 —offset printing unit,  24 —stripping roller lifting control device,  25 —secondary wallboard lifting control device,  26 —stripping roller lifting control device,  27 —main wallboard,  28 —secondary wallboard. 
     DETAILED DESCRIPTION OF THE EMBODIMENTS 
     The present invention will be farther described with specific embodiments below, and the following embodiments are only descriptive but not limiting, and the protection scope of the present invention is not limited thereby. 
       FIG. 1  shows an embodiment of a multi-station non-stop printing processing system disclosed by the present invention. The system includes more than one processing unit, and in this embodiment, the system includes a first processing unit and a second processing unit. 
     The first processing unit described above includes an independent set of a film supply device, a pressure roller  4 , a stripping roller  5  and a curing device  3 ; and the second processing unit includes an independent set of a film supply device, a pressure roller  11 , a stripping roller  12  and a curing device  10 . The curing device is located between the respective pressure roller and stripping roller, the curing device is an ultraviolet or electron beam curing device, and the quantity of the curing device can be one or more. Those skilled in the art understand that the stripping roller is used for separating a base material from a film in an unreeling device. 
     The film supply device of the first processing unit described above includes a reeling device  2  and an unreeling device  1  which are independently driven and can rotate forwardly and reversely; and the film supply device of the second processing unit also includes a reeling device  9  and an unreeling device  8  which are independently driven and can rotate forwardly and reversely. Since the reeling devices and the unreeling devices can rotate forwardly and reversely in two directions, the reeling devices can also unreel, and the unreeling devices can also reel. 
     The pressure rollers, the stripping rollers and the curing devices of the first processing unit and the second processing unit described above are installed in a lifting manner, wherein the lifting installation here indicates ascending and descending is possible relative to the base material to be processed. As shown in  FIG. 15 , the pressure roller  4 , the stripping roller  5  and the curing device  3  in the first processing unit are installed on a group of secondary wallboard  28 . The secondary wallboard  28  can move on a main wallboard  27 . Exemplarily, a slide rail is arranged between the main wallboard  27  and the secondary wallboard  28 , and the secondary wallboard  28  moves up and down by means of a lifting control device  25  in cooperation with the slide rail, installed on the main wallboard  27  to move up and down, that is, the lifting, control device  25  can control the pressure roller, the stripping roller  5  and the curing device  3  to ascend and descend, so that the film in the first processing unit and the impression cylinder can conveniently run in different directions without rubbing because the secondary wallboard  28  can move up and then the film can be separated from the impression cylinder. 
     Exemplarily, the pressure roller  4  and the stripping roller  5  can be installed on the secondary wallboard  28  via lifting control devices  24  and  26  and thus can independently ascend and descend relative to the secondary wallboard. Setting separate lifting control devices for the pressure roller and the stripping roller at least has the advantage that the lifting positions of the pressure roller and the stripping roller can be independently adjusted without lifting the secondary wallboard, so that the adjustment is more convenient; in addition, providing respective lifting control devices for the secondary wallboard, the pressure roller and the stripping roller can also effectively avoid the problem of poor stability caused by too long a lifting distance when a single lifting device controls lifting. The curing device  3  can be directly fixedly installed on the secondary wallboard  28 . 
     Each lifting control device can be a cylinder, a mechanical cam or an electronic cam. The second processing unit has the same structure as the first processing unit, and thus is not described here. The main wallboards of the two processing units can be the same one or different ones. 
     The printing processing system of this embodiment further includes an impression cylinder  6  below the base material. In this embodiment, the two processing units share one impression cylinder. When possible, it is particularly advantageous to share one impression cylinder, because it can significantly reduce the size of the printing processing system, facilitate the connection between this system and other unit and greatly reduce the cost. 
       FIG. 5  shows a structural schematic diagram illustrating each of the two processing units uses one impression cylinder, wherein the second processing unit has an impression cylinder  13 . When the installation space is relatively small, one impression cylinder is used, which needs to be a large-radius impression cylinder because two processing units are arranged thereon so as to cooperate with the two processing units to process the base material; and when the installation space is large enough, two small-radius impression cylinders can be used, and a processing unit is arranged on each impression cylinder, so that processing, of the base material is accomplished. Whichever of one large-radius impression cylinder or two small-radius impression cylinders can be used for single-piece and web-fed printing. However, the surface processing system with one large-radius impression cylinder is more suitable for web-fed printing, and the surface processing system with two small-radius impression cylinders is more suitable for single-piece printing. 
     In the embodiment shown in  FIG. 9 , the film supply device in each processing unit is provided with a positioning stretching device between the pressure roller and the reeling device and a positioning stretching device between the pressure roller and the unreeling device to ensure the stable tension of films in the reeling and unreeling directions. Optionally, each of the first processing unit and the second processing unit described above is provided with at least one positioning stretching device for a film with a recognizable positioning mark or/and a different texture, and the at least one positioning stretching device forms a positioning processing system. As shown in  FIG. 9 , in the film supply device of the first processing unit, a positioning stretching device is arranged between the pressure roller and the unreeling device, and is composed of a first electric eye device  15 , an A group of compaction rollers  14  and a B group of compaction rollers  16 . The first electric eye device is a positioning or electric eye device capable of detecting the recognizable positioning mark and the edges of the film. The two compaction rollers in the A group of self-powered compaction rollers press against each other and rotate at the velocity smaller than or equal to the linear velocity of the impression cylinder, and the two compaction rollers in the B group of self-powered compaction rollers press against each other. Similarly, in the film supply device of the second processing unit, a positioning stretching device is arranged between the pressure roller and the unreeling device, and is composed of a first electric eye device  19 , an A group of compaction rollers  18  and a B group of compaction rollers  20 , and the positioning stretching device has the same structure as that in the first processing unit. The positioning stretching device at least can realize a plastic sheet and a relative positioning mark on the film arrive at the junction synchronously and achieve the beneficial effects of accurate positioning and film saving. 
     Each processing unit described above can be connected with one or more than one web-fed printing device, single-piece printing device or coating device for installation. The coating device generally refers to a common commercial coating or printing device available on the market, may include flexible printing, gravure printing, offset printing and ink-jet coating devices and the like, and can be used for glossing and printing. The gripping teeth on the impression cylinder of the processing unit connected with the single-piece printing device for installation may adopt the ones with vacuum negative pressure adsorption devices, thereby avoiding collision with the pressure roller and the film. 
       FIG. 13  shows a structural schematic diagram of an embodiment of a processing system connected with a coating device  22 .  FIG. 14  shows a structural schematic diagram of an embodiment of a processing system for surface processing in the combination with the processing unit and an offset printing machine  23 . When a paper base material passes through the offset printing unit  23 , the offset-printed uncured paper base material completely comes into fit with the film material having a surface texture supplied by the unreeling device  1  of the processing unit at the rotating junction of the pressure roller and the impression cylinder. Then, the fitted film and paper base material are conveyed to a position below the curing device  3 , the coating on the paper base material is cured by the curing device via the film, the cured coating at the moment is presented on the paper base material in a manner reverse to the surface texture of the film, and then the reeling device  2  in the processing unit strips the plastic film off the surface of the paper base material and rolls back. Finally, the cylinder conveys the paper after surface treatment to a paper reception unit or other processing unit. 
     The specific structure of each embodiment of the printing processing system of the present invention will be understood more clearly via the description of the printing processing technology below. 
     A multi-station non-stop printing processing technology, which is a casting printing technology, includes the following steps
     (1) A base material with an uncured coating is conveyed or dragged to the first processing unit, a film material with a surface texture supplied by the unreeling device of the first processing unit comes into fit with the base material completely at the rotating junction of the pressure roller and the impression cylinder, and the first processing unit is located at a position thrown on to the impression cylinder at the moment.   (2) After the plastic film with the surface texture and the base material with the uncured coating pass through the rotating junction of the pressure roller and the impression cylinder, complete fitting of the base station and the film is ensured, the fitted film and base material are conveyed to a position below the curing device, the coating on the base material is cured by the curing device via the plastic film, and the cured coating at the moment is presented on the base material in a manner reverse to the surface texture of the film; then the reeling device in the first processing unit strips the plastic film off the surface of the base material and rolls back, and finally, the base material is conveyed to a device (not shown in the figures) and the base material after surface treatment is conveyed to a reception unit.   (3) When the unreeling device in the first processing unit is to unreel to the proximity of the axis and the reeling device is to fully reel, the system accelerates the unreeling device and the reeling device in the second processing unit by operation of a computer or control of a sensor switch, and when the linear velocity of the film is same as that of the revolving speed of the impression cylinder, the pressure roller, the stripping roller and the curing device fixed on the secondary wallboard of the second processing unit simultaneously descend, so that the pressure roller comes into fit with the impression cylinder, that is, the second processing unit is thrown on to the impression cylinder; at the moment, the pressure roller, the stripping roller and the curing device fixed on the secondary wallboard of the first processing unit simultaneously ascend; when the secondary wallboard of the first processing unit moves till the straight line between the bottoms of the pressure roller and the stripping roller is higher than the highest point of the impression cylinder, the unreeling device of the first processing unit at the moment accomplishes reeling before unreeling of the unreeling device of the second processing unit is accomplished, and rests and waits for the unreeling device in the second processing unit; and when the second processing unit is to accomplish unreeling, the first processing unit starts unreeling again, so that the processing units cyclically work. The first processing unit and the second processing unit described above can share one impression cylinder to interactively perform the above procedures. If necessary, the first processing unit and the second processing unit described above can also use respective impression cylinders to interactively perform the above procedures.   (4) When the base material is too thick so that the pressure roller jumps when the &lt;leading edge of the base material enters the junction, the pressure roller can be lifted to the height equivalent to the thickness of the base material under the operation of the computer or the control of the sensor switch before the base material enters the film supply device.   (5) The base material is conveyed to a device (e.g., a conveying belt, a drum, etc.) and the base material after surface treatment is conveyed to a reception unit, or the base material is farther connected to a web-fed printing device or a single-piece printing device or a glossing unit device or other processing unit. Thus, the reel change between the first processing unit and the second processing unit is repeated cyclically in sequence, automatic reel change is realized without stop, and the surface treatment of the paper is finally accomplished by the processing units in the processing system of the present invention.   

     A multi-station non-stop printing processing technology, which is a hot stamping processing technology, includes the following steps:
     (1) a base material with uncured adhesive is conveyed or dragged to the first processing unit by a conveying device such as a conveying belt, gripping teeth and the like or a dragging device, the hot-stamped film supplied by the unreeling device of the first processing unit comes into fit with the base material completely at the rotating junction of the pressure roller and the impression cylinder, and the first processing unit is located at a position thrown on to the impression cylinder at the moment; and   (2) after the hot-stamped film and the base material with uncured adhesive pass through the rotating junction of the pressure roller and the impression cylinder, complete fitting of the base station and the hot-stamped film is ensured, the fitted film and base material are conveyed to a position below the curing device, the adhesive on the base material is cured by the curing device via the hot-stamped film, and the cured adhesive at the moment is combined with a sprayed aluminum layer on the surface of the film; then the reeling device in the first processing unit strips the hot-stamped film off the surface of the base material and rolls back, and the sprayed aluminum layer with metal feeling is presented at the original position of the adhesive on the base material at the same time; and finally, the base material is conveyed to a device and the base material after surface treatment is conveyed to a reception unit.   

     The film can be changed according to needs in the hot stamping process. If the secondary impression position can avoid the used or transferred position, the film can be further used. If the secondary impression position cannot avoid the used or transferred position, the film needs to be changed. Other procedures are the same as those in the casting printing technology. 
     The structure and the cooperative relation of the processing system of the present invention can be understood more clearly in combination with the application examples of the processing technology of the present invention below. 
       FIGS. 1 to 4  show an embodiment of application of the processing technology of the present invention: 
     A piece of paper, after subjected to web-fed printing and glossing, enters the processing system simultaneously with a film having a surface texture, the second processing unit at the moment is still and is located at a position thrown off the impression cylinder for standby, the paper  7  with an uncured coating is dragged to completely fit the film material having the surface texture supplied by the unreeling device  1  in the first processing unit at the rotating junction of the pressure roller  4  and the impression cylinder  6 . Then, the fitted film and paper  7  are conveyed to a position below the curing device  3 , the coating on the paper  7  is cured by the curing device via the film, the cured coating at the moment is presented on the paper in a manner reverse to the surface texture of the film, and then the reeling device  2  in the first processing unit strips the film off the surface of the paper  7  and rolls back, as seen in  FIG. 1 . Finally, the cylinder conveys the paper after surface treatment to a paper reception unit or other processing unit. 
     When the unreeling device  1  in the first processing unit is to unreel to the proximity of the axis and the reeling device  2  is to fully reel, the processing system accelerates the unreeling device  8  and the reeling device  9  in the second processing unit by operation of a computer or control of a sensor switch, and when the linear velocity of the film is same as that of the revolving speed of the impression cylinder  6 , the pressure roller  11 , the stripping roller  12  and the curing device  10  installed on the secondary wallboard simultaneously descend, so that the pressure roller  11  comes into fit with the impression cylinder  6 , that is, the second processing unit is thrown on to the impression cylinder, as seen in  FIG. 2 . Then, the pressure roller  4 , the stripping roller  5  and the curing device  3  fixed on the secondary wallboard  28  in the first processing unit ascend; when the secondary wallboard moves till the straight line between the bottoms of the pressure roller  4  and the stripping roller  5  is higher than the highest point of the impression cylinder  6 , the reeling device  2  is independently driven to unreel at a speed higher than that of the impression cylinder  6 , and the unreeling device  1  re-reels at a high speed. Simultaneously, the paper  7  with the uncured coating is continuously conveyed or dragged to completely fit the film supplied by the unreeling device in the second processing unit at the rotating junction of the pressure roller  11  and the impression cylinder  6 . After the paper is completely fitted with the film, the fitted film and paper are conveyed to a position below the curing device  10 , the coating on the paper is cured by the curing device via the film, the cured coating at the moment is presented on the paper in a manner reverse to the surface texture of the film, and then the reeling device  9  in the second processing unit strips the film off the surface of the paper and rolls back, as seen in  FIG. 3 . Finally, the cylinder conveys the paper after surface treatment to the paper reception unit or other processing unit. 
     When the unreeling device  8  in the second processing unit is to unreel to the proximity of the axis and the reeling device  9  is to fully reel, the pressure roller  4  of the first processing unit is thrown on to the impression cylinder  6  by adopting the above method, meanwhile, the pressure roller  11  of the second processing device is thrown off the impression cylinder  6 , and the unreeling device  8  in the second processing unit starts high-speed re-reeling, as seen in  FIG. 4 , to prepare for next unreeling when unreeling of the unreeling device  1  of the first processing unit is to be completed. Thus, the reel change between the first processing unit and the second processing unit is repeated cyclically in sequence, automatic reel change is realized without stop, and the surface treatment of the paper is finally accomplished by the processing units in the system. 
     The judgment criterion that the unreeling device in the first processing unit is to unreel to the proximity of the axis and the reeling device is to fully reel described above is that the linear velocity of the film in the unreeling and reeling devices of the second processing unit is just the same as that of the impression cylinder  6  when the unreeling device of the first processing unit ends unreeling and the reeling device fully re-reels, so that gapless interchange between their throwing on and throwing off can be realized, and vice versa. 
       FIGS. 5 to 8  show another embodiment of application at the processing technology of the present invention; 
     A paper base material  7  with uncured adhesive and a cold-stamped film simultaneously enter the processing system, and the first processing unit and the second processing unit of the processing system are respectively provided with an impression cylinder  6  and an impression cylinder  13 . The second processing unit at the moment is still and is located at a position thrown off the impression cylinder for standby, the paper base material  7  with uncured adhesive is dragged to completely fit the cold-stamped film supplied by the unreeling device in the first processing unit at the rotating junction of the pressure roller  4  and the impression cylinder  6 . Then, the fitted cold-stamped film and paper base material  7  are conveyed to a position below the curing device  3 , the adhesive on the paper base material  7  is cured by the curing device via the cold-stamped film, the cured and viscosified adhesive at the moment is firmly combined with a sprayed aluminum layer at the corresponding position below the surface of the film, then the reeling device  2  in the first processing unit strips the sprayed aluminum layer on the film off the film, and the sprayed aluminum layer is attached to the surface of the paper base material  7 , as seen in  FIG. 5 . Finally, the cylinder conveys the paper base material  7  with the aluminum layer to the paper reception unit or other processing unit. 
     When the unreeling device  1  in the first processing unit is to unreel to the proximity of the axis and the reeling device  2  is to fully reel, the processing system accelerates the unreeling device  8  and the reeling device  9  in the second processing unit by operation of a computer or control of a sensor switch, and when the linear velocity of the cold-stamped film is same as that of the revolving speed of the impression cylinder  13 , the pressure roller  11 , the stripping roller  12  and the curing device  10  fixed on the secondary wallboard simultaneously descend, so that the pressure roller  11  comes into fit with the impression cylinder  13 , as seen in  FIG. 6 . Then, the pressure roller  4 , the stripping roller  5  and the curing device  3  fixed on the secondary wallboard in the first processing unit ascend; when the secondary wallboard moves till the straight line between the bottoms of the pressure roller  4  and the stripping roller  5  is higher than the highest point of the impression cylinder  6 , the reeling device  2  is independently driven to unreel at a speed higher than that of the impression cylinder  6 , and the unreeling device  1  re-reels at a high speed. Simultaneously, the paper base material  7  with uncured adhesive is continuously conveyed or dragged to completely fit the cold-stamped film supplied by the unreeling device  8  in the second processing unit at the rotating junction of the pressure roller  11  and the impression cylinder  13 . After the paper base material  7  is completely fitted with the cold-stamped film, the fitted cold-stamped film and paper base material  7  are conveyed to a position below the curing device  10 , the adhesive on the paper base material  7  is cured by the curing device via the cold-stamped film, the cured and viscosified adhesive at the moment is firmly combined with the sprayed aluminum layer at the corresponding position below the surface of the film, then the reeling device  9  in the second processing unit strips the sprayed aluminum layer on the film off the film, and the sprayed aluminum layer is attached to the surface of the paper base material, as seen in  FIG. 7 . Finally, the cylinder conveys the paper base material with the aluminum layer after surface treatment to the paper reception unit or other processing unit. 
     When the unreeling device  8  in the second processing unit is to unreel to the proximity of the axis and the reeling device  9  is to fully reel, the pressure roller  4  of the first processing unit is thrown on to the impression cylinder  6  by adopting the above method, meanwhile, the pressure roller  11  of the second processing device is thrown off the impression cylinder  13 , and the unreeling device  8  in the second processing unit starts high-speed re-reeling, as seen in  FIG. 8 , to prepare for next unreeling when unreeling of the unreeling device  1  of the first processing unit is to be completed. Thus, the reel change between the first processing unit and the second processing unit is repeated cyclically in sequence, automatic reel change is realized without stop, and the surface treatment of the paper base material is finally accomplished by the processing units in the system. 
       FIGS. 9 to 12  show a further embodiment of application of the processing technology of the present invention: 
     Referring to  FIG. 9 , after a plastic sheet is glossed by a glossing unit and before the plastic sheet and a film simultaneously enter the first processing unit of the processing system, the first group of electric eye device  15  detects the recognizable mark on the film supplied by the unreeling device  1 , and the time from the mark to the junction of the film and the plastic sheet  7  is calculated with a running speed. Based on the predetermined difference of time when the positioning mark on the film and the relative positioning point of the plastic sheet  7  arrive at the junction, the tension of the film itself is changed by adjusting/reducing the speed of the A group of servo controlled active compaction rollers  14  in the positioning stretching device for the film, and the length of the film is changed thereby. However, the speed of the B group of compaction rollers  16  in the positioning stretching device is the same as the running speed of a host to ensure the synchrony when the corresponding points of the film and the plastic sheet  7  enter the junction. The servo control indicates control on the rotating speed via the input of an analog quantity or the frequency of pulse. 
     The second processing unit at the moment is still and is located at a position thrown off the impression cylinder  13  for standby, the plastic sheet  7  with an uncured coating is dragged to completely fit the positioned and stretched film supplied by the unreeling device  1  in the first processing unit at the rotating junction of the pressure roller  4  and the impression cylinder  6 . Then, the fitted film and plastic sheet  7  are conveyed to a position below the curing device  3 , the coating on the plastic sheet is cured by the curing device via the film, the cured coating at the moment is presented on the plastic sheet  7  in a manner reverse to the surface texture of the film, and then the reeling device  2  in the first processing unit strips the film off the surface of the plastic sheet  7  and rolls back. Finally, the cylinder conveys the plastic sheet  7  after surface treatment to the reception unit or other processing unit. 
     When the unreeling device  1  in the first processing unit is to unreel to the proximity of the axis and the reeling device  2  is to fully reel, the processing system accelerates the unreeling device  8  and the reeling device  9  in the second processing unit by operation of a computer or control of a sensor switch, and when the linear velocity of the film is the same as that of the revolving speed of the impression cylinder  13 , the pressure roller  11 , the stripping roller  12  and the curing device  10  fixed on the secondary wallboard simultaneously descend, so that the pressure roller  11  comes into fit with the impression cylinder  13 , as seen in  FIG. 10 . In this process, the first electric eye device  19  in the second processing unit detects the recognizable mark on the film supplied by the unreeling device  8 , and the time from the mark to the junction of the film and the plastic sheet  7  is calculated with a running speed. Based on the predetermined difference of time when the positioning mark on the film and the relative positioning point of the plastic sheet  7  arrive at the junction, the tension of the film itself is changed by adjusting/reducing the speed of the A group of servo controlled active compaction rollers  18  in the positioning stretching device for the film, and the length of the film is changed thereby to realize positioning stretching of the film. Then, the pressure roller  4 , the stripping roller  5  and the curing device  3  fixed on the secondary wallboard in the first processing unit ascend; when the secondary wallboard moves till the straight line between the bottoms of the pressure roller  4  and the stripping roller  5  is higher than the highest point of the impression cylinder  6 , the reeling device  2  is independently driven to unreel at a speed higher than that of the impression cylinder  6 , and the unreeling device  1  re-reels at a high speed. Simultaneously, the plastic sheet  7  with the uncured coating is continuously conveyed or dragged to completely fit the positioned and stretched film supplied by the unreeling device  8  in the second processing unit at the rotating junction of the pressure roller  11  and the impression cylinder  13 . After the plastic sheet  7  is completely fitted with the film, the fitted film and plastic sheet  7  are conveyed to a position below the curing device, the coating on the plastic sheet  7  is cured by the curing device via the film, the cured coating at the moment is presented on the plastic sheet  7  in a manner reverse to the surface texture of the film, and then the reeling device  9  in the second processing unit strips the film off the surface of the plastic sheet  7  and rolls back. Finally, the cylinder conveys the plastic sheet  7  after surface treatment to the reception unit or other processing unit, as seen in  FIG. 1 . 
     When the unreeling device  8  in the second processing unit is to unreel to the proximity of the axis and the reeling device  9  is to fully reel, the pressure roller  4  of the first processing unit is thrown on to the impression cylinder  6  by adopting the above method, meanwhile, the pressure roller  11  of the second processing device is thrown off the impression cylinder  13 , and the unreeling device  8  in the second processing unit starts high-speed re-reeling, as seen in  FIG. 12 , to prepare for next unreeling when unreeling of the unreeling device  1  of the first processing unit is to be to completed. Thus, the reel change between the first processing unit and the second processing unit is repeated cyclically in sequence, automatic reel change is realized without stop, and the surface treatment with positioning stretching on the plastic sheet is finally accomplished by the processing units in the system. 
       FIG. 13  shows a further embodiment of application of the processing technology of the present invention: 
     In addition to the glossing unit (not shown) preceding the first processing unit, a coating unit  22  is further arranged between the first processing unit and the second processing unit. 
     A glossed and uncured paper base material  7  completely comes into fit with a film material having a surface texture supplied by the unreeling device  1  in the first processing unit at the rotating junction of the pressure roller and the impression cylinder. Then, the fitted film and paper base material  7  are conveyed to a position below the curing device  3 , the coating on the paper base material  7  is cured by the curing device via the film, the cured coating at the moment is presented on the paper base material  7  in a manner reverse to the surface texture of the film, and then the reeling device  2  in the first processing unit strips the film off the surface of the paper base material  7  and rolls back. The paper base material  7  with film surface texture I is coated by the coating unit  22 , and the paper base material  7  with film surface texture I glossed for the second time completely comes into fit with a film material having surface texture II supplied by the unreeling device  8  in the second processing unit at the rotating junction of the pressure roller  11  and the impression cylinder  13 . Then, the fitted film and paper base material are conveyed to a position below the curing device  10  the coating on the paper base material  7  is cured by the curing device via the film, the cured coating at the moment is presented on the paper base material with a film surface texture in a manner reverse to the surface texture II of the film, then the reeling device  2  in the first processing unit strips the film off the surface of the paper base material  7  and rolls back, and finally, patterns with a combined surface texture I and surface texture II are presented on the paper base material by using the two different coating units in combination with mutual registration of the films with two different surface textures. 
     Although the embodiments and the drawings of the present invention are disclosed for illustrative purposes, those skilled in the art could understand that various substitutions, changes and modifications are possible without departing from the spirit and scope of the present invention and the appended claims, so the scope of the present invention is not limited to the contents disclosed by the embodiments and the drawings.