IT202100022301A1 - MONITORING SYSTEM AND CERTIFICATION OF THE ECO-SUSTAINABILITY OF THE PRINTING PROCESS AND RELATED METHOD - Google Patents

Description

Description of the invention entitled:

?ECO-SUSTAINABILITY MONITORING AND CERTIFICATION SYSTEM? OF THE PRINTING PROCESS AND RELATED METHOD?

Description

field of technique

The present invention operates in the field of control and monitoring systems of the production stages of a company. In particular, the company that could exploit the present invention will be? a digital printing house or any other business? dedicated to the production of prints on any support.

Known art

The community Since the 1990s, the European Union had identified the paint and ink industry as one of the sectors that make the greatest use of volatile organic compounds. According to estimates, the annual consumption of solvents ? of 1.5 million tons of which about 50% of the products? consisting of ?decorative paints?, sold to private individuals or to professional users active in the typographic sector. Being the volatile organic compounds a class comprising different chemical compounds, assimilable by the fact that they are all characterized by easy vaporization at room temperature and by the high capacity? to react in the troposphere giving rise to polluting compounds, ? obvious their danger? and the pressing need to overcome the use of these inks in printing processes. Try ne ? the fact that the main internal sources of VOCs come from cleaning products, building materials, cigarette smoke and machines such as printers and copiers. The printing processes in modern printing houses have a multiplicity? of deficits from the point of view of the environmental impact of the printing process, not limited to the use of harmful inks. Suffice it to say that even today, in every stage of production, the printing processes involve the use and dispersion of harmful materials such as those present in traditional discharge lamps which, if dispersed into the environment, cause extensive damage caused by the presence of phosphors. Not today? present in the patent system n? an eco-sustainability monitoring and certification system on the market? of the printing process and related method of implementation, monitoring and certification of? eco-sustainability? of the printing process. The patent N105462349A ?Completely-renewable, green and environment-friendly offset printing ink? provides the solution to only one of the problems of eco-sustainability? that afflict the current printing methods implemented in modern printing houses, further patents known to the state of the art are interested in printing procedures, but they do so only from the point of view of maximizing its efficiency, not considering that the attention towards the environment often implies an economic return in terms of the optimization of resources and the positive impact of the company towards an increasingly growing clientele. pay attention to the green theme.

Description of the invention

According to the present invention , an eco-sustainability monitoring and certification system is implemented. of the printing process and described a method for implementing, monitoring and certifying eco-sustainability? of the printing process of a printing house that effectively solve the above problems. As far as the eco-sustainability monitoring and certification system is concerned, it is characterized by allowing a remote control of the procedure by the customer of the printing house; said remote control ? possible thanks to special electronic devices supplied with said printing process monitoring and certification system since said electronic devices are connected via an internet or local network to at least one special software in order to allow immediate transmission and processing of the data collected for by means of said special electronic devices during the printing process.

There are many electronic devices that are part of the printing process monitoring and certification system, including:

- at least a special sensor quality? of the air supplied to the inkjet printer with UV-curing process with LED technology part of the said system, said quality sensor? of the air by being able to detect contaminants in the air, including pollutants, harmful gases and volatile chemicals such as volatile organic compounds (VOC); being said at least one sensor a multi-parametric sensor ? also suitable for detecting the temperature of the environment;

- at least one suitable video camera provided with said printer suitable for allowing the video recording of the entire reproduction phase by means of printing of said image to be printed selected by said customer;

- at least one further video camera supplied with said milling machine suitable for carrying out a video recording of the step of processing said support material of said images to be printed carried out by said milling machine.

How is the eco-sustainability monitoring and certification system clear from the above? of the printing process includes a plurality? of machines such as an inkjet printer with UV-curing process with LED technology and a milling machine, as well as? the related electronic devices for monitoring the printing process. As for the method of implementing, monitoring and certifying eco-sustainability? of the printing process of a typography, it usefully exploits, during said printing process, the advantages in environmental terms deriving from the use of said ink jet printer with UV-curing technology with LED technology and of said milling. Said method includes various steps, the first of which involves sending in mode? telematics of the said image to be printed by the customer to the printing house, consequently it will be realized? the receipt by the person in charge of the printing process of said image suitable for printing. The person in charge of the printing process, or more? generically the digital printing house, will provide in mode? automatic to the assignment of a user ID to the customer, said user ID being capable of allowing said customer to monitor the quality? and the ecological standards of said printing process integrally considered comprising a phase of reproduction by means of printing of said image, a phase of processing of said image performed by said milling machine, a phase of packaging, a phase of delivery to said customer of said reproduced image, a phase of disposal of consumables. Said method of implementing, monitoring and certifying eco-sustainability? of the printing process of a typography foresees three typologies of control and supervision, each of which foresees that said special electronic devices such as the multiplicity? appropriate sensors, at least one of said specific video cameras communicating with the printer and a further video camera communicating with the milling machine are capable of interfacing with said specific software in order to communicate the data detected by said specific electronic devices during said printing process . The first type of monitoring provides for the video recording by means of said special video camera of the entire said phase of reproduction by means of printing of said image to be printed as well as the of the processing phase of the image to be printed performed by the milling machine; does the monitoring include the subsequent filing of the recording on said specific software, in fact said video recording resulting from the monitoring? capable of being obtained by said customer in possession of said user ID through remote access, said access allows the acquisition of the relative file. In this way called registration ? capable of proving the eco-sustainability to third parties? of the proceedings. The second type of monitoring provides for the supervision of said printing process, this time considered integrally, by means of at least one special sensor characterized by the ability? to analyze the quality? of the air being said device suitable for detecting contaminants in the air, including polluting agents, harmful gases, volatile chemical substances such as volatile organic compounds (VOC); being said at least one sensor a multi-parametric sensor ? also able to detect the temperature of the environment. As in the previous case, also in this further type of monitoring, the analysis carried out by the electronic devices and in particular by the at least one sensor of the quality? of the air ? capable of being obtained by said customer in possession of said user ID through remote access, in fact said access allows the acquisition of the relative file. The third type of monitoring envisages that the phase of delivery of said reproduced image to the customer takes place through the use of a means of transport with zero emissions; being equipped with said suitable sensor which is characterized by being a suitable GPS sensor able to interface with suitable software, said zero-emission means of transport allows said customer to monitor the path of said image by accessing said software using said user ID. The next step with respect to that of assigning the user ID involves processing the images object of the printing process by means of a printer on an integral plate of the support material of said images to be printed object of the printing process. The milling machine allows optimization of the use of said support material of the images to be printed by exploiting a video projection system which projects onto the integral plate of said support material the profile of said images previously loaded by the person in charge of the printing process in the digital archive relating to the cutting files, the images involved in the printing process are then selected by the person in charge of the printing process. After said selection, a further special software automatically positions the profile of said images object of the printing process over the entire extension of said integral plate; said positioning by software ? suitable for optimizing the use of said support material since it allows the re-use of the excess support material from previous processes. After the step of preparing the support material of the images to be printed, the actual step of reproducing by means of printing the said image to be printed received electronically begins. Advantageously said reproduction step by means of printing takes place through the use of said special ink jet printer with UV-curing process with LED technology. Said UV-curing process with LED technology involves a photopolymerization exploiting energy from a UV source characterized by the use of said LED technology in order to transform a liquid with UV photoinitiators, preferably ink, into a solid; the LED technology included in this inkjet printer with UV-curing process with LED technology provides for the use of high density chip on board? in such a way as to reach, with a light source of reduced dimensions, a power of w/cm? useful for the polymerization of said liquid with UV photoinitiators, preferably ink. The cooling of said LED technology takes place by air, cooling necessary since the low level of heat dispersion of said technology during normal operation of said printer implies an undesired increase in temperature. As per the purpose of this method, the inkjet printer with UV-curing process with LED technology is characterized by ensuring maximum sustainability? environment of the printing process through a multiplicity? with advantageous characteristics, listed below: - low energy consumption, as this LED technology resets the heating and cooling times in such a way as to guarantee energy savings compared to the normal consumption of watts;

- the average life of this LED technology being equal to the longevity? of said inkjet printer with UV-curing process with LED technology allows to eliminate the replacement cost of said LED technology as well as? the relative costs in environmental terms necessary for the disposal of the lamps of which said LED technology is composed;

- the use of said LED technology within the printing process in such a way as to guarantee a low temperature during the entire said printing process, this limits the ozone emissions during said polymerization process;

- high degree of efficiency linked to the fact that this LED technology ensures that the energy absorbed is only minimally dissipated in the form of heat, allowing for significant energy savings and therefore a lower production of carbon dioxide;

- does the use of said LED technology during the printing process imply that said LED technology requires reduced currents linked to the low level of energy consumption? capable of being powered by means of renewable energies;

- low environmental impact in the disposal phase as this LED technology is made up of 95% recyclable materials;

- understand a multiplicity? of printing heads, preferably eight, able to allow the punctual positioning of the drop of ink on said support material of the said image object of the printing process, optimizing the use of said ink; said multiplicity? of print heads, preferably eight, by expelling drops of size equal to 12 picolitres they guarantee low ink consumption;

- the use of water-based inks equipped with thin ink layer technology capable of guaranteeing a high coloring power and a lower consumption of said ink per square meter compared to the industry standards; furthermore, said water-based inks used in said printing process are contained within environmentally friendly packaging such as cardboard. The use of these water-based inks makes it possible to produce odorless prints, allows for the emission of reduced levels of volatile organic compounds in such a way as to allow less use of ventilation and air conditioning technologies in the environment (and the consequent benefit in terms ecological), allows you to meet the requirements of the ZDHC standards and grants the possibility? to boast ECOLOGO and GREENGUARD Gold certifications, with the relative commercial advantages;

- the use of at least one suitable workflow management software capable of optimizing and automating the printing processes and in particular the management of the coloring of said images object of said printing process; said special flow management software by interfacing with at least one electronic device, preferably a special computer, guarantees in mode? automated a quality? of constant color with a consequent reduction of possible errors, the operator of the printing process can? always check and modify the parameters envisaged by said workflow management software by means of said electronic device, preferably said appropriate computer.

Workflow management takes place through an automatic pre-check of the quality? of said images object of said printing process, this inevitably translates into less waste; the support material of the said images object of the said printing process? an eco-sustainable material such as e.g. capotoile, a completely recyclable material, whose fibers are in turn obtained from recycled PET bottles; alternatively the support material of the image to be printed can? be the polyester, recyclable plastic material, or again, ? It is possible to use a panel made of recycled paper fiber made up of two sheets of printable paper that hold a honeycomb structure. Furthermore, this method of implementing the eco-sustainable printing process can characterized in that said support material of said images object of said printing process is an eco-sustainable material such as honeycomb polypropylene, said honeycomb polypropylene being completely recyclable or, lastly, said support material of said images object of said printing process press ? an eco-sustainable material such as a 100% polystyrene panel, such as to guarantee, once again, complete recyclability.

The final stages of said printing process include a packaging stage, during which the said image object of the said printing process is placed in a suitable packaging envelope which is distinguished by being a completely eco-compatible envelope; a said delivery step which envisages that the image reproduced through said printing process reaches said customer through the use of a zero-emission means of transport, moreover, since said means is equipped with a special GPS sensor capable of interfacing with a suitable software allows said customer to monitor the path of said image by accessing said software using said user ID; a phase of disposal of said consumable resulting from the printing process as well as? any additional materials whose disposal is requested at the request of said customer.

Said disposal phase is characterized by the implementation of a recycling program which reduces the environmental impact of the consumables resulting from said printing process, and in particular from said reproduction phase by means of printing, as well as from this milling phase. Said recycling program offers alternatives to said customer compared to landfill disposal including the reworking of printer cartridges, the reuse of waste ink, the recovery of excess plastic and metals, the transformation of the remaining waste into energy.

The implementation of said recycling program provides for the selection of the product whose disposal is requested by said customer through a specific online portal. In any case, the amount of consumable produced during the printing process? significantly reduced as said printer exploits the aforementioned video projection system supplied with said cutter as well as? the so-called low environmental impact LED technology.

The last phase relating to the method of implementing, monitoring and certifying eco-sustainability? of the printing process relates to the processing of a summary document by said special software comprising the data detected by said special electronic devices during said printing process considered integrally; said summary document? capable of being viewed by said customer on his personal electronic device under his said user ID.

The advantages offered by the present invention are evident in the light of the description set forth up to now and will be even more clear thanks to the annexed figures and the relative detailed description.

Description of the figures

The invention will come described hereinafter in at least one preferred embodiment by way of explanation and not of limitation with the aid of the accompanying figures, in which:

- FIGURE 1 shows an inkjet printer with UV-curing process with LED technology 100 comprising the suitable electronic devices of which a suitable sensor of quality? air quality 95 to detect contaminants in the air, including pollutants, harmful gases and volatile chemicals such as volatile organic compounds (VOCs), as well as suitable for detecting the temperature of the environment. The present figure 1 also shows how said printer 100 includes between said suitable electronic devices a suitable video camera 90 suitable for allowing the video recording of the entire reproduction phase by means of printing of said image to be printed selected by said customer. Finally, the suitable computer 85 suitable for interfacing with said suitable workflow management software suitable for optimizing and automating the printing processes is shown.

- FIGURE 2 illustrates the milling machine 80 adapted to act on an integral plate 75 of the support material of the said images object of the said printing process. The figure shows how the milling machine 80 comprises a further video camera 70 able to carry out a video recording of the processing step of said support material of the images to be printed.

- FIGURE 3 shows how the said milling machine 80 allows optimization of the use of the support material of the said images to be printed by exploiting the video projection system 65, which projects the profile 50 of the images onto the integral plate 75 of said support material said images to be printed previously loaded by the person in charge of the printing process into the digital archive relating to the cutting files, said images are then selected by the person in charge of the printing process by means of a suitable computer 60 able to communicate with said video projection system 65 and then with said milling machine 80.

Detailed description of the invention

This invention will come now illustrated purely by way of example but not in a limiting or binding way, making use of the figures which illustrate some embodiments with respect to the present inventive concept.

The eco-sustainability monitoring and certification system? it is characterized by allowing remote control of the process by the customer of the printing house; said remote control ? possible thanks to special electronic devices provided with said system for monitoring and certifying the printing process since said electronic devices are connected via an internet network to a special software in order to allow immediate transmission and processing of the data detected by means of said appropriate electronic devices during the printing process.

There are a plurality of electronic devices that are part of the printing process monitoring and certification system; a special sensor of quality? of the air 95 supplied with the inkjet printer with UV-curing process with LED technology 100 part of said system, as shown in FIGURE 1, allows to detect contaminants in the air, including pollutants, gases harmful substances and volatile chemical substances such as volatile organic compound (VOC) (being said at least one sensor, a multi-parameter sensor is further adapted to detect the temperature of the environment); in FIGURE 1 ? also shown is the special video camera 90 supplied with the ink jet printer 100 suitable for allowing the video recording of the entire reproduction phase by means of printing of said image to be printed selected by the customer. Finally, the suitable computer 85 suitable for interfacing with said suitable workflow management software suitable for optimizing the printing processes is shown. later explained in detail. FIGURE 2 shows a further video camera 70 supplied with said milling machine 80 suitable for carrying out a video recording of the processing phase of said support material of said images to be printed performed by said milling machine 80.

How is the eco-sustainability monitoring and certification system clear from the above? of the printing process includes a plurality? of machines such as an inkjet printer with UV-curing process with LED technology 100 and a milling machine 80 as illustrated in FIGURES 1 and 2, as well as the related electronic devices for monitoring the printing process. As for the method of implementing, monitoring and certifying eco-sustainability? of the printing process, it usefully exploits, during said printing process, the advantages in environmental terms deriving from the use of said ink jet printer with UV-curing technology with LED technology 100 and of said milling machine 80 Said method includes various steps, the first of which provides for sending in mode? telematics of the said image to be printed by the customer to the printing house, consequently it will be realized? the receipt by the person in charge of the printing process of said image suitable for printing. The person in charge of the printing procedure will provide to the assignment of a user ID to the customer, being said user ID capable of allowing the customer to monitor the quality? and the ecological standards of said printing process integrally considered comprising a reproduction phase by means of printing of said image by means of said printer 100, a processing phase of said image performed by said milling machine 80, a packaging phase, a step of delivering said reproduced image to said customer, a step of delivery, a step of disposing of consumables, a step of preparing a summary document. Said method of implementing, monitoring and certifying eco-sustainability? of the printing process of a printing house provides for three types of control and supervision, each of which provides that said special electronic devices, a said special video camera 90 communicating with the printer 100 and a further video camera 70 communicating with the milling machine 80 are capable of interfacing with said special software in order to communicate the data detected by said special electronic devices during said printing process. The first type of monitoring provides for the video recording by means of said special video camera 90 of the entire said phase of reproduction by means of printing of said image to be printed as well as the the video recording by means of a further suitable video camera 70 of the processing phase of the image to be printed performed by the milling machine 80; does the monitoring include the subsequent filing of the recording on said specific software, in fact said video recording resulting from the monitoring? capable of being obtained by said customer in possession of said user ID through remote access, said access allows the acquisition of the relative file. In this way called registration ? capable of proving the eco-sustainability to third parties? of the proceedings. The second type of monitoring of the reproduction phase by means of printing by means of said ink jet printer 100 provides that the supervision takes place by means of a suitable sensor 95 characterized by the ability to to analyze the quality? dell?air being said sensor of the quality? 95 to detect contaminants in the air, including pollutants, harmful gases, volatile chemicals such as volatile organic compounds (VOC); being said sensor 95 a multi-parameter sensor ? also able to detect the temperature of the environment. As in the previous case, also in this further type of monitoring, the analysis carried out by the electronic devices and in particular by the sensor of the quality? of the air ? capable of being obtained by said customer in possession of said user ID through remote access, in fact said access allows the acquisition of the relative file. The third type of monitoring envisages that the phase of delivery of said reproduced image to the customer takes place through the use of a means of transport with zero emissions; being equipped with said suitable sensor which is characterized by being a suitable GPS sensor able to interface with suitable software, said zero-emission means of transport allows said customer to monitor the path of said image by accessing said software using said user ID. The next step with respect to that of assigning the user ID involves processing the images object of the printing process by means of a milling machine 80 suitable for acting on an integral plate 75 of the support material of said images to be printed object of the printing process . The milling machine 80 allows optimization of the use of said support material of the images to be printed by exploiting a video projection system 65, as illustrated in FIGURE 3, which projects the profile of said images onto the integral plate 75 of said support material images previously loaded by the person in charge of the printing process in the digital archive relating to the cutting files, the images object of the printing process are then selected by the person in charge of the printing process. After said selection, the person in charge of the printing procedure positions at his discretion, using suitable additional software, the profile of said images object of the printing procedure over the entire extension of said integral plate 75; said discretionary manual positioning by software ? suitable for optimizing the use of said support material since it allows the re-use of the excess support material from previous processes. The actual phase of reproduction by means of printing of said image to be printed received electronically then begins. Advantageously said reproduction step by means of printing takes place through the use of said special inkjet printer with UV-curing process with LED technology 100 as illustrated in FIGURE 1. Said UV-curing process with LED technology implies a photopolymerization exploiting energy from a UV source characterized by the use of said LED technology in order to transform a liquid with UV photoinitiators, preferably ink, into a solid; the LED technology included in this inkjet printer with UV-curing process with LED 100 technology provides for the use of high-density chip on board? in such a way as to reach, with a light source of reduced dimensions, a power of w/cm? useful for the polymerization of said liquid with UV photoinitiators, preferably ink. The cooling of said LED technology takes place by air, cooling necessary since the low level of heat dispersion of said technology during normal operation of said printer 100 implies an undesired increase in temperature. As per the purpose of this method, the inkjet printer with UV-curing process with LED 100 technology is characterized by ensuring maximum sustainability? environment of the printing process through a multiplicity? with advantageous characteristics, listed below: - low energy consumption, as this LED technology resets the heating and cooling times in such a way as to guarantee energy savings compared to the normal consumption of watts;

- the average life of this LED technology being equal to the longevity? of said inkjet printer with UV-curing process with LED technology 100 allows to eliminate the cost of replacing said LED technology as well as? the relative costs in environmental terms necessary for the disposal of the lamps of which said LED technology is composed;

- the use of said LED technology within the printing process in such a way as to guarantee a low temperature during the entire said printing process, this limits the ozone emissions during said polymerization process;

- high degree of efficiency linked to the fact that this LED technology ensures that the energy absorbed is only minimally dissipated in the form of heat, allowing for significant energy savings and therefore a lower production of carbon dioxide;

- does the use of said LED technology during the printing process imply that said LED technology requires reduced currents linked to the low level of energy consumption? capable of being powered by means of renewable energies;

- low environmental impact in the disposal phase as this LED technology is made up of 95% recyclable materials;

- understand a multiplicity? of printing heads, preferably eight, able to allow the punctual positioning of the drop of ink on said support material of the said image object of the printing process, optimizing the use of said ink; said multiplicity? of print heads, preferably eight, by expelling drops of size equal to 12 picolitres they guarantee low ink consumption;

- the use of water-based inks equipped with thin ink layer technology capable of guaranteeing a high coloring power and a lower consumption of said ink per square meter compared to industry standards, furthermore said water-based inks used in said printing process are contained within environmentally friendly packaging such as cardboard. The use of these water-based inks makes it possible to produce odorless prints, allows for the emission of reduced levels of volatile organic compounds in such a way as to allow less use of ventilation and air conditioning technologies in the environment (and the consequent benefit in terms ecological), allows you to meet the requirements of the ZDHC standards and grants the possibility? to boast ECOLOGO and GREENGUARD Gold certifications, with the relative commercial advantages;

- the use of a suitable workflow management software suitable for optimizing and automating the printing processes and in particular the management of the coloring of said images object of said printing process; said special flow management software by interfacing with a special computer 85 guarantees in mode? automated a quality? of constant color with a consequent reduction of possible errors, the operator of the printing process can? always check and modify the parameters envisaged by said workflow management software by means of said special computer 85.

Workflow management takes place through an automatic pre-check of the quality? of said images object of said printing process, this inevitably translates into less waste; the support material of the said images object of the said printing process? an eco-sustainable material, preferably a panel made of recycled paper fiber made up of two sheets of printable paper that hold a honeycomb structure. The final stages of said printing process include a packaging stage, during which the said image object of the said printing process is placed in a suitable packaging envelope which is distinguished by being a completely eco-compatible envelope; a delivery phase which envisages that the image reproduced through said printing process reaches said customer through the use of a zero-emission means of transport, moreover, since said means is equipped with a special GPS sensor suitable for interfacing with special software allows said customer to monitor the path of said image by accessing said software using said user ID; a step for disposing of said consumable resulting from the printing process. Said disposal phase is characterized by the implementation of a recycling program which reduces the environmental impact of the consumables resulting from said printing process, in particular from said reproduction phase by printing and from said milling phase. Said recycling program offers alternatives to said customer compared to landfill disposal including the reworking of printer cartridges, the reuse of waste ink, the recovery of excess plastic and metals, the transformation of the remaining waste into energy. The implementation of this recycling program provides for the selection of the product whose disposal is requested by the said customer through a specific online portal. The last phase relating to the method of implementing, monitoring and certifying eco-sustainability? of the printing procedure concerns the elaboration of a summary document by said specific software comprising the data detected by said specific electronic devices during said printing procedure considered integrally among which are included said sensor of quality? of the air 95, said video camera 90 supplied to said ink jet printer with UV-curing process with LED technology 100, said further video camera 70 supplied to said milling machine 80, said GPS sensor; said summary document? capable of being viewed by said customer on his personal electronic device under his said user ID.

? finally, it is clear that modifications, additions or variations that are obvious to a person skilled in the art can be made to the invention described up to now, without thereby departing from the scope of protection which ? provided by the appended claims.

Claims (8)

Claims 1. Eco-sustainability monitoring and certification system? of the printing process, characterized by the fact that it allows remote control, by a customer, of the said eco-sustainability; said remote control taking place by means of suitable electronic devices; said system including a plurality? of machines such as: - an inkjet printer with UV-curing process with LED technology (100), including at least one quality sensor? (95), designed to detect contaminants in the air, including pollutants, noxious gases and volatile chemicals such as volatile organic compounds (VOC); being said at least a sensor of quality? of the air (95) a multi-parameter sensor adapted to also detect the temperature of the environment; said inkjet printer with UV-curing process with LED technology (100) further comprising at least one special video camera (90) able to allow the video recording of the entire phase of reproduction by means of printing of said image to be printed selected by said customer; - a milling machine (80), able to act on an integral plate (75) of support material of the said images object of the said process, comprising at least one further video camera (70) able to carry out a video recording of the processing phase of the said support material of said images to be printed performed by said milling machine (80); said electronic devices being connected via an internet or local network to at least one special software in order to allow immediate transmission of the data detected by means of said special electronic devices. 2. Method (100) for implementing, monitoring and certifying eco-sustainability? of the printing process using a said inkjet printer with UV-curing technology with LED technology (100) and a said milling machine (80), with the relative said appropriate electronic devices supplied, according to the previous claim 1 characterized the fact that you understand at least the following steps; A) sending in mode? telematics of said image to be printed by said customer; B) reception by a person in charge of the printing process of said image suitable for being printed; C) assignment of a user ID to allow said customer to monitor the quality? and the ecological standards of said printing process as a whole considered; D) phase of reproduction by means of printing of said image to be printed received electronically; said stage of reproduction by means of printing by means of a special inkjet printer with a UV-curing process with LED technology (100); E) milling phase during which the processing of the images object of the printing process takes place by means of a milling machine (80) suitable for acting on an integral plate (75) of the support material of said images to be printed object of said printing process; said milling machine (80) allowing optimization of the use of said support material of said images to be printed by exploiting a video projection system (65) able to project onto said integral plate (75) of said support material the profile of said images previously loaded by said person in charge of the printing process into the digital archive relating to the cutting files, said images are then selected by said person in charge of the printing process by means of an electronic device, preferably a suitable computer (60); after said selection, being positioned automatically, through suitable additional software, said profile of said images object of the printing process over the entire extension of said integral plate (75); said positioning being able to optimize the use of said support material since it allows the reuse of said excess support material from previous processes; F) packaging phase during which the said image object of the said printing process? placed in a special packaging that stands out for being environmentally friendly; G) delivery phase in which said image reproduced through said printing process reaches said customer through the use of a means of transport with zero emissions; said zero emission means of transport being equipped with said appropriate sensor, which is characterized by being a GPS sensor which allows said customer to monitor the path of said image by accessing said software via said user ID; H) phase of disposal of said consumable resulting from the printing process as well as? any additional print materials required to be disposed of by said customer; this disposal phase is characterized by the implementation of a recycling program which includes the reworking of printer cartridges, the reuse of waste ink, the recovery of excess plastic and metals and the transformation of waste into energy; the implementation of said recycling program provides for the selection of the product whose disposal is requested by said customer through appropriate software; the amount of said consumable material ? significantly reduced by exploiting said method the video projection system (65) supplied with said milling machine (80) as well as thanks to the use of these low environmental impact LED technology; I) processing of a summary document by said special software comprising the data detected by said at least one quality sensor? of the air (95), at least one said GPS sensor, at least one said video camera (90) and at least one further suitable video camera supplied with said milling machine (80) during the course of said printing process considered integrally; said summary document being adapted to be viewed by said customer on his personal electronic device through his said user ID. 3. Method (100) for implementing, monitoring and certifying eco-sustainability? of the printing process according to the previous claim 2, characterized by the fact that said support material of the said images object of the said printing process? an eco-sustainable material such as capotoile, since said capotoile is a completely recyclable material, the fibers of which are obtained from recycled PET bottles. 4. Method (100) for implementing, monitoring and certifying eco-sustainability? of the printing process of a typography according to the preceding claim 2, characterized in that said support material of the said images object of the said printing process? an eco-sustainable material such as polyester being said polyester a said recyclable plastic material. 5. Method (100) for implementing, monitoring and certifying eco-sustainability? of the printing process of a typography according to the preceding claim 2, characterized in that said support material of the said images object of the said printing process? an eco-sustainable material such as a panel composed of recycled paper fiber formed by two sheets of printable paper and a honeycomb structure. 6. Method (100) for implementing, monitoring and certifying eco-sustainability? of the printing process of a typography, according to the preceding claim 2, characterized by the fact that said support material of the said images object of the said printing process? an eco-sustainable material such as alveolar polypropylene, being called alveolar polypropylene completely recyclable. 7. Method (100) for implementing, monitoring and certifying eco-sustainability? of the printing process of a typography, according to the preceding claim 2, characterized by the fact that said support material of the said images object of the said printing process? an eco-sustainable material such as a 100% polystyrene panel, guaranteeing that the material is completely recyclable. 8. Method (100) for implementing, monitoring and certifying eco-sustainability? of the printing process of a typography, according to any one of the previous claims from 2 onwards, characterized by the fact that it provides three types of control and supervision thanks to the fact that said special electronic devices, such as said at least one special quality sensor? of the air (95), at least one GPS sensor and at least one said special video camera (90), are capable of interfacing with said special software in order to communicate the data detected by said special electronic devices during the said printing process: - the first type of monitoring provides for the video recording by means of said special video camera, of the entire said phase of reproduction by means of printing of said image to be printed as well as the by means of a further suitable video camera (70) and the video recording of said processing step of the said image to be milled performed by said milling machine (80); said monitoring further comprising the subsequent filing of said recording on said suitable software, said video recording resulting from said monitoring being capable of being obtained by said customer in possession of said user ID through remote access, said access allowing the acquisition of the relative file; said registration being likely to prove to third parties the? eco-sustainability? of the proceeding; - the second type of monitoring provides for the supervision of said reproduction phase by means of printing of said image to be printed by means of said at least one appropriate sensor (95) characterized by the ability? to analyze the quality? of the air being said device suitable for detecting contaminants in the air, including pollutants, harmful gases, volatile chemical substances such as volatile organic compounds (VOC); being said at least a sensor of quality? of? air (95) a multiparametric sensor ? also suitable for detecting the temperature of the environment; said quality analysis? of the air resulting from said monitoring being capable of being obtained from said customer in possession of said user ID through a remote access, said access allows the? acquisition of the relative file; said recording? capable of proving the eco-sustainability to third parties? of the proceeding; - the third type of monitoring envisages that said phase of delivery to said customer of said reproduced image takes place through the use of a means of transport with zero emissions; being equipped with said suitable sensor which is characterized by being a said suitable GPS sensor able to interface with suitable software, said zero-emission means of transport allows said customer to monitor the path of said image by accessing said software using said user ID.