In the field of industrial printing, a cleaning system and method is applicable to a converter useful in the corrugated box industry.
In the corrugated box industry, the “converters” that manufacture the boxes comprise as part of their function printing machines to print information on the box material before assembly of the box. There is currently a large amount of waste in time, ink materials and equipment degradation due to the difficulty of maintaining clean anilox rolls and ink chambers at the same time as keeping up the speed of production and hence minimizing the cost of production. Typically, converter ink cleaning systems are largely manual and use up substantial labor resources and machine downtime. Consequently, many converters operate in a fouled state and print quality diminishes. The inventors believe that in particular the cost associated with the negative effect on the lifetime of anilox rolls and ink chambers by inadequate cleaning has been underappreciated in the industry.
There is therefore a need to provide an improved system for cleaning converters.
According to a first broad aspect of the invention there is provided a system for cleaning an anilox roll and/or ink chamber of a converter, comprising: a water supply adapted to supply water through an automatically controllable water supply valve to wash the anilox roll and/or ink chamber of the converter; a cleaning solution supply adapted to supply a cleaning solution through an automatically controllable cleaning solution supply valve to clean the anilox roll and/or ink chamber; and a programmable controller programmed to operate the automatically controllable valves so as to deliver a timed sequence of water and cleaning solution to the anilox roll and/or ink chamber upon the occurrence of a cleaning cycle initiation condition.
In one embodiment, there is a plurality of the converters and corresponding automatically controllable valves, and the water supply and the cleaning solution supply for each of the converters originates from a common water supply source and cleaning solution supply source respectively. The cleaning solution supply source may comprise a container of cleaning solution concentrate, a dilution medium and a cleaning solution dilution apparatus adapted to supply the cleaning solution as a fixed or controllable ratio of the cleaning solution concentrate mixed with the dilution medium.
In one embodiment, the cleaning solution comprises a solvent to dissolve ink fouling the cleanable part, and a surfactant to reduce surface tension. The cleaning solution may further comprise a pH adjustment component. The cleaning solution may be selected and formulated so that the ink drops out of solution after the used cleaning solution is diluted into a waste water treatment plant, allowing the ink to be recovered before the waste water is discarded.
In one embodiment, the cleaning cycle initiation condition comprises a change of ink colour being used on the converter.
In one embodiment, the timed sequence of water and cleaning solution delivery comprises one or more sub-sequences of water and cleaning solution delivery followed by a final delivery of water to rinse out remaining cleaning solution from the converter.
In one embodiment, a water supply non-return valve is disposed downstream of the water supply valve.
In one embodiment, a cleaning solution supply non-return valve is disposed downstream of the cleaning solution supply valve. An outlet of the cleaning solution supply valve enters the water supply line downstream of the water supply non-return valve.
According to a second broad aspect of the invention there is provided a method of cleaning an anilox roll and/or ink chamber of a converter using the system of the first broad aspect, the method comprising the steps of: supplying water through the water supply; supplying cleaning solution through the cleaning solution supply; and activating the programmable controller to operate the automatically controllable valves so as to deliver a timed sequence of water and cleaning solution to the anilox roll and/or ink chamber upon the occurrence of the cleaning cycle initiation condition.
An embodiment of the current invention will now be described, as applied to the fiberboard box business. Box forming premises contain “converters” providing forming, printing, cutting and folding functions for forming printed corrugated fiberboard boxes. Referring first to
According to this embodiment of the invention there is also provided, for each converter, a cleaning solution supply 20a to 20d respectively also originating from a common cleaning solution dilution supply source 20.
Cleaning solution is diluted using cleaning solution dilution apparatus 40 such as a Venturi mixing valve mixing a dilution medium 35 (in this case water) with a fixed or variable proportion of a cleaning solution concentrate from 264 gallon capacity container “tote” 30. In this case the recommended dilution ratio is 1:50. The cleaning solution concentrate held in container 30 contains several solvents to dissolve ink particles, surfactants to reduce surface tension on the cleanable part surfaces and hold the ink in solution, tripolyphosphate (TPP) and EDTA (ethylenediaminetetraacetic acid) to clean and chelate deactivating ions and monoethanolamine (MEA) to adjust the pH of the concentrate to about pH 10 and consequently the pH of the diluted cleaning solution to about pH 9, being a pH which is not too high to corrode parts, but sufficiently high so that the solvents and surfactants dissolve the ink particles.
As will be understood by person skilled in the art, the exact composition of the ingredients and the proportions in the cleaning solution concentrate will depend on the particular printing application and the characteristics of the machines and the printing inks involved. The cleaning solution of this embodiment is designed so that once diluted into the water dilution medium at a ratio of about 1:50, the cleaning solution effectively dissolves the waste ink and cleans the cleanable parts, and when the cleaning solution is further deleted by passage into a waste water treatment plant 60 via waste water drainage lines 50a to 50d, the dissolved ink falls out of solution, enabling recovery of the waste ink before discharge of waste from the premises.
Referring now to
When programmable logic controller 70 energizes electrical control line 12a, water supply passes through the output of water supply control valve 11a and through nonreturn valve 13a, past the junction point meeting the output of cleaning solution supply valve 21 a and into converter washing supply line 80a. Similarly, when programmable logic controller 70 energizes electrical control line 22a, cleaning solution passes through the output of cleaning solution supply control valve 21a past the junction point meeting the output of water supply control valve 11a, and into converter washing supply line 80a. Converter washing supply line 80a thus feeds ink chamber washing supply line 81a and spray bar washing supply line 82a either with nothing, with rinsing water or with cleaning solution depending on the energizing of the solenoids by programmable logic controller 70. Chamber washing supply line 81a feeds washing fluid to clean the ink chamber of the converter, and spray bar washing supply line 82a feeds washing fluid into the washing spray bar for washing the print roll.
In this embodiment, programmable logic controller 70 is programmed to energize the solenoids in a timed sequence so as to deliver a series of alternating water rinses and cleaning with cleaning solution. The cleaning cycle initiation condition that causes the timed sequence to commence is a change of ink color on the converter, sensed by programmable logic controller 70 through a control input 72 feeding an ink change signal from a factory control system or similar. The timed sequence comprises six subsequences each consisting of 14 seconds of water flow followed by 9 seconds of cleaning solution flow, followed at the completion of the six subsequences by 60 seconds of water flow as a final rinse.
The inclusion of nonreturn valves 13a and 23a on the water supply and the cleaning solution supply respectively, prevent the water supply from becoming contaminated with cleaning solution and vice versa. Also, the disposition of the outlet of the cleaning solution supply valve downstream from the water supply valve ensures that no cleaning solution is left in the system after the final water wash.
The system of the invention allows a time efficient and optimized cleaning strategy to be implemented that does not adversely impact on the daily output of the converter, but keeps the converter substantially free of ink residues and as hoped by the inventors has been found to considerably lengthen the service life of the anilox rolls as well as provide the expected overall improvement of the print condition of the formed and printed boxes.
In a typical installation, the cleaning cycle operates between one and 15 times per day.
Persons skilled in the art will also appreciate that many variations may be made to the invention without departing from the scope of the invention.
For example, while the example described utilizes a programmable logic controller 70 in relation to each converter, clearly a factory-wide control system could alternatively be used to control the automatically controllable valves.
Further, constructing systems according to the invention will usually involve attaching and augmenting solenoids, valves, supply lines and controllers to an existing factory system on the printing premises, and not necessarily replacing all existing components. For example, printing premises may already contain water supply lines to supply water to each converter for manual washing procedures and manual addition of cleaning solution.
Further, although the example described herein relates to fiberboard box converter businesses, the broadest aspect of the invention extends to systems for washing other types of converter.
Further still, the term “programmable controller” is used here in extends to any control system capable of being programmed to operate the automatically controllable valves, and includes programmable relay controllers, time clocks, computers and the like.
The timed sequence described in the embodiment above is an example only and can be varied depending on the installation.
In the claims which follow and in the preceding description of the invention, except where the context requires otherwise due to express language or necessary implication, the word “comprise” or variations such as “comprises” or “comprising” is used in an inclusive sense, i.e. to specify the presence of the stated features but not to preclude the presence or addition of further features in various embodiments of the invention. Further, any method steps recited in the claims are not necessarily intended to be performed temporally in the sequence written, or to be performed without pause once started, unless the context requires it.
It is to be understood that, if any prior art publication is referred to herein, such reference does not constitute an admission that the publication forms a part of the common general knowledge in the art, in Australia or any other country.
This application is a continuation of U.S. patent application Ser. 14/170,639 filed 2 Feb. 2014, which claims the benefit of U.S. Provisional Application No. 61/760,653, filed 5 Feb. 2013, which are hereby incorporated by reference herein
Number | Date | Country | |
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61760653 | Feb 2013 | US |
Number | Date | Country | |
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Parent | 14170639 | Feb 2014 | US |
Child | 14662525 | US |