The present invention relates to an improvement in machines for printing images on a garments and an improved method of printing on garments. The improvement of the invention is applicable both to digital printing machines and manual screen printing machines.
Manual machines for printing images on garments, such as shirts, scarves, and pants have been in use for quite a number of years. In a simplified version where a design having a single color is to be imprinted, the machine has a single arm bearing a platen with a screen located above the platen. A garment, such as a shirt, is manually loaded onto the platen and positioned manually at a predetermined location on the platen. The screen is lowered onto the garment and ink is applied through the screen. The screen has a mask that allows ink to be transferred to the garment only at the unmasked location or locations. Once the ink has been applied, the screen is lifted. The garment is removed from the platen and the next garment to which the design is to be applied is manually loaded onto the platen. The printed garment is placed upon a conveyor and passed through a heating machine that dries the ink.
When designs of a plurality of colors are to be applied, a more complex type of garment printing machine is required. A typical conventional manual screen printing machine for printing multicolored designs on garments may employ a device with a number of arms mounted upon a central hub. Each arm carries a single screen. The hub or turntable is rotated to sequentially bring each screen into alignment with a platen upon which a garment is mounted for printing. The printing screen aligned with the platen is lowered into contact with the garment at the printing station. Each screen contains a mask that allows ink to be applied to only a certain area or areas located directly beneath the screen. At each station ink is spread across the screen where it is imprinted upon the garment at the location or locations that are not masked. A different color ink is applied through each screen onto the garment.
The screens on their rotating arms are advanced sequentially, where they apply the color of ink used for each screen. The masks for each of the screens are different so that designs of different colors are imprinted upon each garment as the screens complete their circuit over the platen with the garment mounted upon it. After the last screen the garment is removed and a new blank garment is loaded onto the platen. Only after the printed garment has been unloaded from the platen and a new garment mounted thereon for printing is are the screens again advanced to print on the next garment. As each garment is completed it is manually removed from the platen after the last screen and placed onto a conveyor that passes the garment through a heater to dry the ink.
Digital printing machines have also been devised and are now in widespread commercial use. These machines work somewhat similarly to inkjet printers for printing words and designs from a computer onto paper. In digital garment printing machines there is a single garment receiving arm that is extended and then retracted to a single printing station in the machine. A platen for bearing the garment to be printed is secured to the end of the garment receiving arm that is extended and withdrawn relative to the printing station
In digital printing the garment is manually loaded onto the platen at the end of the garment receiving arm of the digital printer when the arm is extended. Once the next garment to be printed has been mounted on it, the arm is retracted into the machine for the garment to be printed with a computerized, preselected design at the printing station. In digital printing the inkjets are located quite close to, but not in contact with the garment to be printed. Once printing is complete the garment receiving arm is extended out from the printing station where the garment can be manually removed from the platen. With the platen still in position secured to the garment receiving arm of the digitized printing machine, a new, blank garment to be printed is then loaded onto the platen and the cyclical process of printing the garments is repeated.
With conventional garment printing machines a considerable amount of time is consumed in loading and unloading garments from the printing platens that are attached to the garment printing machine arms. Using conventional equipment, the platen to be unloaded and reloaded remains stationary and attached to the printing machine garment receiving arm while a printed garment is removed from it and replaced with the next garment to be printed. It takes approximately 16 seconds to unload and reload a conventional platen. During this time no printing is taking place. Only when the new garment is positioned on the platen can printing resume. The printing process itself takes approximately 30 seconds. Therefore, the complete cycle to unload and reload the platen and print the garment takes approximately 46 seconds.
With the present invention, however, the time required to remove a platen with a printed garment from the printing machine and replace it with an identical platen having a fresh garment mounted thereon for printing takes only about four seconds. Unloading a printed garment from a platen and reloading that platen with a fresh garment to be printed at a garment unloading and loading station near the printer takes place while the printing machine is printing an image on the garment previously loaded on another platen. Consequently, the printing machine is idle only about 4 seconds rather than 16 seconds for each garment to be printed. This represents an increase in garment unloading and reloading efficiency of 400%
The huge increase in efficiency of unloading and reloading a garment on a garment printing machine is made possible through the provision of a transportable garment printing platen. Actually a plurality of identical transportable garment printing platens are employed. Instead of remaining in position on the garment receiving arm of the garment printing machine, the platen of the invention is freely removable therefrom, although it is held tightly in a printing position and restrained from any horizontal movement relative to the garment receiving arm during the actual printing process.
As the printing machine brings the platen with the printed garment thereon to the station at which the garment is removed, not just the garment, but the entire platen with the garment mounted thereon is removed from the platen receiving arm of the garment printing machine and quickly replaced with another platen upon which a fresh garment has already been preloaded and mounted for printing. During the time the machine is printing on the garment that has been positioned for printing, the operator is concurrently unloading the printed garment from the platen just removed from the printing machine at a nearby master unloading and loading station and then reloading that platen with another platen bearing a fresh garment to be printed. This is done concurrently while the machine is still printing on the garment mounted on the platen that is positioned on the garment receiving arm of the machine. The process of unloading the printed garment and reloading the platen at the master station with the next garment to be printed takes less time than does the actual printing process performed by the machine. Consequently, the platen preloaded with the next garment to be printed is already for transfer onto the garment receiving arm of the printing machine before printing of the previous garment is completed. As a result, when the garment receiving arm is extended following printing, the platen with the newly printed garment is positioned by the machine for removal by the operator. The freshly loaded platen is ready for mounting upon the garment receiving arm as soon as the platen with the printed garment mounted thereon is removed. This exchange of platens each bearing a garment takes only approximately 4 seconds.
A plurality of identically constructed interchangeable platens are utilized to achieve the time-saving process of unloading and reloading described. Each platen is designed so that no special assembly is required and no modification of the printing machine is required. To the contrary, a master platen support is provided and is configured to fit into the printing machine. The master platen support is also configured to receive each platen that is dropped onto it. Each platen fits onto the master platen support which in turn fits onto the existing garment receiving arm of a conventional garment printing machine. No modification of any conventional garment printing machine, either digital or screen printing, is required. To the contrary, the master platen support provides the adaptation that allows a transportable platen, constructed according to the present invention, to be used with different models of conventional garment printing machines.
In one broad aspect the present invention may be considered to be a mechanism for a garment printing machine having at least one horizontally extending garment receiving arm. The mechanism is comprised of a platen support on the garment receiving arm and a transportable platen freely removable from the platen support. The platen is comprised of a horizontally extending garment mount having a flat horizontally upwardly facing support surface, the mount further including an apparatus for immobilizing at least a print receiving portion of a garment positioned thereon relative to the platen. This apparatus urges the print receiving portion of the garment into contact with the upwardly facing support surface of the platen. The platen and the platen support together have at least one registration set of at least one mating, vertically extending projection and at least one vertically extending recess that are slidably vertically and engageable with each other when the platen resides atop and in contact with the platen support. The projection and recess of each set are slidable vertically so as to be disengageable from each other when the platen is raised above the platen support. When the platen rests atop the platen support, the projection extends into the recess to immobilize the platen from all movement other than vertical movement relative to the platen support. When the platen is raised above the platen support, the projection and recess in each set disengage from each other and the platen is freely movable and totally detached from the platen support.
A single registration set comprising a single projection and a single recess may be utilized to make the system operable. In such an embodiment the projection and recess must each be configured to have a mating, noncircular cross-section. For example, a projection and recess may both have a mating polygonal or oval cross-section. The cross-sectional dimensions of the recess are just slightly larger than those of the projection, so that the projection fits smoothly into the recess, but is prevented from any movement relative thereto other than in a vertical direction. The projection may be formed to extend downwardly from the platen with the recess formed in the platen support. Conversely, the recess may be formed in the platen with the projection extending upwardly from the platen support. All such variations are encompassed within the scope of the present invention.
In the preferred embodiment of the invention a plurality of registration sets of projections and recesses are defined in the platen and platen support, and all of said projections and recesses have mating, circular cross-sections. Preferably also, the projections are formed to extend downwardly from the platen while the mating recesses are formed in the platen support.
In another broad aspect the invention may be considered to be the combination of a transportable platen and a platen support for a garment printing machine having at least one horizontally extending garment receiving arm upon which the platen support is secured. The transportable platen is freely removable from the platen support. The transportable platen is comprised of a horizontally extending garment mount having a flat, horizontal upwardly facing garment support surface with a peripheral margin thereabout. The mount further includes an apparatus for immobilizing at least a print receiving portion of a garment positioned thereon relative to the transportable platen and for urging the print receiving portion of the garment into contact with the horizontal, upwardly facing garment support surface of the transportable platen. The transportable platen together with the platen support have at least one mating, vertically extending projection and at least one vertically extending recess that are slidably engageable with each other in a vertical direction when the transportable platen resides atop and in contact with the platen support. The projection and recess are slidingly disengageable from each other in a vertical direction when the transportable platen is lifted from the platen support in vertical separation therefrom. When the transportable platen resides atop the platen support, the projection extends into the recess to mobilize the transportable platen from all movement other than vertical movement relative to the platen support. When the transportable platen is raised above the platen support the projection and recess disengage and the transportable platen is freely and totally detached from the platen support.
In another broad aspect the invention may be considered to be a platen for use on a garment printing machine for printing on a garment having a print receiving portion, a forward portion, a rearward portion, and a capturable portion. The platen is comprised of a horizontally extending garment mount, and a stretching apparatus. The garment mount includes: a rigid base plate having an undersurface, an upper surface, a forward end and an opposing rear end; a spacer secured atop the rigid base plate; and a print panel support plate. The print panel support plate has a bottom surface and a top, flat upwardly facing surface for supporting at least the print receiving portion of the garment. The print panel support plate is secured at the bottom surface thereof atop the spacer so as to create at least a first gap between the bottom surface of the print panel support plate and the upper surface of the base plate. This gap is adapted to receive a part of the garment therewithin so that the print receiving portion of the garment resides atop the upwardly facing surface of the print panel support plate. At least a part of the stretching apparatus is located above the garment mount and is advanceable downwardly toward the garment mount to stretch the print receiving portion of the garment in at least a fore and aft direction relative to the forward portion and the rearward portion of the garment. The stretching apparatus holds the capturable portion of the garment between the rigid baseplate and the print panel support plate and presses the print receiving portion of the garment against the upwardly facing surface of the print panel support plate while immobilizing the print receiving portion of the garment relative to the garment mount.
Garments to which printing is applied are primarily shirts, such as T-shirts and sweatshirts. Other types of garments, such as hats, shorts, pants, scarves are also imprinted with designs, logos and lettering utilizing the conventional and digital printing machines of the type previously described herein. The present invention is applicable to virtually any type of garment.
Printing upon hats involves difficulties not encountered in printing upon other types of garments. Hats, by their nature, do not readily present flat surfaces upon which designs, logos and lettering can be easily printed. The present invention provides a transportable platen with a unique construction that facilitates printing upon both the forehead area and the bill or visor area of a hat.
The transportable platen of the invention that is particularly applicable to printing on hats employs a front panel wrap locking system. This allows the printing machine operator to tuck in and secure the hat atop the flat top surface of the print panel support plate in such a manner as to facilitate rapid loading and unloading of the hat. Moreover, the top of the bill of the hat is flattened so as to keep it out of the way of the printing mechanism of a conventional garment printing machine and also allow clear printing on it.
The platen of the invention may be used both on screen printing and digital printing machines. The platen holds the garment tightly in position so that the artwork or other printed material is printed exactly at the proper location of the garment. Unlike many prior garment printing systems, the platen of the invention employs no clamps or clips in order to hold the garment immobilized relative to the print receiving support surface of the platen.
In still another broad aspect the invention is a method of imprinting garments utilizing a plurality of platens adapted to receive a garment thereon having a print receiving portion each of the platen is comprised of:
a flat top surface and an undersurface, preferably with at least one registration projection depending vertically therefrom, and a garment depressing mechanism engageable with the garment to urge the print receiving portion of the garment into contact with the flat top surface of the platen. The steps of the invention comprise:
mounting a garment to be printed on a first of the platens,
employing the garment depressing mechanism to urge the print receiving portion of the garment into contact with the flat top surface of the platen,
removing a second of the plurality of platens having a garment mounted thereon that has already been imprinted with ink by a printing machine by lifting a the second platen vertically upwardly from a platen support attached to a garment receiving arm of the printing machine, and replacing it by placing the first platen on the garment support thereby mmobilizing the first platen from all but vertical movement relative to the platen support. When registration pins depending from the underside of the platen are provided, the registration pins fit into corresponding apertures in the platen support to perform this function. The printing process of the invention continues by actuating the printing machine to imprint ink upon the print receiving portion of the garment mounted up on the first platen. The first platen is thereafter removed from the platen support by lifting it vertically upwardly therefrom. The garment mounted on the first platen is then removed from it.
The invention may be described with greater clarity and particularity by reference to the accompanying drawings.
For purposes of reference throughout this specification, the directions fore and aft and longitudinal should be considered as parallel to the alignment of the garment receiving arm 12 on the printing machine 10, with forward referring to the direction toward the console of 11 and aft referring to the direction away from the console 11. Foreword also refers to the location closest to the console 11 of the digitized printing machine 10, while rearward and aft respectively refer to the direction and location most distant from the console 11 of the digitized printing machine 10. Lateral refers to the direction or alignment perpendicular to the alignment of the garment receiving arm 12.
The garment receiving arm 12 may be considered to extend in a rearword or aft direction relative to the garment printing machine console 11. The mechanism of the invention is also comprised of a transportable platen 16 that is freely removable from the platen support 14, but is also engageable therewith as illustrated in
As illustrated in
The guide mount 18 further includes an apparatus for immobilizing at least a print receiving portion 30 of a garment, which may be a hat 32 as illustrated. In
The hat 32 has a forward portion 34, which is a bill or visor of the hat 32, a print receiving portion 30, a rear portion 36, best shown in
The horizontally extending garment mount 18 of the platen 16 includes a spacer in the form of a pedestal 40 that is secured atop the upper surface 22 of the rigid baseplate 20 and a flat rigid print panel support plate 42. The spacer pedestal 40 holds the print panel support plate 42 immovable and parallel to the rigid baseplate 20. The print panel support plate 42 has a bottom surface 44 and a flat top print receiving support surface 46. The print panel support plate 42 is secured at its bottom surface 44 atop the pedestal 40 and overhangs the pedestal 40 so as to create opposing first and second gaps 48 and 50, respectively. The gaps 48 and 50 are located between the bottom surface 44 of the print panel support plate 42 and the upper surface 22 of the baseplate 20.
The platen 16 also includes a stretching apparatus comprised of a fabric depressing mechanism 52 and a fabric pulling mechanism 53. These are comprised of first and second independently movable elements, a hold down bar 64 and a fabric engaging rod 54. At least a part of the fabric pulling mechanism 53, specifically the transversely extending fabric engaging rod 54, extends across the entire width of the base plate 20 in vertical separation from the upper surface 22 thereof. The fabric engaging rod 54 is located above the garment mount 18 and is advanceable downwardly toward the garment mount 18, from the position shown in
The independently movable elements 64 and 54 of the garment depressing mechanism 52 and the fabric pulling mechanism 53 together stretch the print receiving portion 30 of the hat 32 in at least a fore and aft direction relative to the forward portion 34 and the rearward portion 36 of the garment 32 while holding the capturable portion 38 of the garment 32 between the rigid base plate 20 and the print panel support plate 42. The stretching apparatus presses the print receiving portion 30 of the garment 32 against the upwardly facing surface 46 of the print panel support plate 42 while immobilizing the print receiving portion 30 of the garment 32 relative to the print panel support plate 42 and the garment mount 18.
The first independently movable element of the garment depressing mechanism 52, the hold down bar 64 has opposing end extremities 66 and 68. The hold down bar 64 is carried by a pair of mounting arms 78 and 79 that are located on opposite sides of the rigid base plate 20. The mounting arms 78 and 79 each have a proximal end 82 and a distal end 84. The distal ends 84 are connected to the opposing end extremities 66 and 68 of the first independently movable element, the hold down bar 64. The proximal ends 82 of the mounting arms 78 and 79 are secured to the garment mount 18 on opposite sides of the rigid base plate 20 by hinged connections 104 on the guide strips 26.
The second independently movable element 54 of the fabric pulling mechanism 53 is a fabric engaging rod 54. The fabric engaging rod 54 is carried by a pair of stretching arms 88 and 90 each having a proximal end 83 and a distal end 85. The stretching arms 88 and 90 are located on opposite sides of the garment mount 18. The distal ends 85 of the stretching arms 88 and 90 are connected to the end extremities 55 and 57 of the transverse independently movable member, the fabric engaging rod 54.
The proximal ends 83 of the stretching arms 88 and 90 are located below the top upwardly facing service 22 of the base plate 20. The proximal ends 83 of the stretching arms 88 and 90 are secured to the garment mount 18 on opposite sides thereof at hinged connections 80. The hinged connections 80 are located on a first, common transverse axis of rotation 87 beneath the upper surface 22 of the base plate 20 and forwardly from the spacer pedestal 40. The stretching arms 88 and 90 carry the transverse fabric engaging rod member 54 in rotational movement relative to the base plate 20 so that the transverse fabric engaging rod member 54 is movable in rotation to a position at the second gap 50, horizontally aligned with the second gap 50 behind the spacer pedestal 42.
Each of the stretching arms 88 and 90 is comprised of a piston rod 95, a piston 94, a cylinder 96 and a spring 98, visible in the sectioned portion of drawing
This force directed outwardly from the hinged connections 80 tends to push the pistons 94 distally outwardly within the cylinders 96. The spring 98 in each stretching arm 88 and 90 thereby biases the piston 94 toward the distal end of each cylinder 96 to urge the stretching arms 88 and 90 toward a retracted position illustrated in
The extension of the stretching arms 88 and 90 to the extended position of
Together the stretching apparatus 53 and the depressing apparatus 52 immobilize the print receiving portion 30 of the hat 32 by pulling the print receiving portion 30 downwardly onto and tightly against the top, flat upwardly facing surface 46 of the print panel support plate 42 as illustrated in
The proximal ends 82 of the mounting arms 78 and 79 are mounted to the guide strips 26 of the garment mount 18 by the hinged connections 104, shown in
The hat platen 16 is also provided with a plurality of reciprocally movable, cylindrical locking pins 109, visible in
Once the platen 16 is lowered onto the master loading and unloading station 114, the knobs 111 may be pushed toward each other, thereby pushing the locking pins 109 into their locking positions residing in contact with the lower edge 122 of the peripheral skirt of the platform 118 of the master loading and unloading station 114. The purpose of the locking pins 109 is to hold the platen 16 in position on the master loading and unloading station 114 during removal of a printed hat 32 and loading of the next hat 32 to be printed onto the platen 16. The locking pins 109 prevent the hat platen 16 from being pulled up from the platform 118 when the stretching arms 78 and 79 are pulled to their extended position and rotated clockwise as viewed in
In the embodiment of the transportable hat platen 16 illustrated in
The platen 16 and the platen support 14 are provided with at least one registration set of at least one mating, vertically extending projection and at least one vertically extending recess. Preferably, a plurality of identical, interchangeable, transportable platens 16 are employed in the mechanism of the invention and a plurality of sets of mating projections and recesses are provided for each platen and the platen support. Preferably also, the projections are formed as a plurality of positioning pins 108 depending from the lower surface 24 of the baseplate 20 of each platen 16. The recesses are preferably formed as a corresponding plurality of positioning apertures 110 defined through the structure of the platen support 14, as illustrated in
The invention preferably employs a master unloading and loading station 114 illustrated in
The assembly platform 118 is equipped with positioning apertures 134, illustrated in
In the garment loading and unloading position in which the platen 116 rests atop the assembly platform 118 of the master unloading and loading station 114, illustrated in
The apertures 110 in the platen support 14 are the same diameter and are spaced the same distance apart as the apertures 134 in the assembly platform 118. The platen support 14 is illustrated in detail in
The set screw 146 is part of the coupling mechanism 148, illustrated in
A typical conventional coupling mechanism 148 is depicted in detail in
More specifically, the conventional elevation adjustment mechanism 160 includes a cup 162 with a central, axial, vertical, cylindrical socket 172 formed therewithin The cup 162 is rotatable relative to the garment receiving arm 12 by means of a lever 164. Defined within the cup 162 are three spiral flights of steps having landings 166 located at ascending elevations within the cup 162. The platen support 14 of the present invention includes three corresponding generally cylindrical pegs 168 depending from the underside of the slab 140. The pegs 168 are located at a radial distance from the center post 142 equal to the radial distance of the spiral step landings 166 in the cup 162. The diameter of the center post 142 fits snugly into the central socket 172 of the elevation adjustment mechanism 160.
The lower extremities of the pegs 168 all rest at landings 166 that are of the same height in each of the three spiral flights of steps. The specific landings 166 upon which the pegs 168 rest is determined by rotation of the cup 162 by means of the handle 164. The platen support 14 may be elevated and lowered by rotation of the cup 162, but is prevented from any horizontal shifting or rotational movement by the constraint provided by the center post 142 in the socket 172 and the engagement of the flange 147 in the notch 150.
The positioning pegs 168 that depend from the underside of the slab 140 of the platen support 14 fit into the corresponding positioning receptacles, namely the landings 166 in the cup 162 on the garment receiving arm 12 of the garment printing machine 10. The interaction between the positioning pegs 168 and the landings 160, together with the positioning restraint provided by the projection of the flange 147 into the notch 150 in the bracket 152 on the garment receiving arm 12 prevents horizontal movement of the platen support 14, and consequently the platen 16 and as well, when the platen support 14 rests atop the garment receiving arm 12. However, when the set screw 146 is released by counterclockwise rotation of the handle 174, the garment support 14 is free to move vertically relative to the garment receiving arm 12 and its elevation may be adjusted relative thereto.
When the hat platen 16 is seated atop the garment support 14 as illustrated in
However, the platen 16 is freely movable in a vertical direction. Consequently, once the hat 32 has been imprinted, as illustrated in
The chronological sequence of utilization of the transportable platens 16 of the invention may be described in the following manner. At the start of operations, the platen support 14 is first positioned for a production run relative to the garment receiving arm 12 of the digitized printing machine 10 by adjusting the elevation adjusting mechanism 160, and by locking the set screw 146 against the flat 144 of the central post 142 of the platen support 14.
Once the handle 164 has been rotated to raise or lower the pegs 168 to the desired elevation, the set screw 146 is locked by clockwise rotation of the set screw handle 174. Once the handle 174 has locked the set screw 146 against the flat 144 of the center post 142, the platen support 14 is totally immobilized relative to the coupling mechanism 148 which is secured to the longitudinally projecting end of the garment receiving arm 12 of the digitized printing machine 10, as illustrated in
The platens 16 of the present invention, however, are transportable and may be quickly and easily removed from the platen support 14 when the garment receiving arm 12 is extended as shown in
To commence a printing run an unloaded platen 16 is first mounted onto the master garment transfer unloading and loading station 114 by simply positioning the platen 16 above the master garment transfer unloading and loading station 114, as illustrated in
For the first hat 32 to be printed, the transportable platen 16 is initially empty, as illustrated in
The hat 32 illustrated in
Once the transportable platen 16 is seated atop the master transfer unloading and loading station 114, as illustrated in
The printed hat 32 can then easily be pulled free from the hat platen 16 from the position shown in
The next hat 32 to be printed is then loaded onto the transportable platen 16 while the platen 16 remains seated atop the garment transfer unloading and loading station 114. The next hat 32 to be printed is placed atop the hat platen 16 by manually placing the print receiving portion 30 on the top upwardly facing surface 46 of the print panel support plate 42. The front portion 34, the bill of the next hat 32 to be printed, is manually pressed downwardly against the upper surface 22 of the baseplate 20. Once the hat bill 34 is atop the front portion of the baseplate 20 the capturable portion 38 of the hat 32, which is the extreme forward portion of the crown of the hat and the front portion of the hat band, is manually pushed into the first forwardly opening gap 48 between the baseplate 20 and the print panel support plate 42. The capturable portion 38 is manually forced into the first gap 48 by placing the forward portion 34, the bill of the hat 32, atop the upper surface 22 of the rigid base plate 20 and manually sliding it rearwardly toward the gap 48, thereby forcing the capturable portion 38 of the hat 32 into the gap 48.
The mount arms 78 and 79 are then rotated rearwardly in a counterclockwise direction, as viewed in
The print receiving area 30 of the hat 32 is then pulled rearwardly and downwardly atop the print panel support plate 42. The rear portion 36 of the hat 32 is then manually pulled rearwardly beneath the fabric engaging rod 54 and a part of the rear portion 36 of the hat 32 closest to the print receiving portion 30 is manually pushed into the second, rear gap 50, as shown in
The fabric engaging rod 54 is then released so that the springs 98 within the stretching arms 88 and 90 pull the cylinder 96 forwardly toward the hinge connections 80 and axis of rotation 87, thereby pushing the pistons 94 further toward the distal ends 85 of the stretching arms 88 and 90 and shortening the overall length of the stretching arms 88 and 90. This action causes they fabric engaging rod 54 to lurch forward into the gap 50 stretching the fabric and pulling the print receiving portion 30 of the hat 32 tightly into intimate contact with the upwardly spacing surface 46 of the print panel support plate 42.
Once the next hat 32 to be printed is loaded onto the transportable platen 16, as illustrated in
The entire process of withdrawing the transportable platen 16 with the printed hat 32 thereon from the platen support 14, placing it next to the master garment transfer unloading and loading station 114, lifting a second platen 16 with the next hat 32 preloaded thereon from the master garment transfer unloading and loading station 114 and moving it on to the platen support 14, takes only about four seconds. That is, it takes only about four seconds from the time the garment receiving arm 12 moves rearwardly to bring the printed hat 32 into the position illustrated in
It takes about 16 seconds to place the platen with the printed hat 32 on it onto the master unloading and reloading station 114, remove the printed hat 32 from that transportable platen 16, and load the next hat 32 to be printed thereon. However, unlike prior garment printing systems, the printing machine 10 is not idle during this time. To the contrary, while the operator is exchanging the printed hat for the next hat to be printed on one transportable platen 16 at the garment transfer unloading and loading station 114, the printing machine 10 is engaged in the process of printing an image on the hat 32 located atop an identical platen 16 within the printing machine 10. The printing process itself takes approximately 30 seconds. Consequently, the next hat 32 to be imprinted is positioned on one of the interchangeable platens 16 and that loaded transportable platen 16 is ready for placement on the platen support 14 well before the printing machine 10 extends the printing arm 12 for removal of the transportable platen 16 with the printed hat 32 thereon.
The time-saving achieved is approximately 12 seconds per hat 32. For a printing run of 1000 hats, therefore, the time-saving is about 200 minutes, well over three hours. Therefore, the present invention provides a very considerable savings in efficiency of printing garments.
A transportable garment printing platen in accordance with the invention may be utilized to print garments other than hats.
The transportable platen 16 of the invention may also be utilized with garment screen printing machines as well as garment digitized printing machines.
The attachment mechanism for securing the platen support 214 is somewhat different, however, due to the difference in design of garment receiving arms on a screen printing machine from those on a digitized garment printing machine 10.
The screen printing machine 310 has different screens, three of which are illustrated at 314, 316 and 318 each mounted on a screen carrying arm 320. The arms 320 are mounted upon a hub or turntable 321 and may be independently rotated downwardly toward the platen 16 from the positions illustrated in
More specifically, as illustrated in
It should be noted that when the platen 16 is utilized with the screen printing machine 310 illustrated in
Platens suitable for use in printing on shirts, operating on the same principles, but with a somewhat different construction are also within the scope of the present invention. For example,
A platen support 414 is illustrated in
As with the transportable platen 16, there is a master garment loading and unloading station 514 for the platen 416, illustrated in
The assembly platform 518 has side edges spaced apart a uniform distance equal to the width of the top plate or slab 418 of the platen support 414 so as to prevent lateral movement of the baseplate 420 of the platen 416 relative to the assembly platform 518. Lateral movement is prevented since the guide strips 426 depending from the underside of the baseplate 420 reside snugly against the outer side edges 515 of the assembly platform 518 so as to slidingly embrace the side edges 515 of the assembly platform 518 between them and laterally center the platen 416 relative to the assembly platform 518. The platen 416 is moved forwardly or rearwardly, if necessary, until the vertically extending projection pins 408 drop into the corresponding apertures 510 in the assembly platform 518 so that the platen 416 is seated upon the master garment loading and unloading station 514.
The master loading and unloading station 514 has a generally rectangular, laterally elongated window 521 defined through the assembly platform 518. A cylindrical roller 523 is mounted in the master loading and unloading station 514 for rotation about a horizontal, laterally extending axis of rotation 525. A portion of the roller 523 protrudes upwardly through the laterally extending window 521 and is freely rotatable relative to the master loading and unloading station 514.
The transportable platen 416 has a another feature that is not in the transportable platen 16. The platen baseplate 420 also has a generally rectangular, laterally elongated window 421 defined therethrough proximate the forward end of the platen baseplate 420 and remote from the spacing strip 440. The window 421 resides in vertical registration and congruent alignment with the window 521 in the assembly platform 518 when the platen 416 is seated atop the master loading and unloading station 514. The roller 523 also protrudes through the window 421 of the baseplate 420 as well as the window 521 of the assembly platform 518 when the platen 416 is positioned atop the assembly platform 518 and the vertically extending projections 408 protruding from the underside of the platen baseplate 420 reside in mating engagement with the vertically extending apertures 510 in the assembly platform 518.
The laterally extending spacing strip 440 is located at the rear end of the platen 416 and is thereby remote from the window 421 in the baseplate 420. As shown in
Once a garment, such as a shirt 432, is mounted on the platen 416, the force of gravity causing the print panel support 442 to sag downwardly will tend to immobilize the shirt 432 relative to the platen 416. However, when the platen 416 is positioned atop the master loading and unloading station 514, the roller 523, while protruding through the window 421 defined through the baseplate 420, will press upwardly against the undersurface of the print panel support 442, thereby lifting the forward end of the print panel support 442 slightly up and out of contact with the baseplate 420. This facilitates the loading of a shirt 432 on to the platen 416.
More specifically, if an image is to be printed on the chest portion 431 of the shirt 432, the opposing back portion 433 of the shirt is inserted in between the baseplate 420 and the print panel support 442 at the forward end of the platen 416 remote from the spacing strip 440, as shown in
This action of pulling the shirt 432 from right to left, as viewed in
Even greater immobilization of the shirt 432 is provided by using an open frame 425, forming a part of the platen 416. The frame 425 may be lowered into position onto the print panel support 442. The frame 425 is illustrated in
The structure of the frame 425 therefore extends vertically no higher than the central region of the print support panel 442. Consequently, the frame 425 exerts an immobilizing force on the upwardly facing surface of the garment 432, but does not project above the print receiving surface 431 of the garment 432 located within the window 427 of the frame 425. The frame 425 therefore does not project above the top surface of the print panel support 442 and therefore does not interfere with contact of the print screens 314, 316 and 318 against the print receiving chest portion 431 of the shirt 432 when the transportable platen 416 is used in the screen printing machine illustrated in
The frame 425 likewise does not interfere with any vertical adjustment of spacing between the print receiving surface portion 431 of the garment 432 and the inkjets at the printing station when the platen 416 is used with the digitized printing machine 10. Moreover, when the frame 425 is lowered onto the print panel support plate 442 while the print receiving portion 431 of said garment 432 is positioned atop the top, upwardly facing surface 446 of the print panel support plate 442, the capturable portion 427 of the garment 432 surrounds the print receiving portion 431 of the garment 432. The rim 429 presses the capturable portion 427 of the garment 432 into the recessed, peripheral margin 430 of the print panel support plate 442, thereby stretching the print receiving portion 431 in fore and aft and all lateral directions and pressing the print receiving portion 431 of the garment 432 against the upwardly facing surface 446 of the print panel support plate 442. The frame 425 thereby immobilizes the print receiving portion 431 of the garment 432 relative to the print panel support plate 442.
The transportable platen 416 is utilized with a platen support 414, illustrated in
The steps in loading and unloading shirts 432 using the platen 416 and the platen support 414 are quite similar to the steps employed in loading and unloading hats 32 using the platen 16. Specifically, one platen 414 is first positioned atop the garment mounting station 514. A portion 433 of a shirt 432 is pulled in between the platen baseplate 420 and the print panel support plate 442 while the portion 431 of the shirt to receive the imprint is pulled on top of the print panel support plate 442. Loading of the shirt 432 is from right to left, as viewed in
At the start of operations, the platen support 414 is first positioned for a production run relative to the garment receiving arm 12 of the digitized printing machine 10 by adjusting the elevation adjusting mechanism 160, and by locking the set screw 146 against the flat 144 of the central post 142 of the platen support 414.
Once the handle 164 has been rotated to raise or lower the pegs 168 to the desired elevation, the set screw 146 is locked by clockwise rotation of the set screw handle 174. Once the handle 174 has locked the set screw 146 against the flat 144 of the center post 142, the platen support 414 is totally immobilized relative to the coupling mechanism 148 which is secured to the longitudinally projecting rear end of the garment receiving arm 12 of the digitized printing machine 10, as in a manner similar to that illustrated in
The platen 416 of the present invention, however, is transportable and may be quickly and easily removed from the platen support 414 when the garment receiving arm 12 is extended as shown in
To commence a printing run an unloaded platen 416 is first positioned onto the master garment transfer unloading and loading station 514 by simply positioning the platen 416 above the master garment transfer unloading and loading station 514, as illustrated in
For the first shirt 432 to be printed, the transportable platen 416 is initially empty. However, for all subsequent shirts the transportable platen 416 will bear a printed shirt 432. The shirt 432 on the transportable platen 16 that has just been removed from the platen support 414 will bear an imprintation.
Once the transportable platen 416 is seated atop the master transfer unloading and loading station 514, the frame 425 is lifted upwardly, free from the printed shirt 432 and also the print panel support plate 442. The printed shirt 432 is then pulled free from the print panel support plate 442 and the baseplate 420 by pulling it off the platen 416 from left to right, as viewed in
The next shirt 432 to be printed is then loaded onto the transportable platen 416 while it remains seated atop the garment transfer unloading and loading station 514. The shirt is pulled onto the print panel support plate 442 from right to left, as viewed in
Once the next shirt 432 to be printed is loaded onto the transportable platen 416, as illustrated in
The entire process of withdrawing the transportable platen 416 with the printed shirt 432 loaded thereon from the platen support 414, placing it on the garment transfer unloading and loading station 514, unloading and removing the printed shirt 432, reloading the transportable platen 416 with the next shirt 432 to be printed, lifting the platen 416 from the garment transfer unloading and loading station 514 and returning it to the platen support 414, takes only about four seconds.
Undoubtedly, numerous variations and modifications of the invention will become readily apparent to those familiar with garment printing. Accordingly, the scope of the invention should not be construed as limited to the specific embodiments depicted and the method of implementation described, but rather is defined in the claims appended hereto.
The present application is a continuation in part of U.S. application Ser. No. 15/732,624 filed Dec. 1, 2017, currently pending.
Number | Name | Date | Kind |
---|---|---|---|
4478144 | Maloof | Oct 1984 | A |
4753161 | Kimball | Jun 1988 | A |
4819559 | Szarka | Apr 1989 | A |
5014614 | Thieme | May 1991 | A |
5090313 | Chapman | Feb 1992 | A |
5107758 | Withers | Apr 1992 | A |
5161466 | Burris | Nov 1992 | A |
5588770 | Bart | Dec 1996 | A |
6095628 | Rhome | Aug 2000 | A |
6640714 | Papa | Nov 2003 | B1 |
6775934 | Gallik | Aug 2004 | B1 |
6908190 | Iwatsuki | Jun 2005 | B2 |
7765927 | Liu | Aug 2010 | B1 |
9085849 | Takeuchi | Jul 2015 | B2 |
9434187 | Mashima | Sep 2016 | B2 |
10046553 | Hoffman, Jr. | Aug 2018 | B2 |
20050068400 | Niimi | Mar 2005 | A1 |
20090188404 | Styles | Jul 2009 | A1 |
20090223391 | Keith | Sep 2009 | A1 |
20130017330 | Padilla | Jan 2013 | A1 |
Number | Date | Country |
---|---|---|
104487256 | Apr 2015 | CN |
Entry |
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“Little Sister System II” S&K Mfg. www.littlesister.com Pub. date unknown Retrieved Oct. 3, 2017. |
“Brother GT-541 Little Sister Sys vs. Factory Platen” S&K Mfg. screen shots 1-4 www.youtube.com/watch?v=NYeQU-jLMBc&t=167s Robt. Bohannan Publ. May 25, 2009 Retrieved Oct. 3, 2017. |
“Brother GT-541 Little Sister vs. Factory Platen” S&K Mfg. www.youtu.be/dTwHZpcvJZc Robt. Bohannan Publ. May 25, 2009 Retrieved Oct. 3, 2017. |
“Brother GT-541 Little Sister System-GT541-DGT” S&K Mfg. www.youtube.com/watch?v=5ByWm9TQy8E Robt. Bohannan Publ. May 2, 2009 Retrieved Oct. 3, 2017. |
“How to Assemble the Little Sister System II” S&K Mfg. www.youtube.com/watch?v=EmmuAft=II Robt. Bohannan Publ. Feb. 18, 2013 Retrieved Oct. 3, 2017. |
“Little Sister System GT-541 GT541—Platen for Rt to Lft—oversized prints” S&K Mfg. www.youtube.com/watch?v=CsonkLYYfW8 Robt. Bohannan Publ. Apr. 22, 2010 Retrieved Oct. 3, 2017. |
“Little Sister System GT-541 GT541—Sleeve Pattern” S&K Mfg. www.youtube.com/watch?v-KFBLn5aMWg Robert Bohannan Publ. Apr. 22, 2010 Retrieved Oct. 3, 2017. |
“Little Sister System Top to Bottom Oversized Platen for GT-541” S&K Mfg. www.youtube.com/watch?v=s6JgkcFcL30 Robert Bohannan Publ. Apr. 22, 2010 Retrieved Oct. 3, 2017. |
“Little Sister System GT-541 Neck Pattern” S&K Mfg. www.youtube.com/watch?v=OG6RUBPzURw Robert Bohannan Publ. Apr. 22, 2010 Retrieved Oct. 3, 2017. |
“Little Sister System Full Sleeve and Neckline Platen” S&K Mfg. www.youtube.com/watch?v=AjsLhLswlFw Robert Bohannan Publ. Sep. 3, 2009 Retrieved Oct. 3, 2017. |
“Little Sister System Oversized Printing Right to Left for Brother GT-541” S&K Mfg. https://www.youtube.com/watch?v=Lthbj Robert Bohannan Publ. Sep. 3, 2009 Retrieved Oct. 3, 2017. |
“Little Sister System Top to Bottom LSSCS for Brother” S&K Mfg. www.youtube.com/watch?v=SzwJu5-dAel Robert Bohannan Publ. Sep. 3, 2009 Retrieved Oct. 3, 2017. |
“Little Sister System Top to Bottom and Shoulder to Shoulder” S&K Mfg. www.youtube.com/watch?v=O6hefEc8Xlk Robert Bohannan Publ. Jun. 1, 2009 Retrieved Oct. 3, 2017. |
“GT 381 GT-3 Series Garment Printer with CMYK and 4 White Print Heads” Brothers USA Specification 2 pages www.brother-usa.com Publ. date unknown Retrieved Oct. 3, 2017. |
Workhorse Odyssey Press—6 Color/4 Station www.anthemprintingsf.com Publ. date unknown Retrieved Oct. 3, 2017. |
“Start Printing Caps on Your GT Printer” GT Cap Platen www,capplaten.com Publ. date unknown Retrieved Oct. 3, 2017. |
“Features of the GT Cap Platen” GT Cap Platen www,capplaten.com/features.html#easy Publ. date unknown Retrieved Oct. 3, 2017. |
“Hat Champ” Livington Systems www.livingstonsystems.com/product-category/screen-printing/hat-champ Publ. date unknown Retrieved Oct. 3, 2017. |
“Fernando Cap Platen” Stitch City photos 1-12 taken at public demonstration performed on Apr. 27, 2017. |
“Cap Platen Insert T-Lock Platen—Multipurpose Platen for Brother GT-541 GT-782 GT-3 Printers” T Lock Platen tlockplaten.com/cap-platen/ Pub date unknown Retrieved Oct. 3, 2017. |
Polyprint Screen to DTG Mix at ISS Long Beach 2017 Shirt Printing Thedtgprinter.com youtu.be/dTwHZpcvJZc Publ Jan. 13, 2017 Retrieved Oct. 22, 2017. |
“Polyprint's Texjet Plus Advanced DTG Printer—Screen & Digital Mix” Amaga UK www.youtube.com/watch?v=yBzQ63VHDg4 Publ May 28, 2015 Retrieved Oct. 22, 2017. |
“Polyprint FESPA hybrid demo 02” Junga Nagata riso www.youtube.com/watch?v=vGR1MdJospA Publ Jun. 17, 2015 Retrieved Oct. 22, 2017. |
“GOCCOPRO screen print & DTG combination print” Junya Nagata riso www.youtube.com/watch?v=wRU2vffPGSE Publ Dec. 26, 2015 Retrieved Oct. 22, 2017. |
Number | Date | Country | |
---|---|---|---|
20200223236 A1 | Jul 2020 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 15732624 | Dec 2017 | US |
Child | 16873238 | US |