Page binding support tray having vibratory page alignment

Information

  • Patent Grant
  • 6631897
  • Patent Number
    6,631,897
  • Date Filed
    Saturday, November 25, 2000
    24 years ago
  • Date Issued
    Tuesday, October 14, 2003
    21 years ago
Abstract
A page binding support tray has vibratory page alignment. The tray has a floor having a lower-most corner at which two side walls of the tray converge. Previously edge-glued printed uniformly sized pages are received to form a stack upon the tray floor and vibration of the tray ensures that edges of the page bear against the side walls of the tray to align the pages prior to edge-pressing.
Description




FIELD OF THE INVENTION




The following invention relates to a page binding support tray having vibratory page alignment. More particularly, though not exclusively, the invention relates to a page binding support tray to receive a number of pre-edge glued, uniformly sized printed pages and to ensure alignment of those pages prior to pressing the pre-glued edges together.




It is well known to print individual pages of a volume to be bound, then to place all of the printed pages into a stack, to then crop one or more edges of the stack and to then bind the pages together by applying a binding adhesive to an edge of the stack of pages. This is a time consuming and labour-intensive process.




It would be more efficient to provide pre-cut, uniformly sized pages, to print one or both surfaces of each page and to provide a strip of binding adhesive to one or both surfaces of each page adjacent the edge to be bound, to accurately place the printed and pre-glued pages in a stack, and to press the pages adjacent the spine so that the adhesive binds the page edges together.




It would also be desirable to provide a page binding support tray having vibratory page alignment to ensure alignment of the pages prior to pressing.




OBJECT OF THE INVENTION




It is the object of the invention to provide a page binding support tray having vibratory page alignment.




DISCLOSURE OF THE INVENTION




There is disclosed herein an apparatus comprising:




a support tray for receiving a stack of printed pages having binding adhesive applied adjacent an edge of at least one of the pages, and




a vibrator interacting with the tray so as to induce vibration therein to assist in alignment of the pages of the stack.




Preferably the tray has a support surface having one corner that is lower than other portions of the support surface.




Preferably the tray has at least two side walls extending substantially perpendicularly to each other and against which perpendicular edges of the pages bear for alignment of the pages within the stack.




Preferably vibration of the tray is dampened by dampers.




Preferably the tray is supported by a frame.




Preferably the tray is suspended from the frame.




Preferably the dampers extend from the tray to the frame.




Preferably the vibrator is a subsonic vibrator.




Preferably means are provided to alter a level of the support surface of the tray so as to ensure that an upper page of the stack is situated at a predefined level for interaction with an edge-pressing device.




There is further disclosed herein a method of aligning pages in a stack of pages, the method including the steps of:




delivering pages one upon another to a tray so as to form a stack of pages, and




during and/or after said step of delivering, inducing vibration in the tray.











BRIEF DESCRIPTION OF THE DRAWINGS




Preferred forms of the present invention will now be described by way of example with reference to the accompanying drawings wherein:





FIG. 1

is a schematic illustration of a page conveyed along a path and passing a pagewidth print head and an adhesive applicator;





FIG. 2

is a schematic illustration of a page having an adhesive strip adjacent one edge thereof;





FIG. 3

is a table, schematically illustrating the principles of five alternative adhesive application methods;





FIG. 4

is a schematic elevational view of a number of pages with all but the top page having a strip of adhesive applied to an upper surface adjacent to an edge to be bound;





FIG. 5

is a schematic elevational view of a stack of pages with all but the bottom page having a strip of adhesive applied to a lower surface thereof adjacent to an edge to be bound;





FIG. 6

is a schematic elevational view of a stack of pages with a first part of a two-part adhesive applied to the upper surface of all but the top page and a second part of a two-part adhesive applied to the bottom surface of all but the bottom page,





FIG. 7

is a schematic perspective view of a page binding support tray situated immediately down-line of the adhesive applicator,





FIG. 8

is a schematic cross-sectional elevational view of the page binding support tray of

FIG. 7

showing a first page having a strip of adhesive adjacent its edge at an upper surface en route thereto,





FIG. 9

is a schematic cross-sectional elevational view of the page binding support tray and page of

FIG. 8

, with the page closer to its rest position,





FIG. 10

is a schematic cross-sectional elevational view of the page binding support tray and page of

FIGS. 8 and 9

, with the page at rest thereon,





FIGS. 11

,


12


and


13


are schematic cross-sectional elevational view of the page binding support tray showing a second page as it progresses to rest upon the first page,





FIG. 14

is a schematic cross-sectional elevational view of the page binding support tray having a number of pages resting thereon to be bound, with all but the top page having an upwardly facing strip of adhesive adjacent an edge thereof,





FIG. 15

shows the progression of a page-binding press toward the edge of the stacked pages,





FIG. 16

shows the page binding support tray with pages bound along their edge by application of the binding press,





FIG. 17

is a cross-sectional elevational view of the page binding support tray having a number of individual volumes resting thereon, with a top volume ready to be pressed,





FIG. 18

is a schematic cross-sectional elevational view of the page binding support tray and volumes of

FIG. 17

, with all volumes having been pressed, one upon another,





FIG. 19

is a schematic perspective illustration of a number of volumes having been bound,





FIG. 20

is schematic elevational view of a page binding support tray having an alternative press,





FIGS. 21 and 22

are schematic perspective views of a portion of the alternative press of

FIG. 20

, and





FIG. 23

is a schematic elevational view of a page binding support tray having an alternative press at a trailing edge of a stack of pages to be bound.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




In

FIG. 1

of the accompanying drawings there is schematically depicted a path


10


of a page


11


passing through a printer incorporating an adhesive applicator.




Page


11


is driven to the right at a driving station D. Driving station D might comprise a pair of opposed pinch rollers


12


as shown. The page


11


then passes a printing station P and then an adhesive application station A. As an alternative, the adhesive application station A might precede the printing station P, but it is preferred that the adhesive application station follow the printing station so that adhesive on the page


11


does not clog the print head or print heads at printing station P.




For single sided page printing, the printing station P might comprise a single print head


13


. The print head


13


might be a pagewidth drop on demand ink jet print head. Alternatively, the print head might be that of a laser printer or other printing device. Where the page


11


is to be printed on both sides, a pair of opposed print heads


13


might be provided.




Where the print heads


13


are ink jet print heads, wet ink


15


on page


11


might pass through the adhesive application station A.




An air cushion


14


at either side of the page


11


as it passes printing station P can be provided by means of air passing through an air flow path provided in each print head


13


.




The adhesive application station A can comprise an adhesive applicator


16


at one or both sides of the page


11


, depending upon which side or sides of the page to which adhesive is to be applied.




As shown in

FIG. 2

, a page


11


having matter printed thereon by printing station P also includes a strip


17


of adhesive as applied at adhesive application station A.




As can be seen, the strip


17


can be applied adjacent to the leading edge


27


of page


11


. The application of strip


17


adjacent to the leading edge


28


is suitable for those situations where the adhesive applicator does not contact the page, or contacts the page at a velocity accurately matching that of the page


11


as it passes the adhesive application station A. Alternatively, the strip


17


could be applied adjacent to the trailing edge


28


of page


11


and this position might be more suited to adhesive applicators that make some form of physical contact with the page


11


as it passes adhesive application station A.




A margin


29


of about 1 to 2.5 mm is desirable between the strip


17


and edge


27


or


28


of page


11


.




Various methods of applying adhesive to the page


11


are envisaged, some of which are schematically depicted in FIG.


3


.




Method


1


in

FIG. 3

is a non-contact method of applying adhesive to the moving page


11


. In this method, a stationary adhesive applicator


16


sprays adhesive on one side of page


11


as it passes the applicator. The adhesive applicator might be formed integrally with the print head


13


or might be located upstream or after the print head.




Method


2


also applies adhesive to one side of the moving page


11


, although this time using a contact method. An adhesive applicator


16



is pivotally mounted about a fixed pivot point and is caused to move at a speed matching that at which the page



11


passes through the adhesive application station. A reaction roller


30


comes into contact with the underside of page


11


as the adhesive applicator


16



applies adhesive to the page.





Method


3


applies adhesive to both sides of a page


11


as it passes through the adhesive application station. A pair of pivotally mounted adhesive applicators


16




move pivotally at a speed corresponding with that at which the page



11


passes through the adhesive application station. They both come into contact with the page


11


and mutually counteract each other's force component normal to the page


11


.




Method


4


employs a pair of adhesive applicator rollers


16





spaced from either side of the page



11


until activated to apply adhesive whereupon they move toward and touch the page


11


, leaving a strip of adhesive


17


at either side of the page. The rollers would mutually counteract each other's force component normal to page


11


.




Method


5


employs a pair of adhesive spray applicators


16





, one at either side of page



11


. The applicators do not contact page


11


. Each applicator would apply one part of a two-part adhesive to a respective side of page


11


so as to apply strips


17




a


and


17




b


. Like Method


1


, Method


5


could employ an adhesive applicator formed integrally with the print head. That is, a channel for the flow of one part of a two-part adhesive might be provided in each print head.




Also, the use of a two-part adhesive could be beneficial in situations where there might be some delay in the printing/binding operation. For example, if there were a computer software or hardware malfunction part-way through a printing/binding operation, the use of a two-part adhesive could provide sufficient time within which to rectify the problem and complete the binding process.





FIG. 4

illustrates a stack of pages


11


with all but the top page provided with an adhesive strip


17


at an upper surface adjacent one edge to be bound. An alternative is depicted in

FIG. 5

wherein all but the bottom page has an adhesive strip


17


applied to its bottom surface adjacent an edge to be bound.




In

FIG. 6

, a stack of pages is shown with part A of a two-part adhesive applied to the upper surface of all but the top page and the second part of the two-part adhesive applied to the bottom surface of all but the bottom page.




When the stacks of pages of

FIGS. 4 and 5

are pressed together, adhesion of the pages occurs once the adhesive


17


has dried.




When the pages


11


of

FIG. 6

are pressed together, the respective parts of the two-part adhesive in strips


17




a


and


17




b


combine so as to react and set.




Where print head


13


is an ink jet print head, and non-contact adhesive application Methods


1


and


5


are employed, the adhesive strip


17


is applied to page


11


before ink on the page passing through the adhesive application station


10


has dried. Air passing through air gap


14


accelerates the drying process. That is, adhesive is applied to the page as it passes out of the print head


13


. The velocity of the page


11


does not change as a result of the application of adhesive strip


17


.




Where the strip


17


is applied alongside the leading edge


27


of the page


11


, any alteration to the velocity of page


11


would adversely affect print quality. Hence application of adhesive strip


17


alongside the leading edge


27


is only possible without adversely affecting print quality using non-contact adhesive application methods or methods where the velocity of the adhesive applicator coming into contact with the page is very close to that of page


11


.




Where the adhesive strip


17


is applied alongside the trailing edge


28


of page


11


, a non-contact method or method of very close speed matching is also desired. For example, if the speed of the adhesive applicator of Methods


2


to


4


was faster than that at which the page


11


was passing the print head, the page could buckle.




A most desirable embodiment of the present invention would use a two-part adhesive and would incorporate the adhesive applicators within the print heads themselves. That is, a passage or passages for the flow of adhesive through the print head would be space and cost-effective.




The likelihood of adhesive “gumming” and blocking such channels would be diminished where a two-part adhesive was employed. That is, only one part of the two-part adhesive would pass through any particular channel or channels of the print head.




Where respective parts of a two-part adhesive are applied to opposed sides of pages


11


, those respective parts could pass through dedicated channels in the respective print head at either side of the page. This would greatly reduce the likelihood of adhesive blockages in the flow channels.




The adhesive or respective parts of a two-part adhesive can be provided in a chamber of a replaceable ink cartridge providing ink to the print head.




The print head


13


should be as close a possible to the pinch rollers


12


. This is because the rollers


12


provide a mechanical constraint upon the page


11


to enable accuracy of printing.




The pinch rollers


12


, print heads


13


and adhesive applicator


16


are illustrated in

FIG. 7

alongside a page support tray


18


. That is, the page support tray


18


receives pages


11


that exit the paper path


10


. The tray


18


is suspended from a frame


21


by means of respective dampers


22


at each corner. The dampers could be elastomeric dampers or small hydraulic or pneumatic cylinders for example. The floor of tray


11


is not level. It has a lower-most corner


23


beneath which there is provided a vibrator


19


. The vibrator


19


might be a subsonic vibrator (ie a vibrator having a frequency below 20 hz) or an out-of-balance electric motor for example. A binding press


20


is situated above the tray


18


over the at-rest position of the respective leading edge of the pages


11


. However, as an alternative, the binding press


20


could be provided so as to be situated over the trailing edge of the pages.




In

FIG. 8

a first page


11


is shown in its trajectory toward tray


18


. Page


11


has a strip of adhesive


17


on its upper surface adjacent the leading edge. The page


11


might tend to catch a pocket of air beneath it as it floats into position and the leading edge


28


might strike the vertical wall


31


as shown in FIG.


9


. The vibrations of the tray


18


as a result of the vibrator


19


will cause the page


11


to come to rest with edge


27


alongside the lower edge of wall


23


and with a right angled edge of the page touching the front wall


32


of tray


18


.




In

FIG. 11

, a second page


11


is shown in its trajectory toward tray


18


. In a motion similar to that of the first page, the second page comes to rest upon the first page in a position perfectly aligned therewith. The second page comes to rest into the position depicted in FIG.


13


. Where the pages have the adhesive strip


17


applied to the upper surface, the final page is provided without any adhesive and it comes to rest at the top of the stack as depicted in FIG.


14


. If, instead, the majority of pages


11


had the adhesive strip


17


applied to their bottom surface, the first page (ie the page at the bottom of the stack) would have no adhesive applied to it. This would be suitable for multiple binding compressions.




As shown in

FIG. 15

, the binding press


20


commences downward movement toward the stack of pages


11


over the aligned adhesive strips


17


. The stack is then compressed to a bound volume


24


as shown in FIG.


16


.




It should be noted that no subsequent edge trimming of the bound volume is required so long as standard-sized pages


11


had initially been used. This is because the vibrator


19


has aligned the pages into the lower-most corner


23


of tray


18


as described earlier.




In

FIGS. 17 and 18

, multiple volume


24


are shown stacked on upon another with the upper-most volumes being progressively compressed by repeated application of press


20


.




The binding press


20


is shown schematically in the Figures and could be pneumatically or hydraulically driven, or could be driven by other mechanical means such as rack and pinion, electrical solenoid or otherwise. An alternative embodiment as depicted in

FIGS. 20

,


21


and


22


incorporates a plurality of semicircular disks


20



each spaced apart, but fixedly mounted to a common rotatably driven shaft extending along an axis of rotation



26


. Each disk


20



could pass through a respective vertical slot



32


formed in the end wall


31


of tray


18


. That is, there would be as many vertical slots in wall


31


as there are disks


20



. The disks could commence in the orientation depicted in FIG.



21


and upon rotation of the shaft pivot to the orientation depicted in

FIGS. 20 and 22

so as to press down upon the pages.




The tray


18


might be provided with a floor of adjustable height so as to always present the top page in the tray closely to the pressing device. This would reduce noise levels by minimizing the stroke length of the binding press


20


. Furthermore, the binding press


20


could be fixed and the tray could be pushed upwardly toward it to press and bind the pages.




The floor of tray


18


can be driven so as to move downwardly as each page


11


is delivered thereto. This would ensure that the upper-most page always resided at the same level. This could result in reduced noise of movement of the press bar


20


as it need not move very far to effectively bind the pages.




Where the pages have applied thereto adhesive strips alongside the trailing edge


28


, the press would be provided to the left as shown in FIG.


23


. In this embodiment, a pressing bar


20




is provided. Any pressing arrangement could however be provided.




Claims
  • 1. An apparatus comprising:a support tray for receiving a stack of printed pages having binding adhesive applied adjacent an edge of at least one of the pages; a vibrator interacting with the tray so as to induce vibration therein to assist in alignment of the pages of the stack; a press device configured for applying a compressive force to the stack of pages, adjacent an edge of the stack, wherein a support surface of the tray is of adjustable height relative to the press device, so as to ensure that an upper page of the stack is situated at a predefined level for interaction with the press device.
  • 2. The apparatus of claim 1 wherein the tray has a support surface having one corner that is lower than other portions of the support surface.
  • 3. The apparatus of claim 2 wherein the tray has at least two side walls extending substantially perpendicularly to each other and against which perpendicular edges of the pages bear for alignment of the pages within the stack.
  • 4. The apparatus of claim 2 wherein the support surface of the tray is movable as each page is delivered thereto.
  • 5. The apparatus of claim 1 wherein the tray is supported by a frame.
  • 6. The apparatus of claim 5 wherein the tray is suspended from the frame.
  • 7. The apparatus of claim 5 wherein dampers extend from the tray to the frame.
  • 8. The apparatus of claim 1 wherein the vibrator is a subsonic vibrator.
  • 9. The apparatus of claim 1 wherein vibration of the tray is dampened by dampers.
  • 10. A method of bonding pages in a stack of pages using an apparatus comprising a tray, a vibrator and a press device, the method including the steps of:delivering pages one upon another to the tray so as to form a stack of pages, wherein at least one of the pages has binding adhesive applied adjacent an edge thereof; during and/or after said step of delivering, inducing vibration in the tray, using the vibrator; aligning the pages in the stack, within the tray, by said step of inducing vibration; adjusting the height of the support surface relative to the press device, thereby ensuring that an upper pare of the stack is situated at a predefined level for interaction with the press device; and placing a compressive force, using the press device, on the stack adjacent an edge of the stack corresponding to the edge of the at least one page to which the adhesive is applied, thereby causing the adhesive to bond the pages together.
  • 11. The method of claim 10 wherein the step of aligning the pages comprises aligning the pages in a comer of a support surface of the tray, the comer being lower than other portions of the support surface.
  • 12. The method of claim 11 wherein the tray has at least two side walls extending substantially perpendicularly to each other, and wherein the step of aligning the pages comprises causing perpendicular edges of the pages to bear, for alignment within the stack, against said side walls.
  • 13. The method of claim 11 comprising the step of adjusting the height of the support surface as each pare as each page is delivered thereto.
  • 14. The method of claim 10 comprising the step, prior to the step of delivering pages, of supporting the tray by a frame.
  • 15. The method of claim 14 wherein the step of supporting the tray comprises suspending the tray from the frame.
  • 16. The method of claim 14 wherein the step of supporting the tray comprises providing dampers such that the dampers extend from the tray to the frame.
  • 17. The method of claim 10 wherein the step of inducing vibration comprises inducing vibration by the vibrator wherein the vibrator is a subsonic vibrator.
  • 18. The method of claim 10 wherein the step of inducing vibration comprises dampening the induced vibration by dampers.
Priority Claims (1)
Number Date Country Kind
PR 1573 Nov 2000 AU
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Number Name Date Kind
2573612 Scheinker Oct 1951 A
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3146473 Hoff Sep 1964 A
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3862752 Totten Jan 1975 A
4344727 Chaloupka Aug 1982 A
5429475 Mohr Jul 1995 A
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5632587 Coyette May 1997 A
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Number Date Country
2942965 May 1981 DE
2303580 Feb 1997 GB