Information
-
Patent Grant
-
6634115
-
Patent Number
6,634,115
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Date Filed
Thursday, December 20, 200123 years ago
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Date Issued
Tuesday, October 21, 200321 years ago
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Inventors
-
Original Assignees
-
Examiners
- Lazarus; Ira S.
- Ragonese; Andrea M.
Agents
-
CPC
-
US Classifications
Field of Search
US
- 034 95
- 034 108
- 034 110
- 034 111
- 034 620
- 034 623
- 034 629
- 034 329
- 034 335
- 034 343
- 034 355
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International Classifications
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Abstract
A conditioning device to change the moisture content of printing stock, in which the stock is brought into contact with at least one endless cloth that absorbs moisture. The endless cloth is heated by heated transport rolls. A reduction of the moisture content contributes to a reduction of distortions of the printing image in two-sided printing, especially in digital printing machines.
Description
FIELD OF THE INVENTION
The invention concerns a conditioning device to change the moisture content of printing stock, especially flat paper products, in which the stock is brought into contact with at least one endless cloth that absorbs moisture, the endless cloth being heated by heated transport rolls.
DESCRIPTION RELATIVE TO THE PRIOR ART
EP 0 771 904 concerns a drying device in paper production, in which large amounts of moisture must be removed from the paper. In this case, a paper web is guided past a cloth that absorbs moisture, for example, made of felt, and exposed to infrared radiation in a limited region. At the same time, the moisture emerging from the paper web is drawn into the felt cloth by means of an underpressure from the bottom of the cloth, which contributes to an improvement in drying.
EP 0 078 382 concerns a drying device in offset printing. Infrared emitters are used to evaporate the moisture from paper sheets and a blower is used to blow out the moist air from the paper sheets and, at the same time, cool them.
The moisture content of paper is an important parameter that determines the dimensions of a paper sheet or paper web and therefore has a not insignificant effect on printing quality within a printer. The application of pressure and heat can cause shrinkage of paper stock. This has a particular effect during double-sided printing, if a change in moisture content of the stock occurs between printing of the front and backsides, and a change in size of the stock is caused by this. This produces so-called front-to-back error. This is a regular occurrence in digital printers that use heat and pressure to fix a toner image. This effect can be reduced by predrying of the stock, since only limited shrinkage can still occur, because of the more limited residual moisture content of the stock. An increase in printing quality is achieved on this account.
BACKGROUND OF THE INVENTION
It is therefore the task of this invention to provide an apparatus, in which it is guaranteed that the stock reaches the subsequent processing steps of the printer with a defined geometry and a defined moisture content.
In an advantageous embodiment of the concept underlying the invention, a printing stock is brought in contact with at least one endless cloth that absorbs moisture, which is stretched around a number of transport rolls that serve for movement of the endless cloth, and heated by means of a heating device, so that the moisture within the printing stock also heated by this is transferred to the endless cloth.
In a particularly advantageous variant, the heating device lies within the rolls and heats them from the inside. This avoids a direct effect of the heating device on the printing stock, which can lead to changes, for example, in the printing image or color composition and, in so doing, cause deterioration in printing quality.
Printing stock that comes in contact with the endless cloth heated by the heating device is heated and releases its moisture content to the surroundings, and especially to the endless cloth. The moisture content is further transported within the endless cloth and removed from the cloth at an appropriate site. This is supported by additional contact of the endless cloth with the heated transport rolls, which contribute to evaporation of the moisture from the endless cloth.
In addition to evaporation of the moisture from the endless cloth, an air stream can be generated in a modification of the concept of the invention, especially by a blower, which has at least one flow component directed horizontal to the surface of the endless cloth and is thus guided past the endless cloth. Evaporation of the moisture from the endless cloth is supported by the change in local vapor pressure caused by this. This process can be preferably supported according to the invention in that the endless cloth is dried outside of the contact zone.
In another variant, an air stream generated, in particular, by a blower and having at least one flow component directed perpendicular to the surface of the endless cloth can be guided through the endless cloth and entrain moisture particles, which also contributes to acceleration of drying of the endless cloth. According to the invention, the air stream that is guided through the endless cloth or past the endless cloth will have a temperature deviating from the surrounding temperature, especially an elevated temperature.
In the region of the conditioning device, the paper is advantageously conveyed forward by the mechanical contact between the endless cloth and the printing stock. Alternative methods of conveyance, having a drive on the side of the printing stock facing away from the endless cloth, are also conceivable.
In another advantageous embodiment of the device according to the invention, the printing stock is guided between two identical endless cloths arranged on both sides of the printing stock. This can guarantee a more uniform removal of moisture from the printing stock, since the evaporated moisture here is fully transferred into the endless cloths.
A significant advantage of this embodiment according to the invention is obtained by the fact that costly paper guides drop out. At the same time, relative movement between the printing stock and the endless cloth is reduced by the forward movement, which is transferred by the endless cloths to the printing stock, and contact with stationary paper guides prevented. Because of this, a situation is avoided in which the surface of the printing stock is altered, especially damaged.
It lies within the inventive concept of the device disclosed here that heating of the transport rolls of the endless cloth need not occur uniformly over their width, but can be superimposed with a temperature profile. A variation of the temperature profile in the longitudinal direction can also be simultaneously implemented, in which the power of the heating devices is varied in time, especially in correlation with the format of the printing stock.
In another advantageous variant, an evaporation zone is connected to the tempering zone, in which the printing stock releases moisture, because of its heating, and is cooled based on the released heat of evaporation. Advantageously, guiding of the printing stock can occur in this region through grid-like structures that afford maximum evaporation surface.
In another variant, a cooling device can advantageously be mounted behind the tempering and/or evaporation zone. However, unheated or cooled transport rolls are used. Because of this, a situation can be achieved in which the printing stock, after leaving the cooling device, has essentially the same temperature as before the drying device. It lies within the scope of the concept according to the invention presented here to use the cooling device also for other purposes without a preceding tempering zone, especially for cooling of the printing stock.
Another advantage is obtained from the elasticity, especially compressibility of the endless cloths that absorb the moisture, so that thickness differences of individual types of printing stock are compensated and no corresponding adjustments are therefore necessary or excess loading of the rolls by different thicknesses of the printing stocks can be prevented. By contact of the printing stock with the endless cloth and removal of the evaporated moisture connected with this from the printing stock, traces on the printing stock, like, water spots, are also avoided.
Printing stock is sometimes deformed, especially rolled up, so-called paper curl, by storage or the production process. A further advantage of the device according to the invention lies in the fact that deformed printing stock is kept flat and smooth by close contact with the endless cloths.
Electromagnetic radiation sources, especially infrared radiation sources, can be advantageously used as heating devices to heat the transport rolls. However, other principles for heating the transport rolls are equally conceivable, like, steam, electric heating or others.
Blowers or air nozzles of a wide variety of arrangements and methods of operation can be used as blower devices.
The device according to the invention finds application in digital printers, but can also be used in all other printing machines or other devices that process paper where differences in paper size during passage through the device and its components are to be avoided or at least reduced.
BRIEF DESCRIPTION OF THE DRAWINGS
In the detailed description of the preferred embodiment of the invention presented below, reference is made to the accompanying drawings, in which:
FIG. 1
shows a schematic view of a representative assembly with a conditioning device according to the invention with a tempering zone and an advantageous blower device; and
FIG. 2
shows a schematic view of a representative modification of the conditioning device according to the invention with a tempering zone, evaporation zone and cooling zone.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
A representative assembly with a conditioning device
1
according to the invention with a tempering zone
10
is shown schematically in FIG.
1
. At least two fixed transport rolls
11
are situated within tempering zone
10
, over which an endless cloth
12
that absorbs moisture is stretched. The transport rolls
11
are placed in rotation in the same direction individually or in tandem by a drive (not shown). The transport rolls
11
act on the endless cloth
12
that absorbs moisture. A heating device
13
that heats the surrounding transport rolls
11
is situated within one, preferably all, transport rolls
11
. The heat generated by the heating device
13
is transferred via transport rolls
11
to the endless cloth
12
that absorbs the moisture.
The printing stock
2
is moved forward through the conditioning device
1
by mechanical contact between printing stock
2
and endless cloth
12
.
The printing stock
2
leaves an upstream stock-processing device (not shown) and is guided in friction contact along a grid-like stock guide
14
to the endless moisture-absorbing cloth
12
and thus comes in thermal and mechanical contact with the heated endless moisture-absorbing cloth
12
, and is also heated by it. Because of the condition of endless cloth
12
and the pressure between printing stock
2
and endless cloth
12
, the moisture in the printing stock
2
is transferred to endless cloth
12
. In addition, moisture in printing stock
2
is evaporated by heating of the printing stock
2
, which can escape through the grid-like stock guide
14
. The moisture absorbed by the endless moisture-absorbing cloth
12
leaves the endless cloth
12
by evaporation on the side facing away from printing stock
2
and the endless cloth
12
is dried.
In an advantageous modification of the invention, a blower
15
is arranged within tempering zone
10
, which generates an air stream along the endless moisture-absorbing cloth
12
, which has at least one flow component directed horizontally relative to the surface of the endless cloth and, because of this, supports the evaporation process of the endless moisture-absorbing cloth
12
and printing stock
2
.
In an alternative, particularly advantageous variant, at least one blower
16
, having at least one flow component directed perpendicular to the surface of the endless cloth, is arranged between transport rolls
11
, with which tempered air is advantageously blown onto and especially through the endless moisture-absorbing cloth
12
. In an advantageous modification of the invention, the blower
16
consists of a number of blower units that are distributed uniformly over the surface between transport rolls
11
and are controlled individually or in groups, and whose power can be adjusted and, in particular, switched off.
A particularly advantageous modification of the advice of the invention is shown in FIG.
2
. Instead of a grid-like stock guide
14
, an additional endless moisture-absorbing cloth
12
is arranged here with at least two transport rolls
11
and heating devices
13
on the inside. The printing stock
2
is then conveyed exclusively by the endless cloths
12
. Because of the symmetric arrangement, drying of the printing stock
2
can be advantageously improved.
The printing stock
2
is sent from the tempering zone
10
to an evaporation zone
20
and guided by means of a grid-like stock guide
21
. Contact rolls or other known mechanisms (not shown) preferably serve as means of transport for printing stock
2
. The stock
2
coming from the tempering zone
10
is cooled with further release of moisture because of the released heat of evaporation.
The printing stock
2
in the variant depicted in
FIG. 2
is then taken up by an additional pair of endless moisture-absorbing cloths
32
and convey to a cooling zone
30
. The cooling zone
30
is designed similar to the tempering zone
10
from transport rolls
31
, advantageously two, over which the endless moisture-absorbing cloths
32
are stretched. In this advantageous variant, the additional transport rolls
31
are dispensed with, in order to create the largest possible evaporation region. A blower
33
is arranged between endless cloths
32
, which cools the stock
2
by using their released heat of evaporation essentially to the initial temperature of stock
2
before entering the conditioning device
1
. The stock
2
is released from the conditioning device
1
following cooling zone
30
.
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
Parts list
1
Conditioning device
2
Printing stock
10
Tempering zone
11
Transport roll
12
Moisture-absorbing endless cloth
13
Heating device
14
Grid-like stock guide
15
Blower
16
Blower
20
Evaporation zone
21
Grid-like stock guide
30
Cooling zone
31
Transport roll
32
Moisture-absorbing endless cloth
33
Blower
Claims
- 1. Device for conditioning of printing stock (2), comprising:a tempering zone (10), at least one endless cloth (12) that absorbs moisture, at least two transport rolls (11) in said tempering zone (10), on which the endless cloth is tightened, said at least one endless cloth being adapted to be engaged by printing stock (2), at least one heating device (13), whereby the endless cloth (12) that absorbs moisture is heated and the heating device (13) is situated within the space wrapped around by the endless cloth (12), an evaporation zone (20), characterized by the fact that the evaporation zone (20) being situated behind the tempering zone (10), in which the printing stock (2) is guided, and the printing stock (2) being cooled at least by evaporation of moisture, and a cooling zone (30) situated behind the evaporating zone (20), having at least one endless moisture-absorbing cloth (32) and at least two transport rolls (31).
- 2. Device according to claim 1, wherein said at least one heating device is arranged within at least one of the transport rolls (11).
- 3. Device according to claim 1, further including a gridded printing stock guide (14) being formed on the side of the printing stock facing away from the endless cloths (12), and guiding printing stock (2) in the evaporation zone.
- 4. Device according to claim 1, further including an additional endless moisture-absorbing cloth (12) arranged opposite the transport path of the printing stock (2).
- 5. Device according to claim 1, further including at least one blower (15) within conditioning device (1), said blower (15) directing an air stream with at least one flow component horizontally relative to the surface of the endless cloth, along the endless moisture-absorbing cloth (12, 32), and therefore evaporates moisture from the endless moisture-absorbing cloth (12, 32).
- 6. Device according to claim 1, further including at least one blower (16, 33), located between transport rolls (11, 31) in said tempering zone (10) and said cooling zone (30) respectively, producing an air stream having at least one flow component directed perpendicular to, and forced respectively through the surface of the endless cloth of said tempering zone (10) and said cooling zone (30).
- 7. Device according to claim 1, wherein the endless moisture-absorbing cloth (12, 32) is compressible.
- 8. Device according to claim 6, whereby at least one of said blowers (15, 16, 17, 33) is heated, such that the air stream generated by said at least one of the blowers (15, 16, 17, 33), arranged within the conditioning device (1), is heated in comparison with the endless moisture-absorbing cloth.
- 9. Device according to claim 6, wherein the flow rate of the air stream generated by at least one of the blowers (15, 16, 17, 33) within the conditioning device (1) is controllable.
- 10. Device according to claim 1, wherein each of said heating devices (13) are controllable within at least one transport roll (11), and is disconnectable from its heat source.
- 11. Device according to claim 1, wherein the moisture content of the printing stock is reduced from about 10% to about 5%.
Priority Claims (1)
Number |
Date |
Country |
Kind |
101 01 775 |
Jan 2001 |
DE |
|
US Referenced Citations (17)