DE1063029B - Method and device for heat setting of xerographic powder images - Google Patents

Description

It is common in xerography that electrostatic forces act on the substrate to be printed melt the adhesive powder image onto this by placing the powder image up together with the printing substrate heated above the melting point of the powder. The temperatures required for this are above 100 ° C, usually even above 150 ° C. With these processes, the boiling point of the water becomes considerable exceeded, so moisture is removed from the base. In particular for print documents, other. Dimensional accuracy and dimensional stability are particularly high requirements, such. B. punch cards, this procedure is not applicable because the delay and the rejection of the card after such Fixation exceeds the tolerance limit.

There are other methods known in which the fixation without heating only by Pressure or by the action of chemical solvents. The one using Pressure-working methods have insufficient fixation even when the pressure is so high it is chosen that the image carrier is permanently deformed. With the chemical fixing process it is possible a good fixation without significant change in the moisture content of the image carrier achieve. However, the chemical processes require a relatively high level to be carried out equipment expenditure. Due to the often toxic effect of the chemical solvent, you have to consider Operating instructions and safety precautions specific to the operation of such machines be respected.

The method according to the invention avoids the disadvantages cited by only the powder image one maintains sufficient temperature to melt the powder, while at the same time maintaining the temperature of the image carrier is kept below the boiling point of water.

According to the invention, this is achieved by briefly applying pure infrared radiation to a powder image is directed, its infrared absorption coefficient higher than that of the carrier. In order to ensure an exact dosage, you can use a starchy dose precisely defined infrared ray flash, ζ. Β. by a suitable lamp. One Support of the principle of selective heating of the powder image and its carrier results in a focus of the infrared rays in a focal line that is still above the carrier, but within the lying on top of the powder image.

Another, particularly good results for image carriers that are transported continuously and quickly The supplying device consists of a movement process which runs very close to the source of the ultrared radiation and device

for heat fixing xerographic

Powder pictures

Applicant:

IBM Germany

International office machines

Gesellschaft mbH,
Sindelfingen (Württ), Tübinger Allee 49

Claimed priority:
V. St. v. America June 14, 1956

David Dewey Roshon juii.,
Richard Charles Allen and John Harvey Lego,

Endicott NY (V. St. Α.),
have been named as inventors

path for the same, with the simultaneous circulation of cooling air the image carrier is kept below the boiling point of water. Becomes beneficial thereby the back of the carrier by a vacuum device or by electrostatic attraction drawn against a guide surface, so that the very close distance to the infrared source is sufficient is strictly adhered to.

Further features of the device for carrying out the invention are shown in the drawing and the description of some exemplary embodiments. It shows

1 shows a fixing device with a rapidly moving image carrier and cooling air circulation,

2 shows a device for electrostatic clamping of the image carrier in the device according to FIG. 1,

3 shows a suction device in the device according to FIG. 1 with slots,

FIG. 4 shows a side view of the fixing device according to FIG. 1,

5 shows an image carrier which has become unusable due to excessive dehumidification;

6 and 7 show the course of the melting process a powder image;

8 shows an arrangement for filtered pulse-wise infrared irradiation of a powder image;

909 580/358

Fig. 9 shows an arrangement with focusing of the infrared rays at one level with the powder image lying focal line.

. In the following description, the term! xerographic powder all tinting agents for xerographic prints which, after being applied to a support, are fixed by Heat occurs. So it also includes tinting agents that z. B. initially as a suspension in a Liquid are contained and after the liquid has been poured off from the .niedergeschütten powder image melted by heat. In the known, composed of several components Tinting agents ... the melting temperature is the temperature at which at least one component of the mixture melts.

It is known that water is responsible for radiation in the near infrared is transparent. So if for heat-setting powder images on a card a radiant energy, such as B. the radiation near the infrared is used, is the moisture content the card permeable to this radiant energy. This part of the radiant energy becomes therefore not converted into thermal energy. Because all tinting agents contain pigments and because the ones used Recording media have glossy surfaces and a lighter color than the actual powder must, the infrared rays are mostly reflected from the surface of the same, but absorbed by the tint.

As a tinting agent component, for. B. neutralized, finely powdered mixtures of artificial and Natural resins are used, which contain a few percent, but at least 5% black color pigments (Soot) are added. Other mixtures in which synthetic resins are used instead of natural ones Resins such as B. polyvinyl butyrate mixed with thermoplastic formaldehyde resins and are intimately mixed with dye powder, are also suitable for the aforementioned purposes.

The method according to the invention consists in applying an infrared radiation mileage which is sufficient only to melt the powder into a recording medium and which leads to selective heating of the powder image in relation to the recording medium. Because the transfer of thermal energy to. the. The recording medium is kept very low by conduction by appropriate means and since the recording medium itself is generally made of a material which does not easily absorb radiant energy, its temperature is kept below the boiling point of water. As a result, a considerable part of the original moisture remains in the recording medium, thereby avoiding the warping and warping of the same.
• A microscopic examination of the toning agent 14 (Fig. 6) from which a powder image, showing that the powder particles are arranged on the card in more than one layer prior to fixation and that upon exposure to the direct rays 15 of a InfrarotqueHe the powder ( Fig. 7) has an extremely fast glazing only on the surface 16 of the image. Although the appearance of this under-fixed image looks like an indelible powder image, a complete fixation has not yet occurred because only the outer layer has been melted. If the recording medium 51 were now removed from the source of radiant energy 15 , the powder image would not be permanently connected to the card. Additional thermal energy is therefore required after the initial glazing of the uppermost powder layer 16 in order to bring about permanent fixation of the powder image on its carrier. This can be done through a sufficiently strong and long enough exposure to radiant energy to melt the entire powder material. As a result, the powder layer adjoining the recording medium as well as the powder between this layer and the top layer are also conductive

ίο from the uppermost exposed to the radiant energy Layer off heated to the melting point.

In the device according to FIGS. 1 to 4, the recording medium (punch card) containing the powder image runs under the guidance of pairs of rollers 100 to 109 working together with the image-free edges of the same through the fixing device according to the invention. In this a row of infrared heating lamps 416 are arranged close above the path 485 of the recording media 51 . Since the surface temperature of the lamp 416 is about HOO ⁰ C, cooling air from the outlet openings 417 and 418 is conveyed by an air stream of a fan (not shown) through various air passages surrounding the lamps 416 and the duct 419 into the exhaust air opening 421 , so that all parts the fixing device are cooled. In addition, the heated air is removed from the vicinity of the guide fins 423 through the tube 422 .

The actual fixing station comprises the unit

475. It consists of a V-shaped housing which is open on one side and in which, in addition to the cooling air suction line 422, there is another air suction line 424 which is connected to the fins 423 , which are hollow on the inside. The recording medium 51 is held at a precisely predetermined distance from the lamp arrangement 416 by suction at the slits 285 of the fins 423 . Since the recording media e.g. B. be moved past the lamp assembly 416 at a distance of about 0.1 cm at a speed of about 30 cm / sec, the powder image is heated to about 120 -7-150 ° C. The temperature of the recording medium remains partly because of the lower ultrared absorption coefficient of its aluminum material, on the other hand because of the prevention of the heat reaching the recording medium by conduction below 100 ° C.

According to FIG. 1, the recording media 51 can also be clamped by a plate 485 α, in which a series of bores 485 b are arranged, which are connected to the suction air system 424 ο. The holes advantageously have a diameter of 0.07 to 0.15 cm.

An electrostatic chuck is shown in FIG. The recording medium 51 is guided on a number of webs 20 which are raised from the DC voltage source 21 to a high potential, e.g. B. 6000 - = - 10 000 volts, can be charged. The recording medium 51 is thereby drawn electrostatically against the webs 20 .

5 shows a recording medium 51 which is unusable for further use and which has been discarded by removing moisture. The fault remains, e.g. B. for the purposes of punch card machines, irrelevant if along the measuring sections 10, 11 and 12 no greater deviations than z. B. measured 0.3 cm from the straight line.

8 shows a device for pulse-wise filtered irradiation of a powder image located on a recording medium 51. At this

Arrangement, no great demands are placed on the spatially exact guidance of the recording medium 51. A recording medium 51 with a powder image 14 is moved past the flash lamp 75 by the transport rollers 71 to 74 and conveyed into the storage compartment 80. Between the flash lamp 75 and the recording medium 51 there is a heat transfer barrier 76 which, for. B. consists of a water-filled flat glass tube. The barrier 76 is therefore permeable to infrared rays, but prevents any other transfer of heat from the flash lamp to the recording medium. By a discharge arrangement, e.g. B. a card lever 78, 79, the contact 77 is closed as soon as a recording medium is in the desired position. The required flash lamp voltage of z. B. 2000 V is provided from the network 90 via a transformer 91, rectifier V 1 to the capacitor C1. When the switch 77 is closed, the gas tube G 1 is ignited and the flash lamp 75 is energized. Since such flash lamps can be excited about 100 times per second with appropriate cooling, it is possible to fix successive powder images correspondingly quickly.

Another device for selective heating of the powder image is shown in FIG. 9. A recording medium 51 with a powder image 14 becomes tubular by means of transport rollers 81 to 84 on one Fixing device containing lamp 86 moved past. The rectilinear one located in the lamp 86 The filament is imaged in a focal line within the powder image 14 through the reflection housing 85. This concentrates the radiant energy on the powder image and brings the powder without excessive heating of the recording medium to melt it. Depending on the need, additional Coolants of the type previously described are applied to avoid unwanted heat transfer to lock.

In general, the devices described have in common that the action of infrared radiation occurs only for a very short period of time. In order to generate the necessary energy, sources of high radiation energy must be used. Since the powder image is in direct contact with its carrier, heat is also dissipated by conduction Transfer powder to the base. If the powder image is heated too slowly, it would more energy is lost from the powder image to the material to be printed, d. i.e., the selective Warming changes into uniform warming with its disadvantageous consequences of dehumidification.

Claims (7)

Patent claims: 1. A method for heat setting xerographic powder images, characterized in that that a powder is used for image formation, the infrared absorption coefficient of which is considerable is higher than that of the image carrier, and that after the development on the image for a short time Infrared radiation is brought into action. 2. Device for performing the method according to claim 1, characterized in that that the infrared rays of a flash lamp through a water-filled glass lens onto the powder image be directed. 3. Device according to claims 1 and 2, characterized in that the triggering of the Flash lamps under control (77) of the recording medium takes place. 4. Device for performing the method according to claims 1 and 2, characterized in that that the radiation from the infrared source is so focused that the focal point of the rays just above the record carrier, but within that on the record carrier lying powder image is located. 5. Device for performing the method according to claims 1 and 2, characterized in that that the recording medium, which is at least partially covered with a powder image, passes under the infrared lamps on its path Uiiterdrucksaugschlitze or suction holes kept at a precise distance from the infrared lamps will. 6. Device for performing the method according to claims 1 and 2, characterized in that that d'er with a powder image at least partially covered recording medium by electrostatic clamping on his Railway under the infrared lamps is kept at a precise distance from them. 7. Device according to claims 1 to 6, characterized by the arrangement of coolants to prevent unwanted heat transfer. For this purpose 2 sheets of drawings © 909 580/358 7.