EP1373984A1

EP1373984A1 - Method and device for heating and fixing an inking, particularly a toner powder on a plate-shaped support

Info

Publication number: EP1373984A1
Application number: EP02722254A
Authority: EP
Inventors: Bernd Schultheis; Rainer Solbach; Birgit Lattermann; Hans-Jürgen HOMMES; Dieter Jung
Original assignee: Carl Zeiss AG; Schott Glaswerke AG
Current assignee: AGC Inc
Priority date: 2001-03-22
Filing date: 2002-03-21
Publication date: 2004-01-02
Anticipated expiration: 2022-03-21
Also published as: CN1317608C; CA2441285A1; CN1489721A; DE10114526A1; WO2002077720A1; DE50210593D1; DE10114526B4; US7326443B2; EP1373984B1; US20050100812A1; ATE368877T1

Abstract

The invention relates to a method for heating and fixing an inking, particularly a toner powder on a plate-shaped support, according to which the inking applied to the coated upper side of the support is fixed on the support by heat action. The aim of the invention is to be able to fix toner inkings on thick-walled supports whereby adhering well thereto. To this end, the coated upper side and/or the uncoated underside of the plate-shaped support is subjected to the action of infrared radiation and/or of a hot air stream and/or of a microwave radiation, and a support having a high weight per unit area is used, which permits a portion of the infrared radiation and/or hot air stream and/or microwave radiation directed onto the uncoated underside of the support to pass through while absorbing another portion of the same.

Description

Method and device for heating and fixing a paint application, in particular a toner powder on a plate-shaped carrier

The invention relates to a method for heating and fixing a paint application, in particular a toner powder on a plate-shaped carrier, in which the color application applied to the coated top of the carrier is fixed on the carrier by the action of heat, and a device for carrying out the method.

The use of infrared radiation for heating and fixing a paint application applied to a paper or sheet-like carrier is known from DE 1 98 57 044 A1. The short-wave infrared radiation has a typical emission temperature of 2000 to 2500 K. Paper has a low basis weight, which is usually less than 100 g / m ² .

Another method for fixing the toner is known from EP 0 989 473 A2. The toner powder is fixed on the paper with an inductively heated roller.

BESTATIGUNGSKOPIE In this known method, thin copy paper is heated up relatively quickly, since it generally also has a basis weight of <100 g / m ² . Thick-walled plate-shaped materials such as glass or ceramic plates, plastic plates etc. cannot be easily heated in this way, since they have a significantly higher basis weight and therefore a significantly higher heat capacity.

It is an object of the invention to provide a method and a device with which toner powder, in particular ceramic and thermosetting toner powder, can be fixed quickly and efficiently with good adhesion to plate-like materials with a high basis weight.

This object is achieved according to the invention with a method which is characterized in that the coated top and / or the uncoated underside of the plate-shaped carrier is exposed to infrared radiation and / or a hot air stream and / or a microwave radiation and that a carrier with high Weight per unit area is used which allows part of the loading directed onto the uncoated underside of the carrier and absorbs another part of the same.

Depending on requirements, the energy input occurs both via the coated upper side of the carrier and via the non-coated underside of the carrier with differently selectable exposure to infrared radiation, hot air flow and

BESTATIGUNGSKOPIE Microwave radiation. The carrier allows part of the exposure to pass through and absorbs part of the same. The action on the back of the carrier causes, on the one hand, that the material of the carrier heats up evenly due to partial absorption, and, on the other hand, that increased absorption takes place in the toner powder at the interface between the color application and the carrier, which leads to better melting of the toner powder -vers and thus also leads to better adhesion to the carrier. The energy input is also largely independent of the degree of toner occupancy and the type of toner powder, which is particularly advantageous in the case of direct printing of different carrier materials with different toner powder, such as thermoplastic, thermosetting or ceramic toner powders. The plate-shaped carrier has a weight per unit area of> 1 00 g / m ² , in particular> 1000 g / m ² .

According to one embodiment, it is provided that a transparent material, such as glass, glass ceramic or plastic, is used as the carrier, which has a transmission> 20%, preferably> 50% in the spectral range with a wavelength of 0.8 μm to 5 μm. Materials with a thickness of 3 to 8 mm and a relatively smooth, poorly wettable surface are particularly suitable if a ceramic or thermosetting toner powder is used for the color application.

The fixation of the toner powder on such carriers can be further improved by exposing the coated top and / or the uncoated underside of the carrier to a hot air stream, which is preferably directed bundled onto the ink application if the carrier has a low degree of transmission for this purpose, or also in that the carrier on the coated top and / or the uncoated bottom of a

BESTATIGUNGSKOPIE microwave radiation is exposed, the frequency of which essentially corresponds to the resonance frequency (microwave coupling frequency) of the molecular structure of the carrier.

The fixation can be carried out with a device for carrying out the method with the carrier not moved or with the carrier moving continuously, on the one hand providing that the carrier provided with the paint application is introduced into a chamber which is on the coated upper side and / or the non-coated The underside of the carrier is provided with transmission devices for the selected exposures to the carrier, while on the other hand the procedure is such that the carrier can be moved through a pass-through chamber which has transmitting devices for the selected exposures on the coated top side and / or the uncoated underside of the carrier the carrier is provided.

According to one embodiment, a simple device with infrared emitters arranged on both sides is characterized in that the transmitter devices are arranged on the coated top side and / or the non-coated bottom side of the carrier in a uniform division, the arrangement on both sides of the transmitter devices from the top side and bottom side by one Half division are offset from each other, and that several infrared emitters are arranged as transmission devices on both sides of the carrier and that the sides of the infrared emitter facing away from the carrier are enclosed by semicircular partial reflectors. The infrared emitters extend over the entire color application of the stationary carrier or they form a continuous path which, with the speed of the carrier and its length, ensures a sufficient heating and fixing time. The partial reflectors concentrate the radiation on the paint application and also direct radiation reflected by the carrier back onto the carrier. The partial reflectors associated with the coated upper side of the carrier can be combined to form a reflector unit.

If the carrier is guided past the infrared emitters on a roller conveyor, the device is advantageously designed such that the partial reflectors assigned to the uncoated underside of the carrier are each arranged between two transport rollers of a roller conveyor.

If the toner powder on the carrier is additionally exposed to a flow of hot air, then it is provided that the partial reflectors of the reflector unit are provided with air passage openings and close inflow chambers to which hot air can be supplied by means of a hot air blower via supply lines, and that the reflector unit between the partial reflectors is provided with suction openings which are connected to the hot air blower via suction lines.

The coated carrier can also be introduced into or pass through a microwave chamber and subjected to microwave radiation with an industrially approved frequency of 2.54 GHz. This can be done before or after irradiation with infrared radiation or together with it. The prerequisite is that this microwave frequency in the Essentially corresponds to the resonance frequency (microwave coupling frequency) of the molecular structure of the carrier, which is particularly the case with carrier materials made of aluminosilicate glass ceramic in the high quartz mixed crystal modification (HQMK).

The coated upper side of the carrier can also be applied only with a directed or bundled hot air stream. Depending on the material of the carrier, it is only possible to apply microwave radiation to the uncoated underside.

The invention is explained in more detail with reference to exemplary embodiments shown in the drawing. Show it:

1 is a flow device in section with a flow chamber and infrared emitters arranged on both sides,

2 shows the flow device according to FIG. 1 with an additional top loading of the carrier with a hot air stream,

Fig. 3 shows a device with a hot air exposure to the coated top and

Fig. 4 shows a device with a microwave chamber.

BESTATIGUNGSKOPIE In the continuous device according to Fig. 1, the method according to the invention is applied, since the carrier 1 carried out is exposed to infrared radiation on the coated top side 1 .1 and the uncoated back side underside 1 .2, which emanates from infrared emitters 3 that emit on both sides of the Carrier 1 are arranged. A plurality of infrared emitters 3 are, however, assigned to the top and bottom sides 1 .1 and 1 .2 of the carrier 1 in the same division, offset by half a division. The carrier 1 is moved by transport rollers 2. The speed of this movement and the length of this "pass-through chamber" are coordinated in such a way that a sufficient irradiation time and fixing time are ensured. The infrared radiators 3 are each arranged in semicircular partial reflectors 4.1 or 4.2, so that the radiation is focused in the direction of the carrier 1 and that radiation reflected by the carrier 1 is reflected back again. The partial reflectors 4.1 on the coated upper side 1 .1 of the carrier 1 are combined to form a reflector unit 4, while on the non-coated lower side 1 .2 of the carrier 1 the partial reflectors 4.2 are always arranged between two transport rollers 2.

The infrared emitters 3 are e.g. designed as dark emitters, halogen emitters, quartz emitters or carbon emitters, whose radiation maximums are between 0.8 μm and 5 μm and their emission temperatures are between 1000 K and 750 K. The thickness of the carrier is between 3 mm and 8 mm. Glass or glass ceramic with a transmission> 20%, preferably> 50%, is particularly suitable as a carrier material for the short-wave infrared radiation. Other materials with a sufficiently large transmission for infrared radiation can also be used with an equally good effect.

BESTATIGUNGSKOPIE In a further preferred exemplary embodiment, the emitters are designed as ceramic emitters. These have a radiation maximum between 3.5 and 4 μm and a radiation temperature in the range between 500 and 600 ° C.

In the exemplary embodiment according to FIG. 2, the structural design with the transport rollers 2, the infrared emitters 3 and the partial reflectors 4.1 and 4.2 is practically the same. To heat and fix the toner powder on the coated top 1 .1 of the carrier 1, however, a hot air stream 10 is additionally passed over the paint application of the carrier 1, which is kept in circulation by a hot air blower 6 in a line system 5. The partial reflectors 4.1 of the reflector unit 4 close inflow chambers 11, to which the hot air is supplied via supply lines 5.1. The hot air emerges from the inflow chambers 11 through air through openings 7 of the partial reflectors 4.1 and additionally heats up the paint application. Between the partial reflectors 4.1, the reflector unit 4 has suction openings 8, through which the hot air is sucked into suction chambers 12. In the suction chambers 1 2, the sucked-in air is passed through filters 9 and the impurities contained are retained. The air, freed of contaminants and cooled, returns to the hot air blower 6 via suction lines 5.2, where it is returned to the circulation circuit 5 after heating and pressure increase. The application of additional hot air to the paint application brings an improvement in the heating-up time and thus also the toner fixation. The hot air blower 6 can be designed as a radial blower which axially sucks in the air from the suction lines 5.2 and radially supplies it to the supply lines 5.1 when heated.

As mentioned, the method can also be carried out in a device designed as a receiving chamber without transport rollers. The partial reflection

BESTATIGUNGSKOPIE gates 4.2 are then also combined to form a reflector unit and the carrier 1 is brought into the receiving chamber and exposed to the infrared radiation and / or the hot air stream and / or a microwave radiation for a predetermined time. The combination with hot air and / or microwave radiation can be selected as required, taking into account the material, thickness and transmittance of the carrier 1.

In the embodiment of the device according to FIG. 3, the coated upper side 1 .1 of the carrier 1 is subjected to a directed and bundled hot air stream 10. The carrier 1 is moved on transport rollers 2 past the fixed hot air blower 6, which is housed in a housing 15. The air flow generated by the hot air blower 6 is still heated by a heater 13 and is directed to a discharge opening 16 by a guide element 14. The guide element 1 4 forms with the housing 1 5 an outflow duct 1 7 and an intake duct 1 8 for the air flow 10.

4 shows a microwave chamber 24, in which the carrier 1 can be inserted and removed via closure members 25. The closure members 25 remain closed while the underside 1 .2 of the carrier is being acted upon. The microwave chamber 24 is shielded from the outside, so that the microwave radiation only occurs in the interior. The transport of the carrier 1 into and out of the microwave chamber 24 is carried out by transport rollers 2. Between the transport rollers 2 there are microwave kystrons 23 which are controlled by means of a pyrometer 26. Pyrometers, in particular those in the spectral range with wavelengths around 5.5 μm or in Range 7.5 to 8.2 microns sensitive, are particularly suitable for monitoring the surface temperature of glasses or glass ceramics. Due to the relatively good coupling of carrier materials made of alumosilicate glass ceramics in high-quartz mixed crystal modification (H QM K), temperature monitoring is particularly important to prevent overheating of the toner material and the carrier material.

Pyrometers also have the advantage that they are relatively insensitive to microwave radiation.

Claims

Expectations

1 . A method for heating and fixing a paint application, in particular a toner powder on a plate-shaped carrier, in which the color application applied to the coated top of the carrier is fixed on the carrier by the action of heat, characterized in that the coated top (1 1) and / or the not coated

The underside (1 .2) of the plate-shaped carrier is exposed to infrared radiation and / or a hot air stream and / or a microwave radiation and that a carrier (1) with a high basis weight is used, which part of the underside (1 .2 ) of the carrier (1) allows directed exposure and absorbs another part of the same.

2. The method according to claim 1, characterized in that the plate-shaped carrier (1) has a weight per unit area of> 100 g / m2, in particular> 1000 g / m2.

BESTATIGUNGSKOPIE

3. The method according to claim 1 or 2, characterized in that a transparent material, such as glass, glass ceramic or plastic, is used as the carrier (1), which has a transmission> 20 in the spectral range with a wavelength of 0.8 μm to 5 μm %, preferably> 50% and has an absorption spectrum in the range with a wavelength of approximately 3.2 to 3.8 μm.

4. The method according to any one of claims 1 to 3, characterized in that a ceramic or thermosetting toner is used for the color application.

5. The method according to any one of claims 1 to 4, characterized in that the coated top (1 .1) and / or the uncoated bottom (1 .2) of the carrier (1) is exposed to a hot air flow (1 0), the is preferably directed bundled onto the paint application if the carrier (1) has a low transmittance for it.

6. The method according to any one of claims 1 to 5, characterized in that a carrier (1) with a transmittance> 20%, preferably> 50%, is used.

7. The method according to any one of claims 1 to 6, characterized in that the carrier (1) on the coated top side (1 .1) and / or the uncoated bottom side (1 .2) is exposed to microwave radiation, the frequency of which essentially corresponds to the resonance frequency (microwave coupling frequency) of the molecular structure of the carrier (1) equivalent.

8. The method according to claim 7, characterized in that a carrier (1) made of aluminosilicate in high quartz mixed crystal modification (HQMK) is used, which is acted upon with a microwave frequency of 2.54 GHz.

9. Device for carrying out the method according to one of claims 1 to 8, characterized in that the carrier provided with the paint application (1) is introduced into a chamber on the coated top (1 .1) and / or the non-coated The underside (1 .2) of the carrier (1) is provided with transmission devices for the selected exposures to the carrier (1).

10. Device for carrying out a method according to one of claims 1 to 8, characterized in that the carrier (1) is movable through a passage chamber which is on the coated top side (1 1) and / or the uncoated bottom side (1 .2) of the carrier (1) is provided with transmission devices for the selected exposures to the carrier (1).

BESTATIGUNGSKOPIE

1 1. Apparatus according to claim 9 or 10, characterized in that the transmission devices on the coated top (1 .1) and / or the non-coated bottom (1 .2) of the carrier (1) are arranged in a uniform division, the arrangement on both sides Transmitter devices from the top (1 .1) and bottom (1 .2) are offset by half a division.

1 2. Device according to one of claims 9 to 1 1, characterized in that infrared emitters (3), hot air blowers (6) and microwave generators are used as the transmitting devices.

1 3. Device according to one of claims 9 to 1 2, characterized in that on both sides (1 .1 and 1 .2) of the carrier (1) a plurality of infrared radiators (3) are arranged as transmitting devices and that the carrier (1) opposite sides of the infrared emitters (3) are enclosed by partial reflectors (4.1; 4.2).

14. The device according to claim 1 3, characterized in that the coated top (1 .1) of the carrier (1) associated partial reflectors (4.1) are combined to form a reflector unit (4).

1 5. Device according to claim 1 3 or 14, characterized in

BESTATIGUNGSKOPIE that the partial reflectors (4.2) assigned to the non-coated underside (1 .2) of the carrier (1) are each arranged between two transport rollers (2) of a roller conveyor.

6. Device according to one of claims 9 to 1 5, characterized in that the partial reflectors (4.1) of the reflector unit (4) are provided with air passage openings (7) and close inflow chambers (1 1), which by means of a hot air blower (6) Hot air can be supplied via supply lines (5.1) and that the reflector unit (4) between the partial reflectors (4.1) with suction openings (8) provide suction chambers (1 2) which are connected to the hot air blower (6) via suction lines (5.2) ,

7. Device according to one of claims 9 to 1 6, characterized in that the hot air extracted from the suction chambers (1 2) is returned via filter (9) to the hot air blower (6).

8. Device according to one of claims 1 2 to 1 7, characterized in that the hot air blower (6) is designed as a radial blower which sucks in the hot air coming from the suction lines (5.2) and radially feeds the supply lines (5.1) again.

9. Device according to one of claims 9 to 1 8, characterized in that the infrared emitters (3) are designed as halogen emitters, quartz emitters or carbon emitters, which have a maximum in the radiation spectrum between 0.8 μm and 5 μm wavelength and a radiation temperature in the range from 1000 K to 3750 K.

20. Device according to one of claims 9 to 1 8, characterized in that the infrared radiators are designed as ceramic radiators which have a maximum in the radiation spectrum between 3.5 and 4 m wavelength and a radiation temperature in the range of 500 ° to 600 ° C.

21. Apparatus according to claim 10 or 1 1, characterized in that the coated upper side (1 .1) of the carrier (1) is assigned a housing (1 5) with a hot air blower (6) and a heater (1 3), since with a Outflow opening (1 6) for the hot air flow (10) is provided such that the carrier (1) can be moved past the outflow opening (1 6) and that by means of a guide element (14) in the region of the outflow opening (1 6) to the housing (1 5) an outflow channel (1 7) and an intake channel (1 8) are formed.

22. The apparatus of claim 1 0 or 1 1, characterized in that the carrier (1) in a shielded with closure members (25) to be opened and closed microwave chamber (24) can be introduced that the closed closure members (25) which is not coated

BESTATIGUNGSKOPIE The underside (1 .2) of the carrier (1) can be subjected to the microwave radiation from microwave klystrons (23), and the microwave klystrons (23) can be regulated by means of a pyrometer (26) accommodated in the microwave chamber (29).

23. The device according to claim 22, characterized in that the microwave kystrons (23) are arranged between transport rollers (2) for the carrier (1).