WO1980002257A1

WO1980002257A1 - Heatable sieve for serigraphy

Info

Publication number: WO1980002257A1
Application number: PCT/EP1980/000023
Authority: WO
Inventors: E Messerschmitt
Original assignee: E Messerschmitt
Priority date: 1979-04-23
Filing date: 1980-04-23
Publication date: 1980-10-30
Also published as: DE2916391A1; JPS56500562A; DE2916391C2

Abstract

Serigraphy frame for printing thermoplastic colours in the serigraphy technique. When tensioning the printing screen of a sieve in the frame, the hooking of the screen to the frame has the disadvantage to be relatively difficult and expensive. It is proposed to embed the cloth of the screen on one or several sides with a thermoplastic material. The serigraphy frames keep a lining or insulating clothing of thermoplastic material, in which the cloth of the screen is embedded, for example by heat and pressure.

Description

Screen printing heating screen

It is known to screen print thermoplastic colors in such a way that a chrome-nickel steel screen is used, which is connected to a circuit on two opposite sides and heats up as a result. These steel screens must now be hung up in order to function, which is done by adding insulation, such as rubber or plastic, between the frame and the screen. This requires a complicated hanging device in order to tighten the sieve at the same time and to prevent electrical breakdown. So usually non-conductive fabric sheets are sewn side by side into the steel mesh and mechanically attached to the frame with or without re-tensioning, while on the other two opposite sides the steel mesh is loosely guided over insulating bridges on the frame to an electrically insulated tensioning mechanism. The screen suspension, which allows retensioning, is superior, since the heating of the fabric causes it to stretch. In a simple version, the metal mesh is stretched onto wooden frames. Fabrics have also been embedded in non-thermoplastic fabric frames. Gluing without simultaneous mechanical connection is not known since adhesives are generally thermoplastic and the heated sieve has to come loose. This is partly prejudice. It is overcome according to the invention by embedding the fabric in the thermoplastic on one or more sides, for example also by ironing on, Injection etc. In order to avoid the feared loosening of the embedding at too high a temperature and / or fabric tension, precautions should be suggested.

1) If the embedding goes along the current flow by making the current inlet and outlet narrower than the distance between the embeddings,

2) if the embedding is transverse to the current flow, the steel mesh is made low-resistance conductive from the power connection to the embedding, e.g. by copper plating, so that it does not or hardly heats up at these points.

3) The current flow begins and ends within the thermoplastic screen attachment to the frame and does not cross it.

Using the described features, screen printing frames are proposed which have a thermoplastic, insulating jacket or insert, e.g. made of PE, into which the fabric, e.g. through heat and pressure.

The casing can be produced, for example, by shrinking on, spraying on or whirl sintering. The insert can have the shape of a plastic profile. This can then be detached from the frame, even if the sieve is firmly connected to it. This solution is particularly favorable for frames that have a re-tensioning mechanism. For large heating screens, a thermoplastic elastic border according to the German patent can be used if the above features are observed.

The innovation is explained in more detail below using exemplary embodiments.

It shows:

Figure 1 the frame (1), which has a plastic coating on 2 opposite sides 1.1 and 1.2. The fabric (2) is attached to it and copper-plated on the end faces 2.1 and 2.2.

Figure 2 provide the frame (1) on the sides 1.3 and 1.4 with plastic strips. The fabric (2) is provided at the ends with electrically low-resistance conductive bars (3 and 4), which are shorter than the frame legs 1.1 and 1.2, i.e. the straight connecting lines between the ends of the beams do not touch the plastic strips.

In Figure 3, the side 1.4 is provided on the frame (1) with the plastic so that it can be adjusted outwards.

In Figure 4, pages 1.1 and 1.2 are on the frame (1) provided with a movable device on which the plastic is located.

Figure 5 shows a frame (1) with a heatable screen (2), in which the current flows via a current supply and current discharge (eg low-resistance conductive bars 5.1, 5.2.2), which are arranged within the screen so that the current does not pass through the thermoplastic Embedding (1.1 to 1.4) flows. The power supply is soldered or clamped to the sieve.

All types of screen printing frames can be used. A ₁ , A ₂ and A _{3 show} special frames with attachable or fixed plastic profiles.

A selection of three known frame systems is shown in Figs. 6, 7 and 8, these solutions being analogously applicable to all frame systems.

It represents:

1 the frame 6 non-conductive fabric or film or layer (overlay, adhesive, etc.)

7 low-resistance conductive fabric or foil or connecting material

8 high-resistance conductive fabric Fig. 6 and 7 show two common self-stretching frames. The elastic screen edging 6b (non-conductive fabric or foil) is either welded to a plastic profile 6a or jammed by a bead 6c. It is connected to the sieve 7 and 8. The screen is conductive with low resistance on the surfaces that are not to be heated (7). This can be achieved, for example, by galvanization or patting.

Fig. 8 shows a rigid frame e.g. made of metal profile (mainly welded or put together with corners).

In Fig. 8a, the frame (1) is connected to the fabric (7th and 8th) via an insulating bridge, which is primarily thermoplastic (6) (gluing, sintering or embedding). The fabric part (7) going in the direction of the current flow is designed with low resistance. In Fig. 8b the frame (1) is connected to the heating fabric (8) partly as in Fig. 8a, partly via a fabric and / or film (6a), which have an insulating effect. The current is supplied via highly conductive terminals (5), which are also a connection and can therefore be partially insulated (section 5a). In Fig. 8c the heating fabric is bordered all around with insulating fabric or film (6a), which is primarily thermoplastic.

Fig. 9 shows a solution for smaller formats. The frame 1 primarily carries thermoplastic insulation (7) (film, profile, coating, Adhesive), which is either attached or removable, to which the heating fabric 8 is attached (7.2) or ajar (7.1). This heating fabric is tensioned in the insulated (lo) clamp (3) in the direction of the arrow. Both or one frame side (1.4) can if necessary. be used for tensioning the fabric in the direction of the double arrows, primarily by moving in the direction of the arrow, tensioning strips, etc. using tensioning screws (11). The current-giving terminal strips (3), however, are dimensioned or insulated (3a) in such a way that they only supply current to the heating fabric in a straight connection within the frame, i.e. the ends are shorter than the inside dimension of the frame or, insofar as they go beyond it, insulated ( 3.1). This version can also be transferred to so-called conical sieves.

Fig. Lo shows connections between heating fabric (8) and insulation (6).

10.1 Gluing

10.2 Embedding

10.3 seam (can be combined with 10.1 and 10.2)

The jamming is shown in Figure 8 with terminal 5, which can also be used for power supply.

Claims

P a t e n t a n s r u c h e

L screen printing frame for printing thermoplastic inks, so that a screen printing frame is used that has a thermoplastic surface on one to 4 sides, e.g. Made of polyethylene, owns or is provided with plastic strips and that means that a V2A steel mesh is embedded in these plastics, which extends beyond the frame at 2 opposite ends for connecting low-voltage current, e.g. by means of conductive crossbeams, e.g. made of copper.

2. Screen printing frame for printing thermoplastic inks. According to claim 1, that the opposite fabric ends, at which the connection points for the current are located, are copper-plated up to the inside of the frame over the tissue embedding crossed.

3. Screen printing frame for printing thermoplastic inks according to claim 1 and 2, characterized in that the conductive crossbeams, which distribute the current to the fabric, are shorter than the fabric width, so that the imaginary direct connection of their ends, the side-by-side embedding of the fabric in the thermoplastic material not touched.

4.Screen printing frame for printing thermoplastic inks according to claim 1 - 3 d a d u r c h g e k e n n z e i c h n e t that the crossbeams that supply the current to the screen are located within the screen, which is thermoplastic embedded on the edge, and with this, e.g. connected by soldering or staples, etc.

A screen printing frame for printing thermoplastic inks according to claims 1 to 3, so that the thermoplastic material is detachably attached to the frame, e.g. by clamping, hooking.

Screen printing frame for printing thermoplastic inks according to claims 1 to 4, and the fact that the thermoplastic material for embedding the fabric on adjustable, i.e. tensionable elements of the frame is attached.