DE4308896C2 - Print head for an electrographic printing device - Google Patents

Description

The invention relates to a print head for an electrographic printing device with egg nem LED array arranged on one end face of the printhead and at least one Busbar arranged perpendicular to this end face.

Such a printhead is known from EP-0 404 766 B1. With the known pressure The LED array and the associated control electronics become head over both sides of a door gers arranged power rails supplied with energy. The busbars consist of egg nem sheet-like supply line, which consists of layers of insulating rails and Stromver care rails is constructed. The rails are glued together. On the outside a contact rail is arranged on the supply line. It is used for recording and loading Fixing a flexible ribbon cable that connects the busbar with the connections of the Control electronics of the LED array connects. The entire track is over hers Length glued to the carrier and is on the front side with the power supply sources in Ver binding. A power supply via busbars is necessary because of the large number of the LEDs arranged in the LED array with simultaneous activation of high working currents flow.

The assembly of the well-known character generator is labor-intensive and must be partly by Hand done. Furthermore, due to the nature of the structure of the busbar requires one of the like printhead a relatively large amount of space in the printer, which affects the total construction of the printing device affects.

It is also known from US-49 05 021 a print head of an LED printer, the has a busbar for a ground line, which consists of a plurality of metal plates having composite material. Such composite materials are at least if they are glued together, also with an insulating layer in between Mistake. However, the composite material is used to manufacture a specific one Temperature coefficients for the busbar.  

Another problem is the heat dissipation from the LEDs. The heat in the Druckbe drove safely to be dissipated without causing heat build-up in the area of the LEDs and thus overheating occurs. This hampers the miniaturization of a high printhead Power.

In the case of printheads of the type mentioned, the LED array is activated via control circuits controls that consist essentially of integrated circuits. To reduce the The overall width is from DE 87 04 510 U1 (title: printhead for electrophotographic printing process) known, the control circuits for the LED array to be arranged on printed circuit boards which are laterally attached to the carrier of the printhead. On the  The front of the carrier is the actual LED array with associated others Control circuits, the control circuits, the LED array and the circuit board are connected to each other via bond wires.

The object of the invention is to design a printhead of the type mentioned at the outset ten that he with the smallest possible width in a simple and machine-friendly manner can be mounted and still flexible adaptation to the most varied of types areas of application.

This task is performed with a printhead of the type mentioned at the outset len of the first claim solved.

Advantageous embodiments of the invention are characterized in the subclaims net.

Characterized in that the busbar is constructed as a multilayer compact arrangement, he there is a particularly narrow design of the entire printhead and the current Rail can be easily attached to the print head without much effort. The stream Rail can be made of individual metal plates arranged one above the other with an intermediate layer Insulation layers exist, with comb-like on one side of the metal plates final fingers are formed, starting from the levels of the metal plates to a Contact level are merged such that the ends of the connecting fingers one or Several rows of contacts made up of individual contacts running along the end face for receiving of connecting lines for the LED array. The metal plates with the connection fin like can be built from one-piece metal stamped parts, what the manufacture of Busbar much easier.

The particular advantage of the busbar so constructed is that by under different layer structures a flexible adaptation to electrical values is possible and so Different variants can be created in a simple manner and without great effort can. This includes a bondable surface on the forehead that serves as a contact area side of the track. Additional pads (pads) can be placed on the contact area An additional bond wire can be attached so that components can be exchanged easily to enable elements in the event of repairs.  

In a further advantageous embodiment, the printed circuit board has an additional Si signal line layer, e.g. B. in the form of a separate single layer in the signal lines are integrated.

There can also be electrical control components for on one side of the busbar the printhead be arranged. The busbar is supported by copper existing metal plates heat dissipation.

In a modified form and length, the circuit board can also be used with other products are used, especially if thick copper layers with end connections for strip or welded connections are required.

Embodiments are shown in the drawings and are in the fol for example described in more detail. Show it

Figure 1 is a schematic sectional view of a print head for an electrographic printing device.

Figure 2 is a schematic perspective view of the arrangement of a power rail in the printing head.

Fig. 3 is a schematic perspective view of the bus bar, partially broken up;

Fig. 4 is a schematic representation of a row of contacts formed as bond pads of the busbar and

Fig. 5 is a schematic representation of a printhead with a busbar with control components integrated thereon.

An optical character generator (print head) shown in FIG. 1 for an electrographic printing device, as is known in principle from EP-0 404 766 B1, consists essentially of a carrier part 10 made of solid copper with one on the front side of the carrier part 10 arranged LED array 11 with associated control circuits 12 for the LED array 11 in the form of z. B. IC-B circuits. The carrier part 10 has at the Bodenbe rich cooling fins 13 . Instead of the cooling ribs 13 or in addition to these, the carrier part 10 can also be cooled by a cooling medium via flow channels 13/1 shown in FIG. 5. The end face of the carrier part 10 has a precisely machined flat end face 14 for receiving the LED array 11 with the associated control circuits 12th It absorbs the heat generated during operation of the LED array 11 and dissipates it via the carrier part 10 . Between the end face 14 and the cooling fins 13 , the carrier part 10 is constricted in cross section. In this area 10 busbars 15 are arranged on both sides of the support part, which supply the control circuits 12 and thus the LED array 11 with operating voltages of high power. In the exemplary embodiment shown, these are the voltages 0 V, 3 V and 5 V, which are supplied to the end of the busbars 15 and are passed to the control circuits 12 via corresponding connecting lines 16 . The structure of the bus bars 15 will be described later.

The printhead is arranged in a housing 17 made of extruded profile, which on the one hand accommodates a Selfoc device 18 which serves to image the excited LEDs of the LED array 11 optically on a photoconductor of the electrographic printing device, and on the other hand a correction device for comparing the LED arrays 11 in the form of a photo element 19 which , depending on the operation, is guided through an optical device through the optical path of the Selfoc device 18 and which scans the light energy emitted by the LEDs and compares the LED array 11 with it. The matching device is mechanically guided on the housing 17 formed on the guide rails 20 and slides in the operating case driven by cables, not shown here, on the guide rails 20 of the housing 17 , which extend over the entire width of the character generator.

A busbar 15 for supplying current or voltage to the LED array 11 or the associated control circuits 12 is, as can be seen in particular from FIG. 3, constructed as a multi-layer compact arrangement. It contains a layer arrangement of metal plates 22 , e.g. B. of copper, with intervening insulation layers 23 , z. B. from prepreg or other insulating base material. The metal plates 22 have comb-like connecting fingers 25 or tines which, starting from the planes of the metal plates 22, are nested so that they converge in a contact plane. As in the exemplary embodiment shown, this contact plane can run parallel to the metal plates 22 and thus form the outer layer of the busbar, or it can also be arranged centrally or off-center, depending on the application. The ends of the connecting fingers 25 form a single-row contact row 27 in the contact plane from a single contacts 28 for receiving the connecting lines 16 for the LED array 11 . In the Darge presented embodiment, the contact row 27 is formed in one line, it may also be formed in several lines where appropriate.

According to the different electrical load values, the metal plates 22 can have different strengths. The same also applies to the connecting fingers 25 , which, as shown in FIG. 4, can have differently designed cross sections. The bonding pads serving as terminal ends of the fingers 25 in the area of contact row 27 are so det ausgebil that each electrode is associated with a bonding pad. However, it is also possible to assign each connecting finger 25 to several or wider or larger-area bond pads on the contact row 27 , on which additional bond wires can be contacted. This makes it easier to exchange and repair the elements of the LED array 11 or the control circuits 12 . Designing the bond pads (individual contacts 28 ) accordingly in accordance with the representation of FIG. 4 depending on their associated circuit with different areas, this facilitates the automatic bonding or the detection of the corresponding circuits when making contact when installing the busbars 15 in the Printhead.

The bus bars 15 can be, for example, as manufactured follows: fen from a Metallstrei optionally in different strength for a polabhängige voltage of 0 V, 3 V, 5 V, are comb-shaped lead fingers 25 are punched for nesting of a three-layered structure of the bus bar 15 and formed thereby or, if necessary, etched or engraved and then bent. Then z. B. in a manufacturing benefit or a mold, the individual stamped metal plates 22 with insulating plastic. It is also conceivable to press the individual metal plates 22 with the insulation layers 23 in between.

The busbar 15 thus finished is separated from the manufacturing benefits, revised on the top and processed with nickel and gold to form a bondable busbar 15 . The size of the bond areas (individual contacts 28 ) and the thickness of the copper layers (metal plates 22 , connecting fingers 25 ) are determined by the electrical values and the bond requirements. It is also conceivable to galvanically coat the connecting fingers 25 with a nickel or gold layer prior to casting with plastic.

As can be seen from FIG. 2, three connecting fingers 25 (individual contacts 28 ) are required for contacting the control circuits 12 with the busbar 15 . The dimensioning of the connection finger width is determined by the IC width on the one hand and the electrical values on the other. By suitable contacting of the control circuits 12 with the carrier part 10 , a layer of the layer arrangement in the busbar 15 can optionally be dispensed with. Here, the carrier part 10 itself becomes a suitable 0-volt line.

It is also possible, as can be seen from FIGS. 1 and 5, to arrange additional printed circuit boards 29 on the busbars 15 along their side faces for receiving components for the control electronics of the printhead. This circuit board 29 can either be designed independently or it can consist of additional layers of the entire busbar circuit board 15 . In these additional layers, it is possible to arrange signal lines which can be used to supply control signals to the control circuits 12 . These signal layers can also have corresponding contact rows with additional bondable individual contacts corresponding to the contact rows 27 of the contacting layer. B. are arranged in a parallel row of contacts to row 27 of contacts. Mechanical bonding of these additional components with their signal lines is thus possible in a corresponding manner.

The heat generated during the operation of the additional components is reliably dissipated by the busbar 15 with its copper plates. This safe derivation can be reinforced if the busbars 15 are glued up with their inner surface on the carrier part 10 . Regardless of the busbars 15 are secured and attached by gluing to the Trä gerteil 10 .

In the exemplary embodiment shown, the busbars formed as a multilayer arrangement are used in an optical character generator of an electrographic printing device for supplying operating voltages to the LED arrays 11 . However, it is also possible to design these busbars as an independent component and in a correspondingly modified form for other applications, for. B. Stromver supply circuits, transformers and for the power supply of an electrical consumer: This is particularly advantageous when thick copper layers with end connections for strip or welded connections are required.

It should also be pointed out that the number of metal plates 22 and the number of contact rows 27 vary depending on the desired number of poles and the application. The printed circuit board 15 can be arranged on one or both sides of the carrier part 10 when used in the field of optical character generators, depending on the configuration of the LED array 11 . In the exemplary embodiment shown in FIG. 2, approximately 75 control circuits 12 are supplied with approximately 225 connections via the busbar 15 .

As explained above, additional components for driving the LEDs can be arranged on the busbars 15 on one side or on the sides. These components can also, as shown in FIG. 5, consist of individual integrated control components 31 which are glued to the outside of the busbar and which are then connected accordingly to the control circuits 12 by bonding or other connection methods. If the carrier part 10 is formed correspondingly narrow, it is also possible to arrange on the end faces 14 of the carrier part 10 only the LEDs designed as chips ( FIG. 5) and the additional and associated control circuits 12 or the additional control electronics on the side on the busbars 15 . This results in a particularly narrow design of the character generator and good heat dissipation via the busbars. The LED arrays 11 can also be designed as mini modules in accordance with DE-41 29 146 A1. It is possible to form the mini modules made of copper or printed circuit board material and to provide them with a predetermined kink, in which case the actual LED chip is arranged on the end face 14 and the associated control circuit 12 is connected to the busbar 15 by bonding in the area of the kink is. These mini modules or the entire electronics unit can also be formed in thin-layer ceramics in one or more layers in the form of low-sintering green ceramic foils, so that the conductor tracks pivot 90 ° ge from an electronic module constructed in multichip module technology, which is an application with vertically arranged electronics in relation to the LED chip. The production of multilayer circuits with low-sintering green ceramic films is known from the literature (see Electronics, Production and Testing Technology, Issue 9A, 1986). Instead of a bond connection between the control circuit 12 and the LED array 11 , it is also possible to use a FIexline 30 ( FIG. 5) or another shaped part made of metal using zebra crossing technology, which contacts the end face 14 on the one hand and the busbar 15 on the other hand the associated electronics pre-assembly group is glued or soldered. This is followed by a bond between the molded part and the LED chip or the molded part and the integrated circuits of the electronics preassembly group. In order to enable easy replacement in the event of a repair, it is also conceivable for the control circuits 12 to be detachably mounted on the busbar 15 , for. B. to arrange via screw or snap connections. Furthermore, the control circuits or the additional integrated circuits can be arranged directly on the carrier part 10 and the busbars 15 overlapping on the IC's or below them. It is also possible to produce busbar 15 and associated control circuits 12 integrated in a single structural unit in the green ceramic film technology described, or else in the customary circuit board technology.

Reference list

10 support part
11 LED array
12 control circuit
13 cooling fin
13/1 flow channel
14 end face
15 track
16 connecting lines
17 housing
18 Selfoc facility
19 photo element
20 guide rails
22 metal plates
23 insulation layers
25 connecting fingers
27 row of contacts
28 individual contacts
29 additional circuit boards
30 Flex-Line
31 control components

Claims (7)

1. printhead for an electrographic printing device with an LED array ( 11 ) arranged on one end side of the printhead with at least one busbar ( 15 ) arranged perpendicular to this end side and made of individual metal plates ( 22 ) one above the other with insulating layers ( 23 ) in between, wherein comb-like connecting fingers ( 25 ) are formed on one side on the metal plates ( 22 ) and, starting from the planes of the metal plates ( 22 ), are brought together to form a contact plane in such a way that the ends of the connecting fingers ( 25 ) one or more rows of contacts ( 27 ) along the end face ver current individual contacts ( 28 ) for receiving connecting lines ( 16 ) form. 2. Printhead according to claim 1, wherein the ends of the connecting fingers ( 25 ) have different cross-sectional shapes. 3. Printhead according to one of claims 1 or 2, wherein the individual contacts ( 28 ) of the contact rows ( 27 ) are designed as bonding surfaces. 4. Printhead according to claim 3, wherein each individual contact ( 28 ) in the region of the contact rows are associated with a plurality of bonding surfaces. 5. Printhead according to one of claims 1 to 4, wherein the metal plates ( 22 ) with the closing fingers ( 25 ) are formed as one-piece stamped parts. 6. Printhead according to one of claims 1 to 5, wherein at least on one side of the busbar ( 15 ) electrical control components ( 31 ) for the printhead are arranged with associated signal lines which have a single or multi-cell contact row for receiving the connecting lines ( 16 ) . 7. Printhead according to claim 1 to 8 with a carrier part ( 10 ) with a flat end face ( 14 ) and a narrower receiving area for at least one busbar ( 15 ).