FI88134B - RELEASE INSTRUCTIONS FOR OWNING - Google Patents

Description

1 38134

The present invention relates to a printer or other similar printing device for marking a document fed to its paper path, comprising at least one paper path-related means for detecting a document, comprising a light transmitter and a light receiver arranged on the paper path. -10 The document causes a change in the amount of light received by the light receiver.

Conventional printers, such as those used in banking, use photoelectric components to detect a document, so that they can be applied in a number of, typically three, different ways. It is possible to arrange a light source, such as an LED emitting infrared light, at the bottom of the paper web and a light transistor arranged at a corresponding point on the top surface of the paper web, which detects the light emitted by the LED when there is no obstacle between them. As a second basic principle, a procedure can be applied in which both the light source and the light receiver are both placed at the bottom of the paper path, whereby light is made to pass between them when a document with a reflective lower surface 25 is brought above them. As a third basic principle, a situation can be mentioned in which, as above, both the light transmitter and the receiver are placed at the bottom of the paper web, but are continuously connected to each other by a light beam reflecting means such as a prism arranged on the top surface of the paper web. In this case, importing the document onto the paper path will cut off the connection between the light transmitter and the light receiver. Typically, point detectors such as those described above are used at the edge of the paper path in the vicinity of the document response. Since, when using such a printer, the document 2 88134 must be placed against the edge response, it is sufficient that the document detecting detector be placed in the vicinity of this edge response. In this situation, even the presence of a single point detector can detect the presence of a document on 5 paper paths.

In order to detect whether a document is on a straight paper path, i.e. whether its trailing edge is perpendicular to the longitudinal direction of the paper path, structures developed from the above-mentioned basic detectors are used, in which two detectors as described above are arranged on the same line perpendicular to the longitudinal direction of the paper path. When only one of these indicators indicates that the document is on the paper path, it is known that the document is not straight. Instead, when both detectors detect 15 documents, it is known that the document is straight. Naturally, a prerequisite for this is that the line on which the detectors are located is right at the trailing edge response of the document. The purpose of this trailing edge response is to ensure that the document is straight before feeding it to the paper path.

In a printer where document input is allowed virtually anywhere on the paper path without having to be placed against the side edge response, the document can, of course, still be detected by applying detectors such as those described above, as long as they are placed in a sufficient number across the paper path. However, the problem in this case is to monitor the signals of several light transmitters and in particular several light detectors. Although the simultaneous monitoring of several light-30 detectors is easy to arrange, it nevertheless leads to an increased need for wiring when applying conventional solutions, as well as to the complexity of the detection equipment itself. In the case of mass-produced printers, which should also be as small as possible, these 3 38134 factors are also relevant to the competitiveness of the product.

It is therefore an object of the present invention to provide a printer or other similar printing device in which the feeding of a document to a paper path is allowed from anywhere on the paper-5 path, but in which the expression of the document can still be performed very simply. A printer or other similar printing device according to the invention which fulfills this object is characterized in that the light path between the light transmitter and the light receiver comprises optical means placed on opposite surfaces of the paper web at a distance from each other in the transverse direction of the paper web.

15 If it is desired to observe the perpendicularity of the document to the paper path, in which case the light receivers have to be arranged in pairs, the printer or other similar printing device according to the invention is characterized in that the light paths several times across the paper path before bringing it to the light receivers.

Preferably, the optical means comprises an optical fiber arranged in the form of a prism or a piece of arc for reversing the light beam to travel again across the paper web from the entry point at a distance in the transverse direction of the paper web.

According to a preferred embodiment, in determining the perpendicularity of the document, the optical means is a prism comprising two light entry points and two light output points, thus forming part of both light paths.

In the following, a printer or other corresponding printing apparatus according to the invention will be described in more detail with reference to the accompanying drawing, in which Fig. 1 shows a method according to the invention for detecting a document on a printer's paper path, Fig. 2 shows a method according to the invention for pairing light detectors. and Fig. 3 shows a second embodiment of an optical means for use in connection with the procedure of Fig. 2.

Fig. 1 shows the placement of an optical medium on the printer's paper path 1 so that a document (not shown) fed to the light path between the light transmitter U1 and the light receiver Q1 causes a change in the signal 15 received by the light receiver Q1 when the document is fed substantially anywhere in the paper path. Such a feature is obtained by directing a light beam to pass several times across the paper path 1 separately from its polar points by means of optical means 2. In the embodiment of Figure 1, these optical means 2 consist of prisms which first receive a light beam and then turn it to travel in the transverse direction of the paper web 1 before guiding it again from a new point across the paper web. By dimensioning the prisms as desired, a desired number of spaced locations where the light beam crosses the paper path is generated. By thus dimensioning the prisms 2 appropriately, crossing points are obtained to such a density that a document meeting the definition of the smallest permissible document is always reliably detected. Although in the embodiment of Fig. 1 the prisms 2 direct the light beam to pass perpendicularly across the paper path 1, it is also possible that the light rays are directed to pass diagonally across the paper path, whereby the structure of the optical medium could even be simplified. the simplest possibility in this case is provided by the use of 5 88134 mere reflective mirror surfaces which would direct the light beam to pass zigzagging over the paper path from the light transmitter to the light receiver. However, the problem would then be to obtain sufficiently narrow-beam light beams. This feature is improved in the embodiment of Fig. 1 by placing light masks 9 on both surfaces of the paper web in front of both the optical means 2 and the light transmitter UI and the light receiver Q1, which allow light to pass only in the form of narrow beams. In this way, the detection is made as location-sensitive as possible and, on the other hand, the disturbing effect of the light entering the detector from the environment is avoided. The environmental impact can be further reduced by modulating the light emitted by the light transmitter as desired.

By means of an arrangement such as that shown in Figure 1, it is possible, if desired, to realize the detection of the entire paper path by means of one light transmitter and one light receiver. However, it is conceivable, especially if the paper web is relatively wide, that several of the arrangements of Figure 1 are arranged in parallel in the transverse direction of the paper web. The main reason for such a procedure is the attenuation of the light signal in its path to such an extent that it can no longer be reliably detected.

Figure 1 illustrates an optical device 2 consisting of a prism, which can be made very simply, for example, by molding from a plastic material. Thus, the cost of such prisms is made very low, in practice substantially lower than the cost of a single light transmitter or light receiver. In addition, the dimensions of such a casting are made very precise, and on the other hand, protrusions or the like can be easily formed thereon, which facilitates its installation. As an alternative structural solution to a prism as shown in Fig. 1, an optical means as shown in Fig. 3 35 may be shown, consisting of a piece of optical fiber 6 38134 bent into an arc. In this case, each optical device 2 in Figure 1 would be replaced by one piece of fiber. However, a problem with the use of optical fibers is their relatively smallest allowable bending radius, as a result of which they require a relatively large amount of space in the height direction of the paper web. In addition, it is difficult to install them with sufficient accuracy.

Figure 2 shows a solution utilizing the procedure according to the invention for detecting the perpendicularity 10 of a document. When it is desired to detect whether a document is perpendicular to the longitudinal direction of the paper path, typically two detectors are placed located on the same line transverse to the paper path. If the input of a document is allowed substantially from anywhere on the 15 paper paths, several such pairs of spinnerets will have to be placed in the transverse direction of the paper path. A solution to this situation is provided by the procedure according to Fig. 2, in which the light path between the light transmitter and light receiver pairs U1, Q1 and U2, Q2 is controlled in the same way as in the embodiment of Fig. 1. These light paths are thus guided by means of optical means 4 to pass several times across the paper path 1 from points separated in this direction in the transverse direction. Since there are two signals to be transmitted in this way as well as signals to be received, the optical means 4 have to be designed with this processing of the two signals in mind. As a result, they comprise two light input points 5 and 6 and two light output points 7 and 8, respectively. The signal from point 5, transmitted by the light transmitter UI in the embodiment according to Fig. 2, folds inside the prism 4 so as to leave point 7. Correspondingly, the signal transmitted by the light transmitter U2 enters the prism 4 at point 6 and leaves it at point 8. As can be seen from Fig. 2, the signal paths then possibly intersect with each other. However, due to the nature of the light, 7 38134 does not become a problem.

The same advantages associated with the mass production of molded plastic bodies as in the manufacture of the optical device 2 of Figure 1 can be utilized in the manufacture of the optical device used in the embodiment of Fig. 2. Thus, the embodiment according to Fig. 2 is made very cost-effective.

Figure 3 shows an alternative to the optical means 4 of Figure 2. This alternative optical means 10 according to Figure 3 consists of two pieces of optical fiber bent into an arc and arranged to overlap, whereby the light paths are also made to overlap. This structure of Figure 3 has the same problems as the use of a single piece of optical fiber, which have already been referred to above.

Typically, the light transmitters are infrared light emitting LEDs, but they could also consist of other types of light emitting components or, in the case of the embodiment of Figure 2, even a single wide-area light transmitter transmitting two light signals through openings in the light mask 9. Light receivers, in turn, are most preferably phototransistors. It will be appreciated, however, that the nature of the light transmitters and light receivers may differ from that shown and, in fact, all conventional photosensitive components may be used in the printer of the invention as long as they are applied to these components to transmit or receive light. As for the operation of the embodiment according to Fig. 2, it can further be noted that the signals received from the light receivers Q1 and Q2 are combined in a conventional manner with a logic element which detects when both signals are in a state corresponding to the document fed to the paper path. In this case, the 35 document is considered to be perpendicular to the paper path 8 38134 with the detectors positioned just at the trailing edge response of the document.

The printer or other similar printing device according to the invention, and in particular the associated means for detecting the presence or perpendicularity of a document, has been described above with only some exemplary embodiments, and it is understood that several changes may be made to the described structural solutions without departing from the scope of the appended claims.

Claims (5)

9 «8134 A printer or other similar printing apparatus for making entries on a document 5 fed to its paper path (1), comprising at least one paper path-related means for detecting a document comprising a light transmitter (UI) and a light receiver (Q1) arranged on the paper path (1) so that the light transmitter (UI) and the document fed to the light path between the light receiver (Q1) causes a change in the amount of light received by the light receiver (Q1), characterized in that the light path between the light transmitter (UI) and the light receiver (Q1) comprises optical means (2; 3) spaced opposite the paper path -15 reasons apart in the transverse direction of the paper web (1) to cause light to pass several times across the paper web before it is brought to the light receiver (Q1). A printer or other similar printing device for marking 20 documents fed to its paper path (1), comprising at least one paper path-related means for detecting the perpendicularity of the document to the paper path, comprising at least one light source (UI, U2) and two light receivers (Q) Q2) arranged on the paper path (1) so that a document fed to the light paths between the light transmitter or transmitters (U1, U2) and the light receivers (Q1, Q2) perpendicular to the paper path causes a change in the reception of both light receivers (Q1, Q2). the light paths between the light transmitter or transmitters (U1, U2) and the light receivers (Q1, Q2) comprise optical means (2; 3; 4) placed on opposite surfaces of the paper web to cause light to pass several times across the paper web 35 before it n to the light receivers (Q1, Q2). 10 88134 A printer or other similar printing device according to claim 1 or 2, characterized in that the optical means comprises a prism (2) for reversing the light beam to pass again across the paper web from the entry point at a distance in the transverse direction of the paper web. A printer or other similar printing device according to claim 1 or 2, characterized in that the optical means comprises an arc-shaped piece (3) of optical fiber for reversing the light beam to travel again across the paper web from the entry point at a distance in the transverse direction of the paper web. A printer or other similar printing device according to claim 2, characterized in that the optical means is a prism (4) comprising two light input points (5, 6) and two light output points (7, 8), thus forming part of both light sources. of the crossing. li * 8134