DE3333368A1 - OPTICAL CIRCULAR PRINTER - Google Patents

Description

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The invention relates to a flow printer according to the preamble of claim 1.

With such printers there is information to be recorded thereby printed on a recording medium / that light, 2. B “a laser beam, with one the information containing. signal is modulated. The rotary printer prints the information on a stationary recording medium, by means of light sources arranged on a rotary member Recording light is emitted.

Because laser light sources light rays with high spatial Can generate interference and high spectral line luminance, which is not possible with other light sources, they are used in various optical recording and recording Readers used. Ss is already an optical recording apparatus for recording information known by means of a laser beam, in which one with one the information containing signal modulated laser beam from a Liehtablenker, for example a galvanometer mirror or a multi-surface rotating mirror, is deflected while a laser beam-sensitive recording medium two-dimensional with the laser beam for recording the Information on the recording medium is scanned.

However, the known device requires expensive individual parts, such as, for example, the rotating mirror and a fG lens, which are very expensive. In addition, since the optical path between a converging lens of the laser light emitter and the recording medium is long, it is not possible to collect the laser beam at a high density and to perform recording with high resolution and high luminance o To reduce the distance between the converging lens and the recording medium , there has been proposed a laser printer in which a recording medium

is held on the peripheral surface of a rotatable, drum-like printing pad. In this device, a laser light emitter is located in the vicinity of the peripheral surface of the printing sheet, whereby the main scanning is carried out by rotating the printing sheet, while secondary scanning is carried out by moving the laser light emitter along the axis of rotation of the printing sheet. In this device, however, äXe dimensions of the drum-like pad are very large, if a recording medium of reasonable size is to be printed. In addition, it is not possible to rotate the printing substrate at high speed, so that the printing speed of this known laser printer is relatively slow.

The invention is based on the object of providing a printer of the type mentioned above which is able to To quickly record information with high resolution and high luminance. The information should be consistent with high Resolution and high speed can be recorded.

According to the invention, this object is achieved by means of claim 1 specified features solved.

According to the invention, light sources and converging lenses are provided Recording light emitter for the outward emission of recording light in the circumferential surface of the provided by the rotary drive rotated rotary member. The recording medium becomes concentric around the rotary member stored to this. The rotary member is movable parallel to its axis of rotation. The recording paper becomes two-dimensional scanned with the recording light emitted from the recording light emitters, namely by the movement of the rotary member along its axis of rotation in

With respect to the recording medium, the recording light emitter are designed / that they are finely adjusted can be.

However, the invention is not limited to the embodiment of the printer explained above. According to the invention are in an optical system of a multiple light beam printer, are formed in the mutually parallel scanning lines that several light beams on one Acquire scanning surface elliptical shape, positioned, the elliptical light rays made rotatable on the scanning surface. Since according to the invention the scanning surface is scanned with several light beams by their movement with respect to the scanning surface, can configure the scanning mechanism optically and mechanically in different ways. To the rotation of the elliptical To enable light rays, the light sources can be rotated or the rotation can be through an optical one Set up = Although many light sources should preferably be used, it is also possible to use Use a single light source to form many rays of light. The light sources are used to represent the Information activated by a driver current, which is connected to a modulation signal containing the information is modulated, as it is with the other printers of this type

the case is. . - - "-...

In the rotary optical printer according to the invention, in which the recording medium is held stationary and the Light sources are rotated, the recording light emitters are semiconductor laser sources or the like can therefore be very small, and therefore the rotary member for receiving the recording light emitters correspondingly small and small

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Have weight. It is therefore possible / to operate the rotary link at higher speeds and record to be done at a higher speed than in the prior art. As the recording light emitters be arranged in the vicinity of the recording medium can, the laser beams can be sufficiently collected / so that the recording with high resolution and high Luminance can be done. There are also the recording light emitters are rotatable and the cross-sections of the light beams on the recording medium can be rotated / it is possible to eliminate any unevenness in the recording process.

Since you in the printer according to the invention from the neighboring Light rays_formed light intensity distribution can change in the direction perpendicular to the scanning direction, there is the possibility of a high quality Recording (which is completely free of irregularities, for example) or special effects (including blurring (blurring)) by changing the angle of the elliptical light rays to overlap the light rays or to separate the light beams changed or the extent of the overlap in accordance with the properties of the recording medium and / or the gradation is changed. In addition to the semiconductor lasers mentioned above, light-emitting diodes are used, which are lightweight, can be modulated directly at high speed and Emit light beams that -sich like laser beams through high luminance and special properties, such as. B.

Convergence, excel.

In the following, exemplary embodiments of the invention are explained in more detail with reference to the drawing. Show it:

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a perspective view of an optical tM run printer with partially broken parts,

Fig. 2 is an enlarged view of a part

of the printer shown in Fig. 1 "

Fig. 3 is a schematic view of a part

of the printer according to Pig »1 _f 10

4 shows a sectional view of part of the printer according to FIGS. 1, 1 _a and

FIG. 5 is an enlarged perspective view of a portion of the printer shown in FIG.

That shown in Figure "1 optical circulating printer has a curved top surface having pad 2, which is attached to a frame 1 on a table, and a rotary member 4 _f which is mounted above the printing base 2 by means of einesArms 3» Ber Atm 3 has in the rear section rod bearings 5 and 6 _B in which mutually parallel and aa the frame 1 fixed rods 7 respectively, run 8_ "This i-yiard the arm 3 of the rods 7 and 8 so mounted _p he su in the direction of arrow Ά able to slide »iwisclien the rod bearings and 6 a nut 9 is provided on the arm 3, which is in engagement with a threaded spindle 11 rotated by an axis motor 13 Arrow Ά.

Figure 2 is an enlarged _o © Jtosieht "3 pad

and the rotary member 4 mounted on the arm 3. As can be seen from FIG. 2, the printing pad 2 has an upper one curved side 11 for receiving a recording paper. The upper side 12 is configured concentrically with respect to the circumferential surface 13 of the rotary member 4. At certain Places of the recording paper support surface 11 are located there are recording paper suction holes 14 that have (not tubes shown) are connected to the negative pressure side of a vacuum pump 15 built into the device.

Therefore, if one is to record information by exposure with a laser beam, for example. Recording paper 16 in a predetermined position the surface 12 of the printing substrate 2 is placed and the vacuum pump 15 is set in motion, the recording paper 16 firmly held on the carrier side ^ JI 2. However, needs does not adhere to the recording paper 16 by suction the pad to be held, but other means can also be used. In addition, instead of of the recording paper 16 also any other recording material use.

The rotary member 4 is formed in that on a flat cylindrical part, which consists of a peripheral surface 13 and a bottom surface 17, a cover plate 18 (see Fig. 1) is mounted. The peripheral surface 13 has 4 elongated ones Laser beam exit window 19, which are arranged at regular intervals on the same circumference. Within each laser beam exit window 19 is located a laser beam emitting section 20 for emitting laser beams through the laser beam exit window 19 to the outside. The laser beam emitting sections 20 are fixed to the bottom surface 17. As shown schematically in FIG is, four laser emitters 21 are fixed in each laser beam emitting section 20 with their centers with the circumferential direction of the rotary member 4 are aligned. The four

Laser beam delivery sections 20 have an identical structure, and therefore the centers of the laser emitters of the four laser beam emitting sections 20 are all on the same Perimeter line positioned. The sixteen laser emitters 21 are positioned on a single common circumferential line. Each laser emitter 21 contains a semiconductor laser 23 and a collecting lens 24 which are carried by a cylinder bearing 22 will.

As can be seen from FIG. 4, each semiconductor laser 23 is supported in its bearing 22 by means of fine adjustment screws 25. By operating the fine adjustment screws 25, it is possible to adjust the optical axes of the laser beams independently to pivot from one another in the direction of arrow B in FIG. In addition, the laser emitters 21 can be around their tilt optical axis.

As shown in Fig. 5, there are in each laser beam emitting section 20, the optical axes of the four laser emitters 21 are set such that the optical axis Lb of the second laser emitter 21b is aligned with the mounting center C of the emitter, the optical axis La of the first laser emitter 21a by 12 μΐη on the recording paper 16 in the direction of the arrow A in Fig. 1 is offset to the right from the mounting center C of the radiator, the optical axis Lc of a third laser emitter 21c by 12 µm on the Recording paper in the direction of arrow A from the assembling center C is offset to the left, and the optical axis Ld of a fourth laser emitter 21d is offset by 24 µm on the recording paper 16 is offset in the direction of arrow A from the assembly center C to the left. Hence be the four laser beams emitted from each laser beam emitting section 20 at intervals of 12 µm in the moving direction of rotary link 4 (in the direction of arrow A

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in Fig. 1J directed to the recording paper 16 on.

These four laser beams are directed onto the recording paper 16 so that their centers are spaced apart by a predetermined distance (here 12 μπι) are away from each other. In general is the cross section of the laser beams on the recording paper 16 elliptical. In this case the longer through ' diameter of the ellipses of the laser beams in de.r main scanning direction or in the sub-scanning direction. The laser beams should preferably be adjusted so that the scan lines formed by the adjacent laser beams partially overlap each other when they scan the recording paper 16. When the recording lines of the Laser beams do not overlap, so it sometimes happens that gaps are created between adjacent scanning lines. In addition, it is not always necessary to have available semiconductor lasers which have the same light propagation angle possess · 'and for this reason too the scan lines formed by the laser beams should: themselves partially overlap. If furthermore, as desired, the directions of the longer diameters of the laser beam cross-section « can be made rotatable, so even with fluctuations in the characteristics of several semiconductor lasers, the possibility is created Eliminate recording irregularities by mounting some semiconductor lasers at different angles than other semiconductor lasers. (by considering the directions of the longer diameters of the elliptical beam cross-sections changes).

The rotary member 4 equipped with the laser beam emitting sections 20 in the above manner is moved in the direction of the arrow D (Fig. 1) rotated by a motor 26 with an external rotor, which is mounted in the central section of the rotary member 4 is. "Inside the cover plate 18 of the rotary member 4, a secondary pressure spool 27 is fixed, while inside

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a bearing portion 28 of the arm 3, a primary pressure coil 29 is fixed. A high-frequency current for driving the semiconductor laser, which is modulated with a signal containing the information to be recorded, is applied to the primary printing coil 29 on the stationary side. The current is supplied via a cable 31 which is suspended from a tension wire 30 / as FIG. 1 shows. The high-frequency current supplied to the primary pressure coil 29 is transmitted to the secondary pressure coil 27 located in the rotary member 4 due to the inductive coupling. ment between the coil 29 and the coil 27 transmitted without contact. The supply of the semiconductor laser drive current to the rotary member 4 is instead possibly also carried out by means of a slip ring and a brush. The power supply by inductive coupling has advantages, however, since no disturbances occur and there is no risk of electrical circuits in the vicinity being adversely affected by disturbances. The power supply to the motor 26 provided for rotating the rotary member 4 is also carried out via the cable 31. The starting point of the rotary member 4 is detected by a rotary encoder (not shown) which is arranged inside the rotary member 4, as well as by a (not shown) Detector section which is attached to the arm 3. The range in which the rotary member is moved, is covered a cover 32 of · the i shown in Fig 1 partially is. If the cover 32 is made of a material which transmits light to which the recording paper 16 is not sensitive, the operation of the printer can be observed from the outside.

The optical rotary printer described above works as follows: The printer is connected to a recording information transmitter via cables connected, and the operation

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the printer is controlled via a control panel 33 on the front controlled by the printer. Before the start of the recording process, the rotary member 4 is in the right End portion of the recording paper 16 is positioned. When a signal is sent from the recording information transmitter which indicates the information to be recorded and the printer is turned on, the motor 26 rotates the rotary member 4 in the direction of arrow D in FIG 1. At the same time, the arm 3 supporting the rotary member 4 is moved to the left in the direction of the arrow A in FIG. Therefore, the rotary member 4 rotates with simultaneous movement over the recording paper 16 as shown in FIG. to the left. As a result, the recording paper 16 is cleared from the laser beam exit windows 19 of the rotary member 4 exiting laser beams are scanned two-dimensionally, with the direction of rotation of the rotary member 4 as the main scanning direction and the moving direction of the rotary member 4 parallel to its axis of rotation as the sub-scanning direction. As described above, the optical axes are the four laser emitters 21 of each laser beam emitting section 20 of the rotary member 4 is set so that it is on the recording paper 16 by 12 μι in the direction of movement of the rotary member .4 are offset from one another. Therefore, when the laser beam emitting section 20 is once runs over the recording paper 16, this is scanned in four scanning lines, each scanning line has a scanning width of 12 μΐη. As Fig. 2 shows, the four laser beam emitting portions 20 are positioned so that when a laser beam emitting portion 20 is one Angular rotation of 90 ° on a recording surface. E of the recording paper 16 and stop scanning, the next laser beam emitting portion 20 arrives at the end portion of the recording surface E at the same time and starts scanning. The arm 3 is so con ·?

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Structures that it is moved by 48 \ im (ie 12 ρ χ 4) with an angular rotation of the rotary member 4 by 90 °. As a result, the scanning width of each scanning line is always kept at 12 µm. Since the semiconductor lasers 23 of the laser beams 21 emitting the laser beams for scanning the recording paper 16 are excited by a drive current which is modulated with a recording information carrying fiodulation signal supplied from the recording information transmitter, the information coming from the recording information transmitter is written on the recording paper 16 recorded, which is sensitive to the laser beams emitted by the laser beams 21. After completion of the recording of the information, the arm 3 is returned to the standby position on the right in Fig. 1 and made ready for the next recording operation.

Since the semiconductor lasers used in the above embodiment are simple in structure, small in size have and light weight, are mounted in the thin rotary drum, and because of two-dimensional scanning is done with the laser beams by rotating and moving the rotating drum, it is at the above described embodiment possible to rotate the rotatable drum at high speed, so that high recording speeds be achieved. In addition, since the laser emitters 21 of the laser beam emitting sections 20 are arranged on a straight line in the direction of rotation of the rotary member and the optical axes of the semiconductor laser moved by using the fine adjustment screws will'-would, there is the possibility of a very small To achieve scanning width (12 ^ m) and an information recording perform at high density.

The procedure for positioning the recording lights

in the rotary member is not limited to the method described in detail above. Will be multiple delivery sections provided on the circumferential surface of the rotary member, so .that one of these discharge sections always receives the recording light is on the recording material when the rotary member is rotated, the rotation of the rotary member use to the maximum. If even more recording light emitters are arranged in each light emitting section, a plurality of scanning lines can be printed at the same time. Such measures increase the recording speed even more.

Claims (4)

Claims Optical rotary printer, with one on a stationary Base rotatably mounted rotary link on its peripheral surface Recording light emitters having light sources and converging lenses for emitting recording light are provided to the outside, with a rotary drive for rotating the rotary member, a power supply with which the arranged in the rotary member Electric power modulated with a predetermined modulation signal can be supplied to light sources, and with a printing pad that is integral with the pad is arranged and serves to fix a recording medium concentrically with respect to the rotary member, characterized in that a plurality of recording light emitters (21) in groups in a plurality of light-emitting sections (20) equidistant in the circumferential surface of the rotary member (4) is arranged so that the centers of the radiators (21) of each section (20) are aligned with one another and the " In the middle of the sections lie on a 'common circumferential line that die.Lichtquellen (23) rotatable with respect to the optical axes of the respective radiators (21) are adjustable, and that the locations of each radiator light rays impinging on the recording medium are adjustable in such a way that they are displaced equidistantly from one another in the direction of the axis of rotation of the rotary member (4) will. 2. rotary printer according to claim 1, characterized, that a motion drive is provided with which the .Dreh member (4) can be moved parallel to its axis. 20th 3. rotary printer according to claim 1 or 2, characterized in that • Wed; .. * "" v '\ "■■" that the light sources (23) are semiconductor lasers. _t 4. Rotary printer according to one of claims 1 to 3, characterized in that the power supply has a ¹ : inductive coupling device with which the electrical power is transmitted without contact.