KR840001155Y1 - Magnificatron changing apparatus for use in duplicators - Google Patents

Abstract

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Description

Magnification Converter of Copier

1 is a schematic diagram showing the principle of the magnification conversion operation of the copier.

2 is a graph showing the moving distance ratio between the objective lens and the first reflecting mirror at different magnifications.

Figure 3 is a block diagram showing an embodiment of a magnification conversion device according to the present invention.

4 is a graph showing the moving distance ratios of the objective lens and the first reflecting mirror at different magnifications in the embodiment of FIG.

5 (a) and 5 (b) are front and cross sectional views of a timing pully used in the embodiment of FIG.

6 (a) and 6 (b) are front and side views of the protrusions formed on the drive shaft shown in FIG.

7 (a) and 7 (b) show an operating state with respect to the straight line C of FIG.

The present invention relates to a magnification conversion device of a copying machine, in particular a magnification conversion device of a copying machine having an original reciprocating scanning exposure optical system.

In the copier of the known type, as shown in FIG. 1, the light rays reflected from the reciprocating object 1 pass through the objective lens 2 and are reflected by the first reflecting mirror 3, and then the remaining light is reflected. After being reflected back by the second lens 4, it is concentrated on the photosensitive member 5 to form an electrostatic virtual image, which is transferred to paper through a known electrophotographic process to obtain a copy.

In a copying machine having such a structure, radiation can be made according to different magnifications of the original 1, and the magnification of the electrostatic virtual image concentrated on the photosensitive material 5 is also provided with the objective lens 2 and the first reflecting mirror 3. Can be converted according to different distances of travel.

For example, assuming that each of the positions of the objective lens 2 and the first reflecting mirror 3 shown in FIG. 1 have the same magnification (1.005), each of the objective lens 2 and the first reflecting mirror 3 is 1; To get a copy with the next reduced magnification (0.808), go to the position indicated by the one-point makeover, while to get a copy with the second reduced magnification (0.707), go to the position indicated by the two-dot chain lines.

In such a case, the ratio between the moving distance of the objective lens 2 and the moving distance of the first reflecting mirror 3 between the time when moving at the first reduced magnification and the time when moving at the second reduced magnification. The problem arises.

As shown in FIG. 2, the movement ratio when moving to the positions a 'and b' of the first reduced magnification is Is indicated by a straight line A, and the movement ratio when moving to the position (a ", b") Is indicated by a straight line B. At this time Becomes

If the first reflecting mirror 3 of the objective lens 2 operates independently by different driving sources, the above problem does not occur. However, if the transmission ratios of the objective lens 2, the first reflecting mirror 3 and the driving source are fixed to any one moving distance ratio when the two are operated by a common driving source, this ratio is different from other moving distance ratios. Thus, inconvenience arises in that movement is limited to the position of the reduced magnification of one terminal.

For example, in the case of A, the movement to (a ', b') and (a ", b") can be easily performed, but the movement to (a ', b') and (a ", b") is easy. That's not true. Likewise for B, movement to (a ", b") and (a '", b') is easy, but movement to (a ', b') and (a", b ") is not easy.

The present invention has been completed in view of the above disadvantages, and an object of the present invention is to eliminate the disadvantages associated with the magnification conversion apparatus of the conventional copier. It is also to provide a magnification converting apparatus of a copier in which an objective lens and a first reflecting mirror can be moved to three different magnification positions using a single drive source. Therefore, to achieve the object of the present invention is to use a drive source having a travel distance ratio of "C".

An embodiment of the present invention is described with reference to FIGS. 3 to 6 as follows.

3 is a block diagram showing an embodiment of the magnification apparatus according to the present invention, the objective lens 2 is mounted on the lens carriage 6 and connected to a gas (not shown) to reciprocate, The first reflecting mirror 3 is mounted on the sliding block 7 so as to reciprocate in the same direction as the lens carriage 6 in connection with the guide (not shown), and the sliding molten carrier 7 is the lens carriage 6 Is heavier than).

The first junction element 8 is attached to one end 6a in the reciprocating direction of the lens carriage 6, while the second and third junction elements 9 and 10, which can be adjusted within the mounting length, are opposite ends 6b. ) Is attached. On the other hand, the first stop 11 is provided at one end 6a of the side of the lens carriage 6 in the copier body (not shown), and the second and third stops 12, 13 are provided. Is provided at the opposite end 6b, and the stops 11, 12 and 13 face the first, second and third junction elements, respectively. When the bonding element 8 is in contact with the first stop 11, the objective lens 2 is present at the position having the magnification a of FIG. 1, and the bonding element 9 and the second stop 12 are ) Is in contact with the objective lens 2 at the first reduced magnification a 'of FIG. 1, and when the junction element 10 is in contact with the third stop 13, 2) is present at the position of (a ") with the secondary reduced magnification of FIG. 1. The second stop 12 is adapted to move the second junction element 9 by means of a moving means 13 ', ie solenoid, respectively. It moves between the positions which interfere and do not interfere, and the 1st, 3rd stop bodies 11 and 13 are fixed.

The first junction element 14 is attached to one end 7a in the reciprocating direction of the movable block 7, while the second and third junction elements 15 and 16 have opposite ends that can be adjusted within the mounting length ( 7b). On the other hand, in the copier body (not shown), the first stop 17 is mounted on one side end portion 7a of the moving block 7, while the second, third stops 18, 19 is mounted on the opposite end 7b, and the stops 17, 18, 19 face the junction elements 14, 15, 16, respectively. When the primary junction element 14 is in contact with the first stop 17, the first reflecting mirror 3 is present at a position having the magnification b of FIG. 1, and the second junction element 15 and When the second stop 18 is in contact, the first reflecting mirror 3 is present at the position having the first reduced magnification b 'of FIG. 1 and is in contact with the junction element 16 and the third stop 19. The first reflecting mirror 3 is present at a position having the second reduced magnification b " of FIG. 1. The second stop 18 is secondly joined by the moving device 20, that is, the solenoid. It may be moved between positions that interfere with and do not interfere with the device.

Reference numeral 21 denotes an oral circle such as a memory motor having a timing pulley 23 and an output shaft 22 mounted to the bevel gear 24, which is driven by a timing belt 25. It is connected to a timing pulley 27 rotatably mounted at 26. A notch 41 is formed in the timing pulley 27 so that the protrusion 40 formed on the drive shaft 26 is rotated at a predetermined angle.

The drive pulley 28 on which the cable 29 is wound is installed on the drive shaft 26. One end of the cable 29 is retained in the movable block 7 through the spring 30, while the other end is wound around the idler pulley 31 and then the movable block 7 through the spring 32. Is maintained.

On the other hand, the bevel gear 24 meshes with the bevel gear 34 integrated with the drive pulley 33. The cable 35 is wound around the drive pulley 33 and the end of the cable is held on the lens carriage 6 via a pair of pulleys 36 and 37. The pulleys 36 and 37 are mounted in the reciprocating direction of the lens carriage 6 through springs 38 and 39, respectively.

The movement rate of the output side 22 and the moving block 7 and the movement rate of the output shaft 22 and the lens carriage 6 (the side, the movement distance ratio of the lens carriage 6 and the movement block 7) are shown in FIG. It is the value shown by the straight line C of FIG. 4 connected from the primary reduction magnification positions a 'and b' to the 2nd reduction magnification positions a "and b" of FIG.

In the operating state, the first junction elements 8 and 14 are attached to the first stops 11 and 17, respectively, such that the objective lens 2 and the first reflecting mirror 3 occupy positions a and b of the same magnification in FIG. Moved in contact. In this state, the drive source 21 is operated to rotate the output shaft 22, so that the drive pulley 33 rotates through the bevel gears 24 and 34, whereby the cable 35 moves in the direction of the arrow A. And the lens carriage 6 is moved to the right side of the drawing.

At the same time, the rotation of the output shaft 22 is transmitted to the timing pulley 27 through the timing pulley 23 and the timing belt 25, and eventually the timing pulley 27 rotates in the direction of the arrow C. The timing pulley 27 alone turns against the drive shaft 26 until the cutout 41 and the protrusion 40 contact each other, because it is rotatably mounted on the drive shaft 26. Therefore, the drive shaft 26 does not rotate and the moving block 7 does not move during the interval (the interval until the protrusion 40 contacts the cutout 41).

Therefore, the first reflecting mirror 3 stops until the objective lens moves to a predetermined position (i.e., a point 'a' "in which the straight line C of FIG. 4 crosses the longitudinal coordinate axis).

If the drive source 21 is activated to rotate the output shaft 22, the lens carriage 6 moves to the right as described above, and at the same time the rotation of the output shaft 22 causes the timing pulley 23 and the timing belt 25 to rotate. And the driving pulley 28 is rotated and the cable 29 is moved in the direction of the arrow B through the timing pulley 27, the notch 41, and the drawing part 40, and is driven. The moving block 7 may move to the right foot of the drawing.

In this case, the second stops 12 and 18 are used as the holding positions in advance by the solenoids 13 'and 20, respectively.

Therefore, the objective lens 2 and the first reflecting mirror 3 have the second junction element 9 of the objective lens 2 such that the objective lens 2 occupies the position of the first reduced magnification a 'of FIG. It moves along the straight line C of FIG. 4 until the contact with the 2nd stop 12 is carried out.

Thus, the second junction element 15 of the movable block 7 is in contact with the second stop 18, whereby the first reflecting mirror 3 is at the position of the first reduced magnification b 'of FIG. The limit switch LS ₁ mounted on the two stops 18 is turned on to stop the drive source 21.

In this way, the objective lens 2 and the first reflecting mirror 3 can be located at the eleventh reduced magnification positions a 'and b' of FIG.

Since the cables 29 and 35 are held on the movable block 7 and the lens carriage 6 through the springs 30 and 39, respectively, the second junction elements 15 and 9 are connected to the springs 30 and 39, respectively. By pushing against the second supports 18 and 12 so that the objective lens 2 and the first reflecting mirror 3 are accurately positioned at the first reduced magnification position.

Next, the objective lens 2 and the first reflecting mirrors 3 are positioned with the second lodged magnification in FIG. 1 moved to (a "and b") in the following manner.

If the drive source 21 is reversed so that the output shaft 22 can rotate in the opposite direction, the cables 35 and 29 are moved in opposite directions to the arrows A and B, respectively, so that the lens carriage 6 and the moving block ( 7) moves to the left side of the drawing, and the second junction elements 9 and 15 move away from the second stop bodies 12 and 18, respectively. The opposite rotation causes the first junction element 8 of the lens carriage 6 to contact the first politics 11. Thereafter, the cable 35 and the driving pulley 33 slide with each other, causing only the movable block 7 to move until the first junction element 14 contacts the first stop 17, and accordingly The limit switch LS ₂ mounted on the first stop 17 is turned on to stop the drive source 21. The objective lens 2 and the first reflecting mirror 3 are then located at the same magnification positions a and b in FIG.

In this state, if the second stop bodies 12 and 18 are moved to the non retaining position by the solenoids 13 'and 20, respectively, and the drive source 21 is activated so that the output shaft 22 is rotated. First, only the lens carriage 6 moves to the (a '") position, and then both the lens carriage 6 and the moving block 7 move along the straight line C in FIG.

As a result, the third bonding element 10 of the lens carriage 6 is in contact with the third stop 13, whereby the objective lens 2 is positioned at the second reduced magnification position a "in FIG. 1. At the same time, the third junction element 16 of the movable block 7 contacts the third stop 19, whereby the first reflecting mirror 3 is in the second reduced magnification position b in FIG. 1. Limit switch LS ₃ , which is located at ""

In the above-described embodiment, the cutout portion 41 is formed in the timing pulley 27 while the protrusion 40 is formed in the drive shaft 26. However, this structure is not limited and can be replaced by a time delay transmission mechanism in which the drive shaft 26 is rotated after a certain time from the time when the output shaft 22 of the drive source 21 starts to rotate.

Junction elements 8, 9, 10, 14, 15, 16 and stops 11, 12, 13, 17, 18, 19 may be omitted, i.e. limit switches LS ₁ , LS ₂ and LS ₃ ) May be provided, and the driving source 21 stops the operation in the on state of the switch.

Therefore, when moving from the primary reduction position to the secondary reduction magnification position, the objective lens 2 and the first reflecting mirror 3 can be slightly returned to the left side, and the second paper body 12 can be returned to the non-holding position. After moving and 18) they can be moved back to the right along straight line C.

In the present invention described above, the objective lens 2 and the first reflecting mirror 3 can be moved to three magnification positions with only one driving source 21.

FIG. 7A shows the position of the timing pulley 24, the drive shaft 26, the protrusions and the cutouts 41 at the origin (0, 0), and FIG. 7B shows the position at the initial position (0, a '"). The position of the instrument.

Claims (1)

In a magnification converting apparatus for converting a magnification by moving an objective lens 2 and a first reflecting mirror 3, the objective lens 2 and the first reflecting mirror 3 are connected to the same driving source 21. (2) and the first reflector 3 are moved at a predetermined speed ratio, and a time delay drive shaft 26 is provided between the drive source 21 and the objective lens 2 and the first reflector 3. Magnification converter of copier to do.