BACKGROUND ART In recent years, discrete paper feeders are used in facsimiles, printers, copying machines, etc. , for discretely transferring two or more sheets of manuscript or copying paper one by one. In such a discrete paper feeder, it is necessary to detect the rear end of a manuscript with a sensor and the like disposed in the device in order to detect the completion of transfer of a sheet of the manuscript. For this purpose, it is necessary that the device be able to perceive that reading of a sheet of the manuscript has been completed. It is thus necessary to put an interval between each of sheets of a manuscript that are fed in sequence.

In order to put an interval between each sheet, various configurations can be employed such as to forcibly put feeding intervals by using a reverse roller, an electromagnetic clutch or a solenoid. Especially in the type of discrete paper feeders that have been developed in a large number, manuscript intervals are produced by making a difference between the peripheral speeds of the rotation of a transfer roller and a separation roller and rotating the transfer roller at a speed 10% to 30% higher than that of the separation roller.

Fig. 14 is a perspective view of an essential part of an example of

a conventional discrete paper feeder. Conventional discrete paper feeder 61 includes separation roller 62, transfer roller 63, separation plate 64, separation roller gear 65, delay member 66, one-way clutch spring 67, transfer roller gear 68, reader 69, and butting member 69A.

A description of the action of conventional discrete paper feeder 61 as configured above will be given in reference to the illustration.

Separation roller gear 65 and rotation shaft 62A transmit the power of a drive motor (not shown) to separation roller 62. Separation roller 62 is rotated by this power and transfers manuscript 80 toward reader 69 and transfer roller 63. During this process, manuscript 80 is discretely fed one by one by separation plate 64 that is disposed in a manner pressed to separation roller 62.

Transfer roller gear 68 and rotation shaft 63B transmit the power of a drive motor (not shown) to transfer roller 63. Transfer roller 63 is rotated by this power. Here, the device is so structured that transfer roller 63 is rotated at a peripheral speed that is 10% to 30% higher than that of separation roller 62. Such a structure is realized by selecting gear ratios of two or more transmission gears (not shown) that transmit the power of the drive motor. This difference in the peripheral speeds generates a time difference between the time when manuscript 80 is bitten and transferred by transfer roller 63 and the time when next sheet of manuscript is bitten by separation roller 62 and transferred to and bitten by transfer roller 63. This time difference creates an interval between two consecutively transferred manuscript sheets.

One-way clutch spring 67 is provided in the part where rotation shaft 62A of separation roller 62 and separation roller gear 65 are coupled for absorbing the peripheral speed difference between separation roller 62 and transfer roller 63. Furthermore, delay member 66 is

provided in the part where rotation shaft 62A of separation roller 62 and separation roller gear 65 are coupled. That is, rotation shaft 62A and separation roller gear 65 are coupled with a play. Because of this structure, the timing of biting a manuscript by separation roller 63 is delayed thus causing a further increase in the interval of manuscript sheets.

In such discrete paper feeder 61, a single transfer roller 63 is disposed, and reader 69 is disposed between separation roller 62 and transfer roller 63. This is for the sake of reduction in size and manufacturing cost. With this structure, before manuscript 80 that is bitten by separation roller 62 and transferred is bitten by transfer roller 63, reading of manuscript 80 by reader 69 is started. When manuscript 80 is bitten by transfer roller 63, manuscript 80 is transferred from that position at the peripheral speed of transfer roller 63. Consequently, the transfer speed of manuscript 80 changes due to a difference between the peripheral speeds of separation roller 62 and transfer roller 63.

Accordingly, distortion and elongation of the image read from manuscript 80 by reader 69 is caused at the position where the transfer speed changes. In order to cope with this situation, in discrete paper feeder 61, the peripheral speed difference between separation roller 62 and transfer roller 63 is made to be as small as possible to minimize the distortion and elongation of read images so that they will not be prominent. Furthermore, with a view to minimizing the distortion and elongation of the read images due to peripheral speed difference between separation roller 62 and transfer roller 63, transfer roller 63 is disposed as close to reader 69 as possible in a manner pressed against butting member 69A.

Also, another example of a conventional discrete paper feeder as

disclosed in Japanese Patent Laid-Open Application No. H6-263273 includes a sun gear, a planetary arm and a planetary gear, a planetary gear shaft, and a pressing spring. The device also includes a fixed-disc cam mechanism for absorbing pressing force of the pressing spring via the planetary gear and at the same time allowing rotation and revolution of the planetary gear.

However, the conventional discrete paper feeders as described above suffer from the following problems.

(1) Even when transfer roller 63 is disposed close to reader 69 as described above, distortion and elongation of read images occur at the front end of manuscript 80, making the transmitted manuscript hard to read or spoiling the appearance.

(2) There is a limit in setting the peripheral speed difference as an enough interval between manuscript sheets cannot be obtained when the peripheral speed difference is made too small. If an enough manuscript interval is to be obtained, occurrence of distortion and elongation of the read image of a manuscript is unavoidable.

(3) If the reader is of high performance, it is possible to read a manuscript at a high speed by increasing the speed of transfer. Here, the peripheral speed difference has to be small as entry of a manuscript under transfer roller 63 cannot be smoothly performed. However, when the peripheral speed difference is made too small, a predetermined manuscript interval cannot be obtained.

DISCLOSURE OF THE INVENTION The discrete paper feeder in accordance with the present invention includes a separation roller for separating a sheet of paper from two or more sheets to be loaded and a transfer roller provided on

the side of transfer of the paper by the separation roller and driven to rotate with a predetermined peripheral speed difference from the separation roller. It also includes a sun gear, a ring-shaped geared section disposed coaxially with the sun gear and having an internally- toothed gear provided on the inner periphery, and a planetary gear engaging the sun gear and the internally-toothed gear supported on a planetary gear support section provided on an end portion of the rotation shaft of the separation roller. It further includes a disc member secured to the geared section and having grooves formed on the disc surface opposite the side on which the geared section is secured, and a lever member provided on the side of the disc member on which the grooves are provided in a manner slidable in the radial direction of the disc member. It still further includes a rotation stopping section for regulating rotation of the lever member in a predetermined direction and a slide pin provided on the lever member in a manner projecting and is slidable along the grooves provided on the disc member by the rotation of the disc member.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view of a discrete paper feeder in an exemplary embodiment of the present invention.

Fig. 2A is an exploded perspective view of an essential part of the discrete paper feeder of Fig. 1.

Fig. 2B is a perspective view of a disc member of Fig. 2A.

Fig. 3 is an assembled perspective view of an essential part of the discrete paper feeder of Fig. 1.

Fig. 4 is a front view of a grooved section formed on a disc member of the discrete paper feeder of Fig. 1.

Fig. 5A is an illustration of the action of the disc member and the lever member of the discrete paper feeder of Fig. 1 while standing by.

Fig. 5B is an illustration of the action of the separation roller and the transfer roller of the discrete paper feeding paper of Fig. 1 while standing by.

Fig. 5C is an illustration of the action of the sun gear and the planetary gears of the discrete paper feeder of Fig. 1 while standing by.

Fig. 6A is an illustration of the action of the disc member and the lever member of the discrete paper feeder of Fig. 1 while pre-feeding and feeding a manuscript.

Fig. 6B is an illustration of the action of the separation roller and the transport roller of the discrete paper feeder of Fig. 1 while pre- feeding and feeding a manuscript.

Fig. 6C is an illustration of the action of the sun gear and the planetary gears of the discrete paper feeder of Fig. 1 while pre-feeding and feeding a manuscript.

Fig. 7A is an illustration of the action of the disc member and the lever member of the discrete paper feeder of Fig. 1 while reading a manuscript.

Fig. 7B is an illustration of the action of the separation roller and the transfer roller of the discrete paper feeder of Fig. 1 while reading a manuscript.

Fig. 7C is an illustration of the action of the sun gear and the planetary gears of the discrete paper feeder of Fig. 1 while reading a manuscript.

Fig. 8 and Fig. 9 are illustrations of the action of the disc member and the lever member of the discrete paper feeder of Fig. 1 while reading a manuscript.

Fig. 10A is an illustration of the action of the disc member and the lever member of the discrete paper feeder of Fig. 1 while reading a manuscript.

Fig. 10B is an illustration of the action of the separation roller and the transfer roller of the discrete paper feeder of Fig. 1 while reading a manuscript.

Fig. 10C is an illustration of the action of the sun gear and the planetary gears of the discrete paper feeder of Fig. 1 while reading a manuscript.

Fig. llAis an illustration of the action of the disc member and the lever member of the discrete paper feeder of Fig. 1 while restarting paper-feeding.

Fig. 11B is an illustration of the action of the separation roller and the transfer roller of the discrete paper feeder of Fig. 1 while restarting paper-feeding.

Fig. 12A is an illustration of the action of the disc member and the lever member of the discrete paper feeder of Fig. 1 while transferring a long manuscript.

Fig. 12B is an illustration of the action of the sun gear and the planetary gears of the discrete paper feeder of Fig. 1 while transferring a long manuscript.

Fig. 13 is an illustration of a part of a printed paper when a slanting line is printed on a printing paper by changing the peripheral speed difference between the separation roller and the transfer roller to various values in the discrete paper feeder of Fig. 1.

Fig. 14 is a schematic perspective view of an essential part of an example of a conventional discrete paper feeder.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS Fig. 1 is a perspective view of a discrete paper feeder in an exemplary embodiment. Fig. 2A is an exploded perspective view of an essential part of the discrete paper feeder. Fig. 2B is a perspective view of a disc member of the discrete paper feeder. Fig. 3 is a perspective view of an essential part as assembled of the discrete paper feeder. Fig.

4 is a front view of a grooved section formed on a disc member of the discrete paper feeder.

In Fig. 1, discrete paper feeder 1 includes paper loading section 2A (hereinafter loading section) disposed on the rear upper surface of casing 2 having side plate 2B. Separation roller 3 is disposed at loading section 2A on the side of direction of transfer of a manuscript.

Separation plate 3Ais disposed on top of separation roller 3 in a manner touching and separates a single page from two or more pages of a manuscript. Transfer roller 4 is disposed on the side of direction of transfer of a manuscript by separation roller 3 at a predetermined distance. Reader 5 is disposed between separation roller 3 and transfer roller 4. Reader 5 comprises a CIS (contact image sensor) etc.

Auxiliary roller 6 is disposed under transfer roller 4 keeping contact with it. Pressing spring 6A presses auxiliary roller 6 to transfer roller 4. Transfer roller gear 8 is disposed on one end of rotation shaft 7 of transfer roller 4. Drive motor 9 rotates separation roller 3 and transfer roller 4 via transmission gears 11A, 11B, 13A, 13B, 13C, 13D, separation roller gear 12, and transfer roller gear 8 with a predetermined peripheral speed difference. Drive motor gear 10 is disposed on the motor shaft of drive motor 9.

Transmission gears 11A, 11B transmit rotation of drive motor gear 10 to separation roller gear 12. Separation roller gear 12 engages

transmission gear 11B. Transmission gears 13A, 13B, 13C, 13D are disposed on side plate 2B in a manner engaging with each other and transmit rotation of separation roller gear 12 to transfer roller gear 8.

Disc member 14 is disposed on one end of the rotation shaft of separation roller 3 together with separation roller gear 12. Lever member 15 is provided so as to be accompanied with disc section 14.

In Fig. 2A, Fig. 2B and Fig. 3, disc section 21A is secured to one end of rotation shaft 21 of separation roller 3. Planetary gear support sections 22A, 22B are disposed in a manner vertically symmetrical relative to the center of disc section 21A, that is, the axis of the rotation shaft of separation roller 3. Planetary gears 23A, 23B are supported by planetary gear support sections 22A, 22B, respectively. Geared section 24 is secured to the side of disc member 14 that faces separation roller 3.

Internally-toothed gear 25 is formed on the inner periphery of geared section 24. Insertion hole 26 is bored in the center of disc member 14.

Grooved section 27 is formed on the side of disc member 14 opposite geared section 24. Cylindrical shaft section 28 having insertion hole 26 in it is disposed in a manner projecting from the side of grooved section 27 of disc member 14.

Annular section 29 of lever member 15 is fit to shaft section 28.

Insertion hole 30 of annular section 29 has a play in a predetermined direction and is formed in a roughly elliptical shape. Slide pin 31 is provided on annular section 29 of lever member 15 in a manner projecting and is inserted into grooved section 27 and slides. Rotation stopping section 32 is secured to the periphery of annular section 29 and engages engagement member 51 illustrated in later described Fig. 5A.

Slide groove 33 is formed on rotation stopping section 32. Pressing member 35 is pressed to the periphery of disc member 14. Slide

member 35A is an integral part of pressing member 35. It fits slide groove 33 and slides.

Resilient member support section 34 is disposed on the tip of rotation stopping section 32. One end of resilient member 36 is secured to pressing member 35 and the other end is supported by resilient member support section 34. Resilient member 36 presses pressing member 35 to the periphery of disc member 14. Resilient member 36 is a coil spring, for example. Sun gear 37 integrally formed with separation roller gear 12 is inserted via insertion hole 26 and disposed inside internally-toothed gear 25 while engaging planetary gears 23A, 23B.

Insertion hole 37A is formed in the centers of separation roller gear 12 and sun gear 37. Speed reduction mechanism 40 consists of sun gear 37, planetary gears 23A, 23B and internally-toothed gear 25.

Shaft 38 is inserted into insertion hole 37A and insertion hole 26, and rotatably supports separation roller gear 12, sun gear 37 and disc member 14. Shaft securing hole 39 is formed on rotation shaft 21, one end of shaft 38 is inserted and secured thereinto.

In Fig. 4, engagement grooves (hereinafter grooves) 41A, 41B, 41C are provided in a manner symmetrical with respect to the center of disc member 14. Engagement sections 42A, 42B, 42C are disposed in respective engagement grooves 41A, 41B, 41C. Sliding grooves for peripheral speed difference (hereinafter grooves) 43A, 43B, 43C are provided in series with grooves 41A, 41B, 41C respectively at the side of the periphery of disc member 14 and along the periphery of disc member 14. Sliding grooves for manuscript interval (hereinafter grooves) 44A, 44B, 44C are provided in a manner extending from respective grooves 43A, 43B, 43C on disc member 14 in the clockwise direction. Here,

grooves 41A, 41B, 41C, grooves 43A, 43B, 43C, and grooves 44A, 44B, 44C are provided on disc member 14 at even intervals in a manner symmetrical with respect to the center of disc member 14. Grooves 41A, 41B, 41C and engagement sections 42A, 42B, 43C are respectively provided at an interval angle of 120 degrees with each other. Also, grooves 44A, 44B, 44C are extending in the clockwise direction on disc member 14 and are respectively connected to grooves 41B, 41C, 41A.

Drive power control section comprises speed reduction mechanism 40, disc member 14, lever member 15 that includes rotation stopping section 32, and slide pin 31.

Referring to drawings, a description will now be given on the action of the discrete paper feeder in this exemplary embodiment as configured above. The description will be given on the action of discrete paper feeder 1 for each of the following states: (1) Standing by: the state before feeding a manuscript in which drive motor stops.

(2) Pre-feeding and feeding a manuscript: the state in which the drive motor is driven, a manuscript page is bitten by the separation roller until it is bitten by the transfer roller.

(3) Reading a manuscript: the state in which a manuscript page is being bitten by both the separation roller and the transfer roller.

(4) Reading a manuscript (after leaving the separation roller): the state in which a manuscript page leaves the separation roller and is bitten by the transfer roller.

(5) Restarting paper-feeding: the state in which a manuscript page is transferred and leaves the transfer roller.

(1) Standing by: Fig. 5A illustrates the action of disc member 14 and lever member 15. Fig. 5B illustrates the action of separation roller 3 and transfer roller 4. Fig. 5C illustrates the action of sun gear 37, internally-toothed gear 25, and planetary gears 23A, 23B in speed reduction mechanism 40.

Here, Fig. 5A to Fig. 5C are schematic side views of the discrete paper feeder as viewed from the left side of the device.

Engagement member 51 located on side plate 2B of casing 2 is secured at a position at which rotation stopping section 32 of lever member 15 can come into contact. Rotation of lever member 15 in a predetermined direction (counterclockwise rotation) is regulated by striking of rotation stopping section 32 against engagement member 51.

As shown in Fig. 5A, lever member 15 consists of annular section 29 and rotation stopping section 32. Annular section 29 is formed into a roughly elliptical shape. Insertion hole 30 inside annular section 29 has play on the side of rotation stopping section 32 and on the opposite side. Annular section 29 is fit to shaft 28 of disc member 14. Also, rotation stopping section 32 touches and engages engagement member 51 provided in the counterclockwise direction. This allows lever member 15 slidable along the radial direction of disc member 14. Also, slide member 35A of pressing member 35 is fit in a manner slidable in the slide groove of rotation stopping section 32, and pressing member 35 is disposed on the side of disc member 14 in a manner slidable.

Furthermore, resilient member 36 is disposed in resilient member support section 34 of rotation stopping section 32 and resilient member 36 presses pressing member 35 to the periphery of disc member 14.

With this arrangement, lever member 15 is constantly urged in the radially outward direction of disc member 14 as shown by the arrow.

While standing by, slide pin 31 of rotation stopping section 32 is disposed on groove 41B of disc member 14. Also, slide pin 31 is urged outwardly of disc member 14 together with lever member 15 and engages engagement section 42B. Furthermore, rotation stopping section 32 engages engagement member 51. With this arrangement, even when a counterclockwise rotational force is applied to disc member 14, disc member 14 will not rotate.

Also, while standing by, drive motor 9 is not in motion and separation roller 3, transfer roller 4, and speed reduction mechanism 40 are at a standstill as illustrated in Fig. 5B, Fig. 5C.

(2) Pre-feeding and feeding a manuscripts: Fig. 6A is an illustration of the action of disc member 14 and lever member 15. Fig. 6B is an illustration of the action of separation roller 3 and transfer roller 4. Fig. 6C is an illustration of the action of sun gear 37, internally-toothed gear 25, and planetary gears 23A, 23B in speed reduction mechanism 40.

As shown in Fig. 6A, slide pin 31 provided on lever member 15 is in groove 41B of disc member 14 and is in touch with engagement section 42B. Also, as rotation stopping section 32 of lever member 15 is engaged with engagement member 51, disc member 14 will not rotate even when a counterclockwise rotational force is applied to disc member 14 as shown by the arrow.

When drive motor 9 is driven at a standby state illustrated in Fig.

5A to Fig. 5C, separation roller gear 12 is rotated via transmission gears 11A, 11B. When separation roller gear 12 is rotated, sun gear 37 secured to separation roller gear 12 is rotated, and each of planetary gears 23A, 23B that engage sun gear 37 from the top and bottom is

rotated. And, as planetary gears 23A, 23B are in engagement with internally-toothed gear 25, a rotational force is applied to geared section 24 in the direction of the arrow. However, as counterclockwise rotation of disc member 14 that is integral with geared section 24 is braked by slide pin 31, each of planetary gears 23A, 23B moves around sun gear 37 while it rotates on its own axis. With this, rotation shaft 21 of separation roller 3 is rotated via planetary gear support sections 22A, 22B thus rotating separation roller 3.

Initially, as separation plate 3A is in direct contact with separation roller 3, the anti-rotation resistance of separation roller 3 is large. However, when manuscript 55 comes between them, the anti- rotation resistance of separation roller 3 is reduced by some extent. By the rotation of separation roller 3, manuscript 55 is transferred toward reader 5 and transfer roller 4 as illustrated in Fig. 6B.

In the meantime, speed reduction mechanism 40 is set up in a manner that, for each turn of separation roller gear 12 secured to sun gear 37, separation roller 3 rotates by about 1/4 turn. To be more specific, the diameter and number of teeth of sun gear 37, planetary gears 23A, 23B, and internally-toothed gear 25 are chosen to provide the above reduction ratio.

Also, by the rotation of separation roller gear 12, transfer roller gear 8 is rotated via transmission gears 13A to 13D, and transfer roller 4 and auxiliary roller 6 which is in contact with transfer roller 4 are rotated via rotation shaft 7.

(3) Reading a manuscript: Fig. 7A, Fig. 8 and Fig. 9 illustrate the action of disc member 14 and lever member 15. Fig. 7B illustrates the action of separation roller

3 and transfer roller 4. Fig. 7C illustrates the action of sun gear 37, internally-toothed gear 25 and planetary gears 23A, 23B in speed reduction mechanism 40.

From the state of pre-feeding and feeding a manuscript as shown in Fig. 6A to Fig. 6C, manuscript 55 is further transferred toward reader 5 by separation roller 3. Then, as shown in Fig. 7B, reading of manuscript 55 is started by reader 5 and manuscript 55 is further transferred to transfer roller 4 and is bitten by transfer roller 4. Here, for separation roller 3 and transfer roller 4, a predetermined peripheral speed difference is set. As the peripheral speed of transfer roller 4 is higher than that of separation roller 3, manuscript 55 bitten by separation roller 3 is pulled to transfer roller 4 little by little. By being pulled by manuscript 55, the rotational speed of separation roller 3 becomes faster by the amount of the peripheral speed difference. As a result, the amount of this extra rotation is transmitted from separation roller 3 via rotation shaft 21, planetary gear support sections 22A, 22B, planetary gears 23A, 23B, and internally-toothed gear 25 as a force to cause clockwise rotation. By this, geared section 24 makes clockwise rotation little by little as shown by the arrow in Fig. 7C. That is, the peripheral speed difference between separation roller 3 and transfer roller 4 is absorbed.

When geared section 24 makes clockwise rotation, disc member 14 secured to geared section 24 likewise makes clockwise rotation as shown in Fig. 7A. At that time, slide pin 31 is disengaged from engagement section 42B, lever member 15 moves away from disc member 14 by the force of resilient member 36, and slide pin 31 moves toward groove 43B.

When disc member 14 makes clockwise rotation, some force for clockwise rotation is exerted to lever member 15 due to a small friction

between pressing member 35 and disc member 14. However, by the own weights of rotation stopping section 32 that is integral with lever member 15 and resilient member support section 34, lever member 15 will not rotate following disc member 14 and always remains in touch with engagement member 51. In the event of insufficient own weight, an appropriate weight may be disposed on lever member 15. By this, as only disc member 14 makes clockwise rotation, slide pin 31 of lever member 15 is disengaged from engagement section 42B.

When geared section 24 and disc member 14 make more clockwise rotation, slide pin 31 moves from groove 41B of disc member 14 to groove 43B on the outer side as illustrated in Fig. 8. When disc member 14 makes still more clockwise rotation, slide pin 31 moves along groove 43B until it reaches the innermost part of groove 43B as illustrated in Fig. 9.

Namely, slide pin 31 moves counterclockwise relative to disc member 14 along groove 43B. The length of groove 43B is set in a manner such that slide pin 31 can move to the innermost part as shown in Fig. 9, even when the length of manuscript 55 in the direction of transfer is 356 mm, i. e. , legal size document length which is long among generally encountered manuscript sizes.

(4) Reading a manuscript (after leaving the separation roller): Fig. 10A illustrates the action of disc member 14 and lever member 15. Fig. 10B illustrates the action of separation roller 3 and transfer roller 4. Fig. 10C illustrates the action of sun gear 37, internally-toothed gear 25, and planetary gears 23A, 23B in speed reduction mechanism 40.

As shown in Fig. 9, slide pin 31 moves along groove 43B until it reaches the innermost part of groove 43B. After manuscript 55 leaves

separation roller 3, manuscript 55 is bitten by transfer roller 4 only as shown in Fig. 10B and is further transferred by transfer roller 4 in the direction of transfer.

When manuscript 55 leaves separation roller 3, separation plate 3A comes into direct contact with separation roller 3 thus increasing resistance against rotation and stopping the rotation of separation roller 3. When the rotation of separation roller 3 stops, the rotation of planetary gear support sections 22A, 22B is stopped. Then, the rotation of sun gear 37 is strongly transmitted to internally-toothed gear 25 via planetary gears 23A, 23B as shown in Fig. 10C. With this, both geared section 24 and disc member 14 rotate in the counterclockwise direction.

When manuscript 55 leaves separation roller 3 and disc member 14 makes counterclockwise rotation, slide pin 31 moves from the innermost part shown in Fig. 9 along groove 43B. It further moves along groove 44B as shown in Fig. 10A. During this period, the transmission of driving force to separation roller 3 is interrupted.

In this way, during the period when slide pin 31 is moving along groove 44B from the innermost part of groove 43B, separation roller 3 is at a standstill. Accordingly, next page of manuscript is not fed. This creates predetermined intervals between sequentially fed pages of manuscript 55. The lengths of groove 43B and groove 44B determine the manuscript interval.

(5) Restarting paper-feeding: Fig. 11A illustrates the action of disc member 14 and lever member 15. Fig. 11B illustrates the action of separation roller 3 and transfer roller 4.

As shown in Fig. 10A, slide pin 31 moves along groove 44B until it

reaches the front end of groove 44B. Then slide pin 31 is moved by the urging force of resilient member 36 to groove 41C in the outward direction of disc member 14 and engages engagement section 42C as shown in Fig. 11A. Also, rotation stopping section 32 of lever member 15 engages engagement member 51. By this, counterclockwise rotation of disc member 14 is stopped.

Subsequently, feeding of next page of manuscript 55 is performed in the same action as in" (2) Pre-feeding and feeding a manuscript." During the period drive motor 9 is in operation, the above-described cycle of" (2) Pre-feeding and feeding a manuscript", then" (3) Reading a manuscript", then" (4) Reading a manuscript (after leaving separation roller) ", then" (5) Resuming paper feeding", then" (2) Pre-feeding and feeding a manuscript"is repeated. And paper feeding is performed with predetermined intervals between pages of manuscript 55 that are fed as shown in Fig. 11B. Such a repetitive action is enabled as grooved section 27 and engagement sections 42A, 42B, 42C are arranged in a manner symmetric with respect to a point.

In the event the length in the direction of transfer of manuscript 55 is longer than the general length of 356 mm, even when slide pin 30 moves to the innermost part shown in Fig. 9, manuscript 55 does not leave separation roller 3 and remains bitten by separation roller 3. A description of this case is given below.

Fig. 12A illustrates the action of disc member 14 and lever member 15. Fig. 12B illustrates the action of sun gear 37, internally- toothed gear 25, and planetary gears 23A, 23B in speed reduction mechanism 40.

Manuscript 55 bitten by separation roller 3 is pulled little by little toward transfer roller 4 due to the peripheral speed difference

between separation roller 3 and transfer roller 4, and separation roller 3 makes extra rotation corresponding to the peripheral speed difference.

As shown in Fig. 12B, the amount of extra rotation is transmitted from separation roller 3 via rotation shaft 21, planetary gear support sections 22A, 22B, planetary gears 23A, 23B, and internally-toothed gear 25 thus causing geared section 24 to further rotate in the clockwise direction.

When disc member 14 that is integral with geared section 24 further rotates in the clockwise direction with sliding pin 31 at the innermost part of groove 43B as shown in Fig. 9, lever member 15 rotates in association with the rotation of disc member 14 as shown in Fig. 12A.

Accordingly, even when the length in the direction of transfer of manuscript 55 is greater than 356 mm, separation roller 3 rotates following the rotation of lever member 15. Disc member 14 also rotates without disturbing the rotation of separation roller 3. Consequently, even a long manuscript can be transferred.

Meanwhile, in this exemplary embodiment, each triplet of grooves 41A, 41B, 41C, grooves 43A, 43B, 43C, and grooves 44A, 44B, 44C is disposed at even intervals in a manner symmetric with respect to the center of disc member 14. The number of sets of grooves is not limited to three. Engagement grooves, slide grooves for peripheral speed difference, and slide grooves for manuscript interval may be disposed in pairs, in quadruplets or in larger combinations.

Next, a description will be given on the peripheral speed difference of separation roller 3 and transfer roller 4. Fig. 13 is an illustration of a part of recording paper 56 when slanting lines 71 to 75 are printed on recording paper 56 as fed from loading section 2A while changing the peripheral speed difference of separation roller 3 and transfer roller 4.

As shown in Fig. 13, when the peripheral speed difference of separation roller 3 and transfer roller 4 is 5%, slanting line 73 is obtained, in which scarcely any distortion of the line is observed, compared with slanting line 72 with peripheral speed difference of 2.5% and slanting line 71 with peripheral speed difference of 0%. Slanting line 74 and slanting line 75 are for the cases of peripheral speed difference of 10% and 18%, respectively.

On the other hand, when the peripheral speed difference is 1% or lower, the peripheral speed difference of separation roller 3 and transfer roller 4 becomes negligible and separation roller 3 does not make extra rotation corresponding to the peripheral speed difference in the step of " (3) Reading a manuscript"as described earlier. Especially in the case where the minimum length of manuscript that is readable is fixed, there is a resk that slide pin 31 cannot move from groove 41B of disc member 14 to the side of outer groove 43B before the rear end of a manuscript leaves separation roller 3. For this reason, it is preferable that the peripheral speed difference between separation roller 3 and transfer roller 4 be set in the range 1% to 5%, more preferably, in the range 2.5% to 3.5%.

Discrete paper feeder 1 of this exemplary embodiment has reader 5. However, in the case recording paper is to be fed rather than a manuscript as in a printer, reader 5 is not necessary.

INDUSTRIAL APPLICABILITY The discrete paper feeder of the present invention shortens the distance in the direction of transfer of paper by disposing a reader between a separation roller and a transfer roller. This enables reduction in size and manufacturing cost. Also, by making peripheral

speed difference between the separation roller and the transfer roller small, distortion and elongation of recorded image of a manuscript can be prevented. Furthermore, even when the peripheral speed difference is made small, it is possible to put a predetermined interval between two or more pages of a manuscript that are transferred in sequence. That is, when a manuscript page leaves the separation roller, rotation of the separation roller stops and the rotation of a sun gear is transmitted to an internally-toothed gear by the rotation of planetary gears. This makes a disc member to rotate. The separation roller remains at a standstill until the disc member starts to rotate and comes in touch with a slide pin provided on a lever member. As a result, next manuscript page is not fed thus resulting in an increase in the interval of manuscript pages to be fed in sequence. Even when the peripheral speed difference between the separation roller and the transfer roller is made small, it is possible to put a predetermined interval between two or more pages of a manuscript that are transferred in sequence. Also, rotation of the drive motor can always be in one direction thus not requiring reversion.

Also, a pressing member is slidably disposed on the side of the disc member within a rotation stopping member of the lever member.

Furthermore, a resilient member is disposed in the rotation stopping section so that the pressing member is pressed to the periphery of the disc member by the resilient member. With this configuration, the lever member is constantly urged toward radially outer side of the disc member thus enabling free setting of the engaging position of the lever member.

Also, when transferring a manuscript that is longer than normal manuscripts, a slide pin moves to the innermost part of a slide groove for peripheral speed difference. Furthermore, as a geared section and the

disc member rotate in the clockwise direction, the lever member makes clockwise rotation apart from an engagement member. Consequently, even for a manuscript with a length greater than normal, the separation roller rotates following the manuscript. The disc member also rotates without disturbing the rotation of the separation roller. As a result, even a long manuscript can be transferred.

Also, by disposing two or more of each of the engagement groove, slide groove for peripheral speed difference and slide groove for manuscript interval, the lengths of the slide groove for peripheral speed difference and slide groove for manuscript interval of this discrete paper feeder can be set as appropriate thus providing an adequate manuscript interval.

Reference numerals in the drawings 1. Discrete paper feeder 2. Casing 2A. Paper loading section 2B. Side plate 3. Separation roller 4. Transfer roller 5. Reader 6. Auxiliary roller 6A. Pressing spring 7. Rotation shaft 8. Transfer roller gear 9. Drive motor 10. Drive motor gear 11A, 11B. Transmission gear

12. Separation roller gear 13A, 13B, 13C, 13D. Transmission gear 14. Disc member 15. Lever member 21. Rotation shaft 21A. Disc member 22A, 22B. Planetary gear support section 23A, 23B. Planetary gear 24. Geared section 25. Internally-toothed gear 26. Insertion hole 27. Grooved section 28. Shaft section 29. Annular section 30. Insertion hole 31. Slide pin 32. Rotation stopping section 33. Slide groove 34. Resilient member support section 35. Pressing member 35A. Slide member 36. Resilient member 37. Sun gear 37A. Insertion hole 38. Shaft 39. Shaft securing hole 40. Speed reduction mechanism section 41A, 41B, 41C. Engagement groove

42A, 42B, 42C. Engagement section 43A, 43B, 43C. Slide groove for peripheral speed difference 44A, 44B, 44C. Slide groove for manuscript interval 51. Engagement member 55. Manuscript 56. Recording paper 61. Conventional discrete paper feeder 62. Separation roller 63. Transfer roller 64. Separation plate 65. Separation roller gear 66. Delay member 67. One-way clutch spring 68. Transfer roller gear 69. Reader 69A. Butting member 71,72, 73,74, 75 slanting line 80. Manuscript