KR200247911Y1 - Apparatus for transmitting power of scanner - Google Patents

Abstract

The present invention relates to a power transmission device of a scanner, a drive gear for transmitting the rotational force of the motor as a drive source, gear switching means for switching the rotational force of the drive gear in accordance with the low speed mode and high speed mode, and the gear switching means Gear reduction unit for low speed mode to decelerate the rotational force transmitted by the low speed mode, gear reduction unit for the high speed mode to decelerate the rotational force transmitted by the gear switching means to the high speed mode, and for the low speed and high speed mode By including transmission gears that transmit the rotational force transmitted through the gear reduction unit to each roller gear side, the rotational force of the motor transmitted according to the forward and reverse rotation of the motor is shifted to distinguish between the low speed scan mode and the high speed scan mode. The feed rate is adjustable.

Description

Apparatus for transmitting power of scanner

The present invention is a technology related to a power transmission device of a scanner. In particular, a scanner capable of adjusting a feed speed of an original by distinguishing a low speed scan mode from a high speed scan mode by shifting the rotational force of the motor transmitted according to the forward and reverse rotation of the motor. Relates to a power transmission device.

As shown in Fig. 1, a typical scanner includes a stacker 1 on which an original P is loaded, an document feeder 2 (hereinafter referred to as an ADF) for automatically feeding the loaded original, and a document to be fed. A conveying roller 3 for conveying, a contact image sensor 4 (hereinafter referred to as CIS) for reading the conveyed document, a white roller 5 for conveying the document in close contact with the CIS 4, and a read document It is composed of a discharge roller (6) for discharging, and in front of the ADF (2) and the CIS (4) is provided with a document detection sensor (7) (8) for detecting the entry of the document, respectively.

As shown in FIG. 2, the power transmission structure of the scanner includes a drive gear 11 for transmitting the rotational force of the step motor, a first gear 12 having two stages connected to the drive gear 11, and The second gear reduction gear 13 of the second stage connected to the first gear reduction gear 12 and the rotational force transmitted from the second gear reduction gear 13 are respectively roller-side gears 2a, 3a and 5a. It consists of the 2nd stage 3rd reduction gear 14 conveyed to 6a.

Interlocking gears 15 and 16 are provided between the feed roller gear 2a, the discharge roller gear 6a, and the third reduction gear 13, respectively, and the ADF roller gear 2a is the feed roller gear 3a. The rotational force of is configured to be transmitted through the second reduction gear 17 of the second stage.

5a is a white roller gear.

In the scan operation of the scanner configured as described above, the speed of the step motor to be driven for each resolution mode is determined.

In other words, in the case of high resolution (300dpi: dot per inch) mode, it operates at a low speed of 400pps (pps: pulse per sec), and when the low resolution (100dpi or less) scan is made high speed to reduce the scan time, it is 1200pps high speed. Will be driven.

As described above, while the load of the driving mechanism is almost constant in the conventional multifunction apparatus, the motor torque at low speed and high speed has a problem that the difference is very large by 2 to 3 times.

In addition, at low speeds, driving occurs at the same frequency as the resonance region, so if the motor torque is allowed to prevent outage in the high speed mode, image defects and noise may occur due to vibration in the high resolution mode. In the low speed mode, if the proper torque is maintained to reduce the vibration, the torque is insufficient in the high speed mode, and thus there is a problem in that the step out occurs.

In particular, when the scan data is read in the 300dpi mode from the PC when the image is defective, the image may be read at 150dpi. As shown in the graph shown in FIG. 3a, the motor vibration characteristic vibrates at twice the driving step cycle. This may occur if the motor drive timing and the CIS read timing are irregular.

When two timings of the same period are met as shown in Fig. 3b, the normal reading is read at 300dpi. However, when they are met as shown in Fig. 3a, the reading is stopped at two times as the result is read at 150dpi. By appearing, the phenomenon that the image is uneven due to the change in the local resolution of the entire image occurs.

The object of the present invention devised in view of the above problems is to drive the scanner in the speed range where the motor driving conditions are optimal.

Another object of the present invention is to prevent image defects and outage due to vibration by appropriately controlling the speed difference between the high resolution mode and the high speed mode.

1 is a schematic configuration diagram of a typical scanner.

2 is a power transmission structure diagram of a scanner according to the prior art.

3 is a graph showing a relationship between a vibration period of a motor according to the related art and a read timing period of a CIS.

Figure 3a is a graph of misread 300dpi to 150dpi.

3b is a graph of 300dpi read correctly.

4 is a power transmission structure diagram of a scanner to which an embodiment of the present invention is applied.

5 is a perspective view of a guide rod applied to an embodiment of the present invention.

Figure 6a is a side view as viewed from the direction A of Figure 4 to show the power transmission state in the low speed mode during operation of an embodiment of the present invention.

6B is a side view showing a power transmission state in the high speed mode.

Fig. 7A is a graph of the relationship between the vibration period of the motor in the low speed mode and the read timing period of the CIS.

Fig. 7B is a relation graph in the high speed mode.

(Explanation of symbols for the main parts of the drawing)

21; Drive gear 22; Trance gear

23; First reduction gear 24,25; 1st, 2nd idle gear

26; Second reduction gear 30; A guide rod

31; Guide protrusion 32; Guide Rib

33,34; Balance spring

The power transmission device of the scanner for achieving the above object includes a drive gear for transmitting the rotational force of the motor as a drive source; Gear switching means for transferring the rotational force of the drive gear in accordance with a low speed mode and a high speed mode; A gear reduction unit for a low speed mode for decelerating the rotational force transmitted by the gear switching means in a low speed mode; A gear reduction unit for a high speed mode for decelerating a rotational force transmitted by the gear switching means in a high speed mode; It characterized in that it comprises a transmission gear for transmitting the rotational force transmitted through the gear reduction unit for the low speed and high speed mode to each roller gear side.

The gear switching means includes a guide rib fixed to the frame, a guide rod having a guide groove into which the guide rib is inserted, formed on an outer circumferential surface thereof, and coupled to one side of the guide rod to engage with the drive gear according to the forward and reverse rotation of the motor. The transverse gear is moved to the left and right side together with the guide rod by the rotation direction of the low speed mode gear reduction unit or the high speed mode gear reduction unit side, and the guide rod and the trans gear on both sides of the guide rod and the trans gear. It is preferable that it is comprised by the balance spring which burns to the center.

Further, the low speed mode gear reduction unit is preferably a two-stage reduction gear meshing with the trans gear.

In addition, the high speed mode gear reduction unit is preferably a first idle gear and a second idle gear meshed with the trans gear.

Hereinafter, preferred embodiments of the present invention as described above will be described in more detail based on the accompanying drawings.

4 is a perspective view of a power transmission structure of a scanner to which an embodiment of the present invention is applied, and FIG. 5 is a perspective view of a guide rod applied to an embodiment of the present invention.

6A is a side view as viewed in the direction A of FIG. 4 to show a power transmission state in a low speed mode during operation of an embodiment of the present invention, Figure 6b is a side view showing a power transmission state in a high speed mode.

As shown in the drawing, the embodiment of the present invention is configured to switch the power transmission path according to a mode selected by dividing the power transmission mechanism of the scanner into a low speed mode and a high speed mode.

That is, as shown in Figs. 4, 5 and 6A, 6B, the drive gear 21 for transmitting the rotational force of the step motor, the trans gear 22 for selectively transmitting the rotational force of the drive gear 21, and the low speed Two first gear reduction gear 23 engaged with the trans gear 22 in the mode; first idle gear 24 and the second idle gear 25 engaged with the trans gear in the high speed mode; It consists of the 1st reduction gear 23 or the 2nd reduction gear 26 connected with the 1st, 2nd idle gear 24 and 25. As shown in FIG.

The white roller gear 5a is directly connected to the second reduction gear 26, and the feed roller gear 3a and the discharge roller 6a are connected to the second reduction gear 26 by the interlocking gears 27 and 28. The ADF roller gear 2a is connected by the feed roller gear 3a and the third reduction gear 29.

The guide rod 30 having the guide groove 31 formed on the outer circumferential surface thereof is fixed to the trans gear 22, and the guide rod 30 is inserted into the guide groove 31 of the guide rod 30, thereby guiding the guide rod 30 due to the rotation of the guide rod 30. Guide ribs 32 for guiding the rods 30 to slide left and right are fixed to the frame.

Balance springs 33 and 34 are elastically supported on the other side of the trans gear 22 and one side of the guide rod 30 so that the trans gear 22 and the guide rod 30 are always at the center.

The power transmission structure configured as described above is a structure in which a path through which power is transmitted in accordance with the rotation direction of the step motor is switched. When the step motor is rotated in the forward direction, the power transmission structure 22 receives the driving force of the drive gear 21. The driving force is reduced through the first reduction gear 23 and the power is transmitted to the second reduction gear 26. When the step motor rotates in the reverse direction, the rotational force of the driving gear 21 is transmitted to the trans gear ( The driving force that is not decelerated while passing through the first and second idle gears 23 and 24 through 22 is transmitted to the second reduction gear 26 side.

The operation of the power transmission device of the inventive scanner configured as described above will be described with reference to FIGS. 6A, 6B and 7A, 7B.

First, in the low speed mode of the scanner, that is, the operation for scanning at a high resolution, when the step motor is rotated in the forward direction (clockwise), as shown in FIG. 6A, the transgear 22 engaged with the drive gear 21 is illustrated. The balance spring 34 supporting the guide rod 30 is compressed while being moved to the left side, and the balance spring 33 supporting the trans gear 22 is expanded, and the guide rod 30 is the guide groove 31. It is guided by the guide rib 32 inserted into it and moves to the left side together with the transgear 22.

When the trans gear 22 is moved to the left, it is engaged with the first reduction gear 23, and the rotational force of the drive gear 21 is transmitted to the first reduction gear 23 via the trans gear 22.

The rotational force is transmitted to the second reduction gear 26 in a state where the speed reduction is 1/2 of the size of the first reduction gear 23, and the white roller gear 5a and the feed roller are driven by the second reduction gear 26. The gear 3a and the discharge roller gear 6a are rotated, and the ADF roller gear 2a is rotated through the feed roller gear 3a.

Since the transmission path of the power passes through the first reduction gear 23, which is a two-stage reduction gear, the document is transferred at a relatively low speed, noise and vibration are reduced, and the load torque is also reduced to 1/2.

At this time, since the cycle of the motor vibration and the read timing period of the CIS coincide with each other because the vibration occurs at twice the cycle of the step motor driving cycle, as shown in FIG. 7A, the image read in any situation has a constant resolution. Image defects are prevented.

On the other hand, the scan is performed in the low resolution mode, that is, the high speed mode is the guide rod 30 when the motor is rotated in the reverse direction (counterclockwise) and as shown in FIG. ), The balance spring 34 supporting the trans gear 22 is expanded, and the balance spring 33 supporting the trans gear 22 is compressed while the guide rod 30 is guided by the guide rib 32. It is moved to the right together, and thus the rotational force of the drive gear 21 is transmitted to the first and second idle gears 24 and 25 through the trans gear 22.

Since the rotational force transmitted to the second reduction gear 26 via the first and second idle gears 24 and 25 is transmitted without deceleration, it is possible to implement a low resolution scan operation at a high speed by transferring a document at a relatively high speed. The load torque is also applied at 1/1, which makes it difficult to drive and prevents outage.

In addition, in the low resolution mode, the image quality problem does not occur in the high resolution mode.

The driving speed of the motor set in the power transmission device of the scanner operated as described above is sufficient in terms of torque, and it is explained based on the assumption that the noise and vibration characteristics are good. It is also possible to design by changing the driving speed in the time and low speed mode according to the situation.

As described above, the power transmission device of the scanner of the present invention distinguishes between the high resolution mode and the low resolution mode by switching the path for transmitting the rotational force of the motor, thereby reducing and transmitting the rotational force in the low speed mode, and the rotational force in the high speed mode. By transmitting without deceleration, it is possible to prevent noise and vibration generated in the low speed mode, and to prevent outage due to the lack of torque in the high speed mode.

Claims (3)

A drive gear for transmitting a rotational force of a motor as a drive source; Guide ribs fixed to the frame and guide grooves into which the guide ribs are inserted are formed on the outer circumferential surface thereof, and are coupled to one side of the guide rods so that the guide ribs are engaged with the drive gears according to the forward and reverse rotations of the motor, and thus, by the rotation direction of the drive gears. A balance that moves to the left and right side with the guide rod and is connected to the gear reduction portion for the low speed mode or the gear reduction portion for the high speed mode, and balances the guide rod and the trans gear toward the center on both sides of the guide rod and the trans gear. A gear switching means composed of a spring for switching and transmitting the rotational force of the drive gear according to the low speed mode and the high speed mode; A gear reduction unit for a low speed mode for decelerating the rotational force transmitted by the gear switching means in a low speed mode; A gear reduction unit for a high speed mode for decelerating a rotational force transmitted by the gear switching means in a high speed mode; And a transmission gears for transmitting the rotational force transmitted through the gear reduction unit for the low speed and the high speed mode to the respective roller gear sides. The method of claim 1, The gear reduction unit for the low speed mode is a power transmission device of the scanner, characterized in that the two-stage reduction gear meshing with the trans gear. The method of claim 1, The gear reduction unit for the high speed mode is a power transmission device of the scanner, characterized in that the first idle gear and the second idle gear meshing with the trans gear.