JPH0344978B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a document conveying device used in facsimile machines and the like.

BACKGROUND OF THE INVENTION Conventionally, various means have been used to set the paper feed interval in facsimile machines and the like, including the use of control devices such as electromagnetic clutches.

A conventional document conveying device will be described below.

FIG. 3 is a side view showing the general configuration of a conventional document conveying device, in which 1 is a document, 2 is a document table on which the document 1 is placed, and 3 is a first paper feeder located upstream of the document 1 conveyance path. rollers, 4 is a first pressure roller in contact with the first paper feed roller, 5 is a second paper feed roller located on the downstream side of the conveyance path of the document 1, and 6 is a second paper feed roller.
This is a second pressure roller that is in contact with the paper feed roller 5 of the paper feed roller 5 . Note that when comparing the pressing forces of the first pressing roller 4 and the second pressing roller 6, the second pressing roller 6 is set to be larger.

The operation of the document conveying device configured as described above will be described below.

First, the document 1 passes over the document table 2 in the direction of arrow A by the first paper feed roller 3 and the first pressure roller 4, and then passes over the document table 2 by the second paper feed roller 5 and the second pressure roller on the downstream side. It is transported to between 6 and 6. Next, since the circumferential speed of the second paper feed roller 5 is set higher than the circumferential speed of the first paper feed roller 3, the leading edge of the document 1 is pressed against the second paper feed roller 5. When the document 1 is fed between the rollers 6 and 6, it is pulled by the second paper feed roller 5 and the second pressure roller 6, and the document 1 is pulled between the first paper feed roller 3 and the first pressure roller 4. It is conveyed to the downstream side of the conveyance path while sliding between. and,
The paper feeding interval with respect to the next document was set based on the difference in circumferential speed between the first paper feeding roller 3 and the second paper feeding roller 5.

Problems to be Solved by the Invention However, in the conventional configuration described above, the paper feeding interval is set by the difference in circumferential speed between the two paper feed rollers, so the document 1 is transported at the circumferential speed of the second paper feed roller 5. At this time, a load is applied to the first paper feed roller 3 and the first pressure roller 4 due to friction with the document 1,
As a result, the rotational force transmission system was adversely affected, each roller vibrated, and the paper feeding interval became unstable. To solve this problem, we used a control device such as an electromagnetic clutch to drive the paper feed roller intermittently.
Although it is possible to set the paper feeding interval, it has the drawbacks of high cost and time-consuming installation.

The present invention solves the above-mentioned conventional problems without using a control device such as the electromagnetic clutch described above, and is capable of transporting documents without imposing load on the rotation transmission system and with sufficient paper feeding intervals. The purpose is to provide equipment.

Means for Solving the Problems In order to achieve this object, the document conveyance device of the present invention includes a spring clutch that transmits the driving force of the power source to the paper feed roller only in the feeding direction, and a spring clutch that transmits the driving force of the power source to the paper feed roller only in the feeding direction. It has a drive pin that is driven by the drive force generated by the drive pin, and a driven pin that receives the drive force of the drive pin. Further, it has an auxiliary pin coaxially with the drive pin, and is configured to set the paper feeding interval based on the distance between the drive pin and the auxiliary pin.

Effect With this configuration, when a document is supported by the upstream paper feed roller and the downstream paper feed roller, the transmission of driving force to the upstream paper feed roller is cut off.
When the paper is conveyed while being supported only by the paper feed roller on the downstream side, the driving force can be transmitted again after a certain period of time.

Embodiment An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a side view showing the operating state of a document conveying device in one embodiment of the present invention, and FIG. 2 is a top view showing the internal configuration in one embodiment of the present invention. In FIGS. 1 and 2, numerals 1 and 2 are a document (however, in this embodiment, a plurality of stacked documents are shown) and a document table, respectively, as in the conventional example. Reference numeral 7 denotes an auxiliary paper feed roller that feeds out a plurality of originals 1 one by one, and a roller 8 is pressed onto the original 1 by a spring 8a. 9 is the auxiliary roller 7
The first
A reversing roller 10 is pressed onto the first paper feeding roller 9 by a spring 10a at a separating portion 11. Reference numeral 12 denotes a second paper feed roller for setting the feeding interval between the documents sequentially fed from the first paper feed roller 9, and a spring is mounted on the second paper feed roller. The pressure roller 13 is pressed by 13a.

The springs 8a, 10a, and 13a all apply appropriate pressure to the document, thereby stabilizing the conveyance of the document. Further, the friction coefficient between the outer peripheral surface of the first paper feed roller 9 and the original 1 is μ ₁ , the friction coefficient between the outer peripheral surface of the reversing roller 10 and the original 1 is μ ₂ , and the friction coefficient between the originals is μ ₃
Then, it is set to satisfy the relationship μ ₁ > μ ₂ > μ ₃ . Furthermore, the peripheral speed of the auxiliary roller 7 is V ₁ ,
If the circumferential speed of the first paper feed roller 9 is V ₂ and the circumferential speed of the second paper feed roller is V ₃ , the settings are such that V ₃ >V ₂ >V ₁ .

14 is an auxiliary roller shaft, and a driven pin 15 is attached to the tip of the coaxial shaft perpendicularly to the shaft.
Reference numeral 16 denotes a first paper feed roller shaft, and a driven pin 17 is provided at the tip thereof perpendicularly to the shaft. 18 and 1
9 is an auxiliary roller shaft 14 and a first paper feed roller shaft 16
20a and 20b are belts that transmit the driving force of the motor etc. to the pulleys 21a and 21b, and 22 and 23 are partially connected to the pulley 21.
a, 21b, and a spring clutch that rotates the boss portions 18, 19 only in the feeding direction;
4 and 25 are drive pins provided in boss portions 18 and 19 that perpendicularly intersect and contact the driven pins 15 and 17;
26 is a second paper feeding roller shaft, and 27 is an auxiliary pin for setting the paper feeding interval.

The operation of the document conveying device of this embodiment configured as described above will be described below.

First, in FIG. 2, when a motor (not shown) starts driving, the driving force of the motor is transferred to pulleys 21a, 21 via belts 20a, 20b.
b and the second paper feed roller shaft 26.
When the pulleys 21a and 21b rotate, one end of the spring clutches 22 and 23 is connected to the pulley 2, respectively.
1a and 21b, the spring clutches 22 and 23 are fixed to the boss portions 18 and 19, respectively.
Gradually tighten the spring clutch 2.
The boss portions 18 and 19 of 2 and 23 rotate together.

Next, the operation of each roller and the document 1a will be explained using FIGS. 1a to 1d. First, as shown in FIG. 1A, a loaded document 1 is set in front of the reversing roller 10. The stacked documents 1 are separated one by one as the reverse roller 10 and the auxiliary roller 7 rotate in the direction of arrow B, and are conveyed to the first paper feed roller 9. In this case, the rotational force transmitted to the boss portion 18 via the spring clutch 22 causes the auxiliary roller 7 to rotate via the auxiliary roller shaft 14 in order for the drive pin 24 provided on the boss portion 18 to push the driven pin 15. do. Similarly, the rotational force transmitted to the boss portion 19 of the first paper feed roller 9 is transmitted to the first paper feed roller via the first paper feed roller shaft 16 by the drive pin 25 pushing the driven pin 17. Roller 9 rotates. When the first paper feed roller 9 rotates in the direction of arrow C, one document 1a separated from the stacked documents 1 is sent to the downstream side of the conveyance path, resulting in a state as shown in FIG. 1B. Here, as described above, V ₁ is between the peripheral speed V ₁ of the auxiliary roller 7 and the peripheral speed V ₂ of the first paper feed roller 9.
Due to the relationship < _V2 , the document 1a is pulled by the rotational force of the first paper feed roller 9, and the auxiliary roller 7 also rotates at a circumferential speed of _V2 , so that the driven pin 15 moves in the direction of arrow B. The auxiliary roller 7 moves away from the drive pin 24 in the direction of , and becomes free to receive no driving force from any of them. Furthermore, the original 1a conveyed by the first paper feed roller 9 is transferred to the second paper feed roller 12.
Then, the second paper feed roller 12 starts conveying the document. This is shown in Figure 1c. In this state, as described above, there is a relationship of V ₂ <V ₃ between the circumferential velocity V ₂ of the first paper feed roller 9 and the circumferential velocity V ₃ of the second paper feed roller 12, and the document 1a
is pulled by the rotational force of the second paper feed roller 12,
The first paper feed roller 9 rotates at a circumferential speed of _V3 , the driven pin 17 moves away in the direction of arrow C, and the first paper feed roller 9 is in a free state in which it does not receive any driving force from any of them. Here, the driven pin 15 is the driving pin 24
The driven pin 17 reaches a position where it touches the opposite side of the auxiliary pin 27 . In the state shown in FIG. 1c, the original 1a is supported by the auxiliary roller 7, the first paper feed roller 9, and the second paper feed roller 12, and the rear end of the original 1a is supported by the first paper feed roller 12. 9, the state is as shown in FIG. 1d. That is, the document 1a is transferred to the second paper feed roller 1.
2, the auxiliary roller 7 and the first paper feed roller 9 lose the rotational force that they had been receiving from the second paper feed roller 12 via the document 1a, and come to rest. Then, the drive pins 24 and 25 to which the driving force has been transmitted are in a standby state until they come into contact with the driven pins 15 and 17 again. This drive pin 2
5 corresponds to the time (standby time) until it comes into contact with the driven pin 17, or the time corresponding to the paper feeding interval.

Therefore, since the waiting time varies depending on the distance between the drive pin 25 and the auxiliary pin 27,
By setting the distance between the original document 5 and the auxiliary pin 27 to the shortest original length, it is possible to always convey the document at a constant interval.

Effects of the Invention The present invention provides a driving pin that obtains driving force from a power source and pushes a driven pin provided on the shaft of the upstream paper feed roller as a drive force transmission means to the upstream paper feed roller. As a result, when the document is supported by the paper feed roller on the downstream side, the driving force of the paper feed roller on the upstream side is cut off, and it is possible to perform intermittent driving in which the driving force is transmitted again after a certain period of time. This has the excellent effect of being able to maintain a constant sheet feeding interval with a simple configuration without adding any load to the power source.

[Brief explanation of drawings]

FIG. 1 is a side view showing the operating state of a document conveying device according to an embodiment of the present invention, FIG. 2 is a top view showing the internal structure of the same document conveying device, and FIG. 3 is a side view showing a conventional document conveying device. It is a diagram. 9... First paper feed roller, 12... Second paper feed roller, 17... Driven pin, 25... Drive pin,
23...Spring clutch, 27...Auxiliary pin.

Claims (1)

[Scope of Claims] 1. A paper feed roller 9 that separates and transports stacked documents; a spring clutch 23 that transmits driving force generated by a power source to the paper feed roller 9 only in the feeding direction; and a paper feed roller. The drive pin 25 is rotatably held on the shaft of the paper feed roller 9 and rotates by the driving force transmitted by the spring clutch 23;
1. A document conveying device characterized by having a driven pin 17 that drives a paper feed roller 9 by being pushed by a driven pin 17. 2 Auxiliary pin 2 rotatably held on the shaft of paper feed roller 9 and rotated in conjunction with drive pin 25
7, and the sheet feeding interval is set by the interval between the drive pin 25 and the auxiliary pin 27.