JPH0470218B2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to a device for conveying a strip of paper.

Generally, for example, in the process of manufacturing steel plates,
When these steel plates are stacked, a predetermined piece of paper is inserted between these steel plates. This paper is usually used in the form of a long strip wound into a roll. Conventionally, a device as shown in FIG. 1 has been used to feed the required amount of paper from such rolls. That is, 1 in the figure is a paper roll,
The paper 4 pulled out from the paper roll 1 is guided by a plurality of guide rollers 3 and wound onto a take-up roll 2. Then, this paper 4 was rewound from the paper roll 1 by the required amount and used.

However, with something like this, the pulled paper 4
If the paper 4 is cut, or if the paper 4 is cut in the middle, the paper 4 will droop as shown in Figure 2, and in order to recover, the paper 4 must be guided by the guide roller 3 again and wound up. It was necessary to wrap it around roll 2. For this reason, in this conventional device, the work of taking out the paper 4 was troublesome and inefficient.

To solve this problem, press the paper between a pair of rollers and rotate these rollers.
It is conceivable that the paper is pulled out by the frictional force between these rollers and the paper. However, in this case, when the paper is fed by these rollers, the paper may be skewed or wrinkled, and the paper may be torn, resulting in problems with low reliability.

The present invention has been made based on the above-mentioned circumstances, and its object is to provide a paper conveying device that can easily and efficiently pull out a strip of paper from a roll wound thereon.

That is, the present invention provides a guide body provided along the conveyance direction of a strip of paper and having a smooth conveyance guide surface;
an air supply mechanism that blows out air along the conveyance guide surface between the paper guided along the conveyance guide surface of the guide body and the conveyance guide surface; and an air supply mechanism that blows air along the conveyance guide surface of the paper, and and a drive roller that comes into contact with the surface of the paper and feeds the paper by rotation. Therefore, the air ejected between the conveyance guide surface of the guide body and the paper causes the paper to float from the conveyance guide surface, and the viscosity of this air causes the paper to move in the conveyance direction. A thrust is applied, and the paper is conveyed along this conveyance guide surface. Further, the paper is pressed against the drive roller by the pressure of this air, and the paper is conveyed by both the frictional force of the drive roller and the viscosity of the air. Therefore, the force acts on the paper in a distributed manner, and since the paper is pressed against the drive roller by air pressure, the paper will not be skewed or wrinkled. Further, since the paper floats up from the conveyance guide surface of the guide body by air, there is no frictional force between the paper and the guide body, and the paper can be fed reliably. Further, this paper does not require a take-up roll, and since the paper is conveyed while being guided along the conveyance guide surface, a guide roller or the like is not necessary.
Therefore, by simply inserting the leading edge of paper pulled out from a paper roll into this device, the paper can be fed freely and stopped, and even if the pulled paper is cut midway, there is no need to set the paper again. This makes paper supply work easier and more efficient.

An embodiment of the present invention will be described below with reference to FIGS. 2 and 4. Reference numeral 11 in the figure is a guide body, such as a guide wall, and the upper surface of this guide wall 11 is finished to be smooth and forms a conveyance guide surface. Side walls 14 are formed on both sides of this guide wall 11. Further, a cover wall 12 is formed above the guide wall 11 with a predetermined gap formed between the upper surface of the guide wall and the cover wall 12 . Furthermore, this guide wall 1
1 and the tip of the cover wall 12 are curved downward to form an outlet 13 for paper 30 . A strip of paper 30 pulled out from a paper roll (not shown) is inserted between the guide wall 11 and the cover wall 12, and is conveyed toward the tip end, that is, the delivery port 13 side. Further, an air supply mechanism 15 is provided on the proximal side of the guide wall 11.
The air supply mechanism 15 includes a duct 16 and a blower 17 built in the duct 16. Further, on the upper surface of the guide wall 11, there is a slit-shaped nozzle 1 which is opened along the conveyance guide surface of the guide wall 11 and is oriented in the conveyance direction of the paper 30.
8 is formed, and this nozzle 18 is connected to the duct 1 described above.
It communicates with 6. And the above blower 17
The air pumped by the nozzle 18 is ejected from the nozzle 18 into the space between the conveyance guide surface of the guide wall 11 and the paper 30 in the direction in which the paper 30 is fed. Therefore, the paper 30 floats up from the conveyance guide surface of the guide wall 11 due to the ejected air. Further, due to the viscous resistance of the air flowing between the paper 30 and the conveyance guide surface, the paper 30 receives thrust in the feeding direction and is guided along the conveyance guide surface. Also, this guide wall 1
A drive roller 19 is provided above the roller 1 .
The drive roller 19 is spaced apart from the conveyance guide surface of the guide wall 11 by a predetermined distance and is located downstream of the nozzle 18 described above. This driving roller 19 is connected to the upper surface of the paper 30, that is, the guide wall 1
It is configured to come into contact with a surface opposite to the conveyance guide surface of No. 1. The drive roller 19 is rotatably supported by a pair of bearings 20, and is connected to a motor 22 via a handle 21, and is configured to be rotationally driven by the motor 22. Then, this paper 30 is passed through the nozzle 1
The drive roller 19 is pressed by the pressure of the air ejected from the drive roller 8, and is driven in the feeding direction by the frictional force between the drive roller 18 and the drive roller 18.

In one embodiment of the present invention configured as described above, the leading end of the paper 30 pulled out from a paper roll (not shown) is passed between the guide wall 11 and the drive roller 19 and the guide wall 11 and the cover wall 12 are connected to each other. Insert between.
Then, the blower 17 is activated to send air from the nozzle 18 between the conveyance guide surface on the upper surface of the guide wall 11 and the paper 30. Therefore, the paper 30 rises from the conveyance guide surface due to the pressure of the air and is pressed against the drive roller 19. and,
When the drive roller 19 is guided, the paper 30 moves in the right direction in the figure, that is, in the feeding direction, due to the frictional force between the drive roller 19 and the viscous resistance of the air flowing between the paper 30 and the conveyance guide surface. transported to. The paper 30 is drawn to the conveyance guide surface by the air flow flowing between the paper 30 and the conveyance guide surface, and is stored at a position a predetermined distance away from the conveyance guide surface. You will be guided along the route. Then, when the rotation of the drive roller 19 is stopped, the conveyance of the paper 30 is stopped. In this case, the paper 30 is subjected to a thrust by the air flowing between the paper 30 and the guide wall 11, but the paper 30 is stopped by the frictional force between it and the stopped drive roller 19. maintained in condition.

Note that the present invention is not limited to the above embodiment. For example, the number of drive rollers is not limited to one, and a plurality of drive rollers may be provided.

Furthermore, if the conveyance guide surface is long, air may be blown out between the conveyance guide surface and the paper from the middle of the conveyance guide surface.

As described above, the present invention provides a guide body provided along the conveyance direction of a strip of paper and having a smooth conveyance guide surface, the paper guided along the conveyance guide surface of this guide body, and this conveyance guide surface. The apparatus is equipped with an air supply mechanism that blows out air along the conveyance guide surface between the two, and a drive roller that contacts the surface of the paper opposite to the conveyance guide surface and rotates to feed the paper. be. Therefore, the air ejected between the conveyance guide surface of the guide body and the paper causes the paper to float from the conveyance guide surface, and the viscosity of this air causes the paper to move in the conveyance direction. A thrust force is applied, and the paper is pressed against the drive roller by the pressure of this air, and the paper is conveyed by both the frictional force of the drive roller and the viscosity of the air. Therefore, the force acts on the paper in a distributed manner, and since the paper is pressed against the drive roller by air pressure, the paper will not be skewed or wrinkled. Further, since the paper floats up from the conveyance guide surface of the guide body by air, there is no frictional force between the paper and the guide body, and the paper can be fed reliably. In addition, since the paper is guided along the conveyance guide surface by the flow of air flowing between the paper and the conveyance guide surface, there is no need for paper guide rollers, etc.
The structure becomes simple. In addition, this device does not require a take-up roll, and simply inserting the leading end of the paper pulled out from the paper roll into this device allows the paper to be fed freely and stopped, and the pulled paper can be cut midway. However, there is no need to set the paper again, and the paper supply operation becomes easier and more efficient, which has great effects.

[Brief explanation of the drawing]

FIGS. 1 and 2 show a conventional example, with FIG. 1 being a side view of the paper being conveyed, and FIG. 2 being a side view of the paper being cut. Figures 3 and 4
The drawings show an embodiment of the present invention, in which FIG. 3 is a longitudinal sectional view and FIG. 4 is a view taken along the - arrow in FIG. 3. 11...Guide wall (guide body), 15...Air supply mechanism, 16...Duct, 17...Blower, 18...
... Nozzle, 19 ... Drive roller, 22 ... Motor, 30 ... Paper.

Claims (1)

[Claims] 1. A guide wall provided on the lower surface side of the strip-shaped paper along the conveying direction thereof, a cover wall disposed above the guide wall to form a predetermined distance from the guide wall, and this guide wall. an air supply mechanism that blows out air from the proximal end side of the guide wall in the conveying direction of the paper between the paper inserted into the space between the guide wall and the guide wall; The proximal end of this guide wall is placed above the paper and comes into contact with the upper surface of the paper which is pushed up by the pressure of the air generated from the air supply mechanism, and rotates the paper. A paper conveying device characterized by comprising a feeding drive roller.