JPH07108176A - Formation of corrugated plate for metal carrier honeycomb - Google Patents

Abstract

PURPOSE:To prevent the meandering of a corrugated plate by rapidly correcting the position-shifting of the plate in a forming method of corrugated plate for forming the corrugated plate by passing a flat plate between one pair of forming rollers. CONSTITUTION:A position detecting means 4d or the like to detect the position of the end part of the flat plate or the corrugated plate in the width direction and a pressing means to press at least one end part of the flat plate 10 in the width direction and to change the discharging rate of the corrugated plate 12 formed by one pair of the rollers in the width direction are provided in the vicinity of one pair of the rollers and the pressing means 25 is controlled based on the signal from the position detecting means 4d or the like. The advancing direction of the corrugated plate 12 is optionally changed as the wave height is optionally changed in the width direction by the pressure of the pressing means 25.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for forming a corrugated plate for a honeycomb body used as a metal carrier of a catalyst for purifying exhaust gas of an automobile.

[0002]

2. Description of the Related Art A honeycomb body which is a base of a metal carrier is
It is a general manufacturing method to have a structure in which foil-shaped flat plates and corrugated plates are alternately laminated, and the flat plates and corrugated plates are stacked and wound in a roll shape. Among them, the corrugated plate is, for example, as described in JP-A-63-56323,
It is formed by corrugating to form a flat plate into a wave shape by passing it between a pair of forming rollers.

However, when forming a corrugated plate, there is a problem that the plate moves in the plate width direction and meanders due to variations in the surface roughness and plate thickness of the plate. The occurrence of the meandering means that the corrugated shape of the corrugated sheet is deviated, and the accuracy of the shape of the honeycomb body becomes low. Further, if the meandering is left as it is, a part of the plate comes off the forming roller, which causes a problem of forming failure.

Therefore, as a method for preventing the meandering, a method of applying a tensile force to the flat plate before forming, a method of providing a guide member for guiding the flat plate straight to the outside of both ends of the flat plate in the plate width direction, and the like are performed. There is.

[0005]

However, the method of applying a tensile force to the flat plate is not effective when the plate thickness of the flat plate changes in the plate width direction or the slip resistance of the forming roller changes. Therefore, it becomes difficult to prevent meandering. Further, if the pulling force is increased to increase the effect of preventing meandering, the top of the corrugated sheet is cut off, resulting in foil breakage.

Even if the guide member is provided, since the flat plate is foil-like and is very easily deformed, when the flat plate is pressed by the guide member due to the meandering movement, the end portion is deformed before the course is corrected. There's a problem. The present invention has been made in view of the above circumstances, and an object thereof is to quickly correct the positional deviation of the plate and prevent the corrugated plate from meandering.

[0007]

A method of forming a corrugated sheet for a metal carrier honeycomb of the present invention which solves the above-mentioned problems is a method for forming a corrugated sheet by passing a flat plate between a pair of forming rollers. Position detecting means for detecting the position of the end of the flat plate or the corrugated plate in the plate width direction near the pair of rollers, and a corrugated plate formed by a pair of rollers pressing at least one end of the flat plate in the plate width direction. And a pressing means for varying the discharging speed in the plate width direction, and the pressing means is controlled based on a signal from the position detecting means.

[0008]

The fact that the traveling direction of the corrugated sheet changes means that the corrugated shape is different in the strip width direction. That is, if the wave height varies in the plate width direction, more flat plates are used on the higher wave height side, so that the traveling direction of the corrugated plate bends to the higher wave height side.

Therefore, in the method for forming a corrugated plate of the present invention, the position detecting means detects the position of the flat plate or the end portion of the corrugated plate in the plate width direction. When the position of the end portion exceeds the specified range, the control unit controls the pressing means, and the pressing means presses at least one end portion in the plate width direction of the flat plate to change the discharge speed of the corrugated plate. Variable in the width direction. For example, when the pressing means presses one end of the flat plate in the plate width direction in front of the forming roller, the brake force acts on the movement at that one end,
The discharge speed is slower than at the other end. Therefore, on the other end side, the wave height becomes higher due to the increase in the supply amount of the flat plate, and the traveling direction of the corrugated plate tends to bend to the other end side, so that the corrugated sheet moves to one end side. Is prevented.

Further, for example, if one end of the forming roller presses the flat plate more than the other end, the wave height of one end of the corrugated plate becomes higher than that of the other end, and thus the corrugated plate is formed. The direction of travel is trying to bend toward one end. Therefore, meandering toward the other end side is prevented.

[0011]

EXAMPLES The present invention will be specifically described below with reference to examples. (Embodiment 1) FIG. 1 shows a schematic front view of a corrugated sheet forming apparatus used in an embodiment of the present invention, and FIG. 2 shows a schematic plan view thereof.

In this molding apparatus, a reel 1 on which a flat plate 10 is wound, an upper die forming roller 20 and a lower die forming roller 2 are provided.
It is mainly composed of a pair of forming rollers 2 composed of 1 and a drive source (not shown) for rotationally driving the forming roller 2. On the reel 1, a foil-shaped flat plate 10 made of 20Cr-5Al-remaining Fe alloy and having a plate thickness of 50 μm is wound. The flat plate 10 is supplied between the pair of forming rollers 2 in a state where a tension force is applied by the tension generating unit 3.

Above the one end 11 of the flat plate 10 in the plate width direction in the vicinity of the forming roller 2, four sensors 4a to 4d, which are reflection type photoelectric switches, are spaced apart from each other.
They are arranged in the plate width direction of 0. These sensors 4a-4d
Thereby, the position of the one end 11 of the flat plate 10 can be detected. Corrugated portions are formed on the surfaces of the upper mold forming roller 20 and the lower mold forming roller 21, respectively, and the flat plate supplied by the rotational drive is corrugated to continuously form the corrugated plate 12.

The upper die forming roller 20 is rotatably fixed by a fixed shaft 22 and a movable shaft 23. Movable shaft 23
Is vertically movable, and is urged by a spring 24 in a direction away from the lower mold forming roller 21, and is rotatably held by another fixing member (not shown) on the surface opposite to the surface with which the spring 24 contacts. The cam 25 is in contact. The cam 25 is rotationally driven by a driving means (not shown) and has a function of varying the vertical position of the movable shaft 23 against the biasing force of the spring 24. That is, the forming roller 2 is
The upper mold forming roller 20 and the lower mold forming roller 2 on the movable shaft 23 side.
It is configured so that the distance between the first and the second can be changed.

The signals from the sensors 4a-4d are input to a control device (not shown), and the control device controls the driving means of the cam 25 based on the signals. In the method for forming a corrugated sheet of this embodiment using the corrugated sheet forming apparatus configured as described above, first, one end portion 11 of the flat plate 10 is positioned in the reference area A (FIG. 3) between the sensors 4b and 4c. Arrange to do.

Next, the corrugated plate 12 is continuously formed by rotationally driving the forming roller 2.
If the friction during molding changes due to variations in factors such as the surface roughness of, the presence or absence of oil adhesion, and the plate thickness, the corrugated plate 12 meanders,
Accordingly, the position of the flat plate 10 near the forming roller 2 also shifts. Here, the one end 11 of the flat plate 10 is the sensor 4a.
Suppose that the user has moved to the area B (FIG. 3) between the sensor 4b and the sensor 4b.
Then, in response to the signals from the sensors 4a to 4d, a control device (not shown) drives the cam 25 to push down the movable shaft 23 against the biasing force of the spring 24. As a result, the flat plate 10 is corrugated so that the wave height on the other end 13 side is high and the wave height on the one end 11 side is low, and the amount of flat plate used on the other end 13 side increases. Therefore, as the molding progresses, the corrugated plate 12 shifts to the other end 13 side, and the flat plate 10 returns from the region B to the reference region A.

On the contrary, when the one end 11 of the flat plate 10 moves to the area C (FIG. 3) between the sensors 4c and 4d, the cam 25 is driven so that the movable shaft 23 is at the uppermost position. Therefore, the corrugated plate 12 shifts to the one end portion 11 side, and the flat plate 10 returns from the area C to the reference area A. Therefore, according to the corrugated sheet forming method of the present embodiment, the movable shaft 23 of the upper die forming roller 20 is always driven so as to move up and down in the direction to eliminate the meandering of the corrugated sheet. It can be surely prevented. By the way, according to the present embodiment, the corrugated sheet 12 was formed at a speed of 10 m / min, but the corrugated sheet 12 did not occur and the corrugated sheet 12 could be formed normally.

The sensors 4a to 4d are not limited to the reflection type photoelectric switch, and various kinds of sensors such as a transmission type photoelectric switch and a magnetic sensor capable of position detection can be selected and used. Further, the number of sensors is not limited to four, and the greater the number, the finer the control can be performed. Therefore, from the point detection as in the present embodiment, the change in the end portion is continuously detected, and By continuously changing the operation of the cam with respect to the amount of change, it is possible to further stabilize the wave shape. (Embodiment 2) FIGS. 4 and 5 show a corrugated sheet manufacturing apparatus used in a second embodiment of the present invention. In this embodiment, the upper die forming roller 20 is fixed on both the left and right shafts, and the air that presses the one end 11 and the other end 13 of the flat plate 10 downward between the tension generating unit 3 and the forming roller 2 is used. Cylinder 5
The configuration is the same as that of the first embodiment except that 0 and 51 are provided. Then, a control device (not shown) controls the air cylinders 50 and 51 by signals from the sensors 4a to 4d.

In this embodiment using the above apparatus, for example, one end 11 of the flat plate 10 is assumed to have moved to the area B (FIG. 3) between the sensors 4a and 4b. Then, the sensors 4a-4
Upon receiving the signal of d, the control device (not shown) drives the air cylinder 50. Pads 52 are fixed to the tips of the pistons of the air cylinders 50 and 51, respectively, and the pads 52 are pressed against the surface of the flat plate 10 so that a braking force acts on the one end 11. Therefore, the supply amount on the one end 11 side decreases and the other end 13 side deeply bites into the forming roller 2, so that the corrugated plate 12 receives a bending force toward the other end 13 side, and the flat plate 10 has an area B. To the reference area A.

Conversely, when one end 11 of the flat plate 10 moves to the area C (FIG. 3) between the sensors 4c and 4d, the air cylinder 51 is driven and the braking force is applied to the other end 13 side of the flat plate 10. To work. Therefore, the corrugated plate 12 has one end 1
The flat plate 10 returns from the area C to the reference area A due to the force of bending to the 1 side. The method of the second embodiment is the same as that of the first embodiment.
However, since the flat plate 10 immediately in front of the forming roller 2 moves up and down violently, the air cylinders 50 and 51 have to be provided at positions apart from the forming roller 2. Therefore, the first embodiment is superior in terms of effective use of space. Further, when the pressing force is changed, it can be easily achieved by controlling the air supplied to the cylinder.

[0021]

That is, according to the corrugated sheet forming method of the present invention, it is possible to reliably prevent the corrugated sheet from meandering due to variations in the surface roughness and the plate thickness of the flat sheet. Therefore, the restriction on the standard of the foil material can be relaxed and the cost of the foil material can be reduced. Further, since there is no molding failure or deformation due to the guide, productivity is improved. Since the control of the meandering prevention can be automated, it is possible to further increase the production speed.

Further, since the arrangement position from the winding coil of the flat plate to the forming roller does not need the high precision as in the conventional case, the workability of the arrangement is improved and the number of steps can be reduced.

[Brief description of drawings]

FIG. 1 is a schematic front view of a corrugated sheet forming apparatus used in an embodiment of the present invention.

FIG. 2 is a schematic plan view of a corrugated sheet forming apparatus used in an embodiment of the present invention.

FIG. 3 is an enlarged explanatory view of a main part of FIG.

FIG. 4 is a schematic front view of a corrugated sheet forming apparatus used in a second embodiment of the present invention.

FIG. 5 is a schematic plan view of a corrugated sheet forming apparatus used in the second embodiment of the present invention.

[Explanation of symbols]

1: Reel 2: Forming roller 3: Tension generating unit 10: Flat plate 11: One end 12:
Corrugated plate 13: The other end 25: Cam (pressing means) 4a to 4d: Sensors (position detecting means) 50, 51: Air cylinders (pressing means)

Claims (1)

[Claims] 1. A method of forming a corrugated sheet by passing a flat sheet between a pair of forming rollers to form a corrugated sheet, wherein a position of the flat sheet or an end portion of the corrugated sheet in a sheet width direction is provided in the vicinity of the pair of rollers. The position detecting means for detecting, and the pressing means for pressing at least one end of the flat plate in the plate width direction to change the discharge speed of the corrugated plate formed by the pair of rollers in the plate width direction, A method for forming a corrugated plate for a metal carrier honeycomb, which comprises controlling the pressing means based on a signal from the position detecting means.