JPH09276657A - Method for taking up metal honeycomb member - Google Patents

Abstract

PROBLEM TO BE SOLVED: To compensate the shaft rigidity of a taking-up shaft to produce a metal honeycomb member enhanced in shape accuracy and stable in quality by supporting the central region of the taking-up shaft of a taking-up process on the taking-up outer periphery side of metal foil by three or more support rollers and taking up the metal foil while reducing taking-up load. SOLUTION: When flat metal foil 1 and corrugated metal foil 2 are superposed one upon another to be taken up to produce a metal honeycomb member, the leading end of the flat metal foil 1 supplied through a flat foil supply guide is inserted into the slit of a taking-up shaft 5 and bent by a leading end bending jig to be engaged with the taking-up shaft 5 while the leading end of the corrugated metal foil 2 supplied through a corrugated foil supply guide is held between the taking-up shaft 5 and the flat metal foil 1 and the taking-up shaft 5 is rotated by a drive device 15 through the small diameter support parts 6a, 6b of side clamps 6A, 6B and a pneumatic cylinder is controlled to support the metal foils by three or more support rollers 7a-7c to take up them. By this constitution, the generation of the breakage, twist or bending of the taking-up shaft is prevented and a honeycomb member of high quality is produced with good productivity.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shaft support structure capable of reducing a winding load on a winding shaft when a flat metal foil and a metal corrugated foil are superposed and wound in a honeycomb shape to manufacture a metal honeycomb body. The present invention relates to a method for winding a metal honeycomb body used.

[0002]

2. Description of the Related Art For example, in recent years, there has been known a catalyst device in which a purifying catalyst is arranged in an exhaust passage of an internal combustion engine such as an automobile to purify harmful components such as HC, CO and NOx in exhaust gas. In this type of catalyst device, a metal honeycomb body is used as a catalyst carrier.

This metal honeycomb body 4 is formed into a cylindrical shape as shown in FIG. 6, by stacking a flat foil 1 of a metal foil and a corrugated foil 2 as shown in FIG. Innumerable through holes 4o are formed in the axial direction. The metal honeycomb body 4 is generally used by being inserted into the casing 3.

As a winding device for the flat foil 1 and the corrugated foil 2 of the metal foil in the case of manufacturing the metal honeycomb body 4, for example, there is one disclosed in Japanese Patent Laid-Open No. 4-371234. The winding device is generally configured as shown in FIG. In FIG. 7, 5 is a winding shaft that is rotated by a driving device (not shown), and the winding shaft has a pair of side clamps 6A,
6B is mounted so that the distance between the pair of side clamps can be adjusted, and both end surfaces of the metal flat foil 1 and the metal corrugated foil 2 which are wound around the winding shaft 5 can be pressure-supported between the pair of side clamps.
The winding shaft 5 of this winding device has a slit 5o through which the tips of the flat metal foil 1 and the metal corrugated foil 2 are inserted and locked. Three winding rolls are provided outside the winding shaft. Ra, Rb, and Rc are arranged by the drive device M so as to be movable back and forth with respect to the winding shaft 5.

In this winding device, as shown in FIG. 8, the leading ends of the flat metal foil 1 and the metal corrugated foil 2 supplied from a conveying device (not shown) are inserted into the slits 5o of the winding shaft 5.
Lock, rotate the winding shaft 5, and rotate the three pressure rolls Ra.
The metal honeycomb body 4 is manufactured by winding Rb and Rc while being lightly supported by a constant load from the winding outer peripheral side of the metal foil.

However, in recent years, a metal flat foil for forming a honeycomb body, such as a carrier for a diesel cogenerator, a carrier for cutting a double carrier for the purpose of reducing the manufacturing cost by cutting one carrier into two or three, There is an increasing demand for making metal foils that become metal corrugated foils longer (100 to 500 mm).
Since the width of the flat metal foil or the corrugated metal foil becomes wider and the rigidity further increases, there is concern about the rigidity of the winding shaft when the metal flat foil or the metal corrugated foil is wound to manufacture a metal honeycomb body.

That is, in this winding device, the winding shaft 5 has a slit for superposing the metal flat foil 1 and the metal corrugated foil 2 at the start of winding and inserting and locking the leading end thereof. 5o is formed, and the diameter of the winding shaft 5 is made as small as possible (for example, 5 mm) in order to make the diameter of the shaft hole formed in the center of the metal honeycomb body 4 obtained by winding as small as possible. In many cases, bending is likely to occur.

In this winding device, a pressure-bonding roll is used to lightly support the metal foil from the winding outer peripheral side with a constant load during the winding process. The supporting load of the pressure-bonding roll touches the outer peripheral surface of the metal foil. It is a light load that does not work, and it hardly functions to reinforce the winding shaft. Therefore, when the width of the metal foil is large, the strength (rigidity) of the take-up shaft is reduced, and the take-up shaft is broken and cannot be taken up, or is twisted or bent. However, there is a problem that the shape accuracy is lowered and it becomes difficult to manufacture a metal honeycomb body with stable quality with high productivity.

[0009]

SUMMARY OF THE INVENTION According to the present invention, when a metal flat foil and a metal corrugated foil are stacked on a winding shaft to manufacture a winding metal honeycomb body, the axial rigidity of the winding shaft is supplemented. Provided is a method for winding a metal honeycomb body, which can prevent the occurrence of breakage, twisting, and bending, and can highly productively manufacture a metal honeycomb body having high shape accuracy and stable quality.

[0010]

Means for Solving the Problems The first invention of the present invention is:
A winding device for a metal honeycomb body, which includes a winding shaft for stacking and winding a metal flat foil and a metal corrugated foil, and a pair of side clamps for pressurizing and supporting the side edges of the metal flat foil and the metal corrugated foil during winding. In the winding method of a metal honeycomb body using, the central area of the winding shaft in the winding process is supported from the winding outer peripheral side of the metal foil by three or more supporting rollers, and the winding shaft is wound around the winding shaft. A method for winding a metal honeycomb body, comprising winding while reducing the load. The second invention is the same as the first invention,
The range in which the central region of the winding shaft in the winding process is supported by three or more supporting rollers via the outer periphery of the metal foil includes at least the foil width central region and is 20% of the metal foil width.
A method for winding a metal honeycomb body, which is in the above range. A third aspect of the present invention is, in the first aspect or the second aspect, when the central region of the winding shaft in the winding process is supported from the outer peripheral side of the metal foil by three or more supporting rollers, a supporting reaction force is applied. Is supported within a range of 1 to 5 kg / cm from the start of winding to a winding angle of around 360 degrees, and thereafter is supported with a supporting reaction force of 0.2 kg / cm or less. A method for winding a metal honeycomb body.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION In the present invention, in the process of winding a metal flat foil and a metal corrugated foil on a winding shaft, the central region of the winding shaft is wound by three or more supporting rollers. By supporting from the outer peripheral side of the metal foil, the axial rigidity of the take-up shaft can be supplemented in the central region of the metal foil width, and by preventing breakage and bending of the take-up shaft, the life of the take-up shaft is extended. It is possible to reduce the facility cost and stably maintain the shape accuracy of the winding core portion to improve the productivity of manufacturing a metal honeycomb body with stable quality.

In the present invention, when a thin metal flat foil and a metal corrugated foil are superposed on each other by using a winding device to manufacture a rolled metal honeycomb body, a metal flat foil is formed in the slit of the winding shaft 5. When the tip of the metal corrugated foil is inserted and the take-up shaft is rotated and taken up, the slit forming area of the take-up shaft is supported from the outer circumference side of the take-up shaft of the metal foil with three or more supporting rollers. Supplements the rigidity of.

The supporting range of the supporting roller includes at least the central region of the width of the metal foil and is 20% or more of the width of the metal foil so that it can be supported symmetrically from the center of the width of the metal foil. Is preferred. Support range is 20
If it is less than%, the support is locally supported, so that the winding shaft is displaced at the non-supporting portion, and the winding shaft is broken. When the support range is 100% or more, it interferes with the side clamps during the winding process, which causes an obstacle to the clamps, which is not preferable.

The supporting reaction force of this supporting roller is 1 to 5 until the ends of the flat metal foil and the metal corrugated foil are inserted into the slits 5o of the winding shaft 5 and the winding shaft is rotated once.
It is preferable that the pressure is set to kg / cm, and the supporting reaction force after that is set to 0.2 kg / cm or less. The supporting reaction force here is
Support load per unit length (cm) of support roller (kg)
It is.

When forming the winding core portion, it is wound with a relatively small tension. However, since the winding shaft 5 has a small diameter and has a slit in the center portion, it has a small rigidity, so that three or more supporting members are supported. Unless the supporting reaction force by the roller is set to 1 to 5 kg / cm, the rigidity of the winding shaft cannot be sufficiently compensated. If the supporting force exceeds 5 kg / cm, the winding resistance increases, the metal foil breaks, and the corrugated foil shape is impaired, which is not preferable.

Then, the tips of the metal flat foil and the metal corrugated foil are inserted into the slits of the winding shaft 5, and the winding shaft is rotated by 360 degrees (1
If the supporting reaction force after the rotation is more than 0.2 kg / cm, the metal corrugated foil is crushed and the shape accuracy of the metal honeycomb body is deteriorated, which is not preferable.

In the support roller, the winding shaft is a split shaft and the diameter is 5
~ 7mm, the diameter is 1 when the metal foil width is 100-200mm
It is preferable that 3 to 4 of 5 to 20 mm (3 to 5 times the diameter of the winding shaft) are arranged, and the distance between adjacent support rolls in contact with the winding shaft is equal to or smaller than the diameter of the winding shaft. If the diameter of the support roller is 15 mm or less, the support roller easily bends, so that a uniform support effect cannot be obtained and the effect of reinforcing the rigidity of the winding shaft is insufficient.
If the diameter of the support roller is 20 mm or more, it is not preferable because interference occurs between adjacent support rollers at a stage where the winding diameter is small and stable support cannot be performed.

When the number of supporting rollers is less than 3, it is difficult to balance the support of the winding shaft, the winding shaft is displaced and deformed, and the winding cannot be smoothly performed and is easily broken. When the number of support rollers is four or more, it is not preferable because interference occurs between adjacent support rollers at a stage where the winding diameter is small and stable support cannot be performed. Also,
If the distance between adjacent support rolls (distance between the closest parts) is equal to or larger than the diameter of the winding shaft, the support balance is likely to be lost, which is not preferable.

This support roller may be driven, but it is not essential to drive it, and since the equipment cost increases due to the driving effect, it is advantageous to use a non-driving roller that can rotate. The supporting range of the supporting roller may be divided into a plurality of parts in the axial direction of the winding shaft and arranged side by side so as to be sandwiched intermittently.

The present invention will be described conceptually with reference to an example of a winding device for a metal honeycomb body for carrying out the present invention shown in FIGS. In FIG. 1, reference numerals 10a and 10b denote supports, and a take-up shaft 5 is slidably inserted between the supports 10a and 10b via a slide mechanism 12 provided on a support member 11. The winding shaft 5 includes a pair of side clamps 6 that pressurize and support the side end surfaces of the metal honeycomb body 4.
The small-diameter support portions 6a and 6b of A and 6B are slidably inserted into the central portions thereof.

A spline is formed in the side clamp insertion portion of the winding shaft 5, and the small-diameter support portions 6a and 6b of the side clamp rotate together with the winding shaft 5. The support portions 6c and 6d of the side clamps slide simultaneously with the small diameter support portions 6a and 6b in the axial direction but are in a loosely fitted state and do not rotate together.

That is, the large-diameter support portion 6c of the one side clamp 6A has a structure in which the large-diameter support portion 6c is slidably supported by the slide mechanism 13 provided on the support body 11 and does not rotate, and the small-diameter support portions 6a and 6b are provided. It has a structure that can be slid together with it to adjust the distance b between the pair of side clamps. In addition, the large diameter support portion 6 of the other side clamp 6B
The d is fixedly arranged on the support 10b and has a structure that neither slides nor rotates.

Gears 14a and 14b are provided on the small-diameter support portions 6a and 6b of the pair of side clamps 6A and 6B, and these gears are rotated by a drive unit 15 via a transmission shaft 16 and a gear 17, respectively. It meshes with the relay gear 18, rotates coaxially by the drive device, and transmits the rotation to the winding shaft 5 via the small-diameter support portions 6a, 6b of the pair of side clamps 6A, 6B.

Near the winding shaft 5 between the pair of side clamps 6A, 6B, three support rollers 7a, 7b, 7c are provided.
Is arranged so that it can move back and forth from the side orthogonal to the winding shaft. As shown in FIGS. 2 and 3, these support rollers are rotatably supported by the tip end of a support rod 19 attached to a support base 8 via a pneumatic cylinder 9, and are supported by the winding shaft 5. You can move forward and backward freely.

The supporting rollers 7a, 7b (7b is not shown) 7c has a supporting width a of 20% or more of the metal foil width b and is arranged so as to be symmetrically supported in the central region of the metal foil. The slit 5 as shown in FIG.
The winding shaft 5 having o can be contacted and supported from the outer peripheral side at 120 degree intervals, and the closest distance x between adjacent support rollers x
However, they are arranged so that the height of the metal corrugated foil plus a margin is obtained.

In the case of supporting by this supporting roller, in order to control the supporting reaction force by the supporting rollers 7a, 7b, 7c according to the winding angle (diameter) in the winding process of the metal foil, as shown in FIG. The rotation pulse oscillator 20 is arranged on the winding shaft 5, and as shown in FIG. 2, the rotation pulse from this rotation pulse oscillator is counted to calculate the supporting reaction force by the pneumatic cylinder (elevating device) 9. Controlling device 21
And a pressure adjusting device 22 for adjusting the pressure adjusting valve 22v.

A change pattern of the supporting reaction force according to the winding angle from the start of winding is set in the calculator 21, and the supporting reaction force is controlled according to the change of the winding angle. Therefore, here, the pneumatic cylinder 9 is connected to the compressed air circuit 91.
Is connected via a pressure adjusting valve 22v and a solenoid valve Mv to the pressure adjusting valve 22v and the solenoid valve Mv, and the pressure P1 when the support roller is moved forward and backward, and the one-turn support reaction by the support roller. It is possible to switch between pressure P2 for obtaining a force and pressure P3 for obtaining a supporting reaction force after the support roller has wound once. In addition, here, the air pressure after the pressure adjusting valve 22v is adjusted to the pressure adjusting device 22.
Air pressure feedback circuit 22 for feedback to
p is provided.

Here, the flat metal foil 1 is supplied between the support roller 7a and the support roller 7b via the flat foil supply guide 23, and the metal corrugated foil 2 is passed through the corrugated foil supply guide 24 to the upper surface of the flat metal foil 1. And the support roller 7a.

In the figure, 25 is a foil cutting machine. Also, 26
Is a tip bending jig that bends the leading end of the flat metal foil inserted into the slit 5o of the winding shaft 5 when forming the winding core, and is arranged so as to be movable back and forth with respect to the winding shaft 5 by the elevating mechanism 27. ing.

Numeral 28 is a spot welding machine for fixing the metal flat foil 1 and the metal corrugated foil 2 at appropriate times during the winding completion process, and is arranged so as to be able to move forward and backward with respect to the winding shaft 5 by an elevating mechanism 29. 30 is a metal honeycomb body 4 obtained after winding is completed.
Of the pair of side clamps 6 in the storage table of the unloading device 31 of
It is arranged so that it can move back and forth to the lower part between A and 6B.

In the winding apparatus for a metal honeycomb body of this embodiment having the above-mentioned structure, when the flat metal foil 1 and the metal corrugated foil 2 are stacked to manufacture the roll-up metal honeycomb body 4, a flat foil supply guide is used. 23, the tip of the flat metal foil 1 supplied via
As shown in FIG. 4, the winding shaft 5 is inserted into the slit 5o.

Then, after the tip portion is bent by the tip bending jig 26 and locked to the winding shaft 5, the tip of the metal corrugated foil 2 supplied through the corrugated foil supply / supply guide 24 is connected to the winding shaft 5 and the metal. The winding shaft 5 is sandwiched between the flat foils 1, and the drive device 15 rotates the winding shaft 5 via the small-diameter support portions 6a and 6b of the side clamps 6A and 6B and controls the pneumatic cylinder 9 to support rollers 7a and 7b. After winding once while supporting the reaction force of 1 to 5 kg / cm by the support surface of 7c, the support reaction force of the supporting roller is set to 0.2 kg / cm or less and the winding diameter becomes about 30 mm. It is wound up, and both ends are pressed (pressed) by side clamps, and then wound up to a predetermined winding diameter (angle).

After cutting the metal flat foil 1 and the metal corrugated foil 2 with a predetermined diameter by a cutting machine 25, both ends of the obtained metal honeycomb 4 body are pressed (pressed) by a pair of side clamps 6A and 6B. And the flat metal foil 1 and the corrugated metal foil 2 are spot-welded by a spot welding machine to produce a metal honeycomb body 4. The metal honeycomb body 4 thus obtained is stored in the storage table 30 of the discharge device 31 and is discharged to a predetermined place.

In the winding method for a metal honeycomb body according to the present invention, in the winding process, the slit forming region of the winding shaft is supported by 3 to 4 supporting rollers to supplement the rigidity of the winding shaft and to improve the shaft life. In addition, the shape accuracy and winding density of the winding core portion of the metal honeycomb body can be stably ensured, and the quality such as shape characteristics and structural characteristics of the metal honeycomb body as a whole can be stabilized.

The winding device for carrying out the present invention comprises:
It is not limited to the above embodiment. For example, regarding the structure (shape) of the winding shaft and the pair of side clamps, the drive mechanism, the structure of the support roller, the support reaction force control structure, the arrangement, the feeding direction of the flat metal foil and the corrugated metal foil, etc., the thickness of the metal foil. Now, it is changed within the range in which the present invention according to claims 1 to 3 can be carried out depending on the diameter of the metal honeycomb body, the winding operation conditions and the like.

[0036]

EXAMPLE A flat foil and a corrugated foil made of stainless steel (SUS304) foil were prepared by changing the supporting width and supporting reaction force of a supporting roller by using the winding device for a metal honeycomb body of the present invention shown in FIGS. Were stacked and wound up, and an experiment for manufacturing a metal honeycomb body was conducted. The results of the durability evaluation of the winding shaft and the quality evaluation of the metal honeycomb body will be described together with the results of the conventional example.

[Experimental Conditions] Flat foil width: 170 mm, thickness: 50 μm Corrugated foil width: 170 mm, thickness: 50 μm, wave height: 1.25 mm,
Wave pitch: 2.5mm Winding shaft: Diameter 5mm, slit width 0.4mm, slit forming area 200mm Winding speed (1) Winding core formation (up to winding diameter 30mm): 3m / min (2) Main winding (Winding diameter after 30 mm): 10 m / min Winding tension (1) Core formation (up to winding diameter 30 mm): 0.2 kgf / mm
² (2) Winding (Winding diameter after 30 mm): 1 kgf / mm ² Side clamp Effective diameter: 30 mm Number of support rollers: 3, Support roller spacing x is about 1.7 mm Material: General structural carbon steel (SS41 ) Diameter: 20mm Support width a: 10-170mm (to metal foil width 6-100%) Support reaction force Up to winding angle 360 degrees: 0-10 kg / cm After winding angle 360 degrees: 0-10 kg / cm

In Example 1 satisfying all the ranges of the first, second and third inventions of the present invention, the winding shaft is not broken, twisted, bent or otherwise deformed during the winding process. I was not able to admit. Moreover, when the shape and the winding density of the obtained metal honeycomb body were investigated, the dimension, the shape, and the winding density were within the allowable error (± 1 mm) with respect to the predetermined dimension, and the winding quality was also high. It was good.

On the other hand, the first invention is satisfied,
In the embodiment in which the supporting width of the supporting roller is less than 20% in the central portion, the winding shaft is displaced in the non-supporting portion, and the winding shaft is broken, twisted, bent, or otherwise deformed, and the winding operation cannot be performed. was there.

The first and second inventions are satisfied, but the supporting reaction force of the supporting roller up to the winding angle of 360 degrees is 7 kg /
In the example of cm, the load on the winding shaft becomes large, and the winding drive may stop.

While satisfying the first and second aspects, the supporting reaction force of the supporting roller up to a winding angle of 360 degrees is 0.5.
In the examples of kg / cm, the winding shaft was misaligned, breakage of the winding shaft, deformation such as twisting and bending were recognized, and the winding operation could not be performed in some cases.

The first invention and the second invention are satisfied, but the supporting reaction force after the winding angle of 360 degrees of the supporting roller is 1 kg /
In the example of cm ² , the winding shaft was not broken or twisted, bent, or otherwise deformed, but the corrugated metal foil was sometimes crushed and could not be a product.

From these examples, it can be said that it is more preferable to wind the film while satisfying the conditions for simultaneously satisfying the first invention, the second invention and the third invention. On the other hand, in the conventional example in which the slit forming area of the winding shaft does not have the axial rigidity reinforcing structure such as the support roller or the support, the winding shaft is often misaligned and the winding operation cannot be performed.

[0044]

According to the present invention, in the process of winding the flat metal foil and the metal corrugated foil on the take-up shaft, the central region of the take-up shaft is being taken up by three or more supporting rollers. By supporting in the optimum range from the outer peripheral side of the winding shaft, the axial rigidity of the winding shaft can be supplemented in the central area of the metal foil width, and by preventing the winding shaft from breaking, twisting, bending, etc. It is possible to extend the service life of the core and reduce the equipment cost, and to maintain the shape accuracy of the winding core stably, thereby improving the productivity of manufacturing a metal honeycomb body with stable quality.

[Brief description of drawings]

FIG. 1 is a front conceptual explanatory view showing an example of a winding device for a metal honeycomb body for carrying out the present invention.

FIG. 2 is a side conceptual explanatory view showing an arrangement example of support rollers in an example of a winding device for a metal honeycomb body that implements the present invention.

3 is a partially enlarged front conceptual explanatory view showing an example of a support structure of a support roller in FIG.

FIG. 4 is a partially enlarged side view conceptual diagram showing a state where a winding shaft is supported by a supporting roller in FIG.

FIG. 5 is a three-dimensional conceptual explanatory view showing an example of a conventional method of winding a metal honeycomb body.

FIG. 6 is a plan conceptual explanatory view showing an example of a conventional metal honeycomb body.

FIG. 7 is a front conceptual explanatory view showing an example of a conventional winding device for a metal honeycomb body.

FIG. 8 is a partially cutaway side view conceptual diagram showing an example of a winding core forming structure in an example of a conventional winding device for a metal honeycomb body.

[Explanation of symbols]

 1 Metal Flat Foil 2 Metal Corrugated Foil 3 Casing 4 Metal Honeycomb 5 Winding Shaft 5o Slit 6A, 6B Side Clamp 6a, 6b Small Diameter Support 6c, 6d Large Diameter Support 7a, 7b, 7c Support Roller 8 Support Stand 9 Empty Pressure cylinder 91 Compressed air circuit Mv Solenoid valve 10a, 10b Support 11 Support member 12 Slide mechanism (for winding shaft) 13 Slide mechanism (for side clamp) 14a, 14b Gear 15 Drive device 16 Transmission shaft 17 Gear 18 Relay gear 19 Support Rod 20 Rotation Rotation Pulse Oscillator 21 Operator 22 Pressure Regulator 22v Pressure Regulator Valve 22p (Air Pressure) Feedback Circuit 23 Flat Foil Supply Guide 24 Corrugated Foil Supply Guide 25 Foil Cutting Machine 26 Tip Bending Jig 27 Elevating Mechanism 28 Spot welder 29 Lifting device 30 Storage stand 31 Unloading device

Claims (3)

[Claims] 1. A metal honeycomb provided with a winding shaft for stacking and winding a flat metal foil and a corrugated metal foil, and a pair of side clamps for pressing and supporting side edges of the flat metal foil and the corrugated metal foil during winding. In a winding method of a metal honeycomb body using a body winding device, a central region of a winding shaft in a winding process is supported by three or more supporting rollers from a winding outer peripheral side of a metal foil, A method of winding a metal honeycomb body, comprising winding while reducing a winding load on a winding shaft. 2. The metal foil width is defined as a range in which the central region of the winding shaft in the winding process is supported by three or more supporting rollers via the outer circumference of the metal foil, including at least the central region of the foil width. The method for winding a metal honeycomb body according to claim 1, wherein the range is 20% or more. 3. When the central region of the winding shaft in the winding process is supported from the winding outer peripheral side of the metal foil by three or more supporting rollers, the supporting reaction force is changed from the winding start to the winding angle. 360
3. The metal according to claim 1 or 2, wherein the support is carried out within a range of 1 to 5 kg / cm up to about 100 degrees, and thereafter the support reaction force is set to 0.2 kg / cm or less. Method for winding honeycomb body.