JPH09173868A - Production of metal carrier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To certainly bond a cell main body and an outer cylinder by forming a columnar cell main body by superposing a strip-like flat plate and a corrugated plate composed of metal foil one upon another to wind them in a roll form to insert the same into an outer cylinder and heating the outer cylinder to bond the cell body and the outer cylinder. SOLUTION: For example, a strip-like flat plate 11 composed of Fe-Cr-Al stainless foil and a corrugated plate 12 to which corrugation is applied are used and the leading ends of them are fixed to a winding core material 1 and this core material is rotated to alternately wind the flat plate 11 and the corrugated plate 12. Finally, the other end part of the flat plate 11 is soldered to the wound outermost peripheral surface to form a temporarily fastened cell main body 10. Subsequently, the cell main body 10 is inserted into an outer cylinder and the whole is immersed in a dispersion having a fine granular solder material dispersed therein to apply the solder material to the contact part of the cell main body 10 and the outer cylinder and the contact part of the flat plate 11 and the corrugated plate 18 and introduced into a furnace heated to about 1,200 deg.C and the heated cell main body 10, the outer cylinder, the flat plate 11 and the corrugated plate 13 are bonded to obtain a required metal carrier.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing a metal carrier carrying a catalyst such as an exhaust gas purifying catalyst for an internal combustion engine or the like.

[0002]

2. Description of the Related Art A metal carrier for carrying an exhaust gas purifying catalyst for an internal combustion engine or the like comprises a honeycomb-shaped cell body having a large number of passages through which a gas passes, and an outer cylinder holding the cell body. Generally, the cell body and the outer cylinder are integrally joined. Conventionally, in the metal carrier, as shown in FIG. 1, a tip of a band-shaped flat plate 11 is fixed to a winding core material 1, a corrugated plate 12 is superposed between the flat plates 11, and the flat plate 11 and the corrugated plate 12 are joined together. And winding them in a roll, and fixing the flat plate 11 or the corrugated plate 12 at the end to the already wound outermost peripheral surface by spot welding or the like to form the cell body 10, and the cell body 10 made of metal. An inserting step of inserting into the outer cylinder 20 to form a metal carrier, and heating the outer cylinder 20 having the cell body 10 to join the flat plate 11 and the corrugated plate 12 constituting the cell body 10, and the cell body. It was made by a manufacturing method including a heating step of integrally bonding 10 to the outer cylinder 20.

[0003]

In the conventional method for manufacturing a metal carrier, as shown in FIG. 2, the peeled portion 30 where the cell body 10 and the outer cylinder 20 of the obtained metal carrier are not joined to each other is formed. It happened. The present invention overcomes such inconveniences, and provides a method of manufacturing a metal carrier in which a cell body and an outer cylinder are securely joined.

[0004]

A method of manufacturing a metal carrier according to the present invention comprises a winding step in which a strip-shaped flat plate made of a metal foil and a corrugated plate are superposed and rolled in a roll shape to form a columnar cell body. , An inserting step of inserting the cell body into a metal cylindrical outer cylinder, and heating the outer cylinder in which the cell body is inserted to allow relative movement between the cell main body and the outer cylinder in the initial heating stage. In this state, at least the heating step of joining the cell body and the outer cylinder together is performed.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION As the flat plate and the corrugated plate used in the manufacturing method of the present invention, the flat plate and the corrugated plate used in the conventional manufacturing of a metal carrier can be directly used. In particular,
It can be used according to the application such as rolled stainless steel metal foil or aluminum foil. Also, the thickness of flat and corrugated plates,
The width, length, etc. can be appropriately selected. Further, the wave pitch and height of the corrugated plate can be appropriately selected according to the application.

In the winding step of the present invention, a band-shaped flat plate and a corrugated plate are superposed and wound in a roll shape to form a cylindrical cell body. The wound state of the cell body obtained in this winding step is not fixed. Therefore, it is necessary to keep the wound state temporarily. As a means for maintaining this rolled state, a means such as inserting into a guide having an inner diameter equal to or smaller than the inner diameter of the outer cylinder, or temporarily fixing with a bonding agent that is melted or decomposed in the heating step and loses the bonding strength, is used. Can be adopted.

Further, the winding step can be carried out in a cylindrical mold having a slit extending on the outer peripheral surface in the axial direction and having an inner peripheral diameter equal to or smaller than the inner peripheral diameter of the outer cylinder. In this case, the strip-shaped flat plate and the corrugated plate are supplied into the mold through the slit of the mold. The obtained cell body is guided to the inner peripheral surface of the mold and its outer diameter is restricted. Then, in the inserting step, the cell main body is pushed in the axial direction by the piston and is pushed into the outer cylinder provided coaxially with the mold, whereby the inserting step is carried out.

It is desirable to wind the cell body so that the outermost diameter of the cell body is smaller than the inner diameter of the outer cylinder. This can facilitate the insertion step of inserting the cell body into the outer cylinder. As a joining method, brazing is desirable in terms of simplicity of joining work. At this time, the brazing material used is selected depending on the materials of the flat plate and the corrugated plate to be joined. As the brazing material, a dispersion type brazing material in which fine particles of fine brazing material are dispersed in a liquid can be used. Then, immersing the obtained cell body in this dispersion brazing material,
The brazing material can be applied by sprinkling it like a shower. Further, it is also possible to use a flat plate or corrugated plate to which a brazing material is applied in advance.

[0009]

In the method of manufacturing a metal carrier of the present invention, first, in the winding step, a strip-shaped flat plate made of metal foil and a corrugated plate are superposed and rolled in a roll to form a columnar cell body. Next, in the insertion step, the cell body is inserted into the cylindrical outer cylinder. Then, in the heating step, the outer cylinder in which the cell body is inserted is heated, and the cell body and the outer cylinder are joined in a state where the relative movement of the cell body and the outer cylinder is enabled in the initial stage of heating, and the cell body and the outer cylinder are connected Join together.

In the manufacturing method of the present invention, since the rolled flat plate and the corrugated plate forming the cell body are not fixed and can be moved relative to each other, even if some contraction occurs during heating, The corrugated plates slide relative to each other and move in the unwinding direction. For this reason, the outer diameter of the cell body moves in a direction of increasing, and always comes into contact with the inner peripheral surface of the outer cylinder. Then, in this state, they are joined by a brazing material. Therefore, a peeled portion that is not joined is not generated between the cell body and the outer cylinder.

According to the method for producing a metal carrier of the present invention,
Since the cell body and the outer cylinder are reliably joined together, a sturdy and durable metal carrier can be easily manufactured.

[0012]

The present invention will be described below in detail with reference to examples. (Example 1) Fe-Cr-Al system stainless steel (20Cr
-5Al) strip-shaped flat plate 11 (thickness 50 μm,
A width of 60 mm) was used. The corrugated plate 12 is a corrugated plate obtained by corrugating the flat plate with a wave height of 2.7 mm and a pitch of 4.5 mm by an ordinary rolling method. Then, the flat plate 11 and the corrugated plate 12 are used, and the ends thereof are fixed to the core material 1 for winding, and the core material 1 is rotated to alternately alternate the flat plate 11 and the corrugated board 1 as shown in FIG.
Wrapped around 2. Finally, using low melting point brazing material,
The other end of the flat plate 11 was brazed to the wound outermost peripheral surface to form the cell body 10 temporarily fixed. This cell body 1
A perspective view of No. 0 is shown in FIG.

This cell body has an inner diameter of 52 mm and a thickness of 1 m.
It was inserted in the outer cylinder of m. Next, it was immersed in a dispersion liquid in which a fine-particle brazing material made of BNi-5 was dispersed, and the brazing material was applied to the contact portion between the cell body and the outer cylinder and the contact portion between the flat plate and the corrugated plate. After that, the brazing material was applied and the outer cylinder in which the cell body was incorporated was placed in a furnace heated to 1200 ° C. and heated to bond the cell body and the outer cylinder and the flat plate and the corrugated plate. In this way, a metal carrier was manufactured.

The metal carrier obtained had no gap between the cell body and the outer cylinder. Further, it was observed that the other end of the flat plate was slightly moved in the unwinding direction. (Example 2) In place of the temporary fixing of the low melting point brazing material of Example 1, a ring having an inner peripheral diameter slightly smaller than the inner peripheral diameter of the outer cylinder was adopted. Then, a ring was put on the outer peripheral surface side of the cell body manufactured by the method of Example 1 to prevent the cell body from being unwound. In this state, the cell body was inserted into the outer cylinder. At the time of this insertion, the ring was pulled out from the cell body, and the cell body was held on the inner peripheral surface of the outer cylinder. Thereafter, the first embodiment
A brazing material was applied in the same manner as above and heated in a heating furnace to bond the cell body and the outer cylinder and the flat plate and the corrugated plate. In this way, a metal carrier was manufactured.

The obtained metal carrier had no gap between the cell body and the outer cylinder. Further, it was observed that the other end of the flat plate was slightly moved in the unwinding direction. (Embodiment 3) In this embodiment, the winding and inserting device 50 shown in FIGS. 4 and 5 was used. This device comprises a mold 51 and a pressing piston 55 fixed to a base (not shown). The mold 51 has a C-shaped cross section and a slit 5 parallel to the axial direction.
2, and the diameter of the inner peripheral surface is slightly smaller than the inner diameter of the outer cylinder 20.

The pressing piston 55 is fixed to a drive shaft of a winder (not shown), and has a flange 56 on the front end side and a winding core member 5 extending from the shaft core of the flange 56 to the front end.
With 7. The winding machine has a function of rotating the pressing piston 55 and also of driving the pressing piston 55 in the axial direction. Using this winding and inserting device 50, the tip of the flat plate 11 is fixed to the winding core material 57, and the corrugated plate 1
2 is sandwiched and the winding / inserting device 50 is rotated to move the flat plate 1
1 and the corrugated plate 12 were wound. Then, the cell body 10 was formed in the mold 51.

Next, the mold 51 on the side opposite to the pressing piston 55.
The outer cylinder 20 is coaxially arranged on the end surface of the cell body 10, and in this state, the pressing piston 55 is pushed in the axial direction to move the cell body 10 into the outer cylinder 2.
It was inserted into the shaft hole of 0. Thereafter, a brazing material was applied in the same manner as in Example 1 and heated in a heating furnace to bond the cell body and the outer cylinder and the flat plate and the corrugated plate. In this way, a metal carrier was manufactured.

The metal carrier obtained had no gap between the cell body and the outer cylinder. Further, it was observed that the other end of the flat plate was slightly moved in the unwinding direction.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a winding state of a flat plate and a corrugated plate.

FIG. 2 is an end view of a metal carrier manufactured by a conventional manufacturing method.

FIG. 3 is an end view of the cell body obtained in Example 1 of the present invention.

FIG. 4 is a schematic view showing a winding state of the winding and inserting device used in Example 3 of the present invention.

FIG. 5 is a schematic diagram showing an inserted state of Example 3 of the present invention.

[Explanation of symbols]

1: core material, 10: cell body, 11: flat plate, 12: corrugated plate,
20: Outer cylinder, 30: Gap, 40: Coating liquid, 50: Winding and inserting device, 51: Mold, 52: Mold break, 55: Piston, 56: Flange, 57: Core material

Claims (5)

[Claims] 1. A winding step of stacking a strip-shaped flat plate made of a metal foil and a corrugated sheet and winding them in a roll to form a columnar cell body, and inserting the cell body into a tubular outer cylinder. An inserting step, and a heating step of heating the outer cylinder having the cell body inserted therein and joining at least the cell body and the outer cylinder in a state where the cell body and the outer cylinder can be relatively moved at the initial stage of heating. And a method of manufacturing a metal carrier, comprising: 2. The cell body obtained in the winding step is inserted and held in a guide having an inner diameter equal to or smaller than the inner diameter of the outer cylinder, and in the insertion step, the cell body is guided by the guide. The method for producing a metal carrier according to claim 1, wherein the metal cylinder is inserted into the outer cylinder. 3. In the winding step, a cylindrical mold having a C-shaped cross-section extending in the axial direction is used, and the flat plate and the corrugated plate supplied from the cut are wound in the mold to form the cell. The method for producing a metal carrier according to claim 1, wherein a main body is formed, and in the inserting step, the cell main body in the mold is pushed axially in a piston and is inserted into the outer cylinder. 4. The cell body obtained in the winding step is temporarily fixed with a bonding agent that is melted or decomposed in the heating step and loses the bonding force, and the cell body is maintained in a wound state. The method for producing a metal carrier according to claim 1, wherein the cell body is inserted into the outer cylinder. 5. The method for producing a metal carrier according to claim 1, wherein at least one surface of the flat plate used in the winding step is coated with a brazing material.