JPH0327736Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a welding ceramic piece that can be easily attached to the surface of a metal member by arc stud welding.

[Conventional technology]

By providing a heat-resistant protective layer of ceramics on a metal member, a structural material that can be used in a high-temperature atmosphere such as a furnace wall, burner, or tuyere is obtained. Alternatively, the abrasion resistance of ceramics is utilized as linings for high-speed rotating equipment such as blowers and pumps.

Recently, in order to easily form this ceramic layer on-site, a method has been developed in which ceramics formed into pieces of a certain shape are attached by means such as welding or brazing.

For example, in Japanese Patent Application Laid-open No. 60-65775,
The ceramic piece is attached to the base metal by inserting a metal fixture into a through hole provided in the ceramic piece and resistance welding this fixture to the base metal. According to this method, since the ceramic piece is attached to the base metal by the fixing jig, the ceramic piece is held by a strong metal bond between the fixing jig and the base metal.

However, the fixing jig shown in Japanese Patent Application Laid-Open No. 60-65775 is a columnar body having a constant cross-sectional area. This means that when resistance welding the fixing jig to the base metal, the welding current supplied does not cause local heating inside the fixing jig, and the welding current is applied to the contact area between the fixing jig and the base metal. This is because the purpose is to be used for heat generation in. In order to weld the fixing jig to the base metal with the specified strength,
There is a lower limit to the contact area between the fixture and the base metal.

However, when the fixing jig is molded with the cross-sectional area of this portion unchanged, the surface area of the fixing jig exposed above the ceramic piece becomes large. Therefore, heat resistance, abrasion resistance, etc. are inferior in this part, and the finish is also poor in appearance. In order to avoid this, in Japanese Patent Application Laid-Open No. 60-65775, a metal cap and a ceramic cap are placed over the fixing jig. Therefore, the number of parts increases, and the welding work becomes complicated accordingly.

Therefore, the present inventors developed a ceramic piece incorporating a stud having a flange part and a pin part following the cone part, and filed a separate application for this. FIG. 4 shows this ceramic piece.
That is, the ceramic piece body 1 has a hole 2.
and a recess 3 are provided, into which a stud 5 is inserted. This stud 5 has a cone portion 7 having a protrusion 6 at its tip, followed by a flange portion 8.
A pin portion 9 for supplying welding current is erected from the top.
Note that a plurality of grooves 4 are provided on the lower surface of the ceramic piece body 1 to connect the inner space of the recess 3 to the outer circumferential surface of the ceramic piece body 1.
This groove 4 functions as a passage for discharging gas, fume, etc. generated during welding to the outside.

When the stud 5 having such a shape is arc welded to the base metal, a large bonding area can be obtained, so that the ceramic piece body 1 can be attached to the base metal with sufficient bonding strength. On the other hand, since the stud 5 exposed on the surface side of the ceramic piece body 1 is only the cross section of the pin portion 9, deterioration of properties such as heat resistance and abrasion resistance due to exposed metal is also suppressed.

[Problem that the invention attempts to solve]

When attaching the ceramic piece by welding the studs 5 shown in FIG. 4 to the base metal, the upper surface of the flange portion 8 and the bottom surface of the recess 3 must be connected to prevent the ceramic piece body from peeling off from the base metal. is brazed. In order to make this brazed part 10 have strong joint strength,
Ceramic piece body 1 in contact with flange portion 8
It is necessary to metalize the bottom surface and inner peripheral surface of the cavity, that is, the recess 3.

However, some types of ceramics cannot be metalized. Therefore, the stud 5 shown in FIG. 4 cannot be used for such ceramic pieces. Furthermore, since means such as metallization and brazing are required, the number of steps increases and the work of attaching the ceramic pieces becomes troublesome.

Therefore, the present invention eliminates the need for such a connection process between the stud and the ceramic piece body, and by mechanically interlocking the two,
The purpose is to easily attach a ceramic piece to a base metal.

[Means for solving problems]

In order to achieve this purpose, the ceramic piece for welding of the present invention is made by inserting a stud, which has one or more minimal cross-section parts from the flange part to the core part, into a through hole provided in the ceramic piece body. Features.

〔Example〕

Hereinafter, the features of the present invention will be specifically explained using examples with reference to the drawings.

FIG. 1 is a sectional view showing a ceramic piece for welding according to this embodiment. FIG. 2 also shows several examples of studs to be inserted into the ceramic piece.

The ceramic piece main body 1 is obtained by forming a plate material having a thickness of 3 to 25 mm into an appropriate shape such as a square or a rectangle. By attaching a plurality of such ceramic piece bodies 1 to a target base metal, a ceramic layer having excellent heat resistance, abrasion resistance, etc. is formed. Examples of materials used for the ceramic piece body 1 include alumina, zirconia, cordierite, silicon carbide,
There are various types such as silicon nitride.

A recess 3 is provided in the center of the ceramic piece body 1. This recess 3 corresponds to the shape of the flange portion 8 of the stud 5 accommodated therein, and is formed into various shapes such as circular and rectangular. Further, above the recess 3, there is a tapered hole 2 that continues from the recess 3 and widens upward.
is provided. This tapered hole portion 2 has a shape corresponding to the core portion 11 of the stud 5.
Grooves 4 are formed in all directions from the recess 3 as necessary. This groove 4 functions as a passage for discharging gas, fume, etc. generated during welding to the outside. Note that the corners from the bottom surface of the ceramic piece body 1 to the peripheral wall of the recess 3 and from the bottom surface of the recess 3 to the inner wall of the hole 2 are
It is preferable to keep it rounded.

Into the cavity thus formed in the ceramic piece body 1 is inserted the stud 5, which is provided with a cone portion 7 having a protrusion 6 at its tip, followed by a flange portion 8 and a core portion 11. The core part 11 in this example is
It is formed into a tapered shape that increases in diameter toward the top. The flange portion 8 and core portion 11 of this stud 5 may be integrally molded or may be separately molded. In the case of a stud 5 in which the flange part 8 and the core part 11 are separated, the flange part 8 and the core part 11 are inserted from both sides of the ceramic piece main body 1, and the contact surfaces between the two are brazed, welded, etc. Connect by. Alternatively, it is also possible to connect the flange portion 8 and the core portion 11 using the electric current when arc welding the stud 5 to the base metal.

When the stud 5 with the core portion 11 expanding upward is inserted into the ceramic piece body 1 and connected to the base metal by arc welding, the part of the stud 5 where the cross-sectional area is extremely small is created. The ceramic facing the top is sandwiched between the studs 5, which have a larger cross-sectional area. As a result, the stud 5 will not fall off from the ceramic piece main body 1 along the vertical direction in FIG.

FIG. 2 shows several examples of studs with a similar effect. In either example, a portion with an extremely small cross-sectional area is formed from the flange portion 8 to the upper end of the core portion 11, and the ceramics in contact with this portion are sandwiched from above and below. It goes without saying that a plurality of portions having the smallest cross-sectional area may be provided from the flange portion 8 to the upper end of the core portion 11.

The stud shown in FIG. 1A is provided with a core portion 11 whose large cross-sectional area is once reduced to a large cross-sectional area again on the side in contact with the flange portion 8. By providing the portion where the cross-sectional area is minimum in the middle of the core portion 11 in this way, the surface area of the stud 5 exposed on the surface side of the ceramic piece body 1 can be reduced. This suppresses deterioration of properties such as heat resistance and abrasion resistance due to exposed metal.

Similarly, in the stud shown in FIG. 1B, the outer periphery of the core portion 11 whose cross-sectional area changes is a continuous surface with no inflection points. When the core portion 11 is made into a continuous surface in this manner, the tapered hole portion 2 provided in the ceramic piece body 1 for inserting the stud 5 becomes one without a protruding portion. Therefore, local stress concentration is avoided, and the occurrence of cracks, cracks, etc. in the ceramic piece body 1 is suppressed.

Furthermore, the stud shown in FIG.
The upper end of the core part 11 is set to be inside the ceramic piece body 1. The pin portion 9 is connected to or integrally formed with the core portion 11. Then, the hole from the upper end of the core part 11 to the surface of the ceramic piece body 1 is filled with a suitable refractory material. As a result, the studs 5 exposed on the surface of the ceramic piece body 1
is only the cross section of the pin portion 9. Therefore, deterioration of properties such as heat resistance and abrasion resistance due to exposed metal is suppressed.

By forming the core portion 11 of the stud 5 into such a shape, the ceramic piece body 1 can be fixed without the need to braze the flange portion 8 to the ceramic piece body 1. Therefore, it has become possible to provide a ceramic layer on the target base metal, regardless of the type of ceramic.

As a stud 5 with the smallest cross-sectional area in the middle,
When an integral stud 5 is used, the stud 5 is inserted into the ceramic piece body 1 by pouring molten metal into a cavity provided in the ceramic piece body 1 or by press-forming.
FIG. 3 explains the stud insertion method in the order of steps when press molding is adopted. In other words, the figure a
As shown in FIG. 2, the ceramic piece body 1 is placed on a lower mold 31 having holes corresponding to the protrusions 6 and the cone portions 7, and the heated metal material 33 is inserted into the cavity 32 provided in the ceramic piece body 1. do.
As shown in FIG. 2B, this metal material 33 is plastically deformed by pressurizing it with an upper die 34, and fills the cavity 32 of the ceramic piece body 1.
In this way, an integral stud 5 is provided within the ceramic piece body 1, as shown in Figure c.

The pin portion 9 attached to the core portion 11 may be formed integrally with the core portion 11 or may be formed separately from the core portion 11.
This pin portion 9 is connected to the power source of the welding machine and serves as a lead for co-supplying welding current to the stud 5.
Note that this pin portion 9 may also be provided with a notch 12 at a position corresponding to the upper surface of the ceramic piece body 1 or its vicinity. This knot 12
The effect will be described later.

The ceramic piece body 1 into which the stud 5 is inserted is attached to the base metal by arc welding the stud 5 to the base metal. Generation of the arc starts from the tip of the cone portion 7.
At this time, when the protrusion 6 is provided at the tip of the cone portion 7, the location where the arc occurs can be specified, thereby improving the reliability of welding. In addition, in order to smoothly transfer the arc and penetrate the cone part 7, it is preferable that the inclination angle of the cone part 7 is 120 to 170 degrees.

The arc generated at the tip of the cone portion 7 or the protrusion 6 gradually moves to the periphery while melting the cone portion 7. At this time, since the cone portion 7 is an inclined surface, the arc transitions smoothly.
A portion of the cone portion 7 and flange portion 8 is then melted and serves as a bonding material for bonding the stud 5 to the base metal. Here, the flange portion 8 has the function of replenishing the penetration necessary for joining. and,
By setting the welding current and voltage to values that allow the flange portion 8 to melt slightly, a constant joint area can be obtained at all times. For example, height 0.7mm
At a voltage of 180 V, for a stud 5 having a cone portion 7 with a maximum diameter of 13 mm and a flange portion 8 with a height of 3 mm.
When a current of 21,000 A is supplied, the flange portion 8 melts into a thickness of approximately 0.2 to 0.3 mm.

When providing the notch 12 on this pin part 9,
After the stud 5 has been welded to the base metal, it can be broken from the notch 12 by hitting the pin portion 9 projecting from the upper surface of the ceramic piece body 1 with, for example, a hammer. Alternatively, the notch 12 may not be provided, and the pin portion 9 protruding from the upper surface of the ceramic piece body 1 may be cut using nippers or the like.

In the above example, one stud 5 is placed in the center of the ceramic piece body.
is inserted. However, the present invention is not limited to this. For example, it goes without saying that one or more studs 5 may be inserted around the periphery of the ceramic piece body. Further, when installing the ceramic piece in this way, the stud 5 is placed between the recess 3 of the ceramic piece body 1 using a highly elastic resin material, rubber material, etc.
Materials such as cloth woven from metal fibers and asbestos may also be arranged as a cushioning material. At this time, the impact that the ceramic piece body 1 receives is alleviated,
It becomes possible to protect the ceramic piece body 1 from cracks, cracks, etc.

[Effect of idea]

As explained above, in the present invention, a part with the smallest cross-sectional area is provided from the flange part to the upper end of the core part, and the stud is inserted into a ceramic piece body having a cavity corresponding to this shape. and the ceramic piece body are fixed without the need for brazing. Therefore, when the stud is welded to the base metal by arc welding, the ceramic piece body does not separate from the base metal. In this way, according to the present invention, a ceramic layer having excellent heat resistance, wear resistance, etc. can be easily formed on a target metal structure.

[Brief explanation of drawings]

FIG. 1 shows a ceramic piece according to an embodiment of the present invention, FIG. 2 shows several examples of studs to be inserted into the ceramic piece, and FIG. 3 shows an example of a method of inserting the stud into the ceramic piece body. Moreover, FIG. 4 shows a ceramic piece that was separately developed by the inventors of the present invention.

Claims (1)

[Scope of utility model registration request] A ceramic piece for welding, characterized in that a stud having one or more minimal cross-section parts formed from a flange part to a core part is inserted into a through hole provided in a ceramic piece body.