JPH10111228A - Method and apparatus for testing pipe bottom strength of bottomed hollow pipe made of ceramic - Google Patents

Abstract

PROBLEM TO BE SOLVED: To test simply accurately the strength of a pipe bottom by applying pressure to the outer diameter of a bottomed hollow pipe through two kinds of pressure medium having the outer diameter within a specified range. SOLUTION: The outer peripheral surface of a bottom hollow pipe made of ceramics is held by a holding means 2. A pressure means 14 applies pressure to the bottom surface of the bottomed hollow pipe 10 through a pressure medium 17 abutting thereagainst from the outside in the coaxial direction with the bottomed hollow pipe to test the strength of the pipe bottom. Then, two kinds of pressure mediums 17 having the outer diameter dt are used to apply pressure, in this case the outer diameter dt satisfies the following equations; (1/10)DG<=dt<=(1/2)DG and (2/3)DG<=dt<=DG. Thereby the strength of two portions of the pipe bottom center part 7 or the pipe bottom edge part 8 of the bottomed hollow pipe 10 having the bottom part and the pipe side wall formed integral with each other without a connecting part, and the strength of the whole pipe bottom part can be tested more simply and accurately.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for testing the strength of a bottomed hollow tube made of ceramics.

[0002]

2. Description of the Related Art Conventionally, as a method of testing the bottom strength of a ceramic bottomed hollow tube, as shown in FIG. Provided coaxially with the holding means via a pressurizing medium 3 having an upper surface shape corresponding to the outer shape of the bottom surface for pressurizing with a predetermined force by contacting only the bottom surface of the bottom hollow tube from the outside. And
There has been proposed a method for testing the bottom strength of a ceramic bottomed hollow tube which is pressurized coaxially with the bottomed hollow tube by a pressurizing means 4 connected to the pressurized medium (Japanese Patent Publication No. Hei 7 (1994)). -43305).

[0003]

However, the above-mentioned method uses, as shown in FIG. 3, a bottom surface having one of the open ends of a hollow tube 5 having a joint on the inner surface of the tube side wall, which is used for a fuel cell or the like. The purpose of the present invention is to test the joint strength of the joint between the bottom and the inner surface of the side wall of the ceramic bottomed hollow tube sealed with 6.

[0004] Incidentally, a solid electrolyte tube used for a sodium-sulfur battery or the like is also a hollow tube with a bottom made of ceramics. Unlike the hollow tube with a bottom, the solid electrolyte tube is manufactured by integral molding. As shown, there is no joint between the bottom and the tube side wall. Further, the solid electrolyte tube is
Due to the behavior of sodium polysulfide generated in the tube during charge / discharge of the sodium-sulfur battery or during temperature rise / fall, as shown in FIG.
It has been found that a tensile stress is applied.

[0005] For this reason, in the solid electrolyte tube, it is necessary to test the tube bottom strength at two places, that is, the center of the tube bottom and the edge of the tube bottom. There is a problem that it is impossible to do. Therefore, the present invention provides a simple and accurate test for the center of the bottom of the tube or the edge of the bottom of the ceramic bottom tube having no joint between the bottom and the side wall of the tube. It is an object to provide a test method and an apparatus.

[0006]

That is, according to the present invention, the outer peripheral surface of the bottomed hollow tube is held by the holding means, and only the bottom surface of the bottomed hollow tube is contacted from the outside with a predetermined force. The pressurizing means provided coaxially with the holding means and connected to the pressurizing medium via a pressurizing medium having an upper surface shape corresponding to the outer shape of the bottom surface for pressing. A method of testing the bottom strength of a ceramic bottomed hollow tube pressurized coaxially with the bottom hollow tube, wherein the pressurized medium has an outer diameter (dt: mm) outside the bottomed hollow tube. Diameter (D
_G : mm) and 2 satisfying the following relational expressions (1) and (2):
A method for testing the bottom strength of a ceramic bottomed hollow tube characterized by using a seed is provided. _{(1/10) D G ≦ dt ≦} (1/2) D G ... (1) (2/3) D G ≦ dt ≦ D G ... (2)

Further, according to the present invention, there is provided a holding means for holding the outer peripheral surface of the bottomed hollow tube, and a pressing means provided coaxially with the holding means, wherein the pressing means is provided with the bottomed hollow pipe. Tube bottom strength of a ceramic bottomed hollow tube provided with a pressurizing medium having a top surface shape corresponding to the outer shape of the bottom surface for pressurizing with a predetermined force in contact with only the bottom surface of the hollow tube from outside. In the test apparatus, the outer diameter (dt: mm) of the pressurized medium is
A bottomed hollow tube made of ceramics, characterized by using two kinds of pressurized media satisfying the outer diameter (D _G : mm) of the bottomed hollow tube and the following relational expressions (1) and (2). A bottom strength test device is provided. _{(1/10) D G ≦ dt ≦} (1/2) D G ... (1) (2/3) D G ≦ dt ≦ D G ... (2)

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION In the present invention, a tube bottom strength test is performed by using two types of pressurized media whose outer diameter of a pressurized medium is within a predetermined range with respect to the outer diameter of a bottomed hollow tube. In this way,
By performing the tube bottom strength test, it is possible to more easily and accurately compare the tube bottom center portion or the tube bottom edge portion with the conventional one.
It is possible to know the strength of the spot, and thus the entire pipe bottom.

In the present invention, the ceramic bottomed hollow tube is intended for a bottomed hollow tube manufactured by integral molding and having no joint between the bottom and the tube side wall. However,
Similarly to the above-mentioned conventional method, a strength test according to the present invention can be performed on a bottomed hollow tube in which the open end of the hollow tube is sealed with a bottom surface having a joint on the inner surface of the tube side wall.

In the present invention, the holding means is arranged so as to surround the portion where the bottomed hollow tube is to be loaded. Here, the holding means is means for holding the outer peripheral surface of the bottomed hollow tube, and when performing a strength test by pressing the bottomed hollow tube from the tube bottom portion, the bottomed hollow tube is This is a means for fixing coaxially with the pressing direction so as not to move in the centered state.

In the holding method, the outer peripheral surface of the bottomed hollow tube may be held or gripped. If the holding force is insufficient, a holding means may be further provided above the holding means. For example, a hydraulic chuck or the like provided coaxially with the bottomed hollow tube and provided with a portion for holding the outer peripheral surface of the bottomed hollow tube by expanding the ring-shaped elastic body inward is preferably used.

In the present invention, the pressurizing means is disposed vertically below the portion where the hollow tube with the bottom is to be loaded.
It is also possible to modify the apparatus so that the pressurizing means is arranged vertically upward, the bottomed hollow tube is loaded with the bottom up and pressurized. Here, the pressurizing means means a means for generating a thrust by a fluid pressure such as a hydraulic pressure or a water pressure, and in the present invention, the generated thrust is transmitted in a longitudinal direction of the bottomed hollow tube so as to generate the thrust. Installed vertically to test the strength of empty tubes. For example, a hydraulic cylinder or the like is preferably used.

At this time, it is also possible to provide a structure in which a load cell is interposed between the pressurizing medium and the pressurizing means so that the applied thrust can be accurately measured. As a result, a product whose bottom surface is not broken even when a predetermined force is applied can be made a good product.

Further, a pressurizing medium having the other connected to the pressurizing means is protruded from the tip of the pressurizing means so that one of the pressurizing means is in contact only with the outside of the bottom of the bottomed hollow tube to be loaded. You.

Here, the pressurized medium is a medium that transmits the thrust generated by the pressurizing means to the bottomed hollow tube.
The shape of the pressurized medium is a curved surface whose contact surface with the bottomed hollow tube matches the outer shape of the bottom surface. This prevents a localized concentrated load from acting on the bottom surface and facilitates the centering of the two.

Further, the material of the pressurizing medium is preferably a material which is less likely to be deformed by pressurization and which can ensure the adhesion of the contact surface with the bottomed hollow tube. For example, hard rubber, hard resin and the like are preferably used.

Further, the outer diameter (dt) of the pressurized medium is determined by the relational expressions (1) and (2) with the outer diameter (D _G ) of the bottomed hollow tube. That is, when the pressure outside diameter dt of the pressure medium is used pressurized medium in the regions shown by the following relational expression between the outer diameter D _G of the bottomed hollow tube (1), the chromatic 6 Tensile stress is applied specifically to the center of the bottom of the hollow tube. (1/10) D _G ≤dt≤ (1/2) D _G (1)

In this case, the outer diameter dt of the pressurized medium
If There becomes (1/2) D _G above, a tensile stress is also dispersed in the tube bottom edge portion not Kansoko center only, accurate testing difficult. Further, when dt is (1/10) D _G or less, there is a problem that stress producing site is narrowed. Further, when the outer diameter dt of the pressurizing medium, used pressurized medium in the regions shown by the following relational expression between the outer diameter D _G of the bottomed hollow tube (2) 7
As shown in (1), the tensile stress is transmitted specifically to the bottom edge of the bottomed hollow tube. (2/3) D _G ≦ dt ≦ D _G (2)

In this case, the outer diameter dt of the pressurized medium
If There becomes (2/3) D _G below, the tensile stress is also dispersed in Kansoko center not the tube bottom edge portion only, accurate testing difficult. In addition, dt may be set to _DG or more, but a portion that does not contact the bottom of the bottomed hollow tube cannot transmit thrust to the bottomed hollow tube, and therefore has no technical significance.

Hereinafter, the present invention will be described with reference to the drawings. In the apparatus shown in FIG. 1, reference numeral 9 denotes a base fixed to a machine frame.
Hydraulic chuck 11 for holding the outer peripheral surface of 0 is provided vertically. Hydraulic chuck 11 has guide unit 1 vertically.
2 and a central portion provided with a portion for holding the outer peripheral surface of the bottomed hollow tube 10 by inflating the ring-shaped elastic body 13 inward by hydraulic pressure. It can be reliably held in an accurate centered state. If the holding force is insufficient, the hydraulic chuck 11 can be provided above as shown by the imaginary line in the figure.

Reference numeral 14 denotes a pressurizing unit provided coaxially with the hydraulic chuck 11. The pressurizing means 14 includes a hydraulic cylinder 15, a pressurizing rod 16 provided vertically below the base 9, and a pressurizing medium 17 made of hard rubber protruding from the tip thereof. In addition, a load cell 18 is interposed between the hydraulic cylinder 15 and the pressure rod 16 so that the pressing force at each moment can be accurately known.

In the tube bottom strength test apparatus configured as described above, the bottomed hollow tube 10 is inserted from above the apparatus with the hydraulic chuck 11 opened, and the bottom surface is pressed by the pressing means 14.
On the pressurizing medium 17. Then, the bottomed hollow tube 10
Of the hydraulic chuck 11 and the pressurized medium 1
7, and then supply hydraulic pressure to the hydraulic chuck 11 to firmly chuck the outer peripheral surface of the bottomed hollow tube 10, operate the hydraulic cylinder 15, and pressurize the bottomed hollow tube with the pressurized medium 17. A tube bottom strength test can be performed by strongly pressing only the bottom surface of the tube 10.

[0023]

EXAMPLES Hereinafter, examples of the present invention will be described in more detail, but the present invention is not limited to these examples. (Example 1) In the apparatus shown in FIG.
Using a solid electrolyte tube having an outer diameter (D _G ) of 45 mm as 0,
The outer diameter (dt) of the pressurized medium 17 satisfies the following relational expression (1) with the outer diameter (D _G ) of the bottomed hollow tube 10: 10 mm
After the pressurizing medium 17 is set,
A hydraulic pressure of 0 Kgf / cm ² was applied. _{(1/10) D G ≦ dt ≦} (1/2) D G ... (1) As a result, it takes a tensile stress Kansoko center 7 of the solid electrolyte tube was measured for the stress, 5.48Kgf / m
m ² . The tensile stress applied to the edge 8 of the tube bottom was 0.78 kgf / mm ² , which was negligible. Table 1 shows the results.

[0024] Similarly to Example 2 Example 1, in the apparatus shown in FIG. 1, the outer diameter as the bottomed hollow tube 10 (D _G)
Using a 45 mm solid electrolyte tube, the pressurizing medium 17 having an outer diameter of 38 mm which satisfies the following relational expression (2) with the outer diameter (dt) of the pressurized medium 17 with the outer diameter (D _G ) of the bottomed hollow tube. Was installed, and a hydraulic pressure of 100 kgf / cm ² was applied by the pressurizing means 14. (2/3) D _G ≦ dt ≦ D _G (2) As a result, a tensile stress was applied to the tube bottom edge 8 of the solid electrolyte tube, and the stress was measured to be 8.83 Kgf /
mm ² . Note that no tensile stress was generated at the center 7 of the tube bottom, and only a compressive stress was generated. Table 1 shows the results.
Shown in

[0025] Similarly to Comparative Example 1 Example 1, in the apparatus shown in FIG. 1, the outer diameter as the bottomed hollow tube 10 (D _G)
Using a 45 mm solid electrolyte tube, a pressurizing medium having an outer diameter of 25 mm that satisfies the following relational expression (3) with the outer diameter (dt) of the pressurizing medium 17 and the outer diameter (D _G ) of the bottomed hollow tube is used. After the installation, a hydraulic pressure of 100 kgf / cm ² was applied by the pressurizing means 14. (1/2) D _G <dt <(2/3) D _G (3)

As a result, as shown in FIG. 8, a tensile stress is applied to both the tube bottom center 7 and the tube bottom edge 8 of the solid electrolyte tube. When the stress is measured, the center of the tube bottom is 3.20 kgf. / Mm ² , the edge of the tube bottom is 3.48 kg
f / mm ² . As described above, when the outer diameter of the pressurized medium 17 is out of the range specified by the present invention, the stress is dispersed, and a tensile stress is generated specifically in the center 7 of the tube bottom or the edge 8 of the tube bottom. In addition, it is impossible to obtain a sufficient stress for the test. Table 1 shows the results.

[0027]

[Table 1]

[0028]

As described above, according to the present invention, the outer diameter (dt) of the pressurized medium is equal to the outer diameter (D
_G ) A simple method of using two types of pressurized media satisfying the above-mentioned relational expressions (1) and (2), while suppressing the generation of stress on other portions, while controlling the center of the tube bottom or the tube bottom. It is possible to specifically generate a tensile stress in the edge portion.

[0029] Thus, if the above two types of tests are performed, it is possible to accurately grasp the strength of the entire bottom portion of the hollow tube made of ceramics, which is an extremely effective strength test method and apparatus. .

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing one embodiment of the present invention.

FIG. 2 is a cross-sectional view showing one embodiment of the prior art.

FIG. 3 is a partial sectional view showing an example of a hollow tube with a bottom.

FIG. 4 is a partial sectional view showing an example of a solid electrolyte tube.

FIG. 5 is a cross-sectional view showing the position of a tube bottom center portion and a tube bottom edge portion.

FIG. 6 is a partial sectional view showing one embodiment of the present invention.

FIG. 7 is a partial sectional view showing another embodiment of the present invention.

FIG. 8 is a partial sectional view showing a comparative example with respect to the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... hollow tube with a bottom, 2 ... holding means, 3 ... pressurizing medium, 4 ... pressurizing means, 5 ... hollow tube, 6 ... bottom surface, 7 ... center part of the tube bottom, 8 ...
Tube bottom edge, 9 ... Base, 10 ... Hollow tube with bottom, 11 ...
Hydraulic chuck, 12 guide part, 13 ring-shaped elastic body, 14 pressing means, 15 hydraulic cylinder, 16 pressure rod, 17 pressure medium, 18 load cell

Claims (2)

[Claims] 1. An outer shape of a bottomed hollow tube is held by holding means, and conforms to an outer shape of the bottomed bottom tube so as to contact with only a bottom surface of the bottomed hollow tube from outside and pressurize with a predetermined force. A ceramic material which is provided coaxially with the holding means via a pressurized medium having an upper surface shape and which is pressurized coaxially with the bottomed hollow tube by a pressurizing means connected to the pressurized medium. A method for testing the bottom strength of a hollow tube with a bottom, wherein an outer diameter (dt: mm) of the pressurized medium is defined by the following relational expression (D _G : mm) A method for testing the bottom strength of a ceramic bottomed hollow tube, characterized by using two types satisfying 1) and 2). _{(1/10) D G ≦ dt ≦} (1/2) D G ... (1) (2/3) D G ≦ dt ≦ D G ... (2) 2. A holding means for holding an outer peripheral surface of a bottomed hollow tube, and a pressing means provided coaxially with the holding means, wherein the pressing means is a bottom surface of the bottomed hollow tube. A tube bottom strength testing device for a ceramic bottomed hollow tube provided with a pressurizing medium having an upper surface shape that matches the outer shape of the bottom surface for pressing with a predetermined force by contacting only from the outside, the outer diameter of the pressurizing medium (dt: mm) is the outer diameter of the bottomed hollow tube (D _G: mm) and the following equation (1) and (2) the use of two pressurized medium which satisfies A tube bottom strength testing device for ceramic bottomed hollow tubes. _{(1/10) D G ≦ dt ≦} (1/2) D G ... (1) (2/3) D G ≦ dt ≦ D G ... (2)