JPH0577755U - Ceramic push rod fixture - Google Patents

Abstract

(57) [Abstract] [Purpose] A ceramic push rod fixing jig that eliminates rattling at the joint between the ceramic push rod and metal push rod due to temperature changes and can be applied to material tests of ceramics, metals, etc. in high temperature environments. I will provide a. [Structure] A load is applied to a test piece exposed to a high temperature environment via a ceramic push rod 16. The load is transmitted to the ceramic push rod 16 that abuts the metal push rod 15 as the metal push rod 15 descends. The pair of semi-circular metal collets 34 fitted into the annular recess 33 of the ceramic push rod 16 are locked by the protrusions 37 of the metal fixing jig 36. The female screw portion 39 of the metal fixing jig 36 is screwed to the male screw portion 30 of the metal push rod 15. Thereby, due to the interposition of the metal collet 34, there is no gap in the contact surface between the ceramic push rod 16 and the metal push rod 15,
Further, the ceramic push rod 16 and the metal push rod 15 can be firmly fixed to each other without generating an excessive stress on the ceramic push rod 16.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a ceramic push rod fixing jig used for testing materials such as ceramics and metals, and particularly to a ceramic push rod fixing jig applicable in a high temperature environment.

[0002]

[Prior Art]

 Generally, a test apparatus used for a bending strength test, a compressive strength test and the like applies a load to a test piece via a push rod. In the high temperature test, since the push rod is exposed to a high temperature environment, this push rod is composed of high temperature structural ceramics, and the metal push rod that applies a load to this ceramic push rod is cooled by cooling water.

[0003]

[Problems to be solved by the device]

 Such a connection between the conventional ceramic push rod and the metal push rod is performed by locking the protrusion 3a of the metal fixing jig 3 to the flange portion 1a of the ceramic push rod 1 as shown in FIG. The metal fixing jig 3 and the metal push rod 4 are coupled and fixed by the female screw portion 3b and the male screw portion 4a. Since the ceramic push rod 1 is exposed to a high temperature, the metal fixing jig 3 and the metal push rod 4 are heated to a high temperature due to the heat transfer action. Since there is a difference between the coefficient of thermal expansion of the ceramic push rod 1 and the coefficient of thermal expansion of the metal fixing jig 3 and the metal push rod 4, when fixed at room temperature, the metal push rod 4 has a difference in thermal expansion at high temperature. A gap is generated between the and the ceramic push rod 1 and rattling is likely to occur. For this reason, the flange portion 1a is liable to be partially damaged or the entire member is damaged due to an impact when the test piece is broken. Also, if a partially broken piece enters between the metal push rod 4 and the ceramic push rod 1, the ceramic push rod 1 will give an eccentric load to the test piece, and the measured values will be uneven (non-uniform). There is a problem that it easily occurs. Further, when fixed at high temperature, excessive stress is applied to the flange portion 1a due to the difference in thermal expansion at low temperature, and the flange portion 1a is likely to be damaged. Further, the protrusion 3a of the metal fixing jig 3 is locked to the flange portion 1a of the flange 1a of the ceramic push rod 1 of the fixing jig shown in FIG. In some cases, the thermal insulation deteriorates due to the impact when the test piece breaks, the repeated load on the test piece and the repeated load due to the difference in thermal expansion, and rattling is likely to occur as in the case without the thermal insulation material.

The present invention has been made in order to solve such a problem, and eliminates rattling of the connecting portion between the ceramic push rod and the metal push rod and the load of excessive stress, and the destruction of the ceramic push rod. It is an object of the present invention to provide a ceramics push-rod fixing jig capable of performing highly accurate measurement with less occurrence of occurrence.

[0005]

[Means for Solving the Problems]

 A ceramic push rod fixing jig according to a first aspect of the present invention for solving the above problems is a jig for fixing a ceramic push rod to a metal push rod, the jig being made of metal having a surface that comes into contact with an end face of the ceramic push rod. A push rod and a ceramic push rod that is in contact with the abutting surface and has a recess or flange in the outer peripheral portion near the end face, and the recess or flange is locked from the face opposite to the end face, and is joined to the metal push rod. A metal fixing jig that can be fixed is characterized by including a locking portion that projects toward the end surface of the ceramic push rod.

The ceramic push-rod fixing jig according to the second aspect of the present invention is characterized in that the protruding fixing portion of the metallic fixing jig and the portion excluding the protruding locking portion are separate bodies. It The ceramic push-rod fixing jig according to the third aspect of the present invention is characterized in that the protruding locking portion of the separate body is a metal having a larger thermal expansion than the portion excluding the protruding locking portion.

[0007]

[Action]

 According to the ceramic push rod fixing jig, the ceramic push rod and the metal push rod are fixed to each other from the surface opposite to the contact surface between the ceramic push rod and the metal push rod to the metal having the protrusion in the direction of the contact surface. Since the heat is transferred from the ceramic push rod to the entire metal fixing jig through the protrusions, the thermal expansion of the protrusions, which become high in temperature, is large. The thermal expansion of metal fixing jigs other than the protrusion is smaller than that of the protrusion. Due to this difference in thermal expansion, no gap is formed between the ceramic push rod and the metal push rod even when the push rod is fixed at room temperature or high temperature, and no excessive stress is generated. Therefore, from room temperature to high temperature, the ceramic push rod can be firmly fixed to the metal push rod without damage.

[0008]

【Example】

 Embodiments of the present invention will be described below with reference to the drawings. The first embodiment of the present invention used for the bending strength test is shown in FIGS. As shown in FIG. 2, in the bending strength test apparatus 10, a crosshead 13 is vertically movable inside a load frame 12 forming a frame, and a load cell 14 is attached to the bottom surface of the crosshead 13. ing. The load cell 14 is a device that detects an applied load. A metal push rod 15 is fixed to the lower portion of the load cell 14, and a cooling device 17 using cooling water is attached to the metal push rod 15. A ceramic push rod 16 is fixed to the bottom of the metal push rod 15 by the structure shown in FIG. 1 as described later.

On the other hand, a metal push rod 21 is also fixed to the floor surface 20 supporting the load frame 12 shown in FIG. 2, and a cooling device 22 using cooling water is attached to the metal push rod 21. A ceramic push rod 23 is fixed to the upper portion of the metal push rod 21 by a structure shown in FIG. 4 as described later. A jig 25 having a bending strength test piece 24 set thereon is mounted on the ceramic push rod 23 in a testable state. The controller 44 adjusts the load applied to the test piece 24 and calculates the load signal detected by the load cell 14.

The ceramic push rod 16 and the metal push rod 15 are fixed by the configuration shown in FIG. A male screw portion 30 is formed on the outer peripheral surface of the metal push rod 15, and a cut-out circular concave portion 32 is formed on the bottom surface. An annular recess 33 is formed near the top of the ceramic push bar 16. As shown in the plan view of FIG. 3, the metal collet 34 has a pair of semi-arcuate shapes, and these are fitted in the annular recess 33 as shown in FIG. The radial thickness t of the metal collet 34 is sufficiently thicker than the depth d of the annular recess 33.

The fixing jig 36 has a cylindrical shape made of metal, and has an annular projecting portion 37 that projects radially inward at the bottom thereof, and the inner top wall 37 a of this projecting portion 37 is the bottom surface of the metal collet. 34 a. The female screw portion 39 formed on the inner peripheral wall of the fixing jig 36 is coupled and fixed to the male screw portion 30 formed on the outer peripheral portion of the metal push rod 15. As a result, the protrusion 37, the metal collet 34, the annular recess 33, the ceramic push rod 16, and the metal push rod 15 are fastened and fixed. The metal collet 34 becomes a protrusion of the fixing jig 36 which is a separate body.

The ceramic push rod 23 and the metal push rod 21 are fixed by the structure shown in FIG. The protrusion 26a of the metal fixing jig 26 is locked to the flange portion 23a of the ceramic push rod 23, and the metal fixing jig 26 and the metal push rod 21 are coupled and fixed by the female screw 26b and the male screw 21a. ing. According to the above-mentioned embodiment, when the temperature is changed from the room temperature to the high temperature, the difference in expansion of each member occurs due to the temperature difference due to the heat transfer of each member. In this case, compared with the expansion of the ceramic push rods 16 and 23, The metal push rods 15, 21, which are made of the same metal material, the metal collet 34, and the fixing jigs 26, 36 have relatively large elongations. In the structure shown in FIG. 1, the thermal expansion of the metal collet 34, which is directly transferred from the ceramic push rod 16 and has a high temperature, causes a large thermal expansion of the ceramic push rod 16 in the axial direction. Since the metal fixing jig 36 that indirectly transfers heat from the ceramic push rod has a small thermal expansion, the axial extension is small and the bottom surface 32a of the recess 32 of the metal push rod 15 and the top surface 16a of the ceramic push rod 16 are Since there is no gap between them, the ceramic push rod 16 and the metal push rod 15 are firmly fixed even at high temperature. In the structure shown in FIG. 4 as well, the expansion of the protrusion 26a in the axial direction is large due to the difference in thermal expansion, the expansion of the metal fixing jig 24 excluding the protrusion 24a in the axial direction is small, and the recess 27 of the metal push rod 21 is reduced. Since there is no gap between the top surface 27a of the ceramic push rod 23 and the bottom surface 23b of the ceramic push rod 23, the ceramic push rod 23 and the metal push rod 21 are firmly fixed even at high temperatures.

Therefore, there is no rattling or breakage of the ceramic push rod due to repeated heating / cooling of the heating furnace, load during the test, and impact at the time of breaking the test piece, and the test can always be performed in a good condition. In addition, since there is no rattling at high temperature, it is not necessary to tighten at high temperature, but even when tightened, the ceramic push rod does not generate excessive stress at room temperature due to the difference in axial expansion due to the difference in thermal expansion, and it is firm. Can be fixed.

Comparative Examples 1, 2 and 3 for comparison with the first embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 5, Comparative Example 1 is an example in which the ceramic-made push rod 1 is held by the metal fixing jig 3 and the metal push rod 4. The protrusion 3a of the metal fixing jig 3 is locked to the flange portion 1a of the ceramic push rod 1, and the metal fixing jig 3 and the metal push rod 4 are coupled and fixed by the female screw portion 3b and the male screw portion 4a. is doing. Since the ceramic push rod 1 is exposed to a high temperature, the metal fixing jig 3 and the metal push rod 4 are heated to a high temperature by the heat transfer action. Since there is a difference between the coefficient of thermal expansion of the ceramic push rod 1 and the coefficient of thermal expansion of the metal fixing jig 3 and the metal push rod 4, when fixed at room temperature, the metal push rod 4 has a difference in thermal expansion at high temperature. A gap is generated between the ceramic push rod 1 and the ceramic push rod 1 and rattling easily occurs. Therefore, the impact at the time of breaking the test piece is likely to cause partial damage to the flange portion 1a or the entire damage. Moreover, when the partially broken pieces enter between the metal push rod 4 and the ceramic push rod 1, the ceramic push rod 1 gives an eccentric load to the test piece, and the measured values are not uniform (non-uniform). There is a problem that it easily occurs. Further, when fixed at a high temperature, there is a drawback that the flange portion 1a is likely to be damaged due to excessive stress being applied to the flange portion 1a due to a difference in thermal expansion at a low temperature.

As shown in FIG. 6, Comparative Example 2 is an example in which a heat insulating material 2 is interposed between the flange portion 1 a of Comparative Example 1 and the protruding portion 3 a of the metal fixing jig 3. In this comparative example 2, heat is hardly transferred from the ceramic push rod 1 to the metal fixing jig 3 by the heat insulating material 2 and a difference in thermal expansion is unlikely to occur, but impact at the time of breakage of the test piece and repeated negative load on the test piece. There is a drawback in that the heat insulating material deteriorates due to repeated loads due to load and thermal expansion difference, and rattling is likely to occur as in the case without the heat insulating material.

Comparative Example 3 is an example in which the metal push rod 4 and the ceramic push rod 1 are fixed by a screw 52, as shown in FIG. The screw 52 inserts the screw hole 53 from the outside of the metal push rod 4 to tighten the recess 54 of the ceramic push rod 1. Thereby, the ceramic push rod 1 and the metal push rod 4 are fastened. In Comparative Example 3, when the ceramic push rod 1 was exposed to a high temperature, heat was transferred to the metal push rod 4 and the screw 52, and the coefficient of thermal expansion of the metal push rod 4 and the screw 52 and the ceramic push rod 1 were compared. Due to the difference in the coefficient of thermal expansion, the difference in expansion becomes significant, and there is a drawback that rattling easily occurs between the ceramic push rod 1 and the metal push rod 4. Further, when the screw 52 is tightened at a high temperature, the ceramic push rod 1 is excessively stressed due to the difference in thermal expansion, and the ceramic push rod 1 is easily broken.

On the other hand, in the above-mentioned embodiment, the above-mentioned drawbacks are not present, and the fixing of the ceramic push rod 16 and the metal push rod 15 is not greatly affected by the temperature change due to the interposition of the protrusion 24a and the metal collet 34. Therefore, the ceramic push rod 16 is firmly fixed to the metal push rod 15 in any temperature environment.

Therefore, since a uniform load is applied to the test piece 24 by the ceramic push rod 16 via the jig 25 shown in FIG. 2, the bending strength test can always be performed in a good condition. In the above embodiment, the metal collet 34 is made of the same material as the metal fixing jig 36, but it is preferable that the metal collet 34 is made of a material having a larger thermal expansion than the metal fixing jig 36. By making the metal collet 34 with a material having a large thermal expansion, the metal collet 34 can be more firmly fixed as compared with the case where it is made of the same material. Also, the jig can be downsized in consideration of the difference in thermal expansion.

The material of the ceramic push rod may be a known high-temperature structural ceramic such as silicon carbide, silicon nitride, or mullite depending on the test. Further, as the material of the metal push rod, the fixing jig, and the like, known materials such as stainless steel and heat resistant steel may be used depending on the test. Although the present invention is applied to the high temperature bending strength tester in the above-mentioned embodiment, it is needless to say that the present invention can be applied to a room temperature or low temperature bending strength tester. Further, it can be used not only for bending strength test but also for compression test, repeated fatigue test and the like.

[0020]

[Effect of the device]

 As described above, according to the ceramic push-rod fixing jig of the present invention, since the coupling of the push-rod fastening portion can be maintained firmly from low temperature to high temperature at all times, the ceramic-made push rod is less likely to be broken and eccentric. The effect is that an appropriate load can be applied without applying a load.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a connecting portion between a ceramic push rod and a metal push rod according to a first embodiment of the present invention.

FIG. 2 is a schematic configuration diagram showing a bending strength test apparatus using a ceramic push rod fixing jig according to a first embodiment of the present invention.

FIG. 3 is a plan view showing a metal collet according to a first embodiment of the present invention.

FIG. 4 is a schematic configuration diagram showing a connecting portion between a ceramic push rod and a metal push rod according to the first embodiment of the present invention.

5 is a schematic configuration diagram showing a connecting portion between a ceramic push rod and a metal push rod according to Comparative Example 1. FIG.

FIG. 6 is a schematic configuration diagram showing a connecting portion between a ceramic push rod and a metal push rod according to Comparative Example 2.

FIG. 7 is a schematic configuration diagram showing a connecting portion between a ceramic push rod and a metal push rod according to Comparative Example 3.

[Explanation of symbols]

 15 metal push rod 16 ceramic push rod 16a top surface 30 male screw portion 32a bottom surface 33 annular recess 34 metal collet 36 fixing jig (metal fixing jig) 39 female screw portion

Claims (3)

[Scope of utility model registration request] 1. A jig for fixing a ceramic push rod to a metal push rod, comprising: a metal push rod having a surface in contact with an end face of the ceramic push rod; and an outer peripheral portion in contact with the contact face and near the end face. A ceramic push rod having a concave portion or a flange portion on the end surface of the ceramic push rod, wherein the concave portion or the flange portion is locked from the surface opposite to the end surface, and the metal fixing jig can be coupled and fixed to the metal push rod. A fixing jig for a push rod made of ceramics, characterized in that it has a locking portion that projects in the direction of. 2. The ceramic push-rod fixing jig according to claim 1, wherein a protruding locking portion of the metal fixing jig and a portion excluding the protruding locking portion are separate bodies. 3. The ceramic push-rod fixing jig according to claim 2, wherein the separate protruding locking portion is made of a metal having a larger thermal expansion than the portion excluding the protruding locking portion.