KR102621674B1 - All-in-one Ceramic Ball Crushing Test Device - Google Patents

Abstract

The present invention relates to an integrated ceramic ball crushing test device. More specifically, ceramic balls used in bearings, etc. can be conveniently mounted on the crushing test device regardless of their various sizes, and the fragments of the ceramic balls generated during the crushing test can be safely removed. This relates to an integrated ceramic ball crushing test device that is convenient to handle and has high safety.

Description

All-in-one Ceramic Ball Crushing Test Device}

The present invention relates to an integrated ceramic ball crushing test device. More specifically, ceramic balls used in bearings, etc. can be conveniently mounted on the crushing test device regardless of their various sizes, and the fragments of the ceramic balls generated during the crushing test can be safely removed. This relates to an integrated ceramic ball crushing test device that is convenient to handle and has high safety.

In general, a crushing test device applies a load to an object until it breaks in order to check the limit load, and measures the load at the point of destruction.

These crushing test devices are used by accredited performance testing institutes and other for-profit organizations equipped with jigs tailored to each object, and the jig has various shapes depending on the object.

Meanwhile, balls, rollers, etc. used in bearings may be made of steel or ceramic. Since bearings must support the rotating shaft while withstanding a certain load or more, crushing tests on balls, rollers, etc. used in bearings are essential.

Since the balls, rollers, etc. used in these bearings have various dimensions, jigs of various dimensions that can be used in the crushing tester are required to test them.

Additionally, there is a risk of injury to the user as fragments may scatter during crushing.

Republic of Korea Patent Publication No. 10-2520649 (Title of invention: Jig device for compression testing, Announcement date: 2023. 04. 11)

Accordingly, the present invention is intended to solve the problems of the prior art as described above, and includes an upper support shaft that transmits pressing force, a lower support shaft disposed below the upper support shaft, and an upper support each of the upper support shaft and the lower support shaft. The purpose is to provide an integrated ceramic ball crushing test device that can safely test objects of various sizes by forming a shaft groove and a lower support shaft groove.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

In order to solve the above-described problem, the present invention includes an upper support shaft that transmits a pressing force applied from the top, a lower support shaft disposed below the upper support shaft, and a lower support supporting the lower support shaft, and the upper support An upper support shaft groove in which the first ceramic ball is seated is formed on the shaft, and a lower support shaft groove in which the second ceramic ball is seated is formed in the lower support shaft at the same position perpendicular to the upper support shaft groove. A crushing test device is provided.

Additionally, here, the lower support shaft includes a fragment receiving portion that receives fragments when the first ceramic ball or the second ceramic ball is broken.

In addition, here, the upper support shaft groove and the lower support shaft groove are characterized in that they are formed in an arc shape with a certain angle.

In addition, here, the upper support shaft groove or the lower support shaft groove is characterized in that a fixing member for fixing the first ceramic ball or the second ceramic ball is provided.

In addition, here, the upper support shaft groove or the lower support shaft groove is formed by a combination of a first circular groove having a first constant angle and a first radius and a second circular groove having a second constant angle and a second radius. It is characterized by

In addition, the present invention provides that an upper support shaft groove in which the first ceramic ball is seated is formed in the upper support shaft, and a lower support shaft groove in which the second ceramic ball is seated is formed in the lower support shaft at the same position perpendicular to the upper support shaft groove. In the method of using the integrated ceramic ball crushing test device using the integrated ceramic ball crushing test device, a first ceramic ball fixing step in which the first ceramic ball is fixed to the upper support shaft groove, and the second ceramic ball is Characterized in that it includes a step of fixing a second ceramic ball fixed to the lower support shaft groove and a crushing test force measurement step of measuring the pressing force by which the first ceramic ball and the second ceramic ball are crushed by pressing the upper support shaft. Provides a method of using an integrated ceramic ball crushing test device.

According to the integrated ceramic ball crushing test device according to the present invention, the following effects are achieved.

First, when crushing ceramic balls of various sizes, there is an advantage in that the crushing test can be easily performed by changing the upper and lower support axes on which grooves of various sizes are formed.

Second, it has the advantage of allowing users to use the equipment safely due to its compact size and protective equipment.

Third, it is possible to crush various types of ceramic balls with one type of upper and lower support shaft, which has the advantage of increasing equipment efficiency and reducing unit costs.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned may be clearly understood by those skilled in the art from the description of the claims.

Figure 1 is an overall configuration diagram of an integrated ceramic ball crushing test device according to the present invention.
Figure 2 is a view of the ceramic ball of the integrated ceramic ball crushing test device according to the present invention.
Figure 3 is a detailed view of the support groove of the integrated ceramic ball crushing test device according to the present invention.
Figure 4 is a diagram showing a method of using the integrated ceramic ball crushing test device according to the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely provided to ensure that the disclosure of the present invention is complete and to be understood by those skilled in the art. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

The sizes and shapes of components shown in the drawings attached to this specification may be exaggerated for clarity and convenience of explanation. It should be noted that the same configuration may be indicated by the same reference numeral in each drawing. Additionally, detailed descriptions of the functions and configurations of known technologies that are judged to unnecessarily obscure the gist of the present invention may be omitted.

The terms used herein are used to describe specific embodiments and are not intended to limit the invention. As used herein, the singular forms include the plural forms unless the context clearly indicates otherwise. In addition, throughout this specification, when a part “includes” a certain element, this means that it may further include other elements unless specifically stated to the contrary.

When a component is said to be “connected” or “connected” to another component, it is understood that it may be directly connected to or connected to that other component, but that other components may exist in between. It should be. On the other hand, when a component is said to be “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between. Other expressions to describe relationships between components should be interpreted similarly.

Terms such as top, bottom, upper surface, lower surface, top, bottom, etc. used in this specification are used to distinguish the relative positions of components. For example, for convenience, if the upper part of the drawing is called upper and the lower part of the drawing is called lower, in reality, the upper part can be called lower, and the lower part can be called upper, without departing from the scope of the present invention. .

Terms containing ordinal numbers, such as ~first~, ~second~, etc. described in this specification may be used to describe various components, but the components are not limited by the terms. The above terms are only used to distinguish each component from another, and are not limited by the manufacturing order, and the names may not match in the detailed description and claims of the invention.

All terms, including technical or scientific terms, used in this specification have the same meaning as generally understood by those skilled in the art to which the present invention pertains, unless otherwise defined. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless clearly defined in this specification, should not be interpreted in an idealized or overly formal sense. No.

Hereinafter, the present invention will be described with reference to the drawings to describe an integrated ceramic ball crushing test device according to an embodiment of the present invention.

Figure 1 is an overall configuration diagram of the integrated ceramic ball crushing test device according to the present invention, Figure 2 is a perspective view of the ceramic ball of the integrated ceramic ball crushing test device according to the present invention, and Figure 3 is an integrated ceramic ball according to the present invention. This is a detailed view of the support groove of the crushing test device, and Figure 4 is a diagram showing a method of using the integrated ceramic ball crushing test device according to the present invention.

Referring to FIG. 1, the integrated ceramic ball crushing test device according to the present invention includes an upper support shaft 200 that transmits a pressing force from the top, and a lower support shaft 400 disposed below the upper support shaft 200. and a lower support shaft 500 supporting the lower support shaft 400, wherein an upper support shaft groove 210 in which the first ceramic ball 710 is seated is formed in the upper support shaft 200, and the lower support shaft 200 is formed in the upper support shaft 200. A lower support shaft groove 410 in which the second ceramic ball 720 is seated may be formed in 400 at the same vertical position as the upper support shaft groove 210.

The upper support shaft 200 is formed in a cylindrical shape and serves to apply a load to the first ceramic ball 710 by receiving a load pressed from the input shaft 100 disposed at the top. A pressurizing means capable of applying a load, that is, a hydraulic device or a motor, is provided on the upper part of the input shaft 100, and the load can be increased by a certain amount at certain times.

An upper support shaft groove 210 capable of holding the first ceramic ball 710 may be formed in the upper support shaft 200. The upper support shaft groove 210 is preferably formed to fit the shape of the first ceramic ball 710, and may be formed in a conical or hemispherical shape. As will be described later, the size of the upper support shaft groove 210 (or the lower support shaft groove 410, described later) can be determined by the angle and height of the cone in the case of a cone shape, and the angle of the radius and arc in the case of a semicircular shape.

The lower support shaft 400 may be provided on the same vertical line as the upper support shaft 200. The lower support shaft 400 may be provided with the same size and shape as the upper support shaft 200, and may be arranged in the opposite direction. Accordingly, the lower support shaft groove 410 formed in the lower support shaft 400 may be formed in the same shape as the upper support shaft groove 210.

A second ceramic ball 720 may be mounted in the lower support shaft groove 410, and the first ceramic ball 710 and the second ceramic ball 720 are preferably disposed on the same vertical line. The load applied from the upper support shaft 200 is applied to each of the first ceramic ball 710 and the second ceramic ball 720, and when the limit load is reached, the first ceramic ball 710 ) and/or the second ceramic ball 720 is destroyed. The load at this time is recorded, and the limit load of the produced ceramic ball is confirmed.

A lower support 500 may be provided below the lower support shaft 400 to support the lower support shaft 400. The lower pedestal 500 may be formed with a lower pedestal groove 510 whose size corresponds to the diameter of the lower support shaft 400. The lower support shaft 510 is formed at a certain depth and can fix the lower support shaft 400 so that it does not bend or twist even when the lower support shaft 400 receives a certain load.

Meanwhile, a housing 300 that accommodates a portion of the upper support shaft 200 and the lower support shaft 400 may be provided. The housing 300 has an upper and lower portion corresponding to the diameters of the upper support shaft 200 and the lower support shaft 400 so that the upper support shaft 200 and the lower support shaft 400 can penetrate upward and downward, respectively. A through hole (not shown) may be formed.

Meanwhile, a confirmation window 310 may be provided on the side of the housing 300 to visually confirm that the first and second ceramic balls 700 are broken. The confirmation window 310 is formed of transparent reinforced plastic, etc., so that the progress of the crushing test can be checked with the naked eye, and it can prevent fragments generated when the ceramic ball 700 is broken from scattering. In addition, although not shown, a camera (not shown) is placed outside the confirmation window 310 to capture the phenomenon during the crush test. In particular, it is connected to the controller of the crushing test device and can record a certain amount of time before and after the moment the ceramic ball 700 is destroyed. Additionally, it can be confirmed with the camera whether the ceramic ball 700 is mounted in the correct position. That is, through image recognition, it is possible to check through the image whether the ceramic ball 700 is placed in the correct position on the vertical line, and a warning can be issued if it is misaligned by more than a certain angle.

Meanwhile, when the ceramic ball 700 is deformed below a certain shape, the degree of deformation can be measured through the camera. In other words, the ceramic ball 700 may maintain its original shape and then deform before reaching the limit load. Therefore, when it is detected that the ceramic ball 700 is deformed to a diameter greater than a certain displacement or a spherical shape less than a certain roundness, an alarm can be given in advance.

Additionally, the lower support shaft 400 may include a fragment receiving portion 420 that receives fragments when the first ceramic ball 710 or the second ceramic ball 720 is broken.

The fragment receiving portion 420 may be formed on the lower support shaft 400, and a lower support shaft through hole (not shown) may be formed in the center to allow the lower support shaft 400 to be inserted. In addition, a stopper (not shown) capable of supporting the fragment receiving portion 420 is formed on the lower support shaft 400 to protrude or is formed in the form of a pin to penetrate the lower support shaft 400 in the radial direction. can be formed.

The fragment receiving portion 420 may be provided with a collection portion (not shown) protruding from an edge to collect fragments when the ceramic ball 700 is broken. Preferably, the debris receiving part 420 may be in the shape of a circular dish, and the collection part may be formed in a cylindrical shape.

Referring to FIG. 2, the upper support shaft groove 210 and the lower support shaft groove 410 may be formed in an arc shape at a certain angle. That is, it can be formed in an arc-shaped hemisphere with a certain angle.

The arc shape of the constant angle is determined according to the size of the ceramic ball 700 to be mounted, and when viewed in the longitudinal direction of the upper support shaft groove 210 and the lower support shaft groove 410, the depth C is determined by the ceramic ball 700. It is long enough to safely hold (700). Preferably, in order to safely hold the ceramic ball 700 so that it does not fall off, the ceramic ball 700 may be formed to have a size of 25% to 45% of the diameter of the ceramic ball 700.

The upper support shaft groove 210 and the lower support shaft groove 410 can be formed in various sizes depending on the size of the ceramic ball 700 to be tested, and accordingly, various types of upper support shaft 200 and lower support shaft are used. The axis 400 can be prepared.

Meanwhile, the upper support shaft groove 210 and the lower support shaft groove 410 may be formed in a cone shape, and the depth of the cone shape may be formed to be between 25% and 45% of the diameter of the ceramic ball 700. . When formed in a conical shape, ceramic balls 700 of various diameters can be mounted in one support shaft groove. That is, if the size of the ceramic ball is very small and the depth of the cone is larger than the radius of the ceramic ball (exceeding 50% of the diameter), or if the size of the ceramic ball is very large and the depth of the cone is less than 10% of the diameter of the ceramic ball. The ceramic ball cannot be placed in a cone shape. To be precise, mounting is possible only when a contact point can be created between the ceramic ball and the cone-shaped surface. In other words, it is determined according to the diameter of the ceramic ball and the cone angle and depth of the cone, and can be used up to the extent that a contact point is created.

Referring again to FIG. 2, the upper support shaft groove 210 or the lower support shaft groove 410 is provided with a fixing member 600 for fixing the first ceramic ball 710 or the second ceramic ball 720. It can be.

The fixing material 600 serves to fix the ceramic ball 700 so that it does not move when assembling the crushing test device. Preferably, oil such as grease is preferable, and it can be an adhesive adhesive, or a material with an adhesive component that can be easily fixed, such as double-sided tape, can also be used.

Referring to FIG. 3, the upper support shaft groove 210 or the lower support shaft groove 410 includes a first circular groove 430 and a second constant angle having a first constant angle θ1 and a first radius R1. It may be formed by a combination of a second circular groove 440 having an angle θ2 and a second radius R2.

The first constant angle θ1 may be equal to the second constant angle θ2, and the first radius R1 may be smaller than the second radius R2. If the first constant angle and the second constant angle are the same, the number of ceramic balls that can be mounted can be the same, which has an advantage in manufacturing and makes it easy to determine the range of use. That is, in the case of ceramic balls, the dimensions are numbered. For example, No. 1 and No. 2 can be placed in the first circular groove 430 with a first constant angle, and No. 3 and No. 4 can be placed in the second circular groove 430. If mounting is possible on the second circular groove 440 having a certain angle, the number of ceramic balls that can be used in one support shaft groove is derived. If the second constant angle is smaller than the first constant angle, No. 1 and No. 2 can be used in the first circular groove, and only No. 3 can be used in the second circular groove.

As shown in (b) of FIG. 3, both the small-diameter ceramic ball B1 and the large-diameter ceramic ball B2 can be placed in one support shaft groove, and as described above, the first radius R1 and the first constant Since small-diameter ceramic balls B1 of various sizes can be mounted in the first circular groove 430 having an angle θ1, various types of ceramic balls can be tested in one support shaft groove. That is, the small-diameter ceramic ball B1 that can be placed in the first circular groove 430 can be used as long as its radius is smaller than the depth of the first circular groove 430. Of course, it is preferable that both the small-diameter and large-diameter ceramic balls have a radius larger than the combined depth (Cmax) of the first arcuate groove 430 and the second arcuate groove 440.

Two or more circular grooves may be formed. In other words, two or more ceramic balls of almost any size can be tested in one support shaft groove, so that numbers 1 to 10 can be tested in one support shaft groove.

In the method of using the integrated ceramic ball crushing test device according to an embodiment of the present invention, an upper support shaft groove 210 in which the first ceramic ball 710 is seated is formed on the upper support shaft 200, and the lower support shaft 400 is formed. An integrated ceramic ball crushing test using an integrated ceramic ball crushing test device, characterized in that a lower support shaft groove 410 in which the second ceramic ball 720 is seated is formed at the same vertical position as the upper support shaft groove 210. In the method of using the device, a first ceramic ball fixing step (S100) in which the first ceramic ball 710 is fixed to the upper support shaft groove 210, and the second ceramic ball 720 is fixed to the lower support shaft groove ( A second ceramic ball fixing step (S200) fixed to 410) and a crushing process that measures the pressing force that crushes the first ceramic ball 710 and the second ceramic ball 720 by pressing the upper support shaft 200. It may include a test force measurement step (S300).

Referring to FIG. 4, a method of replacing the upper and lower support shafts suitable for the size of the ceramic balls of the integrated ceramic ball crushing test device according to the present invention will be described as follows.

Referring to (a) of FIG. 4, first prepare the lower pedestal 500 and connect the lower support shaft 400 to the lower pedestal 500. A fixing material 600 is applied to the lower support shaft groove 410 formed on the upper part of the lower support shaft 400. The second ceramic ball 720 is placed on the applied fixing material 600.

Referring to (b) of FIG. 4, the housing 300 is then fixed to the lower pedestal 500. Referring to (c) of FIG. 4, a fixing material 600 is applied to the upper support shaft groove 210 formed in the upper support shaft 200, and the first ceramic ball 710 is mounted. At this time, since there is a possibility that the first ceramic ball 710 may separate downward due to gravity, the fixing material 600 is maintained above a certain viscosity using grease or adhesive to prevent the ceramic ball from falling. Thereafter, the upper support shaft 200 is inserted through the through hole of the housing 300 with the first ceramic ball 710 mounted thereon.

Referring to (d) of FIG. 4, the upper support shaft 200 and the lower support shaft 400 are arranged to exactly coincide on a vertical line by the through hole of the housing 300. Referring to (e) of FIG. 4, the input shaft 100 that transmits the pressing force is fixed by inserting it into the upper support shaft 200. Afterwards, a load is applied by a pressurizing means (hydraulic device or motor) disposed on the upper part of the input shaft 100.

In order to respond to the dimensions of various ceramic balls, the upper support shaft groove 210 and the lower support shaft groove 410 formed on the upper support shaft 200 and the lower support shaft 400 are exchanged for upper and lower support shafts of different sizes. All you have to do is do it. In other words, in order to test a ceramic ball of a different size after the test is completed, disassemble it in the reverse order of the above order, and when reassembling, change the upper and lower support shafts to different ones.

For example, as described above, Nos. 1 to 4 are possible with one upper support shaft and one lower support shaft, so only the fragments can be recovered and the ceramic ball mounted again for testing. Afterwards, Nos. 5 to 8 can be tested by changing to other upper and lower support axes.

As described above, preferred embodiments of the present invention have been shown and described with reference to the drawings, but the present invention is not limited to the specific embodiments described above, and the present invention is not limited to the above-described specific embodiments, and the present invention can be modified without departing from the gist of the present invention as claimed in the patent claims. Of course, various modifications can be made by those skilled in the art in the technical field to which the invention belongs, and these modifications should not be understood individually from the technical idea or perspective of the present invention.

The present invention relates to an integrated ceramic ball crushing test device and can be used in manufacturing industries, etc.

100: input shaft
200: upper support shaft
210: Upper support shaft groove
300: housing
400: lower support shaft
410: Lower support shaft groove
420: fragment receiving unit
430: 1st circular groove
440: 2nd circular groove
500: lower stand
510: Lower pedestal groove
600: Fixing material
700: Ceramic ball
710: first ceramic ball
720: Second ceramic ball

Claims (5)

An upper support shaft that transmits pressing force from the top;
a lower support shaft disposed below the upper support shaft; and
It includes a lower support supporting the lower support shaft,
An upper support shaft groove in which a first ceramic ball is seated is formed in the upper support shaft, and a lower support shaft groove in which a second ceramic ball is seated is formed in the lower support shaft at the same vertical position as the upper support shaft groove,
The upper support shaft groove or the lower support shaft groove,
An integrated ceramic ball crushing test device, characterized in that it is formed by a combination of a first circular groove having a first constant angle and a first radius and a second circular groove having a second constant angle and a second radius. According to paragraph 1,
The lower support shaft is an integrated ceramic ball crushing test device characterized in that it includes a fragment receiving portion that receives fragments when the first ceramic ball or the second ceramic ball is broken. delete According to paragraph 1,
An integrated ceramic ball crushing test device, characterized in that the upper support shaft groove or the lower support shaft groove is provided with a fixing material for fixing the first ceramic ball or the second ceramic ball. An upper support shaft groove in which the first ceramic ball is seated is formed in the upper support shaft, and a lower support shaft groove in which the second ceramic ball is seated is formed in the lower support shaft at the same position perpendicular to the upper support shaft groove, wherein the upper support shaft groove or The lower support shaft groove is an integrated ceramic ball crushing test device, characterized in that it is formed by a combination of a first circular groove having a first constant angle and a first radius and a second circular groove having a second constant angle and a second radius. In the method of using an integrated ceramic ball crushing test device,
A first ceramic ball fixing step in which the first ceramic ball is fixed to the upper support shaft groove;
A second ceramic ball fixing step in which the second ceramic ball is fixed to the lower support shaft groove; and
A method of using an integrated ceramic ball crushing test device, comprising a crushing test force measurement step of measuring a pressing force by which the first ceramic ball and the second ceramic ball are crushed by pressing the upper support shaft.