JPH0843284A - Impact strength measuring apparatus for pottery - Google Patents

Abstract

PURPOSE:To provide an impact strength measuring apparatus which can measure a practical strength of each pottery product. CONSTITUTION:A pottery 44 fixed by a pottery fixing unit 12 is moved in a predetermined direction toward the unit 12, and an arbitrary impact force is applied to a part of the pottery with a steel ball 74. In this case, since the collision position and angle to the pottery 44 with the ball 74 are regulated by a relative position regulating means, the impact strengths when the impact is applied in various direction to the parts of the pottery 44 can be measured. Accordingly, the impact strengths to the parts of the pottery 44 can be measured for each pottery product to obtain the lowest strength, i.e., practical strength for every pottery product.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring impact strength such as chip strength and break strength of ceramics.

[0002]

2. Description of the Related Art Ceramics have a problem in that they are apt to be chipped (broken) at the peripheral edge and easily damaged when they are subjected to impacts due to work mistakes or drops during use. For example, when using it, it may come into contact with other tableware and may be cut off,
Alternatively, it may be damaged by being dropped on the floor. Therefore, in ceramic products made of these brittle materials,
The product is subjected to an impact resistance test in advance, and the impact strength such as chip strength and breakage strength is measured to determine whether or not it can withstand the impact expected to be received during use.

[0003]

For example, as an impact resistance test of ceramic tableware, the American Society for Testing Materials (American Society)
for Testing and Materials: ASTM) C368-8
The method specified in 8 is generally used. According to this method, the tableware is fixed in a horizontal or vertical position by using a V block or a positioning arm, and a rigid pendulum having a hammer fixed at one end is turned toward the tableware from a predetermined angle with the other end as a rotation center. By swinging it down, the hammer collides with the edge of the horizontally fixed tableware or the center of the bottom of the vertically fixed tableware so that the impact is applied in the horizontal direction. At this time, since the impact force given to the tableware is determined by the angle at which the hammer is swung down, the hammer is swung down from a low angle to a high angle, and the test is performed while changing the angle from a low angle to a high angle. The chip strength is measured from the angle at which the edge of the tableware is chipped, and the damage strength is measured from the angle at which the vertically fixed tableware is damaged (in this test, it is usually called impact strength. ) Are determined respectively.

However, there are various shapes of tableware, and the portion showing low strength differs depending on the shape of each product, and the direction of impact, that is, the angle at which the edge hits, the direction in which it falls when dropped, etc. are constant. do not do. On the other hand, the above-mentioned impact resistance test method is the one that uniquely defines the test method, and regardless of the shape of the tableware, especially the shape around the edge, the chip strength is always applied to the edge from the horizontal direction. Since tested, the minimum strength of the tableware is not always obtained. Therefore, even if an impact lower than the chip strength obtained by the test is applied, chipping easily occurs depending on the shape of the tableware. That is, although the tableware users and the like required the minimum strength at which breakage or chipping could occur, such practical strength could not be obtained by the above test method.

The present invention has been made in view of the above circumstances, and an object thereof is to provide an impact strength measuring device capable of measuring the practical strength of each ceramic product.

[0006]

In order to achieve such an object, the gist of the present invention is a device for measuring the impact strength of a ceramic, which comprises (a) a ceramic fixing means for fixing the ceramic. , (B) an impact force imparting means for imparting an arbitrary impact force to a part of the ceramics fixed to the ceramics fixing means by moving the collision body toward the ceramics fixing means from a certain direction, and (c) ) Relative position adjusting means for adjusting the collision position and angle of the ceramics fixed to the ceramics fixing means by the collision body.

[0007]

According to this structure, the ceramics fixed by the ceramics fixing means can exert an arbitrary impact force on a part of the ceramics by the collision body which is moved toward the ceramics fixing means from a certain direction. Given. At this time, since the relative position adjusting means adjusts the collision position and the angle of the collision body of the ceramics, it is possible to measure the impact strength when the impact is applied from various directions on each part of the ceramics. Therefore, by measuring the impact strength of each part for each ceramic product in this manner, the minimum strength for each ceramic product, that is, the practical strength can be obtained.

Here, preferably, the above-mentioned apparatus for measuring the impact strength of a ceramic is (a) a vibration detecting means which is provided in the vicinity of the ceramic and detects vibration generated around the ceramic, and (b)
A crack determination means for determining the occurrence of a crack in the ceramic from the vibration detected by the vibration detection means,
It is also included. By doing so, since the generation of minute cracks in the ceramic which is difficult to detect with the naked eye is surely detected, the strength of the ceramic can be measured more accurately.

Further preferably, the above-mentioned apparatus for measuring impact strength of ceramics comprises: (a) setting the impact force applied to the ceramics by the collision body, and colliding the impact force at a predetermined interval. Impact force setting means that increases sequentially for each,
(b) Impact strength determining means for determining the impact force when the crack determining means determines that a crack has occurred as the impact strength of the ceramics. By doing so, it is possible to automatically measure the impact strength of the ceramic at a predetermined collision position and angle.

Preferably, the impact strength measuring device for a ceramic porcelain comprises: (a) a wire or an elongated rod-shaped arm in which one end of the impacting body is rotatably mounted above the porcelain around the one end. By being attached to the other end and dropping the collision body from a state in which the arm is rotated by a predetermined angle around the one end from the vertical direction,
The spherical body is made to collide with a ceramic, and the relative position adjusting means is (b) an angle adjustment for adjusting the inclination angle of the ceramic by rotating the ceramic fixing means around a predetermined rotation axis. Means, (c) the collision body, so as to be collided with the intended portion of the ceramics, vertical position adjusting means for adjusting the vertical relative position of the collision body and the ceramics, (d) the In order for the colliding body to collide with the ceramic in a state where the arm is in the vertical direction,
The horizontal position adjusting means for adjusting the relative position of the collision body and the ceramic in the horizontal direction is included.

According to this structure, the impact force when the colliding body collides with the ceramics can be easily changed by changing the rotation angle of the arm from the vertical direction. On the other hand, the inclination angle of the ceramic is adjusted to an arbitrary angle by the angle adjusting means, and the vertical relative position between the ceramic and the colliding body is adjusted by the vertical position adjusting means, so that the ceramic is placed at an arbitrary position. It is possible to apply an impact force by a collision body at an arbitrary incident angle. At this time, the inclination angle of the ceramics is changed by rotating the ceramics fixing means around a predetermined rotation axis, so that the relative distance between the collision body and the ceramics changes according to the rotation angle, or Even if the vertical relative position is changed to change the collision position, the relative distance between the collision position and the collision body changes, but the horizontal position adjustment means adjusts the horizontal direction between the collision body and the ceramic. By changing the relative position,
The collision occurs at a position where the arm is in the vertical direction.
For this reason, the direction of the velocity of the collision body at the time of collision is always horizontal, and the direction of the impact force applied to the ceramic is determined only by the inclination angle of the ceramic, and when the rotation angle of the arm is the same. Since the head of the collision body becomes constant, the impact force applied to the ceramics is determined only by the rotation angle of the arm.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. 1 and 2 are front and side views of an impact strength measuring device 10 according to an embodiment of the present invention. The impact strength measuring device 10 includes a ceramics fixing device 12, an impact force applying device 14 corresponding to an impact force applying means, and a control device 1.
6 is provided.

The pottery fixing device 12 is provided with a pair of bearings 24 and 2 each having two legs 18 and 18 and having a bearing hole 20 formed at the center of the upper portion and fixed on a base 22.
4, a discontinuous portion is provided on one side to form a substantially rectangular shape as a whole, and a pair of protrusions 28 projecting toward the other side 26 parallel to the one side at both ends of the discontinuous portion on the one side. 28
And a nut 30 is provided at an intermediate portion of the other side 26, and a pair of rotating shafts 34, 3 is provided at an intermediate portion of a pair of parallel sides 32, 32 different from the one side and the other side 26.
4 is provided with a ceramics fixed frame 36. The nut 30 has a pedestal 38 fixed to one end on the side of the protrusions 28, 28 and a bolt 42 provided with a handle 40 on the other end. The bolt 42 is screwed into the nut 30 to rotate the handle 40. The table 38 is brought closer to the protrusions 28, 28 to hold and fix the ceramics 44, or the ceramics 44 are separated and removed. That is, in the present embodiment, the ceramic fixing frame 36, the pedestal 38, the handle 40,
And the bolt 42 corresponds to the ceramics fixing means.

Further, the rotary shafts 34, 3 of the ceramics fixed frame 36
On one of the pair of sides 32, 32 provided with 4,
An angle changing arm 46 is integrally provided on the other side 26 side. At the tip of the angle changing arm 46, an angle changing guide 48 provided between the pair of leg portions 18, 18 of the bearing 24 is provided with a bearing hole 20 having a curvature substantially over the entire surface between the leg portions 18, 18. Guide hole 50 formed in an arc shape as the center
A bolt 52 that penetrates through the
A handle 54 is screwed onto the unit 2. The ceramics fixed frame 36 has a pair of bearings 2 on the rotary shafts 34, 34.
4 and 24 are rotatably attached, and the handle 54 is loosened and rotated along the guide hole 50, and the handle 54 is tightened at a predetermined angle to fix the pottery 44 to the pottery fixing device 12. , Is fixed at an arbitrary inclination angle within an angle range of 90 degrees from the horizontal position to the vertical position in the figure. That is, in the present embodiment, the bearing 24, the ceramics fixed frame 36, the angle changing arm 4
6, the angle changing guide 48, the bolt 52, and the handle 54 correspond to the angle adjusting means.

The impact force imparting device 14 includes a moving table 56 fixed on the table 22, a moving member 60 which can be moved on the moving table 56 in the left-right direction in FIG. A support column 62 provided upright on the member 60 and a support arm 64 attached to the support column 62 so as to be vertically movable. The pillar 62
A pulley 66 is rotatably attached to an upper end of the rotator about an axis perpendicular to the paper surface of FIG. 2, while a worm gear or the like is used at a lower end near the moving member 60.
8 is attached, the wire 70 is wound or extended by rotating the winding device 68, and the support arm 64 supported by the wire 70 via the pulley 66 moves up and down. To be made.

The lower surface 7 of the tip of the support arm 64 is also used.
A wire 72 is attached to the wire 1.
A steel ball 74 is hung by 2. Further, a motor 76 with a speed reducer is attached to an intermediate portion of the support arm 64, and a rotary shaft of the motor 76 projects at a tip end portion in a direction parallel to the support arm 64 and an electromagnet 78.
A rotating arm 82 having a suction portion 80 to which is attached is fixed. The lower surface 71 of the distal end portion of the support arm 64 to which the wire 72 is attached, that is, the rotation center of the steel ball 74 is located on the rotation center axis of the rotation arm 82. The rotation arm 82 is rotated to move the suction portion 80.
When the electromagnet 78 is energized in a state where the steel ball 74 is close to or in close contact with the steel ball 74, the steel ball 74 is attracted to the adsorbing portion 80, and the rotating arm is rotated counterclockwise in FIG. By being rotated, the steel ball 74 is positioned at a position rotated by a predetermined angle from the vertical direction around the rotation center. In the figure, 84 is an angle display plate for indicating the predetermined angle, that is, the rotation angle of the steel ball 74. In the present embodiment, the steel ball 74 corresponds to a collision body.

When the handle 58 is rotated and the moving member 60 is moved, the steel ball 74 suspended by the wire 72 is moved in the left-right direction in FIG. The relative position in the horizontal direction between the ceramics 44 and the steel ball 74 is changed. On the other hand, the winding device 6
When 8 is rotated and the support arm 64 is moved up and down, the steel ball 74 suspended by the wire 72 is moved in the vertical direction in FIGS. 1 and 2, and the ceramic 44 and the steel ball 74 are vertically opposed to each other. The position is changed. That is, in the present embodiment, the moving base 56, the handle 58, the moving member 6
0 is a horizontal position adjusting means, a support arm 64, a pulley 6
6, the winding device 68, and the wire 70 correspond to the vertical position adjusting means, respectively. Also, the angle adjusting means,
Relative position adjusting means comprises the horizontal position adjusting means and the vertical position adjusting means.

The control device 16 includes a CPU 86 and a RAM.
88 and ROM 90. The motor 76 and the electromagnet 78 are connected to the control device 16, and the motor 76 is rotated and the electromagnet 78 is magnetized or stopped to be magnetized in accordance with an output signal from the control device 16 indicating a predetermined impact force. Therefore, the steel ball 74
Is held at a predetermined rotation angle position, and is moved from that position toward the ceramics 44. In addition, a microphone 92 connected to the control device 16 is provided near the end of the ceramics 44 on the impact force application device 14 side.
A vibration signal generated when the steel ball 74 is collided with is detected and sent to the control device 16. In addition, the control device 16
Is also connected to the display device 94, and the microphone 92
When it is determined that a crack has occurred in the ceramic porcelain 44 by the vibration signal sent from the display device 9, the impact force at that time is displayed.
4 is displayed. In this embodiment, the microphone 92 corresponds to the vibration detecting means.

The measurement of the impact strength of the ceramics 44 by the impact strength measuring device 10 will be described below with reference to the flow chart of FIG. First, the ceramics 44 is fixed to the ceramics fixing device 12, and the handle 54
The tilt angle of the ceramics 44 is set to a predetermined value by operating. Then, the handle 54 and the winding device 68
So that the steel ball 74 abuts the collision point of the ceramics 44 at the position of the wire 72 in the vertical direction,
The relative positions of the steel ball 74 and the ceramics 44 in the horizontal direction and the vertical direction are adjusted. In this way, after the fixing of the ceramics 44 and the position adjustment of the steel balls 74 are completed, the impact strength measuring device is activated by turning on the power supply SW (not shown).

In step S1, the initial value E ₀ of the impact force E applied to the ceramics 44 and the change interval α are manually set and input. However, input of these set values may be omitted by always using constant values preset in the control device 16. When it is determined in step S2 that the measurement start SW (not shown) is turned on,
In step S3, the initial value E ₀ is set as the first impact force E, and in step S4, the motor 76 is rotated and the rotating arm 82 is rotated clockwise in FIG. When the rotating arm 82 is positioned at the lowermost position, that is, the vertical position, the rotation of the motor 76 is stopped, and when the electromagnet 78 is magnetized by being energized in step S5, the steel positioned at the lowermost position. The ball 74 is attracted to the attracting portion 80 of the rotating arm 82.

In step S6, the rotating arm 82 is rotated counterclockwise in FIG. 1 while the steel ball 74 is being attracted, so that the steel ball 74 moves along the chain line shown in FIG. Along the vertical position, it is pulled up to a position rotated about the tip lower surface 71, that is, about the rotation center by a predetermined angle. This rotation angle is a value corresponding to the impact force E, and is determined according to the following equation (1), where W is the weight of the steel ball 74, L is the length of the wire 72, and θ is the rotation angle. To be

[0022]

[Equation 1] E = W · L (1−cos θ) (1)

When the steel ball 74 is pulled up to a predetermined position, the magnetizing of the electromagnet 78 is stopped and the steel ball 74 is released in step S7, and the steel ball 74 is moved toward the ceramics 44 along the orbit when it was pulled up. Then, the wire 72 is caused to collide at a position in the vertical direction. The vibration generated at the time of this collision is detected by the microphone 92, and the detected vibration signal is sent to the control device 16. Step S
In No. 8, it is judged from this vibration signal whether or not a crack has occurred in the ceramics 44. If it is determined in step S8 that a crack has occurred, step S9
Then, the display device 94 displays the impact force E when the crack is generated, that is, the impact strength of the ceramics 44, and the measurement is completed.

On the other hand, when it is judged that no crack has occurred, the routine proceeds to step S10, where the impact force E is updated to a value larger by the preset interval α, and the routine returns to step S4. After step S4, the measurement is continued in the same manner as above except that the steel ball 74 is pulled up to the rotation angle according to the updated impact force E until the determination in step S8 is affirmed. As is clear from the above description, in the present embodiment, the step S8 corresponds to the crack determination means, the step S9 corresponds to the impact strength determination means, the control device 16, the motor 76, the electromagnet 78,
The rotating arm 82 corresponds to the impact force setting means.

Here, in the present embodiment, the ceramic porcelain 44 fixed by the ceramic porcelain fixing device 12 is arbitrarily moved to a part thereof by the steel ball 74 which is moved toward the ceramic porcelain fixing device 12 from a certain direction. Can be given an impact. At this time, since the collision position and the angle of the steel ball 74 of the ceramics 44 are adjusted by the relative position adjusting means,
It is possible to measure the impact strength when impact is applied from various directions on each part of the ceramic ware 44. Therefore, by measuring the impact strength of each part for each ceramic product in this manner, the minimum strength for each ceramic product, that is, the practical strength can be obtained.

That is, conventionally, such a ceramics 44
The impact strength was measured by the method specified in ASTM C368-88. This method is shown in FIG.
As shown in (a) and (b), the ceramic porcelain 44 is fixed in a horizontal or vertical position, and a rigid pendulum 98 having a hammer 96 fixed at one end is rotated about the other end 100 from a predetermined angle. By swinging it down toward the ceramics 44, the hammer 96 is caused to collide with the edge of the horizontally fixed ceramics 44 or the center of the bottom of the vertically fixed ceramics 44 so that the impact is applied in the horizontal direction. It is to measure the breaking strength. Therefore, in the impact strength measuring device used for this measurement, irrespective of the shape of the ceramic ware 44, there are only two relative positions at the time of collision between the ceramic ware 44 and the hammer 96.

However, there are various shapes of the ceramics 44, and the portion exhibiting low strength differs depending on the shape of each product, and the direction of impact, that is, the angle at which the edge hits, the direction in which the edge falls, etc. Not constant. In particular, the chip strength, which indicates the easiness of chipping of the edge of the ceramic ware 44, shows a large difference depending on the impact method. Therefore, even when an impact lower than the chip strength obtained by the above measurement is given, damage or chipping easily occurs depending on the shape of the ceramics 44, but the minimum strength at which damage or chipping can occur. That is, practical strength could not be obtained by the above test method.

On the other hand, according to the present embodiment, by rotating the handle 54 along the guide hole 50,
The ceramics fixed frame 36 is rotated around the rotary shaft 34, and the ceramics 44 is, for example, as shown in FIGS. 5 (a) to 5 (e),
The tilt angle can be freely set within a 90 degree angle range from the horizontal position shown in (a) to the vertical position shown in (c).
Therefore, as to the chip strength, as shown in FIGS. 5 (a) to 5 (c), for example, the steel balls 74 are collided in the angle range of 0 to 90 degrees with the dish-shaped ceramics 44 faced up. When the chip strength is measured, the ceramics 44 is laid down as shown in FIG. 5 (d), and the edge thereof protrudes from the pedestal 38, and the angles shown in FIGS. 5 (a) to 5 (c) are shown. By measuring the chip strength when the steel ball 74 is collided within the range, from the direction of the angle range of -90 to +90 degrees around the horizontal state shown in FIG. The chip strength when impacted can be measured. Therefore, the minimum value of the chip strength corresponding to the shape of the edge of each product of the ceramic ware 44 can be obtained.

FIG. 6 is a diagram showing the chip strength measured by changing the angle as described above in the case of various edge shapes. The angle on the horizontal axis in FIG. 6 indicates the angle of incidence of the impact force on the ceramics 44, which is 0 degree when the ceramics 44 placed on a horizontal surface is impacted from the horizontal direction, and is horizontal. When a shock is applied from above the direction, that is, from + a, it is a positive angle, and from below, that is,-
The case where an impact is applied from the direction of a is shown by a negative angle. That is, 0 degree corresponds to the case where the horizontal position shown in FIG. 5 (a) is measured, and the positive angle is measured in the direction shown in FIG. 5 (b), the negative angle is measured. The respective angles from the horizontal when tilted in the direction shown in FIG.
As is clear from FIG. 6, in the case of the sharp edge shape of A, which has a relatively low chip strength, it shows a substantially minimum value at the horizontal position.
In the case of the round edge shapes of B and C, which are devised to improve the chip strength, the minimum value at the horizontal position does not show. In particular, in the case of the B shape, the minimum value of the chip strength is at the horizontal position. It is only about 1/3.

That is, as shown in Table 1 below, depending on the shape of the ceramic porcelain 44, the chip strength when measured by the ASTM type device and when measured by the impact strength measuring device 10 of this embodiment is the ASTM type. A value higher than 50% is obtained when measured with the device of No. The chip strength in the case of the present embodiment, the minimum value obtained when measured in the above angle range is displayed, and in the shape in which the chip strength is increased as described above, it is generally tilted and measured. Indicates the lowest strength. Therefore, according to this embodiment,
Ceramics that could not be obtained by ASTM measurement 4
The practical strength of 4 is obtained. Regarding the damage strength of the bottom of the ceramic ware 44, as shown in FIG. 5 (e), the cylindrical spacer 102 is arranged between the pedestal 38 and the ceramic ware 44, and the ceramic ware 44 is projected through the spacer 102. By fixing between the part 28 and the pedestal 38, it is possible to fix and measure in the vertical direction as in the conventional case.
With respect to this breakage strength, there is no particular difference between the conventional case and the case of this embodiment because the measuring methods are the same.
In addition, the steel ball 7 is placed at the position indicated by the broken line in FIG.
By making 4 collide with each other, it is possible to measure the breaking strength of various parts.

[0031]

[Table 1]

Further, according to the present embodiment, the vibration when the steel ball 74 collides with the ceramics 44 is detected by the microphone 92, and the presence or absence of the crack is judged based on the vibration signal. Therefore, it is difficult to detect with the naked eye.
Since the occurrence of minute cracks in No. 4 is reliably detected, the strength of the ceramics 44 can be measured more accurately.

Further, since the steel ball 74 has one end attached to the other end of the wire 72 attached to the lower surface 71 of the tip of the support arm 64, the impact force applied to the ceramics 44 when the steel balls 74 collide with the ceramics 44. Is set by rotating the rotation arm 82 to a predetermined rotation angle by controlling the rotation of the motor 76 so that the impact force E set by the control device 16 is obtained, and the steel ball 74 is The impact force E is sequentially increased by adding the interval α set in step S1 to the impact force E in step S10 each time the ceramics 44 is collided once. The value of the impact force E when it is determined that a crack has occurred in step S8 (crack determining means) is
Since it is determined as the impact strength of the ceramics 44, the ceramics 4
Impact strength at a predetermined collision position and angle of 4 is automatically measured.

Further, as described above, by rotating the ceramics fixed frame 36 about the rotary shaft 38, the inclination angle of the ceramics 44 is adjusted to an arbitrary angle, and the winding device 6 is used.
8 is adjusted to adjust the vertical relative position between the ceramics 44 and the steel ball 74.
It is possible to apply an impact force by the steel ball 74 at any position and at any incident angle.

At this time, the vertical relative position is adjusted by moving the support arm 64 up and down, so that the length of the wire 72 is kept constant. On the other hand, since the tilt angle of the ceramic ware 44 is changed by rotating the ceramic ware fixing frame 36, the relative distance between the steel ball 74 and the ceramic ware 44 is changed or the collision position is changed according to the rotation angle. The relative distance between the collision position and the steel ball 74 also changes when the vertical relative position is changed in order to move the moving member 60 on the moving table 56 by operating the handle 58. By changing the horizontal relative position between the steel ball 74 and the ceramics 44, the collision is caused at the position where the wire 72 is in the vertical direction. Therefore, when the turning angle of the wire 72 is the same, the head of the steel ball 74 becomes constant, and the velocity of the steel ball 74 at the time of collision is always horizontal, and the impact force applied to the ceramics 44 is constant. Is determined only by the inclination angle of the ceramics 44, and the impact force applied to the ceramics 44 is determined only by the rotation angle of the wire 72.

Further, according to this embodiment, the angle of the ceramics 44, that is, the angle to which the impact force is applied, can be easily changed only by operating the handle 54.

Further, according to the present embodiment, since the steel ball 74 is used as the collision body for giving the impact force to the ceramics 44, the collision body is always contacted with the ceramics 44 even when the chip strength is measured. Contacted. Therefore, more accurate chip strength can be obtained as compared with the conventional case. On the other hand, in the conventional ASTM type measuring device, the hammer 9 is used as a collision object.
Since 6 was used, the hammer 96 was in line contact when it was made to collide with the edge of the ceramic porcelain 44 for the purpose of measuring the chip strength, and accurate chip strength could not be obtained.

Although one embodiment of the present invention has been described in detail with reference to the drawings, the present invention can be implemented in still another mode.

For example, in the above-described embodiment, it is determined by the microphone 92 whether or not the ceramic porcelain 44 is cracked.
Although the vibration at the time of collision is detected by the control device 16 and the judgment is made by the control device 16 based on the vibration signal, it may be visually confirmed. However, since a minute crack that cannot be visually confirmed can occur, it is preferable to detect it by the microphone 92 or the like as in the embodiment.

Further, for example, the shape of the ceramic ware 44 is stored in the control device 16 in advance for each product number, and the product number is input at the time of measurement, and the angle operation amount of the handle 54 and the rotation amount of the winding device 68 ( That is, the vertical movement amount of the support arm 64) may be detected by the control device 16. In this way, the display device 94 can display the impact strength and the impacted portion of the ceramic ware 44 and the incident angle of the impact, and by repeating the measurement for the ceramic ware 44 of the same type, the ceramic ware 44 can be displayed. It is also possible to display the impact strength distribution (so-called Survival envelope) when the impact is applied from various directions in each part of.

Further, the rotation angle of the ceramics fixed frame 36 is 0 to
Although it is set to 90 degrees, it may be rotatable in a larger angle range. By doing so, the measurement at the minus angle shown in FIG. 6 becomes easier.

Further, in the embodiment, the rotating arm 82 having the steel ball attracting portion 80 provided with the electromagnet 78 is provided, and the motor 76 is rotated by the control device 16, so that a predetermined impact force is exerted. Steel ball 7 to the angle obtained
Although No. 4 has been pulled up, the pulling operation of this steel ball 74 may be performed manually. However, in this case, by inputting the rotation angle separately to the control device 16, the impact strength is displayed when a crack occurs, or when the control device 16 is not used. Is to visually check the occurrence of cracks, and
It is necessary to calculate the impact strength from the rotation angle according to the formula.

Although the steel ball 74 is suspended by the wire 72, it may be suspended by a fiber such as nylon, or may be suspended by an elongated rod-shaped body.

Although the impact force applying device 14 using a pendulum is used as the impact force applying means, for example, an impact force for ejecting a collision object such as a steel ball 74 toward the ceramics 44 at a predetermined injection angle. An imparting means or the like may be used.

Although not illustrated one by one, the present invention can be variously modified without departing from the spirit thereof.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of an impact strength measuring device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a state of the impact strength measuring device of FIG. 1 viewed from a right side surface.

FIG. 3 is a flowchart showing the operation of the control device.

FIG. 4 is a diagram showing a basic configuration of a conventional impact strength measuring device.

5A and 5B are diagrams showing an embodiment in which a ceramic is impacted by the impact strength measuring device of FIG. 1, where (a) to (d) are for chip strength measurement, and (e) are for break strength measurement. Indicates.

FIG. 6 is a diagram showing a relationship between the inclination angle of the ceramics and the chip strength measured by the impact strength measuring device of FIG.

[Explanation of symbols]

10: Impact strength measuring device 12: Ceramic fixing device (ceramic fixing means) 14: Impact force applying device (impact force applying means) {24: Bearing, 36: Ceramic fixing frame, 46: Angle changing arm, 48: Angle changing Guide, 52: bolt, 5
4: Handle 54 (angle adjusting means), 64: Support arm, 66: Pulley, 68: Winding device, 70: Wire (vertical position adjusting means), 56: Moving stand, 58: Handle,
60: Moving member (horizontal position adjusting means)} (relative position adjusting means)

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Takashi Kanie No. 1-36 No. 36, Noritake Shinmachi, Nishi-ku, Nagoya, Aichi Prefecture Noritake Company Limited

Claims (1)

[Claims] 1. A device for measuring the impact strength of ceramics, comprising: ceramics fixing means for fixing the ceramics; and a ceramics fixing means for moving the collision body toward the ceramics fixing means from a certain direction. Impact force applying means for applying an arbitrary impact force to a part of the ceramics fixed to the ceramics, and relative position adjusting means for adjusting the collision position and the angle of the ceramics fixed to the ceramics fixing means by the collision body. An impact strength measuring device for ceramics characterized by the above.