KR102182792B1 - Life test method for materials used in artificial tooth - Google Patents

Abstract

The present invention relates to a life test method of a dental material, and more particularly, performed by an equipment for an accelerated test of a dental material, the equipment comprising: setting and receiving an acceleration condition of the equipment for an accelerated test of the dental material; Deriving an acceleration coefficient from the acceleration condition; Deriving a life test time from the acceleration coefficient; Initiating a deterioration test due to heat generation and thermal shock of the dental material according to the life test time; And terminating the deterioration test due to the heat generation and thermal shock.

Description

Life test method for materials used in artificial tooth}

The present invention relates to a life test method of a dental material, and more particularly, performed by an equipment for an accelerated test of a dental material, the equipment comprising: setting and receiving an acceleration condition of the equipment for an accelerated test of the dental material; Deriving an acceleration coefficient from the acceleration condition; Deriving a life test time from the acceleration coefficient; Initiating a deterioration test due to heat generation and thermal shock of the dental material according to the life test time; And terminating the deterioration test due to the heat generation and thermal shock.

Since dental materials must have high durability against mastication activities, and mastication activities can be regarded as the same model as applying cyclic stress, durability of dental materials corresponding to cyclic stress is a very important index.

Therefore, the dental material must have sufficient reliability in relation to fatigue failure against cyclic stress, and therefore, it is very important to determine the life of the dental material.

As a prior art for life prediction for the cyclic stress of a material, Korean Patent No. 1526313 "Fatigue Life Prediction Method" has been disclosed, and the prior art is a variable state of the object to be measured for a predetermined fatigue stress until failure. By monitoring, obtaining the fatigue data of the measurement object and predicting the fatigue life of the measurement object based on the Weibull distribution based on the obtained fatigue data, but the cumulative failure probability It provides a fatigue life prediction method including the step of predicting the fatigue life of the measurement object according to the criteria of ). Therefore, since the Weibull distribution is selected based on the equally integrated failure probability and the life span is predicted through this, the accuracy and reliability of the fatigue life prediction of the measurement object can be improved.

However, the technology only discloses a method for predicting the lifespan corresponding to the fatigue stress of a material, and not a method for predicting the accelerated life of a material.

Therefore, it is necessary to develop an accelerated life test technique under cyclic loads of materials and to propose a life test method that can shorten the test cost and period through this.

Korean Patent Publication No. 2010-0054229

The present invention was conceived to solve the problems of the prior art, and the present invention sets the acceleration condition of the dental material with respect to pressure (load), and after setting the life test time according to the acceleration coefficient from this, the actual By applying fatigue to the dental material, it is determined whether the amount of wear is less than the standard value due to the occurrence of wear on the dental material, and if the time when the amount of wear is less than the standard value is more than the accelerated life test time, the accelerated life of the dental material is considered suitable The purpose of this study is to provide a method for life test of dental materials that can shorten the test time for repeated loads of dental materials by establishing a reference point for the accelerated life time.

In order to achieve the above object, the present invention is performed by an apparatus for accelerated testing of dental materials, the apparatus comprising: setting and receiving an acceleration condition of an apparatus for accelerated testing of dental materials; Deriving an acceleration coefficient from the acceleration condition; Deriving a life test time from the acceleration coefficient; Initiating a test to cause fatigue in the dental material according to the life test time; And terminating the test for causing the fatigue to occur. It provides a method for testing the life of a dental material, comprising:

It is preferable that the acceleration condition is pressure.

Ending the test for causing the fatigue to occur; Previously, the step of checking whether the amount of wear of the dental material is less than or equal to a preset reference value, and further comprising, and if it does not meet the reference value or less, it is preferable that a test for causing fatigue in the dental material is repeatedly performed.

The step of deriving an acceleration coefficient from the acceleration condition includes: a first step of deriving a pressure application cycle of a use condition and a pressure application cycle of an acceleration condition; A second step of calculating a value using the pressure application cycle (t _f ) of the use condition as a numerator and the pressure application cycle (t _a ) of the acceleration condition as the denominator; and the value calculated in the second step It is preferable to use as the acceleration factor.

The MTTF of the use condition is preferably derived by multiplying the acceleration factor by the MTTF of the acceleration condition.

According to the present invention as described above, after setting the acceleration condition of the dental material with respect to pressure (load), and setting the life test time based on the acceleration coefficient therefrom, fatigue is applied to the actual dental material to cause wear on the dental material. As a result, it is determined whether the amount of wear is less than the standard value, and if the time when the amount of wear is less than the standard value is more than the accelerated life test time, it is possible to determine that the accelerated life of the dental material is appropriate, but establish a reference point for the accelerated life time. As a result, the effect of shortening the test time for repeated loads of dental materials can be expected.

1 is a graph showing a fit line of a dental material fatigue test according to an embodiment of the present invention.
2 is a graph showing an optimal life distribution when the stress is 132 MPa or 145 MPa according to an embodiment of the present invention.
3 is an acceleration test graph when stress is 132 MPa or 145 MPa according to an embodiment of the present invention.
4 is a flowchart showing a conventional method for testing the life of a dental material.
5 is a flow chart showing a life test method according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In the description of the present invention, the defined terms are defined in consideration of functions in the present invention, which may vary according to the intention or custom of a technician engaged in the relevant field, so the definition is based on the contents throughout the present specification. It will have to be lowered.

In the cement for dental materials, fatigue failure under cyclic stress becomes the main failure mechanism, and the present invention derives an accelerated life test method for such a dental material under cyclic load.

1 is a graph showing a line of fit for a dental material fatigue test, and FIG. 2 is a graph showing an optimal life distribution when the stress is 132 MPa or 145 MPa according to an embodiment of the present invention, and FIG. Thus, when the stress is 132 MPa or 145 MPa, it is an accelerated test graph, and FIG. 4 is a flowchart showing a conventional dental material life test method, and FIG. 5 is a flowchart showing a life test method according to an embodiment of the present invention.

Accelerated life test refers to a test method in which high stress is applied for a short period of time to estimate life. When such an accelerated life test is performed, it is possible to dramatically shorten a test time that takes a long time, such as a life test for a dental material. However, in order to perform the accelerated life test on dental materials, a life test method suitable for the accelerated life test of dental materials must be established. The present invention relates to this.

The present invention is carried out by an apparatus for accelerated testing of dental materials, the apparatus comprising: setting and receiving an acceleration condition of the apparatus for accelerated testing of dental materials; Deriving an acceleration coefficient from the acceleration condition; Deriving a life test time from the acceleration coefficient; Initiating a test to cause fatigue in the dental material according to the life test time; And terminating the test to cause the fatigue to occur.

That is, the present invention relates to a method of determining the accelerated life of a dental material, and by measuring the relative life of the dental material manufactured by each manufacturer as a reference value, the accelerated life of the dental material as a reference value. You can check if it is properly made. In other words, it is possible to check whether the dental material is defective or defective, and to check the possibility of modifying the manufacturing conditions of the dental material.

Hereinafter, the process of setting the acceleration factor and the life test time applied in the present invention is represented by an equation.

In this procedure, linear (first-order) and polynomial (second-order or third-order) regression analyzes were performed on a single predictor variable, and the regression lines for the data were plotted on a real scale or log10 scale. At this time, the variable data is as follows.

Response (Y-axis): Stress item (S).

Predictor (X-axis): Time item (t).

Linear: Choose a linear regression model

I. Derivation of fatigue life model and acceleration model

1 is a graph showing by deriving the SN relationship for a plurality of materials as an example and performing regression analysis therefrom. As can be seen in FIG. 1, the R-Square value is accurate as 72.8%. Was judged.

The R-Square value is between 0 and 1, and for two graphs, if it is 0, there is no relationship between the graphs, and if it is 1, it means that the two graphs are the same. In the case of 0.728, it is close to 1, which means that the experimental value and the SN graph fit well in a noisy fatigue test.

Meanwhile, in the case of the S-N function according to FIG. 1, the following S-N function was obtained as a result of curve fitting with an inverse power model.

Here, S means applied stress [MPa], and t means applied cycle [Cycle].

In order to obtain the acceleration model from this, the inverse power model is obtained from the function of time and the inverse function of stress as the following equation.

If the acceleration model is obtained by the S-N function, it is as follows.

Here, S _a is the stress (pressure, load) under acceleration conditions, and S _f is the stress (pressure, load) under actual use conditions.

3. Life prediction

end. Life prediction method

1) In the fatigue test, the optimal life distribution is derived by analyzing the distribution at a specific stress level.

2) Verify the accuracy of the experiment by checking the distribution identity at least two stress levels.

3) If items 1 and 2 are satisfied, MTTF (Mean Time to Failure) at a specific acceleration level is calculated. In the present invention, the distribution at the stress level of 133 MPa was applied.

4) The acceleration factor is derived from the relationship between the stress level selected in item 3 and the stress level under actual use conditions. In the present invention, 102 MPa was defined as the actual stress.

5) MTTF under the conditions of actual use in item 3 is derived by multiplying the MTTF at the acceleration level by the acceleration factor.

I. Life prediction

1) As a result of calculating the distribution fit, the Weibull distribution was found to be the highest with a correlation coefficient of 0.957. Therefore, for life prediction, Weibull distribution is applied.

2) As shown in FIGS. 2 and 3, respectively, as a result of checking the shape parameters at 132 MPa and 145 MPa, they were almost the same as 0.77 and 0.82, respectively, confirming that there was no difference in the shape parameters under acceleration conditions. That is, it was confirmed that the failure mechanism of the dental material was the same.

3) As a result of calculating the MTTF at 132㎫ to compare with the usage conditions, it was predicted to be 1,440 cycles.

4) The stress under the conditions of use was investigated as 85 MPa. Among the results of the accelerated life test, 132 MPa and the acceleration factor are compared as follows.

That is, it was confirmed that the 132 MPa stress condition was 69,342 times the acceleration of the 85 MPa stress condition.

5) Calculating the MTTF under 85㎫ condition is as follows.

MTTF in use condition = MTTF in acceleration condition times acceleration factor

Although the present invention has been described in more detail with reference to examples above, the present invention is not necessarily limited to these embodiments, and various modifications may be made without departing from the spirit of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not stabilized by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

Claims (5)

It is performed by equipment for accelerated testing of dental materials, and the equipment is
Performing a linear regression analysis on the stress (stress) over time in the first order, performing polynomial regression analysis in the second and third orders, and setting and receiving an acceleration condition of the equipment for the accelerated test of the dental material;
Deriving an acceleration coefficient according to the following equation from the acceleration condition;
Deriving a life test time from the acceleration coefficient;
Initiating a test to cause fatigue in the dental material according to the life test time; And
Ending the test for causing the fatigue to occur;
Life test method of a dental material, characterized in that configured to include.
expression)

Here, S is the applied stress [㎫] and t is the applied cycle [Cycle], which is derived when the R-squared value is 72.8% in the above function.

If the acceleration model (acceleration coefficient, AF) is obtained by the SN function, it is as follows.

Here, S _a is the stress under acceleration conditions, and S _f is the stress under actual use conditions. delete The method of claim 1,
Ending the test for causing the fatigue to occur; Before,
Checking whether the amount of wear of the dental material is less than or equal to a preset reference value; further comprising, and if it does not meet the reference value or less, a test to cause fatigue in the dental material is repeatedly performed. Way. delete delete

Images