JP2008215838A - Liquid infiltration evaluation method and liquid infiltration evaluation device for sealing part - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid infiltration evaluation method and a liquid infiltration evaluation device for a sealing part, capable of evaluating existence of liquid infiltration into the sealing part without having to depend on the visual determination by an operator, and without having to disassemble a work. <P>SOLUTION: A dielectric constant sensor 5 is inserted into the sealing part 2 of the work, and the change in the dielectric constant in the sealing part 2 is detected by the dielectric constant sensor 5, to thereby evaluate the existence of liquid infiltration into the sealing part 2. Hereby, liquid leakage from the sealing part 2, and existence of liquid infiltration into the sealing part 2 can be evaluated precisely, without having to depend on the visual decision on the part of the operator, and without having to disassemble the work. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a liquid penetration evaluation method and a liquid penetration evaluation apparatus for a seal portion of a workpiece.

With respect to the conventional liquid intrusion evaluation of the seal portion of the workpiece, an operator visually checks and evaluates whether there is liquid leakage from the seal portion to the outside.
In addition, in the case of a work that is suspected of having liquid infiltrated partway through the seal part, the work is disassembled once, and the seal part is irradiated with black light (ultraviolet light) and the fluorescence reaction is performed by the operator. Visual inspection evaluated the penetration of liquid into the seal.

However, the method of visually confirming and evaluating whether or not there is a liquid leak from the seal part of the former work depends on the sensuality of the worker, so there is a difference in judgment among the respective workers, and the pass / fail judgment is made. There was variation. In addition, when the liquid leaking from the seal part is a transparent liquid or when the liquid leaks from the seal part and becomes a dry transparent deposit, there is a high possibility that it will be missed by visual confirmation. The evaluation method was not reliable.
Moreover, the method of disassembling the latter workpiece and visually checking and evaluating the seal part is particularly effective when the seal part is evaluated and the liquid does not enter the seal part and the product is a good product. It is necessary to apply and harden the member, which requires considerable man-hours and is very inefficient. In addition, it cannot be judged again whether the liquid has entered the sealed portion that has been sealed again.

Further, as a conventional technique for evaluating liquid leakage from a seal portion without disassembling a work, Patent Document 1 discloses a method for microleakage inspection.
That is, in the method of microleakage inspection of Patent Document 1, the inspection head is adsorbed so as to cover the welded portion (seal portion) of the workpiece, and the pressure change measurement space communicating with the inspection head is set to a constant negative pressure. Thereafter, the negative pressure in the pressure change measurement space is measured by a negative pressure type air tester, and it is determined whether there is a liquid or gas leak from the seal portion by the change in the negative pressure.
JP 2004-85461 A

  However, in the method of micro leak inspection of Patent Document 1, the presence or absence of liquid or gas leakage from the seal portion can be evaluated, but it cannot be evaluated whether or not liquid or gas has entered the seal portion.

  The present invention has been made in view of the above points, and is a seal that can evaluate whether liquid has entered the seal portion without depending on the visual judgment of the operator and without disassembling the workpiece. An object of the present invention is to provide a liquid intrusion evaluation method and a liquid intrusion evaluation apparatus.

In order to solve the above-mentioned problems, firstly, the liquid intrusion evaluation method for a seal portion according to the present invention inserts a dielectric constant sensor into the seal portion and detects a change in the dielectric constant in the seal portion by the dielectric constant sensor. The presence or absence of liquid intrusion into the seal portion is evaluated.
Second, the liquid intrusion evaluation apparatus for a seal portion according to the present invention includes a dielectric constant sensor that is inserted into the seal portion and detects a change in dielectric constant within the seal portion.
As a result, it is possible to accurately evaluate liquid leakage from the seal part of the work without depending on the visual judgment of the operator, and also whether or not liquid has entered the seal part without disassembling the work. Can be evaluated.
Various aspects of the liquid intrusion evaluation method and liquid intrusion evaluation apparatus according to the present invention and their functions will be described in detail in the following section (Invention Aspect).

(Aspect of the Invention)
In the following, some aspects of the invention that can be claimed in the present application (hereinafter sometimes referred to as “claimable invention”) will be exemplified and described. In addition, each aspect is divided into a term like a claim, it attaches | subjects a number to each term, and is described in the format which quotes another term as needed. This is for the purpose of facilitating the understanding of the claimable invention, and is not intended to limit the combinations of the constituent elements constituting the claimable invention to those described in the following sections. In other words, the claimable invention should be construed in consideration of the description, embodiments, etc. accompanying each section, and as long as the interpretation is followed, there may be embodiments in which other constituent elements are added to the aspects of each section. In addition, an aspect in which the constituent elements are deleted from the aspect of each item can be an aspect of the claimable invention. In each of the following items, each of items (1) to (4) corresponds to each of claims 1 to 4, and each of items (7) to (8) corresponds to claims 5 to 6. It corresponds to each of.

(1) A liquid intrusion evaluation method for evaluating the presence or absence of liquid intrusion into a seal portion of a workpiece, wherein a dielectric constant sensor is inserted into the seal portion, and a change in dielectric constant in the seal portion is detected by the dielectric constant sensor. A liquid intrusion evaluation method for a seal part, characterized by detecting and evaluating the presence or absence of liquid intrusion into the seal part.
Therefore, in the method for evaluating the liquid intrusion of the seal portion in (1), it is possible to evaluate the presence or absence of liquid intrusion into the seal portion by detecting a change in the dielectric constant in the seal portion by the dielectric constant sensor.
In other words, after the liquid (for example, engine oil) is filled into the workpiece, if the liquid does not enter the seal portion (for example, liquid gasket), the dielectric constant sensor is placed in the seal portion, specifically, the seal portion and the workpiece. Is inserted, the dielectric constant “near 4” of the liquid gasket of the seal portion is output, and even if the dielectric constant sensor is continuously inserted into the seal portion, the value does not change as it is, and the liquid into the seal portion is not changed. It can be judged that there is no intrusion.
On the other hand, if the liquid leaks from the seal part, when the dielectric constant sensor is inserted into the seal part, the dielectric constant “near 2” of the liquid engine oil is output immediately after the insertion, and the liquid leaks from the seal part. It can be judged that there is.
In addition, when the liquid has penetrated into the seal portion, when the dielectric constant sensor is inserted into the seal portion, immediately after the insertion, the dielectric constant “near 4” of the liquid gasket of the seal portion is output. If the dielectric constant sensor continues to be inserted into the seal portion, the dielectric constant of the engine oil changes to “near 2” when the dielectric constant sensor comes into contact with the liquid engine oil, so that it can be determined that the liquid has entered the seal portion.

(2) Quantitatively measuring the degree of penetration of the liquid into the seal portion based on the amount of insertion of the permittivity sensor into the seal portion at the time when a change in dielectric constant is detected ( The method for evaluating liquid intrusion of the seal portion according to item 1).
Therefore, in the method for evaluating the liquid intrusion of the seal portion in the item (2), when a liquid (for example, engine oil) has penetrated several mm into the seal portion (for example, liquid gasket), the dielectric constant sensor is connected to the liquid gasket of the seal portion. The dielectric constant sensor is inserted into the seal portion of the dielectric constant sensor when the dielectric constant sensor changes from the dielectric constant “near 4” of the liquid gasket to the dielectric constant “near 2” of the liquid engine oil. The degree of penetration of the liquid into the seal portion can be quantitatively measured.

(3) The dielectric intrusion evaluation of the seal portion according to (1) or (2), wherein the dielectric constant sensor is set to detect a predetermined dielectric constant of a specific liquid. Method.
Therefore, in the liquid intrusion evaluation method for the seal portion in (3), the dielectric constant sensor can detect only the dielectric constant of the liquid filled in the workpiece and the seal member.

(4) With respect to the intrusion of the liquid whose dielectric constant changes corresponding to the temperature change into the seal portion, the dielectric constant sensor is set so as to detect the dielectric constant corresponding to the temperature of the liquid. The liquid intrusion evaluation method for a seal portion according to any one of (1) to (3), characterized in that:
Therefore, in the liquid intrusion evaluation method for the seal portion in (4), it is possible to evaluate the presence or absence of intrusion into the seal portion of the liquid whose dielectric constant changes corresponding to the temperature change.

(5) The liquid in the seal part according to any one of (1) to (4), wherein the dielectric constant sensor is formed in a rod shape, and an outer diameter thereof is set to 1.0 mm or less. Infiltration evaluation method.
Therefore, in the method for evaluating liquid intrusion of the seal portion in the item (5), the opening diameter when the dielectric constant sensor is inserted into the seal portion can be made as small as possible.

(6) The seal portion is a seal portion of a three-surface mating portion in which a cylinder block, a cylinder head, and a chain cover of an engine are matched, and any one of (1) to (5) is characterized. Evaluation method for liquid intrusion of the seal part.
Therefore, in the liquid intrusion evaluation method for the seal portion of item (6), the seal portion of the three-surface joint portion of the cylinder block, the cylinder head, and the chain cover, which is particularly liable to leak liquid, is easily evaluated in the engine seal portion. be able to.

(7) A liquid intrusion evaluation apparatus for evaluating the presence or absence of liquid intrusion into a seal portion of a workpiece, wherein the liquid intrusion evaluation apparatus is inserted into the seal portion to measure a change in dielectric constant in the seal portion. A liquid intrusion evaluation apparatus for a seal part, comprising a dielectric constant sensor for detection.
Therefore, in the liquid intrusion evaluation apparatus for the seal portion of (7), it is possible to detect the change in the dielectric constant in the seal portion by the dielectric constant sensor and evaluate the presence or absence of liquid intrusion into the seal portion.

(8) The liquid intrusion evaluation apparatus for a seal part according to (7), wherein the dielectric constant sensor is connected to a linear scale for measuring an insertion amount of the dielectric constant sensor into the seal part.
Therefore, in the liquid intrusion evaluation apparatus for the seal part of (8), when the dielectric constant sensor is inserted into the seal part, based on the amount of insertion of the dielectric constant sensor into the seal part when the dielectric constant changes, The degree of penetration of the liquid into the seal portion can be quantitatively measured.

  According to the present invention, the liquid intrusion evaluation method and the liquid intrusion of the seal portion that can evaluate whether or not the liquid has entered the seal portion without depending on the visual judgment of the operator and without disassembling the workpiece. An evaluation device can be provided.

Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to FIG.
A seal portion liquid intrusion evaluation apparatus 1 according to an embodiment of the present invention evaluates the presence or absence of liquid intrusion into a seal portion 2 of a workpiece. As shown in FIG. Specifically, a rod-like dielectric constant sensor 5 inserted at the boundary between the seal portion 2 and the cylinder block 4, a linear scale 6 for measuring the amount of insertion of the dielectric constant sensor 5 into the seal portion 2, and a dielectric constant sensor 5 and the linear scale 6 are electrically connected, and the dielectric constant of the liquid to be detected by the dielectric constant sensor 5 is input. Based on the measurement result from the linear scale 6, the liquid enters the seal portion 2. The data processing unit 7 calculates the degree of penetration.

The dielectric constant sensor 5 is formed in a rod shape, and its outer diameter is set to 1.0 mm or less. The dielectric constant sensor 5 is built in the sensor body 10 so as to be slidable in the longitudinal direction. The detection head 11 of the linear scale 6 is connected to the rear end portion (right end portion in FIG. 1) of the dielectric constant sensor 5. The dielectric constant sensor 5 is electrically connected to the data processing unit 7.
The linear scale 6 includes a scale body 12 on which the detection head 11 slides, and is built in the sensor body 10. A dielectric constant sensor 5 is connected to one end of the detection head 11 (left end in FIG. 1), and the amount of insertion of the dielectric constant sensor 5 into the seal portion 2 is measured by the amount of slide of the detection head 11. It has become. A hand handle 13 is connected to the other end of the detection head 11 (the right end in FIG. 1). Further, the data processing unit 7 is electrically connected to the detection head 11.
The linear scale 6 may be a magnetic scale or an optical scale, and is not limited by the difference in measurement principle.

The data processing unit 7 is preliminarily input with a dielectric constant of a specific liquid to be detected, such as engine oil or distilled water, or a seal member, for example, a liquid gasket, and a dielectric with respect to a temperature change of each liquid. A change in the rate is also input, and even if the liquid to be detected has a dielectric constant characteristic that changes in response to a temperature change, the dielectric constant of the liquid can be selected as appropriate.
That is, when a liquid having a large change in dielectric constant corresponding to a temperature change, such as distilled water, is to be detected, the temperature measured by the data processing unit 7 using the temperature measurement function provided in the data processing unit 7 The dielectric constant of distilled water corresponding to is appropriately selected, and the dielectric constant sensor 5 detects the selected dielectric constant of distilled water.
Note that the temperature measured by the data processing unit 7 is measured if the temperature of the seal unit 2 and the room temperature are substantially the same, and if the temperature of the seal unit 2 and the room temperature are significantly different, The temperature of the seal part 2 is directly measured by the temperature measurement sensor.
Further, the width length of the seal portion 2 is input to the data processing portion 7 in advance, and based on the measurement result of the insertion amount of the dielectric constant sensor 5 from the detection head 11 of the linear scale 6 into the seal portion 2. The degree of penetration of the liquid into the seal portion 2 is calculated.
In the data processing unit 7, after the dielectric constant sensor 5 is inserted into the seal portion 2, the value of the dielectric constant and the amount of insertion of the dielectric constant sensor 5 are displayed at any time, so that the liquid enters the seal portion 2. When there is a change in the dielectric constant, the operator is made to recognize it by sound or flashing, and the degree of penetration of the liquid into the seal portion 2 is calculated from the insertion amount of the dielectric constant sensor 5. Displayed and recorded.

  The liquid intrusion evaluation apparatus 1 is used in FIG. 1 for liquid intrusion evaluation of the seal portion 2 between the cylinder head 3 and the cylinder block 4. In particular, in the seal portion 2 of the engine, the occurrence of liquid leakage occurs. This is useful when performing liquid intrusion evaluation on the seal portion 2 at the portion where the three surfaces are joined, such as the cylinder head 3, the cylinder block 4, and the chain cover (not shown).

Next, a liquid penetration evaluation method using the liquid penetration evaluation apparatus 1 according to the embodiment of the present invention will be described. Here, a liquid intrusion evaluation method for the seal portion 2 between the cylinder head 3 and the cylinder block 4 of the engine will be described. The seal portion 2 is composed of a liquid gasket (dielectric constant “4”), and the cylinder head 3 and the cylinder block 4 are filled with liquid engine oil (dielectric constant “2”). Yes. Liquid gaskets and engine oils are those whose dielectric constant does not change greatly due to temperature changes.
First, before inserting the dielectric constant sensor 5 into the seal portion 2, a signal indicating that the detection target of the dielectric constant sensor 5 is engine oil and liquid gasket is input to the data processing section 7. Then, when the dielectric constant sensor 5 detects the dielectric constants of the engine oil and the liquid gasket, it outputs the signal to the data processing unit 7.

Next, when the liquid intrusion evaluation of the seal portion 2 is started, first, the one end surface of the sensor main body 10 of the liquid intrusion evaluation apparatus 1 is straddled across the seal portion 2 between the cylinder head 3 and the cylinder block 4 from the outside. The dielectric constant sensor 5 is positioned so that it can be inserted at the boundary between the seal portion 2 and the cylinder block 4 and brought into contact with the wall surface of the cylinder head 3 and the cylinder block 4.
Next, the operator slowly pushes the hand handle 13 and inserts the dielectric constant sensor 5 at the boundary between the seal portion 2 and the cylinder block. Then, the data processor 7 displays the dielectric constant “near 4” of the liquid gasket.
Thereafter, when the hand handle 13 is pushed slowly in and engine oil has entered the seal portion 2, the data processing portion 7 displays the indication when the tip of the dielectric constant sensor 5 touches the engine oil. The dielectric constant of the liquid gasket changes from “near 4” to the dielectric constant of the engine oil “near 2”, and the insertion amount of the dielectric constant sensor 5 at that time is measured, and the engine oil is inserted into the seal portion 2. The degree of penetration is calculated and displayed. Further, the data processing unit 7 has a change in the dielectric constant measured by the dielectric constant sensor 5, the amount of insertion of the dielectric constant sensor 5 when the dielectric constant changes, and the liquid seal portion 2 calculated from the amount of insertion. The degree of penetration is recorded.

Finally, the operator stops inserting the dielectric constant sensor 5 at the point when the dielectric constant of the engine oil changes to “near 2”, slowly pulls the hand handle 13, and pulls the dielectric constant sensor 5 from the seal portion 2. Pull out to the outside, and the liquid penetration evaluation of the seal portion 2 is completed.
Then, according to the recording of the data processing unit 7, it is determined that the seal unit 2 has a few mm of liquid entering the seal unit 2.

On the other hand, when the dielectric constant “near 2” of the engine oil is displayed in the data processing unit 7 immediately after the push handle 13 is pushed slowly and the dielectric constant sensor 5 is inserted into the boundary between the seal portion 2 and the cylinder block 4 It is determined that the liquid has already leaked to the outside.
In addition, even when the hand handle 13 is slowly pushed in and the dielectric constant sensor 5 is inserted to the vicinity of the width of the seal portion 2, the display of the data processing section 7 remains the dielectric constant “near 4” of the liquid gasket. If there is no change, it is determined that no liquid has entered the seal portion 2. In this case, since the liquid intrusion evaluation of the seal part 2 of the workpiece is good, the liquid gasket of the seal member is filled in the opening opened by inserting the dielectric constant sensor 5 and cured, and then the process proceeds to the next step.

  If the dielectric constant sensor 5 comes into contact with a substance other than the liquid gasket or engine oil, the dielectric constant sensor 5 does not detect the dielectric constant of the substance, and the data processing unit 7 displays the dielectric constant. Will not be done.

  Further, when the detection target of the dielectric constant sensor 5 is not the above-described engine oil but distilled water whose dielectric constant changes in response to a temperature change, the detection target of the dielectric constant sensor 5 is stored in the data processing unit 7. Input a signal indicating that it is distilled water. Then, the temperature at that time is measured in the data processing unit 7, and the dielectric constant of distilled water corresponding to the measured temperature is appropriately selected, and when the dielectric constant sensor 5 detects the selected dielectric constant, the signal is Is output to the data processing unit 7.

As described above, in the embodiment of the present invention, the dielectric constant sensor 5 is inserted into the seal portion 2 of the workpiece, and the change in the dielectric constant in the seal portion 2 is detected, so that the inside of the seal portion 2 is detected. The presence or absence of liquid intrusion into the workpiece can be accurately evaluated without disassembling the workpiece, and the reliability of the evaluation result is improved.
In the embodiment of the present invention, the position at which the liquid is detected by the dielectric constant sensor 5, that is, the degree of penetration of the liquid into the seal portion 2 is quantitatively measured based on the insertion amount of the dielectric constant sensor 5. Therefore, even when liquid does not leak from the seal portion 2 to the outside, a threshold that guarantees the minimum quality is set for the degree of penetration of the liquid into the seal portion 2, and the liquid intrusion evaluation is performed based on the threshold. By judging the quality, the defect of the seal part 2 after shipment can be greatly improved.
Moreover, in the embodiment of the present invention, the change of the dielectric constant with respect to the temperature of the liquid is input to the data processing unit 7, the temperature is measured by the data processing unit 7, and the dielectric constant corresponding to the temperature is selected. Since the sensor 5 can detect the dielectric constant of the liquid, it is very useful because many kinds of liquid that can be detected can be set.
Furthermore, since the outer diameter of the dielectric constant sensor 5 is set to 1.0 mm or less, the repaired seal portion 2 does not need to be repaired greatly, and problems due to resealing can be eliminated.

FIG. 1 is a schematic diagram of a liquid penetration evaluation apparatus for a seal portion according to an embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Liquid penetration evaluation apparatus, 2 Seal part, 3 Cylinder head, 4 Cylinder block, 5 Permittivity sensor, 6 Linear scale, 7 Data processing part

Claims (6)

A liquid intrusion evaluation method for evaluating the presence or absence of liquid intrusion into a work seal,
A dielectric constant sensor is inserted into the seal portion, and a change in the dielectric constant in the seal portion is detected by the dielectric constant sensor to evaluate the presence or absence of liquid intrusion into the seal portion. Liquid penetration evaluation method.   2. The degree of penetration of liquid into the seal portion is quantitatively measured based on the amount of insertion of the permittivity sensor into the seal portion when a change in dielectric constant is detected. The liquid penetration evaluation method of the seal part as described.   3. The method for evaluating liquid penetration into a seal portion according to claim 1, wherein the dielectric constant sensor is set so as to detect a predetermined dielectric constant of a specific liquid.   The dielectric constant sensor is set so that the dielectric constant corresponding to the temperature of the liquid can be detected with respect to the penetration of the liquid whose dielectric constant changes in response to a temperature change into the seal portion. The liquid penetration evaluation method of the seal part according to any one of claims 1 to 3. A liquid intrusion evaluation apparatus for evaluating the presence or absence of liquid intrusion into a seal part of a work,
The liquid penetration evaluation apparatus according to claim 1, further comprising a dielectric constant sensor that is inserted into the seal part and detects a change in dielectric constant in the seal part. The liquid intrusion evaluation apparatus for a seal part according to claim 5, wherein the dielectric constant sensor is connected to a linear scale for measuring an insertion amount of the dielectric constant sensor into the seal part.

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