JP2009250683A - Inspection method and inspection device of hardened component - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inspection method of a hardened component and an inspection device of the hardened component capable of inspecting existence of a hardening crack more simply, while securing the reliability. <P>SOLUTION: Existence of a hardening crack of a cup part is inspected (determined), based on the change in the outside diameter of the cup part during heating of a shaft part, by noticing the correlation between the variation in the outside diameter of the cup part and the hardening crack during the eating of the shaft part. Consequently, the existence of the hardening crack of an outer race can be inspected more simply, while securing the reliability, in comparison with a conventional technology, and the inspection can be simplified. Furthermore, since the device and a program required for determination are very simple, the constitution can be made low in cost. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a method and an apparatus for inspecting hardened parts, and more particularly, to a method and apparatus for inspecting (determining) the presence or absence of burning cracks in a cup portion in an outer race of a constant velocity joint.

For example, an outer race (quenched part) of a constant velocity joint undergoes a forging process, a machining process, and an induction quenching / tempering process, and the quenching depth and cracking are inspected in an inspection process. Conventionally, burnout cracks in the outer race are generally based on magnetic flaw detection, but there is a problem in reliability (accuracy) because human error is likely to occur. Therefore, the applicant of the present application has developed a quality evaluation method and a quality evaluation apparatus described in Patent Document 1. However, while the invention of Patent Document 1 can improve the reliability of the inspection, the means for giving a hit to the inspection object (outer race), the means for detecting the ultrasonic wave emitted from the inspection object to which the hit is given, Since it includes means for analyzing the detected ultrasonic wave (FFT) and means for determining the presence or absence of burning cracks in the inspection object based on the analysis result of the FFT (determination program), the inspection is complicated, The device is complex and expensive.
JP 2006-284548 A

Then, this invention was made in view of the said situation, and it was made as a subject to provide the inspection method of the quenching component which can test | inspect the presence or absence of a burning crack more easily, ensuring reliability. Is.
Another object of the present invention is to provide a quenching part inspection apparatus capable of more easily inspecting the presence or absence of burning cracks while ensuring reliability.

  In order to solve the above-mentioned problems, a quenching component inspection method according to the present invention includes a first quenching process in which the quenching component includes a cup portion and a shaft portion, the cup portion being quenched, and a second quenching treatment of the shaft portion. A quenching step, and a method for inspecting a hardened part including measuring a change in the outer diameter of the cup portion in the second quenching step, and determining whether or not the cup portion is cracked based on the measurement result. To do.

  In order to solve the above-mentioned problem, the quenching part inspection apparatus according to the present invention includes a cup part and a shaft part, and after quenching the cup part, the quenching part is quenched. An inspection device, a measuring means for measuring a change in the outer diameter of the cup portion in the step of quenching the shaft portion, a determination means for determining the presence or absence of a crack in the cup portion based on the measurement result of the measuring means, It is characterized by having.

(Aspect of the Invention)
In the following, aspects of the invention that is recognized as being capable of being claimed in the present application (hereinafter referred to as claimable invention) will be exemplified, and each exemplified aspect will be described. Here, as in the claims, each aspect is divided into paragraphs, numbers are assigned to the respective paragraphs, and the descriptions of other paragraphs are cited as necessary. This is for the purpose of facilitating the understanding of the claimable invention, and is not intended to limit the combination 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 accompanying each section, the description of the embodiment, etc., and as long as the interpretation is followed, another aspect is added to the aspect of each section. Moreover, the aspect which deleted the component from the aspect of each term can also be one aspect of the claimable invention.
In the following items, each of items (1) to (6) corresponds to each of claims 1 to 6.

(1) A quenching part is composed of a cup part and a shaft part, and includes a first quenching process for quenching the cup part and a second quenching process for quenching the shaft part. A method for inspecting a hardened part by measuring a change in the outer diameter of the cup part in the second quenching step and determining the presence or absence of quenching cracks in the cup part based on the measurement result.
Here, the mechanism by which a crack occurs in the cup portion of the outer race (quenched part) of the constant velocity joint will be described. In the second quenching process in which the shaft portion is quenched, when the shaft portion is heated (high-frequency induction heating), first, the shaft portion expands. As a result, in addition to being originally thin, in the cup portion that has been hardened (martensiticized) in the first quenching process, the tensile stress is increased and the tensile stress in the cup portion is increased. When the yield stress exceeds the yield stress of the material, a crack occurs on the inner surface of the cup portion.
In addition, when the tensile stress in the cup part exceeds the yield stress of the material and the crack is generated in the cup part during heating of the shaft part, the applicant of the present application releases the tensile stress in the cup part and removes the outside of the cup part. The diameter was increased, that is, the correlation between the amount of change in the outer diameter of the cup during heating of the shaft and the cracking was noted. In other words, it is possible to know the burning crack of the cup part based on the change in the outer diameter of the cup part during the heating of the shaft part.
According to the method for inspecting a hardened part described in this section, as described above, it is possible to determine the presence or absence of quench cracks in the cup portion of the outer race based on the change in the outer diameter of the cup portion during heating of the shaft portion. . As a result, it is possible to more easily inspect for the presence or absence of burnout cracks in the outer race while ensuring reliability as compared with the prior art.

(2) The change in the outer diameter of the cup portion during heating of the shaft portion is monitored, and from the outer diameter of the cup portion immediately before heating of the shaft portion and the maximum value of the outer diameter of the cup portion during heating of the shaft portion, (1) The inspection method of the hardened parts of (1) which determines the presence or absence of the burning crack of a cup part based on the variation | change_quantity of the outer diameter of the calculated cup part.
According to the inspection method for hardened parts described in this section, the outer diameter of the cup part during the heating of the shaft part is constantly monitored (measured), the outer diameter of the cup part immediately before the heating of the shaft part, and the heating of the shaft part The amount of change in the outer diameter of the cup portion is calculated from the maximum value of the outer diameter of the cup portion inside. Then, when the calculation result, that is, the amount of change in the outer diameter of the cup portion during heating of the shaft portion exceeds the threshold value, it is determined that there is burning cracking, and when it is equal to or less than the threshold value, it is determined that there is no burning cracking. The threshold value is set according to the hardened part.

(3) The outer diameter of the cup part before and after quenching the shaft part is measured, and the presence or absence of quench cracks in the cup part is determined based on the amount of change in the outer diameter of the cup part before and after quenching the shaft part (1 ) Hardened parts inspection method.
According to the inspection method for quenched parts described in this section, the amount of change in the outer diameter of the cup part before and after quenching of the shaft part is measured, and the difference in the measurement result of the outer diameter of the cup part before and after quenching of the shaft part is calculated. To do. Then, when the calculation result, that is, the difference in the outer diameter of the cup portion before and after quenching of the shaft portion exceeds the threshold value, it is determined that there is a crack, and when it is equal to or less than the threshold value, it is determined that there is no quench crack. The threshold value is set according to the hardened part.

(4) A quenching part is a quenching part inspection apparatus in which a quenching part is composed of a cup part and a shaft part, the quenching process is performed on the shaft part, and then the quenching process is performed on the shaft part. A quenching part inspection apparatus comprising: a measuring unit that measures a change in the outer diameter of the portion; and a determination unit that determines whether or not the cup portion is cracked based on a measurement result of the measuring unit.
In the outer race of constant velocity joints, when the shaft part is heated, if the tensile stress in the cup part exceeds the yield stress of the material and a crack occurs in the cup part, the tensile stress in the cup part is released and the cup part is released. The outer diameter of the part is expanded. The aspect of this section pays attention to this phenomenon, that is, the change in the outer diameter of the cup part during heating of the shaft part and the change in the outer diameter of the cup part during heating of the shaft part. Based on this, the cup portion is inspected (determined) for burning cracks.
According to the quenching part inspection apparatus described in this section, the measuring means measures a change in the outer diameter of the cup portion during heating of the shaft portion. Moreover, a determination means determines the presence or absence of the burning crack of a cup part based on the measurement result of a measurement means.

(5) The measuring means monitors the change in the outer diameter of the cup portion during heating of the shaft portion, and the determining means is the outer diameter of the cup portion immediately before the heating of the shaft portion measured by the measuring means and the shaft portion. The inspection device for a hardened part according to (4), wherein the presence or absence of a crack in the cup part is determined based on a maximum value of the outer diameter of the cup part during heating and a change amount of the outer diameter of the cup part calculated from the maximum value.
According to the quenching part inspection apparatus described in this section, the measuring means constantly monitors (measures) the outer diameter of the cup portion during heating of the shaft portion. And the determination means is based on the measurement result of the measurement means, the amount of change in the outer diameter of the cup part, that is, the outer diameter of the cup part just before the heating of the shaft part and the outer diameter of the cup part during the heating of the shaft part. The amount of change in the outer diameter of the cup is calculated from the maximum value. The determination means determines that there is a crack when the calculation result, that is, the amount of change in the outer diameter of the cup during heating of the shaft exceeds the threshold value, and there is no crack when it is equal to or less than the threshold value. Is determined. The threshold value is set according to the hardened part.
In the aspect of this section, the measurement means uses, for example, a displacement sensor. In this case, the measuring means measures the displacement in the radial direction of the cup portion of the outer race in a state where the shaft portion is supported while the shaft portion is heated, that is, the amount of change in the radius of the cup portion by the displacement sensor. .
As the displacement sensor of the measuring means, for example, a sensor of a type that measures displacement by irradiating an object with laser or infrared rays is used. In this case, as long as the displacement of the end portion on the opening side of the cup portion can be measured, laser or infrared light may be irradiated perpendicularly to the outer race axis, or the outer race axis. You may irradiate with respect to.

(6) The measuring means measures the outer diameter of the cup part before and after the quenching process of the shaft part, and the judging means is the amount of change in the outer diameter of the cup part before and after the quenching process of the shaft part measured by the measuring means. (4) Quenched parts inspection device for determining the presence or absence of burning cracks in the cup based on the above.
According to the quenching part inspection apparatus described in this section, the measuring means measures the amount of change in the outer diameter of the cup portion before and after quenching of the shaft portion. Then, the determination means calculates the difference between the measurement results of the outer diameter of the cup part before and after quenching of the shaft part based on the measurement result of the measurement means, and the calculation result, that is, the outer part of the cup part before and after quenching of the shaft part. When the difference in diameter exceeds the threshold value, it is determined that there is a burning crack, and when it is equal to or less than the threshold value, it is determined that there is no burning crack. The threshold value is set according to the hardened part.

  It is possible to provide a quenched part inspection method and a quenched part inspection apparatus capable of more easily inspecting the presence or absence of quenching cracks while ensuring reliability.

An embodiment of the present invention will be described with reference to FIGS. In the present embodiment, the outer race 1 of the constant velocity joint shown in FIG. 1 is given as an example of the inspection object (hardened part).
As shown in FIG. 1, the outer race 1 (quenched part) includes a cup portion 2 and a shaft portion 4. As shown in FIG. 2, the outer race 1 is induction-hardened in a quenching process through a forging process and a machining process. The quenching process is divided into a first quenching process and a second quenching process. In the first quenching step, the inner surface 3 of the cup part 2 is heated (high-frequency induction heating), and cooled (rapidly cooled) after heating for a predetermined time. Further, in the second quenching step, the shaft portion 4 of the outer race 1 in which the cup portion 2 is quenched in the first quenching step is heated (high frequency induction heating), and cooled (rapidly cooled) after heating for a predetermined time. Then, the outer race 1 in which the quenching process, that is, the quenching process of the cup part 2 and the shaft part 4 has been completed, is tempered in the tempering process.

  Here, in the second quenching step, when the shaft portion 4 of the outer race 1 supported by the shaft center L is heated (high frequency induction heating), first, the shaft portion 4 expands as shown in FIG. . At this time, when the outer race 1 is supported by its axis, the outer race 1 shifts (expands) from the state indicated by the broken line to the state indicated by the solid line, but the position of the opening end 5 of the cup portion 2 is not moved. And in the cup part 2 of the state hardened (martensified) in the 1st hardening process in addition to being originally thin by the expansion | swelling of the shaft part 4, it is shown by FIG.3 (b). As such, the tensile stress increases. Again, the outer race 1 shifts (expands) from the state indicated by the broken line to the state indicated by the solid line due to an increase in the tensile stress, but the position of the open end 5 of the cup portion 2 does not move.

  In the outer race 1, during the heating of the shaft portion 4, when the tensile stress in the cup portion 2 exceeds the yield stress of the material, the cracks occur on the inner surface 3 of the cup portion 2. Thereby, the tensile stress of the cup part 2 is released, and the diameter of the cup part 2 is increased as shown in FIG. Here, in this embodiment, the displacement of the opening end 5 of the cup part 2 in the second quenching step, that is, the displacement of the opening end 5 of the cup 2 during heating of the shaft part 4 is shown in FIG. Monitoring (measurement) is performed by the displacement sensor 6 (measurement means), and based on the measurement result of the displacement sensor 6, the control unit (determination means) composed of a microcomputer performs arithmetic processing (determination processing) of the inner surface 3 of the cup portion 2. The presence or absence of burning cracks is determined.

  In the present embodiment, as shown in FIG. 4, as shown in FIG. 4, the occurrence of burning cracks on the inner surface 3 of the cup 2 appears prominently as the displacement of the opening end portion 5 of the cup portion 2. The open end 5 is guided in the radial direction (left-right direction in FIG. 4) by the work receiver 7.

Next, based on the flowchart shown in FIG. 5, the flow of processing for determining whether or not there is a crack in the inner surface 3 of the cup portion 2 of the outer race 1 (quenched part) will be described.
First, in the second quenching step, the position of the open end 5 of the cup part 2 immediately before heating the shaft part 4, that is, the outer diameter of the cup part 2 is measured by the displacement sensor 6 (measurement means) (FIG. 5). Step 1). The output signal of the displacement sensor 6 is transmitted to a control unit (determination means), and converted into displacement data (hereinafter referred to as outer diameter data of the cup portion 2) of the opening end portion 5 of the cup portion 2 in the control unit. And a control unit extracts the maximum value of the outer diameter data of the cup part 2 during the heating of the shaft part 4 (step 2 of FIG. 5).

Next, the control unit determines the difference between the outer diameter data of the cup portion 2 immediately before the heating of the shaft portion 4 and the maximum value of the outer diameter data of the cup portion 2 during the heating of the shaft portion 4, that is, the cup portion 2 A change amount D1 of the outer diameter is calculated (step 3 in FIG. 5). Then, the control unit compares the outer diameter change amount D1 of the cup part 2 with the threshold value D0 stored in the data area (RAM) of the control unit (step 4 in FIG. 5), and the outer diameter of the cup part 2 When the amount of change D1 is less than or equal to the threshold value D0 (D0 ≧ D1, Y in step 4 in FIG. 5), it is determined that there is no burning crack on the inner surface 3 of the cup portion 2 (step 5 in FIG. 5). When the outer diameter change amount D1 of 2 is larger than the threshold value D0 (D0 <D1,
N in step 4 in FIG. 5, it is determined that there is a burning crack on the inner surface 3 of the cup portion 2 (step 6 in FIG. 5).

This embodiment has the following effects.
When the outer race 1 (quenched part) is heated (high-frequency induction heating) in the second quenching step performed after the inner surface 3 of the cup portion 2 is quenched, that is, in the step of quenching the shaft portion 4. First, the shaft portion 4 expands, whereby the tensile stress in the cup portion 2 that has been originally hardened (martensite) in the first quenching process is increased. And if the tensile stress in the cup part 2 exceeds the yield stress of a material, a crack will generate | occur | produce in the inner surface 3 of the cup part 2. FIG.
When the crack is generated in the cup part 2, the tensile stress in the cup part 2 is released, and the outer diameter of the cup part 2 is expanded. And this embodiment pays attention to this phenomenon, ie, the correlation of the variation | change_quantity of the outer diameter of the cup part 2 during the heating of the shaft part 4, and a burning crack, The cup part 2 during the heating of the shaft part 4 Based on the change in the outer diameter, the presence or absence of burning cracks in the cup portion 2 is inspected (determined).
Therefore, in the present embodiment, for example, means for giving a hit to the inspection object (outer race 1), means for detecting an ultrasonic wave emitted from the inspection object given the hit, means for analyzing the detected ultrasonic wave (FFT) In addition, as compared with the prior art including a means (determination program) for determining the presence or absence of burning cracks in the inspection object based on the analysis result of FFT, it is easier to crack the outer race 1 while ensuring reliability. It is possible to inspect for the presence or absence of, and the inspection can be simplified. Furthermore, in this embodiment, the apparatus and the program necessary for the determination are extremely simple, and can be configured at low cost.

In addition, embodiment is not limited above, For example, you may comprise as follows.
As shown in FIG. 4, the displacement sensor 6 (measuring means) of the present embodiment directs measurement light (for example, laser or infrared rays) toward the opening side end portion 5 of the cup portion 2 and the axial center of the outer race 1. Although the non-contact type displacement sensor 6 that irradiates perpendicularly to L is used, if the displacement of the opening side end portion 5 of the cup part 2 can be measured with high accuracy, the contact type displacement sensor is used. It is also possible to irradiate the measurement light parallel to the axis of the outer race 1.

It is a perspective view of the outer race of the constant velocity joint as an inspection target object (hardened part) of this embodiment. It is a figure explaining the outline of the manufacturing process of the outer race of this embodiment. It is a figure which shows the one side of the cross section of the outer race of this embodiment, Comprising: (a) shows the state which the shaft part expanded, (b) shows the state where the tensile stress of the cup part was increased, ( c) shows a state in which the diameter of the cup portion has been expanded due to the occurrence of burning cracks on the inner surface of the cup portion. It is explanatory drawing which shows schematic structure of the inspection apparatus of this embodiment. It is a flowchart figure explaining the flow of processing of the inspection method of this embodiment.

Explanation of symbols

1 outer race (hardened parts), 2 cup, 3 inner surface, 4 shaft, 5 open end, 6 displacement sensor (measuring means)

Claims (6)

A quenching part is composed of a cup part and a shaft part, and includes a first quenching process for quenching the cup part, and a second quenching process for quenching the shaft part.
A method for inspecting a hardened part, wherein a change in the outer diameter of the cup part in the second quenching step is measured, and whether or not the cup part is cracked is determined based on the measurement result. Changes in the outer diameter of the cup portion during heating of the shaft portion, and the maximum value of the outer diameter of the cup portion immediately before heating of the shaft portion and the outer diameter of the cup portion during heating of the shaft portion The method for inspecting a hardened part according to claim 1, wherein presence / absence of quench cracking in the cup portion is determined based on a change amount of the outer diameter of the cup portion calculated from: Measure the outer diameter of the cup part before and after quenching the shaft part, and determine whether the cup part is cracked based on the amount of change in the outer diameter of the cup part before and after quenching the shaft part. The method for inspecting a hardened part according to claim 1. A quenching part consists of a cup part and a shaft part, and after quenching the cup part, the quenching part is subjected to quenching process,
Measuring means for measuring a change in the outer diameter of the cup portion in the step of quenching the shaft portion;
Determination means for determining the presence or absence of burning cracks in the cup portion based on the measurement result of the measurement means;
A device for inspecting hardened parts, comprising: The measuring means monitors a change in the outer diameter of the cup portion during heating of the shaft portion, and the determining means is configured to determine the outer diameter of the cup portion immediately before the heating of the shaft portion measured by the measuring means. And determining the presence or absence of burning cracks in the cup portion based on the amount of change in the outer diameter of the cup portion calculated from the maximum value of the outer diameter of the cup portion during heating of the shaft portion. The inspection apparatus for hardened parts according to claim 4. The measuring means measures the outer diameter of the cup portion before and after the quenching treatment of the shaft portion,
The said determination means determines the presence or absence of the quench crack of the said cup part based on the variation | change_quantity of the outer diameter of the said cup part before and behind the quenching process of the said shaft part measured by the said measurement means. 4. The inspection apparatus for hardened parts according to 4.