JP2010237179A - Test sample mounting device, bending testing apparatus, bending test method, bending test program, and test sample - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a test sample mounting device, a bending testing apparatus, and a bending testing method, etc. which can accurately apply load to an object. <P>SOLUTION: Test sample mounting devices 13a and 13b for use in a bending testing apparatus for measuring the durability of a test sample by bending the test sample by applying load to the test sample includes shaft sections 22a and 22b turning holding sections 21a and 21b with the bending and enabling the pair of holding sections 21a and 21b to move close to or away from each other. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an apparatus and method related to a bending strength test for testing fatigue or fracture limit for bending of an object (test sample), and more specifically, bending strength for accurately applying a load to the object. The present invention relates to a test apparatus and method.

  In recent years, with the high functionality and high performance of a system using an IC card, the increase in damage caused by failure and the social impact are also increasing, and high reliability is required for the IC card. It has become.

  Generally, in the actual use of an IC card (the stage where it is actually used by a user), various external forces are applied to the IC card. For example, when the IC card is taken out from a wallet or a card case or when the IC card is set in a reader / writer device, a load is applied with both end faces and flat portions of the IC card as fulcrums.

  When the load is continuously applied, the IC card is damaged, and a failure due to the damage occurs. In order to prevent such a failure, various reliability tests are performed on the IC card.

  In Patent Document 1, in order to conduct a characteristic evaluation test of an identification card (Japanese Industrial Standard JISX6305), both ends of the card are fixed, and a bending fatigue test is performed by applying a load (buckling load) from the fixed position toward the center of the card. An invention relating to a bending test apparatus to be performed is disclosed.

  In Patent Document 2, in order to apply a bending strength test (Japanese Industrial Standard JISR1601) to a reliability test of an IC card, a pressing tool that grips both ends of the IC card with a rubber material and holds the front and back surfaces of the IC card is used. An invention relating to a bending test apparatus for a card that applies a load to the central portion of the IC card is disclosed.

JP 2005-315691 A Japanese Patent Application Laid-Open No. 07-210636

  There is no problem when the invention described in Patent Document 1 is applied to an identification card test method (Japanese Industrial Standard JISX6305).

  However, the load applied to the IC card in the bending strength test (Japanese Industrial Standard JISR1601) is more effective than the load applied to the IC card in the characteristic evaluation test of the identification card. It is close to how the load applied to is applied.

  Therefore, in the invention described in Patent Document 1, a reliability test in consideration of the actual use cannot be performed. Further, it is not suitable for taking load-breakage data at the structural evaluation stage or the like.

  Further, the invention described in Patent Document 2 grips the end portion of the IC card with rubber. Therefore, when a load is applied to the IC card, the position is likely to be displaced, and the end portion of the IC card is worn by the rubber. Will occur. Further, when the load applied to the IC card increases and the amount of bending (the amount of deformation of the IC card in the load direction due to the load) increases, the linear distance between the opposing ends of the IC card rather than the distance between the opposing gripping parts. Becomes shorter and the IC card falls off the gripping portion. Therefore, the three-point bending strength test cannot be continued, and is not suitable for measuring the bending limit (load when the IC card breaks).

  On the other hand, if the distance between the gripping parts facing each other is too short, the IC card does not bend due to the above load, which is different from the actually used bent state.

  In recent years, various electronic components (for example, an IC chip) are mounted on the IC card. In the above reliability test, the strength of the IC card device itself can be measured, but the reliability of the mounted electronic component (for example, how much load is applied to the IC card until the IC card functions) It was not possible to measure whether or not

  Therefore, the present invention has been made in view of the above problems, and an example of the purpose thereof is to reliably apply a load to the test sample in a bending strength test for testing fatigue and fracture limit against bending of the test sample. Another object of the present invention is to provide a test sample mounting device, a bending fatigue test device, and the like that can accurately measure the applied load.

  In order to solve the above-mentioned problem, the test sample mounting device according to claim 1 is used in a bending strength test device that bends a test sample by applying a load and measures the durability of the test sample. A test sample mounting device that is mounted on each of a pair of opposed ends of a sample, the fixing unit, and an attachment that can be attached to the fixing unit at a position close to or away from the fixing unit And a pair of gripping portions for gripping both end portions of the test sample inserted on these facing surfaces, and a direction perpendicular to the direction in which the test sample is bent. A shaft portion that is provided and pivots with the bending to enable the pair of gripping portions to move so as to approach or separate from each other.

  According to the present invention, when a load is applied to the test sample mounted on the test sample mounting device by the bending strength test device and the test sample is bent, the pair of gripping portions are bent in the direction in which the test sample is bent. Move vertically with respect to.

  Therefore, since the test sample is bent in a state where both ends are gripped, the bending of the test sample in actual use is reproduced, and a reliability test with higher reproducibility can be performed. In addition, even when the load applied to the test sample increases and the bending amount (the amount by which the test sample deforms in the load direction due to the load) increases, the test sample is reliably loaded without dropping from the gripping portion. Is added. Further, since the gripping part moves while rotating, an extra load is not applied to the test sample, and the natural bending state of the test sample can be reproduced in the reliability test.

  A test sample mounting apparatus according to a second aspect is the test sample mounting apparatus according to the first aspect, wherein the shaft portion includes a pair of bearings at positions facing each other via the grip portion.

  Therefore, since the test sample is bent in a state where both ends are gripped, the bending of the test sample in actual use is reproduced, and a reliability test with higher reproducibility can be performed. Moreover, even if the load applied to the test sample increases and the amount of bending increases, the test sample is reliably applied without dropping from the gripping portion. Further, since the gripping part moves while smoothly rotating, no extra load is applied to the test sample, and the natural bending state of the test sample can be reproduced in the reliability test.

  A test sample mounting apparatus according to a third aspect is the test sample mounting apparatus according to the first aspect, wherein the shaft portion is provided so as to be rotatable with respect to the grip portion.

  Therefore, since the test sample is bent in a state where both ends are gripped, the bending of the test sample in actual use is reproduced, and a reliability test with higher reproducibility can be performed. Moreover, even if the load applied to the test sample increases and the amount of bending increases, the test sample is reliably applied without dropping from the gripping portion. Further, since the gripping portion moves while rotating more smoothly, an extra load is not applied to the test sample, and the natural bending state of the test sample can be reproduced in the reliability test.

  The test sample mounting device according to claim 4 is the test sample mounting device according to any one of claims 1 to 3, wherein the gripping portion passes through the rotation center axis, and The target shape is formed with reference to a virtual plane perpendicular to the moving direction.

  Therefore, it is possible to apply a gripping part (common part) having the same shape or function to the pair of gripping parts, and to suppress the manufacturing cost for the test sample gripping apparatus and the bending strength test apparatus at low cost. it can. Further, since the test sample gripping device and the bending strength test device can be manufactured with a simple configuration, the failure rate of the device can be reduced.

  The test sample mounting device according to claim 5 is the test sample mounting device according to any one of claims 1 to 4, wherein a movable member provided at both ends of the shaft portion, and the movable member A pair of rail members having a U-shaped opening portion provided at the bottom, and the rail member is provided such that the opening portions are opposite to each other.

  Accordingly, since the gripping part moves while rotating more smoothly, an extra load is not applied to the test sample, and the natural bending state of the test sample can be reproduced in the reliability test.

  The test sample mounting apparatus according to claim 6 is the test sample mounting apparatus according to any one of claims 1 to 5, wherein the shaft portion is provided to be rotatable with respect to the movable member. .

  Therefore, since the gripping part moves while rotating more smoothly, an extra load is not applied to the test sample, and the natural bending state of the test sample can be reproduced in the reliability test.

  A bending strength test apparatus according to claim 7 is a bending strength test apparatus using the test sample mounting apparatus according to any one of claims 1 to 6, wherein a load applied to the test sample is measured. A pushing load detecting means for continuously detecting; and a pushing displacement detecting means for continuously detecting the amount of deformation of the test sample by the load.

  Therefore, since a load (limit load) required until the test sample is destroyed can be measured in real time, a test sample having high reliability that can withstand actual use can be provided. In addition, since the amount of deformation (limit displacement) of the card required until the test sample is destroyed can be measured in real time, it is possible to provide a highly reliable test sample that can withstand actual use.

  In addition, since the load and the displacement when the electronic component mounted on the test sample is destroyed can be measured in real time, a test sample having high reliability that can withstand actual use is provided. Can do.

  The bending strength test method according to claim 8 is a bending strength test method using the test sample mounting device according to any one of claims 1 to 6, wherein a load applied to the test sample is measured. It has a pressing load detection step for continuously detecting, and a pressing displacement detection step for continuously detecting the amount of deformation of the test sample due to the load.

  The test sample according to claim 9 is inspected by the bending strength test method according to claim 8.

  As described above, according to the present invention, when a load is applied to the test sample mounted on the test sample mounting device by the bending strength test device and the test sample is bent, the pair of gripping portions are connected to the test sample. Since the sample moves in a direction perpendicular to the direction in which the sample is bent, it is possible to reliably apply a load to the test sample and accurately measure the applied load.

It is a general-view figure shown about the structure and function outline | summary of a bending strength test apparatus. It is a perspective view which shows the structure of a test sample mounting part. It is detail drawing which shows the detail of a structure of the test sample mounting apparatus 13a. It is a schematic diagram which shows the outline | summary of operation | movement of the test sample mounting apparatus concerning this embodiment, and FIG. 5 is a graph which shows the outline | summary of a measurement result. 7 is a graph showing an example of a measurement result displayed on the display unit 8. It is detail drawing which shows the detail of 2nd Embodiment of the test sample mounting apparatus concerning this embodiment. It is detail drawing which shows the detail of 3rd Embodiment of the test sample mounting apparatus concerning this embodiment. It is detail drawing which shows the detail of 4th Embodiment of the test sample mounting apparatus concerning this embodiment. 5 is a conceptual diagram showing the shape of a gripping part 71 in a test sample mounting device 70. FIG. It is detail drawing which shows the detail of 5th Embodiment of the test sample mounting apparatus concerning this embodiment. It is detail drawing which shows the detail of 6th Embodiment of the test sample mounting apparatus concerning this embodiment. It is detail drawing which shows the detail of 7th Embodiment of the test sample mounting apparatus concerning this embodiment.

  Hereinafter, the best embodiment of the present application will be described with reference to the accompanying drawings. In addition, embodiment described below is embodiment at the time of applying this application with respect to a bending strength test apparatus. The following embodiments do not limit the invention according to each claim, and all the combinations of features described in the embodiments are essential for the solution of the invention. Not exclusively.

  First, the configuration and functional outline of a bending strength test apparatus according to the present embodiment will be described with reference to FIG.

  FIG. 1 is an overview diagram showing the configuration and functional outline of a bending strength test apparatus.

  As shown in FIG. 1, the bending strength test apparatus S includes a base 1, shafts 2 a and 2 b erected in the vertical direction with respect to the base 1, and vertical movement along the shafts 2 a and 2 b by the power of the actuator 3. A head 4 movably provided in the direction, a load cell 5 attached to the head 4 for measuring a load applied to the test sample, a pressure contact portion 6 attached to the load cell 5 for applying a load to the test sample, and a base described later 1, a test sample mounting portion T on which a test sample is installed, a control unit 7 as an indentation load detection unit and an indentation displacement detection unit of the present application, and a liquid crystal display or the like that displays information such as characters and images An operation unit 9 that receives an operation instruction from an operator or the like and outputs the content of the instruction to the control unit 7 as an instruction signal; Composed of a storage unit 10 or the like for recording over de a disk drive such as various programs and data, and the like.

  Explaining in more detail each part of the above configuration, the bending strength test apparatus S applies a load so as to cause bending of the test sample to be tested, and measures the fatigue and the like of the test sample against bending. It is. A known bending tester or a material tester can be applied to the bending strength test apparatus S, but is not limited thereto.

  The actuator 3 is a mechanical or hydraulic / pneumatic device for allowing the head 4 to move in the vertical direction along the shafts 2a and 2b under the control of the control unit 7. As an example, a pneumatic actuator, A hydraulic actuator or an electric motor is applied.

  The load cell 5 is a sensor that detects a load. When a load is applied, the load cell 5 converts the load cell 5 into an electrical signal and outputs the signal to the outside. In the present embodiment, under the control of the control unit 7, the load applied to the test sample by the pressure contact unit 6 is measured, and the measurement result is output to, for example, the display unit 8.

  The pressure contact portion 6 contacts or separates from the test sample by the movement of the head 4 by the actuator 3 and applies a load to the test sample. The test sample is bent and broken as the load increases.

  The control unit 7 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. For example, the CPU reads and executes various programs stored in the ROM and the storage unit. Thus, each part of the bending strength test apparatus S is controlled and functions as the above-described means and the like.

  Specifically, the control unit 7 continuously detects the load applied to the test sample via the load cell 5 and displays the detection result on the display unit 8 or stores it in the storage unit 10. Yes.

  Further, the control unit 8 continuously detects the amount of bending of the test sample due to the load applied to the test sample by an unillustrated infrared sensor or the amount of movement of the head 4, and the detection result to the display unit 8. It is displayed or stored in the storage unit 10.

  Next, the configuration and functional overview of the test sample mounting portion and the test sample device according to the present embodiment will be described with reference to FIGS.

  FIG. 2 is a perspective view showing the configuration of the test sample mounting portion.

  As shown in FIG. 2, the test sample mounting portion T includes four support columns 11 a to 11 d erected in the vertical direction with respect to the base 1, and rails 12 a and 12 b provided between the two support columns. The test sample mounting apparatuses 13a and 13b are movably installed on the rails 12a and 12b, and the test sample 14 is mounted on the test sample mounting apparatuses 13a and 13b with a pair of ends held.

  Explaining each part of the above configuration in more detail, the test sample mounting portion T is a device for mounting the test sample 14 to the bending strength test apparatus S so as to perform the bending strength test on the test sample 14. .

  Although described in detail later, the rails 12a and 12b are rails provided so that the test sample mounting portions 13a and 13b can be moved so as to approach or separate from each other with the load. In this embodiment, rails 12a and 12b having a U-shaped opening and extending linearly are used. However, the present invention is not limited to this. Existing rails can also be used.

  Moreover, the material used for the rails 12a and 12b can be arbitrarily selected, and iron, aluminum, stainless steel, or the like can be used.

  The test sample 14 is a test object of the bending strength test, and in this embodiment, for example, an IC card or the like is applied, but the test sample 14 is not limited to this. For example, an IC card on which a display unit such as a liquid crystal is mounted, a PDA, a mini-notelet, or a portable information terminal device represented by a portable music player can be applied.

  Next, the configuration of the test sample mounting device 13a will be described with reference to FIG.

  FIG. 3 is a detailed view showing details of the configuration of the test sample mounting device 13a.

  As shown in FIG. 3, the test sample mounting device 13a includes a gripping portion 21a as a gripping portion of the present application, a shaft portion 22a as a shaft portion of the present application provided on the gripping portion 21a, and the like.

  The gripping part 21a penetrates a fixing part 23a as a fixing part of the present application and a hole part drilled in a fixing part (not shown), and corresponds to, for example, a general-purpose metric triangular screw standardized by the International Organization for Standardization (ISO) Screws 24a and 24b in which screw threads are formed, nuts 25a and 25b screwed into the screws 24a and 24b, and mounting portions 26a that can be attached to the fixing portion 23a by the screws 24a and 24b and nuts 25a and 25b. Etc.

  Further, the test sample mounting device 13b (not shown) is used in the bending strength test device S as a pair with the test sample mounting device 13a. Here, the configuration of the test sample mounting device 13b is the same as that of the test sample mounting device 13a, and the respective parts not shown are defined as a gripping portion 21b, a shaft portion 22b, a fixing portion 23b, and a mounting portion 26b.

  If it demonstrates in detail about each part of the said structure, the attachment part 26a will be arrange | positioned facing the fixing | fixed part 23a, and the nuts 25a and 25b will adhere to the position opposite to the said opposing surface. Then, by rotating the screws 24a and 24b, the nuts 25a and 25b approach or separate from the heads of the screws 24a and 24b. As a result, the mounting portion 26a also approaches or separates from the fixing portion 23a. Yes.

  And the distance (A part of FIG. 3) of the opposing surface of the fixing | fixed part 23a and the attaching part 26a approaches or separates with the proximity | contact or separation | separation of the fixing | fixed part 23a and the attaching part 26a.

  The grip portion 21a in the present embodiment grips the end portion of the test sample 14 inserted into the facing surface by reducing the distance between the facing surfaces of the fixed portion 23a and the mounting portion 26a. And since the test sample mounting device 13b is mounted on the opposite ends of the gripped test sample 14, both ends of the test sample 14 are gripped.

  The shaft portion 22a is provided in the grip portion 21a in a direction perpendicular to the direction in which the test sample is bent, and the test sample mounting device 13a is installed on the rails 12a and 12b by the shaft portion 22a.

  And if the said bending | flexion arises, it will cause rotation to the holding | grip part 21a by the axial part 22a. By this rotation, the pair of test sample mounting devices 13a and 13b mounted at both ends of the test sample 14 can move so as to approach or separate from each other.

  Next, the outline | summary of operation | movement of a test sample mounting apparatus concerning this embodiment and a measurement result is demonstrated using FIG.4 and FIG.5.

  FIG. 4 is a schematic diagram showing an outline of the operation of the test sample mounting device according to the present embodiment, and FIG. 5 is a graph showing an outline of the measurement result.

  As shown in FIG. 4, the test sample mounting devices 13a and 13b on which the test sample 14 is mounted are movably installed on a rail 12a and a rail 12b (not shown). 4 (a) to 4 (c) show how the pressure contact portion 6 applies a load to the test sample 14 and the test sample 14 is bent in order to perform a bending strength test.

  In FIG. 4, the direction in which a load is applied to the test sample 14 by the pressure contact portion 6, that is, the direction in which the test sample 14 is bent is defined as the Y axis, and the direction perpendicular to the bending direction is defined as the X axis (see FIG. 4-30).

  Further, in order to describe the amount of deformation of the test sample 14 in the Y-axis direction due to the load, a point where the pressure contact portion 6 and the test sample 14 are in contact with each other through the shaft 32 is defined as a Y-axis origin 33.

  Here, the deformation in the X-axis direction of the test sample 14 is the amount by which a pair of opposing ends of the test sample 14 approach or separate from each other as the test sample 14 is bent by the load, in other words. The pair of test sample mounting devices 13a and 13b mounted on both ends of the test sample 14 can be obtained by a displacement approaching or separating.

  Therefore, in order to explain the amount of deformation of the test sample 14 in the X-axis direction due to the bending, the center point of the shaft portion 22a in the test sample mounting device 13a passing through the shaft 31 is set as the X-axis origin 34a, and similarly the shaft 31 Let the center point of the shaft part 22b in the test sample mounting apparatus 13b be the X-axis origin 34b.

  Hereinafter, the outline of the operation of the test specimen mounting apparatus will be described in correspondence with the operation of the bending strength test apparatus S.

  When the bending strength test is started, the control unit 7 brings the pressure contact portion 6 into contact with the test sample 14 in order to continuously apply a load to the test sample 14 (FIG. 4A).

  Then, the control unit 7 continuously applies a load to the test sample 14. Then, the test sample 14 to which the load is applied is bent (FIG. 4B).

  When a load is applied to the test sample 14, as the test sample 14 is bent, the pair of test sample mounting devices rotate about the shaft portion.

  Specifically, the test sample mounting device 13a rotates around the center 34a of the shaft portion 22a in the direction of the rotation direction 36a along the virtual circle 35a. Further, the test sample gripping device 13b rotates on the rail 12a around the center 34b of the shaft portion 22b in the direction of the rotation direction 36a along the virtual circle 35b.

  As a result, the test sample mounting device 12a moves on the rail 12a in the direction of the arrow 37a, and the test sample mounting device 12b moves on the rail 12a, that is, the pair of test sample mounting devices move so as to approach each other. .

  Furthermore, when a load is continuously applied by the control unit 7, the test sample 14 exceeds the elastic limit, undergoes permanent distortion, and then is destroyed (FIG. 4C).

  The control unit 7 continuously detects and stores the load applied to the test sample 14 from when the load is applied to when the load is broken by the load cell 5.

  Further, the control unit 7 continuously detects and stores the deformation amount of the test sample 14 from when the load is applied until it is destroyed.

  Specifically, the test sample 14 is deformed in the Y-axis direction and the X-axis direction by the load. Accordingly, the control unit 7 detects the displacement 38 as the deformation amount in the Y-axis direction and the displacements 39a and 39b as the deformation amounts in the X-axis direction, respectively.

  As a detection method of these deformation amounts, for example, the displacement 38 may be detected by the control unit 7 recording the displacement of the head 4 from when the load is applied until it is destroyed. .

  Further, the displacements 39a and 39b may be detected by, for example, an infrared sensor (not shown), or may be measured visually by a memory written on the rail 12a.

  The control unit 7 records these measurement results and displays them on the display unit 8.

  FIG. 5 is a graph showing an example of the measurement result displayed on the display unit 8.

  As shown in FIG. 5, the graph showing an example of the measurement result is shown by a curve 43 in which the horizontal axis 41 is the displacement 38 (as the amount of deformation in the Y-axis direction), the vertical axis 42 is the load, and Yes.

  In FIG. 5, an IC card on which an IC chip is mounted is applied as an example of the test sample 14.

  A curve 43 shows how the displacement 38 increases as the load increases.

  Generally, when some change occurs in an object to which a load is applied (for example, when the object is an IC card and an electronic component mounted on the IC card is destroyed), the load applied to the object In addition, some change occurs (for example, when the load increases proportionally, the load decreases rapidly).

  The curve 43 shows that the load suddenly decreases from the point 44 to the point 45, and this shows a state in which the electronic component mounted on the IC card to be tested is destroyed.

  It is shown that when the load is continuously applied and the IC card is destroyed (point 46), the load becomes zero.

  As described above, the load and displacement when the IC chip mounted on the IC card is broken can also be measured from the measurement result.

  Further, the load and displacement when the IC chip is broken can be detected more accurately by performing a communication test on the IC chip continuously during the test.

  Such a communication test is performed by transmitting a signal to the IC chip and transmitting a signal indicating that the signal is received from the IC chip. If the IC chip is destroyed while the load is continuously applied, no signal is transmitted from the IC chip, and as a result, the signal cannot be received.

  Therefore, by detecting the load and displacement when the signal cannot be received from the IC chip, the load and displacement when the IC chip is broken can be detected more accurately.

  In addition, a more reliable test sample can be provided with reference to the displacement and load values.

  Specifically, for example, it is assumed that the displacement and the load applied to the test sample 14 in actual use can be assumed to be a load 30 (N) or less and a displacement 30 (mm) or less.

  Then, according to the above test results, when the above displacement and load values applied to the test sample 14 do not occur during the load 30 (N) or more and the displacement 30 (mm), the test sample It can be assumed that 14 can sufficiently withstand actual use (pass).

  The conditions of the test sample 14 on which the test is performed can be adopted as the actual product conditions (for example, the displacement and load values applied to the test sample 14 are a load 30 (N) or more and a displacement). For example, a test sample 14 having a predetermined thickness and material is applied when the above-described destruction does not occur until 30 mm).

  In this way, a test sample with higher reliability can be provided by referring to the values of the displacement and the load and setting the actual product conditions.

  As another evaluation standard, when the electronic component is not mounted inside the test sample 14, the test sample 14 is actually used if it is somewhat soft (even if the displacement is large) or not broken. It may be assumed that it can sufficiently withstand (pass).

  As another evaluation standard, when the electronic component is mounted inside the test sample 14, the test sample 14 needs to be hard, and therefore, the one having the least displacement is selected. May be.

  As another evaluation standard, for example, in the graph of FIG. 4 described above, when there is a sudden change point of the load (in the case where the internal chip is broken), the actual evaluation is performed regardless of the values of the displacement and the load. You may make it judge that it cannot endure use (failed).

  Next, a second embodiment of the test sample mounting device according to this embodiment will be described with reference to FIG.

  FIG. 6 is a detailed view showing the details of the second embodiment of the test sample mounting device according to the present embodiment.

  As shown in FIG. 6, the test sample mounting device in the second embodiment is an example of a pair of bearings at a position facing the test sample gripping device 13a shown in FIG. Each bearing is provided.

  Since the holding portion 21a moves on the rail 12a while rotating smoothly by the bearing, for example, an extra load is not applied to the test sample 14, and the natural bending state of the test sample 14 in the bending strength test is performed. Can be reproduced.

  In this embodiment, a bearing is used as an example of a bearing. However, the present invention is not limited to this. For example, a spacer made of a material having good sliding properties (for example, POM (polyacetal, polyoxymethylene) or the like is applied). Etc. may be used.

  Next, a third embodiment of the test sample mounting device according to this embodiment will be described with reference to FIG.

  FIG. 7 is a detailed view showing the details of the third embodiment of the test sample mounting device according to the present embodiment.

  As shown in FIG. 7, the test sample mounting apparatus according to the third embodiment is provided with a perforated part 61 in the gripping part 21a with respect to the test sample gripping apparatus 13a shown in FIG. The perforated part 61 is a hole that penetrates the grip part 21, and a shaft part 22 a is passed through the hole part.

  Since the shaft portion 22a moves on the rail 12a while rotating smoothly by the perforated portion 61, for example, an extra load is not applied to the test sample 14, and the natural bending of the test sample 14 in the bending strength test is performed. The state can be reproduced.

  Furthermore, you may make it provide a bearing as an example of a pair of bearing in the position which opposes via the holding part 21a.

  Next, a fourth embodiment of the test sample mounting device according to this embodiment will be described with reference to FIG.

  FIG. 8 is a detailed view showing details of the fourth embodiment of the test sample mounting device according to the present embodiment.

  As shown in FIG. 8, the test sample mounting apparatus 70 in the fourth embodiment includes a gripping part 71, a shaft part 72 provided on the gripping part 71, and the like.

  The grip portion 71 includes an attachment portion 73, eleven screws 74a to 74k that pass through holes formed in the attachment portion 73, and screw holes 76a to 76k (XX) that are screwed into the screws 74a to 74k. It is comprised from the fixing | fixed part 75 grade | etc., Which can attach the attaching part 73 by `refer a cross-sectional part).

  If it demonstrates in detail about each part of the said structure, the attaching part 73 will be arrange | positioned facing the fixing | fixed part 75. FIG. Then, by rotating the screws 74a to 74k, the screws 74a to 74k are screwed into the screw hole portions 76a to 76k. As a result, the mounting portion 73 approaches or separates from the fixing portion 75. .

  As with the test sample mounting device 13a, the distance between the opposing surfaces of the fixing portion 75 and the mounting portion 73 (B portion in FIG. 8) approaches or separates as the fixing portion 75 and the mounting portion 73 approach or separate from each other. It has become. And the edge part of the test sample 14 inserted in the said opposing surface is hold | gripped.

  Further, the gripping portion 71 in the test sample mounting apparatus 70 is formed in a target shape with reference to a virtual plane perpendicular to the moving direction of the gripping portion 71 through the rotation center axis (of the gripping portion 70).

  FIG. 9 is a conceptual diagram showing the shape of the gripping portion 71 in the test sample mounting device 70.

  FIG. 9A is a conceptual diagram showing gripping portions 71a and 71b as the shape of the gripping portion 71 of the third embodiment of the test sample mounting device according to the present embodiment.

  As shown in FIG. 9A, the gripping portion 71 passes through the rotation center axis 73 and has a target shape based on a virtual plane 75 perpendicular to the arrow portion 74 that is the moving direction of the gripping portion 71. Is formed. That is, with the virtual plane 75 as a reference, the gripping portions 71a and 71b indicate target shapes.

  FIG. 9B shows more specifically the shapes of the gripping portions 71a and 71b, and shows that the gripping portions 71a and 71b show the target shape with the virtual plane 75 as a reference.

  By forming the gripping portion 71 in the above-described target shape, it is not necessary to consider the load caused by the weight of the test sample mounting device on the test sample 14.

Specifically,
As described above, in the test sample mounting device 70 in which the gripping portions 71a and 71b indicate the target shape with the virtual plane 75 as a reference, the target shape is indicated with reference to the cross-sectional center of the shaft 72 that is the rotation center axis. In other words, the weight balance of the test sample mounting device 70 is equally formed with reference to the center of the cross section.

  Therefore, when the test sample mounting device 70 is installed on the rails 12a and 12b, the test sample mounting device 70 does not rotate in the direction in which the test sample 14 is bent due to the weight balance. Since a load due to the weight of the test sample mounting device is not applied to the test sample, a test with higher accuracy can be performed.

  The test sample mounting device 70 in the present embodiment is formed so that the gripping portions 71a and 71b show the target shape with the virtual plane 75 as a reference in order to equalize the weight balance of the test sample mounting device 70 with the cross-sectional center as a reference. However, the present invention is not limited to this.

  That is, the shape, mass, etc. of the apparatus may be set so that the center of gravity of the test sample mounting apparatus 70 and the rotation center of the apparatus are the same.

  Next, a fifth embodiment of the test sample mounting device according to the present embodiment will be described with reference to FIG.

  FIG. 10 is a detailed view showing details of the fifth embodiment of the test sample mounting device according to the present embodiment.

  As shown in FIG. 10A, the test sample mounting device in the fifth embodiment is different from the test sample gripping device 13a shown in FIG. 3 in the gripping portion 21a and the shaft portion 22a provided in the gripping portion 21a. A movable member 81a and 81b provided at both ends of the shaft 22a via bearings 51a and 51b, a pair of rail members 82a and 83a and 82b and 83b provided at the bottom of the movable members 81a and 81b, and a pair of rails A rail member 84a on which members 82a and 83a are installed, a rail member 84b on which a pair of rail members 82b and 83b are installed, and the like are provided.

  The parts of the above configuration will be described in more detail. The pair of rail members 82a and 83a are rails having an opening having a U-shaped cross section, and the bottom of the movable member 81a is arranged so that the openings are opposite to each other. Provided.

  Further, the cross-sectional shape of the rail member 84a is formed by an opening portion having a U-shaped cross section and sides bent at right angles in directions in which the end portions of the facing surfaces of the opening portions are close to each other. In this case, the cross-sectional shape has a substantially C-shaped cross section.

  And it installs in the opening part of a pair of rail members 82a and 83a so that the said side may each mesh | engage.

  Similarly, the sides of the rail member 84a are installed so as to mesh with the openings of the pair of rail members 82b and 83b.

  Moreover, in the said embodiment, the perforation part which penetrates the holding part 21 may be provided in the holding part 21, and the axial part 22 may be axially penetrated to the said hole part.

  Further, the shaft 22 and the movable members 81a and 81b may be fixed so as not to be movable.

  Furthermore, a known slider may be applied to the pair of rail members 82a and 83a and 82b and 83b, respectively, and a rail corresponding to the slider may be provided on the pair of rail members 84a and 84b.

  Next, a sixth embodiment of the test sample mounting device according to the present embodiment will be described with reference to FIG.

  FIG. 11 is a detailed diagram showing details of the sixth embodiment of the test sample mounting device according to the present embodiment.

  In FIG. 11A, as a sixth embodiment of the test sample mounting device, a surface treatment was applied to the opposing surfaces of the fixing portion 23a and the mounting portion 26a of the test sample mounting device 13a shown in FIG. Things are shown.

  In FIG. 11A, the facing surfaces 90a and 90b, which are the facing surfaces of the fixing portion 23a and the mounting portion 26a of the test sample mounting device 13a, are subjected to embossing or etching treatment as an example of surface treatment, and surface roughness. Is getting rough.

  When the test sample 14 is gripped, the fixing portion 23 a and the attachment portion 26 a are close to each other, and the opposing surfaces 90 a and 90 b are in contact with the test sample 14.

  By such surface treatment, the coefficient of friction between the facing surfaces 90a and 90b and the test sample 14 is higher than the coefficient of friction between the facing surface that has not been surface-treated and the test sample 14. Therefore, it is possible to hold the test sample 14 more firmly by applying the facing surfaces 90a and 90b subjected to the surface treatment.

  The surface treatment can be arbitrarily selected depending on the material of the grip portion 21a. For example, when the material of the grip portion 21a is a resin material (for example, ABS, PC, or the like), embossing or the like is selected as the surface treatment. When the material of the grip portion 21a is a metal material (for example, stainless steel or aluminum), blasting or the like is selected as the surface treatment.

  FIG. 11B shows a sixth embodiment of the test sample mounting device in which uneven rubbers 91a and 91b are installed on the opposing surfaces of the fixing portion 23a and the mounting portion 26a of the test sample mounting device 13a. It is shown.

  Similarly to FIG. 11A, the friction coefficient between the rubbers 91a and 91b and the test sample 14 is higher than the friction coefficient between the facing surface not subjected to the surface treatment and the test sample 14. Therefore, it is possible to hold the test sample 14 more firmly by applying the facing surfaces 90a and 90b subjected to the surface treatment.

  Next, a seventh embodiment of the test sample mounting device according to the present embodiment will be described with reference to FIG.

  FIG. 12 is a detailed view showing details of the seventh embodiment of the test sample mounting device according to the present embodiment.

  As described above, the control unit 7 continuously detects and stores the load applied to the test sample 14 from when the load is applied to when the load is broken by the load cell 5. At this time, the detected load (measurement result) includes a so-called resistance force such as a kinetic frictional force between the test sample gripping device 13a (and 13b) and the rail 12a (and 12b).

  In the present embodiment, calibration is performed in advance, in which the resistance is measured in advance and subtracted from the measurement result of the bending test. By performing such calibration, a more accurate measurement result can be obtained.

  In FIG. 12, a wire 100 for fastening the test sample gripping device 13a and the press contact portion 6 is hung on a shaft 100 provided between the rail 12a and the rail 12b (not shown) in order to perform the calibration.

  When the head 4 is raised (moved in the direction of the arrow 102 in FIG. 12), the tension is applied to the wire 100. As a result, the test sample gripping device 13a moves along the rail 12a and the rail 12b (not shown) along the arrow 103 in FIG. Move in the direction.

  The tension can be controlled by the force that moves the test sample gripping device 13a, that is, the resistance force.

  The resistance can be measured by measuring the tension with the load cell 5. A more accurate measurement result can be obtained by subtracting the measured tension from the measurement result of the bending test.

  As described above, in the present embodiment, the test sample mounting devices 13a and 13b that are mounted on a pair of opposing ends of the end portion of the test sample 14 are fixed to the fixed portion 23a and the fixed portion 23b, respectively. Mounting portions 26a and 26b that can be attached to the fixing portion 23a and the fixing portion 23b are arranged to face each other at positions close to or away from the portion 23a and the fixing portion 23b, and the test sample 14 inserted into these opposing surfaces A pair of gripping portions 21a and 21b for gripping both ends of the test piece 14 and the gripping portions 21a and 21b are provided in a direction perpendicular to the direction in which the test sample 14 bends. The shaft portions 22a and 22b are configured to rotate and to move the pair of gripping portions 21a and 21b so as to approach or separate from each other.

  Therefore, when a load is applied to the test sample 14 mounted on the test sample mounting devices 13a and 13b by the bending strength test device S and the test sample 14 is bent, the test sample 14 is bent at the pair of gripping portions. Since it moves in the direction perpendicular to the direction, the bending of the test sample 14 during actual use is reproduced, and a reliability test with higher reproducibility can be performed. Further, even if the load applied to the test sample 14 increases and the amount of bending increases, the test sample is reliably applied without dropping from the gripping portion. Further, since the gripping part moves while rotating, an extra load is not applied to the test sample, and the natural bending state of the test sample can be reproduced in the reliability test.

  Further, the shaft portions 22a and 22b of the test sample mounting devices 13a and 13b can be provided with a pair of bearings at positions facing each other via the grip portions 21a and 21b.

  Accordingly, since the gripping portions 21a and 21b move while smoothly rotating, no extra load is applied to the test sample, and the natural bending state of the test sample can be reproduced in the reliability test.

  Further, the shaft portions 22a and 22b of the test sample mounting devices 13a and 13b can be provided so as to be rotatable with respect to the grip portions 21a and 21b.

  Therefore, since the gripping portions 21a and 21b move while rotating more smoothly, an extra load is not applied to the test sample, and the natural bending state of the test sample can be reproduced in the reliability test.

  In addition, the grip portion 71 of the test sample mounting device 70 is formed in a target shape with reference to a virtual plane 75 that passes through the rotation center axis and is perpendicular to the movement direction of the grip portion 71. Yes.

  Therefore, a gripping part having the same shape or function can be applied to the pair of gripping parts, and the manufacturing cost for the test sample gripping apparatus and the bending strength test apparatus can be kept low. Further, since the test sample gripping device and the bending strength test device can be manufactured with a simple configuration, the failure rate of the device can be reduced.

  Further, the test sample mounting device 13a includes a pair of rail members 82a having movable members 81a and 81b provided at both ends of the shaft portion 22a, and U-shaped openings in the bottom of the movable members 81a and 81b. , 82b, 83a and 83b, and the rail members 82a and 83a and 82b and 83b may be provided so that the openings are opposite to each other.

  Accordingly, since the gripping part moves while rotating more smoothly, an extra load is not applied to the test sample, and the natural bending state of the test sample can be reproduced in the reliability test.

  The control unit 7 continuously detects the load applied to the test sample 14 and continuously detects the amount of deformation of the test sample due to the load.

  Therefore, since a load required until the test sample is destroyed can be measured in real time, a test sample having high reliability that can withstand actual use can be provided. In addition, since the amount of deformation (limit displacement) of the card required until the test sample is destroyed can be measured in real time, it is possible to provide a highly reliable test sample that can withstand actual use.

  In addition, since the load and the displacement when the electronic component mounted on the test sample is destroyed can be measured in real time, a test sample having high reliability that can withstand actual use is provided. Can do.

  In the above embodiment, the IC card is applied as an example of the test sample 14, but the present invention is not limited to this. For example, a substrate on which an electromagnetic component is mounted, a portable terminal device, a PDA, or other electronic equipment can be used as the test sample.

  Moreover, the material of each part (gripping part 21a etc.) constituting the test sample mounting part T can be arbitrarily selected, and iron, aluminum, stainless steel or the like can be selected depending on the use application (for example, durability). It can also be applied.

DESCRIPTION OF SYMBOLS 1 Base 2a Shaft 2b Shaft 3 Actuator 4 Head 5 Load cell 6 Pressure contact part 7 Control part 8 Display part 9 Operation part 10 Memory | storage part 11a Post 11b Post 11c Post 11d Post 12a Rail 12b Rail 13a Test sample holding device 13b Test sample holding device 21a , 21b, 71 Grip part 22a, 22b, 72 Shaft part
23a, 23b, 75 fixing part 24a, 24b, 74a, 74b, 74c, 74d, 74e, 74f, 74g, 74h,
74i, 74j, 74k Screws 25a, 25b Nuts 26a, 26b, 76 Mounting portions 51a, 51b Bearings 74a, 74b, 74c, 74d, 74e, 74f, 74g, 74h, 74i, 74j,
74k Screw part 81a, 81b Movable member 82a, 82b, 83a, 83b, 84a, 84b Rail member 90a, 90b, 91a, 91b Opposing surface S Bending strength test device T Test sample mounting part

Claims (9)

Used for a bending strength test apparatus that bends a test sample by applying a load and measures the durability of the test sample, and is attached to a pair of opposite ends of the test sample. A device,
A fixing portion and an attachment portion that can be attached to the fixing portion at a position close to or away from the fixing portion are arranged to face the fixing portion, and the test sample inserted into these opposing surfaces A pair of gripping portions for gripping both ends,
The grip portion is provided in a direction perpendicular to the direction in which the test sample bends, and the grip portion is rotated in accordance with the bend, so that the pair of grip portions can be moved close to or away from each other. The shaft,
A test sample mounting apparatus comprising: The test sample mounting device according to claim 1,
The test sample mounting device according to claim 1, wherein the shaft portion includes a pair of bearings at positions opposed to each other via the grip portion. The test sample mounting device according to claim 1,
The test sample mounting device, wherein the shaft portion is provided so as to be rotatable with respect to the grip portion. The test sample mounting device according to any one of claims 1 to 3,
The test sample mounting apparatus according to claim 1, wherein the gripping part is formed in a target shape with reference to a virtual plane perpendicular to the moving direction of the gripping part, passing through the rotating central axis of rotation. The test sample mounting device according to any one of claims 1 to 4,
A movable member provided at both ends of the shaft portion;
A pair of rail members having a U-shaped opening in cross section provided at the bottom of the movable member;
With
The test sample mounting device, wherein the rail member is provided so that the opening portions are opposite to each other. The test sample mounting device according to any one of claims 1 to 5,
The test sample mounting device, wherein the shaft portion is provided so as to be rotatable with respect to the movable member. A bending strength test apparatus using the test sample mounting apparatus according to any one of claims 1 to 6,
Indentation load detecting means for continuously detecting the load applied to the test sample;
Indentation displacement detecting means for continuously detecting the amount of deformation of the test sample due to the load;
A bending strength test apparatus comprising: A bending strength test method using the test sample mounting device according to any one of claims 1 to 6,
An indentation load detection step of continuously detecting a load applied to the test sample;
An indentation displacement detection step for continuously detecting the amount of deformation of the test sample due to the load;
A bending strength test method characterized by comprising:   A test sample inspected by the bending strength test method according to claim 8.

Images