JPH0738187U - Suture strength tester - Google Patents

Abstract

(57) [Summary] [Purpose] An object of the present invention is to provide a suture strength testing device capable of accurately measuring the strength of a suture in a stretchable sample and obtaining the measurement result numerically. To do. [Structure] A strip-shaped sample (1
Winding part (39) for respectively winding and gripping both ends of (0)
(39) a pair of holding members (40) provided so as to face each other, and a direction in which at least one of the pair of holding members (40) moves away from or approaches one of the other holding members (40). A suture strength testing device (38) comprising a moving means for moving the holding member (40) and a load cell (24) for measuring a tensile load applied to at least one of the holding members (40).

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a test device for measuring the strength of a stitched part, and more particularly to a test device for strength of a stitched part that tests the strength of a stitched part in a stretchable knitted fabric such as a stocking material.

[0002]

[Prior art]

 Conventionally, the strength of the sutured part of stockings such as pantyhose has been measured by a wearing test. However, in the wearing test, the behavior varies depending on the wearer, so the test results obtained are ambiguous, and it is difficult to express the measurement results as numerical values. Have Therefore, the strength of the sutured part is measured by using the Murren burst tester.

The Mullen burst tester applies pressure to a sample to cause the sample to burst, and measures the pressure at that time. An outline of the main components is described with reference to FIG. The upper part of the handle (1) is provided with a disc-shaped upper clamp (2) and the lower clamp (3) is provided below the disc-shaped upper clamp (2). The upper clamp (2) is provided with an upper through hole (4) at the center and a transparent case (5) at the top, and can be moved up and down by a handle (1). Further, the lower clamp (3) has a lower through hole (6) opened in the central portion and is located above the pressure portion (8) via the rubber film (7). The rubber film (7) receives pressure from the pressure portion (8) and expands upward from the lower through hole (6) by this pressure. Then, this burst tester positions the sample (10) between the upper clamp (2) and the lower clamp (3) so that the sutured portion (9) is located at the center of both through holes. The rubber film (7) is expanded to apply a pressure to the sample (10) to rupture it, and the pressure applied to the rubber film (7) at this time is measured as the burst strength.

However, in knitted fabrics such as stockings, the sewing thread has a strength superior to that of the material thread, and the cause of the rupture of the suture portion (9) is mainly the cutting of the material thread or the slipping of the material thread. It will be That is, when pressure is applied from the rubber film (7), the fabric thread having excellent elasticity expands together with the rubber film (7), but the sewing thread has only a certain degree of elasticity, so the rubber film ( It will have tension due to the pressure from 7). In other words, the sewing thread presses or tightens the material thread. Therefore, the pressure exerted on the fabric at the time of rupture is due to the rubber film (7) and the sewing thread, and the measured value that displays only the pressure from the rubber film (7) as the pressure at rupture is accurate. Not a thing. Further, the measurement results obtained from such a test are greatly influenced by the tension of the sewing thread, and it is not possible to obtain reproducible measurement results.

Therefore, in order to improve such a thing, the strength of the sutured portion is measured by using a tensile tester as shown in FIG. This tensile tester (11) measures the tensile load applied to the sample (10) by pulling the sample (10) to damage the sutured part (9) of the sample (10). The left vertical frame body (13) and the right vertical frame body (14) standing upright on the base (12), and the horizontal frame body (15) and the left and right vertical frames provided above them. A crosshead (16) provided between the bodies (13) and (14), a pair of chucks (17) provided below the crosshead (16), and an upper part of the base (12). It consists of a control box (18) provided on the right side.

[0006] The left vertical frame body (13) and the right vertical frame body (14) are U-shaped in cross section, each have an opening, and are erected in a state of being oriented in the same direction. . The left vertical frame body (13) is provided with a screw shaft (19) in the inner space of the U-shaped body, and the screw shaft (19) is mounted on the base (12) to the transmission motor (20). ), And is rotatably supported. The right vertical frame body (14) has a guide shaft (21) standing upright in the inner space of the U-shape.

The crosshead (16) is provided with a left support portion (22) on the left side surface and a right support portion (23) on the right side surface, and a concave portion for disposing the load cell (24) in the central portion. (25). The crosshead (16) has a nut portion A (26) formed on the left support portion (22), and the screw shaft (19) is screwed onto the nut portion A (26). Further, a round hole (27) is formed in the right support portion (23), and the guide shaft (21) is inserted through the round hole (27). That is, the crosshead (16) moves up and down with the guide shaft (21) as a guide as the screw shaft (19) rotates. The load cell (24) measures the load applied to the lower part, and has a universal joint (28) connected to the lower part.

Further, the chucks (17) are a pair of two chucks each consisting of an upper chuck (29) and a lower chuck (30) provided below the upper chuck (29). The lower chuck (30) is connected to the lower part of the universal joint (28), while the lower chuck (30) is fixed to the upper part of a support table (31) provided on the base table (12). As shown in FIG. 9, the chuck (17) has a connecting portion (32) for connecting to the above position, a substantially U-shaped gripping portion (33), and a U-shaped gripping portion (33). It is composed of a pressing plate (34) located in a character-shaped space. The grip portion (33) has a nut portion B (35) formed on one side wall of a U shape, and the screw body (36) is inserted into the nut portion B (35). The pressing plate (34) is fixed to the tip of the screw body (36). That is, the chuck part (17) positions the sample (10) between the other side wall of the grip part (33) and the pressing plate (34) and rotates the screw body (36) to rotate the pressing plate (34). ) Is clamped to hold the sample (10).

The control box (18) is connected to the shift motor (20) and controls the shift motor (20). Then, in this control box (18), a pulling speed setting switch for setting the pulling speed of the sample (10), a one-time mode for testing the sample (10) by pulling only once, and a sample (10) Repeat pull several times to perform a test.A pull mode selection switch that selects the repeat mode, and a count setting switch that sets the number of repetitions when the repeat mode is selected, top dead center, and bottom dead center. Various switches are provided, such as a stop time setting switch for setting the stop time of the. A recorder (37) is provided above the control box (18), and the recorder (37) is linked with the load cell (24) and measured by the load cell (24). The load is to be recorded.

Then, such a tensile tester (11) selects the tensile mode after mounting the sample (10) on the upper chuck part (29) and the lower chuck part (30). ), And then the suture part of the sample (10) was damaged, and when the sample (10) was damaged, the load (load measured by the load cell (24)) applied to the sample (10) was applied. The measurement is displayed.

[0011]

[Problems to be solved by the present invention]

 However, when a test is conducted using the above tensile tester (11), when the sample (10) is a knitted fabric, especially a stocking fabric having an excellent expansion / contraction ratio, the fabric is stretched so much that the chuck ( Only the stocking material near 17) is loaded, and the material near the chuck (17) is damaged before the sewn part (9) bursts, which makes it impossible to measure the strength of the sewn part (9). .

As described above, the conventional measuring instrument has some drawbacks, and no dedicated device for measuring the strength of the suture portion has been provided so far. Especially, the suture for a stretchable sample such as stocking fabric is sutured. The advent of a device that accurately measures the strength of parts has long been awaited.

The present invention has been made in view of such circumstances, and it is possible to accurately measure the strength of a sutured portion in a stretchable sample such as stocking cloth, and to repeat the measurement result. It is an object of the present invention to provide a suture portion strength test device that can be obtained with a certain numerical value.

[0014]

[Means for Solving the Problems]

 In order to solve the above problems, the suture portion strength testing device of the present invention has the following configuration. That is, a pair of holding members provided so as to face each other, and at least one of the pair of holding members, which have winding portions for winding and gripping both ends of the strip-shaped sample, each of which has a stitching portion at an intermediate portion. And a load measuring means for measuring a tensile load applied to at least one of the holding members, and a moving means for moving the holding member away from or approaching the other holding member.

[0015]

[Action]

 Since the suture strength testing device of the present invention is provided with the pair of holding members provided so as to face each other and the winding portions for winding and gripping both ends of the sample, the pair of holding members is provided. When is moved away from the sample, an even force is applied to the entire sample, preventing damage to the sample from near the sample mounting part. Further, the suture strength test device of the present invention is provided with a load measuring means for measuring a tensile load applied to at least one of the holding means. It becomes possible to measure the tensile load, and the strength of the sutured portion can be obtained accurately and in numerical value.

[0016]

【Example】

 Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following embodiments, the same components as those of the conventional technique described with reference to FIG. 8 are designated by the same reference numerals, and detailed description thereof will be omitted.

FIG. 1 is an explanatory view of a suture portion strength testing device according to an embodiment of the present invention, and FIG. 2 is a perspective view of a holding member provided in the suture portion strength testing device. As shown in FIG. 1, the apparatus of the embodiment has the apparatus shown in FIG. 8 as a core, and in place of the chuck (17), a holding member (40) for holding a sample having a roll-shaped winding portion (39) is vertically moved. It is characterized by being installed in.

That is, the holding member (40) is composed of an upper holding member (41) holding the upper part of the sample (10) and a lower holding member (42) holding the lower part of the sample (10). . Then, as shown in FIG. 2, the upper and lower holding members (41) and (42) respectively have the above-mentioned winding part (39) around which the sample is wound, and a substantially U-shaped cross section for supporting the winding part (39). The locking member (43) and a cylindrical connecting portion (44) fixed to the apex of the locking member (43) are provided. The winding part (39) is a thick rod body, and the diameter of its cross section is formed in three steps by lathe processing so that it becomes gradually narrower toward both ends, and its end part is made into a square cross section. The insertion portion (45) is formed by shaving so that the surface of the thickest part in the center is knurled to prevent the sample (10) from slipping off. In addition, the locking member (43) provided on the upper holding portion (41) has an inverted L-shaped locking opening A (46) formed on the U-shaped opposing vertical pieces, and The locking member (43) provided in the holding portion (42) has a U-shaped facing vertical piece provided with a character-shaped locking port B (47). Then, the insertion portion (45) is inserted into these locking openings to fix the winding portion (39). The suture strength testing device (38) has a cylindrical connecting portion (44) having a connecting hole (48) formed in the opposite side wall thereof and having a diameter equal to that of the connecting hole (48). A hole (not shown) is opened in the lower part of the universal joint (28) (see FIG. 1), and further, a connecting fitting (not shown) is fixed to the upper part of the support base (31), and this connection is made. The metal fitting is provided with a connected hole having the same diameter as the connecting hole (48). That is, the upper holding member (41) is connected to the lower part of the universal joint (28) as shown in FIG. 1, and the lower part of the universal joint (28) is connected to the inner space of the connecting part (44). The structure is such that the pin (50) is inserted into the connection hole formed in the universal joint (28) and the connection hole (48) of the connection portion (44) to insert the pin (50). . Further, the lower holding member (42) is adapted to be connected to the connecting fitting, and the connecting fitting is fitted into the inner space of the connecting portion (44) and is connected by the pin (50) in the same manner as above. It is structured.

Such a suture portion strength testing device measures strength as follows. First, the load cell (24) is attached to the cross head (16), and the universal joint (28) is attached to the lower portion of the load cell (24). Then, the upper holding part (41) is connected to the lower part of the mounted universal joint (28), and the lower holding part (42) is connected to the connecting fitting. Then, the winding part (39) is removed from both holding members, and the sample (10) having the suture part (9) is set between the both winding parts (39) as shown in FIG. As shown in FIG. 4, it is wound so that the distances L ₁ and L ₂ from the sewn portion (9) to the winding portion (39) have the same length. Next, the crosshead (16) is lowered to an appropriate position so that the sample (10) can be attached to the locking member (43) in a wound state, and the winding portion (39) is shown in FIG. Wear as shown. Then, the speed change motor (20) is driven and the crosshead (16) is moved up and down to perform the test. Normally, in the suture strength test device, when measuring the strength of the suture portion of a relatively thin stocking, which is known to rupture with one pull, the pull mode is selected as the one-time mode. When measuring the strength of sutures such as relatively thick tights, the test is performed in a repeated mode in which pulling is performed several times.

FIG. 10 shows an example of measuring the strength of the sutured part in the crotch part of the panty hose, which was measured using the above-described test apparatus. In this test, two types of relatively thin panty hose A, B was used. The load cell was 25 kg, and the output rate was set to 50%. Further, the pulling speed was set to 1000 cm / min, and the pulling mode was tested in the one-time mode. Since the load cell is not loaded when the sewn part ruptures, as is clear from the figure, stocking A ruptures with a load of 3.68 kg (point A in the figure) and stocking B has 5.56 kg ( It can be seen that it burst under the load of point B in the figure). The result that the stocking B is superior to the stocking A in the strength of the stitched portion was obtained.

FIG. 11 is a measurement example in which the strength of the crotch portion of two types of relatively thick tights C and D is measured using the same test apparatus. The load cell was 25 kg, and the output rate was set to 100%. Further, the pulling speed was set to 1000 cm / min, the pulling mode was set to the repeating mode, and the number of repetitions was set to 10 times, and the test was conducted. Tights C ruptured with a load of 25 kg (C ₁ point in the figure) at the 4th reciprocation, the load was lightened by the rupture, and it was further pulled because it was further pulled (C ₂ point in the figure). ). Further, the tights D ruptured under the load of 19.75 kg (D ₁ point in the figure) at the first reciprocation, and then ruptured significantly (D ₂ point in the figure). As is clear from the above results, the tights C were found to have a strength superior to the tights D in the crotch stitched portion.

The suture strength testing device (38) of one embodiment of the present invention is, in short, provided with a roll-shaped winding part (39) on the holding member (40), and the sample (10) is wound around the winding part (39). 10) is pulled so that a uniform load can be applied to the entire sample, and a load cell (24) for measuring the tensile load applied to the sample at this time is provided to select the pull mode. Since the setting is made possible, the strength of the suture portion (9) can be measured without being involved in the strength and stretchability of the sample (10), and the measurement result can be obtained as a numerical value.

Further, since the suture strength test device (38) of the above-mentioned embodiment is knurled as a means for preventing the sample from slipping, the sample is sufficiently protected without being damaged by the slip preventing means. Can be held at.

Although the support base (31) is fixed to the base base (12) in the embodiment shown in FIG. 1, the present invention is not limited to this, and the support base may be configured to be movable up and down. That is, as shown in FIG. 6, a screw shaft B (51) is erected in the right vertical frame body (14), and a transmission motor B (52) interlocking with the screw shaft B (51) is arranged on the base (12). . Then, the left support portion B (54) and the right support portion B (55) are formed on the left and right sides of the support base B (53), and the nut portion C (56) is formed on the right support portion B (55). The nut portion C (56) is screwed onto the screw shaft B (51), and a round hole B (57) is formed in the left support portion B (54). The screw shaft is inserted in the round hole B (57). Insert (19). As a result, the support base B (53) can be raised and lowered by the screw shaft B (51), and the crosshead (16) can be raised and lowered by the screw shaft (19). In this way, when measuring a short distance, the test can be performed while holding the sample (10) at an appropriate height without bending down near the base (12).

Further, in the above embodiment, the pair of two holding members are provided so as to face each other in the vertical direction, but the present invention is not limited to this, and the holding members face each other in the horizontal direction. They may be present, or may be opposed to each other in the oblique direction.

Further, in the above embodiment, the winding portion (39) is knurled so that the sample can be sufficiently held, but the present invention is not particularly limited to this, and the sample can be sufficiently held and As long as it does not damage the sample, surface fasteners may be attached to the winding part (39), pins, needles, nails, etc. may be attached radially, and the sample may be attached to the winding part (39). A groove to be held may be formed.

[0027]

[Effect of device]

 The suture strength testing device of the present invention is provided with a pair of holding members for holding a sample having a suture, a moving means for moving the holding members, and a tensile load applied to the holding means. Load measuring means for moving the holding means to rupture the sample by pulling the sample and measuring the tensile load applied to the sample at this time. Obtainable .

Further, the suture portion strength test device of the present invention is provided with a winding portion for winding and gripping the end portion of the sample on the holding member, and the holding means is provided in the state where the sample is wound around the winding portion. Since it is constructed so that it can be moved, a tensile load is evenly applied to the entire area of the sample, and damage from near the mounting part of the sample is prevented. Then, by securely rupturing the sample from the sutured portion and measuring the tensile load at that time, the strength of the sutured portion can be accurately measured, and reproducible test results can be obtained.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a suture portion strength test apparatus showing an embodiment of the present invention.

FIG. 2 is a perspective view of a holding member used in the suture portion strength testing device.

FIG. 3 is an explanatory diagram when mounting a sample on the holding member.

FIG. 4 is an explanatory diagram when mounting a sample on the holding member.

FIG. 5 is a perspective view when a sample is mounted on the holding member.

FIG. 6 is an explanatory view of a suture portion strength test device showing another embodiment of the present invention.

FIG. 7 is an explanatory diagram of a main part of a Murren burst tester.

FIG. 8 is an explanatory diagram of a tensile tester.

FIG. 9 is a perspective view of a chuck used in the tensile tester.

FIG. 10 is a graph showing Measurement Example 1 in which measurement was performed using the suture portion strength test device according to the embodiment of the present invention.

FIG. 11 is a graph showing a measurement example 2 in which measurement is performed using the suture portion strength test device according to the embodiment of the present invention.

[Explanation of symbols]

 9 stitching part 10 sample 16 crosshead 19 screw shaft 20 variable speed motor 24 load cell 39 winding part 40 holding member

Claims (1)

[Scope of utility model registration request] 1. A wrapping part (3) for wrapping and gripping both ends of a band-shaped sample (10) provided with a suture part (9) at an intermediate part.
9) (39), a pair of holding members (40) provided so as to face each other, and the pair of holding members (4)
0) at least one of the holding members (40) is moved away from or closer to the other holding member (40), and a load measuring unit for measuring a tensile load applied to at least one of the holding members (40). A device for testing the strength of a suture portion, which is characterized in that