DE112011101680T5 - Test Piece Elongation and Test Piece Elongation Method - Google Patents

Abstract

A test piece stretch device of the present invention includes: a first rail and a second rail arranged on tracks in which a distance between the first rail and the second rail is increased from one side to the other side; a first terminal group including a plurality of first terminals, the first terminal group configured to travel along the first rail; and a second terminal group including a plurality of second terminals, the second terminal group configured to travel along the second rail. The first terminal group and the second terminal group are arranged opposite to each other to clamp a test piece. The first terminal group and the second terminal group may run along the first rail and the second rail, respectively, from the one side toward the other side, while the first terminal group and the second terminal group clamp the test piece so that the test piece in a width direction by running the first terminal group and the second terminal group is stretched.

Description

TECHNICAL AREA

The present invention relates to a test piece stretch device and a test piece stretch method for stretching a test piece such as a film or a sheet. Specifically, the present invention relates to a test piece stretch device and a test piece stretch method for stretching a test piece of a sheet sheet or a test piece of a sheet while the test piece is clamped.

STATE OF THE ART

A biaxially stretched film manufacturing apparatus is known as an apparatus for continuously producing a packing sheet and / or a substrate sheet. In the stretching steps of a biaxially stretched film manufacturing apparatus, various types of stretching devices are used depending on a material of a film and its use.

JP 10-249934 A (Patent Document 1) discloses that a plate sheet is stretched in a flow direction thereof by a longitudinal stretching device, and that the sheet sheet is then stretched in a widthwise direction by means of a device in which a plurality of clamps connected in series and endlessly by chains running continuously along a pair of endless tracks formed by rails and sprockets.

JP 2008-44339 A (Patent Document 2) discloses that a web or a film in one of them. Width direction is stretched by means of a device in which a plurality of terminals, which are connected together by connecting parts in series and endless, continuously along a pair of endless tracks, which are formed by rails and sprockets. There, it is also disclosed that the web or film is stretched in one of its flow direction (running direction) by changing the distance between the adjacent clamps by opening and closing the connecting parts (connecting type multi-biaxial clamping device).

JP 2004-122640 A (Patent Document 3) discloses that a clamping distance of a clamping device in a curved part of a rail of a stretching device including connecting devices of equal length is varied.

JP 2002-103445 A (Patent Document 4) discloses that a film is stretched in a width direction thereof by a plurality of linear motor driven clamps continuously running along a pair of endless tracks formed by rails. There, it is also described that the film is stretched in one of its flow direction (running direction) by changing a distance between the adjacent clamps (linear type multi-biaxial stretching device).

Furthermore, various stretching methods and various stretching devices have been developed to produce a functional film, such as an optical film.

JP 2-113920 A (Patent Document 5) discloses a method of obliquely stretching a film or a web by changing a distance between a pair of endless tracks formed by rails.

JP 2008-23775 A (Patent Document 6) discloses an apparatus and a method for stretching a sheet film in which a position where a distance along a track of running clamps increases in a pair of endless tracks formed by rails and sprockets increases, and a position, at which a distance from along the other lane running terminals starts increased, are different from each other.

When a film is continuously produced by using a biaxially stretched film making apparatus employing the aforementioned various stretching devices and methods, a test piece of a sheet web or a test piece of a film web is stretched by a test piece stretching device, and properties of the stretched test piece (film pattern) are evaluated to ensure in advance that a film with desired properties can be made.

JP 2009-258571 A (Patent Document 7) discloses that a film piece which has not yet been stretched is uniaxially stretched by a ductility tester to obtain a stretched pattern.

JP 61-112628 A (Patent Document 8) discloses a biaxial elongation tester which biaxially stretches a web-like pattern by means of joints forming a pantograph mechanism.

JP 2004-148694 A (Patent Document 9) discloses a tester for stretching a web-like article, the tester including a joining device, longitudinal stretching means and lateral stretching means. The tester further includes a control means configured to control a variation time of the longitudinal expansion means and a variation time of the lateral expansion means.

However, when a film is continuously produced by a biaxially stretched film manufacturing apparatus applying the stretch devices and stretching methods disclosed in Patent Documents 1 to 6 based on the evaluation of characteristics of an elongation tester disclosed in any of Patent Documents 7 to 9, there is a possibility that a film having properties equivalent to those of the film pattern can not be obtained because of a structural difference of the elongation tester and respective stretching devices and / or differences in stretching performance.

In addition, a test piece of a sheet web or a test piece of a film web under stationary conditions is stretched in the extensibility tester disclosed in Patent Document 7 and the biaxial elongation tester disclosed in Patent Document 8. Thus, it can not be said that this is an elongation test performed under conditions equivalent to a condition in which a film is continuously produced by the stretch device of a biaxially stretched film manufacturing apparatus.

In addition, joints of the same length of the connecting device in the elongation tester disclosed in Patent Document 9 are opened, and clamping devices are extended from one end to the other end of the pair of tracks arranged so that a distance therebetween widens toward the other end to perform a stretching test to be realized under a condition equivalent to a condition in which a film is continuously produced by the stretch device of the biaxially stretched film manufacturing apparatus. In this strain tester, however, only the far-end clamp reaches the other end, and only a distal end of a sheet-like article clamped by the clamp is fully stretched. Since the far end of the web-like article is a cut edge, there is a possibility that its properties differ from properties of a continuous film. Namely, it can not be said that even the strain tester disclosed in Patent Document 9 can achieve a strain test performed under conditions equivalent to a condition in which a film is continuously produced by the stretch apparatus of the biaxially stretched film manufacturing apparatus.

Although the distance between adjacent clamps in the curved part of the rail of the expander varies as disclosed in Patent Document 3, the strain tester disclosed in Patent Documents 9 does not consider this behavior in the curved part. Further, it is impossible to perform a stretching test according to the method of obliquely stretching a film or sheet disclosed in Patent Documents 5 and 6, respectively.

SUMMARY OF THE INVENTION

The present invention has been made in view of the above circumstances. It is an object of the present invention to provide a test piece stretching apparatus and a test piece stretching method capable of performing an elongation test under a condition equivalent to a continuous production state in which a film is continuously produced by a stretching apparatus of a biaxially stretched film manufacturing apparatus a film pattern can be obtained which has properties equivalent to those of a film continuously produced by the stretching apparatus.

The present invention is a test piece stretch apparatus comprising: a first rail and a second rail located on tracks in which a distance between the first rail and the second rail increases from one side to the other side; a first terminal group including a plurality of first terminals, the first terminal group configured to travel along the first rail; and a second terminal group including a plurality of second terminals, the second terminal group configured to travel along the second rail; wherein: the first terminal group and the second terminal group are oppositely arranged to clamp a test piece; and the first terminal group and the second terminal group along the first rail and the second rail, respectively, can move from one side toward the other side while the first terminal group and the second terminal group clamp the test piece so that the test piece runs in a widthwise direction the first terminal group and the second terminal group is stretched.

According to the present invention, an evaluation of properties of the stretched test piece (pattern) can be regarded as an evaluation of properties of a continuously formed film because the test piece as a whole (specifically, a middle portion of the test piece) is subjected to the stretching process in the width direction.

Preferably, a distance between the first terminals of the first terminal group is increased during running and a distance between the second terminals of the second Terminal group is increased during running, so that the test piece is stretched in the running direction.

In this case, characteristics of the stretched test piece (pattern) can be further approximated to the properties of a continuously formed film because the test piece as a whole (specifically, the center portion of the test piece) is subjected to the stretching process also in the running direction.

Alternatively, the present invention is a test piece stretch apparatus comprising: a first rail and a second rail arranged with a space therebetween; a first terminal group including a plurality of first terminals, the first terminal group configured to travel along the first rail; and a second terminal group including a plurality of second terminals, the second terminal group for running along the second rail; wherein it is arranged: the first terminal group and the second terminal group are oppositely arranged to clamp the test piece; the first terminal group and the second terminal group may travel along the first rail and the second rail, respectively, from one side toward the other side while the first terminal group and the second terminal group clamp the test piece; and a distance between the first terminals of the first terminal group is increased during running, and a distance between the second terminals of the second terminal group is increased during running, so that the test piece is stretched in the running direction.

According to the present invention, evaluation of properties of the stretched test piece (pattern) can be regarded as evaluation of properties of a continuously formed film because the test piece as a whole (specifically, the middle portion of the test piece) is subjected to the stretching process in the lacing direction.

Alternatively, the present invention is a test piece stretching method for stretching a test piece using the test piece stretch apparatus having one of the features, wherein the test piece stretching method includes: arranging the first clip group and the second clip group opposite to clamp the test piece, and causing the first clip group and the second clip group along the first rail and the second rail from one side to the other side, so that the test piece is stretched in the width direction.

BRIEF DESCRIPTION OF THE FIGURES

1 Fig. 10 is a view showing a test piece stretch apparatus in an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Hereinafter, an embodiment of the present invention will be described with reference to FIG 1 described.

1 shows a test piece stretching device 10 in an embodiment according to the present invention capable of performing an elongation test under a condition equivalent to that of a continuous production state in which a plate web or a film web is simultaneously biaxially stretched by a compound type multi-biaxial stretching device, whereby a film pattern can be obtained Has properties equivalent to those of a continuously produced film. In 1 The up and down direction relative to the sheet surface corresponds to a running direction (flow direction) in which the upper side corresponds to an upstream side in the running direction and the lower side corresponds to a downstream side in the running direction. In addition, the right and left directions correspond to a width direction relative to the sheet surface.

The test piece stretch device 10 contains a pair of a first rail 11 and a second rail 12 , A first support unit 13 can run along the first rail while being guided by it. A second support unit 14 can run along the second rail while being supported by it. A variety of clamps 16 for clamping an edge of the test piece 15 are set up on the first support unit 13 attached to a first terminal group 17 to build. Similarly, a plurality of second terminals 18 for clamping the other edge of the test piece 15 are set up on a second support unit 14 arranged a second terminal group 19 to build. The first support unit 14 is through a first drive unit 20 driven, creating the first terminal group 17 along the first rail 11 can run. Similarly, the second support unit 14 by a second drive unit 21 driven, creating the second terminal group 19 can run along the second rail. In addition, a heating unit 22 for heating the test piece 15 provided.

The first rail 11 has one longitudinal end acting as a starting point S1 and the other longitudinal end serving as an end point E1 acts. In 1 the starting point S1 is on the upstream side in the flow direction, and the end point E1 is on the downstream side in the flow direction. Similarly, the second rail 12 a longitudinal end acting as a starting point S2 and the other longitudinal end functioning as an end point E2. In 1 is the starting point S2 on the upstream side in the flow direction and the end point E2 is located on the downstream side of the flow direction.

The first rail 11 and the second rail 12 themselves are arranged to be able to be movable in the flow direction and the width direction, respectively. Furthermore, the longitudinal tracks (profiles) of the first rail 11 and the second rail 12 set up to be adaptable (deformable). In the in 1 The example shown are the tracks (profiles) of the first rail 11 and the second rail 12 formed so that a zone is formed in which a predetermined distance Dp between the first rail 11 and the second rail 12 is maintained in accordance with a tensile test condition of the test piece 15 ,

The arrangement example of the first rail 11 and the second rail 12 will now be described with more details. In the in 1 example shown are the first rail 11 and the second rail 12 arranged symmetrically with respect to a center line CL in the flow direction to a tensile test condition of the test piece 15 correspond to. Between the first rail 11 and the second rail 12 Starting from the starting point S1 / starting point S2 to the end point E1 / end point E2, a preheating zone A in which the distance Dp is constant, a stretching zone B in which the distance toward the downstream side is increased, and a heating zone C, in the distance Dp is wider than that of the preheating zone A and constant, formed in this order from the upstream side of the flow direction. The preheating zone A, the expansion zone B and the heating zone C are by oven-like heating units 22a . 22b respectively. 22c covered.

The preheating zone A is a zone in which the test piece 15 is preheated. The strain zone B is a zone in which the distance Dp is increased so that a distance between the first terminal group 17 and the second terminal group 19 is increased, whereby the test piece, whose opposite side edges are clamped, is stretched in the width direction. The heating zone C is a zone in the characteristics of a film pattern 23 be stabilized by stretching the test piece 15 was formed.

As described above, the distance Dp between the first rail and the second rail for each position in the flow direction is determined based on a tensile test state of the test piece 15 determined (can be modified or adapted).

In this embodiment, the first support unit 13 formed by connecting a plurality of first connection mechanisms 24 , each containing two connections which are interconnected by a hinge so that the connections can be opened and closed (rotated). At a side of far ends of the openable and closable connections of the first connection mechanism 24 (inner side in 1 ), a bearing is arranged through the first rail 11 is led to be rolled down there. On one side of the near ends of the joint (outer side in 1 ) is arranged a bearing that of a first distance adjustment rail 25 is led to be rolled down there. The first distance adjustment rail 25 is arranged such that a distance L1p between the first distance adjusting rail 25 and the first rail 11 is defined. The variety of first terminals 16 is fixed on the side of the far ends of the connection to the first connection mechanism 24 correspond to. When the distance L1p between the first rail and the first distance adjusting rail 25 so varies that the opening and closing condition of each first link mechanism 24 is varied, so is a distance between the adjacent first terminals 16 , that is, terminal spacing, varies.

Similar is the second support unit 14 formed by connecting a plurality of second connection mechanisms 26 each of which contains two connections interconnected by a connection so that the connections can be opened and closed (rotated). On one side remote ends of the openable and closable connections of the second connection mechanism 26 (inner side in 1 ) A bearing is arranged, which is guided by the second rail to roll along there along. On one side of close ends of the joint (outer side in 1 ) is arranged a bearing, which by a second distance adjustment rail 27 is led to be rolled down there. The second distance adjustment rail 27 is arranged such that a distance L2p between the second distance adjusting rail 27 and the second rail 12 is defined. The variety of second terminals 18 are fixed on the side of the far ends of the connection to the second connection mechanism 26 correspond to. When the distance L2p between the second rail 12 and the second clearance adjustment rail 27 is varied so that the open-close state of each second link mechanism 26 is varied, a distance between the adjacent second terminals 18 , that is, terminal spacing, varies.

To trace based on a stretch test condition of the test piece 15 to form, become the first rail 11 and the second rail 12 formed by firmly arranging a plurality of rail tables 29 , each of which with a linear rail part 28 , on a first rail base 30 and a second rail base 31 , and by connecting the adjacent rail parts 28 through a curved rail part 32 , The first rail base 30 and the second rail base 31 are on a basis 33 placed. This is the distance between the first rail 11 and the second rail 12 in the right and left direction of the 1 (the direction perpendicular to the flow direction) is fixed as the predetermined distance Dp.

The first distance adjustment rail 25 is formed by connecting the on the rail table 29 arranged rail part 28 with the curved rail part 32 such that the predetermined distance L1p between the first gap adjusting rail 25 and the first rail 11 on the second rail 12 is defined opposite side. Similarly, the second gap adjusting rail becomes 27 formed by connecting the on the rail table 29 arranged rail part 28 with the curved rail part 32 such that the predetermined distance L2p between the second distance adjusting rail 27 and the second rail 12 on the first rail 11 is defined opposite side. When the first support unit 13 and the second support unit 14 on the first track 11 or the second rail 12 are the first terminals 16 and the second terminals 18 across the center line CL to face each other.

In this embodiment, when the distance L1p and the distance L2p are reduced, the first connection mechanisms become 24 and the second connection mechanisms 26 opened, so that the terminal distances are increased. This will be the test piece 15 that through the first terminals 16 and the second terminals 18 is stretched, also stretched in the direction in which the terminal gaps are increased (the up and down direction in 1 : Flow direction).

As described above, the distance L1p and the distance L2p for each position in the flow direction are determined based on a tensile test condition of the test piece 15 certainly. In this embodiment, the distance L1p and the distance L2p are gradually reduced toward the downstream side in the strain zone B, so that the test piece 15 is stretched simultaneously in the width direction and the flow direction.

The first drive unit 20 contains a wire 34 whose one end is connected to the first support unit 13 connected to a drum, which is the wire 34 wound up, and a motor 36 who is the drum 35 rotates. In this embodiment, there are the drum 35 and the engine 36 on the downstream side of the first rail base 30 , By pulling the first support unit placed at the starting point S1 13 to the end point E1 by means of the first drive unit 20 , becomes the first support unit 30 through the first rail 11 and the first distance adjusting unit 25 so led to walk along there. Thus, the first terminal group is running 16 along the first rail 11 , Similarly, the second drive unit includes 21 a wire 34 whose one end is connected to the second support unit 14 connected, a drum 35 that the wire 34 rolls up, and a motor 36 who is the drum 35 rotates. In this embodiment, there are the drum 35 and the engine 36 on the downstream side of the second rail base 31 , By pulling the second support unit placed at the second starting point S2 14 to the end point E2 by means of the second drive unit 21 , becomes the second support unit 14 through the second rail 12 and the second clearance adjustment rail 27 so led to walk along there. Thus, the second terminal group is running 18 along the second rail 12 ,

According to this embodiment, an elongation test can be performed under a condition equivalent to that of a continuous manufacturing state in which a plate sheet or a film film is biaxially simultaneously stretched by a compound type multi-biaxial stretching apparatus. Consequently, a film pattern equivalent to a film continuously produced by a compound type multi-biaxial stretching apparatus can be obtained. Concrete procedures of a strain test performed by the test piece stretch device 10 will be described below.

Based on a strain test state such as an elongation increase of the test piece 15 in the flow direction and one whose expansion magnification in the width direction, etc., are first the tracks of the first rail 11 and the second rail 12 determined, and the first rail 11 and the second rail 12 are installed (moved) so that these tracks are defined. Specifically, the first rail 11 and the second rail 12 arranged symmetrically with respect to the center line CL, so that the predetermined. Distance Dp is formed at each position in the flow direction.

Then the first Abstandseinstellschiene 25 installed so that the distance L1p between the first Abstandseinstellschiene 25 and the first rail 11 is defined, and the second Abstandseinstellschiene 27 will be installed so that the Distance L2p, which is equivalent to the distance L1p (L1p = L2p), between the second distance adjusting rail 27 and the second rail 12 is defined. In addition, between the first starting point S1, the second starting point S2 and the end point E1 and the end point E2 a strain zone B is set, in which the test piece 15 is simultaneously stretched in two directions, that is in the width direction and the flow direction. Specifically, the distance Dp is increased to stretch the test piece in the width direction, and the distance L1p and the distance L2p are reduced to increase the terminal pitches to the test piece 15 to stretch in the direction of flow. Further, a preheating zone A is set on the downstream side of the stretching zone B, and the heating zone C is set on a downstream side of the stretching zone B.

As described above, after the first rail 11 and the second rail 12 , and the first distance adjustment rail 25 and the second distance adjusting rail 27 becomes installed (placed) based on an elongation test condition, becomes an edge of the test piece 15 from at the starting point S1 of the rail 11 located first terminal group 17 clamped and the other edge of the test piece 15 is from the at the starting point S2 of the second rail 12 located terminal group 19 clamped.

After that, the first drive unit 20 and the second drive unit 21 triggered, leaving the first support unit 13 and the second support unit 14 to be pulled. This will cause the first terminal group to run 17 and the second terminal group 19 that the test piece 15 clamp along the first rail 11 or the second rail 12 so that the first terminal group 17 and the second terminal group 19 penetrate into the preheating zone A. The first terminal group 17 and the second terminal group 19 are temporarily stopped in the preheating zone A. In preheating zone A, the test piece becomes 15 to a predetermined preheat temperature from the heating unit 22a heated.

After the preheating of the test piece in the preheating zone A is completed, the first drive unit becomes 20 and the second drive unit 21 then pressed again. As a result, the first terminal group is running 17 and the second terminal group 19 that the test piece 15 clamp, along the first rail or the second rail, so that the first terminal group 17 and the second terminal group 18 go through the expansion zone B, which previously to a predetermined extension temperature of the heating unit 22b was heated.

At this time, the test piece becomes 15 in the width direction in accordance with the increase in the distance Dp stretched. At the same time it becomes the test piece 15 also stretched in the flow direction, in accordance with the increase in the terminal intervals caused by the reduction of the distances L1p and L2p. If the entire first terminal group 17 and the entire second terminal group 19 , which clamp the test piece, pass through the expansion zone B, thus becomes the test piece 15 as a whole stretched in the width direction and the flow direction.

After the first terminal group 17 and the second terminal group 19 have passed through the expansion zone B, enter the first terminal group 17 and the second terminal group 19 in the heating zone C and temporarily stop in the heating zone C. In the heating zone C is a film pattern 23 by stretching the test piece 15 was formed, to a predetermined heating temperature by the heating unit 22c heated. This will make properties of the slide pattern 23 stabilized.

After heating the pattern foil 23 is completed in the heating zone C, the first drive unit 20 and the second drive unit 21 pressed again. This will hit the first terminal group 17 and the second terminal group 19 that the pattern foil 23 terminals, at the end point E1 and the end point E2, respectively. After that, the pattern foil will be 23 coming from the first terminal group 17 and the second terminal group 19 is clamped, removed.

After the pattern foil 23 are removed, with the first terminal group 17 equipped first support unit 13 and those with the second terminal group 19 equipped second support unit 14 from the end point E1 and the end point E2, respectively, and are again at the starting point S1 and the starting point 52 placed for a subsequent stretch test. Alternatively, the movement of the first support unit 13 from the end point E1 to the starting point S1 and the movement of the second support unit 14 from the end point E2 to the starting point S2 by providing train units on the sides of the starting point 51 and the starting point S2. That is the first drive unit 20 and the second drive unit 21 can be structured so that the first support unit 13 and the second support unit 14 between the starting point 51 and the end point E1 or the starting point S2 and the end point E2 can move back and forth.

According to the above embodiment, the first terminal group run 17 and the second terminal group 19 that the test piece 15 clamp, from the starting point 51 and the starting point 52 the first rail 11 and the second rail 12 in the direction of the end point E1 or the end point E2. When the first terminal group 17 and the second terminal group 19 pass through the expansion zone B set in the running zone, the entire test piece 15 stretched, leaving the foil pattern 23 can be obtained. Since at least one central portion of the test piece 15 is continuous (the central portion of the test piece 15 is not a cut end), it can be said that the film pattern thus obtained 23 Has properties equivalent to those of a film continuously produced by a production apparatus of a biaxially stretched film.

When a compound type multi-biaxial expansion device itself is used for performing a tensile test, it is necessary to cause a plurality of terminals connected in series and endlessly by means of connecting parts to travel along a pair of endless tracks formed of rails and sprockets. Such a test is big and inefficient.

On the other hand, in this embodiment, since the first terminal group 17 and the second terminal group 19 that the test piece 15 clamp, only along the first rail 11 and the second rail 12 , which correspond to the size of the test piece 15 are arranged to run from the starting point S1 and the starting point S2 toward the end point E1 and the end point E2, respectively, an efficient stretching test can be performed.

In addition, in this embodiment, the first rail 11 and the second rail 12 arranged symmetrically with respect to the center line CL. However, this arrangement is suitably selected based on a tensile test condition of the test piece 15 , and the traces (lengths and radii of curvatures of the curved parts) of the first rail 11 and the second rail 12 can be suitably changed depending on the strain test condition. For example, it is possible to perform a test under a condition in which the test piece 15 is stretched obliquely by asymmetrically arranging the first rail 11 and the second rail 12 , and by varying the length of the second rail 12 from that of the first rail 11 to make different tracks. Alternatively, for example, it is possible to perform a test by placing the test piece 15 is skewed by deviating from a position at which the terminal distance of the first terminal group 17 begins to increase, and a position at which the terminal distance of the second terminal group 19 begins to increase, from each other.

In this embodiment, the preheating zone A and the heating zone C are provided before and after the stretching zone B. This structure is also based on a tensile test condition of the test piece 15 set.

Depending on a strain test condition, a zone may be added, changed or omitted. In accordance with such changes, the heating units can 22a . 22b and 22c otherwise combined or replaced by each other.

Additionally, in this embodiment, speeds are constant with which the first drive unit 20 and the second drive unit 21 the first support unit 13 and the second support unit 14 pull. In this case, however, the running speeds of the first terminals 16 and the second terminals 18 by opening and closing the first connection mechanisms 24 and the second connection mechanisms 26 be varied during the drawing operation. In view of this, depending on the elongation test condition, there may be a case in which pulling speeds of the first drive unit 20 and the second drive unit 21 desirably be corrected for each position in the flow direction.

In addition, in this embodiment, the first drive unit 20 and the second drive unit 21 temporarily stopped in the preheating zone A and the heating zone C, and preheating and heating are performed. Based on a tensile test condition of the test piece 15 Different periods for preheating and heating, different preheat temperature rise / fall patterns, and different heating temperature rise / fall patterns can be set. Consequently, a long preheating zone and a long heating zone of the stretching apparatus can be reflected, whereby a stretching test can be performed under a condition equivalent to a state in which a plate sheet or a sheet is running.

In addition, the movements of the first rail base 30 and the second rail base 31 in terms of the base 33 , the movements of the rail tables 29 regarding the first rail base 30 and the second rail base 31 and the movements of the first distance adjusting rail 25 and the second distance adjusting rail 27 in terms of the first rail and the second rail on the rail tables 29 are assembled using a linear motion mechanism formed by combining a ball screw and a servomotor. This allows a positional relationship between the first rail 11 and the second rail 12 and a positional relationship between the first distance adjusting rail 25 and the second distance adjusting rail 27 be easily changed. As a result, the distance Dp, the distance L1p and the distance L2p can be adjusted to cope with thermal deformations such as expansion and contraction of the test piece 15 (ie foil pattern 23 ) in preheating zone A and heating zone C.

The first clamp 16 and the second clamp 18 may have the same shape or different shapes based on a strain test condition. The first connection mechanism 24 and the second connection mechanism 26 may have the same shape, symmetrical shapes with respect to the center line CL, or different shapes based on a strain test condition. To different tracks of the first rail 11 and the second rail 12 is sufficient to satisfy the rail part based on a strain test condition 28 different lengths and the rail tables 29 different lengths are prepared.

The number of the first terminal group 17 forming first terminals 16 and the number of the second terminal group 19 forming second terminals 18 is desirably selected so that the test piece coming from the first clamps 16 and the second terminals 18 is clamped, can run through the expansion zone B when the first terminals 16 and the second terminals 18 from the starting point S1 and the starting point S2 of the first rail 11 and the second rail 12 in the direction of the end point E1 and the end point E2 thereof.

In the aforementioned embodiment, a test piece stretch device is 10 which is capable of performing an elongation test under a condition equivalent to that of a continuous production state in which a film is continuously produced by a bonding type multi-biaxial stretching apparatus. However, it is possible to provide a test piece stretch apparatus capable of performing an elongation test under a condition equivalent to that of a continuous production state of a wide stretch apparatus by patterning the first terminal group 17 containing support unit 13 and the second terminal group 19 containing second terminal group 14 by tables connected by chains and by structuring the first rail and the second rail as rails corresponding to the clamp table. In addition, it is possible to provide a test piece stretch apparatus capable of performing a strain test under a condition equivalent to that of a continuous production state of a linear type multi-biaxial stretch apparatus using clamp tables driven by linear motors.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 10-249934A [0003]
• JP 2008-44339A [0004]
• JP 2004-122640 A [0005]
• JP 2002-103445A [0006]
• JP 2-113920 A [0008]
• JP 2008-23775A [0009]
• JP 2009-258571 A [0011]
• JP 61-112628 A [0012]
• JP 2004-148694 A [0013]

Claims (6)

A test stretch apparatus comprising: a first rail and a second rail located on tracks in which a distance between the first rail and the second rail is increased from one side to the other side; a first terminal group including a plurality of first terminals, the first terminal group configured to travel along the first rail; and a second terminal group including a plurality of second terminals, the second terminal group configured to travel along the second rail; in which: the first terminal group and the second terminal group are opposed to each other to clamp a test piece; and the first terminal group and the second terminal group may run along the first rail and the second rail, respectively, from the one side toward the other side, and the first terminal group and the second terminal group clamp the test piece so that the test piece is stretched in a widthwise direction by the running of the test piece first terminal group and the second terminal group is stretched. A test stretch apparatus comprising: a first rail and a second rail arranged with a distance therebetween; a first terminal group including a plurality of first terminals, the first terminal group configured to travel along the first rail; and a second terminal group including a plurality of second terminals, the second terminal group configured to travel along the second rail; in which: the first terminal group and the second terminal group are disposed opposite to each other to clamp the test piece; the first terminal group and the second terminal group may travel along the first rail and the second rail, respectively, from one side toward the other side while the first terminal group and the second terminal group clamp the test piece; and a distance between the first terminals of the first terminal group is increased during running, and a distance between the second terminals of the second terminal group is increased during running, so that the test piece is stretched in the running direction. The test piece stretch apparatus according to claim 1, wherein a distance between the first terminals of the first terminal group is increased during running and a distance between the second terminals of the second terminal group is increased during running, so that the test piece is also stretched in the running direction. A test piece stretching method for stretching a test piece using a test piece stretch apparatus according to claim 1, wherein the test piece stretching method comprises: Arranging the first terminal group and the second terminal group opposite to each other to stretch a test piece; causing the first terminal group and the second terminal group to travel along the first rail and the second rail from one side toward the other side, so that the test piece is stretched in the width direction. A test piece stretching method for stretching a test piece using the test piece stretch apparatus according to claim 2, wherein the test piece stretching method comprises: Arranging the first terminal group and the second terminal group opposite to each other to clamp the test piece; and Causing the first terminal group and the second terminal group to travel along the first rail and the second rail from one side to the other side, so that the test piece is stretched in the running direction. A test piece stretching method for stretching a test piece using the test piece stretch apparatus according to claim 3, wherein the test piece stretching method comprises: Arranging the first terminal group and the second terminal group opposite to each other to clamp the test piece; and Causing the first terminal group and the second terminal group to travel along the first rail and the second rail from one side to the other side, so that the test piece is stretched in a biaxial direction, that is, in the width direction and in the running direction.

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