EP2291605A1

EP2291605A1 - Attachment displacement sensor for measuring the change in length of a sample and measuring method which uses such a sensor

Info

Publication number: EP2291605A1
Application number: EP09765593A
Authority: EP
Inventors: Norbert Dahlem; Jan Kuhnke
Original assignee: Bayer MaterialScience AG
Current assignee: Bayer Intellectual Property GmbH
Priority date: 2008-06-17
Filing date: 2009-06-16
Publication date: 2011-03-09
Also published as: DE102008028403A1; CN102066870A; US20110088481A1; WO2009153013A1; JP2011524529A; KR20110031281A

Abstract

The present invention relates to an attachment displacement sensor for use when mechanically measuring the change in length of a sample as a result of stretching. It also relates to a method for measuring the change in length of a sample by means of such an attachment displacement sensor, to a system for measuring the change in length of a sample with such an attachment displacement sensor, and to the use of such an attachment displacement sensor for measuring the change in length of a sample. The attachment displacement sensor comprises a body which is used to make contact with the sample. According to the invention, the body is rotatably mounted and arranged in such a manner that, if the sample is torn, it causes the body to rotate. As a result of the fact that the sample causes the body to rotate if torn, only a small amount of energy is transmitted to the attachment displacement sensor which is thus not overloaded or damaged.

Description

Start-up monitor for measuring the change in length of a sample and measuring method using the same

The present invention relates to a batch taker for use in mechanically measuring the change in length of a sample by drawing. It further relates to a method for measuring the change in length of a sample by means of such a batch receiver, a system for measuring the change in length of a sample with such a batch picker, and the use of such a batch pick-up.

In mechanical extensibility measurement methods, with a lug bumper contacting the sample, the lug buffers are backlash-free and very movably mounted to provide extremely stiff and backlash-free travel in the direction of the length change to be measured. The contact force of the Ansatzaufaufhhmer to the sample should be as low as possible, so that the strain and fracture behavior of notch-sensitive samples remains largely unaffected.

Therefore, the storage of the neck jack and its sensor system is very susceptible to overloading, such as may occur when samples break during stretching and the specimen remnants jump back uncontrollably and strike against the neck trailers. This leads, in particular in the testing of extremely elastic and high-energy materials such as elastomers, to considerable damage in some cases, both to the approach pathway obstructers and to the entire measuring system.

From DE 7804241 Ul a Längenänderungsaufnehmer for measuring the change in length of stressed on train or pressure samples is known. This has two pairs of adjustably mounted probes, which can be attached directly to the sample with custom cutting at the front end of the probe and transmit the change in distance between the two sensor pairs to generate a corresponding measurement signal. In this case, the measuring cutting edges are located on cutting pieces, which are pivotally mounted on the front end of the measuring probe, wherein the pivot axis of the cutting pieces is oriented substantially perpendicular to the direction of the distance change to be measured. The measuring position of the cutting pieces, in which they are directed against each other at each pair of measuring probes with their measuring cutting edges, is determined by a force-dependent holding device which allows the cutting pieces to pivot about their pivot axis for a given size of a pivoting moment acting on them.

A disadvantage of such an embodiment of the extensometer that the measuring blades can pivot against their holding device and then the forces are transmitted to the probe and can damage this. Damage can also consist in the fact that the cutting pieces can not swing back and thus the system manually repaired and adjusted. This leads to capacity losses in an automated analytical laboratory, especially if the system is shut down for an overnight measurement run and the samples can not be examined until the next morning.

Furthermore, sensors are known which have very small knurled Messingröllchen with an integrated ratchet mechanism in which due to their structural design high forces are transmitted to the probe. In addition, the ratchet mechanism is very complex and has no continuous transmission characteristic due to the detent and dead centers distributed around the circumference. Known optical Wegaufhehmer avoid the risk of mechanical damage, but have the disadvantage that the strain range can not be reliably mapped to over 1000%, since the necessary marking of the samples is problematic.

Therefore, it would be desirable to have stroke removers in which a specimen which has been torn and rebounded during stretching leads to little or no damage to the neck remover or to the transducer system. It would also be desirable to have a method for measuring the change in length of a sample in which high-energy elastomer samples can be automated and measured with less interference.

The invention therefore proposes a Ansatzwegaufnehmer for use in the mechanical measurement of the change in length of a sample by drawing, comprising a rotationally symmetrical body connected to a neck finger, wherein the body is rotatably mounted, the axis of rotation of the body is also the geometric axis of rotation of the body and the body Having around its axis of rotation formed peripheral surface, with which the sample can be contacted.

The adjustably mounted Ansatzwegaufnehmer designed according to the invention comprises a connecting finger connected to a rotationally symmetrical body. The rotationally symmetrical body is preferably formed by a complete rotation of its profile cross-section about its geometric axis of rotation. The fact that the body is rotatably mounted about its geometric axis of rotation, the effort for the adjustment and / or repair of the Ansatzaufaufnehmer is avoided before each repeated measurement, since a rotation of the body at a tearing of the sample has no influence on the positioning of the Ansatzwegaufnehmers.

In addition, is reduced by the rotationally symmetrical body, such as a roller or cylindrical body, inaccurately clamped samples, the probability of slippage and thus measurement errors. To avoid slippage of the Ansatzwegaufnehmers the surface of the body with which this touches the sample, be suitably designed or made of a suitable material. Suitable materials for the surface of the body or for the body as a whole may for example be selected from the group comprising stainless steel, aluminum and / or polytetrafluoroethylene (PTFE). The body preferably has a diameter of> 10 mm to <50 mm, particularly preferably of> 15 mm to <40 mm, very particularly preferably of> 20 mm to <30 mm.

By making the body rotationally symmetric, the distance between the lug transducer and the sample remains the same at all times of the measurement, even when the body has been rotated after tearing a sample. The positive effect of this invention is achieved in particular by the constant large and constant distance of the Ansatzwegaufnehmer axis to the sample.

This avoids direct contact between the sample and the approach transducer or transducer system.

The rotationally symmetric shape of the body also ensures that, at the moment of rupture of the sample, it can not get caught on the body and therefore no harmful amount of energy can be transferred from the recoiling sample to the necking transducer or to the measuring transducer system.

From the zurückschnellenden sample, the static friction of the body is overcome and this is smoothly rotated. This converts most of the energy directed against the lobe pickup into rotational energy, thus protecting the lug picker and the metering system from damage. Resetting and adjusting the body to its measuring position is not necessary geometriebedingt because the, facing the sample, profile cross-section remains unchanged, and thus the distance between the axis of rotation of the body and sample remains unchanged. Advantageously, the Ansatzwegaufnehmer is mounted so that the axis of rotation of the body is perpendicular to the direction of stretching of the sample.

The axis of rotation of the body may, for example, be arranged congruent with the central axis of the lug catcher, parallel to the central axis of the lug catcher or at an angle to the central axis of the lug catcher.

Due to the special design of the Ansatzwegaufnehmers this is also suitable for the testing of samples with very large Längenändεrungen, for example, 1000% or higher, and / or high energy stored in the strain. In addition, the Ansatzaufaufnehmer is particularly well suited to be used in an automated sample testing, since an inventively designed Ansatzwegaufnehmer must not be readjusted before each measurement. Automated operation is further supported by the reduction of the Danger of damage at the neck of the Aufwegaufaufhhmer or Meßaufhehmersystem to longer life of the measuring system leads.

In one embodiment of the Ansatzaufaufhehmers the body is in the form of a roller whose peripheral surface is convex. By this is meant that the peripheral surface, with which the body can contact the sample, is curved convex or convex to the outside. By a convex or convex configuration there is no line contact between the body and the sample, but a nearly point-like contact. This increases the accuracy of the

Measurement results, especially for long changes in length. In addition, the

Peripheral surface of the body then no edges, so that a notch effect in the sample and thus a falsification of the measurement results is avoided.

In another embodiment of the approach path obstruction, the body is connected to the necking medium by a bearing. By virtue of the bearing, the body is not only pivotable but rotatably mounted, so that the body can rotate about its geometric axis of rotation and thus can not catch a torn, back-fasting sample on the body. The storage of the body is preferably designed without play, thereby ensuring accurate measurement results. For storage, for example, tapered or needle bearings made of suitable materials can be used. Furthermore, a bearing without rolling elements, for example in the form of a sleeve or as an integral part of the body itself, of a suitable, lubricious material, such as PTFE, can be used. However, it is preferred that the storage is carried out in the form of a ball bearing.

In another embodiment of the Ansatzwegaufhehmers the rotational resistance of the body is adjustable by a friction clutch. Due to the adjustable rotation friction is ensured with continuous movement, due to the change in length of the sample, a take away the Ansatzwegaufhehmers. With jerky movement of the sample, for example, at the moment of tearing, the static friction of the roller is overcome and the body is rotated smoothly. As a result, most of the energy directed against the body and the neck-way susceptor is converted to rotational energy, thus protecting the neck-hopper and the measuring system from damage.

It is preferred that the friction clutch is designed in the form of an adjustable spring-slip ring system. This means that the rotational resistance of the body can be adjusted, wherein manually by a set screw, which is arranged on the central axis of the Ansetzfingers body side, a pressure spring is biased, which in turn presses a pressure ring against the body and thus generates the rotational resistance , The body is equally rotatable in both directions of rotation. Elaborate coupling parts, such as a ratchet, are not needed. In a further embodiment of the Ansatzwegaufhehmers the axis of rotation of the body is spaced to the central axis of the lug finger. As a result, in particular in the case of highly elastic and strongly elongatable materials, the attachment finger can be arranged further apart from the sample, so that the risk of damage to the attachment finger and the measurement system is further reduced.

The present invention further provides a method for measuring the change in length of a sample by drawing in a stretching direction, wherein at least one Ansatzwegaufhehmer according to the present invention with the peripheral surface of the rotationally symmetrical body contacts the sample and wherein the Ansatzwegaufnehmer is mounted so that the axis of rotation of the body is perpendicular to the direction of stretching of the sample.

The inventive method thus relates to the measurement of the change in length of a sample, wherein the change in length over lying on the sample Ansatzaufnehmer, which are tracked upon expansion of the sample. The tracking of the receiver absorbs the measured values from which the expansion path is calculated.

The stretching direction of the sample is also the direction in which the two remainders of the sample snap back when the sample breaks at the end point of the expansion. Characterized in that the axis of rotation of the body is perpendicular to the direction of stretching, the linear movement of the sample residues can be converted into a rotation of the body when hitting the body of the Ansatzaufnehmers. As a result, damage is avoided, as already described above.

In one embodiment of the method, at least one pair of oppositely disposed tab pathway hoppers according to the present invention contacts the sample with their respective peripheral surfaces of the rotationally symmetric bodies. Furthermore, the Ansatzwegaufhehmer are mounted so that the respective axes of rotation of the body are perpendicular to the direction of stretching of the sample. In a pair of the paired lobes, they are on opposite sides of the sample.

In addition, the subject of the present invention is a system for measuring the change in length of a sample by stretching, comprising a necking path absorbent according to the present invention. Such a system may be, for example, a commercially available apparatus for measuring the change in length of samples, in which the conventional approach path collectors, which are designed, for example, as measuring cutting edges, have been replaced by the approach pathway absorbers according to the present invention. Advantageously, in this system the Ansatzwegaufhehmer are mounted so that the axis of rotation of the body perpendicular to Stretching the sample is.

In one embodiment of the system, at least a pair of oppositely disposed tab pathway heaters according to the present invention are configured with their respective peripheral surfaces of the rotationally symmetric bodies for contacting the probe. Furthermore, the Ansatzwegaufhehmer are mounted so that the respective axes of rotation of the body are perpendicular to the stretching direction of the sample. In a pair of the paired lobes, they are on opposite sides of the sample.

It is also an object of the present invention to use a neck lift-off according to the present invention for measuring the change in length of a sample by stretching.

The invention will be explained in more detail with reference to the accompanying drawings with reference to preferred embodiments.

Show it:

Fig. 1: a schematic view of a Ansatzwegaufhehmers invention

FIG. 2 is a schematic perspective view of an arrangement of FIG

Approach markers for measuring a change in length of a sample

Fig. 1 shows a schematic view of a Ansatzwegaufhehmers invention. The Ansatzwegaufhehmer 10 has an approach finger 12, at the end facing the sample, a body 14 is arranged, which can touch a sample 16 with its peripheral surface 24. The geometric axis of rotation 20 of the body 10 corresponds to its axis of rotation 18, which lies on the central axis 34 of the neck finger 12.

The body 14 is supported by a ball bearing 26 so that it can rotate about its axis of rotation 18. The rotational resistance of the body 14 is adjustable by a spring-Schleifπng system. About a screw 28, a pressure spring 30 is biased, which exerts a spring force on a pressure ring 32 and is pressed against the body 14.

Fig. 2 shows a schematic perspective view of an arrangement of Ansatzwegaυfnehmern for measuring the change in length of a sample, as practiced in the inventive method. The illustrated Ansatzwegaufhehmer 10 are each arranged in pairs on both sides of the sample 16 at two measuring points on the sample 16. The roller-shaped body 14 of the Ansatzwegaufhehmer 10 touch the sample 16 each with its convex peripheral surface 24. Due to the spherical configuration of the peripheral surface 24 this results in an approximately punctiform contact.

The axis of rotation of the body 14 is simultaneously the central axis of the lug finger 12 and the axis of rotation of the body 14, whereby the peripheral surface 24 is formed. According to the invention, the axis of rotation of the body 14 is perpendicular to the drawing direction 22. As a result of the peripheral surface 24 formed by a rotation contacting the sample, the spatial position of the neck catcher 10 is fixed.

When stretching the sample 16 in the direction of stretching 22, there is a change in length, which follow the Ansatzwegaufhehmer 10 and thus allow metrological detection of the change in length. The sample 16 is stretched to break. After rupture, the two pieces of sample 16 snap past the bodies 14 of lug bumper 10 back to their original length.

Claims

claims

A necking means for use in the mechanical measurement of elongation of a specimen (16) by stretching, comprising a necking finger (12) connected to a rotationally symmetrical body (14), characterized in that

the body (14) is rotatably mounted,

the axis of rotation (18) of the body (14) is also the geometric axis of rotation (20) of the body (14), and

the body (14) has a peripheral surface (24) formed about its axis of rotation (20), with which the sample (16) can be contacted.

2. Ansatzwegaufnehmer according to claim 1, wherein the body (14) is in the form of a roller, the peripheral surface (24) is convexly curved.

3. Ansatzaufaufnehmer according to claim 1, wherein the body (14) with the approach finger (12) is connected by a storage.

4. Ansatzwegaufhehmer according to claim 3, wherein the bearing in the form of a ball bearing (26) is executed.

5. Ansatzwegaufhehmer according to claim 1, wherein the rotational resistance of the body (14) is adjustable by a friction clutch.

6. Ansatzwegaufhehmer according to claim 5, wherein the friction clutch is designed in the form of an adjustable spring-slip ring system.

The lug tab according to claim 1, wherein the axis of rotation (18) of the body (14) is spaced from the central axis (34) of the lug finger (12).

8. Method for measuring the change in length of a sample (16) by drawing in a drawing direction (22),

characterized in that

at least one Ansatzwegaufhehmer (10) according to claim 1 with the peripheral surface (24) of the rotationally symmetrical body (14) the sample (16) contacted, and wherein

the lug lift-off device (10) is mounted so that the axis of rotation (18) of the body (14) is perpendicular to the drawing direction (22) of the sample (16).

9. The method of claim 8, wherein at least one pair of oppositely disposed tab exclusions according to claim 1 contacts the sample (16) with their respective peripheral surfaces (24) of the rotationally symmetric bodies (14) and wherein the tab path heaters (10) are mounted such that the respective axes of rotation (18) of the bodies (14) are perpendicular to the drawing direction (22) of the sample (16).

A system for measuring the change in length of a specimen (16) by stretching, comprising a specimen path detector (10) according to claim 1.

A system according to claim 10, wherein at least one pair of oppositely disposed lug hoppers according to claim 1 are arranged with their respective peripheral surfaces (24) of the rotationally symmetric bodies (14) for contacting the sample (16) and wherein the lug mover (10) is mounted in that the respective axes of rotation (18) of the bodies (14) are perpendicular to the drawing direction (22) of the sample (16).

12. Use of a Ansatzaufaufhehmers (10) according to claim 1 for measuring the change in length of a sample (16) by stretching.