RU2225466C1 - Method for determining torque of twisted fiber and yarn - Google Patents

Abstract

FIELD: textile industry, in particular, equipment for controlling and optimizing of twisted fiber and yarn. SUBSTANCE: method involves placing fiber or yarn sample under test in horizontal position and rigidly fixing its fastened end or disposing it for axial rotation; joining free end of sample under test with auxiliary sample of elongate thread-like material having thickness close to that of sample under test and strength exceeding that of sample under test, with sample under test being balanced for twisting or without twisting; providing single applying of force or successively changing force value; connecting sample under test and auxiliary sample through sensitive member and judging torque value on the basis of sensitive member signals. Method allows torque with different axial loading and twisting to be measured upon single testing procedure, as well as several fiber cuts to be tested simultaneously with following neutralizing of results. Also, flexible torque relaxing value may be measured and thread may be optimized on the basis of torque value. EFFECT: increased efficiency by increased precision of fiber or yarn torque measurement. 1 dwg, 10 ex

Description

 The invention relates to spinning production of the textile industry and can be used to control and optimize twisted yarn and yarn in terms of torque.

 It is known that the presence of elastic torque in a twisted yarn or yarn is evaluated in practice as equilibrium and is an important quality property, and also has great practical value in its subsequent processing. Large torque in unbalanced yarn leads to the formation of loops and succrutin, which creates additional breakage during its further processing, and also reduces the quality of the finished fabric and knitwear.

 A known method for determining the equilibrium of a thread or yarn, which consists in reducing the ends of a segment of the tested thread or yarn of a certain length to form a loop [1] C. 41-45. The equilibrium of the test thread or yarn is evaluated visually by the number of loop revolutions.

 The disadvantage of this method is the inability to numerically determine the magnitude of the torque of the thread or yarn with different values of the axial tensile force.

 The prototype adopted a method for determining the torque of an unbalanced twisted yarn or yarn, which consists in fixing one end of the test sample of yarn or yarn and the axial application of force to its other end [2].

 The disadvantage of this method is the inaccuracy of the measurements, due to the complexity of determining the magnitude of the torque. In addition, to determine the torque at different axial tensile forces, it is necessary to repeatedly repeat the tests at different masses of the load. This method is also complicated when studying the relaxation of torque in time at constant axial load and makes it difficult to optimize the thread in terms of torque.

 The technical result of the claimed invention is to increase the accuracy of measuring the torque of a twisted thread and yarn, the ability to measure the torque with different axial tensile forces in a single test, the ability to test several sections of the thread simultaneously with averaging the results, the ability to measure the relaxation of the torque of the thread under constant load for long time, as well as the ability to optimize the thread by the value of the twist to obtain the desired value of the spin yaschego moment.

 The specified technical result is achieved by the fact that in the method for determining the torque of a twisted textile thread and yarn, which consists in fixing one end of the test sample of thread or yarn and axial application of force to its other end, according to the invention, the test sample is placed horizontally and its fixed end is fixed rigidly or with the possibility of axial rotation, and the free end of the test sample is connected to an auxiliary sample of torsion-balanced or torsion-free long filamentary material is similar in thickness to the test specimen and having a strength greater than the strength of the test sample, wherein the force application is carried out once or sequentially changing the amount of force, and the test samples and supporting connected via the sensing element, on which the judged value and torque.

 The drawing shows a diagram for implementing the proposed method.

 The introduction of a sensitive element at the end of the test sample (between the test and auxiliary samples) is performed, for example, in the form of an elastic plate with strain gauges, which eliminates the unwinding of the test sample, allows numerically determining the magnitude of the thread torque and eliminates the measurement error due to twist loss. A single or sequential loading of the studied sample of the thread by suspending loads of different weights makes it possible to determine the torque of the thread at different values of axial tension, as well as to study the relaxation parameter of the torque of the thread for a long time and constant load. Fixing one end of the test sample of the thread with the possibility of axial rotation and thereby changing its twist at different values of the axial load allows you to optimize the thread according to the twist parameter with the necessary or minimum torque.

 The method is as follows.

 The inventive method is carried out according to the scheme (see drawing), where 1 is a test sample, 2 is an auxiliary sample, 3 is a sensitive element, 4 is a block, 5 is a load, 6 is a fixing screw, 7 is a device for turning the end of the test sample, 8 - support.

 Take a segment of a certain size of an untwisted twisted yarn or yarn 1, place it in a horizontal position, one end of a segment 1 is fixed in a support 8 with a screw 6, and a segment of an auxiliary long threadlike material 2 attached to the torsion is attached to the second end of a segment 1 ( for example, sewing thread), or without torsion (for example, kapron fishing line), close in thickness, rigidity and length of the tested thread, but exceeding it in tensile strength. The free end of the auxiliary segment 2 is thrown over the block 4 and the load 5 is attached to it, thereby loading the auxiliary 2 and the test 1 sections with axial tensile force and providing a horizontal arrangement. The sensing element 3 is installed in the guide with the possibility of longitudinal movement (not shown) when stretching the test sample 1, i.e., the sensitive element 3 does not interfere with the propagation of the axial tensile force from the auxiliary 2 to the test 1 pieces of thread. The loose end of a section of a twisted test thread 1 (at the point of connection with the sensing element 3) under the action of elastic torque transmits torque to the sensing element 3, for example, an elastic plate with strain gages (not shown). Thus, the torque of the test piece of thread 1 is converted into an electrical signal and recorded by tensometric devices (not shown). Attaching a load 5 of different weights makes it possible to vary the axial tensile force in the test specimen of thread 1 and test it with different axial tensile forces, and the presence of a device 7 allows you to change the twist of the test sample of thread 1 and examine the effect of twist of thread 1 on the value with a loose screw 6 torque, and also, changing both parameters (twist and axial force), optimize the yarn in terms of torque. In addition, it is possible to install, instead of one piece of the test thread 1, several (for example, 10 pieces) pieces of the test thread 1 of the same length, connected only at the ends. They create a torque (recorded by a sensitive element 3 and a strain gauge device) equal to the sum of the torques of all the studied sections of thread 1. Therefore, the true value of the torque of one thread is determined by dividing the result by the number of simultaneously tested pieces of thread 1. This allows you to speed up the test , while increasing their accuracy in the statistical processing of the obtained data.

Examples of practical implementation of the method
Example 1. Testing a single yarn with different axial tensile forces with torsion-balanced auxiliary material.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. One meter of yarn is taken, one end is fixed motionless, and an auxiliary torsion-balanced sewing thread 40 (25 tex) is attached to the second end through the sensing element. The second end of the sewing thread is thrown over the block and loads of various weights are attached to it (5 grams at the initial moment, and then 50, 100, 150, etc., to the tensile strength of the studied yarn). The sensing element converts the elastic torque of the tested section of yarn into an electrical signal, which determines the amount of torque at each value of the axial load. This test allows you to determine the equilibrium of the thread at different axial loads.

 Example 2. Testing a single yarn with different axial tensile forces with untwisted auxiliary material.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. One meter of yarn is taken, one end is fixed motionless, and a nylon line with a diameter of 0.2 mm is connected through the sensitive element to the second end. The second end of the fishing line is thrown over the block and loads of various weights are attached to it (5 grams at the initial moment, and then 50, 100, 150, etc., to the tensile strength of the studied yarn). The magnitude of the torque is determined, as in the previous example, by the magnitude of the signal of the strain gauge installation. This test allows you to determine the equilibrium of the thread at different axial loads.

 Example 3. Testing a single yarn with constant axial load and a different twist value with torsion-balanced auxiliary material.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. Take one meter of yarn, one end is fixed in a special rotary device, and the second end is loaded with an axial force of 50 grams through the sensing element and auxiliary sewing thread 40 (25 tex). Then, the twist of the test yarn is reduced by axial rotation of the fixed end of the test yarn by 50, 100, 150, etc. revolutions to the twist value at which there is a loss of strength and breakage of the tested yarn at a set axial load (in this example, 50 grams). The magnitude of the torque is determined, as in the previous examples, by the magnitude of the signal of the strain gauge installation. This test allows you to determine the minimum required twist of the yarn to obtain the minimum torque at the maximum possible strength of the yarn.

 Example 4. Testing a single yarn with constant axial load and a different amount of twist with untwisted auxiliary material.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. Take one meter of yarn, one end is fixed in a special rotary device, and the second end is loaded with an axial force of 50 grams through a sensitive element and a nylon line with a diameter of 0.2 mm. Then, the twist of the test yarn is reduced by axial rotation of the fixed end of the test yarn by 50, 100, 150, etc. revolutions to the twist value at which there is a loss of strength and breakage of the tested yarn at a set axial load (in this example, 50 grams). The magnitude of the torque is determined, as in the previous examples, by the magnitude of the signal of the strain gauge installation. This test allows you to determine the minimum required twist of the yarn to obtain the minimum torque at the maximum possible strength of the yarn.

 Example 5. Testing a single yarn for relaxation of elastic torque in time at constant axial load.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. Take 1 meter of yarn, one end is fixed motionless, and the second end is loaded with an axial force of 50 grams through a sensitive element and auxiliary sewing thread 40 (or a kapron fishing line with a diameter of 0.2 mm). Then measure the value of torque at constant axial force through 30, 60, 180, 240, 300, etc. minutes. This test allows you to determine the relaxation of the thread by torque at a given axial load.

 Example 6. Testing simultaneously several single segments of yarn with different axial tensile forces with torsionally balanced auxiliary material.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. Take several (for example 10) lengths of yarn of the same length (1 meter). Fasten all the segments at the ends with the same (5 grams) tension. Some ends of the pieces of yarn are fixed motionless, and the other ends are connected through a sensitive element to an auxiliary sewing thread 4 (250 tex), one end of which is thrown through the block and loads of 500, 1000, 1500 grams of various weights are attached to it, etc. to the ultimate strength of at least one of the test pieces of yarn. The magnitude of the torque is determined by the strain gauge installation, dividing the testimony by the number of simultaneously tested pieces of yarn. This test allows you to more accurately determine the torque of the yarn with a long-wave irregularity and simplifies the statistical processing of the results.

 Example 7. Testing simultaneously several single pieces of yarn with different axial tensile forces with untwisted auxiliary material.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. Take several (for example 10) lengths of yarn of the same length (1 meter). Fasten all the segments at the ends with the same (5 grams) tension. Some ends of the pieces of yarn are fixed motionless, and the other ends are connected through a sensitive element to a nylon line with a diameter of 2 mm, one end of which is thrown over the block and loads of 500, 1000, 1500 grams of various weights are attached to it, etc. to the ultimate strength of at least one of the test pieces of yarn. The magnitude of the torque is determined by the strain gauge installation, dividing the testimony by the number of simultaneously tested pieces of yarn. This test allows you to more accurately determine the torque of the yarn with a long-wave irregularity and simplifies the statistical processing of the results.

 Example 8. Testing simultaneously several segments of yarn for relaxation of elastic torque in time with constant axial load.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. Take several meter-long segments of yarn that are the same in length, fix them, as described in example 6 or in example 7, then load an axial load of 500 grams and measure the amount of elastic torque after 30, 60, 180, 240, 300 minutes. This test allows you to more accurately determine the relaxation of the thread by torque at a given axial load for yarn with a long-wave irregularity and simplifies the statistical processing of the results.

 Example 9. Optimization of yarn in torque with torsion-balanced auxiliary material.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. Take one meter of yarn, one end is fixed in a special rotary device, and the second end is loaded with an axial force of 5 grams through the sensing element and auxiliary sewing thread 40 (25 tex). Then measure the amount of torque. If this value is greater than what is required by the conditions (standard), then the twist of the test yarn is reduced with the knob of the turning tool (if less, then increase) until the torque becomes the desired value, and the resulting twist becomes optimal at this (5 grams ) axial load. Then the tests are repeated at a load of 50, 100, 150 grams, etc. This test allows you to determine the necessary twist of the yarn at a certain axial load with the condition of a certain (given, standard) torque.

 Example 10. Optimization of yarn torque with untwisted auxiliary material.

 The test material is a single cotton yarn 40 (25 tex) having a twist of 800 cr / m. Take one meter of yarn, one end is fixed in a special rotary device, and the second end is loaded with an axial force of 5 grams through a sensitive element and a nylon line with a diameter of 0.2 mm. Then measure the amount of torque. If this value is greater than what is required by the conditions (standard), then the twist of the tested yarn is reduced with the knob of the turning tool (if less, then increased) until the torque becomes the desired value, and the resulting twist becomes optimal at this (5 grams ) axial load. Then the tests are repeated at a load of 50, 100, 150 grams, etc. This test allows you to determine the necessary twist of the yarn at a certain axial load with the condition of a certain (given, standard) torque.

The advantages of the proposed method compared to the prototype:
- improving the accuracy of measuring torque, because the thread does not lose twist when measuring;
- the ability to investigate the effect of changes in axial load on torque in one segment, which increases accuracy and speeds up the measurement process;
- the possibility of studying the relaxation of elastic torque in time with constant axial force, which allows to determine the ductility of the thread by twist;
- the ability to simultaneously study the effect of changing the twist of the yarn and the axial load on the amount of torque, which allows us to optimize the yarn for twisting, selecting the amount of twist with the lowest torque, but providing the necessary strength;
- the ability to study several samples of the thread at the same time to average the measurement results, which significantly reduces the test time and improves the measurement accuracy with uneven threads.

Sources of information
1. G.V. Sokolov. Theory of torsion of fibrous materials. M.: Light Industry, 1977, 144 p.

 2. Copyright certificate of the USSR 1767419, cl. G 01 N 33/36, published. 10/07/1992 g.

Claims (1)

A method for determining the torque of a twisted textile thread and yarn, which consists in fixing one end of the test sample of thread or yarn and axial application of force to its other end, characterized in that the test sample is placed horizontally and its fixed end is fixed rigidly or with the possibility of axial rotation, and the free end of the test sample is connected to an auxiliary sample of torsion-balanced or torsion-free long threadlike material close in thickness to the test sam ples and having a strength greater than the strength of the test sample, wherein the force application is carried out once or sequentially changing the amount of force, and the test samples and supporting connected via the sensing element, on which the judged value of torque.