RU2231031C2 - Method of measurement of tension of flexible long-cut members and device for realization of this method - Google Patents

Abstract

FIELD: measurement technology; measurement of tension of moving wire in the course of drawing.

SUBSTANCE: proposed method includes forming the supports for section of wire at two extreme points, tension of middle point of section by transversal force, measurement of resulting sag and analytic determination of the unknown of tension at tension limited by preset permissible error of measurement. Magnitudes of permissible sag and permissible error are related by definite relationship. Device proposed for realization of this method includes bearing rollers fitted on axles and pusher whose one end is engageable with article through force-sensing roller and other end is engageable with pressure unit and roller motion indicator. Novelty of invention consists in connection of pusher with body through hydraulic shock absorber.

EFFECT: enhanced accuracy and reliability of measurements.

7 cl, 3 dwg

Description

The invention relates to the field of measuring equipment, in particular, to measuring the tension of a moving wire during its drawing.

A known method of measuring the tension of wire reinforcement, including supporting a section of wire at two extreme reference points, applying a transverse force to the midpoint of this section and measuring this force and deflection of the reinforcement (see, for example, USSR author's certificate No. 338797, class G 01 L 5 / 04, 1972 [1]).

Also known is a device for implementing a method for measuring the tension of wire reinforcement, which contains two support rollers and a pusher, the movement of which is carried out through an eccentric connected to the lever [1].

The known method [1] does not allow to measure the tension in moving flexible products.

The device [1] for implementing the known method is relatively difficult, laborious to manufacture, requires the use of a hydraulic drive.

The closest in technical essence to the analogue of the invention in terms of the method is a known method for measuring the tension of flexible long products, including supporting a portion of a flexible product (in this case, a rope) at two extreme reference points, pressing the midpoint of the deflection section, measuring the resulting deflection and determining the desired the magnitude of the tension (see, for example, USSR author's certificate No. 3111155, class G 01 L 5/04, 1970 [2]).

In terms of the device, the closest analogue of the invention is the known device for measuring the tension of flexible long products (ropes), comprising a housing on which support rollers are mounted on the axes, a pusher interacting at one end through a power-receiving roller with the product, and at the other end with a pressure device and with roller movement indicator.

In the specified known method, the magnitude of the tension is determined by calibration charts. For certain predetermined deflections, the magnitude of the transverse force (pressing) on the product is counted on the scale of the manometer associated with the mass dose.

Calibration must be done by preloading the power-sensing roller and fixing accordingly these loads, the magnitude of the deflection and the magnitude of the tension. With large values of the measured tensions, there is a certain difficulty in constructing calibration diagrams, since it is necessary to first create large values of transverse loads, which in practice is difficult to implement.

A disadvantage of the known method is also that it is designed to measure constant tension over time and is unacceptable for measuring a moving flexible product (for example, wire during drawing), when the measured tension varies randomly depending on the conditions of movement of the wire and changes in technological parameters, and it’s difficult to take readings from the scale of the force meter. The influence of the moment of resistance of the product to bending, which occurs when the product deviates from the axis of tension, is also not taken into account.

As for the device for implementing this known method, it is difficult to manufacture due to the use of a pulsed dose and does not allow safe measurement of the tension of moving products, because it is not possible to fix the device case. The location of the device’s body is not on the same axis as the device itself leads to the bending of the body during loading, which affects the accuracy of the measurement of tension.

The objective of the invention in terms of the method is to simplify and improve the accuracy of measuring the tension of a moving product, in particular, by eliminating the construction of calibration diagrams and taking into account the given measurement error.

The objective of the invention in terms of the device is to increase the accuracy and safety of measuring the tension of a moving product, which is achieved by damping a power-sensing roller and due to the rigid fixation of the device.

The problem in terms of the method is solved by the fact that in the method for measuring the tension of flexible long products, including supporting the portion of the flexible product at two extreme reference points, pressing the midpoint of the portion with transverse force, measuring the resulting deflection and determining the desired magnitude of the tension, according to the invention, the measurement of tension the magnitude of the deflection defined by the following inequality:

and the desired value of tension is determined by the expression

where h is the deflection (deviation value) of the product from the initial axis of pulling;

L is the measurement base, the distance between the extreme reference points;

D is the diameter of the product;

N is the transverse force pressing the midpoint of the plot;

ε is the given measurement error;

P is the desired tensile force of the product.

The problem in terms of the device is solved in that in a device for measuring the tension of flexible long products, comprising a housing on which support rollers are mounted on the axes, and a pusher interacting at one end through a power-sensing roller with the product and at the other end with a pressure device and with an indicator moving the roller according to the invention, the pusher is connected to a rigidly fixed housing through a hydraulic shock absorber.

In addition, the push device can be made in the form of a flexible cargo suspension with a guide block and is equipped with a set of weights.

In addition, the push device can be made in the form of a spring dynamometer.

In addition, the pressure device can be made in the form of a hydraulic jack.

In addition, the housing of the device is installed coaxially with the pusher.

In addition, these means of rigid fixation of the housing can be provided with eyes on the housing and fixing means.

Thus, inventions, by eliminating the use of calibration diagrams, simplify and make more accurate the determination of tension, make it possible to determine the amount of tension in moving flexible products, and make the measurement process safe due to the rigid fixation of the device body.

Next, the method and device for measuring the tension of flexible long products are illustrated by drawings, where

figure 1 shows a diagram of the forces and moments that arise when measuring tension;

figure 2 shows a diagram for determining the moment of resistance to bending;

figure 3 shows a method of measuring tension and the design of the device for its implementation.

Symbols in the illustrations:

h - deflection (deviation value) of the product from the initial axis of pulling;

L is the measurement base, the distance between the extreme reference points;

D is the diameter of the product;

N is the transverse force pressing the midpoint of the plot;

P is the desired tension force of the product;

M _izg - the moment of resistance to bending;

σ _0.2 - yield strength of the product material.

A device for measuring the tension of flexible long products (in this case, moving in a wire drawing mill) includes (see FIG. 3): support rollers 1, rigidly mounted by means of axes in a housing 2 having eyes 3 for its rigid fixation. (The fixing means for fixing the case are not shown in the drawing.) The force-sensing roller 4, located at equal distances from the support rollers 1, is mounted on the pusher 5 and connected via the hydraulic shock absorber 6 and axis 7 to the case 2. The pressure device 8 is made in the form of a cargo area, on which the goods 9 are placed, which create, through the flexible connection system 10 and the pusher 5, the pressure N applied to the product 11. An indicator 12 is fixed on the housing 2, which records the amount of movement of the pusher 5 (or the deflection of the product h).

Alternatively, the pressure device 8 may be in the form of a spring dynamometer or in the form of a hydraulic jack.

Having set a certain maximum permissible error of measurement ε, we determine by inequality (1) the maximum allowable deflection of the product h when loading it with a transverse force N, at which the result does not go beyond the specified error. Further, by the expression (2), we determine the desired tension P of the product 11.

We show that for certain ratios of the product diameter (D), deflection (h) and length of the measurement base (L), the influence of bending moments is small and less than the specified error (ε).

The magnitude of the bending moments is influenced by the diameter of the measured product (D), the value of the specified deflections (h), the base (L), the material of the product (in particular, the yield strength σ _0.2 ) and the diameter of the support rollers. A diagram of the forces arising from the measurement by the device is shown in FIG.

In places where two support rollers are applied, a moment of resistance to bending of the product occurs

Where

- проекция усилия Р на ось протяжки;

- the projection of the force P on the axis of the broach;

N ₀ - force, taking into account the load force N and the influence of the moment of resistance to bending.

From (3) it follows

The unit can be neglected, because it does not affect the result, because it is a small quantity in comparison with another member of the radical expression. Consequently

The value of N ₀ determined from the ratio

or

where M _izg - bending moment that occurs in the product when it deviates from the axis of the broach;

L / 2 is the shoulder of the force creating the given bending moment.

As a result of the bending moment, elastic and plastic deformations occur in the product. Suppose that on the surface of the product, the deformations reach a yield strength σ of _0.2 . The moment M _izg arising in the product during kinks on the support rollers is determined according to figure 2 by the formula

Where

Then formula (8) takes the form

where R is the radius of the cross section of the product;

y is the current coordinate of the deformation zone that arises in the product, and at the same time is the shoulder of the force creating the moment relative to the center of the cross section of the product;

2b is the current (in y) width of the deformation zone.

Two of the integral front indicates that the bending moment (M _mfd) counted by the two support rollers.

Solving the integral (10) and taking into account that R = D / 2, we obtain a formula for determining the moment arising in a product from bending

where D is the diameter of the product.

Taking into account formulas (7) and (11), the expression for determining the magnitude of the tension takes the form

or

Thus, formula (13) differs from formula (2) by the value of the second term. With certain ratios of the product diameter (D), base (L), deflection (h), the second member of formula (13) does not have any effect on the result of measuring the magnitude of the tension.

We define these relationships in relation to the measurement error (ε)

or

The magnitude of the lateral pressure efforts should correspond to those efforts that can be created at the expense of available means - loads of springs. These forces should be several tens of times smaller than the tensile force. For example, if in the general case the tension force is maximum

and measured, for example, in tons, the pressure must be measured in tens of kilograms. For the convenience of working with loads, the value of the lateral load can be taken as 1/30 of the maximum tension force, then

Substituting (17) into (15) we obtain the inequality

or

The magnitude of the moment of resistance to bending is also affected by the magnitude of the deflection (h), which it is desirable to take the smaller, the larger the diameter of the product (D). Therefore, in formula (19) it is more correct to take into account the invariant - the product of the diameter and deflection, i.e.

Considering also that D and h are quantities of the same order, expression (19) can be written in the form

where from

Inequality (22) links together the product diameter (D), deflection (h) and the measurement base (L) and shows that for a given measurement error (ε), the deflection should be such that this inequality is fulfilled. In this case, formula (2) in the calculations expresses the magnitude of the tension with a given error (ε), and also the second term in formula (13) does not have an effect greater than the specified measurement error (ε).

By inequality (22), one can also judge the effect on the magnitude of the bending moment, the diameter of the product (D) and the base (L). Namely, the bending resistance increases with increasing diameter of the measured product, with an increase in the deviation of the product from the axis.

A device for measuring the tension of flexible long products (figure 2) works as follows.

The device is mounted on a fixed product 11 in such a way that the support rollers 1 abut against the product at the extreme reference points, and the movable power-sensing roller 4 mounted on the pusher 5 is led behind the product 11 on the other side opposite to the one on which the rollers 1 are located. All rollers touch the product 11 on one axis (axis of pulling). Set (configure) the indicator 12 of the movement of the pusher 5 to the maximum value of the readings and fix it. The body 2 of the device is fixed using the eyes 3 and other means not shown in the drawing to the fixed parts of the processing equipment.

Turn on the working equipment, the product begins to move along the axis. The movement of the device with the product is excluded, because its body is rigidly fixed. Next, the pressure device 8 is loaded, for example, with weights 9. The load is transmitted via a flexible coupling system 10 to the plunger 5, the force-sensing roller 1, which when it moves deflects the product 11 from the axis of movement. The deviation (deflection h) of the product is controlled by indicator 12 (deflection is defined as the difference between the initial, before the change, and the current, when measuring, indicator readings), it should not exceed the value of h determined by formula (1), for a given value of the maximum permissible error measurements. Possible fluctuations in the force and deflection that occur randomly, depending on the conditions of movement, are damped (damped) by the hydraulic shock absorber 6. The sought-for tension force P is determined, as already mentioned, by the formula (2).

EFFECT: inventions allow determining the tension force of an article experimentally, but without preliminary construction of calibration diagrams. Those. The final step in determining the desired effort is purely analytical. They allow you to get the value of the desired effort directly in the process of movement and with a predetermined accuracy, which is important according to the requirements of the technology. In particular, this is of great importance in the study of new devices for in-line drawing technology, in the measurement by this method of wire drawing forces and anti-tension forces of a wire rod. The invention also allows you to control the process of drawing.

Claims (7)

1. A method of measuring the tension of flexible long products, including supporting the portion of the flexible product at the two extreme reference points, pressing the midpoint of the portion with transverse force, measuring the resulting deflection and determining the desired magnitude of the tension, characterized in that the tension is measured with the magnitude of the deflection defined by the following inequality:

and the desired value of tension is determined by the expression

where h is the deflection (deviation value) of the product from the initial axis of pulling; L is the measurement base, the distance between the extreme reference points; D is the diameter of the product; N is the transverse force pressing the midpoint of the plot; ε is the given measurement error; P is the desired tensile force of the product. 2. A device for measuring the tension of flexible long products, comprising a housing on which support rollers are mounted on the axes, and a pusher interacting at one end with a force-sensing roller with the product, and with the other end with a push device and with a roller movement indicator, characterized in that the pusher is connected to the rigidly fixed housing through a hydraulic shock absorber. 3. The device according to claim 2, characterized in that the pressure device is made in the form of a flexible cargo suspension with a guide block and is equipped with a set of weights. 4. The device according to claim 2, characterized in that the pressure device is made in the form of a spring dynamometer. 5. The device according to claim 2, characterized in that the pressure device is made in the form of a hydraulic jack. 6. The device according to claim 2, characterized in that the housing is mounted coaxially with the pusher. 7. The device according to claim 2, characterized in that the means of rigid fixation of the housing are provided with eyes on the housing and fixing means.

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