CS244894B1 - Testing device for measuring deformation forces of flanges by non-destructive method - Google Patents

Abstract

The solution is suitable for use in measuring the size of the hem clamp of hosiery products, especially in production units and in testing rooms. The subject is a testing device for measuring the deformation forces of hems by a non-destructive method, which consists of a stand, a device for measuring deformation forces, a stationary and movable tensioning element and a movement mechanism for moving these tensioning elements apart. The essence of the invention lies in the fact that the stationary tensioning element, which is mounted firmly on the stand of the testing device, is formed of a fixed jaw /2/, provided with a cylindrical element /3/. The movable tensioning element is formed from a divided movable jaw /4/, which carries a cylindrical element /5/ in combination with an additional compensating jaw /6/ carrying one or two cylindrical elements /7, 7'/. The crossbar /1/ is acted upon by a movement mechanism for moving the tensioning elements apart and a carrier /10/, which is firmly connected to it, in which the rod /11/ of the divided movable jaw /4/ is slidably mounted, the relative movement /A h/ with respect to the carrier /10/ being limited by the tolerance field /9/ of the locking member /8/.

Description

The invention relates to a test apparatus suitable for measuring the deformation forces of the rims, for example the rims of knitted standard hosiery, by a non-destructive method, in which the test product as a whole remains intact.

The tester comprises essentially a stand, a device for measuring the deformation forces, and a movement mechanism for detaching the tensioning elements in the form of open hook-like jaws.

The elastic hem of standard hosiery, such as stockings, socks, or knee socks, is designed to hold these articles on the lower limb. In practice, due to the deformation of these articles and their elastic properties, forces are exerted on the part of the limb which has caused this deformation.

The tension in the hosiery is compensated by friction between the article and the limb, whereby the hem of the hosiery fulfills for the most part the function of the carrier due to the higher clamping effect.

In some cases, the sweater is too large and acts directly as a strike, making it difficult to return blood in the venous system of the lower limb. From a health perspective, the use of such a product is directly harmful.

On the other hand, for medical stockings that affect blood flow by their clamping effect, this controlled, relatively high effect is used for therapeutic purposes and to support the venous system. However, the use of hosiery with these properties should be checked by a physician.

The prerequisite for the production of health-friendly hem of standard hosiery is, among other things, an objective, undemanding method of measuring the size of the grip. The permissible clamp values for these products are not yet set by a binding standard.

However, several methods are used to measure the prescribed clamp sizes for a special type of product, that is, for medical stockings, along the entire length of the legs. The measurements of the skirts themselves have not yet received the desired attention.

Several procedures are known in the literature for determining the permissible pressure values of elastic knitted articles, in particular compressive medical stockings exerting an appropriate pressure on different parts of the foot when worn.

One known measurement method is to thread a hose strip taken from a stocking onto rollers or over two non-split hangers, one of which is stationary and the other moves away from the stationary hanger, thereby deforming the threaded hose. The tension force required to cause deformation is determined when the prescribed deformation is reached.

According to another non-destructive method, a cushion filled with compressed air is inserted under the deformed state of the product under test. This pneumatic quasi-point method measures the clamp value directly.

However, the results are only relative and do not show the actual state of pressure - the grip. In addition, the size of the air cushion sensor is large relative to the geometric dimensions of the flanges and significantly distorts the measurement result.

Also known in the literature is a measuring device adapted to determine the grip size of hosiery by another non-destructive method. In this case, the rim of the article is placed on a split tension roller which, by moving the sliding half, stretches the rim to a position corresponding to the wear condition.

The second, stationary half of the tensioning roller is provided with a recess in which the tensioned portion of the skirt covering the recess engages. A tactile sensor mounted on one end of the rocker is used to force the tensioned portion of the hem to the surface of the tensioning roller, while the other end of the rocker is loaded so that the tactile sensor aligns the surface at the recess to the level of the tensioning roller without overhanging.

However, the measurement results depend on the objectivity of the evaluation because they lack uniform criteria and the equipment and method used do not guarantee the reproducibility of the measurement results.

In order to overcome the disadvantages of the aforementioned known methods and apparatuses, the present invention is directed to a crimping force measuring apparatus which operates on the principle of using a nondestructive clamping method for rims of knitted standard hosiery.

The basic equipment of the tester includes a stand, a device for measuring the deformation forces and a stationary and movable tensioning element including a movement mechanism for their removal.

SUMMARY OF THE INVENTION The stationary tensioning element, fixedly mounted on the machine stand, is formed from a fixed jaw to which one cylindrical element is attached, while the movable tensioning element is formed from a split movable jaw in which the other cylindrical element is inserted, in combination with an additional compensating jaw provided with one or two other cylindrical elements on one or both sides of the split movable jaw with a second cylindrical element inserted.

The compensating jaw is rigidly connected to the crossmember of the tester, the crossbeam being acted upon by a movement mechanism for detaching the tensioning elements, with which the carrier is fixedly connected to a slidably mounted split movable jaw. The relative movements of this split movable jaw relative to the carrier are defined by the height of the tolerance field of the locking member.

Depending on the type and method of measuring the deformation forces of the flanges, a tolerance field with defined fixed dimensions and a defined shape may be used. Alternatively, an arresting device may be used for any adjustable amount of relative movement of the rod relative to the carrier, replacing the arresting member with a tolerance field.

The use of an additional compensation jaw with one or two cylindrical elements makes it possible to eliminate the strokes of the other part of the product when measuring the deformation forces of the edges themselves.

The advantages of the design of the tester include the fact that it allows the product to return to its mission without any damage, and also that the measurement method is advantageous for its simplicity and ease of use.

The principle of the exemplary embodiment of the tester and the structural arrangement of the functional units are explained in the accompanying drawings, which show in FIG. 1 a diagram of a tester with a threaded test product, FIG. 2 shows a movable split and compensating jaw with one cylindrical element; 3 is a partial cross-sectional view of the movable split and compensating jaw with two cylindrical elements, FIG. 4 is a partial cross-sectional view of the movable part of the tester in a position prior to the deformation forces measurement;

According to FIG. 1, the rim L of the test article 4 is threaded onto a cylindrical element 6 of an inverted jaw 2, which is fixed to a frame of a test apparatus (not shown), the position of the jaw 2 being fixed relative to the frame.

The opposite portion of the flange L of the test article P is threaded onto the cylindrical element 5 of the split movable jaw 4, while the adjoining actual portion of the test product 4 surrounds the cylindrical element 5 of the compensating jaw 4 firmly connected to the crossbar 2 of the tester. An insert 12 and a carrier 10 provided with a groove 15 are connected to the crossbar 2. ^{In the} carrier 10 a tie rod 22 'is connected slidingly connected by means of a pin 13 to a divided movable jaw A and retained by a cylindrical element 5.

The tie rod 11 is provided with a locking pin 14 and terminates with a hinge 16 for connection with an unmarked device for exerting an external compensating force F. The carrier 10 has a locking member 8 with a tolerance field 9 inserted.

FIG. 2 shows the upper movable part of the tester with a split movable jaw A ' provided with a cylindrical element 5 and having a one-sided compensating jaw vybav equipped with a cylindrical element..

The remaining parts of this upper movable part of the tester are identical to Fig. 1 and described therein. The drawing of FIG. 3 differs from that of FIG. 2 only in that the compensating jaw 6 is double-sided and connects with its two cylindrical elements 7, 7 'from both sides to the cylindrical element 5 of the divided movable jaw 4.

An indirect method of measuring the crimping of the elastic articles themselves by the non-destructive method using the special split hook jaws of Figures 2 and 3, respectively, makes it possible to perform measurements on any deformation force measuring device, for example a conventional dynamometer or device described in this application.

In Fig. 4, the movable part of the tester is shown in partial section prior to measurement, i.e. with the locking member 11 extended to the right in the groove 18 of the carrier 20, thereby moving the rod 11 with the movable split jaw A and the cylindrical element 5. to the level of the cylindrical element 6 of the compensating jaw 5.

The groove 19 in the rod 11 allows insertion of the locking member and simultaneously also defines ^a vertical movement of the rod 11 when measuring the deformation forces. The spring 17 serves to facilitate replacement and securing of the split movable jaw 4.

FIG. 5 shows a view of the movable part of the tester during measurement, i.e. with the locking member 6 inserted to the left in the groove 18 of the TO-carrier. Due to the pull in the not shown edge L of the test product P and the external compensating force F, the locking pin 14 of the divided movable jaw A is located in the middle of the tolerance field £.

Function Description:

The rim L of the test product P is threaded onto the jaw-tester in such a way that the transition portion between the rim L and the adjoining actual portion of the test product P lies exactly between the cylindrical element 5 of the divided movable jaw A ^{and the} cylindrical element 6 of the compensating jaw 6. If a variant with a double-sided compensating jaw is used, the rim L or its part is placed on the cylindrical elements 7 ', 5' and 6 '.

Thereafter, the split movable part 4 is moved away from the fixed jaw by a magnitude corresponding to the prescribed deformation and in this case the rim L is loaded for a prescribed period of time. During this time, the divided movable jaw A is at the level of the compensating jaw £, which is due to the extension of the locking member do to the extreme right position - see Fig. 4.

After the prescribed loading time of the rim L, the locking pin 14 is released by moving the locking member 8 to the left, thereby relatively moving the rod 11 with the divided movable jaw A relative to the carrier 10 - see Fig. 5.

The magnitude of the relative movement of the rod 11 relative to the carrier 10 is determined by the magnitude A h of the tolerance field 9 of the locking member 6. The reduction of the magnitude A h of the tolerance field je can be achieved by partially inserting the locking member 8, or

After releasing the locking pin 14, the deformation forces in the lip L are compensated by the external compensating force F so that the compensating pin 14 assumes the middle original locking position - see FIG. 5.

Light signaling (not shown) with precise setting of the signaling area is used for precise identification of the locking position.

Claims (2)

A tester for measuring the crimping forces of the rims by a non-destructive method, such as the rims of knitted standard hosiery, comprising a stand, a crushing force measuring device, a stationary and movable open-hook tensioner and a movement mechanism for pulling off the tensioners; wherein the stationary tensioning element fixedly mounted on the stand of the tester is formed of a fixed jaw (2) provided with a cylindrical element (3), while the movable tensioning element is formed of a split movable jaw (4) provided with a cylindrical element (5) in combination with an additional compensating jaw (6) with one or two cylindrical elements (7, 7 ') connected rigidly to the cross beam (1) of the apparatus, the cross beam (1) being actuated by a movement mechanism for detaching the tensioning elements and in which it is sliding hlo (11) of a divided movable jaw (4), the relative movement (Δ h) of the carrier (10) being defined by the tolerance field (9) of the locking member (8). Testing device according to claim 1, characterized in that a tolerance field (9) having defined dimensions and a defined shape is formed in the locking member (8).