SU1397792A1 - Arrangement for determining elasticity of footwear - Google Patents

Abstract

The invention relates to a measurement technique for light industry and provides data on the flexibility of the shoe upper. The device includes a new platform on which a preformed shoe upper sample is being placed on the bend test. To imitate the work of the top of the shoe, taking into account the force interaction with the foot and the influence of its spreading forces on the top of the shoe 3, the platform is made in the form of a shoe pad, the exact part 2 of which can freely rotate relative to the toe part 1 at an angle of 33 while simultaneously increasing the fastening sizes in bundles by 5% and preserving the frame shape of the pad in any position. For this, the nose 1 and the right 2 parts of the pad are connected by a hinge 8 along the line of the beams from the side of track 9, and from the side of the dark surface both parts in the area of the beams have vertical longitudinal slits evenly spaced across the entire width of the block. slotted fine part. 5 il. about $ (L

Description

with so

s ± s

The invention relates to measuring equipment for light industry, namely, devices for determining the flexibility of shoes, and is intended to assess the flexibility of the shoe upper, to determine the nature and magnitude of the force interaction exerted on the foot during bending of the shoe in bundles. It can be used in research on the development of rational shoe designs,

The purpose of the invention is to improve the accuracy of determining the flexibility of the shoe upper.

FIG. 1 shows a diagram of a device for determining the flexibility of a shoe; in fig. 2 shows the construction of a platform for mounting a sample of the shoe upper, made in the shape of a shoe pad in the initial position (a) and when the heel is rotated relative to the toe (b) (section A-A) j in FIG. 3 is a section A-A in FIG. 2 (an example of changing the vertical division line); in fig. 4 - a platform with a shoe top spread and a device for fixing it; in fig. 5 is a section BB in FIG. 4, in the position of the sample, the sample is fixed (a), in the position of preparation for fixing the sample (b) and the form of the clamping plate (c).

A device for determining the flexible shoe (Fig. 1) contains a platform 1 and 2 for mounting the test sample 3 of the shoe upper, a device 4 for fixing the shoe top 3 on the platform sample, a mechanism for rotating the flat part of the platform 2 relative to the toe part 1 , an exact stop 5, small tensometric pressure sensors 6 and a device 7 for recording bending forces.

FIG. 2 shows the structure of the platform, which is made in the form of a shoe pad and consists of a toe 1, up to the beam line, and a flat part 2. Both parts are interconnected by a hinge 8 along the line of the beams on the track side of the block 9, with the possibility of turning the heel part 2 with respect to the toe part 1, which is horizontally mounted on the guide 10 with the possibility of movement along it and fixed with a screw 11. The specified rotation is ensured by the fact that in the body of the toe 1 and 5, 2 parts of the pad are perpendicular to the line of tufts

longitudinal vertical slits are made on the back side

12 (Fig. 2), evenly spaced across the width of the pads in the area of the beams. Moreover, the slits 12 in the toe part 1 are made asymmetrically by the slits 12 of the exact part 2, i.e. slot 12 of the exact part 2 corresponds to the protrusion

13 of part 1 and vice versa. The depth H of the slits 12 provides rotation of the exact part 2 by the angle of the NE, so that in the future it is possible to further study the flexibility properties of sports shoes as opposed to the household one, where the deflection angle is set to 25 when determining its flexibility. The width h of the slits 12 is determined by the dimensions of the strain gauge sensors used, 6 pressure and in this case corresponds to 12.5 mm for the toe part 1 and 10.5 mm for the flat part 2 of the pad. The width m of the resulting protrusions 13 in p 2

and the toe-shaped 1 part of the block, respectively, 12 mm and 10 mm, which makes it possible to place the projections 13 of the exact part 2 of the strain gauge 6 pressure sensors 6 with dimensions 10x10 mm on the smooth surface. This implementation of the slits 12 ensures the preservation of the frame of the pad in the area of the beams both in the initial position (Fig. 2a) and in the position of maximum rotation of the spot part 2 (Fig. 2b). This is important in simulating the forces of the interaction of the top of the shoe 3 and the foot, the role of which is assigned to the pad. Moreover, in the position of maximum rotation, the slots 12 are filled with the corresponding protrusions 13 (Fig. 26), thus forming a smooth junction of the thick surfaces of the 1 and 2 pads (Fig. 26), which does not prevent the natural formation of transverse folds on the top of the shoe when bending. According to the construction of the shoe, the value of its girth size in the beam area of the plenary part 2 is greater than the value of the girth size of the beam area of the toe part 1. Therefore, in the position of turning the nt (of the 2 part relative to the toe 1, the value of girth size in bunches is comparable with the initial position increased (fig, 2b) by 4 and 5.2%, respectively, at angles, turning 25 and 33. This ensures imitation of the action of the spacer usb from the foot to the top

shoes. FIG. 4 shows a general view of the platform in the initial position with the sample 3 installed on top of the sports shoe and fixed on the platform by means of the device 4 imitating the glue tightening of the top of the shoe. In more detail, the device 4 dp securing the sample of the shoe upper 3 is shown in FIG. 5. It consists of a metal plate 14 with the edges 15 curved upwards along the edge of the pad, in the threaded holes of which the clamping screws 16 are placed, the stop gasket 17 and the pressure plate 18 which is freely placed along the edge of the pad on the plate 14 between its curved edge 15 and the thrust pad 17 and is provided with protrusions 19, preventing its longitudinal movement. The metal plate 14 and the gasket 17 are rigidly attached to the shoe from the side of the track 9 in the toe and calf regions.

The rotation mechanism of the exact part of the platform consists of a vertical rod 20, on which the arm 21 is pivotally mounted with a plane of rotation coinciding with the longitudinal-axial section of the pad. One shoulder of the yoke 21 (Fig. 1) is connected to the exact part 2 blocks by means of a rigid link 22, having an adjustment along the length 23, and hinges, the upper hinge 24 being complete with the ability to move along the shoulder of the rocker arm 21, and the lower hinge 25 Located on the right part of the 2 pads in the place corresponding to the Achilles tendon on the foot. Such an arrangement is performed 22 in order to imitate the work of the lower leg calf group, and to register the effort required to bend the sample of the shoe upper 3, the ha 22 is equipped with a dynamometer 7. The other arm 21 is pivotally connected to the drive lever 26 by means of a rigid rod 27 also having an adjustment in length 28. The plane of rotation of the drive lever 26 with respect to the rigidly fixed hinge support 29 is aligned with the plane of rotation of the rocker arm 21, and its value is limited by adjusting

45 to meet the required value of the angle of rotation on a scale of 33 and fix this position of the lever 26 with a screw stop 30. The lever 26 is gently released, which, under the action of the return spring 31, returns the pad to its initial position. On the back surface there are small-sized strain gauge pads, pressure sensors 6, which are across pavements

a screw stop 30. For the set g, the measuring circuits are connected to the drive lever fixtures in the initial results of the quick action position — a return spring 31 is provided. To determine the angle to a self-powered device, for example, H 338 / 6п. Pushing the lever 26 down until it stops 30 turns the exact part

gate of the exact part 2 pads on

five

you is 0

Q

it has a pointer 32, and the silo rod 20 has a corresponding scale 33.

On the back surface of the block in the range from 0.55 to 0.95 D, is certain; Experimentally, as a region of folding when bending shoes in bundles, small-sized tensometric pressure sensors 6 (Fig. 1 and 4) are attached in the amount of 1 to 9 pcs with thin self-adhesive tape. depending on the required completeness of information. P exactm stop 5 is configured to adjust its height by means of a screw 34

(Fig. 1).

Preparing the device for operation

is that the block (Fig. 1) is set so that its longitudinal-axial section coincides with the guide 10, and the exact part 2 rests on the stop 5, installed in accordance with the required height 5 by an adjusting screw 34. In this position the nose part 1 of the pad is fastened with the clamping screw 11. After the connection with the hinge 25 of the exact part 2, the weight of 22 with the dynamometer 7 is adjusted along the length of the device 23 so that the direction of the thrust 22 coincides with the specified direction of the tibia by fixing the hinge 24 , and the yoke 21 received horiz ntalnoe position T gu 27 connected to a lever actuator 26 is adjusted along the length of device 28 until the lever 26, the uppermost position. On a scale of 33 using the pointer 32 mark the value of the initial position of the pads, and the scale of the dynamometer 7 is set to the initial position. Lower the drive lever 26 down to

0

five

0

position when pointer 32 is

Q

45 to meet the required value of the angle of rotation on a scale of 33 and fix this position of the lever 26 with a screw stop 30. The lever 26 is gently released, which, under the action of the return spring 31, returns the pad to its initial position. On the back surface there are small-sized strain gauge pads, pressure sensors 6, which are across pavements

measuring circuits are connected to the fixed results of high-speed

a self-feeding device, for example, H 338 / 6п. Pushing the lever 26 down until it stops 30 turns the exact part

2 pads to the extreme upper position at which the readings of the dynamometer 7 are computed. Then the device is brought to the initial position and prepared for installation on the shoe of sample 3 of the shoe upper, for which the clamping screws 16 (Fig. 4, 5) are turned out until when the clamping bar 18 takes a position inclined to the edge 15 (Fig. 5b). A sample of the top of the curb 3, preformed on a block of the same style5 as the platform and laced}, is cut along the edge of the track 35 of the pad of the most prominent area of the toe part 1 (up to the cross section 0.95 Dj.) And impose on the platform by the coincidence of the lines of ; track 35. At the same time tightening the edge; 36 in the toe cap 1 and the HEEL 2 h-THk are placed between the support plate, the laying 17 and the presser bar 18. In the stopped position, the sample of the shoe upper 3 is fixed, sequentially tightening the clamping screws 16; Sock, beam and gelbone on | | asteio. The lacing 37 of sample 3 is adjusted. to achieve his most nofiHoro fit pads. Opposite to the swivel 8 of the nose 1 and the exact 2 parts of the pad, a vertical segment of the draw edge 35 is cut on both sides of the sample 3 °.

The action of the device for determining the flexibility of the shoe is in a cycle) h: in the dry turning of the exact part 2 of the platform, with a pre-installed pattern of the shoe upper 3 (FIG. 4), relatively horizontally

fixed toe part 1 at a predetermined angle (25 °), by cyclic pressing of the drive lever 26 of the rotation part 5 of the mechanism up to the stop 30s. At the same time, the sample 3 of the shoe upper is bent into a bend in the form of a transverse fold in the beam area. The readings of the dynamometer 7 for registering the effort required for bending, are read at the moment when the exact part 2 reaches the specified angle of rotation, and the absolute value of the total thrust spent

for bending of the sample 3 tops of the shoe, calculated as the difference between the readings of the dynamometer in the tests with and without sample 3 of the shoe tops on the platform. The readings of the sensors 6 are continuously recorded with an appropriate recording device. Reading begins after the third test cycle. Duration of one cycle is 1 - 2 s. The number of samples of the top 3 for each shoe model under investigation is determined according to the known method for determining the required number of tests. Each sample is subjected to 5–8 test cycles, with the coefficient of variation not exceeding 5%, which is sufficient for obtaining the volume data.

Claims (1)

Invention Formula A device for determining the flexibility of a shoe, comprising a platform for mounting a sample of a shoe, a device for attaching it to the platform, a turning mechanism, a precision part, an abutment stop, strain gauges for recording pressure mounted on the platform and associated with a bend force detection device5 characterized in that, in order to improve the accuracy of determining the flexibility of the shoe upper, the platform for mounting the shoe sample consists of two parts, one of which is made in the shape of the toe part of the shoe The pads are up to the line of beams, the other is in the form of the exact part of the shoe, both parts are connected along the line of the beams from the side of the track with the possibility of rotating the right part 33 ° relative to the horizontally fixed toe part by means of a hinge and vertical longitudinal cuts uniformly made along the entire width of the foot in the toes and parachute parts are perpendicular to the line of beams on the side of the tympanic surface, with the notches in the parachute part being asymmetrically cut by the toe. 12 , ё- / .. , 0 II (iji {, -1 / .l // X h // I   J6 W / 5 Ig AT