RU2006023C1 - Device for determining stretching resistance of footwear top - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: device has a deforming unit, unit for stretching, recording unit and unit for mounting foot wear to be tested including a stop controllable in the dependence of footwear size. The deforming unit is made in the form of stretching rollers having shape of a ball truncated on both sides and mounted on a rack kinematically coupled with a shaft at one end of which a disk for recording the stretching is mounted and on the other end of which a loading handle is mounted. The recording device is made in the form of a scale with an indicator coupled through a spring with the deforming unit. EFFECT: enhanced accuracy and efficiency. 2 dwg

Description

 The invention relates to measuring equipment and can be used to measure the spacer stiffness of the upper shoe. Spacer stiffness characterizes the resistance of the cross sections of the shoe approximately in the region of the metatarsophalangeal joint to a change in its shape.

 The prototype is a device designed to determine the spacer stiffness of the upper of the shoe, which characterizes its resistance to changes in the transverse dimensions of the foot in the area of lifting and metatarsophalangeal articulation, i.e., the ability of the upper to stretch when wearing shoes. The device contains a sliding block simulating the nose-beam part, in the surface of which pressure sensors are mounted. The block is divided into sectors that are moved apart by means of a device equipped with a wedge.

 Spacer stiffness is defined as follows. A table is compiled of the ratios of the angle of rotation of the handle and changes in the linear dimensions of the pad ΔV. The forces between the surface of the block and the top are recorded through specific angles of rotation using the sensor calibration schedule and the table of changes in the volume dimensions of the block depending on the angle of rotation. The ratio of efforts to the corresponding change in volume gives the value of the coefficient of expansion stiffness.

 The disadvantage of this methodology and the device for measuring the shoe spacer stiffness is that different types of shoes and styles require their own pads. The extension of the pad segments in the device does not simulate the complex interaction of the foot with the shoe.

 There is no clear definition of the index of expansion stiffness (the characteristic of expansion stiffness with the help of a coefficient is only valid if P is proportional to ΔV). The readings of capacitive sensors strongly depend on the humidity of the surrounding space and the material filling the dielectric gap and other factors.

 The purpose of the invention is to increase the accuracy and objectivity of the measurement results by approximating loading conditions to real ones and expanding technological capabilities.

 This goal is achieved in that the device for determining the spacer stiffness of the upper shoe, containing a base, an insert with deforming elements mounted on it, a mechanism for moving the deforming elements with a handle and means for recording the resistance to deformation, according to the invention, further comprises a fifth stop mounted on the base coaxial to the insert with the possibility of axial movement and fixing its position depending on the size of the shoe, while the deforming elements are made in the form e spacer rollers, each of which has the shape of a ball truncated on both sides, and the mechanism for moving the deforming elements comprises a shaft rigidly connected to the handle and a disk for recording the magnitude of the expansion of the deforming elements mounted on the shaft in gear racks kinematically connected to the shaft and bearing on spacer rollers at its outer ends, and the means for registering the deformation resistance force is made in the form of a scale with a pointer connected through a spring and a cable to the deformation movement mechanism ive elements.

The device makes it possible to install a deforming device depending on the width of the insole in a section of 0.73 D _feet for various types of shoes, has a device for determining deformation in millimeters in this section and a device for determining the tensile force.

 In FIG. 1 shows a device in a perspective view; in FIG. 2 - section AA in FIG. 1.

 The device (see Fig. 1) is a device consisting of a housing 1 of a welded or cast construction, at the base of which there is a shaft 2, on the first end of which there is a handle 3 with a pointer 4 indicating the insole width in millimeters in a segment with a scale of 5 section 0.73D, where D is the foot length equal to the size of the shoe. At the left end of the shaft there is a disk 6 with a limb, which serves to determine the deformation in millimeters of the shoe sample in cross section 0.73D. Through the cables 7, the shaft 2 through the intermediate rollers 8 is connected to the gear 9. The wheel 9 through the gear transmission transmits the rotation of the gear 10, and then, in turn, through the racks 11 to two spacer rollers 12.

 A spring-loaded clamp 13 is located in the upper rear part of the housing, which is able to press the heel of the shoe against the stop 16 through the lever 14 using the ratchet locking dog 15. The angle of inclination of the clamp 13 in the upper part of the lever 14 is fixed by the nut 17.

 The stop 16 is mounted on a screw 18 having a scale on which the dimensions of the shoe being tested are plotted. The distance to the 0.73D cross-section of the test shoe sample is established by rotating the nut 19 by aligning the face of the nut 19 with dividing the scale of the screw 18 corresponding to the size of the shoe.

 Fixing the shaft 2 in a certain position, if necessary, is carried out by screw 20.

 A device is installed on the right side of the housing strut for determining the resistance to deformation of the tested shoe sample, which is a slider 21 connected by a spring to the cable 7, on which the pointer 22 is fixed. The pointer 22 shows the deformation resistance force on the scale of the slide 23 fixed by the screw 24.

 Instrument setup.

 Before starting work, the device must be adjusted to the desired size of the shoe being examined. To do this, first set the necessary insole width corresponding to a given shoe size, by aligning the pointer 4 on the handle 3 with the desired division on the scale of the segment 5 and screw 20 to fix the position of the handle.

 By rotating the disk 6, combine the zero division of the latter with the risk B on the device body.

 Set the slider 23 so that the pointer 22 coincides with the zero division of the scale on the slider 23 and fix the position of the slider 23 with the screw 24.

 Turn the nut 19 to set the required distance to the cross section 0.73D by combining the face of the nut 19 with the risks corresponding to the desired size on the screw 18.

 Place the test sample upside down at three points: an emphasis 16 (heel support) and two rollers 12.

 Bring clamp 13, having previously pressed dog 15 and fix the test shoe sample with clamp.

 If necessary, install and fix with the nut 17 the desired angle of inclination of the clip.

 Release the locking screw 20 and make the handle 3 extend the spacer rollers 12 by 10 m, which is fixed on the dial of the disk 6. After that, on the scale of the slider 23, determine the deformation resistance force, which characterizes the spacer stiffness of the shoe. (56) Copyright certificate of the SSR N 221381, cl. G 01 N 2/20, 1984.

Claims (1)

 A device for determining the spacer stiffness of the Upper of shoes, comprising a base, an insert with deforming elements mounted on it, a mechanism for moving deforming elements with a handle and means for registering the deformation resistance force, characterized in that it further comprises a heel stop mounted on the base coaxially with the insert with the possibility of axial movement and fixing its position depending on the size of the shoe, while the deforming elements are made in the form of spacer rollers, each of which has the shape of a ball truncated on both sides, the movement mechanism of the deforming elements comprising a shaft rigidly connected to the handle, a disk for recording the magnitude of the expansion of the deforming elements mounted on the shaft, and gear racks kinematically connected to the shaft and carrying spacer rollers at the outer ends, and the means for registering the deformation resistance force is made in the form of a scale with a pointer connected through a spring and a cable to the movement mechanism of the deforming elements.

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