SU660673A1 - Device for measuring coefficient of friction of man's skin against cloth - Google Patents

Description

(54) DEVICE FOR MEASURING THE COEFFICIENT OF FRICTION OF HUMAN SKIN ON TISSUE

Claims (1)

The invention relates to medical technology, namely to instrumentation technology and can be used in studies of irivative systems and orthopedic devices (prostheses for arms, legs, orthopedic corsets, etc.). A device for measuring the coefficient of friction of human skin is known. A scan comprising a housing, a measuring drive and a transducer. A measuring drive is fixed in the housing, which is a tape rolled up in a ring and driven by the engine. The tape is pulled across the skin of a person with a frequency of 11 cycles per minute. A friction engine is used as a measuring transducer that measures the resistance force of pulling a tape over a person’s skin, the speed of which is functionally related to friction force 1. The coefficient of friction of a person’s skin against a fabric depends on the force of normal pressure, the relative speed of movement of a person’s skin on the fabric, posture of a person, which determines the pre-tension of the skin. From this point of view, the coefficient of friction of a person’s skin against tissue can be measured most accurately only in natural conditions, when a person is placed in a real structure and is subjected to real loads (for example, overloads arising from ejection or sudden braking of a car). The device does not allow, with the required accuracy, to measure the coefficient of friction of a person’s skin against a tissue in a person placed in an actual design when exposed to short-term dynamic loads due to the large inertia of both the measuring drive and the measuring transducer. The purpose of the present invention is to increase the accuracy of measuring the ratio of the skin of a person to a tissue in real conditions of dynamic loads. The goal is achieved by adding a measuring device to the device — a logometer, a measuring transducer made in the form of two perpendicular to each other, elastic sensitive elements with resistance strain gages mounted on them connected to two separate bridge circuits, and the measuring drive is in the form of in the body of the table for a sample of tissue mechanically connected through ball guides to elastic sensing elements, while the outputs of bridge circuits are connected cheny two measuring chains of the ratio-meter. FIG. 1 shows schematically a device for measuring the coefficient of friction of human skin against tissue; in fig. 2 -. electrical circuit device. The device comprises a housing 1, in which a measuring transducer is placed in the form of two perpendicular to each other, elastic, sensitive elements 2 and 3 with resistance strain gages 4 and 5 glued to them. On an elastic sensitive element 2, the measuring drive is mounted on a ball guide 6 table 7, on which the test sample of fabric 8 is attached. Table 7 through the ball 9 contacts its end with an elastic sensor 3. The device itself is installed in a slot of the structure, for example, the back of a chair 10. Strain gages 4 and 5 are included in two bridge circuits I and I. The outputs of these bridge circuits are connected to two measuring circuits 11 and 12 of a measuring instrument — a logometer. The measurement of the coefficient of friction of the human skin against the tissue by the device is performed as follows. Under the influence of dynamic loads, the person sags along the back of the chair (for example, during ejection or sudden braking of the car) and with his skin slides along the back of the chair 10, along the working surface of the body 1 and the sample of fabric 8, while the measuring table 7 moves along the ball guides 6 on the elastic sensing element 2 parallel to the working surface of the body until the ball 9 rests on the elastic sensing element 3. The deflection of the element 2, depending on the value of the normal pressure of the human skin The measuring table is perceived by the strain gauges 5, the deflection of the element 3, depending on the strength of the resistance to the movement of human skin through the tissue — the force of friction — is sensed by the strain gauges 4. The output voltage of circuit I, directly proportional to the normal pressure, is fed to frame 11, and the output voltage of circuit II, directly proportional to the magnitude of the friction force, is connected to the circuit 12 of the frame of the measuring instrument - the logometer. In a gauge-type measuring instrument, the angle of rotation of the moving system is “f, or M). where 1 | - The current flowing through one measuring circuit, and Iz - on the other. If Ui is the voltage proportional to the magnitude of the friction force, and Ua is the voltage proportional to the magnitude of the normal pressure force, then a UF) PC), where K is the coefficient of friction. Thus, the electrical circuit of the device generates a signal directly proportional to the value of the coefficient of friction of the human skin on the tissue sample under investigation, which improves the measurement accuracy. The device is convenient to use and allows measurement of the coefficient of friction of a person's skin against a tissue under natural conditions when a person is exposed to short-term dynamic loads. An apparatus for measuring the coefficient of friction of a person's skin against a fabric comprising a body, a measuring drive and a transducer, characterized in that, in order to improve the measurement accuracy under real conditions of dynamic loads, a measuring device, a logometer, is additionally introduced into the device perpendicular to each other, elastic sensing elements with strain gages mounted on them, connected in two separate bridge circuits, and KSR Control drive is designed as a table disposed in the housing for the tissue sample is mechanically bonded through a ball-s Yusch guide with elastic sensing elements, the outputs of the bridge circuits connected to the two measurement chains ratiometer. Sources of information taken into account in the examination 1. Proceedings of the conference: Proceedings of 25 th annual SopGege lse on Eng. in Medicine and Biology, USA, 1972. Pete