RU2775560C1 - Disposable shoe covers with conductive inserts - Google Patents

Abstract

FIELD: medical technology.

SUBSTANCE: group of inventions relates to barrier-type hygiene products used in medical diagnostics, physiotherapy, as well as non-medical measurements of human body parameters in cases where the procedure requires contact of a person’s feet with the electrodes of the equipment/device used. Disposable shoe covers with conductive inserts for bioimpedance measurement consist of a single flap of material with two conductive inserts located in the holes for inserts. The base of the shoe cover is made of a material with the functions of a dielectric. The first conductive insert is located in the middle zone of the toe part of the shoe cover sole, and the second insert is located in the middle zone of the heel part of the sole. The location of the conductive inserts in the sole of the shoe covers coincides with the location of the electrodes on the bioimpedance analyzer. Disposable shoe covers are used for use as insulating and conductive shoes.

EFFECT: increase in the accuracy of bioimpedance measurements is achieved, reducing or eliminating the ingress of dirt, fungi, bacteria, viruses and other undesirable particles on the surface of the human foot from the elements of the measuring instruments used due to the use of disposable shoe covers with increased ease of use (excluding disinfection or sanitary treatment of the surface of the instruments, reducing the measurement time and operating costs), and also having simplicity of design.

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Description

The present invention relates to light industry, and more specifically, to barrier-type hygiene products used in medical diagnostics, physiotherapy, as well as non-medical measurements of human body parameters in cases where the procedure requires contact of a person's feet with the electrodes of the equipment / device used.

One of these devices is the InBody bioimpedance body composition analyzer, manufactured in South Korea, which, for example, can analyze the increased amount of fat in the human body, which is associated with an increased risk of serious medical complications, including cardiovascular problems, diabetes and other diseases in adults, which is very important in today's world.

Such devices are located in publicly accessible places and allow, without visiting medical institutions, to determine the fat content in the body. In connection with the coronavirus and other infections spread in public places, the issue of disinfection of bioimpedance analyzers after each analysis is an acute issue. This requires the allocation of service personnel who would disinfect and sanitize the surface of the device after each measurement, which is very costly economically.

These costs can be greatly reduced by using disposable shoe covers with conductive inserts. This product is designed to avoid direct contact of a person's feet with elements of medical and other measuring / diagnostic equipment / device in cases where procedures require electrical contact between the surface of the feet and the electrodes of the device.

The result of using the product is to limit the ingress of dirt, fungi, bacteria, viruses and other unwanted particles on the surface of the human foot from the elements of the device used. Thus, with a large flow of patients, there is no need to disinfect the surfaces of the device after each use. EFFECT: invention makes it possible to save disinfectants, save personnel time, and also protects surfaces from the aggressive action of disinfectants.

From US Pat. No. 3,146,377 A, disposable conductive shoe covers are known which are specially adapted for health or hygiene purposes, for example, containing a conductive material capable of discharging electrostatic charges. These overshoes are intended for use where it is desirable to conduct static electricity from the wearer in surgical operating rooms to discharge static charges during operations. The coating not only provides static discharge, but also provides a bacterial barrier against virulent organisms that can enter the operating room from the shoes of the surgeon or his assistants.

The disadvantages of the known device are the limited scope and inconvenience in operation and the impossibility of their use in the measurement of impedance.

From US Pat. No. 3,335,506 A, an electrically conductive surgical shoe cover for surgeons is known, containing a conductive material that allows electrostatic charges to be discharged. The hygienic shoe cover completely covers the shoe with a non-conductive coating, but which has a conductive sole and a conductive tongue connected to the sole and extending into the shoe cover to provide contact with the human foot.

The disadvantages of the known device are the limited scope and inconvenience in operation and the impossibility of their use in the measurement of impedance.

From US Pat. No. 3,381,174 A impenetrable conductive shoe covers are known, specially designed for use in environments such as hospital operating rooms and the like, where anesthetics pose a distinct explosion hazard. The product includes a conductive overshoe made of expandable and contracting textile material to tightly fit the user's foot and be able to be held on the user's foot without the need for additional supportive means such as ties, laces, separate elastic bands, etc.

The disadvantages of the known device are the limited scope and inconvenience in operation and the impossibility of their use in the measurement of impedance.

US Pat. No. 3,296,489 A discloses low-cost surgical overshoes which, due to their significantly reduced cost, allow these overshoes to be used and disposed of after use, thereby eliminating the additional washing and sterilization costs associated with current types. In addition, this overshoe can be easily expanded to fit over shoes of any size, thereby eliminating the need to store a large number of overshoes of different sizes. In addition, the disposable surgical shoe has a strip of conductive material, the free end of which can be easily grabbed and tucked inside the user's sock to fit against the skin of the user's leg for grounding.

The disadvantages of the known device are the limited scope and inconvenience in operation and the impossibility of their use in the measurement of impedance.

From US Pat. No. 2,958,012 A, conductive disposable shoe covers are known which are primarily made of paper, but which can be sterilized in conventional sterilizers for reuse. The article of the present invention comprises an upper part enclosing the leg of the user, connected to a lower part, which is usually a conductive material, and means for completely enclosing the foot and part of the leg of the user, as well as means for providing electrical contact.

The disadvantages of the known device are the limited scope and inconvenience in operation and the impossibility of their use in the measurement of impedance.

From US Pat. No. 3,564,335 A, shoe covers are known that are adapted to be worn by doctors and nurses during surgical operations to electrically ground their bodies to the floor they stand on so that static electricity does not build up and cause a spark in the vicinity of explosive gases that are sometimes used. in surgery. The shoe covers fit a variety of shoe sizes and have two overlapping plastic panels joined along their back and bottom edges by a tie bar in the middle of their top edges holding the panels together. An electrically conductive plastic strip is sealed along the bottom edge of one panel, the strip having a protrusion for tucking into a wearer's shoe or stocking to provide electrical contact to the wearer's body.

The disadvantages of the known device are the limited scope and inconvenience in operation and the impossibility of their use in the measurement of impedance.

From US Pat. No. 3,359,658 A, disposable electrically conductive shoe covers for surgical and similar purposes are known, consisting of two halves of a thin material, each of which, in a flattened state, before use, takes the form of a shoe when viewed from the side, open at the top for inserting the wearer's shoe and connecting, at least , on the toe and sole. Ties are provided to hold the cover in place, and means are provided to ground the user's foot to the floor.

It is known from patent RU 2400112 C2 that most of the known shoe designs use antistatic threads or conductors, which are often located evenly under the supporting surface of the foot or on the surface of the sole. But, due to the anatomical structure of the human foot, the supporting surface of the foot does not fully and evenly touch the floor. There are areas of support of the human foot that are subjected to more pressure, and areas of the foot that are hardly affected by the weight of the body, and thus are not subjected to pressure and are not in contact with the floor.

Since it is known that the electrical conductivity also depends very strongly on the pressure between two objects in mutual contact, it is obvious to a person skilled in the art that not the entire supporting surface of the foot is in contact with the sole, i.e. not the entire sole has the same electrical conductivity. . This inevitably leads to the disadvantage of different resistance at different points on the foot's supporting surface and, in particular, to an increase in resistance in those areas of the foot that are subjected to lower pressure, since the electrical contact is not reliable. As a result, since the electric current always passes at the point of lowest resistance in the circuit, the discharge of the electrostatic charge to the device preferably occurs through certain areas of the foot, i.e. those. which are subjected to higher pressure. For this reason, the use of most existing shoe covers with conductive inserts inevitably leads to distortion of bioimpedance measurements.

The purpose of this invention is to provide shoe covers with conductive inserts that can be used in bioimpedance measurements of the type described above, in which it is possible to eliminate the shortcomings of the known conductive shoe covers in a simple and inexpensive way, while simplifying and reducing the cost of manufacturing such shoe covers.

According to the present invention, the above objectives are achieved by creating the above-described shoe covers, in which the sole contains at least two zones made of electrically conductive material that are tightly adjacent to the desired areas of the human foot and to the surface of the electrodes of the devices. The sole of the shoe cover has two electrically conductive inserts located in the areas of opposite ends of the sole, that is, the toe and heel, the location of each of which coincides with the location of the electrodes of the measuring device.

The technical result consists in the creation of shoe covers with conductive inserts that make it possible to increase the accuracy of bioimpedance measurements, reduce or eliminate the ingress of dirt, fungi, bacteria, viruses and other unwanted particles onto the surface of the human foot from the elements of the measurement devices used, which have increased ease of use (excluding disinfectant or sanitization of the surface of instruments, which reduces measurement time, reduces operating costs), and also has a simple design.

The advantages of this invention are obvious from the above description and primarily consist in providing a more complete electrical contact of the user's body with the measuring device at a sufficiently high resistance. In addition, the specific design makes it easy to put on and take off the shoe cover. The location of the sole inserts made of electrically conductive material in the toe area and in the heel area, which are typical points of support determined by the anatomy of the foot and the dynamics of walking, always provide the possibility of electrical contact between the foot and the device, thus excluding as much as possible the occurrence of conditions under which decreases measurement accuracy due to unstable electrical contact between the sole and the device. The design and arrangement of the electrically conductive zones of this invention does indeed result in a substantially uniform distribution of resistance across the foot's support surface such that the electrostatic charge passing from the device to the foot and back to the device travels evenly over a significant portion of the foot's support surface without being concentrated in one place. . Thus, the disadvantage associated with the presence of preferential current passage zones, which lead to measurement distortion when the charge passes from the device to the foot and back to the device all the time in the same place of the foot, is eliminated.

Features of the invention and its improvements are given in the claims.

Features of the present invention and the advantages arising from them. are explained in the following detailed description of the accompanying drawings, in which:

Fig. 1 is a top view of the shoe cover.

Fig. 2 is a bottom view of the shoe cover.

Fig. 3 is a sectional view of the shoe cover.

It is well known that shoe covers consist of a single piece of polymeric material glued on the side of the toe and heel and in the upper part around the circumference of a glued rubber ring.

On FIG. 1 and FIG. 2 shows a disposable hygienic shoe cover having the construction of the present invention. As can be seen in particular in FIG. 2, the sole part 1 of the hygienic shoe covers has a shape in plan corresponding to the sole, consisting of the toe part 2 and the heel part 3, both parts of the sole have a conductive insert located in the areas of opposite ends of the sole, that is, the toe and heel, the location of each of which coincides with the location of the electrodes of the measuring device.

The basis of the products is made from a material that has the functions of a dielectric, including, but not limited to: woven textile materials, non-woven textile materials, or non-textile materials such as polyethylene, cardboard, paper, etc.

For the manufacture of shoe covers, non-woven material - spunbond - is best suited.

Cutting of materials is carried out using a punching press.

To fasten the shoe cover and give it a finished shape, semi-automatic sewing machines with an overlocker or with a edging machine are used.

Conductive inserts can be made both from conductive woven materials containing copper and nickel, and from non-woven materials, including, but not limited to: metal foil.

Also, the conductive inserts can be made of an absorbent material with dielectric properties, but immediately before use, the inserts can be given the function of an electric current conductor by wetting them with a conductive liquid.

To select the material of conductive inserts, experimental studies of various types of conductive materials were carried out using the InBody bioimpedance body composition analyzer.

Most of the studied materials, which are conductive fabrics from various manufacturers from China, due to the high resistance to the passing electric current, distorted the results of InBody770 measurements and cannot be used for the manufacture of final products.

Based on the experiments carried out, two basic conductive materials are most preferred, suitable in terms of conductance. low resistance to electric current and suitable cost. This is, firstly, aluminum foil, and secondly, a fabric containing at least 20 mass% copper and at least 20 mass% nickel, as well as polyester.

Both materials give the measurement error of a person with the InBody770 device less than one percent, which is extremely low against the background of the own error declared by the manufacturer of this device up to 3%.

Conductive inserts are attached to the dielectric substrate in several ways, including, but not limited to: sewing, gluing, thermal fusion, and others.

For attaching conductive inserts to the base of the shoe cover, the gluing method and the stitching method turned out to be the most preferable.

The conductive inserts of the products are made in a shape close to the shape of the electrodes of the used model of a medical/diagnostic/measuring device.

The sole shown in Fig. 3 has two inserts made of electrically conductive material and extending through the entire thickness of the sole.

The first electrically conductive insert, indicated by the position 4, is located in the middle zone of the toe of the sole, and its location coincides with the location of the sensor of the device. The second insert 5 is made in the heel part. Its location also coincides with the location of the instrument's sensor. Thus, electrical contact between the user's foot and the device occurs when the conductive inserts of the sole and electrodes are applied and forms a mutual electrical contact between the areas of the foot and the electrodes of the device.

According to the first distinguishing feature, the conductive inserts are located in the zones of the opposite ends of the sole, that is, the toe and heel parts. With regard to the location of the insert 4, made of electrically conductive material in the toe area of the sole, it is located not in the middle part of the sole, but essentially near the metatarsophalangeal joint, in particular in the area of the first metatarsal bone.

Taking into account the anatomy of the normal foot and the location of the inserts 4 and 5, made of electrically conductive material, it should be noted that the inserts are located in the heel area and the first metatarsal area, and that these points are two of the three main points of foot support. This is true for static state.

Claims (8)

1. Disposable shoe covers with conductive inserts for bioimpedance measurement, consisting of a single piece of material with two holes for inserts, with two conductive inserts, characterized in that the base of the shoe cover is made of a material that has the functions of a dielectric, with the first conductive insert located in the middle zone the toe part of the sole of the shoe cover, the second conductive insert is located in the middle zone of the heel part of the sole of the shoe cover, while the location of the conductive inserts in the sole of the shoe cover coincides with the location of the electrodes on the bioimpedance analyzer. 2. Disposable shoe covers with conductive inserts according to claim 1, characterized in that the base of the shoe cover is made of a material that has the functions of a dielectric, including woven textile materials, non-woven textile materials or non-textile materials such as polyethylene, cardboard, paper. 3. Disposable shoe covers with conductive inserts according to claim 1, characterized in that the conductive inserts are made of a material that has the functions of an electric current conductor, including woven and non-woven materials. 4. Disposable shoe covers with conductive inserts according to claim 3, characterized in that the conductive inserts are made of metal foil. 5. Disposable shoe covers with conductive inserts according to claim 1, characterized in that the conductive inserts are made of an absorbent material with dielectric properties and acquire the functions of an electric current conductor by wetting them in a conductive liquid. 6. Disposable shoe covers with conductive inserts according to claim 1, characterized in that the location of the conductive inserts in the sole of the shoe covers coincides with the location of the electrodes of the bioimpedance body composition analyzer. 7. Disposable shoe covers with conductive inserts according to claim 1, characterized in that the conductive inserts are attached to the base of the dielectric by sewing, gluing, fusion. 8. The use of disposable shoe covers according to claim 1 for use as insulating and conductive shoes.

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