RU42952U1 - MANUAL EXPOSURE DEVICE - Google Patents

Abstract

The device can be used in surgery to correct the spine and limbs, reposition of dislocations, in diagnostics, with body massage and other medical purposes. It contains a medical glove 1, flexible strain gauges 2, mounted on the finger of the glove 1 in areas adjacent to the pads of the fingers entered into the glove of the hand. Strain gauges 2 are connected to the computer 4 through the block of microcontrollers 3. In the process of using the device, the user observes on the screen of the computer 4 the force of the influence of his fingers on the patient and corrects it, maintaining it at a given level. Indicators of manual exposure are recorded in the memory of the computer 4 and are used for subsequent analysis. 5 cp f-ly, 6 ill.

Description

The utility model relates to medical devices and devices and can be used in surgery for correction of the spine and extremities, reposition of dislocations, in diagnosis, as well as for body massage and other medical purposes.

Known medical protective glove glued from a plastic film with the formation of holes for dressing on the user's hand (international application PCT 93/240068, A 61 B 19/04, A 41 D 19/00, A 41 D 13/10, publ. 09.12 .1993). The glove has a release surface that prevents adhesion to sticky objects.

A medical glove is also known, containing the inner and outer layers made of a transparent or light-transmitting polymer material (international application PCT 94/02080, A 61 B 19/04, publ. 02.02.1994). A solid water-soluble dye is placed between the layers. When a glove breaks, the liquid dissolves the dye, which is a signal that the glove breaks.

Known hygienic glove containing the palm and back surfaces (RF patent for utility model No. 33706, 7 A 61 B 19/04, publ. 16.07.2003). A bag with

shampoo or medicinal ointment and a bag with a washing or disinfecting solution. The bags are connected to the bags, laid on the middle finger of the glove. The free ends of the tubes are closed with plugs. The hygienic glove, in addition to its protective function, improves the convenience of cleaning and disinfecting body parts.

Also known is a surgical glove equipped with an insert of high strength (UK application No. 2264670, A 61 B 19/04, publ. 08.09.1993). The insert is made of several layers of durable flexible material, glued to each other by spot welding or sewn so that the insert can be freely bent.

Closest to the proposed device for the totality of signs is a medical glove with the palm and back surfaces and overlays fixed on the finger of the glove in areas adjacent to the pads of the fingers entered into the glove (US patent No. 5428841, 6 A 41 D 13/08, A 41 D 19/00, publ. 04.07.1995). Pads reinforce the glove, prevent punctures and tears of its most stressed sections. Such a glove can be used for manual exposure to humans.

A disadvantage of the known medical glove is the low accuracy of withstanding the force of the user's fingers squeezing the patient’s body parts and the pressure on the patient’s fingers, as well as the lack of the ability to visually control the force exposure over time. In addition, the well-known glove does not provide the ability to memorize the parameters of the produced force impact over time, which complicates the subsequent analysis of the results of this effect and the comparison of parameters with parameters of similar effects.

The objective of the utility model is to increase the accuracy of withstanding the efforts of the user's fingers to squeeze parts of the patient’s body and the pressure of fingers on the patient,

providing the ability to visually control the force impact over time. Another objective of the utility model is to provide the ability to memorize the parameters of the produced force action over time to facilitate subsequent analysis of the results of this effect and to compare their parameters with parameters of similar effects.

The specified technical result is achieved by the fact that the proposed device for manual exposure to humans, containing a medical glove with the palm and back surfaces and patches attached to the finger part of the glove in areas adjacent to the pads of the fingers entered into the glove, additionally contains flexible strain gauges, unit microcontrollers and computers, and strain gauges are installed between the finger part of the glove and attached to them overlays and are electrically connected mi conductors with the input of the microcontroller block, the output of which is connected to a computer.

The patch is mounted on the finger of the glove with the formation of a pocket for placement and holding in it a strain gauge.

The pocket is made with an opening for input and output strain gauge sensor.

The microcontroller unit is mounted on a bracelet worn on the user's hand.

Electrical conductors connecting the strain gauge sensors to the input of the microcontroller unit are placed on the back of the glove and attached to it with adhesive tape.

Strain gauges mounted on the finger of the glove, the microcontroller unit and the computer, electrically connected to each other, allow the patient to act on the patient with a given force, visually control the force of influence, maintaining at a given level, and also fix

parameters of manual exposure to the patient over time, while the glove does not create unpleasant sensations in the patient due to the implementation of strain gauges flexible and their placement under the pads.

Pockets with openings formed by appropriately securing the pads on the finger of the glove and securing the electrical conductors to the glove with adhesive tape allow you to quickly and conveniently connect the gloves to the rest of the device before use and to separate the gloves after using the device.

By placing electrical conductors on the back of the glove, their damage is prevented when using the device.

By fixing the microcontroller unit on a bracelet worn on the user's hand, it is possible to conveniently place it on the user.

The proposed device is illustrated by the drawings shown in figures 1-6.

Figure 1 shows a front view of the device for manual exposure to humans.

Figure 2 shows a view of the palm surface of the glove with strain gauges located in the pockets.

Figure 3 is a side view of the finger part of the glove with a strain gauge located in the pocket.

In Fig.4 is a right view of the finger part of the glove shown in Fig.3.

Figure 5 is a view of the back surface of the glove with strain gauges located in the pockets.

Figure 6 is a perspective view of a bracelet with a microcontroller unit mounted on it.

A device for manual exposure to humans contains a medical glove 1, flexible strain gauges 2, a block of microcontrollers 3 and a computer 4.

Medical glove 1 has a palmar 5 and a back 6 surface. On the finger part 7 of the glove 1 from the side of the palm surface 5, pads 8 are fixed with the formation of pockets 9 for placement of strain gauge sensors 2. The pockets 9 are made with openings 10 for input and output of the strain gauge sensors 2 and are located on the parts of the glove 1 adjacent to the pads 11 fingers 12 inserted into the glove 1 of the user's hand. In this case, the nail plates 13 of the fingers 12 are located on the opposite side of the pockets 9. Strain gauges 2 are connected by electrical conductors 14 to the input 15 of the microcontroller unit 3. Electrical conductors 14 are laid on the back surface 6 of the glove 1 and are attached to it by adhesive tape 16. Microcontroller unit 3 mounted on a bracelet 17, worn on the user's hand, and connected to its output 18 via cable 19 with a computer 4.

The device operates as follows.

Before using the device, strain gauge sensors 2 are inserted into the pockets 9 of the glove 1 through the openings 10. The electrical conductors 14 are laid on the back surface 6 and attached to it with adhesive tape 16. The glove 1 is put on the user's hand so that the pads 11 of the fingers 12 are adjacent to the same areas gloves to which strain gauges 2 are attached. In this case, strain gauges 2 are bent and, due to their flexibility, take the form of pads 11 of fingers 12. In pocket 9, strain gauge 2 is held by friction against atku 1 and the sheet 8. Put on the bracelet 17 in the user's hand and connect the cable 19 to the computer 4. The computer 4 After connecting to the mains produce zero resistance indices of strain gauges 2.

In the process of using the device, for example, during correction of the spine and limbs, reduction of dislocations, diagnostics and massage, the user acts on the patient or other person, squeezing parts of his body with his fingers or pressing on certain points of his body. In this case, the compression or pressure force is transmitted from the user's hand through flexible strain gauges 2. The resistance of the strain gauge 2 changes depending on the change in the force acting on it. An electrical signal characterizing the resistance of the strain gauge sensor is transmitted through the electrical conductor 14 through the input 15 to the block of microcontrollers 3, in which it is converted to digital form. After conversion, the electric signal enters through cable 19 to the computer 4, is reflected on the screen of the computer 4 and is recorded in its memory. The user observes the strength of his influence on the computer screen 4 and maintains the magnitude of this force at a level corresponding to a given program. Indicators of manual exposure recorded in the memory of a computer 4 are used later in the analysis of the results of exposure, comparing them with similar effects and adjusting the program of manual exposure.

Claims (6)

1. Device for manual exposure to humans, containing a medical glove with the palm and back surfaces and overlays fixed on the finger of the glove in areas adjacent to the finger pads of the gloved hand, characterized in that it additionally contains flexible strain gauges, a microcontroller unit and a computer, and strain gauges are installed between the finger part of the glove and the pads attached to them and are connected by electrical conductors to the input of the microcontrol unit scooters, the output of which is connected to a computer. 2. The device according to claim 1, characterized in that the patch is mounted on the finger part of the glove with the formation of a pocket for placement and holding in it a strain gauge. 3. The device according to claim 2, characterized in that the pocket is made with an opening for input and output strain gauge sensor. 4. The device according to any one of claims 1 to 3, characterized in that the microcontroller unit is mounted on a bracelet worn on the user's hand. 5. The device according to claim 1, characterized in that the electrical conductors connecting the strain gauges to the input of the microcontroller unit are placed on the back surface of the glove. 6. The device according to claim 5, characterized in that the electrical conductors are attached to the back surface of the glove with adhesive tape.