RU2166307C1 - Complex immobilization stretcher and method for immobilizing victims - Google Patents

Abstract

FIELD: medicine; medical engineering. SUBSTANCE: device has gas-proof air-inflatable envelope filled with granulated material, vacuum pump, and fastening belts. Flexible pneumatic chambers are mounted on the working surface of the envelope. The inferior chamber is arranged symmetrically with respect to longitudinal axis of the stretcher and the superior one is positioned asymmetrically with respect to longitudinal axis of the stretcher. Fastening belts of the inferior pneumatic chamber are fixed on the longitudinal axis of the stretcher and on its lateral members. Pneumatic chamber sections have tube for compressed air delivery and valve for controlling air pressure limit. A victim is placed on vacuum mat filled with granulated material and rigid bed is formed by pumping air out of the mat. The vacuum mat is provided with the inferior and superior pneumatic chamber. The lower and part of the vacuum mat is fastenable around the victim legs together with the inferior pneumatic chamber, the superior pneumatic chamber being fixable around the abdominal cavity. Compressed air is supplied into the pneumatic chambers, beginning from the inferior one. Compressed air is optionally supplied into any pneumatic chamber independently of the other ones. Air pressure in the inferior pneumatic chamber is set to be 1.2-2.3 times as high as that in the superior one. EFFECT: multiple functional applications of the stretcher. 13 cl, 3 dwg

Description

 The invention relates to medicine, in particular to disaster medicine, and can be used for the evacuation of a victim with simultaneous hemostatic measures.

 When the victim is evacuated from the scene of a disaster - a road accident, an earthquake, the collapse of buildings, mine rescue operations in mines, mountain climbing, during military operations, etc. - there is a problem of fixing the victim’s body on a stretcher with simultaneous hemostatic measures, and fixing the victim should allow, firstly, to carry the stretcher through obstacles (blockages, cracks, etc.), tilting and turning them, and, secondly, to prevent large blood loss during evacuation.

 Known pressure bandage to stop bleeding from an open wound, containing a dense gas-tight compress, a flexible elastic wall of which is applied on the outside of the treated wound. This part of the wall is deformed outward under the pressure of the air injected into the compress. The dressing is installed on the damaged place and fastened with straps (patent EPO 0216883 from 1986, MKI A 61 F 5/34).

 Also known is the thoraco-brachial corset for immobilization of the limbs, comprising a body consisting of two half-corsets, and lodgements. Half-corsets and lodgements are made two-layer in the form of rigid external and hermetically connected internal elastic shells forming a pneumatic chamber. Both lodges are laced up in the required position, then air is pumped into the pneumatic chamber between the outer and inner shells and the damaged limb is stably fixed (A.S. USSR 1533687 from 1990, MKI 5 A 61 F 5/37).

 Another device for stopping bleeding in the hip part is made in the form of a bandage, on the inner surface of which, facing the victim, a pneumatic chamber is installed connected to a source of compressed air. The bandage is installed and fixed on the victim so that the pneumatic chamber is in the damaged area, then air is pumped into the pneumatic chamber, covering the pre-treated wound (PCT patent WO 97/49360 of 1997, MKI 6 A 61 F 5/34).

 All the analogues described above solve only one problem: they prevent blood loss during injuries, but do not allow the victim to be fixed on a stretcher during his evacuation. In addition, none of these analogues is not adapted to squeezing, if necessary, plasma and blood from the lower limbs and abdominal cavity of the victim.

 The problem of fixing the victim on a stretcher for the time of his evacuation is solved by immobilization stretchers containing a gas-tight, air-filled shell with working and back surfaces filled with granular material, a vacuum pump and seat belts. The victim is laid on the working surface of the gas-tight shell so that granules are placed on all sides of the body, and then the air in the shell is pumped out. Due to the created vacuum and the natural roughness of the granules, they stick together with each other, as if forming a rigid shell repeating the bends of the victim’s body and covering it from below and from the sides (AS USSR 381349 from 1973, MKI 5 A 61 G 1 / 00). This analogue is taken as a prototype of the claimed device and method for immobilizing the victim.

 The prototype does not provide for the possibility of simultaneously fixing the body of the victim and the use of pneumatic devices to stop bleeding.

 The objective of the proposed invention is to create immobilization complex stretchers that combine the functions of an immobilization fixation device and a hemostatic bandage that allows you to squeeze bleeding wounds and, if necessary, squeeze plasma and blood from the lower extremities and abdominal cavity.

 This problem is solved in that the immobilization complex stretchers contain a gas-tight, air-filled casing with working and back surfaces filled with granular material, a vacuum pump and seat belts. Sectional elastic pneumatic chambers are additionally fixed on the working surface of the shell, the lower of which is located symmetrically to the longitudinal axis of the stretcher at a distance of 0.1-0.15 to 0.5-0.55A from their bottom, and the upper is asymmetrically placed relative to the longitudinal axis of the stretcher and is located at a distance of 0.5-0.55 to 0.65-0.75A from their bottom, where A is the length of the stretcher. The straps of the lower pneumatic chamber are fixed on the longitudinal axis of the stretcher and along their edges, and the straps of the upper pneumatic chamber are fixed on its lateral edges. The sections of the pneumatic chambers are equipped with a nozzle for supplying compressed air and a valve of maximum air pressure. The length of the stretcher is equal to 1.0-1.5 of the average human anthropometric growth. The upper and lower pneumatic chambers can be connected by a bypass air valve, and the compressed air supply pipe is installed on the lower section of the lower pneumatic chamber. The air pressure limit valve is equipped with a pressure indicator made in the form of a whistle or an inflatable ball, or in the form of a light signaling device. The sections of the pneumatic chambers can be made isolated from each other, and each section can be equipped with a nozzle for supplying compressed air and an air pressure limit valve with a pressure indicator. The air pressure in the sections of the lower pneumatic chamber can exceed the air pressure of the sections of the upper pneumatic chamber by 1.2-2.3 times. The width of the lower pneumatic chamber may exceed the width of the stretcher by 2.4-2.8 times, and the width of the upper pneumatic chamber may exceed the width of the stretcher by 1.8-2.5 times.

 In addition, this problem is solved by the fact that the method of immobilizing the victim is that the victim is placed on a vacuum mattress filled with granular material, and a rigid bed is formed by pumping air out of the mattress. The vacuum mattress is pre-equipped with lower and upper pneumatic chambers, and when forming a hard bed, the lower part of the vacuum mattress together with the lower pneumatic chamber is fixed around the victim's legs, and the upper pneumatic chamber is fixed around his abdominal cavity, then compressed air is supplied to the pneumatic chambers. The lower part of the vacuum mattress together with the lower pneumatic chamber can be fixed around each leg of the victim. Compressed air can be supplied starting from the lower pneumatic chamber, and also can be supplied to each chamber separately, independently of other chambers. The air pressure in the lower pneumatic chamber during the implementation of the method is set 1.2-2.3 times higher than the air pressure in the upper pneumatic chamber.

 A comparative analysis of the claimed inventions with the prototype shows the presence of distinctive features in them, allowing to conclude that there is novelty in the claimed device and method.

 A comparison of the proposed immobilization complex stretchers and the method of immobilizing the victim with other known devices and methods that perform the same functions shows that the combination of gas-tight air-filled shells with granular material inside and elastic pneumatic chambers and their relative position in one device allow, firstly, to create around hard shell, repeating all the bends of the body adjacent to the shell, secondly, due to this shell to get an outer bandage for I pneumatic chambers, thirdly, to create, through pneumatic chambers, the effect of depreciation during transportation of the injured person and, fourthly, by gradually filling air chambers with air from the bottom up and squeezing plasma and blood from the lower extremities and abdominal cavity due to the air pressure difference in the lower and upper pneumatic chambers . In addition, the shape of the air-filled shell and pneumatic chambers make it possible to carry out artificial respiration and indirect heart massage of the victim, laid on a stretcher, if necessary. The presence of indicators of air pressure and bypass valves in the pneumatic chambers allows you to adjust the force of the impact of the pneumatic chambers on individual parts of the victim's body. The same effect can be achieved due to the fact that the sections of the pneumatic chambers are made independently of each other and are equipped with individual nozzles for supplying compressed air and limit pressure valves.

 Thus, the technical effect obtained from the use of the proposed invention exceeds the prior art.

 The invention is illustrated by the example of its implementation.

The drawings show:
- in FIG. 1 - general view of the immobilization complex stretcher, plan view;
- in FIG. 2 is a section along AA in FIG. 1;
- in FIG. 3 - map, indications for the use of a stretcher.

 The stretchers are made in the form of a gas-tight main shell 1 of elastic material filled with granules 2. On the side of the main shell there are adjoining additional wings 3 located symmetrically to the longitudinal axis 4 of the stretcher and formed, like the main shell, from elastic material and filled with granules. Additional wings are adjacent to the main shell in a section of length (0.3-0.45) A, where A is the length of the stretcher, taken equal to 1.2-1.5 of the average human anthropometric growth, and the lower end of 5 additional wings is located at a distance ( 0.10-0.15) A from the lower end of the stretcher 6. Sectional pneumatic chambers are fixed on the working surface 7 of the main shell and additional wings, the lower 8, 9 of which are located symmetrically to the longitudinal axis of the stretcher at a distance of 0.1-0.15 up to 0.3-0.45A from the lower end of the 6 stretcher, and the upper 10 is placed asymmetrically relative to the longitudinal axis of the stretcher and is located at a distance from 0.3-0.45 to 0.65-0.75A from their bottom. The attachment belts 11 of the lower 8 and 9 pneumatic chambers are fixed on the longitudinal axis 4 of the stretcher and along their edges 12, and the attachment belts 13 of the upper pneumatic chamber are fixed on its lateral edges 14. The sections 15, 16, 17 of the pneumatic chambers 8, 9 and 10 are equipped with a pipe 18 for feeding compressed air and the valve 19 of the ultimate air pressure. The upper 10 and lower 8 and 9 air chambers can be connected bypass air valve 20. A pipe 18 for supplying compressed air is mounted on the lower section 15 of the lower 8 air chambers. The valve 19 of the maximum pressure of the air is equipped with a pressure indicator 21, made in the form of a whistle or an inflatable ball, or in the form of a light indicator (not shown). The sections 15, 16 and 17 of the pneumatic chambers can be made isolated from each other, each section in this case must be equipped with its own pipe 18 for supplying compressed air and a valve 19 of the maximum air pressure with a pressure indicator. The width of the lower 8 and 9 pneumatic chambers exceeds the width of the main shell 1 of the stretcher by 2.4-2.8 times, and the width of the upper 10 pneumatic chambers exceeds the width of the main shell 1 by 1.8-2.5 times. An embodiment of the main shell is the separation of its inner cavity by longitudinal jumpers 22, forming the extreme sections of the cavity by longitudinal jumpers 22, forming the extreme sections 23. The stretchers are equipped with a vacuum pump 24 for pumping air and maintaining the vacuum in the inner cavity and the air pump 25 or other source of compressed air (for drawings not shown) to maintain a given pressure in the pneumatic chambers. Depending on the design of the stretcher, pumps 24 and 25 can be attached to each casing 1 and 3 and each section 15, 16 and 17 of the air chambers, respectively, or connected to them in series. The main 1 vacuum shell and additional wings 3 can be connected to each other by air channels with valves (not shown), which can overlap, isolating the cavity of the sections from each other. Handles 26 are used to carry the stretcher.

 Work with a stretcher is carried out in the following order: the victim is placed on the main shell 1 filled with air. Granules 2, which are in the shell in a free state, move and are located around the body under the influence of the victim’s body weight. Then, around the victim’s legs, additional wings 3 of the main shell are wrapped together with the lower 8 and 9 pneumatic chambers and secured with straps 11, and the abdominal cavity is closed with the upper 10 pneumatic chamber to the level of the solar plexus and fixed with the straps 13. After that, from the main shell 1 and wings 3 air is evacuated, as a result of which the granules located in the shell and wings "stick together" with each other, creating a hard shell 27, repeating the bends of the victim’s body from below. The carapace individually covers each leg of the 28th victim and fixes the hip joint. Due to the fact that the main shell of the stretcher has a length exceeding the average human anthropometric height by 1.2-1.5 times, at the bottom under the soles of the legs and above the victim’s head are formed rollers 29 made of granular material, allowing tilting the stretcher with the victim around the horizontal transverse axis . Next, air is pumped into the nozzles 18, which inflates the pneumatic chambers 8, 9 and 10. At the same time, tamponage of open wounds occurs and at the same time (if necessary) extrusion of plasma and blood from the lower extremities and abdominal cavity of the victim. The efficiency of this operation is increased due to the fact that air is first supplied to the lower pneumatic chambers 8 and 9 and already through them and through the bypass air valve 20 it enters the upper pneumatic chamber 10, distilling the plasma and blood from the bottom up. With an air valve 20, it is possible to set the air pressure in the upper pneumatic chamber below the air pressure in the lower pneumatic chamber; the pressure in the lower air chambers can be in the range of (1.2-2.3) P, where P is the pressure in the upper air chambers. The design of the stretcher allows, if necessary, to carry out artificial respiration and indirect heart massage during transportation of the victim, since the chest remains free.

 Air-filled pneumatic chambers stop bleeding from the femoral artery and vessels of the lower leg, iliac artery, and even from large branches of the abdominal aorta. Displacing blood from the lower extremities and some organs of the abdominal cavity and small pelvis, pneumatic chambers are able to provide normal blood supply to the brain, heart, lungs, liver and kidneys for 10-12 hours, make it possible to ensure a normal level of blood pressure.

Claims (13)

 1. The method of immobilization of the victim, which consists in the fact that the victim is placed on a vacuum mattress filled with granular material, and a rigid bed is formed by pumping air out of the mattress, characterized in that the vacuum mattress is pre-equipped with lower and upper air chambers, and when forming a hard bed, the lower part of the vacuum mattress along with the lower pneumatic chamber is fixed around the victim’s legs, and the upper pneumatic chamber is fixed around his abdominal cavity, then compressed into the pneumatic chamber boiled air.  2. The method of immobilizing the victim according to claim 1, characterized in that the lower part of the vacuum mattress, together with the lower pneumatic chamber, is fixed around each leg of the victim.  3. The method of immobilizing a victim according to claim 1, characterized in that the compressed air is supplied starting from the lower pneumatic chamber.  4. The method of immobilization of a victim according to claim 1, characterized in that the compressed air is supplied to each pneumatic chamber separately, independently of other pneumatic chambers.  5. The method of immobilizing a victim according to claim 1, characterized in that the air pressure in the lower pneumatic chamber is set 1.2 to 2.3 times higher than the air pressure in the upper pneumatic chamber.  6. Immobilization complex stretchers containing a gas-tight, air-filled shell with working and back surfaces filled with granular material, a vacuum pump and attachment belts, characterized in that sectional elastic pneumatic chambers are additionally fixed on the working surface, the lower of which is located symmetrically to the longitudinal axis of the stretcher at a distance from 0.1 - 0.15 to 0.3 - 0.45 A from their bottom, and the top is placed asymmetrically relative to the longitudinal axis of the stretcher and is located at a distance from 0.3 - 0.45 to 0, 65 - 0.75 A from the bottom, where A is the length of the stretcher, and the attachment belts of the lower pneumatic chamber are fixed on the longitudinal axis of the stretcher and along their edges, and the attachment belts of the upper pneumatic chamber are fixed on its lateral edges, while the sections of the pneumatic chambers are equipped with a supply pipe compressed air and air pressure limit valve.  7. Immobilization complex stretchers according to claim 6, characterized in that the length of the stretcher is 1.2 to 1.5 times the average human anthropometric height.  8. The immobilization complex stretcher according to claim 6, characterized in that the upper and lower pneumatic chambers are connected by a bypass air valve.  9. Immobilization complex stretchers according to claim 6, characterized in that the compressed air supply pipe is installed on the lower section of the lower pneumatic chamber.  10. The immobilization complex stretcher according to claim 6, characterized in that the limit valve for air pressure is equipped with a pressure indicator made in the form of a whistle, or an inflatable ball, or in the form of a light signaling device.  11. The immobilization complex stretcher according to claim 6, characterized in that the sections of the pneumatic chambers are made isolated from each other, each section being equipped with a nozzle for supplying compressed air and an air pressure limit valve with a pressure indicator.  12. The immobilization complex stretcher according to claim 6, characterized in that the air pressure in the sections of the lower pneumatic chamber exceeds the air pressure of the sections of the upper pneumatic chamber by 1.2 - 2.3 times.  13. The immobilization complex stretcher according to claim 6, characterized in that the width of the lower pneumatic chamber exceeds the width of the main shell of the stretcher by 2.4 - 2.8 times, and the width of the upper pneumatic chamber exceeds the width of the stretcher by 1.8 - 2.5 times.

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