RU2294187C2 - Transformable altitude chamber - Google Patents

Abstract

FIELD: medical engineering.

SUBSTANCE: device has axially symmetrical reservoir having sealed internal flexible membrane and power membrane embracing it. End covers are available on their rims one of which has sealed unit for introducing cradle into the reservoir. Power membrane is manufactured from structural fabric having edges shaped as ring-shaped closed loops having at least one embedded member connectable to end cover. The embedded member is of profiled shape formed by two cylindrical surfaces conjugated with hemisphere on one side and with conic surface on the other one.

EFFECT: high reliability; easily transformable structure.

16 cl, 5 dwg

Description

The invention relates to medical equipment and can be used in hyperbaric oxygenation systems for the treatment and prevention of patients.

Hyperbaric oxygenation systems known at medical centers around the world are built on the basis of rigid pressure chambers and, as a rule, are made of metals. Such pressure chambers are very bulky and inconvenient during transportation.

Known attempts to create similar systems using soft pressure chambers (Pat. RF №2076676). In such a system, the soft pressure chamber contains a place (lodgement) for the patient connected to the supporting structure, a hermetic soft container made of a thin film with a multicellular mesh of flexible cord, tape or wire, isolating the patient's place from the surrounding space. This design uses a cantilever clamping tool tray, placing the patient in it is difficult. The visualization of the internal volume is complicated due to the presence of cells and there is practically no possibility of reliable installation of medical and emergency control and alarm equipment.

A flexible transformable pressure chamber is also known, containing an axisymmetric container, consisting of a sealed inner shell of elastic fabric and a power shell enveloping it, along the edges of which end caps are placed, one of which is made with a sealed connector for introducing a lodgement into the container (US Pat. US 5738093, 1998 g.). The design of the chamber is such that the inner elastic shell is connected to the end caps through a transitional sealing assembly on a spherical surface, which does not allow for sufficient tension of the fabric of which the shell is made and its tight fit. This leads to the complexity of the implementation of the site of sealing and the possible mechanical destruction of the tissue at the place of its entry into this site.

The power shell is made of separate longitudinal elements, passed at their ends through the slots made in the spherical surface of the ring-shaped parts located on the side of the covers. The deduced ends of these elements are sewn respectively to their element, thereby securing the fastening of the shell at the ends of the chamber. The friction of these elements in the slots can lead to weakening and even destruction in this place of the element, which also reduces the reliability of the entire camera. Also, the design of the camera does not allow it to be easily transformed into a compact structure for the convenience of transportation.

The objective of the invention is the creation of a transformable flexible pressure chamber of high reliability, with the possibility of easy transformation in the field.

The problem is solved in that in a transformable pressure chamber containing an axisymmetric container with a sealed inner shell of elastic fabric and a power shell covering it, at the edges of which end caps are placed, one of which is made with a sealed connector for introducing a lodgement into the tank, the power shell is made of structural fabric with edges in the form of closed ring-shaped loops, inside of which at least one embedded element is placed with the possibility of connection with the end cover, while the embedded element is made profiled with a cross section formed by two cylindrical surfaces, conjugated on one side in a hemisphere, and on the other on a conical surface

The problem is also solved by the fact that the end caps are made with shells, on the cylindrical surfaces of which holes are made through which fasteners are introduced, which serve to connect the power shell with the embedded elements, and in the embedded elements threaded holes can be made into which the fastening elements are screwed.

To solve this problem, the pressure chamber can be equipped with shock absorbers placed in guides mounted on the outer surface of the power shell.

The pressure shell of the pressure chamber can be multilayer in the radial direction, and its layers can be made of materials with different mechanical properties. In this case, the layers can be made of separate canvases connected along a generatrix, and arranged so that the connection lines of the canvases are offset in space relative to each other.

The objective of the invention is also solved by the fact that the guides with shock absorbers are attached to the outer layer of the multilayer power shell. In addition, the tank is equipped with forming elements placed inside a flexible sealed shell and made in the form of elastic rings, discretely installed along the length of the shell.

The problem is also solved by the fact that at least one end cover has audio and video monitoring and life support equipment, and additional supports are made to accommodate the lodgement in the covers. In addition, the pressure chamber is equipped with a pneumatic device to bring the pressure chamber into working condition, and the pneumatic device is made in the form of a sleeve made of elastic fabric covering the power shell and connected to the shells, in which an annular tight cavity is connected to the compressed gas supply means.

The invention is illustrated by drawings (Fig.1-5). Figure 1 shows a longitudinal section of a pressure chamber from the input side of the lodgement (fragment). Figure 2 and 3 shows a General view of the pressure chamber with visualization of the internal cavity. Figure 4 shows a cross section aa of the pressure chamber (see figure 1). Figure 5 shows the pressure chamber when folded.

According to the invention, the pressure chamber is made (Fig. 1) in the form of an axisymmetric container 1 containing an internal airtight shell 2 of elastic fabric and a power shell 3 surrounding it, at the edges of which end caps 4 and 5 are placed, one of which is made with a hermetic connector for patient input inside the container 1. At the same time, the cover 5 is the head part for accommodating the patient and consists of an elliptical bottom 6 with two transparent portholes 7 for visual observation of the patient, lighting the internal volume with daylight and electric eral light, and the cylindrical shell 8 welded with elliptical bottom cover 6. 5 connected communication pipes 9, which has quick release fittings 10 for supplying gas and electric germorazemy 11.

The cover 4 is made in the form of a detachable sealing assembly containing a cylindrical shell 12, at the end of which a flange 13 is made, and a central removable cover 14 with an elliptical flange connected through an annular rubber seal 15 to the flange 13.

A safety valve 16 is installed in the cover 4. The cover 4 is also provided with a handle 17, which is used for installing and removing the cover 4.

The power shell 3 in working condition has the shape of a cylinder and is made of high strength non-combustible fabric with loop pockets 18 at the ends of the tank. One or more embedded elements 19 are placed in pockets 18 (FIG. 1) in the form of a specially profiled ring or several segments to ensure a strong connection of the power shell 3 with the cylindrical shells 8 and 12 of the covers 4 and 5 of the pressure chamber. The outer branch of the loop pockets is placed and firmly fixed between the inner surface of the cylindrical shells 8, 12 and the outer surface of the embedded element 19 using, for example, a threaded connection. The inner branch of the loop pockets 18 is freely placed on the inner surface of the embedded element 19 and exits smoothly out of the shell at an angle α, while the exit angle α is provided by a special chamfer made on the embedded element 19, which can significantly reduce the stress concentration at the metal-fabric interface. Due to this, the axial force from the working pressure in the pressure chamber is most favorably distributed between the branches of the loop pockets, increasing the strength of the power shell.

On the outer surface of the power shell 3 is made of shock absorbers 20, placed in the rails 21.

The tank 1 is also made with forming elements 22, placed inside a flexible sealed shell 2 and made in the form of rings, discretely installed along the length of the shell.

The power shell 3 is multilayer in the radial direction, while its layers 23 can be made of materials with different mechanical properties. To increase reliability, the layers 23 are made of separate webs connected along the generatrix of the cylindrical surface of the layer and arranged so that the lines 24 connecting the webs are offset in space relative to each other by an angle β.

Flexible sealed shell 2, having a cylindrical shape in working condition, is fixed on the inner surface of the power shell 3 with elastic clips 25, its free ends are connected hermetically to the inner surface of shells 8 and 12. In working condition, the flexible sealed shell 2 is pressed against the power shell 3 by an internal excess pressure, without being subjected to tensile forces.

Figure 4 shows the implementation of the power shell 3 multilayer on the example of a three-layer shell. Each layer 23 is made with one longitudinal power connection 24 in the form of a seam.

The guides 21 are made of the same material as the power casing 3, and at a working pressure in the pressure chamber they serve as additional power annular bandages that increase the overall strength of the power casing. The inner layers 23 of the power shell 3 are made with the same longitudinal power seams as the outer layer. To form a multilayer shell, the layers are inserted so that the longitudinal seams 24 of each layer are spaced around the circle with equal angular pitch β relative to each other. Then, at the ends of the multilayer shell, loop pockets 18 are formed, made with holes for introducing fasteners into them, and final assembly of the pressure chamber as a whole is carried out.

For transportation and manual movement, the pressure chamber is equipped with transport slings 25 (Figure 3). Slings 25 are installed and fixed on the cylindrical shells 8 and 12, and, if necessary, on the power shell 3.

The pressure chamber is filled with compressed air, oxygen and other gases from compressed air cylinders 26, oxygen 27 or from cylinders not shown in the drawing with other gases through reducer 28 via flexible hoses 9. Air, oxygen or other gases first enter a closed volume (not shown ) filled with sound-absorbing filler, and then to the pressure chamber. For ease of maintenance, the pressure chamber is equipped with a portable control panel 29 in which the gas supply controls 30, a pressure gauge 31, a microclimate control device 32, a portable monitor 33 for continuous video monitoring of a patient and an intercom (not shown) are mounted. The control panel 29 is equipped with light and sound signaling devices, as well as control buttons for electrical equipment.

Inside the container 1 of the pressure chamber, a folding tool tray 34 is installed to accommodate the patient. In the lower part of the lodgement 34, an aggregate 35 for cleaning the respiratory gas mixture from carbon dioxide CO ₂ , consisting of a fan block and a cartridge with an HP-I brand absorber, is fixed. For video surveillance of the patient and audio communication with him, a miniature color video camera 36 is installed in the protective part in the upper part of the pressure chamber, as well as a microphone-speaker intercom (not shown).

Illumination of the internal volume of the pressure chamber is carried out through the viewing windows 7 by daylight or with the help of lamps 37 mounted externally on the viewing windows in protective tilting shades.

To bring the pressure chamber from the folded state (Fig. 5) to the working chamber, the latter is equipped with an elastic, sealed annular pneumatic device (Fig. 3), made in the form of a sleeve 38 made of elastic fabric, which is sealed around the shells 8, 12, and in which it is sealed an annular cavity 39 connected to means for supplying compressed gas to it.

When compressed gas is supplied to the annular cavity 39 of the sleeve 38 under excessive pressure, the pressure chamber from the "accordion" turns into a smooth elongated cylinder, and thus the folded shell is expanded into a working state, which allows the cover 4 to be freely closed after being placed in the patient’s pressure chamber.

In addition, the pneumatic device also performs the function of protecting the power shell 3 from mechanical damage, exposure to atmospheric factors, as well as from vibration during transportation of the victim in the pressure chamber.

The device operates as follows. The pressure chamber is horizontally folded. After removing the cover 4, the patient is placed head first on the bed 34 in the head of the pressure chamber and then the pneumatic device is turned on by supplying compressed air to the annular sealed cavity 39. In this case, the tool holder is supported on weight until the pressure chamber is fully expanded and then lowered to an additional support 40. Then they turn the unit 35 for cleaning the gas mixture from carbon dioxide is put into operation and the lid is closed 4. Then, compressed air is supplied to the container 1 to the working pressure and the treatment and / or transportation process is started. After completion of the necessary procedure, the opening process is carried out in the reverse order. Relieve pressure, open the lid, remove the tool tray with the patient, and the pressure chamber when folded is placed in a container.

The claimed invention allows for the provision of prompt care to patients immediately on the spot, literally in the field, as well as the transportation of a patient in need of an oxygenation system to a medical center with therapeutic recompression and other transportation actions.

The invention will be widely used as a coastal recompression and rehabilitation device for decompression sick divers, divers, and can also be used on rescue ships, training complexes and special medical stations.

Claims (16)

1. A transformable pressure chamber containing an axisymmetric container with a sealed inner shell of elastic fabric and a power shell covering the sealed inner shell, end caps are placed on the edges, one of which is made with a sealed connector for introducing a lodgement into the tank, characterized in that the power shell is made from structural fabric with the edges in the form of closed ring-shaped loops, inside of which at least one embedded element is placed with the possibility of connection end cap. 2. The pressure chamber according to claim 1, characterized in that the embedded element is shaped, formed by two cylindrical surfaces, conjugated on one side in a hemisphere, and on the other on a conical surface. 3. The pressure chamber according to claim 1, characterized in that the end caps are made with shells, on the cylindrical surfaces of which holes are made through which fasteners are introduced, which serve to connect the power shell with the embedded elements. 4. The pressure chamber according to claim 2 or 3, characterized in that threaded holes are made in the embedded elements, into which the fastening elements are screwed. 5. The pressure chamber according to claim 1, characterized in that the tank is equipped with shock absorbers placed in guides mounted on the outer surface of the power shell. 6. The pressure chamber according to claim 4, characterized in that the guides are made of a material whose strength characteristics are equal to or exceed the strength characteristics of the material of the power shell. 7. The pressure chamber according to claim 1, characterized in that the power shell is multilayer in the radial direction. 8. The pressure chamber according to claim 7, characterized in that the layers are made of materials with different mechanical properties. 9. The pressure chamber according to claim 1 or 7, characterized in that the layers are made of separate canvases connected along a generatrix and arranged so that the connection lines of the canvases are offset in space relative to each other. 10. The pressure chamber according to claim 7, characterized in that the guides with shock absorbers are attached to the outer layer. 11. The pressure chamber according to claim 1, characterized in that the container is equipped with forming elements placed inside a flexible sealed shell. 12. The pressure chamber according to claim 11, characterized in that the forming elements are made in the form of rings discretely installed along the length of the shell. 13. The pressure chamber according to claim 1, characterized in that at least one end cover contains audio-video monitoring and life support equipment. 14. The pressure chamber according to claim 1, characterized in that for supporting the lodgement in the covers, additional supports are made. 15. The pressure chamber according to claim 1, characterized in that it is equipped with a pneumatic device for bringing the pressure chamber into working condition. 16. The pressure chamber according to claim 3 or 15, characterized in that the pneumatic device is made in the form of a sleeve of flexible fabric covering the power shell and connected to the shells, in which a sealed annular cavity is connected to the means for supplying compressed gas to it.

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