RU2060726C1 - Device for stimulation of blood circulation - Google Patents

Abstract

FIELD: medicine for stimulation of blood circulation. SUBSTANCE: the device uses hollow working members secured on a flexible base and connected to the means used to feed and discharge the working agent and a drive. The drive has a double-section pressure chamber. Each section uses pressure disks, with a pusher placed between them. The pusher uses a shaft, rim and a hub, the rim is made as a flexible thread. The means used to feed and discharge the working agent are made in the form of individual and parallel manifolds. The hub is made in the form of rods of a variable length. The ends of the flexible thread are thrown over bearing rollers, positioned on the hub, and coupled to a tensioning device. EFFECT: enhanced efficiency. 11 cl, 29 dwg

Description

 The invention relates to medicine and can be used, for example, to stimulate blood circulation in patients with bed rest, various kinds of operators whose working day is characterized by relative immobility.

 The device "Medical Suit" is known according to a / c N 762885, class. A 61 N 9/00 to ensure the regulation of blood flow in the cardiovascular system in traumatic shocks and cases of acute heart failure of various ethnologies. The suit is equipped with built-in suction devices in the form of adjustable ejectors connected with air cavities between the patient’s body and the airtight legs and auxiliary longitudinal airtight chambers with fittings installed along the length of the legs. Pneumatically aspirators are installed along the legs on the outer surface. Auxiliary longitudinal sealed chambers are located inside the legs along the perimeter of their cross section.

The disadvantages of the device as. N 762885 "Medical suit" may include the following:
1. Not provided stimulation of the blood circulation of the venous channel.

 2. It does not provide stimulation of blood circulation of individual parts of the body, for example, upper limbs, torso, etc.

 3. Supply of the device with air cavities between the patient’s body and tight legs requires the installation of various types of seals on the limbs and the trunk to maintain a given pressure in these air cavities, which impairs the functional characteristics of the suit, leads to impaired circulation of the patient, complicates the design.

 A device is known by A.S. N 367864, M.C. A 61 g 7/04 "Mattress for conducting wave massage" prototype. The device itself contains a mattress with closed sections of elastic material, a source of compressed air, pipelines, a switchgear. The switchgear is made in the form of rigid cassettes with jumpers connected by means of a throttle valve to a compressed air source, forming compartments communicating with the transverse sections of the mattress, connected in series with one another, normally closed by spring-loaded valves.

 The disadvantages of the known device as. N 367864 "A mattress for conducting wave massage may include the following.

 1. Not provided, for example, management of venous outflow.

 2. A complex switchgear in the form of rigid cassettes with many serially installed spring-loaded valves significantly reduces the reliability of the device.

 3. The pressure system (compressed air supply), made in the form of a cylinder with a piston and articulated with a drive motor through a crank mechanism, is also complex, requires additional operating costs for lubricating the piston, for replacing the piston and piston rod seals. The flow of air (working fluid) through the piston rings from one part of the cylinder to the other is not ruled out, since the chambers on both sides of the piston are not isolated from each other, are not tight. The air is polluted by oil vapor and destroys the working elements.

 In addition, the known design is not hygienic enough, since it contaminates the room where the patient is exposed to oil vapor due to leakage of compressed air with oil vapor into the room, for example, through a piston rod seal.

 The aim of the invention is to increase the efficiency of stimulation of blood circulation, expanding functionality and simplifying the design.

 In FIG. 1 and 2 show a general diagram of a device; figure 3 diagram of the working element; figure 4 pusher; figure 5 pusher, option; figure 6 pusher, view aa, figure 5; Fig.7 pusher, view BB, Fig.6; on Fig stretch of a flexible filament drum; Fig.9 profile of the rim of the pusher (initial position); in FIG. 10 profile of the pusher rim, option; Fig.11 profile of the rim of the pusher, option; on Fig profile of the rim of the pusher, option; in FIG. 13 bypass valve; on Fig diaphragm adjusting; on Fig diagram of the heating of the working agent; in FIG. 16 heating element of the working agent; on Fig element heating the working agent, view BB, on Fig; in FIG. 18 heating element of the working agent, type GG, in Fig.16; on Fig device for stimulating blood circulation of body parts in areas of contact with the support; in FIG. 20 device for moving venous (or arterial) blood; in FIG. 21 device for moving venous (or arterial) blood, type DD in FIG. on Fig device for stimulating blood circulation of the pilot (astronaut), front view; in FIG. 23 device for stimulating blood circulation of the pilot (astronaut), rear view; on Fig a device for stimulating the blood circulation of a diver, front view; on Fig device for stimulating the blood circulation of a diver, rear view; on Fig device for providing regulation of blood flow of shock patients; on Fig device for ensuring the regulation of blood flow of shock patients, type EE (under vacuum); in FIG. 28 device for ensuring the regulation of blood flow of shock patients, type EE (with positive pressure); on Fig circuit control valves.

 The device contains a hollow isolated (in the supply and outlet of the working agent) cylindrical even and odd working elements 1 having a cylindrical, conical or other shape.

 The conical surface 2 (with a taper value, for example, in the range of 0.02-0.05) is made with a variable modulus of elasticity. For example, due to the uniform thickening of the wall 3. The end of the working element 4 having a larger cross section and a smaller modulus of elasticity is connected to the parallel flow pipe 5 connected to the individual manifold 6 (see figure 3).

 Giving the working element a conical shape with a variable elastic modulus ensures a smooth opening of the vessel after constriction throughout the cycle of the force F on the patient’s body, since the formed taper of the vessel is numerically equal to the taper of the working element (but is directed backward). This provides an effective and safe effect of force F on the patient's body. The walls of the vessel do not experience overvoltages, since there is no spasmodic increase in pressure, there are no vortices and return currents of blood.

 Working elements are fixed on an elastic supporting base 7.

 The sequential action of an external force F on the patient's body can be carried out, for example, by installing in the pipeline parallel supply of bypass valves 8.

In the first embodiment, the bypass valves can be equipped with interchangeable diaphragms 9 with passage openings 10 of variable diameter d ₁ ; d ₂ ; d ₃ .d _n , for d ₁ > d ₂ > d ₃ . The dimensions of the apertures in the diaphragms are determined by calculation depending on the rational speed of the sequential application of external force to the patient's body.

 In the second embodiment, the bypass valves 11 have a constant passage hole, but are provided with a drive and a shutter for closing the passage hole (from maximum to zero). The valve actuator may be, for example, electromagnetic.

 Individual collectors 6 are connected to pressure chambers of variable volume 12 and 13. The pressure chambers are hinged 14 and are connected to the frame 15, equipped with pressure plates 16 and rollers 17 moved in the guides 18. Pressure plates are equipped with rollers 19 s for smooth transmission of force and reduce friction losses endless ribbon 20.

 For the purpose of forcing the suction effect, the pressure chambers are connected by shock absorbers 21.

 A pusher 22 is placed between the pressure chambers of variable volume. The pusher contains a shaft 23 with bearings, a sleeve 24, a hub in the form of support rods 25 of variable length, the rim 26 is made in the form of a flexible thread 27 with the possibility of increasing its perimeter by changing the curvature of the working surface in a given section . To this end, the ends of the flexible thread 28 are thrown through the support rollers 29 and equipped with a screw tensioner 30 and a shock absorber 31 according to embodiment 1. According to option 2, the ends of the flexible thread are held in tension by means of a drum tension 30 a, including a free tension drum 30 b sec mounted on the shaft sides of the 30th century The outer side is provided with 30 g openings. The device shaft has levers 30 d with 30 e openings. The tension drum is fixed on the shaft with clamps 30; the shaft is braked, the drum is rotated clockwise with the calculated force until the holes on the outer side of the drum and the shaft levers are aligned (see Fig. 8).

 Changing the length of the support rods is carried out according to the first embodiment by means of a threaded connection 32. According to the second embodiment, the design of the support rods is performed, for example, in the form of a hydraulic cylinder 33, connected via a channel 34 in the shaft of the pusher with a hydraulic pump 35, while the console of the shaft of the pusher 36 is connected with a stationary the end of the pipe 37 gland device 38.

 When performing the support rod in the form of a hydraulic cylinder, it is possible to remotely change the length of the support rod and to remotely control the curvature of the working surface of the pusher rim when the device is running and at stops.

 The pusher is driven by a drive 39 provided with a reversible motor.

 The drive motor can be powered by either an AC mains or a battery. The motor speed is adjustable. The drive ensures the operation of the device is equivalent to respiratory and cardiac movements.

 The device can operate using a manual drive.

 To control the solenoid valves on the parallel supply line of the working agent, the cantilever part of the pusher shaft on the opposite side to the drive is equipped with a magnetic slider 39 mounted rotatably with a gap in the stationary ring 40, in which magnetically operated contacts are placed along the inner perimeter, each reed contact is electrically connected with appropriate solenoid valve.

 In order to apply external force to the patient’s body with a given unevenness, for example, ahead of or delayed within the cycle of force change, the reed switches are mounted on a stationary ring 40 with the possibility of their displacement along (against the course) of rotation of the magnetic slider 39.

 The profile of the pusher rim by changing the lengths of the support rods and a given modulus of elasticity of the flexible thread can be performed, for example, according to schemes 42 (initial position, circle), 43 (combination of circumference and ellipse elements, also circumference and parabola elements), 44 (parabolic shape) 45 (polyhedron) and others (see Figs. 9-12).

 The profile of the pusher rim according to the schemes 43 provides alternating application of the disturbing force F to adjacent sections of the patient’s body, and the profile of the pusher rim according to the schemes 44 provides the simultaneous application of the disturbing force F to adjacent sections of the patient’s body.

The curvature of the profile of the pusher rim, for example, in sections B _about A ₁ and A ₁ D _about determines the rate of change of growth and pressure drop in the working elements in the range, respectively, from P _min to P _max and from P _max to P _min (see figure .4).

 Pressure chambers are connected to the working elements by pipe quick-detachable elements 46 and electrical connections (plug socket, plug) 47.

 On Fig shows the control circuit of the valves during stimulation of both venous and arterial channels. When the pressure chambers are connected to the individual collector from the side indicated by arrow A (see Fig. 20), the pusher shaft is rotated clockwise by setting the pusher rim according to option 44. In this case, venous outflow from the periphery of the body to the center is performed. Signals for opening closing valves are shown in solid lines.

 When the pressure chambers are connected to the individual collector from the side indicated by arrow B (see Fig. 20), the plunger shaft is rotated counterclockwise by adjusting the plunger rim according to scheme 44. In this case, the arterial blood is moved from the center of the body to the periphery. The signals for opening the closing of the valves (see Fig. 29) are shown in dashed lines.

 The ends of the pipeline and the electric cable free from use are overlapped at the connection section with plugs, respectively, 48 and 49.

 The carrier base of the device can be made, for example, in the form of a pillow, mattress, medical suit, medical stocking, etc. on which the working elements are placed (shown in the attached drawings).

 The working elements and the supporting base are made of materials with hygienic properties.

 The carrier base may have holes for irrigating the patient’s skin with oxygen, air, etc.

According to option 1, the magnitude of the disturbing force F acting on the body is controlled by changing the pressure of the working agent (for example, air, water) in the pressure chambers by pumping it (discharge) through valve 50. According to option 2, the magnitude of the disturbing force F is controlled by increasing (decreasing) the stroke the pressure disk of the pressure chamber due to the increase (decrease) in the radius R _{2 of the} pusher (see Fig. 10, 11).

 The working agent before feeding it into the working elements can be heated (cooled) by a heating system 51 (cooling) located in the area between the pressure chamber 52 and the working elements 53 (see Fig. 15).

 The gas heating element 54 includes a housing 55, a cover 56, inlet and outlet pipes, respectively, 57 and 58, a heating element 59, a nozzle 60, a separation wall 61, insulation 62, a protective casing 63, a rheostat 64, a thermometer 65. The gas heating element works in automatic mode in the range of set temperatures.

 A device for stimulating blood circulation in parts of the body in the area of contact with the support, for example, in a sitting position, is shown in Fig. 19. A standard seat 66, for example, of a car, is equipped with a prefix with the working part of the device 67, including working elements 68 fixed to the supporting base 69. The supporting base is made, for example, in the form of a flat pillow. The working part of the device is mounted to the seat using straps 70. The case 71 with the drive part of the device (pressure chambers, drive and, for example, a heating element) is installed, for example, under the seat. Or in the trunk. Device controls can be placed on the vehicle control panel.

 The working part of the device for stimulating the blood circulation of body parts in the zone of contact with the support in the supine position is performed in the form of a flat mattress (supporting base with working elements). Fasten the working part of the device to a standard mattress using, for example, belts. Or otherwise. A case with a drive part of the device is placed next to the patient’s bed (sofa).

 To stimulate blood circulation of body parts in the zone of contact with the support, the profile of the pusher 22 is formed according to scheme 43 (see Fig. 10). Stimulation can be carried out both with the use of valves 8 (or 11), and without their use.

 The working part of the device for moving, for example, in the lower extremity of venous blood in the direction from the periphery to the center and arterial blood in the direction from the center to the periphery is performed in the form of a stocking 72 (see Fig. 20), including the supporting base 73, working elements 74, individual collector 75, parallel supply pipelines 76 with valves 77. When connecting the drive part of the device to the stocking 72 from the side indicated by arrows A, venous blood is moved from the periphery to the center. When connecting the drive part of the device to the stocking 72 from the side indicated by arrows B, the arterial blood is moved in the direction from the center to the periphery.

 The movement of venous and arterial blood is performed when forming the profile of the pusher 22 according to scheme 44 (see Fig. 1-1).

 On Fig shows the combined working part of the device for moving venous and arterial blood with the implementation of the working elements 74, for example, of a cylindrical shape. In this case, it seems more technologically advanced to perform the working part of the device separately for venous blood and for arterial blood. In this case, it is advisable to install the working element predominantly conical in shape (see figure 3).

 The device for stimulating the blood circulation of the pilot (astronaut) 78 includes a bearing base 79, working elements 80, an individual manifold 81, parallel supply pipes 82. In order to implement an additional function of the overload suit, the supporting base 79 in the abdomen is equipped with additional working elements 83, a supply pipe 84, a connecting valve 85 with a solenoid valve 86. The pressure chambers of the device are connected by means of a valve 50 to a source of compressed air 87 (see figure 2).

 When flying without overloads, the pilot (astronaut) continuously (or with the desired frequency) stimulates blood circulation in the legs and back. In this case, the working elements 83 (region of the abdomen) are disconnected from the pressure chamber system, and the profile of the pusher rim is formed according to scheme 43 (see figure 10).

 When overloads occur, the pusher rim profile is formed according to scheme 44 (see Fig. 11) due to the operation of the hydraulic pump 35 and hydraulic cylinder 33 (see Fig. 1.5). The valve 86 opens and the working elements 83 through the pipelines communicate with the cavity of the pressure chamber. The pusher 22 is rotated to the maximum compression of the working agent in the pressure chambers and fixed in this position. This ensures the same pressure of the working agent in the working elements in the area of the lower extremities, back and abdomen and prevents inertial movement of blood into the region of the lower extremities and abdomen. If necessary, the pressure in the working elements can be increased by supplying a compressed working agent to the pressure chamber from a source of compressed air 87.

 At the end of the overload mode, the working elements 83 (region of the abdomen) are disconnected from the pressure chamber system and the device is switched to the mode of blood circulation stimulation.

 A device for stimulating blood circulation of a diver 88 (see Fig. 24, 25) includes a supporting base 89, working elements 90, an individual manifold 91, parallel supply pipelines 92 with an electromagnetic valve 93. The design features of the device for stimulating blood circulation of a diver are mainly aimed at stimulating blood circulation in areas of the lower extremities, since due to the uneven hydrostatic pressure acting on the diver, less blood is supplied to his legs compared to, for example, the upper with children.

 By connecting the drive part of the device to the diver's suit (shown in Fig. 24), the arterial blood is moved in the lower extremities in the direction from the center to the periphery with the formed profile of the pusher rim 22 according to scheme 44 (see Fig. 11).

 The device for regulating the blood flow of shock patients 94 includes a supporting elastic base 95, trough-shaped working elements 96, an individual manifold 97, parallel supply pipes 98, detachable airtight fasteners 99, fastening and sealing belts 100 and 101, girth adjusters 102 (see Fig. 26 )

The value of the modulus of elasticity of the working elements E _{1 is} taken at a level of 0.8-1.0 kgf / mm ² or more, and the value of the modulus of elasticity of the carrier base E ₂ at a level of 0.1-0.2 kgf / mm ² or less.

 Due to the low value of the modulus of elasticity, the carrier base is movable relative to a more rigid working element. When air is taken from the working element, the base is drawn into the inside of the working element, forming a cavity with a negative pressure over a given part of the body. Work elements are not deformed. This occurs during systole and conditions are provided for the expansion of peripheral vessels, reduction of peripheral resistance and reduction of the mechanical work of the heart through blood pumping. When air is supplied to the working elements, the base protrudes from the cavity of the working element and is pressed tightly to the patient's body, compressing the vessels. This occurs during diastole. And in the aorta, an anti-diastolic discharge is formed, which improves coronary blood flow, since about 70% of the latter occurs during diastole. Improving coronary blood flow leads to an improvement in heart function as a whole by improving the nutrition of the heart muscle itself with oxygen and nutrients.

 To regulate the blood flow of shock patients, the profile of the rim of the pusher 22 is formed according to scheme 44 (see figure 11).

 The device operates as follows.

 Stimulation of blood circulation, such as the lower leg. Management of venous outflow. The working part of the device is performed in the volume shown in Fig.20. The drive part of the device is performed in the volume shown, for example, in FIG. 2. The working elements are performed according to the scheme shown in figure 3. Valve control is performed according to the circuit shown in Fig. 32. The working part of the device is put on the shin.

 The drive part of the device is installed next to the patient’s bed and is connected to the working part from the side of arrow A by means of elements 46, 47. From the side of arrow B, the individual collector 75 is closed by a plug 49. The profile of the rim of the pusher 22 is formed according to embodiment 44 (see figure 11).

 An equal amount of air is supplied through the valve 50 to the pressure chambers 12 and 13 with the valves 11 closed. The pressure in each chamber is brought to a level that ensures, with decreasing chamber volume (working stroke), the value of the total disturbing system F, for example, at the level of 0.3 Y (the load is determined by the doctor).

 The drive of the device 39 is turned on. The drive rotates the shaft of the pusher 22. The force from the pusher is transmitted through the rollers 19 with an endless belt 20 and the pressure disk 16 to the pressure chambers 12 and 13.

 A simultaneous decrease in the volumes of the pressure chambers 12 and 13 occurs. The air in the chambers is compressed and flows into the collectors 75. Simultaneously with the compression of the chambers, the magnetic slider 39 mounted on the pusher shaft rotates clockwise. When the magnetic runner 39 approaches the first, in the direction of travel, reed switch 41, the latter falls into the magnetic field of the runner 39. In the magnetic field, the electric permeability of the reed switch increases and the contacts close. A signal is given to open the first (from arrow A) electromagnetic valve on both pipelines 76. The first valves 77 are opened and air from the manifolds 75 is supplied through parallel supply pipelines 76 to the even and odd working elements 74, the first row of working elements is filled. When the magnetic slider 39 approaches the second reed switch 41 in the direction of travel, the second contact closes similarly to the first and a signal is given to open the second (from the side of arrow A) electromagnetic valve on both parallel supply pipelines 76. The second valves 77 open and air from the manifolds 75 fed through pipelines of parallel supply 76 to the second row of even and odd working elements. Similarly, the subsequent rows of four and odd work elements are sequentially filled with air. The sequence of filling one row of working elements relative to another row can be controlled by the speed of rotation of the pusher and the movement of the reed switches 41 along the inner perimeter of the distributor 40 relative to each other. For example, when installing on the working part 72 of the device (see Fig. 20) three rows of even and odd working elements 74, the rotation speed of the pusher 0.5 turns per minute and filling the first row of even and odd working elements 12 seconds after the start of compression pressure chambers, the second row is filled 9 seconds after the first, the third 9 seconds after the second.

When the major axis of the pusher coincides with the longitudinal axis of the pressure chambers (the angle between the axes is zero), the air pressure in the pressure chambers and working elements of each row reaches a maximum. At points A ₁ and C ₁ (see Fig. 4), the pressure chambers are compressed as much as possible, the speed of their moving elements is zero. With further movement of the pusher, the force on the pressure plates decreases and under the action of shock absorbers 21 (see figure 2), the inner ends of the pressure chambers move to the center of the pusher pressure chambers stretch, the pressure in the working elements drops. When the angle between the major axis of the pusher and the longitudinal axis of the pressure chambers reaches 90 ^about , the pressure in the system becomes minimal. The magnetic slider approached the reed switch 41 (point D _o , figure 4). Under the influence of the magnetic field of the slider, the contacts close and a signal is sent to simultaneously close all valves 77. The cycle of pressure change in the working elements is completed (increase from P _min to P _max and drop and P _max to P _min ). Rotating the pusher with the selected speed and changing the air pressure in the working elements from P _min to P _max control the venous outflow from the lower leg of the patient.

Claims (11)

 1. A device for stimulating blood circulation, containing hollow elastic working elements fixed on an elastic basis and connected to means for supplying and withdrawing a working agent, and a drive including a pressure chamber, characterized in that, in order to increase the efficiency of stimulation and expand the functionality, pressure the camera is made of two sections with pressure plates, between which there is a pusher containing a shaft, hub and rim, made in the form of a flexible thread with the possibility of increasing its perimeter, and medium The feed and outlet of the working agent are made in the form of individual and parallel collectors.  2. The device according to claim 1, characterized in that the hub is made in the form of rods of variable length, and the ends of the flexible thread are placed on the support rollers located on the hub, and are connected to the tensioner through a shock absorber.  3. The device according to claims 1 and 2, characterized in that, for the purpose of forcing the suction effect, the sections of the pressure chamber are interconnected with the possibility of depreciation.  4. The device according to claims 1 to 3, characterized in that, in order to remotely control the change in the curvature of the pusher rim, at least two rods holding the rim are made in the form of hydraulic cylinders connected through a cavity in the shaft of the pusher with a hydraulic pump, while the shaft console the pusher from the side opposite to the drive is connected to the stationary end of the pipe of the hydraulic pump drive through the stuffing box.  5. The device according to claims 1 to 4, characterized in that the working element is made in the form of a closed conical cavity with a variable elastic modulus in the direction from a larger cross section to a smaller one, while the end of the working element having a larger cross section is connected to an individual collector.  6. The device according to PP.1 to 5, characterized in that, with the aim of sequential exposure of the working agent to the patient’s body, the parallel supply pipe is equipped with bypass valves with interchangeable diaphragms made with through holes of variable diameter.  7. The device according to claims 1 to 5, characterized in that, for the sequential action of the working agent on the patient’s body, the parallel supply pipe is equipped with solenoid valves, and the cantilever part of the pusher shaft from the side opposite to the drive is equipped with a magnetic slider mounted on the shaft with the possibility of rotation with a gap in a stationary ring, in which reed switches are placed along the inner perimeter, each of which is electrically connected to a corresponding electromagnetic valve.  8. The device according to paragraphs. 1 7, characterized in that, in order to apply external force to the patient’s body with a given unevenness, the reed switches are mounted on a stationary ring with the possibility of their movement.  9. The device according to paragraphs. 1 to 8, characterized in that, in order to ensure a linear movement of the pressure disks of the pressure chambers, the latter are equipped with rollers moving in the guide rails mounted on the end of the pressure disks.  10. The device according to paragraphs. 1 to 9, characterized in that, in order to smoothly transmit effort and reduce friction losses, the pressure discs are equipped with rollers with an endless belt installed in contact with the pusher.  11. The device according to paragraphs. 1 to 10, characterized in that, in order to expand the vessels and reduce blood viscosity, the pressure chamber is connected to the working elements by means of a heating agent working unit made in the form of a thermally insulated body with a cover, the bottom of which is equipped with a heating element, over which a nozzle with a dividing wall is placed and in the area between the upper end of the nozzle and the cover, the housing is equipped with inlet and outlet pipes.

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