RU2647329C1 - Method of underwater massage, device for its implementation and cavitator for underwater massage - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions includes a method of underwater massage, device for underwater massage and cavitator for underwater massage, belongs to the field of medicine and is designed for underwater hydrocavitation massage in medical, health and sports institutions and for an individual massage at home in a Jacuzzi bath. Method of underwater massage is based on a combined hydrodynamic and cavitation massage effect by a flooded pulsating jet stream on the patient's body parts immersed in a bath with a liquid medium. Massage is performed by simultaneous action on selected patient body parts by a set of spatially distributed cavitation jets with formation in each local area of action of the central circular zone of reduced pressure, middle annular zone with a hydrocavitating cavity, radially spreading along the selected area of local impact, and a peripheral annular zone of force hydrodynamic action. Impact on the allocated local areas is provided by means of cavitators installed in the respective places of the bath with the orientation of the cavitation jets on the hands, legs, neck and trunk of the patient. Device for underwater massage contains a water pump, a bath filled with water, valves installed in the water supply line, cavitators and a control panel, aerocompressor and an additional valve installed in the compressed air supply line. Cavitators are made in accordance with p. 4 and mounted on the walls of the bath with orientation of the cavitation jets on the arms, legs, neck and trunk of the patient. Water pump is connected through the water return loop to the hydraulic inputs of the cavitators. Aerocompressor is connected through the compressed air supply line to the air passages of the cavitators equipped with protective caps installed on the outputs of the cavitators, and the outputs of the control panel are connected to the control outputs of the water pump, the air compressor and the control inputs of the valves.

EFFECT: inventions make it possible to increase the efficiency of the procedure by carrying out a massage simultaneously on several parts of the patient's body with a combination of different types of massage effects provided by the use of cavitators.

5 cl, 11 dwg

Description

The invention relates to medicine, namely to therapeutic massage, and can be used for underwater hydrocavitation massage in medical, health, sports facilities and for individual massage at home in the Jacuzzi bathtubs.

A known method of underwater massage (RF patent No. 2252739, IPC A61H 9/00, published. 05.27.2015), providing for the placement of at least one part of the human body in a bath with a liquid medium and exposure to the body by forming hydrodynamic vibrations in the volume of a liquid medium .

There is also known a method of underwater vacuum-vortex massage (RF patent No. 2543272, IPC АH 9/00, published. 02.27.2015), which provides for the placement of the human body or at least one of its parts under the surface of the water in the bath and exposure to them through a special a massage device, by successively absorbing and releasing the skin that the massage device implements when moving across the body of the adjacent massage device, while a flow of water is supplied to the massage device, which swirls INDICATES in its vortex chamber and creates in the central part of the vacuum, and except a constant smooth movement of the human body specific vacuum vortex impact massage apparatus complement manualnomu movements that result in a change in the hydrodynamic liquid flow regimes on the border with the massaged body portions.

A device for implementing the known method (RF patent No. 2543272) contains a housing, inside which there is a cavity, in which the inner walls form a body of revolution, including communicating upper and lower parts of the cavity, the upper part forming a vortex chamber and connected to the pressure water hose through tangential channel in the housing, ensuring that the jet flowing from it enters the vortex chamber tangentially to its generatrix, and the lower part of the cavity is made with gradual expansion in the direction from the vortex of the chamber to its open exit, at this exit the body is equipped with a neck-lip, with the possibility of a painless fit of this lip-neck to the massed surface of the human body, while the neck-neck and at least the adjacent part of the body containing the lower part the inner cavity, made of flexible hygienic material, with the possibility of changing during the massage the geometry of the lips, neck and lower part of the inner cavity by the efforts of the masseur's hands.

The disadvantage of these methods and devices is the lack of effectiveness of the massage effect on the human body, due to the limited set of different types and parameters of the physical effect of the liquid jet on the biological tissues of the body, which is associated with the capabilities of the known technical means that do not provide deep effects on the patient’s body parts.

A significant disadvantage of bathtubs used for underwater massage (such as a “Jacuzzi”) is that microorganisms feel great in a closed hydraulic system. For example, in one teaspoon of tap water contains about 138 bacteria, and in the same amount of water taken from the Jacuzzi bathtub - more than 2 million. There is only one way to deal with this unpleasant phenomenon - regular disinfection of the system. According to American microbiologists (http://remont-akrilovyh-vann.ru/stati/nedostatki-vann-dzhakuzi.html), bacteria-infected water that adversely affects humans is released from the massage jacuzzi bathtubs. Such microorganisms can lead to infection of the genitourinary tract, skin and lungs. According to the results of research and microbiological analysis, intestinal bacteria were found in 95% of the jacuzzi, pathogenic fungi were found in 81% of the jacuzzi, and staphylococci were found in 34% of the jacuzzi, which pose a potential threat to human life. Therefore, it is not recommended to take a jacuzzi bath without preliminary sanitation of equipment, which complicates the operating conditions of bathtubs for underwater massage.

The closest in technical essence to the proposed technical solution is a well-known method of underwater massage (RF patent No. 2499588, IPC АH 9/00, published. 11/27/2013), based on the hydrodynamic effect of a liquid stream on parts of the patient’s body immersed in a bath with a liquid medium at the same time, a combined hydrodynamic force cavitational pulsating and magnetic action is carried out on the patient’s body by a flooded jet magnetized flow of a liquid medium, ensuring the generation of cavitational air-vapor bubbles with a pressure drop in the flooded jet stream ΔР≥0.15 MPa and providing a velocity of the liquid stream u≥17.1 m / s, as well as with the formation of a magnetic field with magnetic induction В≥3200 Gauss in the surface areas of the patient’s body parts .

A device that implements this method of underwater massage contains a circulating water unit made to provide pressure control in a flexible hose, at the end of which there is a massage nozzle, while the end of the flexible hose with a massage nozzle is immersed in the bath in which the patient is located, the massage nozzle is made in the form of a cavitation pathogen with a Laval nozzle, and ring magnets are placed in the housing of the cavitation pathogen.

The use of cavitating jets of liquid for massage improves the results of massage, however, in the known method and device, incomplete capabilities of technical means are used for the optimal effect of cavitating jets, which does not allow to achieve maximum efficiency. When sequentially conducting massage in different parts of the body, using one nozzle in a known technical solution leads to an increase in the total time of massage procedures.

Moreover, the use of a magnetic field in the known method for some patients is not always acceptable for medical reasons, for example, if the patient has a pacemaker.

The technical result, which consists in increasing the efficiency of providing an underwater massage procedure simultaneously on several parts of the patient’s body with a combination of various types of massage effects, such as retraction, rubbing, vibration and deep kneading, is achieved in the proposed method of underwater massage based on combined hydrodynamic and cavitation massage effect of a flooded pulsating jet stream on parts of the body of a patient immersed in a bath with a liquid medium, the fact that massage is carried out by simultaneously acting on selected areas of the patient’s body with a combination of spatially distributed cavitation jets with the formation in each local area of influence of the central circular zone of reduced pressure, the middle annular zone with a hydrocavitation cavity radially spreading over the selected area of local impact, and the peripheral ring zone hydrodynamic force impact, while the impact on the selected local areas provide using cavitators installed in the appropriate places of the bath with the orientation of cavitation jets on the hands, feet, neck and torso of the patient.

The technical result, which consists in increasing efficiency and ensuring the sanitation of the environment and objects in the bath, is achieved by the fact that simultaneously with the combined massage effect on the patient’s body, preventive disinfection of microflora in the working volume and on the surface of the bath is ensured due to intense hydrodynamic pulsation of the jet stream and increased temperatures in the zones of formation of hydrocavitation caverns.

The indicated technical result is achieved in an underwater massage device comprising a water pump, a bathtub filled with water, valves installed in the water supply line, cavitators and a control panel, in that it contains an air compressor and an additional valve installed in the compressed air supply line, this cavitators mounted on the walls of the bath with the orientation of the cavitation jets on the hands, feet installed in the water supply line, cavitators and control panel, so that it contains aero an compressor and an additional valve installed in the compressed air supply line, while the cavitators are made as described below and mounted on the walls of the bathtub to ensure that the cavitation jets are oriented to the patient's arms, legs, neck and body, and the water pump is connected through a water supply line looped through the bathtub to the hydraulic inputs of the cavitators, and the air compressor is connected through the compressed air supply line to the air pipes of the cavitators equipped with protective nozzles mounted on the outputs of the cavitators, and the outputs of the control panel are connected to the control inputs of the water pump, air compressor and control inputs of the valves.

Underwater massage requires a special cavitator design.

Known hydrocavitation generator Rodionova VP "(RF patent No. 1614241, IPC B01F 5/00, B08B 3/12, 05/25/1993), having an inner surface in the form of a confuser communicated with a diffuser, a reflective element, while the confuser is communicated with a diffuser by means of a two-stage cylindrical section, the diameter of the first stage of which is equal to the smaller diameter of the confuser and less than or equal to 0.5 of the diameter of the second stage, the ratio of the smaller diameters of the diffuser and confuser is 1.25-2.0, and the ratio of the distance from the diffuser outlet to reflect an element to a smaller diameter of the confuser is not less than 4.

The disadvantage of this device is the insufficient intensity of cavitation in the jet flooded stream.

Closest to the proposed cavitator is the famous cavitator Rodionova V.P. (patent No. 2568467, IPC B08B 3/12, published. November 20, 2015), comprising a housing with an internal through cavity, including an inlet with a cylindrical section and a confuser with an angle of convergence α, an expansion chamber, side openings, and an outlet made in the form a diffuser with an angle of divergence β, while the internal through cavity contains transition sections made with a ribbed internal relative to the remaining step sections and connected with n side openings, the outlet of the expansion chamber being connected through another transition second portion to an input of the diffuser made with the stepped shape of the inner side surface, wherein converger configured convergence angle α = 5-60 °, and a diffuser formed with an angle of divergence β = 10-60 °.

A disadvantage of the known cavitator is that it requires an increased pressure drop ΔP ₀ ≥1.0 MPa and a fluid flow rate ϑ≥170.1 m / s to excite cavitation, i.e. the pump unit must supply liquid to the nozzles of the bath with a pressure not lower than that indicated for the initiation and effective development of cavitation, which requires the use of a powerful pump and leads to high energy consumption.

The technical result, which consists in reducing energy consumption, is achieved in a cavitator for underwater massage, comprising a body with an internal through cavity formed by a consecutive inlet confuser with a convergence angle β _to , a transition chamber communicating with side openings for air ejection, and an output diffuser made with a step inner surface with divergence angle β _d = (10-90) °, in that it comprises a bush, pressed into the transition chamber formed in said sleeve to the central nical hole with convergence angle α = _C 10 ÷ 90 ° and outlet diameter D ₀ = (0.5-10) mm converger is formed with a stepped internal surface with an angle of convergence β _K = 10 ÷ 90 °, and steps on the side surfaces converger and diffuser are made with conditions:

h _k = 1-2 mm; h _d ≥1,1 ÷ -2h _K ,

d _i <d ₂ <d _i <d _n , (i = 1-n) and

D ₁ <D ₂ <D _J <D _m , (j = 1-m), n≥3, m≥3,

where h _k is the height of the steps on the inner surface of the confuser;

h _D - the height of the steps on the inner surface of the diffuser;

d _i - the diameter of the i-th circular steps on the inner surface of the confuser,

D _J - the diameter of the j-th circular steps on the inner surface of the diffuser,

n and m are the number of steps, respectively, on the surfaces of the confuser and diffuser,

wherein D _{i + 1} - D _i = d _{i + 1} - d _i = (1.8-2.2) mm, and the output diffuser is made with a divergence angle β _d = (10-90) °.

The invention is illustrated by drawings:

in FIG. 1 shows a functional diagram of a device for implementing the proposed method;

FIG. 2 illustrates the effect on the patient of cavitation jets on various parts of the patient's body during underwater massage;

in FIG. 3 shows a design drawing of a cavitator for bathtubs, with the help of which the proposed method and device are implemented;

in FIG. 4 is a drawing of a known nozzle design widely used in a Jacuzzi bath for hydrodynamic underwater massage without forming a cavitating jet;

FIG. 5 illustrates the effect of a jet stream (without cavitation) flowing out of a nozzle (FIG. 4) on the skin of a patient;

in FIG. 6 shows a design drawing of a nozzle with a cavitator (Fig. 3) used in the proposed method and device;

FIG. 7 a), b) illustrates the effect of a jet stream flowing from a nozzle with a cavitator (Fig. 5) used in the proposed method and device on the skin of a patient;

in FIG. 8 a), b) photographs of the hydrocavitation jet stream flowing from the cavitator into the free volume of the liquid in the form of a cavity at various pressures P ₀ in the liquid stream are shown;

in FIG. 9 a), b), c) photographs of the hydrocavitation jet stream flowing from the cavitator to the surface and the formation of cavitation zones on it at various pressures in the fluid flow are shown; P ₀ ;

струйного гидрокавитационного потока, действующего на поверхность тела пациента, и относительной суммы площадей

, образуемых кавитационным потоком, от относительного расстояния

от среза кавитатора до массируемой поверхности тела пациента;in FIG. 10 is a graph of dependencies of changes in the relative magnitude of the total energies

jet hydro-cavitation flow acting on the surface of the patient’s body, and the relative total area

formed by cavitation flow from a relative distance

from a cut of a cavitator to a massaged surface of a patient's body;

in FIG. 11 shows the location of cavitators grouped on one of the sections of the surface of the bath.

A device for implementing the method of underwater massage (Fig. 1, 2) comprises a bath 1 filled with water, a water pump 2, valves 3, 4; installed in the water supply line 5, an air compressor 6 and a valve 7, installed in the compressed air supply line 8, cavitators 9, control panel 10 and pressure gauges 11 and 12.

Cavitators 9 are mounted on the walls of the bath 1 with the orientation of the cavitation jets 13, 14 (Fig. 2) to local areas 15 of the patient’s body 16.

The water pump 2 is connected through a water supply line 5 looped with a bath to the hydraulic inlets 17 of the cavitators 9 (Fig. 6), and the air compressor 6 is connected through a line 8 of compressed air supply to the air pipes 18 of the cavitators 9, equipped with protective nozzles 19 (Fig. 4) installed at the outputs of the cavitators 9, and the outputs of the control panel 10 are connected to the control inputs of the water pump 2, the air compressor 6 and the control inputs of the valves 4 and 7.

The cavitator 9 (Fig. 3) contains a housing 20 with an internal through cavity formed by a consecutive inlet confuser 21 with an angle of convergence β _to , a transition chamber 22 communicating with side openings 23 for air ejection, and an output diffuser 24 made with a stepped inner surface with a divergence angle β _d = (10-90) °, the sleeve 25, pressed into the transition chamber 22.

In the sleeve 25 a central conical hole is made with a convergence angle α _C = 10 ÷ 90 ° and an output diameter D ₀ = (0.5-10) mm.

The confuser 20 is made with a stepped inner surface with a convergence angle β _K = 10 ÷ 90 °, and the steps on the side surfaces of the confuser and diffuser are made with the conditions:

h _k = 1-2 mm; h _D ≥1,1 ÷ 2h _K ,

d ₁ <d ₂ <d _i <d _n , (i = 1-n) and D ₁ <D ₂ <D _J <D _m , (j = 1-m), n≥3, m≥3,

where h _k is the height of the steps on the inner surface of the confuser;

h _D - the height of the steps on the inner surface of the diffuser;

d _i - the diameter of the i-th circular steps on the inner surface of the confuser,

D _J - the diameter of the j-th circular steps on the inner surface of the diffuser,

n and m are the number of steps, respectively, on the surfaces of the confuser and diffuser, while D _{i + 1} - D _i = d _{i + 1} - d _i = (1.8-2.2) mm.

The output diffuser 24 is made with a divergence angle β _d = (10-90) °.

In FIG. 4 shows for comparison the design of the known nozzle 26 used in the bath "whirlpool" for hydrodynamic underwater massage, containing a nozzle 27 of a conical shape.

In FIG. 6 shows the design of the nozzle 28 with the cavitator 9 located therein.

The nozzles are equipped with a protective nozzle 29, which protects against direct contact of the nozzle 27 and the cavitator 9 with the patient’s body. When using the nozzle shown in FIG. 4, the water flowing under pressure to the inlet 17 of the nozzle 26 flows out of it in the form of a flooded jet 30 (Fig. 5) having certain geometric dimensions of the “living cross-section of the stream”. Depending on the diameter of the inner section of the nozzle 27, a funnel 31 is formed on the skin of the patient 16 with dimensions close to the dimensions of the "live section" of the jet stream, and then it splits into many streams 32, which, spreading over the surface of the formed funnel 31, simultaneously produce a dynamic effect 33 to the subcutaneous and muscle layers of the patient’s body 16, producing one of the well-known massage techniques, namely kneading.

When using the nozzle 28 with a cavitator (Fig. 6, 7), water enters the input 17 of the cavitator 9 and, passing through its internal cavity, flows out of it, forming a hydrocavitation cavity 34 expanding from the cutter of the cavitator (Fig. 7), " living section ”of which has the form of a torus 35 with a central annular zone 36 (Fig. 7a), in which there are no gas-vapor bubbles, and hydrostatic pressure has a negative value. In this case, the middle cavitation part 37 is also limited by the outer annular zone 36, in which the static pressure is higher than atmospheric pressure.

In FIG. 8 a), b) shows the change in the geometric dimensions of the cavitation cavity flowing out of the cavitator with a central diameter of D ₀ = 1 mm depending on the pressure P ₀ leading to the cavitator, namely, the pressure P ₀ = 0.5 MPa in the first image and the second image P ₀ = 0.3 MPa.

In FIG. 9 a), b), c) shows the change in the size of the zone of accumulation of gas-vapor bubbles on the surface depending on the pressure P ₀ leading to the cavitator with a central diameter D ₀ = 1 mm, namely, in the first picture, the pressure P ₀ = 0.2 MPa, in the second picture P ₀ = 0.3 MPa, in the third picture P ₀ = 0.4 MPa.

The proposed method is as follows.

The method is based on a combined hydrodynamic and cavitation massage effect by a flooded pulsating jet stream on parts of the patient’s body immersed in a bath with a liquid medium.

Massage is carried out by simultaneously acting on selected areas of the patient’s body with a combination of spatially distributed cavitation jets (Fig. 1) with the formation of a central circular zone 36 of reduced pressure in each local area of influence, a middle annular zone 37 with a hydrocavitation cavity radially spreading over the selected area of local impact, and the peripheral annular zone 38 power hydrodynamic effects (Fig. 7).

The impact on the selected local areas is provided by means of cavitators 9 installed in the appropriate places of the bath with the orientation of the cavitation jets on the hands, feet, neck and torso of the patient (Fig. 1, 2).

Water under pressure ΔР ₀ ≥0.15 MPa and a jet stream of fluid ϑ≥17.1 m / s, enters the inputs of 17 cavitators 9 and flows out of them, forming a cavitation cavity at the cavitators output (Figs. 7, 8, 9). Hydrocavitation cavity spreading over the surface of the skin of the patient’s body 16 carries out hydrocavitation massage, forming three zones of its influence: central 36, median cavitation 37 and peripheral 38.

с размерами S_ц≥1÷3 см², зависящая от диаметра наименьшего сечения кавитатора d₀, угла раскрытия диффузора β_Д, давления на выходе кавитатора Р₀, и относительного расстояния

от среза кавитатора до поверхности тела пациента, на которую действует пониженное давление Р_вак≅-(0,05÷0,07) МПа, которое обеспечивает вакуумный массаж путем попеременного вытягивания кожного покрова участка 39 тела пациента.In the central zone 36 of the jet action, a circular region is formed with an area of

with dimensions S _n ≥1 ÷ 3 cm ^2, depending on the diameter of the smallest section cavitator d ₀ the angle of opening β of the diffuser _D, pressure P at the outlet cavitator _0, and the relative distance

cavitator cut from the patient's body to the surface on which it acts a reduced pressure P _vac ≅- (0,05 ÷ 0,07) MPa which provides vacuum massage by alternately pulling the skin portion 39 of the body.

, зависящей от параметров струйного истечения, с размерами S_КАВ≥27÷15 см² для кавитаторов с проходным сечением D₀=1÷10 мм и давлении на срезе кавитатора ΔР₀=0,15÷0,5 МПа.In the middle cavitation zone 37, a jet stream with a mass of gas-vapor bubbles in the form of a torus with a certain area acts on the skin

depending on the parameters of the jet flow, with sizes S _KAV ≥27 ÷ 15 cm ² for cavitators with a bore D ₀ = 1 ÷ 10 mm and a pressure at the cutter section ΔР ₀ = 0.15 ÷ 0.5 MPa.

In this case, a mass of collapsing gas-vapor bubbles is massaged by hydrodynamic pressure pulsating in a wide range of cumulative flows of microjets from collapsing gas-vapor bubbles, which create a temperature drop in the microzones and a pressure drop that provides massage by vibration.

зависящей от кавитационной площади S_КАВ.In the peripheral zone 38 there is a force dynamic pressure reflected from the patient’s surface of the jet stream with a certain area of impact on the patient’s body

depending on the cavitation area S _KAV .

As a result of the influence of spreading jet streams on the surface of the peripheral zone 38, peculiar seals of the shifted skin and subcutaneous surface of the patient’s body are formed, on which hydrodynamic force is applied, providing massage by deep kneading.

до тела пациента выбирается в пределах

, для максимального давления на срезе кавитатора.In this case, the relative distance from the cutoff of the cavitator

to the patient’s body is selected within

, for maximum pressure on the cut of the cavitator.

, где

, растекающегося по поверхности тела пациента и относительного суммарного значения энергий

, где

от относительного расстояния

от среза кавитатора до тела пациента.In FIG. 10 shows graphs of the dependencies of the relative total value of the areas of the cavitation jet stream zones

where

spreading over the surface of the patient’s body and the relative total energy

where

from relative distance

from the cut of the cavitator to the patient’s body.

, наибольшую величину имеет динамическая силовая составляющая энергии струйного гидрокавитационного потока и осуществляется первая степень силового воздействия струйного гидрокавитационного потока в виде жесткого классического массажа.Tests have shown that at

, the largest value is the dynamic power component of the energy of the jet hydro-cavitation flow, and the first degree of force action of the jet hydro-cavitation stream is carried out in the form of a hard classical massage.

. В этом диапазоне значений относительного расстояния

от среза кавитатора до поверхности тела пациента осуществляется массаж силовым воздействием струйного гидрокавитационного потока с наибольшей площадью охвата массируемой поверхности и максимальным суммарным эффективным воздействием струйного кавитационного потока. При значении

осуществляется «щадящее» (умеренное) силовое воздействие струйного кавитационного потока.In FIG. 10 shows the hatched portion of the graph for which

. In this range of relative distance values

From the cut of the cavitator to the surface of the patient’s body, massage is performed by the force of the jet hydro-cavitation stream with the largest coverage area of the massed surface and the maximum total effective effect of the jet cavitation stream. At value

“gentle” (moderate) force effect of the jet cavitation flow is carried out.

In the known massage method illustrated in FIG. 5, only one hydrodynamic component of the jet fluid stream is used, providing only kneading, which reduces the effectiveness of underwater massage.

The advantage of the proposed method is that when conducting underwater massage, the total energy of the cavitating jet of liquid is used to the maximum, which provides an intensive effect on the skin of the patient by using several massage techniques, such as retracting, rubbing, vibration and deep kneading, which can be effectively used for treatment of cellulitis, diseases of the musculoskeletal system, psoriasis and other diseases requiring a wider range of uses of the main method in massage.

Simultaneously with the combined massage effect on the patient’s body, prophylactic disinfection of microflora is ensured in the working volume and on the surface of the bath due to the intense hydrodynamic pulsation of the jet stream and the elevated temperature in the zones of formation of hydro-cavitation cavities.

Research conducted by the author (Rodionov V.P. et al. Supercavitational jet sterilization of liquids // Transactions of KubGTU: Scientific journal. - Krasnodar: Publishing KubGTU, 2005. TXX1. Ser. Life safety and environmental protection. - Issue 2 - C 266-268), it was shown that when a water stream passes through the cavitator and the cavity’s hydro-cavitation zone and, falling into the region of increased static pressure, the bubbles collapse in a very short time interval of the order of 10 ^-5 -10 ^-6 s. In this case, cumulative microjets are formed, having sizes of 10-100 μm and a velocity of 300-1000 m / s, and the pressure in microvolumes during collapse of gas-vapor bubbles can reach about 100-1000 MPa. In addition, electric charges arise, causing the phenomenon of electrolysis of water, the appearance of ozone and ionizing radiation. Cavitation is also accompanied by the formation of shock waves and high thermal effects of the order of 1000 or more degrees in microvolumes. At this moment, the chemical reactions of reduction and oxidation, decomposition and synthesis, polymerization, intramolecular rearrangement are activated. Therefore, conditions are created that destroy the structure of protein molecules, nucleic acid molecules and fat molecules, i.e. under these conditions, water is sterilized as a result of the disintegration of the vital molecules that make up the microbial bodies (the same source of information).

A device for implementing the proposed method (Fig. 1) and cavitators for underwater massage works as follows.

In the water supply line 5, the valve 3 opens and the bath 1 is filled with water from the water supply network 40 to the required level, after which the valve 3 closes.

Further process control is carried out using the remote control 10 control nursing personnel or directly to the patient 16 after conducting the necessary instruction and training.

The electrically controlled valve 4 opens and the water pump 2 is turned on, installed in the looped water supply line 5, ensuring the flow of water under pressure to the hydraulic inputs 17 of the cavitators 9 and the circulation of water in the bath 1.

Then, the electrically controlled valve 7 opens and the air compressor 6 is turned on, installed on the compressed air supply line 8, providing compressed air supply to the air nozzles 18 of the cavitators 9.

At the inputs of the cavitators 9, water under pressure enters the confuser 21 and, when passing along the inner step surface of the confuser, is turbulized due to the sharp edges of the steps of the confuser, increasing the kinetic component of energy and reducing the potential energy storage (pressure). The potential energy of pressure in the corresponding sections of the flow becomes lower than the pressure of saturated vapors and gas-vapor bubbles begin to be intensively released from the liquid.

Upon reaching the flow of the central part of the cavitator (its speed reaches a maximum, which corresponds to the maximum value of the kinetic part of the energy and the minimum value of the potential energy, which contributes to a sharp increase in the release of gas-vapor bubbles from the liquid. When the flow passes through the sleeve 25 into the transition chamber 22 (Fig. 3) the flow velocity decreases sharply, the potential component of the flow energy increases, and the kinetic component of the energy decreases accordingly. I in a stream of vapor-gas bubbles does not withstand the static pressure of their environment and begins to collapse, creating a sound effect.Liquid flow passing through the transition chamber 22, and then the diffuser 24 expands and turbulates, and intensive nucleation begins in contact with the walls of the diffuser due to the sharp edges of the steps even more gas-vapor bubbles in addition to the already formed bubbles generated in the confuser 21. The amount of dissolved air extracted from the liquid with the formation gas-vapor bubbles becomes close to maximum. The mass of liquid with the maximum number of gas-vapor bubbles present escapes from the diffuser 24 (Figs. 7, 8, 9) forming a hydro-cavitation cavity 34 with certain geometric dimensions in the form of an expanding drop in which a huge number of gas-vapor bubbles accumulate along the edges of the cavity with a certain wall thickness.

The hydrocavitation cavity 34 in cross section has the appearance of a torus with a central and transitional part (Fig. 7). In the central part of the cavity, the static potential pressure is set below atmospheric pressure and, when the jet stream spreads over the surface of the patient’s skin, creates a zone of a certain area with vacuum (vacuum).

Low pressure, acting on the skin of the patient, provides a vacuum massage with the ensuing effect known in medical medicine.

The mass of gas-vapor bubbles located in the transitional part of the spreading cavity occupies a zone of a certain area in which gas-vapor bubbles collapse, creating a multitude of cumulative jets directed in different directions, affecting the patient's body and on the oncoming fluid flows, generating pulsations of the hydrodynamic pressure of the entire jet, and micropulsations in microjets, with a wide range of amplitude-frequency fluctuations in pressure on the patient’s body.

Thus, in the zone 37 (Fig. 7) a deep vibratory pulsation massage with its healing properties known in medical practice is carried out.

The fluid flow spreading over the patient’s surface from zone 37 is directed at a certain angle to different directions from the center of the flow and forms an external peripheral annular zone 38, in which the static pressure is higher than atmospheric pressure.

Thus, in zone 38, a constant hydrodynamic force effect of the reactive force of the jet stream reflected from the patient’s surface is provided, providing a kneading technique known in the practice of massage.

When air is supplied to the air nozzles 18 of the cavitators 9 from the air compressor 6, air enters through the side openings 23 into the transition chamber 22 of the cavitators 9. In the chamber 22, the air is mixed with the hydro-cavitation jet stream and, without penetrating into the depth of the hydro-cavitation cavity moving at high speed, is transported by the jet flow, forming its air zone of certain sizes near the hydro-cavitation cavity.

The air flow, falling on the surface of the patient’s body, forms a ring-shaped zone of certain sizes with an accumulation of air bubbles and, pushing off from the patient’s body surface and rushing upward filled with liquid bath, in addition to hydro-cavitation massage, produces a massage effect similar to stroking and vibration.

Massage techniques in the form of stroking, rubbing, kneading, vibration, based on moderate or strong pressure, are perceived by the body as an irritant of tactile sensitivity.

Tactile sensations arise because massage causes deformation of the skin surface and excites mechanoreceptors of the skin analyzer. The excitement arising in them is transmitted along the peripheral nerves and causes a sensation of touch, pressure or vibration. Different areas of the skin have different tactile sensitivities.

The smallest skin sensitivity to pressure is observed along the midline in the back and, if taken as a unit, then in other areas of the skin, pressure sensitivity will correspond to: 1.06 - on the stomach in the midline; 1.39 - on the chest in the midline; 3.01 - on the front surface of the shoulder; 3.38 - on the back of the foot; 3.80 - in the area of the wrist joint; 7.54 - on the forehead [Kunichev L.A. Massotherapy. Publishing Association "Vishka School", 1982].

When using the proposed device, it is recommended that the magnitude of the force impact of the jet hydro-cavitation flow be regulated by the patient himself, who is in the bathroom using the control panel 10, taking into account the individual sensitive sensations of the massage of various parts of the body. Pressure monitoring in the water supply line 5 and the compressed air supply line 8 is carried out using manometers 11 and 12.

By changing the pressure ΔР ₀ = 0.15 ÷ 0.5 MPa in the jet stream, any degree of force exposure can be carried out by the patient himself, taking into account the sensitivity of the skin to pressure by changing the geometric dimensions of the hydrocavitation cavity and moving the zones of force exposure along its length with a change their energy values.

The design of cavitators 9 determines such physical factors as intensity, type of jet, enrichment of the water flow with air bubbles, which determines the type of massage effect on the human body.

The hot tub is equipped with a set of cavitators 9, grouped in various places to influence a particular area of the human body, taking into account the location of reflex points.

A distinctive design feature of the proposed cavitator for underwater massage is that cavitation in the jet stream of liquid is generated at a reduced pressure drop ΔP ₀ ≥0.15 MPa and a flow velocity ϑ≥17.1 m / s, which allows the use of widely available and economical pumps.

The constructive solution was chosen empirically, taking into account the laws of conservation and change in the energies and physical properties of liquids, known from the foundations of hydraulics, the known dependencies and patterns during jet outflow from nozzles of various designs [P. Osipov Hydraulics, hydraulic machines and hydraulic drive, Textbook for universities, 3rd edition, Forestry, 1981 - p. 424], pump parameters and experimental studies to determine the cavitational ability of jet streams flowing from various designs of cavitators.

To use the proposed method, it is recommended that cavitators be placed in the bath most rationally, as shown in FIG. 11, taking into account the distances between their centers so that the impact zones of the jet streams flowing from adjacent cavitators do not intersect and are located at certain distances L and L ₁ .

Underwater massage can be carried out under the supervision of nurses in medical and recreational organizations or independently according to the regimes prescribed by the attending physician.

For the technical implementation and industrial use of the proposed method, a device for its implementation and a cavitator, complex and expensive components and materials are not required, and technical means available for industrial use are used.

It uses a converted bath, standard water pumps, pipelines, manometers, solenoid-operated electrically operated valves, and stainless steel cavitators. The control panel layout is implemented on available electronic components.

The method of underwater massage, the device for its implementation and the cavitator passed pilot tests confirming the effectiveness of the technical solution, which can be repeatedly reproduced.

Claims (13)

1. The method of underwater massage, based on the combined hydrodynamic and cavitation massage effect of a flooded pulsating jet stream on parts of the patient’s body immersed in a bath with a liquid medium, characterized in that the massage is performed by simultaneously acting on selected areas of the patient’s body with a combination of spatially distributed cavitation jets with the formation in each local area of influence of the central circular zone of low pressure, the middle annular zone with hydro a gravitational cavity radially spreadable for the selection of the local feedback, and a peripheral annular zone of the hydrodynamic force feedback, the effects on the selected local areas by providing cavitators installed in appropriate locations bath orientation cavitation jets on hands, feet, neck and torso of the patient. 2. The method according to p. 1, characterized in that, simultaneously with the combined massage effect on the patient’s body, prophylactic disinfection of microflora in the working volume and on the surface of the bath is ensured due to the intense hydrodynamic pulsation of the jet stream and the increased temperature in the zones of formation of hydro-cavitation cavities. 3. An underwater massage device comprising a water pump, a bathtub filled with water, valves installed in the water supply line, cavitators and a control panel, characterized in that it contains an air compressor and an additional valve installed in the compressed air line, while cavitators made according to claim 4 and mounted on the walls of the bath with the orientation of the cavitation jets on the arms, legs, neck and torso of the patient, and the water pump is connected through a supply line looped to the bath rows to the hydraulic inputs cavitators and aerokompressor connected via a compressed air supply line to the air nozzles cavitators provided with protective nozzles mounted on outputs cavitators, wherein the control unit outputs are connected to the control inputs of water head pump aerokompressora gates and control inputs. 4. Cavitator for underwater massage, comprising a housing with an internal through cavity formed by successively arranged inlet confuser with convergence angle β _to , a transition chamber in communication with side openings for air ejection, and an output diffuser made with a stepped inner surface with a divergence angle of β _d = (10-90) °, characterized in that it comprises a bush, pressed into the transition chamber in said bushing has a central conical hole with the angle of convergence α = _C 10 ÷ 90 ° and the output Diamé rum D ₀ = (0.5-10) mm converger formed with a stepped internal surface with an angle of convergence β _K = 10 ÷ 90 °, and steps on the side surfaces of the converging tube and the diffuser are made to the terms: h _k = 1-2 mm; h _D ≥1.1 ÷ 2h _K , d ₁ <d ₂ <d _i <d _n , (i = 1-n) and D ₁ <D ₂ <D _J <D _m , (j = 1-m), n≥3, m≥3, where h _to - the height of the steps on the inner surface of the confuser; h _D - the height of the steps on the inner surface of the diffuser; d _i - the diameter of the i-th circular steps on the inner surface of the confuser, D _J - the diameter of the j-th circular steps on the inner surface of the diffuser, n and m are the number of steps, respectively, on the surfaces of the confuser and diffuser, wherein D _{i + 1} -D _i = d _{i + 1} -d _i = (1.8-2.2) mm. 5. Cavitator for underwater massage according to claim 4, characterized in that the output diffuser is made with a divergence angle β _d = (10-90) °.

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