RU2252739C2 - Method and device for carrying out massage treatment in self-excited vibration mode - Google Patents

Abstract

FIELD: medicine; medical engineering.

SUBSTANCE: method involves applying periodic negative stress to human skin causing alternating suction skin area under massage into internal cavity of vibration vacuum nozzle in self-excited vibration mode and producing hydrodynamic oscillations of pressure in frequency bandwidth of 6-50000 Hz. Water discharge rate Q (m³/s) through the vibration vacuum nozzle is determined by relationship 7d²≤Q≤30d², where d is the equivalent diameter of the inlet canal (m),

S is the cross-section area of at least one canal (m²), π=3.1415. The vibration vacuum nozzle has whirlpool chamber having vertical symmetry axis and at least one inlet canal which symmetry axis is arranged at an angle and laterally displaced relative to the vertical symmetry axis of the whirlpool chamber and axially symmetrical outlet canal coaxially arranged relative to the whirlpool chamber. Outlet canal surface smoothly transforms into flat surface of lower part of the vibration vacuum nozzle. The flat surface is arranged in perpendicular to the vertical symmetry axis of the whirlpool chamber.

EFFECT: enhanced effectiveness, depth and quality of massage treatment.

10 cl, 5 dwg

Description

FIELD OF THE INVENTION

The invention relates to medicine, namely to therapeutic methods for influencing human skin, is intended to increase skin elasticity, conduct anti-cellulite actions and deep massage and can be used in cosmetology and sports medicine.

State of the art

Known methods and devices for hydromassage, in which massage is carried out using a hydrodynamic nozzle. The nozzle directs a water-air stream to the body of a person in a bathtub filled with water. The nozzle can be moved laterally along the respective rails by using the energy of the flow of the water supply system (US Pat. Nos. 4,698,939, class A 61 H 09/00, and No. 4726080, class A 61 H 9/00).

The disadvantage of these methods and the corresponding devices is the low massage efficiency, since massage can be carried out only on those parts of the body that are in close proximity to the hydrodynamic nozzle installed and moving along the side wall of the bath.

Known devices for hydromassage, in which the nozzle is connected via a hose to either a pump or a water supply system. Massage is carried out using a pulsating jet directed at the human body, regenerated by a hydromassage nozzle. During massage, the nozzle is held in the hand and moved along the entire body, including when the body and the nozzle are immersed in water (US Pat. No. 5,230,006, class A 61 H 7/00, and No. 5197459, class A 61 H 9/00) .

The disadvantage of these devices is the low massage efficiency due to the fact that the pulsation frequency of the water jet is low, not exceeding several tens of hertz, and also due to the lack of the ability to create pressure below ambient pressure, which will allow the skin to be absorbed and thereby significantly increase the effectiveness of massage.

Known devices for hydromassage, the nozzle of which has tangential inlet channels for swirling the flow of water and creating a vacuum to suck the skin into the nozzle. However, the design of the device does not allow the generation of low-frequency high-amplitude self-oscillations of pressure directly acting on the skin (RF patents No. 2010559, class A 61 H 9/00, and No. 2095046, class A 61 H 9/00).

A known method of vibro-acoustic shower massage and a device for its implementation (RF patent No. 2147860, class A 61 H 9/00), adopted for the closest analogue. The method includes the formation of a main vortex stream to create a vacuum space in the chamber and the formation of a side spray stream to create a pulsating water jet, the side stream being reused, cyclic impacts of the main vortex stream with a side spray stream, and a vacuum is created in the nozzle, which promotes suction skin inside the nozzle and the impact on it by the stream of the jet.

The disadvantage of this method and device is the technical impossibility of creating simultaneously high-amplitude alternating low-frequency self-oscillations of pressure in the nozzle and high-frequency vibrations.

SUMMARY OF THE INVENTION

The technical result of this invention is to increase the intensity and depth of massage.

The specified technical result is achieved due to the fact that in the method of vibro-vacuum massage, which involves placing at least one of the parts of the human body in a bath filled with water and exposing it to a stream of liquid from a nozzle immersed in water connected by a flexible hose to the outlet of the water pump, the entrance of which, in turn, is connected via a hose or pipe to a bathtub filled with water, the water is circulated through a vibro-vacuum massager, thereby creating a periodic negative e pressure on the human skin in the self-oscillation mode, which leads to alternately sucking into the vibrated massager of the massed skin area due to cavitation inside the vibro-vacuum massager, and the generation of hydrodynamic pressure fluctuations in the frequency range of 6-50000 Hz, thereby causing the breakdown of fat in subcutaneous fat vacuoles and increase elasticity and, accordingly, elongation of the vertical connective fibers between the surface of the skin and muscle tissue, between which there are fat vacuoles, leading to a significant reduction in the manifestation of cellulite on the surface of the skin or, in other words, fibrosclerotic paniculopathy.

In addition, vibro-vacuum massage is carried out at a flow rate of Q (m ³ / sec) through a vibro-vacuum massager in accordance with the dependence

7d ² ≤ Q≤ 30d ² ,

S - площадь поперечного сечения по крайней мере одного входного канала (м²), π =3,1415.where d is the equivalent diameter of the input channel (m),

S is the cross-sectional area of at least one input channel (m ² ), π = 3.1415.

In addition, vibro-vacuum massage is carried out by moving the nozzle over the skin of a person along the fibers of muscle tissue, and not across the latter, which allows to maximize the depth and intensity of the massage.

The specified technical result is achieved due to the fact that the device for conducting a vacuum massage contains a bath filled with water, connected via a hose or pipe to the pump inlet, the output of which, in turn, is connected using a flexible hose to a nozzle made in the form of a vacuum a massager including an axisymmetric vortex chamber with at least one inlet channel, the axis of symmetry of which is angled and laterally offset with respect to the axis of symmetry the vortex chamber and disposed coaxially with the swirl chamber axisymmetric outlet channel whose surface smoothly into the flat surface of the lower portion vibrovakuumnoy chamber perpendicular to the axis of symmetry of the vortex chamber.

In addition, at least one hemispherical fixed protrusion or a body of revolution recessed into a flat surface of the lower part of the vibro-vacuum massager is installed on a flat surface of the output channel and can rotate around its axis of symmetry.

In addition, the height h (m) of the hemispherical shape of the protrusion or body of revolution is determined by the dependence

where P is the negative pressure in the axisymmetric outlet channel (Pa), D is the diameter of the axisymmetric hollow chamber (m), k is the coefficient of linear elasticity of water, the pressure gradient (Pa / m) determined experimentally, P = 1,6ρ Q ² / d ⁴ , where ρ is the density of water (kg / m ³ ), Q is the maximum possible flow rate of water through a vibro-vacuum massager (m ³ / s), d is the equivalent diameter of the inlet channel (m).

In addition, the angle between the axis of symmetry of the input channel and the axis of symmetry of the vortex chamber φ varies from 35 to 110 degrees.

In addition, the lateral displacement of the input channel of the vibro-vacuum massager with respect to the axis of symmetry of the vortex chamber is determined by the ratio

(D-d) / 2≤ x≤ d,

where x is the lateral displacement (m), d is the diameter of the input channel (m), D is the diameter of the axisymmetric vortex chamber (m).

In addition, the connection of the output channel with the flat surface of the lower part of the vacuum chamber is made in the form of a toroidal surface with a radius R, the lower part of which smoothly passes into a flat surface located perpendicular to the axis of symmetry of the vortex chamber, and the radius R (m) is determined by the dependence

D-d≤ R≤ 3D,

where d is the equivalent diameter of the input channel (m), D is the diameter of the axisymmetric vortex chamber (m).

It is possible to install a spiral element in the vortex chamber to impart additional swirling of the water flow coming from the inlet to the vortex chamber.

List of drawings

Figure 1 shows a diagram of a device for conducting a vacuum massage; figure 2 shows a vibro-vacuum massager in longitudinal section; figure 3 is the same, but in cross section; figure 4 shows a vibro-vacuum massager with an installed spiral element inside an axisymmetric vortex chamber; 5 shows the frequency spectra generated by a vibro-vacuum massager.

Information confirming the possibility of carrying out the invention

The proposed device for conducting a vacuum massage consists of a pump 1 (Fig. 1), which supplies water under pressure through a pressure line through a flexible hose 4 to a vacuum nozzle 5, which is located below the surface of the water 7 in the bath 6 and acts on the area of human skin 8. Using pipes or hose 9, water from the bath 6 is fed back to the inlet of the pump 1. Using the valves 2 and the pressure gauge 3, the pressure is regulated by the pressure and the fluid flow through the nozzle 5, thereby changing the frequency spectrum and the force of absorption of the human skin 8 in the mode self-oscillation.

The vibro-vacuum nozzle 5 is made in the form of an axisymmetric vortex chamber 10 with at least one input channel 11, the axis of symmetry of which is located at an angle φ (FIG. 2) and is offset laterally with respect to the symmetry axis of the vortex chamber 10 by a distance x (FIG. 3), and the output channel 16 coaxially located with the vortex chamber 10, the surface of which smoothly passes into the flat surface 18 of the lower part of the nozzle 5, perpendicular to the axis of symmetry of the vortex chamber 10. At least 18 are installed on the flat surface 18 of the output channel 16 e, a hemispherical shape fixed protrusion 13 or recessed into the flat surface 18 of the lower part 5 vibrovakuumnogo massager body of rotation 13 (not shown) that can rotate around its axis of symmetry. For the convenience of the massage, the vibration vacuum nozzle 5 is equipped with a handle 15 connected to the flexible hose 4. The outer surface of the handle 15 is connected to the vibration vacuum massager 5 by means of a smooth surface 12, thereby ensuring the ergonomics of the latter. Inside the handle 15, the channel 19 is connected to at least one input channel 11.

The claimed method is implemented as follows. Water 7 is poured into the bath 6 (Figure 1), the temperature of which is comfortable for a person 8 in the bath 6. After turning on the pump 1 in the recirculation mode along the circuit: pump outlet 1 - flexible hose 4 - vibration nozzle 5 - water in the bath 7 - hose 9 - pump inlet 1, using valves 2 and pressure gauge 3, set the optimal fluid flow rate and discharge pressure through the vibrating nozzle 5 depending on the sensitivity of human skin 8. The massaged area of human skin 8 and the vibro-vacuum massager 5 are located below the surface of water 7. When income water from the flexible hose 4 through the channel 19 (Figure 2) and at least one inlet channel 11 into the axisymmetric vortex chamber 10, the fluid flow swirls and then flowing out of the outlet channel 16 along the flat surface 18, forms a fan stream perpendicular to the axis of symmetry of the vortex chambers 10. Due to the swirling of the water flow 17 in the vortex chamber 10, a cavitation cavity is formed on its axis of symmetry, from which air bubbles periodically come off, which collapse at the outlet of the outlet channel 16, causing hydrodynamic vibrations Nia pressure in the range 6-50000 Hz (Figure 5, lower spectra). In turn, the cavitation cavity formed inside the vortex chamber 10 causes a local decrease in pressure at the transition point of the outlet channel 16 to a flat surface 18, which leads to the suction of the skin located directly under the outlet channel 16 into the outlet channel 16 and to the hydrodynamic overlap of the latter. However, due to the injection of water through the vibrating nozzle 5, this continues for only tens of fractions of a second, until the pressure in the vortex chamber 10 is equal to the surrounding hydrostatic pressure of the water at the location of the nozzle 5. At this point, the suction of the skin area ceases and the nozzle breaks off. 5 from the skin as a result of excess pressure inside the outlet channel 16 over the surrounding hydrostatic, but again for tens of fractions of a second, due to the newly appeared local decrease in pressure under the nozzle 5, the skin area is again sucked into the inside of the output channel 16 and the process is repeated, leading to the generation of low-frequency self-oscillations in the range of 6-224 Hz (Fig. 5, upper spectrum). Such periodic suction and release of the skin area at a low frequency in the self-oscillation mode simultaneously with high-frequency vibrations generated by the breakdown and collapse of cavitation bubbles at the outlet of the output channel 16, significantly intensifies the process of breaking up cellulite vacuoles of subcutaneous fat and increasing the elasticity of the skin and, accordingly, lengthening the vertical connective fibers between the surface of the skin and muscle tissue, between which there are fat vacuoles, leading to a significant decrease uw manifestations of "orange peel" skin and cellulite. The presence of a flat surface 18, providing the formation of a fan diverging stream, allows you to get the maximum vacuum in the vortex chamber 10 and, as a result, a deeper absorption of the skin in the output channel 16 in the mode of self-oscillations and, accordingly, a deeper massage. Moreover, in order to provide an effective deep massage of human skin 8, on the one hand, and, on the other hand, not to cause the appearance of superficial papillary hemorrhages, the water flow Q (m ³ / s) through the nozzle 5 should be within the following limits:

7d ² ≤ Q≤ 30d ² ,

S - площадь поперечного сечения по крайней мере одного входного канала 11 (м²), π =3,1415. Периодические отрицательные напряжения (отсасывающее действие) в режиме автоколебаний позволяют, кроме того, интенсифицировать процесс транспортировки жира из жировых вакуолей в митохондрии (за счет аминокислоты L-карнитина), где и происходит процесс его перерабатывания в энергию. В данном случае массаж, проводимый струей воды, проходящей через насадку в автоколебательном режиме, гораздо эффективнее обычно рекомендуемого вакуумного массажа для синтезирования аминокислоты L-карнитина, поскольку концентрация напряжений на отдельный участок кожи и мышц существенно превосходит напряжения, возникающие при обычных вакуумных нагрузках.where d is the equivalent diameter of the input channel 11 (m),

S is the cross-sectional area of at least one input channel 11 (m ² ), π = 3.1415. Periodic negative stresses (suction effect) in the mode of self-oscillations allow, in addition, to intensify the process of transporting fat from fat vacuoles to mitochondria (due to the amino acid L-carnitine), where it is converted to energy. In this case, the massage carried out by a stream of water passing through the nozzle in self-oscillating mode is much more effective than the usually recommended vacuum massage for synthesizing the amino acid L-carnitine, since the stress concentration on a separate area of the skin and muscles significantly exceeds the stresses that arise under ordinary vacuum loads.

The optimal mode of self-oscillations in terms of suction force and, as a consequence, the depth of the massage effect is ensured if the flat surface 18 is at a certain distance h from the human skin 8, which is achieved by installing at least one output channel 16 on the flat surface 18 hemispherical shape of the stationary protrusion 13 or recessed into a flat surface 18 of the body of revolution, able to rotate around its axis of symmetry, and the height of the protrusion 13 (Figure 2) or body of revolution is equal to the distance h and defined by the formula

where h is the height of the hemispherical shape of the protrusion or body of revolution (m), P is the negative pressure in the outlet channel 16 (Pa), D is the diameter of the axisymmetric vortex chamber 10 (m), k is the coefficient of linear elasticity of water (Pa / m), determined empirically, P = 1.6ρ Q ² / d ⁴ , where ρ is the density of water (kg / m ³ ), Q is the maximum possible flow rate of water through a vibro-vacuum massager 5 (m ³ / s), d is the equivalent diameter of the input channel 11 (m). The rotation body 13 is expediently used for skin hypersensitivity to reduce friction between the vibro-vacuum massager 5 and human skin 8. For the parameters of the circulation regime Q = 3.15 × 10 ^-4 m ³ / s, ρ = 1000 kg / m ³ , d = 0.004 m , k = 2000 Pa / m, the rarefaction pressure P is 0.056 MPa, and the height of the hemispherical protrusion 13 is 0.007 m.

Perhaps the implementation of the input channel 11 with an offset x (Figure 3) within

(D-d) / 2≤ x≤ d,

where x is the lateral displacement (m), d is the diameter of the inlet (m), D is the diameter of the axisymmetric vortex chamber (m),

and also at an angle φ (Figure 2), which can vary from 35 to 110 °. The implementation of at least one inlet with an offset of x and at an angle φ can increase the frequency occupancy of the high-frequency part of the vibration spectrum of the vibro-vacuum nozzle 5 and increase the effectiveness of massage with a relatively low amplitude of self-oscillations in the case of massage of especially sensitive skin areas, for example, a person’s face, when To prevent papillary hemorrhage, it is impossible to apply excessively intense suction of the skin.

To prevent separation of the water flow 17 curled in the vortex chamber 10 from the surface of the outlet channel 16 and with the aim of forming a flat diverging fan stream along the flat surface 18 to create the most optimal mode of self-oscillations, the lower part of the outlet channel 16 is made in the form of a toroidal surface with a radius R, smoothly turning into a flat surface 18 located perpendicular to the axis of symmetry of the vortex chamber 10, and the radius R (m) is determined by the dependence

D-d≤ R≤ 3D,

where d is the equivalent diameter of the input channel 11 (m), D is the diameter of the axisymmetric vortex chamber 16 (m).

Satisfaction of the condition of the absence of flow stall is also possible when the lower part of the output channel 16 is executed in the form of a paraboloid, a rotation hyperboloid, and also a parabolic hyperboloid.

In addition, it is possible to connect a vibro-vacuum massager directly to the water supply system, provided that the requirements for pressure and water flow through it are met.

In the case of using an aqueous suspension for massage based on various flavoring, mud and salt inclusions for additional homogenization, it is advisable to connect the inlet channel 11 hydrodynamically with a spiral element 14 installed in the vortex chamber 10 to impart additional turbulence to the flow and homogenize the suspension.

Example. Four women with visually noticeable manifestations of cellulite underwent a course of vibro-vacuum massage, consisting of 10 sessions, two sessions a week for 45 minutes each. Before each course of vibro-vacuum massage, each of them measured five volumes, namely, ankles, knees, hips, buttocks, and waist, and determined the average body volume index equal to the sum of all volumes divided by the number of measurements (i.e. by 5), which amounted to 51.2 cm, 53.6 cm, 55.6 cm and 58 cm. After taking a course of vibro-vacuum massage, the manifestations of cellulite significantly decreased and the average body volume index was 49.2 cm, 52.1 cm, 51.8 cm, respectively and 54.3 cm or decreased by an average of 2.75 cm.

A reduction in the external manifestations of cellulite and the amount of adipose tissue was noted, skin elasticity and appearance improved due to intensive stimulation of collagen production during the sessions.

Claims (10)

1. A method of conducting a vacuum massage, comprising placing at least one part of the human body in a bath with water and exposing it to a vacuum nozzle immersed in water and connected by a flexible hose to a water pump, characterized in that the device is exposed to the device according to claim .4 by periodically sucking the skin into a vibrating nozzle in the self-oscillation mode due to the creation of a vortex flow forming hydrodynamic pressure fluctuations in the frequency range of 6 ÷ 50,000 Hz. 2. The method according to claim 1, characterized in that the vibration vacuum massage is carried out in the range of water flow Q through the vibration vacuum nozzle in accordance with the dependence 7d ² ≤ Q≤ 30d ² , where Q is the flow rate of water through the vibrating nozzle (m ³ / s), d is the equivalent diameter of the inlet channel (m),

S is the cross-sectional area of at least one input channel (m ² ), π = 3.1415. 3. The method according to claim 2, characterized in that the vibro-vacuum massage is carried out by moving the vibro-vacuum nozzle over the human skin along the fibers of muscle tissue. 4. A device for conducting a vacuum vacuum massage comprising a bath with water and a nozzle connected by a flexible hose to the outlet of the water pump, characterized in that the inlet of the water pump is connected to the bath to create water circulation through the vibration vacuum nozzle, while the vibration vacuum nozzle includes a vortex chamber, having a vertical axis of symmetry, with at least one input channel, the axis of symmetry of which is at an angle and offset laterally with respect to the vertical axis of symmetry of the vortex measures, and an axisymmetric output channel located coaxially with the vortex chamber, the surface of which smoothly passes into the flat surface of the lower part of the vibratory vacuum nozzle perpendicular to the vertical axis of symmetry of the vortex chamber. 5. The device according to claim 4, characterized in that the angle φ between the axis of symmetry of the input channel and the vertical axis of symmetry of the vortex chamber varies from 35 to 110 degrees. 6. The device according to claim 4, characterized in that the lateral displacement of the axis of symmetry of the input channel with respect to the vertical axis of symmetry of the vortex chamber is determined by the ratio (D-d) / 2≤ x≤ d, where x is the lateral displacement (m), d is the equivalent diameter of the input channel (m), D is the diameter of the vortex chamber (m). 7. The device according to claim 4, characterized in that the surface of the transition of the output channel to the flat surface of the lower part of the vacuum nozzle is made in the form of a toroidal surface with a radius R, which is determined by the dependence D-d≤ R≤ 3D, where d is the equivalent diameter of the input channel (m), D is the diameter of the vortex chamber (m). 8. The device according to claim 7, characterized in that at least one fixed hemispherical protrusion is mounted on the flat surface of the output channel or a body of revolution is installed, recessed into the flat surface of the output channel, with the possibility of rotation around its axis of symmetry. 9. The device according to claim 8, characterized in that the height h of the hemispherical shape of the protrusion or body of revolution is determined by the dependence

where P is the negative pressure in the axisymmetric outlet channel (Pa), D is the diameter of the vortex chamber (m), k is the coefficient of linear elasticity of water (Pa / m), determined experimentally, P = 1,6ρ Q ² / d ⁴ , where ρ is the density of water (kg / m ³ ), Q is the maximum possible flow rate of water through the vortex chamber (m ³ / s), d is the equivalent diameter of the inlet channel (m). 10. The device according to claim 4, characterized in that the spiral element is additionally mounted in the vortex chamber for additional swirling of the water flow.

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