RU2068682C1 - Device for underwater hydropneumatic massage - Google Patents

Abstract

FIELD: medicine, in particular, conducting of massage and physiotherapy in sanatoriums and other medical institutions at treatment of various diseases. SUBSTANCE: the device is made in the form of two pipes 2 and 3 placed one inside the other, between which there is a space for air supply to nozzle 6; the inner surface of nozzle 6 is made in the form of baffles, having four successively connected sections: conical inlet, cylindrical straight, expanding and conical outlet ones. Air supply is controlled by changing the flow area. EFFECT: enhanced efficiency. 4 cl, 1 dwg

Description

 The invention relates to medical equipment, namely to devices for underwater hydraulic massage.

 Known devices for underwater massage, comprising a housing with a channel for forming a jet of liquid.

 A disadvantage of the known device is that the massage occurs with a small capture area of the massaged surface, i.e. The device has a low performance.

 A device is known for underwater hydraulic massage, taken as the prototype closest in terms of the problem to be achieved and the result achieved and containing a housing with central and peripheral channels, a nozzle located at the end of the central channel from the side of the massaged body surface, the channels being in communication with a source of air and liquid.

 A disadvantage of the known technical solution is the lack of effectiveness of the impact of the air jet on the body due to the mixing of air with water, i.e. dissolving most of the air and softening the impact of the jet.

 The aim of the invention is to increase the effectiveness of the hydromassage massage by providing a “stabbing” effect on the massaged body with a hydraulic jet.

 This goal is achieved by the fact that in the device for underwater hydromassage massage, comprising a housing with central and peripheral channels, a nozzle placed at the end of the central channel from the side of the massaged body surface, the channels being in communication with sources of liquid and air, the channels are formed by two coaxially arranged pipes mounted on the housing and nozzle, the inner surface of which has four working sections of the input conical, cylindrical, expansion and output conical, while the central channel is in communication with the liquid source, and the peripheral channel is connected on one side through the regulator of the passage to the air source, and on the other hand is connected with the expansion section.

 In addition, the connection of the peripheral channel with the expansion section is made in the form of an annular cavity communicated by radial channels of at least three with the expansion section and at least one longitudinal channel with the peripheral channel.

 In addition, the exit cone is made with curves on the part of the massaged body surface.

 The drawing shows a General view of a device for underwater hydraulic massage.

 A device for underwater hydro-air massage (see drawing) consists of a housing 1, on which two coaxially arranged tubes 2 and 3 are fixed to form the central and peripheral channels 4 and 5. On the opposite side of the housing 1, the sides of the tubes 2 and 3 are mounted on a nozzle 6 having four working sections of the input conical 7, cylindrical 8, expansion 9 and the output conical 10. The Central channel 4 is in communication with the fluid source 11, and the peripheral channel 5 is connected on one side through the regulator of the passage 12 to the air source 13 , and on the other hand communicated with the expansion section 9, the diameter of which is greater than the diameter of the cylindrical section.

 An annular cavity 14 is made on the nozzle 6, which is communicated by radial channels 15 of at least three with an expansion section 9 and at least one longitudinal channel 16 with a peripheral channel.

 The output conical section of the nozzle 6 is made with rounding from the side of the massaged body surface, forming a bell, which its lower part is in contact with the massaged surface 17.

 The air supply to the peripheral channel 5 is carried out and regulated by the regulator 12 through passage.

 The proposed device operates as follows.

Water (mineral, fresh, sea) with a temperature of 34 38 ^o C from the source 11 in the form of a pumping unit (type TANGENTOR 8) through a flexible hose (not shown) flows through the housing 1 into the pipe 2 and flows through the nozzle 6 to the surface 12 of the patient’s body .

 The flow of water entering through the pipe 2 narrows in the inlet cone section 7 of the nozzle 6, then stabilizes and accelerates in the straight cylindrical section 8. Having passed the straight section 8, the water stream narrows sharply in the expansion section 9, and then, expanding sharply at the end of it, a flowing stream spreads over the inner surface of the outlet conical section 10, affecting the massaged body.

 In the expansion section 9, a negative pressure is created due to the high-speed flow, that is, the static pressure in it becomes lower than the pressure surrounding the upper unheated part of the medium device, which allows air to be introduced through channels 16 and 15 from the peripheral channel 5. By changing the position of the regulator 12, i.e. by overlapping the holes 18 and 19 with the plates 18, the size of the area of the orifice of the holes is changed and thereby the air volume is controlled.

 Due to the high-speed flow of water passing through the gap 21, spreading from the center of the device to its periphery, the static pressure in the stream becomes lower than the pressure of the surrounding fluid, which creates a suction effect that holds the nozzle on the patient's surface with the possibility of free movement of it with little massage .

 The air entering through the ejector is injected directly into the stream of water (without preliminary dissolving the air in the stream) (it has a low static pressure in this area) and is “conserved” because the stream is also carried in the form of bubbles by the stream, affecting the patient’s body with micowaves, taking place when the bubbles collapse. This total hydraulic effect allows a deeper massage of the patient’s body with a slight tingling sensation at the massage site when using the proposed nozzle compared to the prototype. The effectiveness of the massage when using the proposed nozzle increases due to the fact that the area of influence of the flow spreading from it is several times larger than the area of the impact of the jet flowing from the nozzle of the prototype with the same flow area.

 To ensure the collapse of the bubbles on the massaged surface, it is necessary to ensure the condition: 6-5 d ≅ L ≅ 8d, where L is the distance between the nozzle expansion section and the nozzle end surface from the massaged surface, d is the diameter of the expansion section.

Claims (4)

 1. A device for underwater hydromassage massage, comprising a housing with central and peripheral channels connected to sources of liquid and air, a nozzle located at the end of the central channel from the side of the massaged body surface, characterized in that the channels are formed by two coaxially arranged tubes fixed to housing and nozzle, the inner surface of which has four series-connected working sections of the input conical, cylindrical, expansion and output conical, with In this case, the central channel is in communication with the fluid source, and the peripheral channel is connected on one side through the regulator of the passage to the air source, and on the other side is connected with the expansion section.  2. The device according to claim 1, characterized in that the connection of the peripheral channel with the expansion section is made in the form of an annular cavity communicated by radial channels of at least three, with the expansion section and at least one longitudinal channel with the peripheral channel.  3. The device according to claim 1, characterized in that the output cone is made with rounding from the side of the massaged body surface. 4. The device according to claim 1, characterized in that the distance L from the end surface of the nozzle from the side of the massaged surface is determined from the condition
6,5d≅L≅8d,
where d is the diameter of the expansion section.