Compression wave massage device

Abstract

A compression wave massage device for body parts is described, particularly for erogenous zones such as the clitoris, including a pressure field generation device and a drive device. The pressure field generation device has a cavity with a first end and a second end, located opposite the first end and distanced from the first end, with the first end being provided with at least one opening for placement on a body part. The drive device causes a change of the volume of the cavity between a minimal volume and a maximal volume such that in at least one opening a stimulating pressure field is generated. The cavity is formed by a single chamber, and the ratio of the volume change to the minimal volume is not below 1/10, preferably not below 1/8.

Claims

1. A compression wave massage device for body parts, comprising: a pressure field generation device consisting essentially of a flexible membrane and one continuous chamber, wherein the one continuous chamber includes one cavity having (i) a volume, (ii) a first end including an opening configurable for physical placement over a body part, and (iii) a second end, located opposite the first end and distanced therefrom, and wherein portions of the flexible membrane are physically attached and fixed to the one cavity at the second end to close the one cavity at the second end; a drive device including a motor, physically coupled to the flexible membrane, to, in operation, deflect the flexible membrane in a reciprocal motion in a direction towards the first end of the one cavity and away from the first end of the one cavity to thereby generate a change of the volume of the one cavity of the one continuous chamber between a minimum volume and a maximum volume such that a pressure field is generated at the first end of the one cavity of the one continuous chamber, wherein: (i) a ratio of the change in volume of the one cavity of the one continuous chamber to the minimum volume is greater than 1/10, and (ii) the ratio of the change in volume of the one cavity to the minimum volume is less than 1; a housing, wherein the drive device and the pressure field generation device are disposed within the housing; and a socket, physically engaged with the housing and having a shape that conforms to fit over the first end of the one cavity of the one continuous chamber to attach to an exterior surface of the housing and extends into the one continuous chamber to form a section of an inner lateral wall of the one cavity of the one continuous chamber, wherein: the housing includes a channel formed in an external surface thereof and spaced apart from the first end of the one cavity of the one continuous chamber, the socket includes a portion that is disposed on an exterior of the housing and a projection that engages and fits in the channel of the housing to secure the socket to the housing, and the socket is made from a flexible material and further includes a section, located between the projection and the portion that conforms to fit over the first end of the one cavity of the one continuous chamber, wherein the section of the socket is spaced apart from the exterior of the housing thereby providing a void between the socket and the housing.

2. The compression wave massage device of claim 1, wherein the socket is made from a soft, flexible material.

3. The compression wave massage device of claim 1, wherein the socket is detachable from the housing by removing the projection from the channel of the housing and wherein the socket is separate and spaced apart from the flexible membrane.

4. A compression wave massage device for body parts, comprising: a pressure field generation device consisting essentially of a flexible membrane and one continuous chamber, wherein the one continuous chamber includes a cavity having (i) a volume, (ii) a first end including an opening configurable for physical placement over a body part and (iii) a second end, located opposite the first end and distanced therefrom, and wherein portions of the flexible membrane are physically attached and fixed to the cavity at the second end to close the cavity at second end; a drive device including a motor, physically coupled to the flexible membrane, to, in operation, deflect the flexible membrane in a reciprocal motion in a direction towards the first end of the cavity and away from the first end of the cavity to thereby generate a change of the volume of the cavity of the one continuous chamber between a minimum volume and a maximum volume such that a pressure field is generated at the first end of the one cavity of the one continuous chamber, wherein: (i) a ratio of the change in volume of the cavity of the one continuous chamber to the minimum volume is greater than 1/10, and (ii) the ratio of the change in volume of the one cavity to the minimum volume is less than 1; a housing, wherein the drive device and the pressure field generation device are disposed within the housing; a socket, physically connected to the housing and having a shape that conforms to fit over the first end of the cavity of the one continuous chamber and extend into the one continuous chamber to form a section of an inner lateral wall of the cavity of the one continuous chamber and wherein the socket is separate and spaced apart from the flexible membrane wherein: the housing includes a channel formed in an external surface thereof and spaced apart from the first end of the one cavity of the one continuous chamber, the socket includes a portion that is disposed on an exterior of the housing and a projection that fits in the channel of the housing to secure the socket to the housing, and the socket is made from a flexible material and further includes a section, located between the projection and the portion that conforms to fit over the first end of the one cavity of the one continuous chamber, wherein the section of the socket is spaced apart from the exterior of the housing thereby providing a void between the socket and the housing; and wherein, in operation, the pressure field generation device and the drive device cooperate to provide a pressure field having a pattern of relative vacuum stages and relative overpressure stages which are modulated on a reference pressure, wherein a maximum pressure of each relative overpressure stage in reference to normal air pressure is below a value of a relative vacuum in reference to the normal air pressure.

5. The compression wave massage device of claim 4, wherein the maximum pressure of each relative overpressure stage in reference to the normal air pressure is less than or equal to 10% of the value of the relative vacuum in reference to the normal air pressure.

6. The compression wave massage device of claim 4, wherein the pressure field is a sinusoidal periodic pressure progression.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the following, a preferred exemplary embodiment of the invention is explained in greater detail based on the attached drawings. Here it shows:

(2) FIG. 1 is a perspective side view of the compression wave massage device according to the invention in a preferred embodiment;

(3) FIG. 2 is a front view of the compression wave massage device of FIG. 1;

(4) FIG. 3 is a longitudinal section through the compression wave massage device of FIG. 1;

(5) FIG. 4 is an enlarged detail of the longitudinal section of FIG. 3 in the head section of the compression wave massage device of FIG. 1; and

(6) FIG. 5 is a compression wave progression preferably generated by the compression wave massage device of FIG. 1.

DETAILED DESCRIPTION

(7) The preferred embodiment of the compression wave massage device 1 shown in the figures comprises an oblong housing 2 with a first end section 2a, an opposite second end section 2b, and a central section 2c located therebetween. Preferably the housing is made from plastic. As discernible from the FIGS. 1 to 3, in the exemplary embodiment shown the two end sections 2a and 2b are rounded and taper slightly towards the central section 2c, which is embodied slightly narrower. At the first end section 2a of the housing 2 a projection 4 is formed, protruding perpendicular in reference to the longitudinal extension of the housing 2 and forming together with the first end section 2a of the housing 2 a head of the compression wave massage device 1, while the second end section 2b of the housing 2 preferably serving as the handle in order to hold the compression wave massage device 1 during application, described in greater detail in the following.

(8) As further discernible from FIG. 1, in the direction of its longitudinal extension the housing 2 is composed of two half shells, with one of the half shells being provided with the above-mentioned projection 4. The two half shells of the housing 2, not marked in greater detail in the figures, are preferably glued to each other; alternatively it is also possible to connect the two half shells of the housing 2 in a different way, namely for example using screws or other fastening means arranged at the interior sides.

(9) As particularly discernible from FIGS. 1, 3, and 4, a socket 6 is located on the projection 4, which shows an opening discernible in FIGS. 2 to 4 and marked with the reference character “8”. Preferably the socket 6 is made from a soft and/or flexible plastic material, such as silicon.

(10) In the head of the compression wave massage device 1, formed by the first end section 2a of the housing 2 and the projection 4, a compression wave generation device 10 is located, by which a stimulating pressure field is generated with the help of the opening 8. As particularly discernible in detail from FIG. 4, the pressure field generation device 10 comprises a cavity 12 with an exterior first end 12a and an inner second end 4b, opposite the first end 12a and located distanced from the first end 12a, with the first end 4a simultaneously also forming the opening 8 in the socket 6. The cavity 12 is formed by a single continuous chamber 14 and is limited by an inner or lateral wall 12c connecting its two ends 12a, 12b to each other. As discernible from FIGS. 3 and 4, the socket shows an exterior section 6a by which it can be detachably fastened to the projection 4, and an inner section 6b, with the exterior section 6a and the inner section 6b of the socket 6 being connected to each other in the proximity of the opening 8. The inner section 6b of the socket 6 is formed like a sheath and limits an exterior section of the cavity 12 leading to an exterior first end 12a. This way, the inner wall of the sheath-shaped inner section 6b of the socket 6 forms simultaneously an exterior section 12c1 of the inner or lateral wall 12c of the cavity 12, leading to the opening 8. Further, in the exemplary embodiment shown the cavity 12 is limited by an interior annular element 16, with its inner wall simultaneously forming the other inner section 12c2 of the lateral wall 12c of the cavity 12. Accordingly, in the exemplary embodiment shown the continuous single chamber 14 is composed of the sheath-shaped inner section 6c of the socket 6 and the annular element 16.

(11) Alternatively it is also possible, for example, that the annular element 16 is omitted and instead the sheath-shaped inner section 6b of the socket 6 is extended to the membrane 18 and is connected to the membrane 18 to a joint, one-piece component such that the inner wall of the sheath-shaped inner section 6b of the socket 6 would form in this case the entire lateral wall 12c of the cavity 12.

(12) As further discernible in FIGS. 3 and 4, the arrangement of the socket 6 and the annular element 16 is rendered such that the first section 12c1 of the cavity 12 is aligned to the second section 12c2 of the cavity 12 such that the lateral wall 12c of the cavity 12 is free from any discontinuities. The cavity 12 of the chamber 14 essentially shows the form of a rotary body with a circular cross-section, with the cross-section of the cavity 12, defined perpendicular to its length L between the two ends 12a, 12b, in the exemplary embodiment shown essentially being almost constant over the entire length L between the two ends 12a, 12b and only expanding slightly towards the opening 8 such that the opening cross-section of the opening 8 is almost equivalent to the cross-section of the cavity 12. Alternatively it is also possible for example to provide the cavity 12 with an elliptic cross-section. Thus, the chamber 14 shows a continuous tube with a cross-section almost identical over its entire length, with in the exemplary embodiment shown the cavity being aligned in the direction of its length L approximately perpendicular to the longitudinal extension of the housing 2.

(13) In the exemplary embodiment shown the ratio of the width of the cavity 12, defined perpendicular to its longitudinal extension, to the length L of the cavity 12, defined in the direction of its longitudinal extension, values to approximately 0.39. However, other values are also possible for the ratio of diameter or width to length of the cavity 12 of the chamber 14 from 0.1 to 1.0.

(14) As further discernible from FIGS. 3 and 4, the cavity 12 is closed at its inner second end 12b with a flexible membrane 18, preferably produced from silicon, which extends over the entire cross-section of the cavity 12 and is driven via the mechanism 20 by a drive engine 22. Here the mechanism 20 is embodied such that the rotary motion of the output shaft 22a of the drive engine 22 is converted into a reciprocal longitudinal motion, causing the membrane 18 to be set in motion perpendicular to the level stretched, alternatively in the direction towards the opening 8 and opposite thereto. This way, the volume of the cavity 12 of the chamber 14 is altered depending on the rotation of the output shaft 22a of the drive engine 22. Preferably the mechanism 20 shows an eccentric or a con rod in order to convert the rotary motion of the output shaft 22a of the drive engine 22 into a reciprocal longitudinal motion for the reciprocal deflection of the membrane 18. In general, other forms of drives are also possible, which cause a deflection of the membrane 18 for changing the volume of the cavity 12. The reciprocal motion of the membrane 18 causes thereby a change of the volume of the cavity 12 between a minimal volume and a maximal volume such that a stimulating pressure field is generated in the opening 8. This can occur for example also in an electromagnetic, piezo-electric, pneumatic, or hydraulic fashion. However the arrangement must be made such that the ratio of the volume change to the minimal volume is not below 1/10 and preferably not below 1/8, so that the ratio of minimal volume to volume change is not exceeding 10, and preferably not exceeding 8, because otherwise during the motion of the membrane 18 in the direction away from the opening 8 the suction effect becomes too low. Further, preferably the arrangement should also be rendered such that the ratio of volume change to minimal volume is not greater than 1, and preferably not exceeding ½ so that the ratio of minimal volume to volume change is not below 1 and preferably not below 2, because otherwise on the one hand the power requirement of the drive engine 22 becomes excessive and on the other hand excessive vacuum develops during the motion of the membrane 18 in the direction away from the opening 8. This way, with the help of the flexible membrane 18 driven by the drive engine 22 alternating vacuum and overpressure stages are generated in the cavity 12 of the chamber 14.

(15) The volume of the cavity 12 is defined as the volume of the chamber 14 which ends in the proximity of the opening 8 at a virtual planar area, which virtually closes the opening 8 when the membrane 18 is in its normal and/or middle position. The minimal volume of the cavity 12 is defined such that the opening 8 of the cavity 12 is virtually closed with a planar area and the membrane 18 is in a position with the shortest distance from the opening 8 and thus in its maximally deflected state in the direction towards the opening 8. The maximal volume of the cavity 12 is defined here such that the opening 8 of the cavity 12 is virtually closed with a planar area and the membrane 18 is in a position with the greatest distance from the opening 8 and thus at a stage maximally deflected away from the opening 8.

(16) As further discernible from FIGS. 3 and 4, the drive engine 22, which in the described exemplary embodiment represents an electric motor, is connected via an electric cable 24 to an electric control circuit board 26, controlling the drive engine 22. As further discernible from FIG. 3, via an electric cable 28 a batter 30 is connected to the control circuit board 26, which provides the drive engine 22 and the control circuit board 26 with the required electric power. The battery 30 may optionally represent a battery that cannot be recharged or also a rechargeable accumulator. While in the exemplary embodiment shown the drive engine 22 is arranged in the connection area between the narrow central section 2c of the housing 2 and the first end section 2a of the housing 2 and thus adjacent to the head of the compression wave massage device 1 formed by the first end section 2a of the housing 2 and the projection 4, the battery 30 is arranged in the second end section 2b of the housing 2, resulting in the housing 2 being well balanced when the compression wave massage device 1 is held manually by the user.

(17) As further discernible from FIGS. 1 and 3, a power switch 32 is provided, with can be operated from the outside of the housing 2 to switch the compression wave massage device 1 on or off and is arranged in the narrow central section 2c of the housing 2. A sensor 34 is also arranged in the narrow, central section 2c of the housing 2, to be operated from the outside, by which the various operating conditions of the compression wave massage device 1 can be adjusted, and a control light 36 is arranged there, preferably embodied as a light diode visible from the outside. The power switch 32 and the sensor 34 are arranged directly on the control circuit board 26 fastened below the wall of the housing 2, while the control light 36 is connected via an electric cable, not shown in the figures, to the control circuit board 26.

(18) In addition to the control of the drive engine 22, in the exemplary embodiment shown, the electric control circuit board 26 also assumes the charge management of the battery 30. For this purpose, the control circuit board 26 is connected via an electric cable 38 to the charge contacts 40 arranged at the face of the second end section 2b of the housing 2 and accessible from the outside, as discernible from FIGS. 1 to 3. An external charging device, not shown in the figures, can be connected to these connections 40 via a plug with magnetic plug-in contacts, which can be made to contact the connection contacts 40 to establish an electric connection based on magnetic forces.

(19) The compression wave massage device 1 described is embodied as a hand-held device and for the application it is placed with the socket 6 onto a body part to be stimulated, not shown in the figures, such that in the proximity of the opening 8 of the socket 6 it is essentially surrounded. During operation of the compression wave massage device 1 then the body part to be stimulated is alternating subjected to different air pressures caused by the reciprocal motion of the membrane 18. Under normal application conditions, when no excessive pressures are applied after the placement of the compression wave massage device 1 with its socket 6 on the body part to be stimulated, relative pressures perhaps can largely dissipate which arise during the respective motion of the membrane 18 in the direction towards the opening 8 so that therefore essentially the pattern develops shown in FIG. 5 of a modulated relative vacuum in reference to the normal air pressure P.sub.0. However, as discernible from the pressure progression of FIG. 5, here relative overpressures can occur in the maximum in reference to normal pressure P.sub.0, which are considerably lower than the minima of the relative vacuum. Usually the value of the relative overpressure in reference to the normal pressure P.sub.0 amounts to no more than 10% of the value of the relative vacuum in reference to the normal pressure P.sub.0. Alternatively it is also possible that the pressure field only comprises a pattern of relative vacuum conditions, which are modulated on the normal pressure P.sub.0 (quasi from the bottom). In particular when the mechanism 20 comprises an eccentric, the sinusoidal periodic pressure progression develops shown in FIG. 5.

(20) Due to the fact that the cross-section of the cavity 12 of the chamber 14, as already described, is essentially almost constant over the entire length L, this results during operation in the air flow over the entire length L of the cavity 12 essentially remaining constant as well. This way a particularly effective air flow can be generated for an effective stimulation of the body part to be stimulated with relatively low energy consumption of the drive engine 22.

(21) The control circuit board 26 preferably shows a memory, not shown in the figures, in which various modulation patterns are saved. By an appropriate operation of the sensor 34, here a desired modulation pattern can be selected in order to control the drive engine 22 accordingly.