The invention relates to a massaging device for the male genital organ with an elongated massaging recess for receiving the male genital organ.
The existing art is familiar with numerous massaging devices for sexual stimulation of a male genital organ, in particular a human penis.
The goal of such massaging devices is to apply vibrations to the male genital organ to achieve excitation of the male genital organ. One primary problem with such massaging devices is the unusual manner of stimulation, which differs from that of natural sexual intercourse.
From this point of departure, it is an object of the invention to present a massaging device with a new type of drive mechanism for generating a massaging motion that achieves stimulation of the male genital organ in a manner that is as natural as possible.
An essential aspect of the massaging device, according to the invention, is the fact that the drive mechanism comprises a plurality of bearing surfaces, which are arranged at a radial distance from the longitudinal axis and which at least sectionwise enclose the elongated massaging recess and that the drive mechanism is designed for an oscillating deformation of the elongated massaging recess at least radially inward along the longitudinal axis of the elongated massaging recess. The oscillating radial deformation of the elongated massaging recess, along the longitudinal axis of the massaging recess, achieves particularly advantageous massaging of the male genital organ held in the elongated massaging recess and therefore a stimulation that is as natural as possible.
A further advantage is that the oscillating deformation along the longitudinal axis of the elongated massaging recess and/or in the circumferential direction of the elongated massaging recess is preferably out of phase. This achieves a wave-like deformation of the elongated massaging recess, for example, in the form of a wave progressing along the longitudinal axis of the massaging recess.
Advantageously, several bearing surfaces are arranged concentrically around the longitudinal axis or radially offset to the longitudinal axis of the massaging recess or radially offset to the longitudinal axis of the massaging recess.
The elongated massaging recess can be formed by an at least sectionwise tubular formed part made of a rubber-elastic material and the bearing surfaces can bear at least partially on the lateral surface of the elastic formed part.
In a preferred embodiment, several bearing surfaces are arranged concentrically around the longitudinal axis of the massaging recess. The oscillating deformation advantageously along the longitudinal axis of the elongated massaging recess and/or in the circumferential direction of the elongated massaging recess is preferably out of phase.
Advantageously, the drive mechanism is designed for a wave-like deformation of the elongated massaging recess, namely in the form of a wave progressing along the longitudinal axis of the elongated massaging recess.
In particular, it is advantageous for one bearing surface to be formed by at least one drivable shaft comprising at least one eccentric section.
Further, the bearing surfaces can be formed by a plurality of bearing elements, in which case several bearing elements arranged respectively along the longitudinal axis can be driven by means of at least one shaft to produce a radial stroke movement. For this purpose, the bearing elements comprise at least one guide opening respectively for holding the at least one shaft. It is especially advantageous for the bearing elements to be jaws, disks, balls and/or bristles.
The bearing elements are made of a solid or elastically deformable material, for example of metal, plastic, elastomer, foamed polyurethane or any combination of these materials. In particular, the bearing elements are designed differently at least sectionwise along the longitudinal axis. For example, several support elements can be arranged in a common plane perpendicular to the longitudinal axis of the elongated massaging recess and form one group of support elements, and a plurality of such groups can be provided successively along the longitudinal axis of the elongated massaging recess.
In a further embodiment a plurality of successive, at least sectionwise circular ring-shaped bearing elements with at least one guide opening are provided along the longitudinal axis of the elongated massaging recess. At least one rod-shaped guide or support element is guided through the at least one guide opening.
On the at least one rod-shaped guide or support element, several jaw-shaped or at least sectionwise circular ring-shaped bearing elements are advantageously lined up, the at least one rod-shaped guide or support element being approximately parallel to the longitudinal axis of the holding space and arranged at a distance to said axis. Preferably several such rod-shaped guide or support elements with lined-up bearing elements are provided concentrically around the longitudinal axis. Further, for driving the bearing elements lined up on a rod-shaped guide or support element, the at least one shaft acts upon one circumferential side of the bearing elements.
For moving the support surfaces and/or the support elements forming said support surfaces, it is advantageous to provide at least one shaft comprising at least one eccentric section and interacting with the support elements and that can be driven by a drive unit. The at least one eccentric section extends parallel or approximately parallel to the longitudinal axis of the shaft at least over a partial length of the at least one shaft. Also, the at least one eccentric section can extend diagonally to the longitudinal axis of the shaft over a partial length of the at least one shaft or have a twisted design at least over a partial length of the at least one shaft, namely so that it extends spirally around the longitudinal axis of the shaft.
Advantageously, the at least one eccentric section is formed by one edge of the at least one shaft and the eccentric section is designed so that the at least one shaft at least partially has a non-circular cross section, for example a polygonal, essentially polygonal or oval cross section. Preferably at least the eccentric section is surrounded by an elastically deformable material, in particular an elastomer or a foamed polyurethane material.
Further embodiments of the invention ensue from the following description of exemplary embodiments and the drawings. All characteristics described and/or represented, alone or in any combination, are subject matter of the invention, regardless of their being summarized or referenced in the claims.
The invention is described in more detail below based on exemplary embodiments with reference to several drawings, in which:
a, b are two exemplary side views of shafts in a first embodiment;
a, b are two exemplary side views of alternative shafts in a second embodiment;
The massaging device 1 comprises an elongated massaging recess 2 for receiving the male genital organ, with a drive mechanism 4 for deformation of the elongated massaging recess 2. The elongated massaging recess 2 can, as shown in
The elongated massaging recess 2 of the massaging device 1 is essentially tubular or hollow cylindrical in shape, and on at least one end of the elongated massaging recess 7 an opening 2′ is provided for insertion of the penis to be stimulated into the elongated massaging recess 2. Preferably the end of the elongated massaging recess 2 opposite the opening 2′ is closed, for example, so that it contains a holding space for the ejaculate.
In a preferred embodiment, the elongated massaging recess 2 is at least partially lined with an elastic formed part 3, which is designed as one piece and at least sectionwise comprises a wall 3′ surrounding the longitudinal axis LA approximately concentrically. The elastic formed part 3 or its wall 3′ adapts with the outer lateral surface 3″ to the contour defined by the drive mechanism 4. In addition, the elastic formed part 3 is preferably reverse drawn over the end opening 2′ and fixed there.
Further, a drive mechanism 4 at least sectionwise radially surrounding the elongated massaging recess 2 is provided along the longitudinal axis LA, which (drive mechanism) is designed for an oscillating deformation of the elongated massaging recess 2 at least radially inward, namely relative to the longitudinal axis LA of the elongated massaging recess 2. The oscillating deformation can take place along the longitudinal axis LA of the elongated massaging recess 2 and/or in the circumferential direction of the elongated massaging recess 2 preferably out of phase, producing an approximately wave-like deformation of the massaging recess 2, in the form of a wave progressing along the longitudinal axis LA of the elongated massaging recess 2.
The drive mechanism 4 comprises, for this purpose, a plurality of bearing surfaces 5, which surround the elongated massaging recess 2 and are arranged concentrically to its longitudinal axis LA, and the bearing surfaces 5, in the case of the massaging recess 2 being lined with an elastic formed part 3, at least partially bear against its lateral surface 3″. The bearing surfaces 5 can be formed by different mechanical components, which are explained exemplarily in the following.
The drive mechanism 4 can, for example, comprise several guide and support elements 9 fixed between a first support element 11 and an opposing second support element 12, and firmly connected with the support elements 11, 12. The guide and support elements 9 are designed, for example, in the form of a rod or bar and are oriented approximately in the direction of the longitudinal axis LA of the massaging device 1.
Between the first support element 11 and the second support element 12, which is at a distance from the first support element 11, a plurality of bearing elements 6 is arranged, each bearing element 6 comprising at least one guide opening 3, and at least one guide or support element 9 being guided through this guide opening 8. The guide openings 8 are designed so that a radial displacement of the bearing elements 6 in the X-Z plane is possible, i.e. from the outside to the inside and vice versa, respectively in relation to the longitudinal axis LA. Preferably the guide opening 8 is oval or oblong in shape.
The surface sections of the bearing elements 6 oriented in the direction of the longitudinal axis LA form the bearing surfaces 5 for the outer lateral surface 3″ of the elastic formed part 3. The surface sections of the bearing elements 6 opposite these bearing surfaces 5 bear against at least one shaft 7, and the longitudinal axis LW of the shaft 7 is approximately parallel to the longitudinal axis LA of the massaging device 1 and is at a distance from the latter. The shaft 7 is preferably rotatably mounted in the first and second support element 11, 12 and can be driven on its respective longitudinal axis LW by means of a drive unit not depicted in the drawings.
In the area between the first support element 11 and the second support element 12 the shaft 7 comprises at least one eccentric section 7.1, which interacts with the surface sections of the bearing elements 6 facing away from the longitudinal axis LA, and displaces these bearing elements 6 radially to the longitudinal axis LA during rotation of the shaft 7, i.e. produces a radial stroke movement. This radial stroke movement of the bearing elements 6 causes deformation of the elastic formed part 3 or at least of its wall 3′. The guide opening 8 of the bearing elements 6 can likewise be designed for holding the shaft 7, so that the bearing elements 6 are both guided and driven by the shaft 7.
Several bearing elements 6 can be provided in a common plane along the circumference of the elastic formed part 3, and these bearing elements 6 can be distributed approximately equally along the circumference of the elastic formed part 3 or concentrated in certain angle sectors. The bearing elements 6 are in turn lined up on the guide and support elements 9, producing a “stack” of bearing elements 6 in the Y-direction that is preferably driven by means of an allocated shaft 7. The bearing elements 6 shown in
The bearing elements 6 in the exemplary embodiment of
Alternatively, a plurality of successive, at least partially circular bearing elements 6 with an inner opening can be provided along the longitudinal axis of the massaging device 1, which, arranged concentrically to the longitudinal axis LA, form the preferably circular inner openings. The elastic formed part 3 is at least partially held in or guided through the circular inner opening formed by the bearing elements 6.
The driving of the bearing elements 6 therefore results from interacting of the shaft 7 with the guide and support elements 9. The bearing elements 6 are movably arranged by means of the guide and support elements 9 guided through the guide holes 8 and mounted immovably relative to the longitudinal axis LA of the massaging device 1 and guided through the inner surfaces of the guide openings 8 so that a displacement can take place only in radial direction relative to the longitudinal axis LA of the massaging device 1, each bearing element 6 is therefore movable nearly independent of the adjacent bearing elements 6 above and below, namely preferably in a plane extending perpendicular to the longitudinal axis LA of the massaging device 1.
To produce the desired massaging movement the bearing surface 5 of the bearing element 6 bearing against the shaft 7 can have different forms or surface characteristics. Also, the shaft 7 can have different cross sectional forms, for example oval, round or polygonal. In case of use of the guide opening 8 for driving the bearing element 6, the opening can likewise have different forms, for example round, oval or oblong.
In the embodiment depicted in
For driving the bearing elements 6, shafts 7 of a wide variety of forms can be used, for example, preferably with at least one eccentric section 7.1, in particular shafts such as those depicted in
Depending on the design of the shaft 7 in interaction with the above described embodiment of the guide openings 8 and of the surface sections coming into contact with the shaft 7, a displacement of the respective bearing element 6 occurs in the plane extending perpendicular to the longitudinal axis LA of the massaging device 1 and therefore in the overall view of the massaging device 1 a preferably sinus wave shaped stroke movement of the bearing elements 6 progressing along the longitudinal axis LA. These different stroke movements of the plurality of the support surfaces 5 of the bearing elements 6 are converted into an oscillating radial deformation of the massaging recess 2 or of the elastic formed part 3.
Alternatively, the shaft 7 can be designed with a deviating form, namely at least over a partial length parallel or approximately parallel to the longitudinal axis LA of the shaft 7, at least over a partial length of the shaft 7 diagonal to the longitudinal axis LW of the shaft 7. Also, the at least one eccentric section 7.1 of the shaft 7 can be formed by one edge of the shaft 7.
In an alternative embodiment according to
In the exemplary embodiment shown here, shafts 7 such as those shown in
Alternatively, ball-shaped, disk-shaped or otherwise shaped bearing elements 6 provided with a drive opening can be lined up on the shaft 7 at least along a partial area of the shaft 7 for increasing the stimulating effect. The cross section of the massaging recess 2 at least partially described by the outer surface of the shafts 7 or of the bearing elements 6 lined up on the shafts 7 or the elastic formed part 3 interacting with the outer surface of the shafts 7 or of the bearing elements 6 lined up on the shafts 7 is changed at least sectionwise along the longitudinal axis LA upon applying a rotary motion to the shafts 7.
Depending on the rotary angle of the shafts 7 oriented along the circumference preferably at regular angle intervals, a periodic enlargement or reduction of the diameter of the elongated massaging recess 2 or an enlargement or contraction of the elastic formed part 3 or of its wall 3′ is achieved. This produces an oscillating stroke movement progressing along the longitudinal axis LA of the massaging device 1, preferably a wavelike deformation of the massaging recess 2 or of the elastic formed part 3.
In this embodiment, the desired massaging effect can be selected by the number of the shafts 7 used along the circumference of the sleeve 3, the form or design of the eccentric sections 7.1 and of the cross sectional form of the shafts 7. Also, the massaging effect can be modified or increased by varying the rotary speed or the rotary direction of the shafts 7. In particular, the shafts 7 distributed along the circumference of the massaging recess 2 can be actuated so that the deformation produced by a shaft 7 is out of phase with the deformation produced by the adjacent shaft 7.
Alternatively to the embodiment of the shafts 7 shown in
In particular, the at least one eccentric section 7.1 can extend parallel, approximately parallel or diagonally to the longitudinal axis LW of the shaft 7 at least over a partial length of the at least one shaft 7. Also, the at least one eccentric section 7.1 can be formed by one edge of the at least one shaft.
The invention was described above based on several exemplary embodiments. It goes without saying that numerous modifications and variations are possible without abandoning the underlying inventive idea upon which the invention is based.
Number | Date | Country | Kind |
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10 2008 059 460 | Nov 2008 | DE | national |
10 2009 051 639 | Nov 2009 | DE | national |
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