The present disclosure relates to sexual aid devices and, more particularly relates, to the massagers for engaging and sexually stimulating the human body, particularly the female genitals.
Sexual stimulating massage is used to develop and enhance sexual arousal in the human body. A sexual stimulator creates sexual stimulation by engaging the stimulator in sensitive erogenous zones of the human body for sexual pleasure. For instance, the sexual stimulator can be used for creating sexual pleasure in various body parts such as the vulva, clitoris, vagina, and the like.
A variety of sexual stimulation massagers such as sex toys, adult toys, dildos, etc., are available in the market for performing a variety of functions, ranging from medical therapy to erotic stimulation. The stimulating massagers are designed to provide massaging effects through several operations like vibration, expansion and contraction, suction, etc. However, the movement of these sexual stimulation massagers is fairly limited. Also, the currently available stimulating massagers are not designed specifically to accommodate the physiologies of different kinds of users while stimulating more than one area of the body simultaneously and providing independent user control of the stimulation. Also, it is noted that the conventional stimulating massagers have a short service life and need to be replaced after a relatively short time due to the design of the movement mechanisms.
Therefore, there exists a need for a sexual stimulation massage apparatus with an improved mechanism of movement to enhance sexual arousal on the user's body.
Various embodiments of the present disclosure provide a sexual stimulation massage apparatus for providing sexual stimulation and enhancing sexual arousal on the user's body.
In an embodiment, a sexual stimulation massager is disclosed. The sexual stimulation massage apparatus includes a body. A reciprocating motion structure is disposed within the body. The reciprocating motion structure includes a rotational structure and a linear motion structure mechanically coupled with each other. A motor including a rotating shaft is mechanically coupled with the rotational structure to rotate the rotational structure. The reciprocating motion structure imparts a reciprocating motion to the linear motion structure. A stimulating structure is operatively coupled with the linear motion structure. The stimulating structure is configured to contact a human body and provide sexual stimulation to the human body based on the reciprocating motion of the linear motion structure. A power source is configured to provide electric power to the motor for rotating the rotating shaft. A controller is configured to control the operation of the motor.
The following detailed description of illustrative embodiments is better understood when read in conjunction with the appended drawings. To illustrate the present disclosure, exemplary constructions of the disclosure are shown in the drawings. However, the present disclosure is not limited to a specific device, or a tool and instrumentalities disclosed herein. Moreover, those in the art will understand that the drawings are not to scale.
The drawings referred to in this description are not to be understood as being drawn to scale except if specifically noted, and such drawings are only exemplary in nature.
In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure. It will be apparent, however, to one skilled in the art that the present disclosure can be practiced without these specific details. Descriptions of well-known components and processing techniques are omitted so as to not unnecessarily obscure the embodiments herein. The examples used herein are intended merely to facilitate an understanding of ways in which the embodiments herein may be practiced and to further enable those of skill in the art to practice the embodiments herein. Accordingly, the examples should not be construed as limiting the scope of the embodiments herein.
Reference in this specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present disclosure. The appearances of the phrase “in an embodiment” in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Moreover, various features are described which may be exhibited by some embodiments and not by others. Similarly, various requirements are described which may be requirements for some embodiments but not for other embodiments.
Moreover, although the following description contains many specifics for the purposes of illustration, anyone skilled in the art will appreciate that many variations and/or alterations to said details are within the scope of the present disclosure. Similarly, although many of the features of the present disclosure are described in terms of each other, or in conjunction with each other, one skilled in the art will appreciate that many of these features can be provided independently of other features. Accordingly, this description of the present disclosure is set forth without any loss of generality to, and without imposing limitations upon, the present disclosure.
Various examples of the present disclosure provide sexual stimulation massage apparatus. In an embodiment, a sexual stimulation massage apparatus includes a main body. The body includes a reciprocating motion structure configured to provide movement to a stimulating structure. The reciprocating motion structure includes a rotational structure and a linear motion structure. The rotational structure is rotated by a rotating shaft of a motor. The motor is configured to receive electric power from a power source to rotate the rotational structure. The rotational structure converts rotational motion into reciprocating motion of the linear motion structure. The linear motion structure includes a moving rod configured to reciprocate within a limiting structure. The limiting structure guides the moving rod to reciprocate in a specified direction. The stimulating structure may be integrated, coupled, or be in intermittent contact with the moving rod. In one form, when the stimulating structure is not physically coupled with the moving rod, an impact occurs due to the reciprocation of the moving rod into the stimulating structure. In another form, when the stimulating structure is physically coupled with the moving rod of the linear motion structure, both the moving rod and the stimulating structure get reciprocated. The movement of a part of the stimulating structure may be used on one or more areas of the user's body such as vulva, clitoris, vagina, and the like.
In one embodiment, the stimulating structure includes at least one of stimulation massager, a vibrator, a heater, a bellow, and a suction cup. Introducing these stimulating components within the stimulating structure may cause sexual stimulation to the vagina and clitoris of the female body. The stimulation effect includes, but is not limited to, a thrusting stimulation, a vibration stimulation, a temperature stimulation, a rotation stimulation, a sucking stimulation, an expansion and contraction stimulation, a telescopic stimulation, and an impact stimulation. A controller controls the rotational speed of the motor by controlling the power supplied to the motor. The electric power is supplied to the motor through a power source. The power source may be an electrical connection or a battery. The controller controls the rotational speed of the motor based on the input provided by the user. The input is provided through a knob positioned on the body or through a wireless connection. The stimulating structure also includes a sensing element enabled to measure at least one of a pressure parameter, a temperature parameter, and a humidity parameter of the user's body part to be stimulated. Based on the acquired data from the sensing element, the data is sent to the controller. Based on a predefined program, the controller adjusts the operational parameter of the stimulating structure. With respect to the speed of the rotation of the motor having a rotating shaft, the frequency of reciprocation of the stimulator changes. For example, in one predefined program, the reciprocation frequency of the reciprocating motion structure may operate in the range of 1000 to 3000 cycles/min. Further, based on the mechanism of the reciprocating motion structure, the stroke of the moving rod is varied, which provides a sexual sensation to the user.
Various example embodiments of the present disclosure are described hereinafter with reference to
The massage apparatus 100 includes a body 102 and a stimulating structure 104. The body 102 is configured to accommodate at least a grip structure 106 and a reciprocating motion structure 108. The reciprocating motion structure 108 includes a rotational structure 110 and a linear motion structure 112. The body 102 acts as a housing to cover one or more components incorporated therein. The body 102 is constructed in a manner to be split at least into two parts. The split parts
The outer surface of the grip structure 106 may be constructed to form a gripper for holding the body 102 tightly while performing sexual stimulation. The grip structure 106 may be formed with grooves, textures, cross patterns, or a combination thereof to provide a frictional effect to the user's palm during holding. The gripped surface assists in transmitting the force applied by the user and eliminating the chances of slippage from the user's palm.
The stimulating structure 104 is operatively coupled with the body 102 by means of a suitable temporary joint. As shown in the illustrated representation of
The attachment and detachment capability of the stimulating structure 104 with the body 102 provides ease in the cleaning of the stimulating structure 104. The cleaning of the stimulating structure 104 assists in maintaining the hygiene level of the massage apparatus 100. The stimulating structure 104 is replaceable and different kinds of stimulating structure 104 may be attached with the reciprocating motion structure 108 of the body 102 as per the need of the user. The stimulating structure 104 may be configured in a variety of shapes and configurations to accommodate massagers of different sizes and lengths. The stimulating structure 104 may satisfy the functionality that includes a stimulator extension length, a stimulator expansion and contraction, a stimulator vibration, a stimulator temperature sensation, and the like. The body 102 may be in continuous contact or in intermittent contact with the stimulating structure 104 which will be discussed further in detail.
In a non-limiting configuration, the grip structure 106, the reciprocating motion structure 108, and the stimulating structure 104 have the same longitudinal axes. However, it should be noted that the present disclosure is not limited to this orientation and these components may be configured or coupled with each other in a different manner as per the feasibility and requirement. For instance, the orientation of the grip structure 106 and the reciprocating motion structure 108 with respect to the stimulating structure 104 may be different. Based on the coupling mechanism between the grip structure 106 and the reciprocating motion structure 108, the angle of orientation between these two can be changed. The grip structure 106 may be coupled orthogonally or obliquely with the reciprocating motion structure 108 using a suitable coupling mechanism.
The motor 206, disposed within the body 102, is compact in design and serves the purpose of converting electrical energy into mechanical motion (
In an embodiment, the rotational structure 110 is positioned on the rotating shaft 210 of the motor 206. A rotational motion of the rotational structure 110 imparts a reciprocating motion to the linear motion structure 112 because of their coupling. It should be noted that the reciprocating motion of the linear motion structure 112 engages the stimulating structure 104 depending upon the operable coupling of the linear motion structure 112 and the stimulating structure 104. In one form, the rotating shaft 210 is mounted on a bearing disposed at least at each end of the rotating shaft 210. Each of the bearings is integrated with a pedestal assembled to the inner surface of the body 102. The pedestal includes a bearing housing for accommodating the bearing configured to support the rotating shaft 210. The bearing used for supporting the rotating shaft 210 may be one of a roller bearing, a ball bearing, a journal bearing, or a magnetic bearing. The bearing is configured to support the load of the rotating shaft 210 and the rotational structure 110. Also, the bearing is designed to eliminate friction and vibration generated during the operation of the rotating shaft 210.
In another embodiment, the rotational structure 110 is mounted on a driven shaft (not shown in FIGS.). In this configuration, the rotating shaft 210 of the motor 206 (
The rotational structure 110 includes a cam (shown in
The linear motion structure 112 includes the moving rod 214 configured to reciprocate through a limiting structure 216. The moving rod 214 is made up of a cylindrical shape which is easier to fabricate. In another configuration, the moving rod 214 may be constructed to form a shape of a stimulating member. The limiting structure 216 is fixed within the inner surface of the body 102 through a suitable fastener and oriented along a sliding direction of the moving rod 214. The moving rod 214 slides within the limiting structure 216 in a linear direction. Therefore, an inner profile of the limiting structure 216 is identical to that of the moving rod 214.
A sliding motion between the moving rod 214 and the limiting structure 216 takes place with a minimum loss in energy that is consumed to overcome sliding friction and stickiness of mating surfaces. In one configuration, a clearance fit is provided in between the moving rod 214 and the limiting structure 216 for ease of sliding. Further, an outer surface of the moving rod 214 may be formed with a layer of material (
The stimulating structure 104 is operatively coupled with the moving rod 214 of the linear motion structure 112. The stimulating structure 104 is configured to contact a human body and provide sexual stimulation based on the reciprocating motion of the moving rod 214. As shown in
The stimulating structure 104 may include a stimulating member (
Further, the stimulating structure 104 includes conductive contacts 224. The conductive contacts 224 are configured to receive the electric power from a contact base 226 formed or integrated at the proximal end 218 of the moving rod 214. The contact base 226 is electrically connected to the power source 202. Using this arrangement, one or more components of the stimulating structure 104 are operated by receiving electric power from the power source 202. As the power source 202 is coupled with the controller 204, the amount of electric power required to operate the components of the stimulating structure 104 is adjusted by the controller 204.
Moreover, the stimulating structure 104 includes a sensing element 228. The sensing element 228 is configured to detect the preset parameters of the stimulating structure 104 that is in contact with the human body. The preset parameters include at least one of a pressure parameter, a temperature parameter, and a humidity parameter. In an example, the pressure of the area of the human body, to be stimulated, is measured using a suitable pressure sensor. The temperature of the area of the human body to be stimulated may be measured using a thermocouple. The humidity
In another configuration, the stimulating structure 104 may be integrated with the moving rod 214 and is configured to contact the human body and provide sexual stimulation. The stimulation effect that creates sensational pleasure on the user's body depends at least upon the change in displacement (
In yet another configuration, the proximal end 218 of the moving rod 214 may be designed to form a shape of the sexual stimulator (
The cam 302 may be constructed to form a circular or non-circular shape. The geometrical profile of the cam 302 is chosen based on maintaining the eccentricity between a central axis of the rotating shaft 210 and a central axis of the cam 302. For example, the cam 302 profile is non-circular when the central axis of the rotating shaft 210 coincides with the central axis of the cam 302. Furthermore, the shape of the cam 302 acts as a balance weight to counter the rotating mass of the connection link 212. It is noted that the forces exerted by the rotating mass (
As shown in the illustrated embodiment of
In another embodiment, multiple connection links, such as the connection link 212, may be used to transfer mechanical power from the cam 302 to the moving rod 214 utilized to operate the stimulating structure 104 in a specified direction. The number of connection links required to drive the reciprocating motion structure 108 depends upon the stroke length 222 of the moving rod 214
The communication module 404 may include a communication circuitry having a transceiver circuitry that further includes an antenna and other communication media interfaces to connect with other devices like smartphones, computers, etc. The communication circuitry may, in at least some example embodiments, enable the reception of temperature data from a thermocouple of the sensing element 228 integrated within stimulating structure 104 that makes physical contact with the user's body part where stimulation is desired.
The input/output module 408 may include a mechanism that receives an input signal and provides an output signal to an operator of the controller 204. To that effect, the input/output module 408 may include one or more input interfaces and/or one or more output interfaces. The storage module 410 is any computer-operated hardware that is suitable for storing and/or retrieving data. The various components of the controller 204, such as the processor 402, the memory 406, the communication module 404, the input/output module 408, and the storage module 410 are configured to communicate with each other through a centralized circuit system 412.
Furthermore, a set of electrical switches may be installed around the body 102 for operating and controlling the working of the massage apparatus 100. The switches are electrically connected to the controller 204 which adjusts the rotational speed of the motor 206 as per the user's desire for sexual stimulation. In one configuration, a knob may be provided to regulate the speed of the motor 206. In addition, a LED (light emitting diode) light may be provided on the body, where the LED is operated by the controller 204 to notify the user about the power source 202. Other than this, knobs are provided on the body 102 for the user to adjust the vibration intensity of the vibrator, operating temperature of the heater, expansion and contraction rate of the bellow, and suction pressure of the suction cup. Each knob is electrically connected to the controller 204 such that the electric power supplied to these components of the stimulating structure 104 can be adjusted using knobs. The knobs and switches may be operated manually by the user or automatically using a suitable communication device. The communication devices such as a smartphone, a notebook, a desktop computer, etc., are communicably coupled to the controller 204. In one configuration, a Wi-Fi device may be used to connect the smartphone with the controller 204 to adjust the operating parameters of the stimulating structure 104.
The stroke length 222 of the moving rod 214 along a longitudinal axis 516 is dependent upon the position of the connection groove 508 at which connection point 506 of the eccentric cam 502 is secured. In one example, when the connection point 506 is secured at an end portion of the connection groove 508, the stroke length 222 of the moving rod 214 is maximum. In contrast, when the connection point 506 is secured at the start portion of the connection groove 508, the stroke length 222 of the moving rod 214 is minimum. Based on this configuration, the stroke length 222 of the moving rod 214 during reciprocating movement 314 can be varied for effective sexual stimulation.
In another scenario, when the link 608 is coupled at the intermediate position of the crank 602, the distance traveled by the moving rod 214 is constrained by a certain length. Specifically, the distance between the intermediate position and the end of the crank 602 is the constraint of the movement of the moving rod 214. Further, when the crank 602 rotates from one end to another along longitudinal axis 612, the minimum distance is traveled by the moving rod 214. Therefore, based on different configurations of the crank 602 mechanism, the stroke length 222 of the moving rod 214 can be altered. Due to this configuration, different kinds of stimulation effects can be generated.
In an embodiment, one of a disc cam, a concave cam, a convex cam, and a wedge cam may be used to provide reciprocating movement 314 to the moving rod 214 at variable frequency. It is noted that the traveling displacement, velocity, and acceleration of the moving rod 214 depend upon the geometrical profile of the cam 704. In the present configuration, the moving rod 214 remains motionless for about half of the cycle of the cam 704 where the cam profile is circular, and in the second half, it rises and falls. The rotating shaft 210 of the motor 206 rotates the cam 704. When the rotating shaft 210 rotates, the cam 704 creates lateral movement of the bump 706. Movement of the bump 706 creates movement of the moving rod 214.
The wheel 702 is fabricated with cam 704 may be positioned on the rotating shaft 210 using a suitable temporary joint. In an example, a key joint may be used to couple the wheel 702 with the rotating shaft 210. Both the rotating shaft 210 and the wheel 702 are fabricated with a keyway and a key seat to accommodate and fit the key. The key joint between the wheel 702 and the rotating shaft 210 eliminates the chances of relative motion that occurs during operation. In other words, the rotational speed of the rotating shaft 210 is the same as that of the wheel 702. In another example, an interference fit may be used to couple the wheel 702 with the rotating shaft 210. The interference fit between the wheel 702 and the rotating shaft 210 eliminates the chances of relative motion.
The bump 706 is used to transmit the rotary motion in the pre-specified direction 304 of the wheel 702 formed with the cam 704 into the reciprocating motion of the moving rod 214 coupled with the stimulating structure 104. The reciprocating movement 314 of the moving rod 214 moves the stimulating structure 104 at the same velocity. The stroke length 222 of the moving rod 214 depends upon the profile of the cam 704 formed on the wheel 702 and the eccentric distance provided between the axis of rotation of the rotating shaft 210 and the axis of the cam 704. The bump 706 may be integrated or coupled with the moving rod 214. A roller-type bump 706 is mounted on an axle 710 positioned at one end of the bar 708. The other end of the bar 708 is mechanically coupled with the distal end 220 of the moving rod 214. The force acquired while rotating the cam 704 is transmitted to the bump 706. Further, the force is transferred from the bump 706 to the moving rod 214 through the bar 708. In another configuration, one of a knife-edge bump, a flat-faced bump, and a spherical-faced bump profile may be used for creating surface contact with the cam 704.
In one embodiment, the center of the cam 704 and the line of action of the bump 706 are in the same axial line 712. Alternatively, the cam 704 center and the line of action of the bump 706 may be positioned eccentrically with each other. An impact generated by the cam 704 is transferred to the bump 706. The intensity of the impact generated is dependent upon the eccentricity between the center axis of the cam 704 and the axis of the line of action of the hump 706.
The screw rod 802 is configured to rotate in a rotational direction 806 with respect to the pre-specified direction 304 of the rotating shaft 210. The rotational direction 806 of the screw rod 802 is converted into the reciprocating movement 314 of the moving rod 214 through the crescent plate 810 and the slider 808. As shown, the screw rod 802 is cylindrical in shape and formed with a bidirectional thread 812. The bidirectional thread 812 is configured to provide a channel for the movement of the crescent plate 810. The crescent plate 810 is a piece of metal that accommodates at least a portion of the bidirectional thread 812 of the screw rod 802. The geometrical profile of the crescent plate 810 is designed considering a clearance fit between bidirectional thread 812 of the screw rod 802 and the crescent plate 810. The crescent plate 810 easily slides within the bidirectional thread 812 of the screw rod 802 without jamming or sticking the surfaces. The head of the crescent plate 810 is attached to the slider 808 using a pin 814. In other words, the slider 808 is in engagement with the screw rod 802 via the crescent plate 810 that is slidably positioned in the bidirectional thread 812 of the screw rod 802. The slider 808 is provided with a guideway (not shown in FIG) to reciprocate the slider 808 based on the rotational direction 806 of the screw rod 802. In one scenario, the bidirectional thread 812 of the screw rod 802 is a continuous thread and formed as bidirectional. The thread profile may be designed to transmit maximum torque with the least loss. In another scenario, the thread is a continuous thread formed of a left-hand helical groove and a right-hand helical groove connected to one another at either end of the screw rod 802 for providing sliding movement to the slider 808. Alternatively, a spiral thread may be formed on the screw rod 802. The moving rod 214 may be integrated or coupled with the slider 808 to form a single structure for movement of the stimulating structure 104 configured to stimulate the user's body in an effective manner.
In another embodiment, the rotating shaft 210 of the motor 206 may be fabricated with bidirectional thread 812 and eliminating the need for the coupler 804 and the screw rod 802. The bidirectional thread 812 produced on the rotating shaft 210 creates reciprocating movement 314 of the moving rod 214 by means of the slider 808 and the crescent plate 810. The reciprocation frequency of the moving rod 214 used for operating the stimulating structure 104 is directly proportional to the speed of rotation of the rotating shaft 210 of the motor 206 while the rotational speed is controlled by the controller 204 that is used to alter the predetermined extension position of the stimulating massager to accommodate within the stimulating structure 104. In an embodiment, the stimulating structure 104 may integrate or couple with the screw rod 802 that is being coupled with the slider 808 along coaxial direction 816 of the screw rod 802.
Various embodiments of the disclosure, as discussed above, may be practiced with steps and/or operations in a different order, and/or with hardware elements in configurations, which are different from those which are disclosed. Therefore, although the disclosure has been described based upon these exemplary embodiments, it is noted that certain modifications, variations, and alternative constructions may be apparent and well within the scope of the disclosure.
Although various exemplary embodiments of the disclosure are described herein in a language specific to structural features and/or methodological acts, the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as exemplary forms of implementing the claims.
This application is a Continuation of co-pending U.S. patent application Ser. No. 17/968,463, filed on Oct. 18, 2022, the entire contents of which are herein incorporated by reference.
Number | Date | Country | |
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Parent | 17968463 | Oct 2022 | US |
Child | 18385180 | US |