A skin cleanser includes a surface, such as a silicone surface, with at least one textured portion for transmitting vibrational tapping to the skin. The skin cleanser includes at least one oscillating motor for generating the tapping motion to the skin. The textured portion in touch-points or a wave that transmit the tapping motion to skin in contact with the to portions. The touch-points may include thicker and thinner formations of the touch-points to provide firmer or softer vibrations to the skin. The touch-points are within about 0.5 to 2.5 mm in diameter. One configuration includes multiple oscillating motors configured to provide different vibration frequencies at around 50-300 Hertz and operable simultaneously.

A skin cleanser includes a surface, such as a silicone surface, with at least one textured portion for transmitting vibrational tapping to the skin. The skin cleanser includes at least one oscillating motor for generating the tapping motion to the skin. The textured portion in touch-points or a wave that transmit the tapping motion to skin in contact with the to portions. The touch-points may include thicker and thinner formations of the touch-points to provide firmer or softer vibrations to the skin. The touch-points are within about 0.5 to 2.5 mm in diameter. One configuration includes multiple oscillating motors configured to provide different vibration frequencies at around 50-300 Hertz and operable simultaneously.

A method and device for non-abrasively cleansing and exfoliating skin in combination with a cleansing solution. A cylindrical housing comprises a base for engagement with a fluid source and a vacuum source and a skin interface positioned on an end opposing the base and configured to contact and traverse a surface of the skin. The skin interface comprises non-abrasive, or rounded, smooth surfaces for contacting the skin. A combination of variable cleansing fluid delivery to the tip and vacuum pressure removal cleanses and exfoliates skin tissue or debris.

A method and device for non-abrasively cleansing and exfoliating skin in combination with a cleansing solution. A cylindrical housing comprises a base for engagement with a fluid source and a vacuum source and a skin interface positioned on an end opposing the base and configured to contact and traverse a surface of the skin. The skin interface comprises non-abrasive, or rounded, smooth surfaces for contacting the skin. A combination of variable cleansing fluid delivery to the tip and vacuum pressure removal cleanses and exfoliates skin tissue or debris.

Voice-cue based motorized skin treatment system is presented. In an embodiment, a skin treatment device includes: an audible instruction unit including memory configured to store a plurality of audio files associated with a plurality of voice cues, and a processor electrically coupled with the memory. The processor is configured to determine which voice cues of the plurality of voice cues are to be audibly presented to a user based one or more inputs indicative of a skin treatment type. An audio unit electrically is coupled with the audible instruction unit. The audio unit is configured to receive the determined voice cues from the processor and to audibly present the determined voice cues, where the determined voice cues include verbal guidance for operating the skin treatment device.

The present invention provides a handheld multifunctional facial cleansing brush structure, including a housing, a power supply assembly, a control switch, a massage assembly, a thermal conduction assembly, and a silicone sleeve. The power supply assembly, the control switch, the massage assembly, and the thermal conduction assembly are electrically connected to the power supply assembly. The thermal conduction assembly passes through an upper surface of the housing to form a thermal conduction working face. The massage assembly passes through a lower surface of the housing to form a massage working face. The housing is covered by the silicone sleeve. The present invention has a thermal conduction massage function and an LED phototherapy function and is convenient to use. In addition, a surrounding design of massage bumps better fits with the face and provides a more comfortable massage.

The present invention relates to a brush head (10, 10a, 10b, 10c) for use with a body care device (100), comprising a plurality of bristles (22, 22a-22e), a carrier (16) for fixedly carrying the plurality of bristles (22, 22a-22e), and connection means for connecting the carrier (16) to a housing (50) of the body care device (100) defining a first axis (14), so that, when the brush head is connected to the housing (50), the carrier (16) is rotatable about the first axis (14) and pivotable about a second axis (20) perpendicular to the first axis (14) with respect to the housing (50), wherein the carrier (16) comprises a plurality of carrier parts (17), each fixedly carrying a corresponding one of a plurality of bristle groups (26, 28, 30), and wherein at least one of the plurality of carrier parts (17) comprises a shaft defining a third axis (40, 42, 44) about which the corresponding bristle group (26, 28, 30) is rotatable.

The present invention relates to a brush head (10, 10a, 10b, 10c) for use with a body care device (100), comprising a plurality of bristles (22, 22a-22e), a carrier (16) for fixedly carrying the plurality of bristles (22, 22a-22e), and connection means for connecting the carrier (16) to a housing (50) of the body care device (100) defining a first axis (14), so that, when the brush head is connected to the housing (50), the carrier (16) is rotatable about the first axis (14) and pivotable about a second axis (20) perpendicular to the first axis (14) with respect to the housing (50), wherein the carrier (16) comprises a plurality of carrier parts (17), each fixedly carrying a corresponding one of a plurality of bristle groups (26, 28, 30), and wherein at least one of the plurality of carrier parts (17) comprises a shaft defining a third axis (40, 42, 44) about which the corresponding bristle group (26, 28, 30) is rotatable.

Foot washing apparatus including a base, a housing with a first arm extending vertically from the base so as to generally divide an upper surface of the base into a toe area and a heel area, and a second arm having a lower surface extending generally horizontally from the first arm, the lower surface of the second arm overlying the toe area. A soap dispensing assembly includes a receptacle for receiving a pressurized soap can, an activating lever for dispensing soap, a conduit system for carrying dispensed soap from the soap can to brushes carried by the apparatus, and a stabilizing handle extending upwardly form the base. A trigger mechanism is carried by a grip and coupled to the activating lever by a link for moving the activating lever to the activated position.

The present invention is an applicator tip for a hand piece assembly used in dermal abrasion procedures, the applicator tip having a cap shape with a plurality of apertures that form ports communicating with a fluid supply line in the hand piece assembly and a vacuum source to remove the abrading fluid. The fluid is introduced onto the outer abrading surface of the applicator tip through a first central aperture and spreads out along the outer abrading surface when the applicator tip is placed against the patient's skin. Recesses in the outer abrading surface establish pathways for the abrading fluid to move along as the applicator tip is moved over the patient's skin. The fluid emitting from the central port is moved into one of four quadrants defined by recesses in the outer abrading surface, each quadrant serving as a fluid chamber that receives fluid from the central fluid supply port. Each sector shaped chamber includes within its border a C-shaped barrier with its opening facing a dividing sector wall. As the applicator tip forms a seal with the patient's skin, fluid is introduced through the supply port and through the entrance of the chamber, filling each chamber with working fluid as the working fluid flows to and around the C-shaped barrier. Disposed inside each C-shaped barrier is a respective vacuum port that removes the working fluid from each chamber. Fluid from each chamber is vacuumed through its vacuum port after having flowed around a maze-like path, navigating the C-shaped barrier and sector walls in a vortex flow pattern.