A shoe includes an upper portion surrounding an internal space configured to accommodate a foot. The upper portion includes an inner foot outer surface of an inner foot portion, and an air sucking out portion from which air is capable of being sucked out from the internal space to outside of the shoe when a leg of a wearer of the shoe swings is disposed on the inner foot outer surface of the inner foot portion of the upper portion. The air sucking out portion extends in a direction which is slanted by a predetermined first angle with respect to a vertical direction when the shoe is placed on a horizontal plane and is recessed relative to the inner foot outer surface.

Systems and devices are described for creating a more effective mechanical ventilation system for footwear. For example, a mechanical ventilation system can include an air reservoir that is almost as large as the entire shoe under the footwear's foot bed. In some examples, the air reservoir can be connected to an area that includes a foot of a user in the footwear. The air reservoir can be compressed using a movable part that circulates air in the footwear with every step. The movable part can be relatively small, extending into the air reservoir, and able to compress and inflate the air reservoir. Movement of the movable part can cause a large effective compressible area of the air reservoir to release fresh air near the toes of a foot to flush stale air out of the footwear.

Describes are support elements for a sole of a shoe, in particular a sports shoe, a sole and a shoe with such a support element, as well as a method for the manufacture of a support element. As examples, the support element includes a first partial member formed of a first material, and a second partial member formed of a second material. The first partial member is mechanically joined to the second partial member in a connection region, wherein the connection region is configured to allow the first partial member to rotate or slide relative to the second partial member. The first partial member, the second partial member, and the connection region can be co-molded and joined together in a single fabricating step.

Under normal usage condition, wearing any pair of shoes especially for extended amount of time regardless of the type of shoe, makes feet sweaty and uncomfortable which potentially results in an exhausted foot. By circulating air inside a pair of shoes and around one's feet inside such shoe one can have a more hygienic/healthy and a more pleasant experience throughout the day. Exposure to fresh air not only makes feet more relaxed and comfortable it allows for less odor trapped inside such shoes due to less sweating. I have invented a means of ventilating men's, women's, or kids' shoes to remove heat and objectionable odors normally caused by sweating of one's feet inside a pair of shoes being worn, by means of circulating fresh outside air inside such pair of shoes and around one's feet wearing such shoes.

The invention described herein is a self-cleaning footwear system comprising a sole, where a plurality of check valves are located within said sole. The plurality of check valves are preferably configured between an upper sole and a lower sole to allow debris to flow downwards but not upwards. The plurality of check valves preferably further comprise flap assemblies, where a length of flexible material preferably further comprises a semi-circular flap on one end. The flexible material is preferably a rubber-type material. The sole could be attached to normal footwear, as shown in a sandal. Alternately, the sole could be attached to any type of footwear.

Describes are support elements for a sole of a shoe, in particular a sports shoe, a sole and a shoe with such a support element, as well as a method for the manufacture of a support element. As examples, the support element includes a first partial member formed of a first material, and a second partial member formed of a second material. The first partial member is mechanically joined to the second partial member in a connection region, wherein the connection region is configured to allow the first partial member to rotate or slide relative to the second partial member. The first partial member, the second partial member, and the connection region can be co-molded and joined together in a single fabricating step.

The ventilative sole structure includes a sole, a first one-way valve, and a second one-way valve. The sole's heel portion includes a hollow chamber inside and a bottom piece beneath the chamber. The first one-way valve is configured on a circumferential wall of the chamber. The second one-way valve is configured between a tread portion of the sole and the chamber. When a user wears a shoe with the ventilative sole structure, air enters the chamber through the first one-way valve when the user raises his/her feet, and air is released from the chamber through the second one-way valve towards the tread portion when the user treads on the ground and compresses the chamber, thereby enhancing ventilation and removing odor of the shoe.

A rain boot and uniform footwear with an intelligent temperature-controlling air extractor and water-proofing and air-venting functions, includes: a boot upper layer (10), a middle cushion layer (11) and a boot lower layer (12), wherein a miniature air extractor (13) is provided at a position below an instep of the boot bottom layer (12), a magnetic levitation power switch (14), a temperature sensor (15) and a control main board (16) are also provided in the boot bottom layer (12), the temperature sensor (15) being electrically connected to an input end of the control main board (16) and transmitting a temperature sensing signal of the foot to the control main board (16), and an output end of the control main board (16) being electrically connected to the miniature air extractor (13) via the magnetic levitation power switch (14).

Disclosed is a waterproof shoe with an improved ventilation mechanism, designed to circulate air from the outside environment through the shoe in order to provide convective cooling to a wearer's foot. In a desired embodiment, the shoe may incorporate a pump-ventilation mechanism which, coupled with airflow channels incorporated in the upper, acts to establish continuous substantially one-way airflow through the shoe in a heel-to-toe direction while a user walks.

A ventilation apparatus including at least one flexible energy storage device (FESD), a switching unit, a pump, and a fluid diffuser is provided. The FESD flexibly conforms to varying contours of footwear. The FESD positioned at one or more locations of the footwear supplies electrical energy to the pump via the switching unit. The switching unit in communication with the FESD and the pump selectively changes modes of operation of the pump. The pump attached to the footwear pumps fluid into and exhausts fluid from a cavity of the footwear. A feed pipe of the fluid diffuser connected to the pump, within the cavity of the footwear, transfers the fluid pumped from the pump to the cavity of the footwear during a pump mode and transfers the fluid in the cavity of the footwear to an ambient environment external to the footwear during an exhaust mode for ventilating the footwear.