An insole having a top sheet, a base layer, a forefoot pad, a heel cushion, and stability cradle. The forefoot pad can be made a blown EVA or other material, and the heel cushion can be made of a clear TPR, soft polyurethane or blown EVA. A heel cup surrounds the exterior back by a heel cup, and a heel pod opening and midfoot pod opening is located in the stability cradle for allowing placement of heel pads and midfoot pads in a replacement manner. There is also a soft metatarsal raised dome on the top (foot contact) surface of the insole which would be directly above the metatarsal midfoot area.

An insole having a top sheet, a base layer, a forefoot pad, a heel cushion, and stability cradle. The forefoot pad can be made a blown EVA or other material, and the heel cushion can be made of a clear TPR, soft polyurethane or blown EVA. A heel cup surrounds the exterior back by a heel cup, and a heel pod opening and midfoot pod opening is located in the stability cradle for allowing placement of heel pads and midfoot pads in a replacement manner. There is also a soft metatarsal raised dome on the top (foot contact) surface of the insole which would be directly above the metatarsal midfoot area.

A non-slip removable footwear insert includes an insert member and a non-slip material applied on an upper surface and a lower surface of the insert member. The insert member conforms to and is removably positioned on an inner surface of footwear. The upper surface of the insert member is proximal to a user contact surface, for example, a bottom surface of a user's foot, and distal to the inner surface of the footwear. The lower surface of the insert member is proximal to the inner surface of the footwear and distal to the user contact surface. The non-slip material applied on the upper surface and the lower surface of the insert member provides simultaneous gripping contact between the upper surface of the insert member and the user contact surface, and between the lower surface of the insert member and the inner surface of the footwear.

A non-slip removable footwear insert includes an insert member and a non-slip material applied on an upper surface and a lower surface of the insert member. The insert member conforms to and is removably positioned on an inner surface of footwear. The upper surface of the insert member is proximal to a user contact surface, for example, a bottom surface of a user's foot, and distal to the inner surface of the footwear. The lower surface of the insert member is proximal to the inner surface of the footwear and distal to the user contact surface. The non-slip material applied on the upper surface and the lower surface of the insert member provides simultaneous gripping contact between the upper surface of the insert member and the user contact surface, and between the lower surface of the insert member and the inner surface of the footwear.

An insole which generates an air flow during use, which assists in cooling or warming the foot of a user is disclosed. In a first embodiment, air flow facilitated by said insole provides for convective heat transfer away from the plantar surface of the foot. The insole is intended for insertion into a shoe which is ventilated, preferably an athletic shoe with a ventilated upper. The bottom layer defines a plurality of ridges and a channel lining portion which together define a plurality of air channels. The bottom layer defines a heel recess in which a heel pad is situated. In a second embodiment, an insole which collects, retains, and heats and to a user's foot is disclosed. Said insole further comprises a middle layer of thermal reflective material secured to and coextensive with a top layer and a bottom layer secured to said middle layer.

An insole which generates an air flow during use, which assists in cooling or warming the foot of a user is disclosed. In a first embodiment, air flow facilitated by said insole provides for convective heat transfer away from the plantar surface of the foot. The insole is intended for insertion into a shoe which is ventilated, preferably an athletic shoe with a ventilated upper. The bottom layer defines a plurality of ridges and a channel lining portion which together define a plurality of air channels. The bottom layer defines a heel recess in which a heel pad is situated. In a second embodiment, an insole which collects, retains, and heats and to a user's foot is disclosed. Said insole further comprises a middle layer of thermal reflective material secured to and coextensive with a top layer and a bottom layer secured to said middle layer.

A slip-resistant material is disclosed. According to embodiments of the disclosure, the slip-resistant material can partially conform to the body's contours during physical activity to eliminate, or at least to reduce, slippage. The slip-resistant material can be a coated lightweight, synthetic hexagonal mesh. The slip-resistant material can also be a base wicking fabric with soft nodules formed on it. The slip-resistant material can also be a base wicking fabric with a top layer comprising nodules and pores. The slip-resistant material can also be a combination of a base wicking fabric with a polymer-based thread. The embodiments of the disclosure are safe to be worn directly against skin and are comfortable, breathable, and durable. The embodiments of the disclosure can be used as a liner between an article and the wearer's skin to hold the article in place during movement.

The present disclosure provides a smart insole special for golf, belonging to the technical field of insoles. The smart insole includes a toe portion and a heel portion; inside the toe portion and the heel portion is formed a communicated cavity, the toe portion is formed with a groove, inside which groove is formed a plurality of through holes, the through holes are communicated with the cavity, one end inside the cavity close to the heel portion has a top fixedly connected to a partition block, and the cavity has an area located at a bottom of the heel portion filled with a porous sponge. The present disclosure can be combined with different application scenarios, select different usage modes, and improve the comfort specifically.

A shoe insert assembly includes a panel that is selectively positioned in a shoe. The panel has an opening therein and the opening is aligned with a heel when the shoe is worn thereby facilitating pressure to be relieved from the heel. A cushion is positioned within the panel and the cushion absorbs pressure exerted by a foot onto the shoe thereby enhancing comfort of the shoe. A pad is coupled to the panel and the pad is aligned with an arch in the foot when the shoe is worn thereby enhancing comfort of the shoe.

A convective air pad with weight balancing and massage buffering effect, which includes a pad body (1), convective air chamber (2) integrally and uniformly arranged on a surface side of the pad body (1), wherein the convective air chamber (2) is filled with gas, wherein the convective air chamber (2) includes airbag members (21), a convective channel (22) connected between each two adjacently positioned airbag members (21), and a ventilation gap (23) provided between each two adjacently positioned airbag members (21). Through the convective air chamber (2) on the pad body (1), the load-bearing portion is in direct contact with the convective air chamber (2) to provide a very strong weight reducing and pressure buffering effect, thus effectively reduce the stress from the load to the load-bearing portions. The convective air chamber (2) is formed by a number of interconnecting airbag members (21) so that the pressure can be dispersed effectively by gas movement through the convective channels (22), therefore the load is translated into massage effect on the load-bearing parts through the interconnecting airbag members (21) and hence the fatigue and pain in the load-bearing parts is greatly reduced. Moreover, since ventilation gap is formed between the airbag members (21), the contact area between the load-bearing parts is effectively reduced while a superior ventilation effect is provided, hence the heat is dissipated effectively and timely and the comfort level is increased.