A method for detecting an electrical leakage includes acquiring a voltage of a source of the electrical leakage detected by a voltage detector of a shoe when a walking user is wearing the shoe on a wet ground, and acquiring electromagnetic field strength between the source of the electrical leakage and the shoe, by a first induced circuit of the shoe. A distance between the shoe and the source of the electrical leakage is acquired and the voltage and distance sent to a mobile device as representing a danger when the voltage of the source of the electrical leakage is greater than the predetermined voltage.

An antistatic shoe includes an outsole having a conducting portion that is made of a conducting material and an insole that has a conducting portion mad of a conducting material. An antistatic unit is sewn to the conducting portion of the insole from below so as to be located between the outsole and the insole. An upper is mounted on the outsole and the insole. Electric connection between the components allows static electricity from a human body to be transmitted to a resistor in the antistatic unit, so that static electricity that would otherwise accumulate in the human body can be stably removed by the resistor and sent to the ground. This eliminates the risk of a transient electrostatic discharge that may disadvantageously damage adjacent electronic devices or generate sparks.

An antistatic shoe includes an outsole having a conducting portion that is made of a conducting material and an insole that has a conducting portion mad of a conducting material. An antistatic unit is sewn to the conducting portion of the insole from below so as to be located between the outsole and the insole. An upper is mounted on the outsole and the insole. Electric connection between the components allows static electricity from a human body to be transmitted to a resistor in the antistatic unit, so that static electricity that would otherwise accumulate in the human body can be stably removed by the resistor and sent to the ground. This eliminates the risk of a transient electrostatic discharge that may disadvantageously damage adjacent electronic devices or generate sparks.

An antistatic sport device includes a basic body and a basic element placed at the basic body, made of a running surface layer and side edges. At least one of the side edges forms a contacting surface that can be turned towards the terrain. Between a rear surface of the running surface layer and the basic body, a contacting element made of an electrically conductive material is placed at least in sections. The running surface layer is electrically conductively connected to the contacting element via a discharge path and further the contacting element to the contacting surface formed by the at least one side edge. Further, a sport system has antistatic function and a sport clothing system is for such sport system.

An antistatic sport device includes a basic body and a basic element placed at the basic body, made of a running surface layer and side edges. At least one of the side edges forms a contacting surface that can be turned towards the terrain. Between a rear surface of the running surface layer and the basic body, a contacting element made of an electrically conductive material is placed at least in sections. The running surface layer is electrically conductively connected to the contacting element via a discharge path and further the contacting element to the contacting surface formed by the at least one side edge. Further, a sport system has antistatic function and a sport clothing system is for such sport system.

An antistatic shoe with a conductive member includes: a sole made of conductive material; a conductive member having a first conductive portion, a resistor and a second conductive portion; and an insole disposed on the sole. The conductive member is sandwiched between the insole and the sole, and the insole has a conductive portion made of conductive material, wherein the resistor is electrically connected to the first conductive portion and the second conductive portion, the conductive portion is electrically connected to the first conductive portion and disposed in an offset manner to the second conductive portion, and the second conductive portion is electrically connected to the sole. Or, an insulating member made of a non-conductive material is provided between the insole and the conductive member to cover the second conductive portion and the resistor.

An antistatic shoe with a conductive member includes: a sole made of conductive material; a conductive member having a first conductive portion, a resistor and a second conductive portion; and an insole disposed on the sole. The conductive member is sandwiched between the insole and the sole, and the insole has a conductive portion made of conductive material, wherein the resistor is electrically connected to the first conductive portion and the second conductive portion, the conductive portion is electrically connected to the first conductive portion and disposed in an offset manner to the second conductive portion, and the second conductive portion is electrically connected to the sole. Or, an insulating member made of a non-conductive material is provided between the insole and the conductive member to cover the second conductive portion and the resistor.

The present disclosure generally relates to intelligent garments that provide thermal regulation in a variety of environments. The garments may include different layers such as a hydrophobic layer in direct contact with a wearer's skin surface and saturated with an aqueous mixture, a spacer layer, a reflective layer, and an outer hydrophobic layer. The layers of the garment may work together to reduce the metabolic expenditure of the wearer in extreme environmental conditions or during demanding physical activity. A variety of sensors may be displaced throughout the garments so as to enable the collection of data associated with wearers as well as environmental conditions. Wearers may control the thermal balance and other properties of the garments as desired.

A conduit for discharging excess static electricity through the sole of a shoe has a base a compressible central cylinder, a cap coupler, a detachable cap, and a coupler-receiving receptacle. The base, the compressible central cylinder, the cap coupler, and the detachable cap are all composed of compressible conductive materials. This enables the conduit for electrical discharge to be compressed, when a user takes a step. The base is terminally connected to the compressible central core, opposite to the cap coupler. The coupler-receiving receptacle traverses through the detachable cap, and the cap coupler engages into the coupler-receiving receptacle. This enables the detachable cap to function as an endcap that clamps the sole of the shoe between the base and the detachable cap. As a result, the detachable cap comes into contact with the user's foot and discharges static electricity through the compressible central core and the base, into the ground.

A conduit for discharging excess static electricity through the sole of a shoe has a base a compressible central cylinder, a cap coupler, a detachable cap, and a coupler-receiving receptacle. The base, the compressible central cylinder, the cap coupler, and the detachable cap are all composed of compressible conductive materials. This enables the conduit for electrical discharge to be compressed, when a user takes a step. The base is terminally connected to the compressible central core, opposite to the cap coupler. The coupler-receiving receptacle traverses through the detachable cap, and the cap coupler engages into the coupler-receiving receptacle. This enables the detachable cap to function as an endcap that clamps the sole of the shoe between the base and the detachable cap. As a result, the detachable cap comes into contact with the user's foot and discharges static electricity through the compressible central core and the base, into the ground.