An automatic induction heating pet mat includes a pet mat body, a control switch, a pressure device, a temperature controller, a control chip, and a heating device. The pressure device, the temperature controller, the control chip and the heating device are arranged inside the pet mat body. One end of the control switch is coupled to an external power supply through a power cord, and another end of the control switch is coupled to the control chip through a wire. The control chip is electrically connected to each of the pressure device, the temperature controller, the control chip, and the heating device. The pressure device is a pressure sensor and has a pressure range of 0.5-80 KG.

The disclosed technology includes systems and methods for continuously supplying livestock to a processing plant. The disclosed technology can include an enclosure configured to house livestock. The enclosure can include an enclosure entrance, an enclosure exit, and moveable walls to partition the enclosure into separate pens and automatically direct the livestock from the enclosure entrance toward the enclosure exit. A passageway can be connected to the enclosure exit and include moveable walls to automatically direct the livestock from the enclosure exit toward a processing plant. The moveable walls can be configured to move at a predetermined speed such that the plurality of livestock enter the enclosure as offspring, are reared in the enclosure, and are directed through the enclosure exit into the passageway approximately when the plurality of livestock have reached slaughter weight.

In one or more arrangements, a heating system is provided having one or more heating panels positioned in a housing. The housing has a hollow interior with an open lower end. A first panel is positioned in the open lower end of the housing. The first heating panel includes a heating layer. The heating layer includes a conductive microfilm. A first electrical contact is connected to the conductive microfilm. A second electrical contact is connected to the conductive microfilm. In one or more arrangements, the conductive microfilm includes at least one layer of graphene or nanofiber carbon material. Application of a voltage difference between the first electrical contact and the second electrical contact causes current to flow through the conductive microfilm, thereby generating heat. In one or more arrangements, current which flows through the conductive microfilm causes the conductive microfilm to emit infrared radiation.

A heating mat system is presented for use with livestock. The heating mat system includes a heating layer positioned between an upper support pad and a lower support pad. The heating layer includes a conductive microfilm that has a generally planar shape extending between a front edge, a rear edge, and opposing side edges. In one or more arrangements, the conductive microfilm includes a layer of graphene. In one or more arrangements, the heating mat system has a first electrical contact and a second electrical contact that are connected to the conductive microfilm. When a voltage difference is applied between the first electrical contact and the second electrical contact, current flows through the conductive microfilm, thereby generating heat to the heating mat system and heating livestock positioned on the system.

A farm system comprising a plurality of smart tags which are each configured to be worn by an animal, a transmitter and receiver unit for wireless communication with the smart tag, one control unit which is communicatively connected to the transmitter and receiver unit and a farm unit which can be controlled by the control unit. Each smart tag comprises at least one sensor and is configured for wirelessly transmitting information obtained by one of the sensors to the transmitter and receiver unit, wherein the transmitter and receiver unit is configured for supplying the received information to the control unit and wherein the control unit is configured for processing the received information and, at least on the basis of this processed information, controlling at least a farm unit and/or generating a report signal for indicating to a user of the system that an activity is to be carried out.

A pressure activated recharging cooling platform for cooling an object is provided. The cooling platform comprises a temperature regulation layer, a support layer, and a channeled covering layer. The temperature regulation layer is adapted to hold a composition. The temperature regulation layer has a plurality of angled segments, wherein angled segments within a sealed perimeter of the temperature regulation layer are formed by a top side and a bottom side at a predefined distance, and channels, wherein the channels substantially form sides by contacting the top side with the bottom side at a distance lesser than the predefined distance. The support layer is substantially bonded to the bottom side of the temperature regulation layer and is comprised of material sufficiently pliable to deform and sufficiently rigid to withstand collapse in response to the weight of the object. The channeled covering layer encompasses the support and temperature regulation layers.

A pressure activated recharging cooling platform for cooling an object is provided. The cooling platform comprises a temperature regulation layer, a support layer, and a channeled covering layer. The temperature regulation layer is adapted to hold a composition. The temperature regulation layer has a plurality of angled segments, wherein angled segments within a sealed perimeter of the temperature regulation layer are formed by a top side and a bottom side at a predefined distance, and channels, wherein the channels substantially form sides by contacting the top side with the bottom side at a distance lesser than the predefined distance. The support layer is substantially bonded to the bottom side of the temperature regulation layer and is comprised of material sufficiently pliable to deform and sufficiently rigid to withstand collapse in response to the weight of the object. The channeled covering layer encompasses the support and temperature regulation layers.

A pressure activated recharging cooling platform for cooling an object is provided. The cooling platform comprises a temperature regulation layer, a support layer, and a channeled covering layer. The temperature regulation layer is adapted to hold a composition. The temperature regulation layer has a plurality of angled segments, wherein angled segments within a sealed perimeter of the temperature regulation layer are formed by a top side and a bottom side at a predefined distance, and channels, wherein the channels substantially form sides by contacting the top side with the bottom side at a distance lesser than the predefined distance. The support layer is substantially bonded to the bottom side of the temperature regulation layer and is comprised of material sufficiently pliable to deform and sufficiently rigid to withstand collapse in response to the weight of the object. The channeled covering layer encompasses the support and temperature regulation layers.

Systems and methods that include a metallic panel having an upper surface for contacting an animal and a lower surface, at least one metallic cooling element thermally contacting the lower surface of the metallic panel and having an internal passage therein, and a coolant supply that flows a coolant through the internal passage of the cooling element. Flow of the coolant through the cooling element reduces the temperature of the upper surface of the metallic panel and thereby reduces the body temperature of the animal when the animal is in contact with the metallic panel.

The present animal cooling mat apparatus includes a mat shell, at least one coolant sheet, at least one cushioning pad, and at least one foam pad. The coolant sheet is removably located within the mat shell, with the cushioning pad removably located within the mat shell above the at least one coolant sheet and the insulating pad is located within the mat shell below the at least one coolant sheet. The coolant sheet provides a heat sink to rapidly cool an animal, while the cushioning pad facilitates heat transfer and the insulating pad reduces the amount of ambient heat transferred from the environment. Multiple apparatuses may be combined to accommodate larger animals.