A heat press includes a handle portion and a curved heat plate. That handle portion may be configured to be grasped by a user, and the curved heat (i.e., having a curved engagement surface) may be configured to engage a heat-activated design implement to transfer a design of the heat-activated design implement to a curved surface of a workpiece. Also disclosed herein, according to various embodiments, is a heat press stand having a curved floor and a hat form for supporting a workpiece (e.g., a hat) during a heat-activated design transfer using the heat press. Associated methods are also disclosed herein.

A heat press includes a handle portion and a curved heat plate. That handle portion may be configured to be grasped by a user, and the curved heat (i.e., having a curved engagement surface) may be configured to engage a heat-activated design implement to transfer a design of the heat-activated design implement to a curved surface of a workpiece. Also disclosed herein, according to various embodiments, is a heat press stand having a curved floor and a hat form for supporting a workpiece (e.g., a hat) during a heat-activated design transfer using the heat press. Associated methods are also disclosed herein.

The present invention discloses wireless handheld device. The wireless handheld device comprises a device structure and a handle, wherein the device structure is detachably connected to the handle by a magnetic type structure or a clamping type structure; a lithium battery is disposed in the handle; a driving mechanism is disposed in the device structure; wherein the magnetic type structure comprises a slot and a connector, the slot is arranged on a lower surface of the handle and the connector is arranged on an upper surface of the device structure, wherein, a first magnetic structure is disposed in the slot and a second magnetic structure is disposed in the connector; wherein the clamping type structure comprises a slot and a connector, the slot is arranged on a lower surface of the handle and the connector is arranged on an upper surface of the device structure, wherein a lower end of the slot extends inward to form a first clamping block, an upper end of the connector extends outward to form a second clamping block, and the slot and the connector are rotated and connected by the first clamping block and the second clamping block. The present invention has the advantages of small volume, light weight, so that it is easy to carry and occupies less space for storage, making it possible to make the handheld device act as a wireless device.

The present invention discloses wireless handheld device. The wireless handheld device comprises a device structure and a handle, wherein the device structure is detachably connected to the handle by a magnetic type structure or a clamping type structure; a lithium battery is disposed in the handle; a driving mechanism is disposed in the device structure; wherein the magnetic type structure comprises a slot and a connector, the slot is arranged on a lower surface of the handle and the connector is arranged on an upper surface of the device structure, wherein, a first magnetic structure is disposed in the slot and a second magnetic structure is disposed in the connector; wherein the clamping type structure comprises a slot and a connector, the slot is arranged on a lower surface of the handle and the connector is arranged on an upper surface of the device structure, wherein a lower end of the slot extends inward to form a first clamping block, an upper end of the connector extends outward to form a second clamping block, and the slot and the connector are rotated and connected by the first clamping block and the second clamping block. The present invention has the advantages of small volume, light weight, so that it is easy to carry and occupies less space for storage, making it possible to make the handheld device act as a wireless device.

A device for guiding a Flex Extending from an Appliance The present application relates to a device 1 for guiding a flex 8 of a garment care appliance that, during use of the appliance 6, hangs downwardly from said appliance. The device comprises a guide tube 4 having a passage therethrough to slideably receive the flex of the garment care appliance, and an attachment part 5 for attachment of the guide tube to a support such that the guide tube is positioned in proximity to, or below, a height at which the appliance is being used. A lower part of the flex that hangs through and below the guide tube maintains an upper part of the flex, extending between the appliance and the guide tube, substantially straight or taut during movement of the appliance towards and away from the device.

A heat press docking station base (52) comprises a nest portion (75) and one or more legs (58). The nest portion (52) includes a body shell (60, 62) and a perforated floor (54). The body shell (60, 62) includes a lower surface (63). The perforated floor (54) is connected to the body shell (60, 62). The one or more legs (58) extend from a lower surface (63) of the body shell (60, 62).

A heat press includes a handle portion and a curved heat plate. That handle portion may be configured to be grasped by a user, and the curved heat (i.e., having a curved engagement surface) may be configured to engage a heat-activated design implement to transfer a design of the heat-activated design implement to a curved surface of a workpiece. Also disclosed herein, according to various embodiments, is a heat press stand having a curved floor and a hat form for supporting a workpiece (e.g., a hat) during a heat-activated design transfer using the heat press. Associated methods are also disclosed herein.

A heat press includes a handle portion and a curved heat plate. That handle portion may be configured to be grasped by a user, and the curved heat (i.e., having a curved engagement surface) may be configured to engage a heat-activated design implement to transfer a design of the heat-activated design implement to a curved surface of a workpiece. Also disclosed herein, according to various embodiments, is a heat press stand having a curved floor and a hat form for supporting a workpiece (e.g., a hat) during a heat-activated design transfer using the heat press. Associated methods are also disclosed herein.

Disclosed are methods and apparatus for cleaning a substrate, such as a fabric material, involving the application of optical energy to the substrate, typically in the form of a beam of light, where the energy of the beam causes removal of the contaminant from substrate, such as from the fibres of a fabric material. The cleaning may occur via any mechanism, including one or more of, alone or in any combination, ablation, melting, heating or reaction with the substrate or contaminant or agent introduced to aid in the cleaning. The optical energy is typically applied to a selected area of the substrate (e.g., as a beam), and the substrate and beam or optical energy source moved relative to one another so as to clean a larger area of the substrate, either by moving the substrate or the beam, or both. Movement of the beam with respect to the substrate can be attained through a beam scanning mechanism or through movement of the optical source itself.

Disclosed are methods and apparatus for cleaning a substrate, such as a fabric material, involving the application of optical energy to the substrate, typically in the form of a beam of light, where the energy of the beam causes removal of the contaminant from substrate, such as from the fibres of a fabric material. The cleaning may occur via any mechanism, including one or more of, alone or in any combination, ablation, melting, heating or reaction with the substrate or contaminant or agent introduced to aid in the cleaning. The optical energy is typically applied to a selected area of the substrate (e.g., as a beam), and the substrate and beam or optical energy source moved relative to one another so as to clean a larger area of the substrate, either by moving the substrate or the beam, or both. Movement of the beam with respect to the substrate can be attained through a beam scanning mechanism or through movement of the optical source itself.