A pipe conditioning tool comprising a drive unit to move the tool along a pipe and a work head rotatable about an axis of the pipe to condition a surface of the pipe, the drive unit includes a frame extending to opposite sides of the pipe, the frame having legs extending radially beyond the work head to provide support for the tool upon removal from said pipe.

A sealant-applicator tip (100) comprises a body (102), having a plane of symmetry (104) and comprising an inlet opening (106). The sealant-applicator tip (100) also comprises a head (108), extending from the body (102) opposite the inlet opening (106). The head (108) comprising a first planar face (110), comprising a first linear edge (112), a second planar face (114), comprising a second linear edge (116), a third face (118), comprising a third edge (120), a fourth face (122), comprising a fourth edge (124), a fifth edge (126), a sixth edge (128), a seventh edge (130), and an outlet opening (134), formed in the third face (118) and in communication with the inlet opening (106) of the body (102). The sealant-applicator tip (100) further comprises a channel (140), extending from the inlet opening (106) to the outlet opening (134).

A fabrication assembly comprises an apparatus that receives a composite substrate and a glass substrate having a surface with a release coating layer. A resin layer is deposited between the composite and glass substrates such that a first portion of the resin layer is positioned adjacent to a surface of the composite substrate and a second portion of the resin layer is positioned adjacent to the surface with the release coating layer to prevent aperture(s) from forming. A curing of the resin layer is conducted using electromagnetic radiation. A post-processing chamber receives the resin layer positioned between the composite substrate and the glass substrate and conducts another curing of the resin layer. The resin layer and the composite substrate are released from the glass substrate. Another deposition apparatus receives the resin layer and the composite substrate. A metallic coating is deposited to form a composite mirror object.

A fabrication assembly comprises an apparatus that receives a composite substrate and a glass substrate having a surface with a release coating layer. A resin layer is deposited between the composite and glass substrates such that a first portion of the resin layer is positioned adjacent to a surface of the composite substrate and a second portion of the resin layer is positioned adjacent to the surface with the release coating layer to prevent aperture(s) from forming. A curing of the resin layer is conducted using electromagnetic radiation. A post-processing chamber receives the resin layer positioned between the composite substrate and the glass substrate and conducts another curing of the resin layer. The resin layer and the composite substrate are released from the glass substrate. Another deposition apparatus receives the resin layer and the composite substrate. A metallic coating is deposited to form a composite mirror object.

A fabrication assembly comprises an apparatus that receives a composite substrate and a glass substrate having a surface with a release coating layer. A resin layer is deposited between the composite and glass substrates such that a first portion of the resin layer is positioned adjacent to a surface of the composite substrate and a second portion of the resin layer is positioned adjacent to the surface with the release coating layer to prevent aperture(s) from forming. A curing of the resin layer is conducted using electromagnetic radiation. A post-processing chamber receives the resin layer positioned between the composite substrate and the glass substrate and conducts another curing of the resin layer. The resin layer and the composite substrate are released from the glass substrate. Another deposition apparatus receives the resin layer and the composite substrate. A metallic coating is deposited to form a composite mirror object.

A fabrication assembly comprises an apparatus that receives a composite substrate and a glass substrate having a surface with a release coating layer. A resin layer is deposited between the composite and glass substrates such that a first portion of the resin layer is positioned adjacent to a surface of the composite substrate and a second portion of the resin layer is positioned adjacent to the surface with the release coating layer to prevent aperture(s) from forming. A curing of the resin layer is conducted using electromagnetic radiation. A post-processing chamber receives the resin layer positioned between the composite substrate and the glass substrate and conducts another curing of the resin layer. The resin layer and the composite substrate are released from the glass substrate. Another deposition apparatus receives the resin layer and the composite substrate. A metallic coating is deposited to form a composite mirror object.

A brush (400) for delivering a glutinous substance (168) to a workpiece (170) from an end-effector (102) is disclosed. The brush (400) comprises a body (402), having a rotational axis (438). The brush (400) also comprises a shaft (404), coupled to the body (402) and coaxial with the rotational axis (438). Additionally, the brush (400) comprises a tube (430), having a first end (411) and a second end (412), opposite the first end (411). The tube (430) comprises a first channel (408), coaxial with the rotational axis (438) and having an inlet (409) and an outlet (480). Furthermore, the tube (430) extends from the body (402) in a first direction (A) along the rotational axis (438), to the second end (412). The brush (400) further comprises bristles (420) that surround a portion of the tube (430), wherein the bristles (420) extend from the body (402) in the first direction (A).

A brush (400) for delivering a glutinous substance (168) to a workpiece (170) from an end-effector (102) is disclosed. The brush (400) comprises a body (402), having a rotational axis (438). The brush (400) also comprises a shaft (404), coupled to the body (402) and coaxial with the rotational axis (438). Additionally, the brush (400) comprises a tube (430), having a first end (411) and a second end (412), opposite the first end (411). The tube (430) comprises a first channel (408), coaxial with the rotational axis (438) and having an inlet (409) and an outlet (480). Furthermore, the tube (430) extends from the body (402) in a first direction (A) along the rotational axis (438), to the second end (412). The brush (400) further comprises bristles (420) that surround a portion of the tube (430), wherein the bristles (420) extend from the body (402) in the first direction (A).

The grill grate-oiling device includes a main body, an applicator, and a valve. The grill grate-oiling device may be operable to apply oil to grates of a grill in order to prevent food from sticking to the grates. The grill grate-oiling device may be spill resistant if tipped or knocked over. The oil may be held within the main body and may flow from the main body into the applicator. Responsive to the main body being pressed downward, the valve may open to allow the oil to flow to an applicator pad located on the bottom of the applicator. The oil may be applied to the grates by rubbing the applicator pad over the grates.

The grill grate-oiling device includes a main body, an applicator, and a valve. The grill grate-oiling device may be operable to apply oil to grates of a grill in order to prevent food from sticking to the grates. The grill grate-oiling device may be spill resistant if tipped or knocked over. The oil may be held within the main body and may flow from the main body into the applicator. Responsive to the main body being pressed downward, the valve may open to allow the oil to flow to an applicator pad located on the bottom of the applicator. The oil may be applied to the grates by rubbing the applicator pad over the grates.