A liftable and adjustable shower device, that includes: an outer tube, an inner tube, an upper fixing seat, and a liftable tube. The outer tube is disposed in the shower device; and the inner tube is disposed in the outer tube. The upper fixing seat is disposed around an upper end of the outer tube. The liftable tube is sleeved around the inner tube, the liftable tube is insertable from an upper end of the upper fixing seat, to sleeve around outside the outer tube.

A liftable and adjustable shower device, that includes: an outer tube, an inner tube, an upper fixing seat, and a liftable tube. The outer tube is disposed in the shower device; and the inner tube is disposed in the outer tube. The upper fixing seat is disposed around an upper end of the outer tube. The liftable tube is sleeved around the inner tube, the liftable tube is insertable from an upper end of the upper fixing seat, to sleeve around outside the outer tube.

A telescopic lance, comprising a lance handle (5) with a fixed inner pipe (3), an extractable outer pipe (4) and at least one locking mechanism (10,20), wherein the extractable outer pipe (4) is located outside, and slidably longitudinally arranged with the fixed inner pipe (3), and said locking mechanism (10,20) is arranged to allow motion of the extractable outer pipe (4) with respect to the fixed inner pipe (3). A first locking mechanism (20) comprises a protrusion (21) for engagement with a locking slot (22), wherein twisting of the extractable outer pipe (4) brings the protrusion (21) into or out of engagement with the locking slot (22), and a second locking mechanism (10) comprises a spring loaded lock handle (13) with a through going aperture (15) for trapping and releasing the extractable outer pipe (4). The invention also relates to a combination of a telescopic lance and a trigger gun (8) for use with a high pressure washer.

A telescopic lance, comprising a lance handle (5) with a fixed inner pipe (3), an extractable outer pipe (4) and at least one locking mechanism (10,20), wherein the extractable outer pipe (4) is located outside, and slidably longitudinally arranged with the fixed inner pipe (3), and said locking mechanism (10,20) is arranged to allow motion of the extractable outer pipe (4) with respect to the fixed inner pipe (3). A first locking mechanism (20) comprises a protrusion (21) for engagement with a locking slot (22), wherein twisting of the extractable outer pipe (4) brings the protrusion (21) into or out of engagement with the locking slot (22), and a second locking mechanism (10) comprises a spring loaded lock handle (13) with a through going aperture (15) for trapping and releasing the extractable outer pipe (4). The invention also relates to a combination of a telescopic lance and a trigger gun (8) for use with a high pressure washer.

A system and method have been shown for the effective implementation of a height and rotational adjustment system for one or more spray guns for use in a line striper.

A system and method have been shown for the effective implementation of a height and rotational adjustment system for one or more spray guns for use in a line striper.

An automatic agricultural machine according to the present invention includes: a fixed base disposed on farmland; a first-direction movement guide part installed on the fixed base so as to be spaced apart from the farmland; a first-direction movement trolley configured to travel on the first-direction movement guide part; and an automatic spraying device configured to travel on a second-direction movement guide part connected to the first-direction movement trolley, wherein traveling control of the first-direction movement trolley and winding control of the second-direction movement guide part are performed on the basis of at least any one of the trigonometric function principle and the Pythagorean theorem.

An automatic agricultural machine according to the present invention includes: a fixed base disposed on farmland; a first-direction movement guide part installed on the fixed base so as to be spaced apart from the farmland; a first-direction movement trolley configured to travel on the first-direction movement guide part; and an automatic spraying device configured to travel on a second-direction movement guide part connected to the first-direction movement trolley, wherein traveling control of the first-direction movement trolley and winding control of the second-direction movement guide part are performed on the basis of at least any one of the trigonometric function principle and the Pythagorean theorem.

A method of controlling application of material onto a substrate includes ejecting atomized droplets from an array of micro-applicators while the array of micro-applicators cyclically moves about at least one axis. The atomized droplets from each of the plurality of micro-applicators overlap with atomized droplets from adjacent micro-applicators and a diffuse overlap of deposited atomized droplets from adjacent micro-applicators is provided on a surface of the substrate. The array of micro-applicators cyclically rotates back and forth around the at least one axis and/or moves back and forth parallel to the at least one axis. For example, the at least one axis can be a central axis of the array of micro-applicators, a length axis of the array of micro-applicators, a width axis of the array of micro-applicators, and the like. Also, the array of micro-applicators can be part of an ultrasonic material applicator used to paint vehicles.

A method of controlling application of material onto a substrate includes ejecting atomized droplets from an array of micro-applicators while the array of micro-applicators cyclically moves about at least one axis. The atomized droplets from each of the plurality of micro-applicators overlap with atomized droplets from adjacent micro-applicators and a diffuse overlap of deposited atomized droplets from adjacent micro-applicators is provided on a surface of the substrate. The array of micro-applicators cyclically rotates back and forth around the at least one axis and/or moves back and forth parallel to the at least one axis. For example, the at least one axis can be a central axis of the array of micro-applicators, a length axis of the array of micro-applicators, a width axis of the array of micro-applicators, and the like. Also, the array of micro-applicators can be part of an ultrasonic material applicator used to paint vehicles.