The present application relates to an automatic production equipment for label-free packaging bottles, which belongs to the technical field of packaging bottle production. The equipment comprises a machine frame, wherein a bottle body conveying device and a bottle body labeling device are arranged on the machine frame, wherein the bottle body labeling device comprises a rotating shaft arranged on the machine frame and an driving annular plate coaxially fixed on the rotating shaft, a driving mechanism for driving the rotating shaft to rotate is arranged on the machine frame, a plurality of storage plates are rotatably arranged on a top portion of the driving annular plate, the plurality of storage plates are distributed in a circular array along a circumferential direction of the driving annular plate, at least one self-rotating motor for driving each of the plurality of storage plates to rotate is arranged at a bottom portion of the driving annular plate, a servo annular plate is coaxially fixed on the rotating shaft, pressing assemblies corresponding to the storage plates are arranged on the servo annular plate, a plurality of laser heads for bottle labeling are arranged on the machine frame. The present invention is conducive to meeting the labeling requirements of large breadth and high production capacity for packaging bottles, is conducive to the mass production of the label-free packaging bottles, and is conducive to environmental recycling, energy consumption saving, and production cost reduction.

A computer-implemented method for marking an object on an aligner. The aligner surface is modeled. The method includes calculating a normal for each tile in a tessellated surface and disqualifying a tile from being selected. For tiles not disqualified, a patch is identified that produces a markable area. The method includes selecting an object to be marked, calculating a location of the object in the markable area, and providing the location of the object to a marking device. Disqualifying includes comparing an angle between a normal and an orientation of the beam to an origin of the calculated normal on each tile. Disqualifying includes disqualifying the at least one tile when the angle is outside of a range of 90 to +90. Identifying the patch includes separating the patch into at least two smaller patches, and one of the two smaller patches of tiles is the markable area.

This laser processing device comprises a processing pattern input unit, a two-dimensional display unit, a three-dimensional position display data generation unit for generating three-dimensional position display data compatible with three-dimensional display, a profile information input unit, a three-dimensional display unit, a processing-condition-setting unit for displaying the position of a processing pattern on a surface being processed by using the three-dimensional position display data and setting a processing condition as position information, and a three-dimensional laser processing control data generation unit for generating three-dimensional laser processing control data in accordance with the processing condition. The processing condition is edited after display is carried out such that the processing pattern is replaced with three-dimensional position display data having a smaller data volume by a setting terminal; therefore, it is possible to smoothly edit the processing condition.

A safe, integrated dye sublimation printer apparatus is disclosed. The apparatus is configured to print one or more images. In some embodiments, the apparatus may be incorporated into a fully-enclosed vending machine, equipped with one or more product storage containers, to provide on-demand personalized sublimated products and accessories for a consumer.

A process for laser marking a measuring cup including the steps of: providing a measuring cup; and providing a lasing apparatus having a lens having an optical axis, a field of view, and a working distance; positioning the measuring cup at least partially within the field of view such that a first worked portion of the sidewall is oriented towards the lens, is spaced apart from the optical axis, and the optical axis is oblique or askew of the longitudinal axis; and lasing a dosing indicium into the sidewall.

A printing process for a metal container includes the steps: Heating the metal container, in particular formed as a metal bottle ready for filling, to a pre-treatment temperature lying in an interval between 100 degrees Celsius and 250 degrees Celsius, cooling the metal container to a temperature below 100 degrees Celsius, locally activating a printing zone, formed on an outer surface of the metal container to increase a surface energy of the printing zone and/or locally heating the printing zone to a printing temperature which is in an interval between 30 degrees Celsius and 70 degrees Celsius, printing the printing zone with a printing method.

A non-lethal projectile launcher toy that comprises a full-colour, high DPI, printed aggregate coating on an outer shell (101, 301); the decal coating is not limited to flat surfaces, allowing for substantially unrestricted product design, and is substantially undisturbed visual continuity when crossing part lines between discrete parts that make up the outer shell. Methods of producing the decal-coated toy gun using inkjet printing technology are also provided, allowing for high-detail and comprehensive colour range aggregate coatings that may be programmatically controlled to maximise the visual quality of the applied decal.

A method for safely differentiating a three dimensional object subsequent to its creation and varnish protection by means of applying and sealing a decoration and/or data between the original and a final varnish layers. The three dimensional object may be decorated and/or contain data from its original manufacturing process but it may also be protected by a varnish prior to utilizing this process. The method enables the addition of decoration and data at any time or location subsequent to the original manufacturing process. The process takes place on top of the original varnish and may be subsequently sealed by applying another varnish layer.

A printing system is provided that may include plural stations that load objects to be printed upon into the printing system, print indicia on the objects, cure the indicia printed on the objects, inspect the indicia printed on the objects, re-orient the objects, and/or unload the objects from the printing system. The printing system also may include a conveyance assembly extending between the stations. The conveyance assembly may independently and/or separately move the objects between or among the stations.