A hot stamping machine is provided, including a machine table, a processing platform, a hot stamping device and a license plate conveying device, wherein the hot stamping device includes an upper heating plate, a single-rod cylinder, a carbon ribbon and a carbon ribbon conveying mechanism; two groups of lifting mechanisms are used for driving lifting plates to move in the perpendicular direction, tops of two groups of grabbing devices are connected, and tin grabbing device moving mechanisms are used for driving the grabbing devices to move linearly between the two groups of lifting plates and the processing platform up and down and to the left and the right. Compared with an existing rolling hot stamping machine, the hot stamping machine does not require manual involvement in feeding and discharging, shortens the time for hot stamping one license plate by two-thirds, and has a high hot stamping efficiency.

A tube marking device includes a delivery unit having operating rollers for delivering a tube. A thermal press printing unit includes a first heating device and a press printing roller which are actuated by a first lift cylinder to move vertically. A first transmission printing sheet is mounted to a first rotary disc, carries a plurality of marks thereon, and is moved by an operating unit. Two adjacent marks are continuous to each other or have a spacing therebetween smaller than 50 cm. A control unit is electrically connected to the delivery unit, the thermal press printing unit, the first rotary disc, and the operating unit. The delivery unit and the operating unit respectively move the tube and the first transmission printing sheet. The thermal press printing unit transmissions the plurality of marks of the first transmission printing sheet onto an outer periphery of the tube.

In some examples, a processing machine has at least one cleaning device for cleaning a substrate. The at least one cleaning device and the at least one substrate are able to be arranged in a first and a second cleaning state, and the substrate is arranged at a distance from the at least one cleaning device in the first cleaning state. The substrate is arranged in contact with the at least one cleaning device in the second cleaning state, and the at least one cleaning device and the substrate are arranged so as to be transferable at least from the first cleaning state into the second cleaning state. The at least one cleaning device is arranged to be adjusted from a first cleaning position in the first cleaning state into a second cleaning position in the second cleaning state.

Some examples include a print system including a memory to store instructions and print data of a print job, a processor to execute the instructions in the memory to reference print data of a print job, determine a print parameter of the print job, and transform the print data and the print parameter into a conditioning modifier. The print system includes a print engine to dispense a print substance on a medium based on the print data to generate printed medium, and a conditioner to apply heat and pressure to the printed medium, the conditioner including a pressure roller assembly, and a controller to selectively increase a transport speed the pressure roller assembly based on the conditioning modifier and a position of the printed medium relative to the pressure roller assembly to selectively increase the speed of the printed medium through the conditioner.

A recording device, when recording is performed on a predetermined type target recording medium stored in a storage unit, drives a surface potential adjustment unit so that a surface potential is a positive potential within a predetermined range. By configuring such a recording device, it is possible to suppress adhesion of ink to an ejecting unit, and occurrence of an ink ejection failure can be suppressed.

A recording device, when recording is performed on a predetermined type target recording medium stored in a storage unit, drives a surface potential adjustment unit so that a surface potential is a positive potential within a predetermined range. By configuring such a recording device, it is possible to suppress adhesion of ink to an ejecting unit, and occurrence of an ink ejection failure can be suppressed.

The present invention provides cleaning solutions for removing ink, coating, varnish, adhesive, etc. residue from printing equipment. The cleaning solutions of the present invention comprise one or more solvents, preferably selected from acetoacetates, alcohols, glycol ethers, glycol esters, terpenes, and water, and are preferably free of surfactants. The cleaning solutions of the invention have a relative evaporation time (RET) of less than 60 seconds, and a ratio of the RET to the radius of the sphere of solubility of the resin in the ink to be removed of less than 6.

A machine (100) for surface treatment of a film (202) is disclosed. The machine (100) includes a surface treatment unit (110) for surface treating at least a portion (204) of the film (202). In addition, the machine (100) includes a template (112) arranged between the surface treatment unit (110) and the film (202). The template (112) includes at least one cut-out (126) exposing the portion (204) of the film (202) to the surface treatment unit (110) for performing the surface treatment. Furthermore, the machine is adapted to displace the film (202) relative to the surface treatment unit (110) during the surface treatment of the film (202).

A method and system for printing multiple-color at multiple positions on a golf ball is disclosed herein. A printing station of the system and method is capable of printing as many as twenty different colors in a single cycle. The printing station preferably has a four stamping stations, four curing stations and four reorientation stations.

Certain examples of seals that can move along a slit are disclosed. The seals can comprise a first leaf, a second leaf, and a biasing member to push the first leaf away from the second leaf. Also, apparatus for applying a fluid, and printing systems are described.