Abstract: A coater (1) includes: a droplet jet part (4) which ejects droplets of a first solution toward an object to be coated (2) to apply the droplets to the object to be coated (2); and a remoisturizing-drying part (6) which gives a residue of the first solution applied on the object to be coated (2) a solvent capable of dissolving the residue to form an applied body with a second solution containing the residue as a solute, and which dries the formed applied body with the second solution.

Abstract: A method of producing a low-molecular luminous material dispersant having: inserting a coat agent in gas phase and an inner gas into a vacuum atmosphere, wherein the coat agent has a strong affinity for a solvent when the coat agent is in liquid phase; heating and vaporizing a low-molecular luminous material in the vacuum atmosphere so as to obtain a mix gas comprising the low-molecular luminous material and inner gas; cooling the mix gas so as to obtain a coat agent in liquid phase; and recovering the coat agent in liquid phase and adding the coat agent in liquid phase into the solvent so as to obtain the low-molecular luminous material dispersant.

Abstract: An ink jet system according to the present invention is provided with an air bubble removing unit including: an ink jet body having a plurality of ink supply path; a nozzle plate connected to an end of the ink jet body and having a plurality of spaced nozzle holes therein; and a cap configured to cover the nozzle holes formed in the nozzle plate wherein a first ink channel space is formed continuous to the nozzle holes and the plurality of ink supply path, and a second ink channel space is formed between a recess of the cap and a surface of the nozzle plate, so that the second ink channel space and the first ink channel space are continuous through the nozzle holes.

Abstract: The droplet jetting applicator includes an irradiator and a droplet jetting head. The irradiator is configured to irradiate, to a water-repellent film formed on a surface of an application target, a light beam for removing the water-repellent film. The droplet jetting head is configured to jet a droplet to each of multiple hydrophilic regions of the surface of the application target, each of the hydrophilic regions being exposed to the outside in a dot shape by removing the water-repellent film.

Abstract: A data processor 1 converts serial data in an STM-16 to parallel data that is based on eight bytes (64 bits). A transparent information detector 10 detects the position of the data (transparent data) as a candidate for transparent processing in the parallel data and transparent processors 30a through 30e serially connected in five stages converts the transparent data and rearranges the processed data based on the detected information. Thus, the data processor 1 can perform transparent processing easily via a relatively low-speed general-purpose device, by converting high-speed serial data in the STM-16 to every 8-byte parallel data for further processing.

Abstract: The data processor 1 converts the serial data in the STM-16 to parallel data that is based on four bytes (32 bits). The transparence data detector 20 detects the position of the data (transparence data) as a candidate for transparence processing in the parallel data and the transparence data sampling section 30 converts the transparence data based on the detected position and rearranges the processed data in each parallel data block (hereinafter referred to as a block). then, the data arrangement section 40 sequentially inserts empty byte data in each block to the preceding block to rearrange parallel data. Thus, the data processor 1 can perform transparence processing easily via a relatively low-speed general-purpose device.

Abstract: A data processor 1 converts serial data in an STM-16 to parallel data that is based on eight bytes (64 bits) . A transparent information detector 10 detects the position of the data (transparent data) as a candidate for transparent processing in the parallel data and transparent processors 30a through 30e serially connected in five stages converts the transparent data and rearranges the processed data based on the detected information. Thus, the data processor 1 can perform transparent processing easily via a relatively low-speed general-purpose device, by converting high-speed serial data in the STM-16 to every 8-byte parallel data for further processing.

Abstract: The data processor 1 converts the serial data in the STM-16 to parallel data that is based on four bytes (32 bits). The transparence data detector 20 detects the position of the data (transparence data) as a candidate for transparence processing in the parallel data and the transparence data sampling section 30 converts the transparence data based on the detected position and rearranges the processed data in each parallel data block (hereinafter referred to as a block). then, the data arrangement section 40 sequentially inserts empty byte data in each block to the preceding block to rearrange parallel data. Thus, the data processor 1 can perform transparence processing easily via a relatively low-speed general-purpose device.