Abstract: A display device free from a deterioration in luminescence efficiency is provided. In the display device of the present invention, since an inorganic film is formed after concave parts in which luminescence portions are positioned are filled with a filling film, no crack is formed in the inorganic film. Since the inorganic film is made of a material having high gas tightness and heat conductivity (such as, diamond-like carbon or AlN), water and oxygen will hardly penetrate the luminescence portions, and heat of the luminescence portions will be conducted to the inorganic film, so that the luminescence portions do not reach high temperatures. Further, since a gap between first and second panels is filled with a resin film, the atmosphere does not enter from the outside. Because the luminescence portions are free from damage from water, oxygen and heat, the display device of the present invention has a prolonged life.

Abstract: A vapor deposition apparatus capable of forming an organic thin film having a good film quality is provided. In the vapor deposition apparatus of the present invention, a tray is disposed in an evaporation chamber, and a feed device feeds a vapor deposition material onto the tray. The tray is placed on a mass meter, which measures the mass of the vapor deposition material disposed on the tray, and a controller compares the measured value with a reference value in order to make the feed device feed the vapor deposition material in a necessary amount. Since the vapor deposition material is replenished when needed, the vapor deposition material does not run short during the film formation, or a large amount of the vapor deposition material is not heated for a long time. Thus, the vapor deposition material does not change in quality.

Abstract: A technology is provided, which obtains an organic EL device free from any reduction in the luminescent efficiency, even if an electrode layer is formed on a surface of a charge injection layer by a sputtering method. An organic EL device of the present invention includes a first charge injection layer, a first organic layer, and a second charge injection layer. The second charge injection layer is formed as a mixed layer in which a matrix organic material and a charge injectable metallic material are mixed. Even when the electrode layer is formed on a surface of this second charge injection layer by the sputtering method, the luminescent efficiency does not decrease.

Abstract: An inkjet printhead substrate includes: a heat generating element configured to generate energy for ejecting ink; an electric wire electrically connecting the heat generating element and an electrode lead provided on a flexible film wiring substrate; a protecting film configured to protect the electric wire; an electrode pad to which the electrode lead is connected, the electrode pad being formed by providing an opening in the protecting film at a position above the electric wire; a region to which a sealing resin configured to protect an electrically connected portion of the electrode pad and the electrode lead is to be applied; and an ink-detecting electrode composed of a metal wire and formed at the region to which the sealing resin is to be applied. The metal wire has a smaller width than an opening provided in the protecting film from which the metal wire is exposed.

Abstract: An inkjet recording head includes a connection-state output circuit provided on the recording element substrate of a recording head, where the connection-state output circuit externally transmits data of the connection state of each of input signal ends. An output from the connection-state output circuit is activated when the same logic as that used when signals are pulled up and/or pulled down is used.

Abstract: A vapor deposition apparatus is provided, which does not cause changes in composition, decomposition and quality change of an organic vapor deposition material. The organic vapor deposition material is placed on a conveying unit by an amount for a single substrate, and conveyed into a vapor deposition vessel preliminarily heated. Since a small amount of the organic vapor deposition material is heated and exhausted through generation of an organic material vapor under heating condition for each substrate, neither decomposition nor quality change with moisture occurs because heating time is short. Even though different organic compounds are mixed, no change in composition occurs so that an organic vapor deposition material in which a base material is mixed with a coloring substance can be pooled in a pooling tank and then placed in the conveying unit.

Abstract: This thin film-forming apparatus comprises a vacuum chamber 2 for forming a thin film on a target material 5, an evaporation source 3 arranged in the chamber 2 and having an evaporation port 33 through which the vapor of a material 40 to be vapor-deposited passes, and a moving mechanism 20 for moving the source 3 towards the widthwise direction of the port 33 between a prescribed waiting position and film-forming position of the source 3. This apparatus further comprises a film-thickness sensor 50 for detecting a film-forming speed of the material 40, which is arranged in a vicinity of the waiting position of the source 3 and on a side of the material 5. The source 3 is positioned opposite to the sensor 50 at the waiting position and is positioned opposite to the material 5 at the film-forming position.

Abstract: An evaporation source of the present invention has; a storage receptacle for accommodating an evaporation material, a cover member arranged thereabove and provided with a through hole, and a protective plate arranged beneath the through hole, and positioned with a rim portion outside of the periphery of the through hole. The cover member and the protective plate can be heated together. Even if the evaporation material melts and flies out in droplet form or solid particle form, the droplets or solid particles which fly out adhere to at least one of the cover member and the protective plate, and are then heated and vaporized. Therefore, the evaporation material does not fly out to outside the evaporation source in droplet form or solid particle form. Consequently, there is no deterioration in film quality, and the interior of the apparatus is not contaminated with the droplets or solid particles.

Abstract: An inactive gas is introduced into an organic material evaporation source to place a thin organic film material in the organic material evaporation source in an atmosphere having a relatively high pressure, and the temperature of the thin organic film material is increased up to a certain temperature. Then, the organic material evaporation source is evacuated to lower the pressure around the thin organic film material for thereby causing the thin organic film material to emit a vapor. Since no wasteful vapor is emitted from the thin organic film material, the thin organic film material is effectively utilized. Because the inactive gas acts as a heating medium, the temperature of the thin organic film material is increased at a high rate, and the thin organic film material is uniformly heated. When the temperature of the thin organic film material is lowered in an inactive gas atmosphere, it can be lowered at a high rate.

Abstract: An inactive gas is introduced into an organic material evaporation source to place a thin organic film material in the organic material evaporation source in an atmosphere having a relatively high pressure, and the temperature of the thin organic film material is increased up to a certain temperature. Then, the organic material evaporation source is evacuated to lower the pressure around the thin organic film material for thereby causing the thin organic film material to emit a vapor. Since no wasteful vapor is emitted from the thin organic film material, the thin organic film material is effectively utilized. Because the inactive gas acts as a heating medium, the temperature of the thin organic film material is increased at a high rate, and the thin organic film material is uniformly heated. When the temperature of the thin organic film material is lowered in an inactive gas atmosphere, it can be lowered at a high rate.

Abstract: An inactive gas is introduced into an organic material evaporation source to place a thin organic film material in the organic material evaporation source in an atmosphere having a relatively high pressure, and the temperature of the thin organic film material is increased up to a certain temperature. Then, the organic material evaporation source is evacuated to lower the pressure around the thin organic film material for thereby causing the thin organic film material to emit a vapor. Since no wasteful vapor is emitted from the thin organic film material, the thin organic film material is effectively utilized. Because the inactive gas acts as a heating medium, the temperature of the thin organic film material is increased at a high rate, and the thin organic film material is uniformly heated. When the temperature of the thin organic film material is lowered in an inactive gas atmosphere, it can be lowered at a high rate.

Abstract: An inactive gas is introduced into an organic material evaporation source to place a thin organic film material in the organic material evaporation source in an atmosphere having a relatively high pressure, and the temperature of the thin organic film material is increased up to a certain temperature. Then, the organic material evaporation source is evacuated to lower the pressure around the thin organic film material for thereby causing the thin organic film material to emit a vapor. Since no wasteful vapor is emitted from the thin organic film material, the thin organic film material is effectively utilized. Because the inactive gas acts as a heating medium, the temperature of the thin organic film material is increased at a high rate, and the thin organic film material is uniformly heated. When the temperature of the thin organic film material is lowered in an inactive gas atmosphere, it can be lowered at a high rate.

Abstract: An inactive gas is introduced into an organic material evaporation source to place a thin organic film material in the organic material evaporation source in an atmosphere having a relatively high pressure, and the temperature of the thin organic film material is increased up to a certain temperature. Then, the organic material evaporation source is evacuated to lower the pressure around the thin organic film material for thereby causing the thin organic film material to emit a vapor. Since no wasteful vapor is emitted from the thin organic film material, the thin organic film material is effectively utilized. Because the inactive gas acts as a heating medium, the temperature of the thin organic film material is increased at a high rate, and the thin organic film material is uniformly heated. When the temperature of the thin organic film material is lowered in an inactive gas atmosphere, it can be lowered at a high rate.