Abstract: An image forming apparatus includes a first and second processor. The first processor controls a transport device that transports a sheet and a first image forming section that forms an image on the sheet. The second processor controls a second image forming section that forms an image on the sheet. If an image is to be formed at the second section, the first processor causes the first section to perform image formation preparation and causes the device to transport the sheet upon receiving a notification from the second processor in response to a preparation command transmitted to the second processor for performing image formation preparation in the second section. If an image is not to be formed at the second section, the first processor causes the first section to perform the image formation preparation and the transport device to transport the sheet, without receiving the notification from the second processor.

Abstract: Provided is an intermediate base material (incised prepreg) which has exceptional surface quality and mechanical properties when solidified and with which it is possible to obtain a fiber-reinforced plastic having excellent three-dimensional shape conformance properties. This incised prepreg has, in a prepreg that includes a resin and reinforcing fibers oriented in one direction, incisions substantially parallel to the orientation direction of the reinforcing fibers (the incisions substantially parallel to the orientation direction of the reinforcing fibers are referred to as parallel incisions) and incisions that cut across the reinforcing fibers (the incisions that cut across the reinforcing fibers are referred to as intersecting incisions).

Abstract: A recording medium post-processing device includes a binding unit and a hole forming unit. The binding unit performs a binding process on a recording medium bundle. The hole forming unit performs a hole forming process in a region of recording media that constitute the recording medium bundle including a part of a binding region in which the binding process is performed.

Abstract: To provide a gas filling method in which it is possible to estimate a volume of a tank with high accuracy even when the tank has a small volume. A hydrogen filling system includes a hydrogen station having a pressure accumulator of compressed hydrogen gas, a vehicle having a hydrogen tank, a connection tube system that connects the accumulator and the tank, and a flow rate sensor and a station pressure sensor provided on the connection tube system. A hydrogen gas filling method is a method of filling the tank with the hydrogen gas from the pressure accumulator and includes estimating a volume of the hydrogen tank based on detection values of the flow rate sensor and the station pressure sensor and a volume value of the connection tube system, after a start of filling of the hydrogen tank with the hydrogen gas from the pressure accumulator.

Abstract: A substantially flat-plate-shaped laminated base material has at least a layer-shaped body ? and a layer-shaped body ? are layered or disposed side by side, the layer-shaped body ? having one or more cut prepregs A in which reinforcing fibers oriented in one direction are impregnated with a resin composition, the volume fraction of fiber is 45-65%, and at least a portion of the reinforcing fibers are segmented into a fiber length of 10-300 mm by a plurality of cuts, and the layer-shaped body ? having one or more base materials B in which reinforcing fibers having a fiber length in the range of 10-300 mm are impregnated with a resin composition.

Abstract: Provided is a method for manufacturing a fiber-reinforced plastic composite containing a fiber-reinforced plastic part having a plate-like portion and a rib protruding from one surface of the plate-like portion, and a metal part, having an average thickness of 0.5-3.0 mm, laminated on part of or all of the plate-like portion of the fiber-reinforced plastic part, comprising: a lamination step for stacking a plurality of incised prepreg layers as a plurality of sheets of base material to form a base laminate, each prepreg layer containing unidirectionally oriented fibers and resin, and a plurality of incisions crossing the fibers, a base material heating step for heating the base laminate, and a molding step for integrating the base laminate and the metal part by pressing them between a rib molding member having a recessed portion for forming a rib and a skin molding member free of such a recessed portion in a pressing device.

Abstract: An image forming apparatus includes a first and second processor. The first processor controls a transport device that transports a sheet and a first image forming section that forms an image on the sheet. The second processor controls a second image forming section that forms an image on the sheet. If an image is to be formed at the second section, the first processor causes the first section to perform image formation preparation and causes the device to transport the sheet upon receiving a notification from the second processor in response to a preparation command transmitted to the second processor for performing image formation preparation in the second section. If an image is not to be formed at the second section, the first processor causes the first section to perform the image formation preparation and the transport device to transport the sheet, without receiving the notification from the second processor.

Abstract: An image forming apparatus includes first and second processors. The first processor controls a transport device transporting a sheet and a first image forming section forming an image on the sheet. The second processor controls a second image forming section forming an image on the sheet. If an image is to be formed at the second section, the first processor transmits, to the second processor, a preparation command. Then upon receipt and completed preparation in the second section, the second processor transmits a completion notification to the first processor. Then, the first processor causes the first section to perform image formation preparation and causes the transport device to transport the sheet if an image is to be formed at the first section, or causes the transport device to transport the sheet without causing the first section to perform the preparation if an image is not to be formed there.

Abstract: A prepreg laminate is provided which includes: a woven fabric prepreg on at least one surface layer; and a discontinuous fiber prepreg; the woven fabric prepreg including reinforcing fibers R1 having a woven structure, and a thermosetting resin A, the discontinuous fiber prepreg including unidirectionally oriented discontinuous reinforcing fibers R2 and a thermosetting resin B, the thermosetting resin A and the thermosetting resin B satisfying the following calorific value condition: calorific value condition: when each of the thermosetting resin A and the thermosetting resin B is heated using a differential scanning calorimeter from 50° C. to 130° C. at 700° C./min under a nitrogen atmosphere followed by retention at 130° C.

Abstract: An intermediate base material is provided that is excellent in the conformity to three-dimensional shapes and that, when formed into a fiber reinforced plastic, develops good surface quality and high mechanical properties. According to one aspect, an incised prepreg is provided that has, in at least a partial region in a prepreg that contains unidirectionally oriented reinforcing fibers and a resin, a plurality of incisions that divide reinforcing fibers, wherein, in the case where a population is made up of the numbers of incisions contained in ten small circular regions of 10 mm in diameter randomly selected in the aforementioned region, a mean value for the population is 10 or greater and a coefficient of variation therefor is within 20%.

Abstract: An intermediate base material is provided that is excellent in the conformity to three-dimensional shapes and that, when formed into a fiber reinforced plastic, develops good surface quality and high mechanical properties. According to one aspect, an incised prepreg is provided that has, in at least a partial region in a prepreg that contains unidirectionally oriented reinforcing fibers and a resin, a plurality of incisions that divide reinforcing fibers, wherein, in the case where a population is made up of the numbers of incisions contained in ten small circular regions of 10 mm in diameter randomly selected in the aforementioned region, a mean value for the population is 10 or greater and a coefficient of variation therefor is within 20%.

Abstract: An intermediate base material has high handleability and shape conformity to complicated shapes and serves to perform high-yield production, even by low pressure molding, of fiber reinforced plastic material that do not suffer from significant generation of molding defects, such as creases and voids, that can cause a decrease in strength and that has good mechanical characteristics, decreased variations therein, and high dimensional stability. The prepreg includes a layer containing reinforcement fibers impregnated with a resin composition and the impregnation rate with the resin composition in the prepreg is in a predetermined range. It is characterized by being an incised prepreg having a plurality of incisions, being at least partly formed of reinforcement fibers with a predetermined fiber length, and having a reinforcement fiber content by volume Vf in a predetermined range.

Abstract: Provided is a method for producing a fiber-reinforced plastic having high mechanical properties and high productivity during molding of a complicated shape.

Abstract: A recording medium post-processing device includes a binding unit and a hole forming unit. The binding unit performs a binding process on a recording medium bundle. The hole forming unit performs a hole forming process in a region of recording media that constitute the recording medium bundle including a part of a binding region in which the binding process is performed.

Abstract: Provided are methods for producing a fiber-reinforced plastic having high mechanical properties and high productivity during molding of a complicated shape. In one aspect, the method produces a fiber-reinforced plastic using a tape substrate A and a sheet substrate B, the tape substrate A being a tape-shaped substrate including one or more sheets of incised prepreg a; the incised prepreg a being a prepreg including unidirectionally oriented reinforcing fibers and a resin and having a plurality of incisions dividing the reinforcing fibers formed in the prepreg, and satisfying the following condition 1; the sheet substrate B being a substrate including randomly oriented reinforcing fibers and a resin.

Abstract: To provide a gas filling method in which it is possible to estimate a volume of a tank with high accuracy even when the tank has a small volume. A hydrogen filling system includes a hydrogen station having a pressure accumulator of compressed hydrogen gas, a vehicle having a hydrogen tank, a connection tube system that connects the accumulator and the tank, and a flow rate sensor and a station pressure sensor provided on the connection tube system. A hydrogen gas filling method is a method of filling the tank with the hydrogen gas from the pressure accumulator and includes estimating a volume of the hydrogen tank based on detection values of the flow rate sensor and the station pressure sensor and a volume value of the connection tube system, after a start of filling of the hydrogen tank with the hydrogen gas from the pressure accumulator.

Abstract: Provided is an intermediate base material (incised prepreg) which has exceptional surface quality and mechanical properties when solidified and with which it is possible to obtain a fiber-reinforced plastic having excellent three-dimensional shape conformance properties. This incised prepreg has, in a prepreg that includes a resin and reinforcing fibers oriented in one direction, incisions substantially parallel to the orientation direction of the reinforcing fibers (the incisions substantially parallel to the orientation direction of the reinforcing fibers are referred to as parallel incisions) and incisions that cut across the reinforcing fibers (the incisions that cut across the reinforcing fibers are referred to as intersecting incisions).

Abstract: A prepreg, including: a fiber layer containing unidirectionally arranged discontinuous carbon fibers and a thermosetting resin; and a resin layer existing on at least one side of said fiber layer and containing a thermosetting resin and a thermoplastic resin; in which said prepreg contains carbon fibers having an areal weight of fibers of 120 to 300 g/m2, and has a mass fraction of resin of 25 to 50% with respect to the whole mass of said prepreg; and in which a temperature at which a coefficient of interlayer friction is 0.05 or less is in a temperature range of from 40 to 80° C., the interlayer friction being caused at the contact interface between layers of said prepreg when the middle one of three layers that are each made of said prepreg and laid up is pulled out, said coefficient of interlayer friction being measured at 10° C. intervals in a temperature range of from 40 to 80° C. under conditions including a pulling speed of 0.2 mm/min, a perpendicular stress of 0.08 MPa, and a pulling length of 1 mm.

Abstract: A method of producing a fiber reinforced plastic includes a laminating step of laminating a plurality of groups of prepregs containing an incised prepreg to obtain a prepreg laminate, when the incised prepreg is formed by providing at least a partial region in a prepreg containing unidirectionally oriented reinforcing fibers and a resin with a plurality of incisions that divide the reinforcing fibers, a forming step of disposing the prepreg laminate on a top surface of a mold containing the top surface and a side surface or disposing the prepreg laminate on a bottom surface of a mold containing the bottom surface and a side surface, and bending and forming the prepreg laminate along the side surface to obtain a preform having an approximate shape of the mold, and a solidifying step of disposing and solidifying the preform in a mold different than the mold used in the forming step.

Abstract: A substantially flat-plate-shaped laminated base material has at least a layer-shaped body ? and a layer-shaped body ? are layered or disposed side by side, the layer-shaped body ? having one or more cut prepregs A in which reinforcing fibers oriented in one direction are impregnated with a resin composition, the volume fraction of fiber is 45-65%, and at least a portion of the reinforcing fibers are segmented into a fiber length of 10-300 mm by a plurality of cuts, and the layer-shaped body ? having one or more base materials B in which reinforcing fibers having a fiber length in the range of 10-300 mm are impregnated with a resin composition.