Abstract: The magnetic tape container includes a core around which a magnetic tape is wound. The magnetic tape includes a non-magnetic support, and a magnetic layer including a ferromagnetic powder, and the roundness of the trajectory of one rotation drawn by the magnetic tape in a case where the wound magnetic tape is pulled out from the core is 100 ?m or less as the arithmetic mean of the measured values at three points in the width direction of the magnetic tape.

Abstract: The magnetic tape container includes a core around which a magnetic tape is wound. The magnetic tape includes a non-magnetic support, and a magnetic layer including a ferromagnetic powder. A maximum value of a deviation of a center position of an average minimum region reference circle of a trajectory of one rotation drawn by the magnetic tape, in a case where the wound magnetic tape is drawn out from the core core is 100 ?m or less for three points of the magnetic tape in a width direction.

Abstract: The magnetic tape container includes a core around which a magnetic tape is wound. The magnetic tape includes a non-magnetic support, and a magnetic layer including a ferromagnetic powder. A maximum value of a deviation of a center position of an average minimum region reference circle of a trajectory of one rotation drawn by the magnetic tape, in a case where the wound magnetic tape is drawn out from the core core is 100 ?m or less for three points of the magnetic tape in a width direction.

Abstract: The magnetic tape container includes a core around which a magnetic tape is wound. The magnetic tape includes a non-magnetic support, and a magnetic layer including a ferromagnetic powder, and the roundness of the trajectory of one rotation drawn by the magnetic tape in a case where the wound magnetic tape is pulled out from the core is 100 ?m or less as the arithmetic mean of the measured values at three points in the width direction of the magnetic tape.

Abstract: A ceramide dispersion, which includes at least: natural-ceramide-containing particles that are dispersed in an aqueous phase as an oil-phase component; and at least one surfactant, wherein the natural-ceramide-containing particles contain one or more natural ceramides in an amount of 50% by mass or higher with respect to the total mass of the oil components contained in an oil phase, and have a volume average particle diameter of from 0.5 nm to 100 nm; and the ceramide dispersion contains, in the at least one surfactant, at least one polyglycerin fatty acid ester having an HLB of from 10 to 16.

Abstract: A method for mixing fluids that can control mixing characteristics of fluids, a method for producing particulates that can provide desired particulates, and particulates produced thereby are provided. According to an embodiment of the present invention, in a method for mixing at least two kinds of fluids in a microreactor, a first fluid is supplied to a mixing zone through a divided supply passage, and a second fluid is supplied to the mixing zone through a supply passage. A total value of dynamic pressures of the first and second fluids is controlled to mix the first and second fluids in the mixing zone. Then, the mixed fluids are flowed into a micro passage.

Abstract: A water-soluble organic solvent solution containing a natural ingredient that has been extracted from a natural animal or plant using a water-soluble organic solvent and an aqueous solution are passed through respective microflow channels each of which has a cross-sectional area at a narrowest portion of from 1 ?m2 to 1 mm2; and thereafter mixed by a counter collision. Preferably, the water-soluble organic solvent is removed after the mixing. Also provided are a food, a skin external preparation, and a drug, each of which contains an emulsion or dispersion obtained thereby.

Abstract: An apparatus for evaluating scientific phenomena by feeding liquid to a minute channel, which is inexpensive, imposes little environmental load and enables advanced technology to be easily enjoyed and can eliminate experimental failures due to the clogging of the minute channel with a bubble, is provided. Before starting the experiment with the experimental liquid, the preparatory step of removing air in the minute channel by vigorously injecting inert dummy liquid which does not react with the experimental liquid into the minute channel and thereby filling the minute channel with the dummy liquid is carried out. If one round of preparatory step proves insufficient to wholly remove the air in the minute channel and a bubble is found in the dummy liquid, the step will be repeated until no bubble is found any longer in the dummy liquid.

Abstract: There is provided a method for producing chemicals using a device which carries out reaction operations or unit operations for fluids flowing through a flow channel, in which the reaction operations or unit operations for the object fluids can be controlled highly accurately, and besides, a functional fluid can be provided with various functions according to the type of the reaction operations or unit operations. The method produces chemicals using a device 10 in which a plurality of object liquids L1, L2 are fed through respective fluid-feeding channels 24, 28 therefor and joined together in a single flow channel 30 to carry out reaction operations or unit operations, the method including forming a functional layer between the object fluids by allowing a functional fluid having a function of controlling the reaction operations or unit operations to flow through the flow channel.

Abstract: The present invention provides that a method for preparing an emulsion or a dispersion composed of an oily phase and an aqueous phase by contacting the oily phase with the aqueous phase, the method comprising: injecting the oily phase, which contains a water-soluble organic solvent and at least one hydrophobic functional ingredient and in which the content of a surfactant is approximately 0.1% by mass or less based on the total mass of the oily phase, into the aqueous phase such that the Reynolds number of the oily phase immediately before contact with the aqueous phase is approximately 1,000 or more, and that foodstuffs, a skin external and a medicament which contain an emulsion or a dispersion prepared by the method described above.

Abstract: In a method of producing magnetic particles which includes the steps of preparing alloy particles capable of forming a CuAu or Cu3Au hard magnetic ordered alloy phase and of forming magnetic particles for forming CuAu or Cu3Au magnetic particles, a plurality of solutions L1 and L2 for preparing the alloy particles are passed in a thin-plate laminar flow and diffused in the direction perpendicular to the flow direction at the contact interface of the solutions L1 and L2 in a mixing channel by using a microreactor, whereby a uniform mixing reaction is conducted in a short time.

Abstract: According to the present invention, a continuous layer liquid used as a continuous layer of a diffusion phenomenon is injected into the first reservoir, and passed through the channels to the second reservoirs to fill the plurality of radially formed channels with the continuous layer liquid. Then, a predetermined amount of diffusion experiment reagent, for example, a coloring liquid used as a diffusion substance of the diffusion phenomenon is injected into the first reservoir. This causes the diffusion experiment reagent to be diffused from the first reservoir to the second reservoirs only by the diffusion phenomenon. At this time, the radially formed channels have the different sectional areas, and thus the diffusion experiment reagent is diffused through the channels at different velocities. This allows the diffusion phenomena that occur in the micro channels or the diffusion velocities to be observed or measured with ease using an inexpensive device.

Abstract: In the evaluation apparatus of the present invention, there are formed a plurality of minute channels having a cross-sectional area of not more than 1 mm2, one end of each of these channels joins in at a single meeting point and, when liquids are put into one or more of the liquid reservoirs in a higher position over any other liquid reservoir, the liquids flow down in the channels by gravity. Therefore, a scientific phenomenon, such as the diffusion of molecules, can be qualitatively observed. Furthermore, the apparatus provides a sufficient level of accuracy to enable the user to watch various phenomena involved in advanced technology, and uses no large quantity of chemicals or the like, which means little load on the environment.

Abstract: An aspect of the present invention provides a method of manufacturing an emulsion by using a nonionic surfactant, an oil agent and water, wherein the following steps are conducted in a continuous flow system: an emulsification step of forming an emulsion by emulsifying the nonionic surfactant, the oil agent and the water at a phase inversion temperature at which three phases of the nonionic surfactant, the oil agent and the water coexist; and an emulsion stabilization step of passing the emulsion in a microchannel with an equivalent diameter equal to or less than 1 mm to rapidly cool or rapidly heat the emulsion from the phase inversion temperature to a temperature at which the emulsion is stabilized.

Abstract: In the scientific phenomena evaluation device of the present invention, a plurality of elongated grooves each having a cross-sectional area of not more than 1 mm2 are formed, an end of each of the plurality of flow passages joins in at one meeting point and furthermore, a liquid absorption device is provided. Therefore, it is possible to qualitatively observe scientific phenomena, such as the dispersion phenomena of molecules. Also, accuracies sufficient for experiencing high technologies, for example, various phenomena such as the diffusion phenomenon of a liquid, heat transfer phenomenon of a liquid, mixing phenomenon of liquids and chemical reactions of a liquid that occur in this fine flow passage are obtained, consumption of chemical agents and the like is small and environmental burdens are small. Therefore, this evaluation device of scientific phenomena is appropriate as an educational tool for scientific experiments.

Abstract: An evaluation apparatus of scientific phenomena, including: a base plate of a plate-like body on whose surface is formed an elongated groove having a transversely cross-sectional area of not more than 1 mm2; and a cover plate that is disposed on a surface of the base plate in close contact therewith and forms a fine flow passage on the base plate by covering the elongated groove, wherein scientific phenomena in the fine flow passage can be visually recognized.

Abstract: The present invention provides a method for operating fluids of a chemical apparatus which performs reaction operations or unit operations by causing multiple kinds of fluids having different densities to join together through respective fluid supply passages and flow into one flow passage and forming a mutually continuous interface, wherein the flowing direction of the fluids in the flow passage is made substantially parallel to the direction of an acceleration to which the fluids are subjected, and an apparatus for manufacturing pigment particles to which the method for operating fluids of a chemical apparatus, in order to solve the problem that unit operations or reaction operations of multiple kinds of fluids cannot be uniformly performed.

Abstract: According to the scientific phenomenon evaluation device of the present invention, a test liquid is injected into the first reservoir while sample liquids are injected into the second reservoirs. When the test liquid is supplied to the second reservoirs by being caused to flow through the branching-structure channel, the test liquid and the sample liquid mix and react with each other to cause, for example, a scientific phenomenon such that the colors of the sample liquid change. Thus, the plurality of sample liquids can be evaluated by injecting the test liquid one time. In this case, the scientific phenomenon can be grasped with a single glance since at least the scientific phenomenon in the second reservoirs is visually recognizable. Moreover, the scientific phenomenon evaluation device of the present invention can be effectively used as a portable pH measurement experimental device.

Abstract: According to the scientific phenomenon evaluation device of the present invention, a test liquid is injected into the first reservoir while sample liquids are injected into the second reservoirs. When the test liquid is supplied to the second reservoirs by being caused to flow through the branching-structure channel, the test liquid and the sample liquid mix and react with each other to cause, for example, a scientific phenomenon such that the colors of the sample liquid change. Thus, the plurality of sample liquids can be evaluated by injecting the test liquid one time. In this case, the scientific phenomenon can be grasped with a single glance since at least the scientific phenomenon in the second reservoirs is visually recognizable. Moreover, the scientific phenomenon evaluation device of the present invention can be effectively used as a portable pH measurement experimental device.

Abstract: A manufacturing method of a scientific phenomena evaluation device including a drying step of heating resin materials at a temperature lower than a glass transition point Tg of said resin materials and drying the resin materials, a stacking step of stacking a base plate and a cover plate together, and a bonding step of bonding said stacked base plate and cover plate together while heating said base plate and cover plate at a temperature equal to or higher than the glass transition point Tg of said resin materials.