▎ 摘　　要

NOVELTY - Collection of graphene aggregates involves producing graphene aggregates from a collection of scaly graphite particles or a collection of scaly graphite particles, classifying the graphene into a collection of graphene covered with n-butanol of multiple sizes, collecting scaly graphite particles or scaly graphite particles which is flatly packed on the surface of one of the two parallel plate electrodes, filling the parallel plate electrode with n-butanol in a container, producing graphene aggregate from a collection of scaly graphite particles, producing collection of n-butanol-covered graphene in a container, which is separated into a single graphene, producing graphene aggregate from an aggregate of scaly graphite particles or an aggregate of scaly graphite particles, forming graphene aggregate by n-butanol having different sizes, and classifying into a collection of covered graphene, and each of the classified graphene collections. USE - Collection of graphene aggregates used in manufacture of paste for forming graphene bonded component (all claimed). Uses include but are not limited to transparent electrode or transparent conductive film, thin film solar cell, organic electroluminescent lighting fixture, touch panel, electronic material, heat radiation material, etc. ADVANTAGE - None given. DETAILED DESCRIPTION - Collection of graphene involves producing graphene aggregates from a collection of scaly graphite particles or a collection of scaly graphite particles, classifying the graphene into a collection of graphene covered with n-butanol of multiple sizes, collecting scaly graphite particles or scaly graphite particles which is flatly packed on surface of one of two parallel plate electrodes, filling parallel plate electrode with n-butanol in a container, producing graphene aggregate from a collection of scaly graphite particles, producing collection of n-butanol-covered graphene in a container, which is separated into a single graphene, producing graphene aggregate from an aggregate of scaly graphite particles or an aggregate of scaly graphite particles, and forming graphene aggregate by n-butanol having different sizes, and classifying into a collection of covered graphene, and each of classified graphene collections. The other parallel plate electrode is further superposed on one parallel plate electrode. The two parallel plate electrodes are separated from each other, and two separated parallel plate electrodes are immersed in n-butanol. Then, in the gap between the two parallel plate electrodes, from a predetermined size. A direct potential difference is applied, whereby an electric field corresponding to magnitude of potential difference divided by size of gap between two parallel plate electrodes is applied to collection of scaly graphite particles or is applied to the collection of the scale-like graphite particles, and by application of electric field, the interlayer bonds of all graphite crystals forming the scale-like graphite particles or scale-like graphite particles are simultaneously destroyed, and two parallel plate electrodes composed of the basal plane of the graphite crystals is deposited in the gaps between the two, and the collections of scaly graphite particles or collections of graphene are produced from the collections of the scaly graphite particles. The gap between two parallel plate electrodes is expanded, the two parallel plate electrodes are tilted in n-butanol, and vibration accelerations in three directions of left, right, front and back, and up and down are repeatedly applied to the container. The collection of graphene deposited in the gap between the two parallel plate electrodes is moved from the gap between two parallel plate electrodes into n-butanol in the container, and then two parallel plate electrodes are moved from the container. A parallel plate electrode is taken out, a homogenizer device is further operated in the container, an impact is repeatedly applied to the graphene aggregate through the n-butanol, and the graphene aggregate is one sheet through the n-butanol. The wire meshes having different meshes are arranged separately in the upper stage in the order of coarse meshes, and a multi-stage vibration sieving machine having wire meshes. The fixed amount of a collection of graphene covered with n-butanol was continuously added from the upper portion of the uppermost wire mesh, and the vibration sieve is operated to vibrate the wire meshes at the same time. A collection of butanol-covered graphenes is sequentially brought into contact with the vibrating wire mesh, whereby the n-butanol-covered graphene that cannot pass through each wire mesh of the vibrating wire mesh is the said. The n-butanol-covered collection of graphene released outside the vibrating sieve and vibrates with the n-butanol-covered graphene that cannot pass through each of the vibrating wire meshes. The graphenes that are classified into the n-butanol-covered graphenes that passed through multiple wire meshes and could not pass through each wire mesh of the vibrating wire meshes and are released to the outside of the machine and collected in different containers. The graphene that has passed through the vibrating wire mesh is collected in a container different from the container, and a collection of graphene covered with n-butanol is converted into a collection of graphene covered with n-butanol of multiple sizes. An INDEPENDENT CLAIM is included for removal of graphene covered with a collection of fine crystals of an organic compound; #manufacture of a paste consisting of a collection of graphene in which graphenes are overlapped with each other through n-butanol, which involves using the graphene aggregates having a size of 500 mu m or less, overlapping a paste consisting of the graphene aggregates in which graphenes are overlapped with each other through n-butanol, filling a container with an aggregate of graphene covered with n-butanol having a size of 500 mu m or less, and having a weight of 5 times or more the weight of the graphene aggregate, adding n-butanol to the container, and then applying vibration acceleration in three directions of front-back, left-right, and up-down to the container; and #formation of the graphene bonded component, which involves applying paste to a base material to form a coating film, heating the base material to the boiling point of n-butanol, and vaporizing from the coating film to form a coating film consisting of a collection of graphene on which graphenes are overlapped on the substrate, and then the upper flat surface of the coating film is evenly compressed, whereby the graphene is formed. DESCRIPTION OF DRAWING(S) - The drawing shows an explanatory diagram of graphene covered with fine crystals of alpha -olefin derivative in an enlarged manner. Graphene (1) Collection of fine crystals of alpha-olefin derivative (2)