Abstract: Disclosed herein is an open healthcare apparatus and method in which a user personally performs integrated management of health records including data concerning western medicine, oriental medicine, life logs, etc. health-related big data is built by receiving health information, from which personal information is deleted, under the agreement of the user, and customized health service is provided by various service providers based on the health-related big data. The disclosed apparatus includes a personal cloud repository for storing personal health data, a health-related big data repository for storing public and personal health data on a health case basis, a healthcare platform for storing and analyzing personal health data and for relaying and managing a customized service, and an analysis platform for analyzing user's health based on the information of the health-related big data repository and for providing customized service depending on the analysis result.

Abstract: Disclosed are a method and an apparatus for detecting a translocation. The apparatus acquires BAM for a first pair of chromosomes and a second pair of chromosomes. Also, the apparatus detects a translocation generated in at least one chromosome by selecting at least one translocation case corresponding to the translocation information produced on the basis of BAM from among multiple translocation cases in which a translocation may be generated in at least one of the first and the second chromosomes.

Abstract: An apparatus and method for counting alleles are disclosed herein. The apparatus for counting alleles includes a file input unit and a counting unit. The file input unit receives one or more files including human genome data. The counting unit reads the files on a predetermined window size basis by means of parallel reading using multi-threading based on the position information of the files, performs allele counting, and merges the results of the counting.

Abstract: Disclosed herein are an apparatus and method for providing a customized personal health service based on personal health information. The apparatus includes a health information input unit for receiving individual health information, a similar case search unit for calculating weights of the health information for respective features and calculating similarities based on the weights, thus searching for similar cases, a health pattern analysis and future health prediction unit for analyzing patterns of found similar cases and predicting a health pattern of the corresponding individual, a healthcare planning unit for designing individual customized healthcare plans based on the predicted health pattern for the corresponding individual, and a healthcare knowledge base including a knowledge map required for calculation of the weights of the health information for respective features and a knowledge map required for the analysis and prediction of patterns.

Abstract: Disclosed are a method and an apparatus for detecting a translocation. The apparatus acquires BAM for a first pair of chromosomes and a second pair of chromosomes. Also, the apparatus detects a translocation generated in at least one chromosome by selecting at least one translocation case corresponding to the translocation information produced on the basis of BAM from among multiple translocation cases in which a translocation may be generated in at least one of the first and the second chromosomes.

Abstract: Disclosed herein is an open healthcare apparatus and method in which a user personally performs integrated management of health records including data concerning western medicine, oriental medicine, life logs, etc. health-related big data is built by receiving health information, from which personal information is deleted, under the agreement of the user, and customized health service is provided by various service providers based on the health-related big data. The disclosed apparatus includes a personal cloud repository for storing personal health data, a health-related big data repository for storing public and personal health data on a health case basis, a healthcare platform for storing and analyzing personal health data and for relaying and managing a customized service, and an analysis platform for analyzing user's health based on the information of the health-related big data repository and for providing customized service depending on the analysis result.

Abstract: A detachable device for preventing sliced food ingredients from sticking on the blade of a knife when a user slices the food ingredients. The device is attached to a kitchen knife and acts to bend food ingredients outwardly from the blade. It includes an adhesion preventing member having a predetermined length and width, and having a flat lower face. The adhesion preventing member includes a curved portion, a first inclined portion and a second inclined portion which are respectively formed on the upper part thereof. The curved portion has an arc-shaped curved surface and the first inclined portion extends downwardly from an end portion while forming a curved surface. The second inclined portion extends downwardly from the other end portion while forming a curved surface. A silicon attachment pad is joined to the lower face of the adhesion preventing member.

Abstract: The present invention relates to a polypropylene resin composition comprising polypropylene resin, wollastonite as inorganic filler, modified polypropylene which is grafted by maleic anhydride, dispersing agent. The present invention has an excellent surface hardness and scratch resistance.

Abstract: The polyolefin resin composition of the present invention includes 100 parts by weight polypropylene, 5 to 45 parts by weight inorganic filler, and 2 to 20 parts by weight silicon-grafted polyethylene. The polyolefin resin composition of the present invention is useful as a material of construction for various kinds of housings for electronic appliances and automobile parts since the resin exhibits better scratch resistance, resin fluidity, and moldability than prior art polyolefin resin compositions while maintaining mechanical properties.

Abstract: A portable computer is provided that has a monitor pivotally mounted onto a main body. The base of the main body have holes that can receive a fastener. On the sides of the main body are receptacles that are positioned near a corresponding hole in the base of the main body of the computer.An L-shaped member forms a connector that allows a strap to be attached to the portable computer to allow the computer to be more easily transported. The L shaped member has a bore on one leg and a boss on the other leg. To attach the connector the boss is inserted into a receptacle in the side of the main body and the bore of the connector is aligned over a hole in the base of the main body. Then, a fastener is inserted through the bore and into the hole in the base of the main body.On a portion of the connector is a bail shaped member that forms a chute between the member and the connector. A strap can be attached to the bail shaped member to simplify the transporting of the portable computer.

Abstract: A portable computer is provided that has hand grips on both sides of the main body of the computer. The hand grips allow the computer to be carried with two hands when the display screen is in an open position and allow the computer to be carried with one hand when the display screen is in a closed position. Additionally, a rubber bumper may be installed around the hand grips and the side of the main body of the computer to increase the ability of the computer to withstand impacts with foreign object. Furthermore, the computer may be designed with any one of an elliptical prism shape, a circular prism shape, and an oblong prism shape to further reduce the stress experienced by the computer when the computer undergoes an impact with a foreign object.For situations when a user wishes to transport the laptop computer without holding the computer in either hand, a shoulder strap may be fastened to the hand grips to allow the computer to be carried over a shoulder.

Abstract: The present invention relates to a portable computer with endurance against shock by attachment of a shock-absorber to the portable computer. The external shock to the portable computer during transport is absorbed by a shock-absorber which is attached to the portable computer so as to cover an external case, an edge part of a cover case of the external case, and an established area of a main body case.

Abstract: Gamma titanium aluminide alloys having the composition Ti-(45.5-47.5)Al-(0-3.0)X-(1-5)Y-(0.05-1.0)W, where X is Cr, Mn or any combination thereof, and Y is Nb, Ta or any combination thereof (at %), are treated to provide specific microstructures. To obtain duplex microstructures, the annealing temperature (T.sub.a) range is the eutectoid temperature (T.sub.e)+100.degree. C. to the alpha transus temperature (T.sub..alpha.)-30.degree. C.; to obtain nearly lamellar microstructures, the annealing temperature range is T.sub..alpha. -20.degree. C. to T.sub..alpha. -1.degree. C.; to obtain fully lamellar microstructures, the annealing temperature range is T.sub..alpha. to T.sub..alpha. +50.degree. C. The times required for producing these microstructures range from 0.25 to 15 hours, depending on the desired microstructure, alloy composition, annealing temperature selected, material section size and grain size desired.

Abstract: Gamma titanium aluminide alloys having the composition Ti--(45.5-47.5)Al--(0-3.0)X--(1-5)Y--(0.05-1.0)W, where X is Cr, Mn or any combination thereof, and Y is Nb, Ta or any combination thereof (at %), are treated to provide specific microstructures. To obtain duplex microstructures, the annealing temperature (T.sub.a) range is the eutectoid temperature (T.sub.e)+100.degree. C. to the alpha transus temperature (T.sub..alpha.)-30.degree. C.; to obtain nearly lamellar microstructures, the annealing temperature range is T.sub..alpha. -20.degree. C. to T.sub..alpha. -1.degree. C.; to obtain fully lamellar microstructures, the annealing temperature range is T.sub..alpha. to T.sub..alpha. +50.degree. C. The times required for producing these microstructures range from 0.25 to 15 hours, depending on the desired microstructure, alloy composition, annealing temperature selected, material section size and grain size desired.

Abstract: Gamma titanium aluminide alloy articles having improved properties are produced by the following methods:The first of these methods comprises the steps of: (a) heat treating an alloy billet or preform at a temperature in the approximate range of T.sub..alpha. to T.sub..alpha. +100.degree. C. for about 0.5 to 8 hours, (b) shaping the billet at a temperature between T.sub..alpha. -30.degree. C. and T.sub..alpha. to produce a shaped article, and (c) aging the thus-shaped article at a temperature between about 750.degree. and 1050.degree. C. for about 2 to 24 hours.The second method comprises (a) rapidly preheating an alloy preform to a temperature in the approximate range of T.sub..alpha. to T.sub..alpha. +100.degree. C., (b) shaping the billet at a temperature between T.sub..alpha. and T.sub..alpha. +100.degree. C. to produce a shaped article, and (c) aging the thus-shaped article at a temperature between about 750.degree. and 1050.degree. C. for about 2 to 24 hours.

Abstract: A first method for producing articles of gamma titanium alumide alloy having improved properties comprises the steps of: (a) shaping the article at a temperature between the titanium-aluminum eutectoid temperature of the alloy and the alpha-transus temperature of the alloy, and (b) aging the thus-shaped article at a temperature between about 750.degree. and 1050.degree. C. for about 4 to 150 hours. Shaping is preferably carried out at a temperature about 0.degree. to 50.degree. C. below the alpha-transus temperature.A second method for producing articles of gamma titanium aluminide alloy having improved properties comprises the steps of: (a) shaping the article at a temperature in the approximate range of about 130.degree. C. below the titanium-aluminum eutectoid temperature of the alloy to about 20.degree. C.

Abstract: A method for refining the microstructure and enhancing the processability of titanium aluminum alloys containing about 45 to 55 atomic percent aluminum which comprises the steps of:(a) rapidly solidifying a titanium aluminum alloy containing about 45 to 55 atomic percent aluminum to provide a rapidly solidified material having at least one dimension not greater than about 100 micrometers;(b) diffusing hydrogen into the resulting rapidly solidified material at a temperature in the approximate range of 400.degree. to 780.degree. C., and;(c) diffusing hydrogen out of the hydrogenated solid material.

Abstract: An improved alloy consisting essentially of about 6 to 10 weight percent Fe, about 2 to 10 weight percent Gd, balance Al. The alloy may also contain minor amounts of one or more refractory metals.

Abstract: Methods are presented to produce duplex (DP) microstructures, nearly lamellar (NL) microstructures, and fully TMT lamellar (TMTL) microstructures in gamma titanium aluminide alloy articles. The key step for obtaining a specific type of microstructure is the post-hot work annealing treatment at a temperature in a specific range for the desired microstructure. The annealing temperatures range from Te+100° C. to T&agr;−25° C. for duplex (DP) microstructures, from T&agr;−25° C. to T&agr;−5° C. for nearly lamellar (NL) microstructures, and from T&agr; to T&agr;+60° C. for fully TMT lamellar (TMTL) microstructures, where Te is the titanium-aluminum eutectoid temperature of the alloy and T&agr; is the alpha transus temperature of the alloy. The times required for producing specific microstructures range from 2 min to 15 hours depending on microstructural type, alloy composition, annealing temperature selected, material section size, and desired grain-size.