Abstract: A reciprocating compressor includes a compressing unit placed over a motor unit. A crankshaft, which converts rotating action of the motor unit into reciprocating action of a piston of the compressing unit, has (a) a centrifugal pump provided at a lower section of the crankshaft, and (b) a pair of spiral pumps that communicate with the centrifugal pump and have leading grooves running in opposite directions to each other. The crankshaft also includes a pair of eccentric paths at its upper section. The eccentric paths open into an enclosed container and communicate with the spiral pumps respectively. This structure allows production of greater force for transferring lubricant oil regardless of the rotating direction of the crankshaft.

Abstract: The present invention provides novel target proteins and target genes for drug discovery, and the means that enable the development of novel drugs using the same. More particularly, the present invention provides NCS proteins and genes thereof; screening methods for drug (for example, anti-central nervous disease drug); agents for regulating disease (for example, central nervous disease); production methods of a drug derivative; a complex comprising a drug and NCS protein, and a method of producing the complex; a kits comprising a drug or a salt thereof; determination methods for the onset or risk of onset of a specified disease, determination methods for susceptibility to a drug, and determination kits used for the determination methods; and the like.

Abstract: A device 1 for measuring a propagation time of a sound wave comprises a sound source means 11 and a calculation means 12. The sound source means 11 outputs a time stretched pulse as a sound source signal input to a speaker 3. The calculation means 12 calculates a cross-correlation function of the time stretched pulse and the sound signal which is output from the speaker 3 and is received in a microphone 4. Based on the cross-correlation function, the propagation time of the sound wave between the speaker 3 and the microphone 4 is found.

Abstract: The present invention provides a high refractive index, high dispersion optical glass for precision molding, being free from harmful materials causing environmental problems, such as lead oxide, etc., and having a low yield temperature (At), i.e. at most 580° C., a refractive index (nd) of at least 1.89 and an Abbe number (?d) of at most 23.0 and further providing a low softening property as well as an improved mass production property with less coloration, which is represented in terms of for making up the glass, by the following chemical composition (wt %): P2O5 3 to 20% B2O3 0 to 5% GeO2 more than 14 to 37% Sum of P2O5 + B2O3 + GeO2 24 to 43% Li2O 0 to 5% Na2O 0 to 8% K2O 0 to 10% Sum of Li2O + Na2O + K2O 1 to 10% Nb2O5 0 to 50% Bi2O3 12 to 67% BaO 0 to 5% WO3 0 to 12%.

Abstract: Resonant frequencies f2 and f3 detected in a resonant space are determined as center frequencies of a dip. Based on measurement values at a speaker and a microphone in the resonant space, a basic amplitude frequency characteristic Ca and a target amplitude frequency characteristic Cd are found. A smoothness degree on a frequency axis is larger in the target amplitude frequency characteristic Cd than the basic amplitude frequency characteristic Ca. A damping level and quality factor of the dip are determined based on a difference between the basic amplitude frequency characteristic Ca and the target amplitude frequency characteristic Cd in the center frequencies f2 and f3 of the dip and frequencies near the center frequencies.

Abstract: A device 1 for measuring a propagation time of a sound wave comprises a sound source means 11 and a calculation means 12. The sound source means 11 outputs a time stretched pulse as a sound source signal input to a speaker 3. The calculation means 12 calculates a cross-correlation function of the time stretched pulse and the sound signal which is output from the speaker 3 and is received in a microphone 4. Based on the cross-correlation function, the propagation time of the sound wave between the speaker 3 and the microphone 4 is found.

Abstract: The present invention provides a high refractive index, high dispersion optical glass for precision molding, being free from harmful materials causing environmental problems, such as lead oxide, etc., and having a low yield temperature (At), i.e. at most 580° C., a refractive index (nd) of at least 1.89 and an Abbe number (?d) of at most 23.

Abstract: The present invention provides an optical glass for press molding, in particular, a low softening point glass which contains, in an oxide glass of phosphate type, a durability improving component in addition to glass forming components, and has a weight loss of at most 0.15 weight % in a durability test, and which is represented, in term of elements for making up the glass, by the following chemical composition (mol %): P2O5   32 to 40% Li2O   6 to 21% Na2O   8 to 31% K2O   4 to 22% Al2O3  7.4 to 16% ZnO   0 to 19.6% BaO   0 to 12% and Sum of Li2O + Na2O + K2O 35.1 to 49%.

Abstract: A reciprocating compressor includes a compressing unit placed over a motor unit. A crankshaft, which converts rotating action of the motor unit into reciprocating action of a piston of the compressing unit, has (a) a centrifugal pump prepared at a lower section of the crankshaft, and (b) a pair of spiral pumps that communicate with the centrifugal pump and have leading grooves running in an opposite direction to each other. The crankshaft also includes a pair of eccentric paths at its upper section. The eccentric paths open into an enclosed container and communicate with the spiral pumps respectively. This structure allows producing greater force for transferring lubricant oil regardless of rotating directions of the crankshaft.

Abstract: The present invention provides an optical glass for press molding, in particular, a low softening point glass which contains, in an oxide glass of phosphate type, a durability improving component in addition to glass forming components, and has a weight loss of at most 0.15 weight % in a durability test, and which is represented, in term of elements for making up the glass, by the following chemical composition (mol %): 1 P2O5   32 to 40% Li2O   6 to 21% Na2O   8 to 31% K2O   4 to 22% Al2O3  7.4 to 16% ZnO   0 to 19.6% BaO   0 to 12% and Sum of Li2O + Na2O + K2O 35.

Abstract: The present invention provides an optical glass for precision molding, having excellent properties, i.e. yield temperature (At) of at most 550° C., refractive index (nd) of at least 1.83 and Abbe number (&ngr;d) of at most 26.0 and further providing a low softening property as well as an improved mass production property with less coloration, which is represented, in term of atoms for making up the glass, by the following chemical composition (wt %) P2O5 14.0 to 31.0% B2O3   0 to 5.0% GeO2   0 to 14.0% Sum of P2O5 + B2O3 + GeO2 14.0 to 35.0% Li2O   0 to 6.0% Na2O  2.5 to 14.0% Sum of Li2O + Na2O  2.5 to 15.0% Nb2O5 22.0 to 50.0% WO3   0 to 30.0% Bi2O3  5.0 to 36.0% BaO   0 to 22.0%.