Abstract: A collection unit (80)includes: a collection carrier cartridge (82) formed, at its center, with a through hole (82b3) into which a nozzle for supplying hot water or ATP reagent is inserted including a carrier filling dish (82b), on an outer circumference of the through hole (82b3), to be filled with a collection carrier (90) for collecting floating bacteria in the air, and an upper lid (82a) on which the carrier filling dish (82b) is placed, formed with a protrusion to be inserted through the through hole (82b3); an impactor nozzle head (86) covering a surface of the collection carrier (90) and has a plurality of nozzle holes (87) facing the collection carrier (90) surface; and a fan (84) introducing air to the collection carrier surface through the nozzle holes (87). A velocity of the air passing through the nozzle holes (87) is 40 m/s to 50 m/s.

Abstract: In order to make a process of capturing and testing air-borne microorganisms more convenient and quick, a capturing device which comprises the capturing carrier comprising a polymer which is in a gel phase at the time of capturing the microorganisms but undergoes a phase transition under heating to a sol phase at the temperature at or less than 40° C. (especially in the temperature range between 15° C. and 37° C.), and a vessel to contain the capturing carrier is used. Further, by comprising a test reagent in the polymer, the test reagent can be eluted upon said phase transition from a gel phase to a sol phase. By heating the capturing carrier, a phase transition to a sol phase can occur at or less than 40° C. As such, since recovery of microorganisms and addition of a test reagent to the microorganisms can be carried out simultaneously, the process can be simplified and the process time can be shortened.

Abstract: A collection unit (80) of this invention includes: a collection carrier cartridge (82) formed, at its center, with a through hole (82b3) into which a nozzle for supplying hot water or ATP reagent is inserted including a carrier filling dish (82b), on an outer circumference of the through hole (82b3), to be filled with a collection carrier (90) for collecting floating bacteria in the air and an upper lid (82a) on which the carrier filling dish (82b) is placed, formed with a protrusion to be inserted through the through hole (82b3); an impactor nozzle head (86) which covers a surface of the collection carrier (90) and has a plurality of nozzle holes (87) facing the surface of the collection carrier (90); and a fan (84) which introduces air to the surface of the collection carrier through the nozzle holes (87). A velocity of the air passing through the nozzle holes (87) is 40 m/s to 50 m/s.

Abstract: A floating bacteria counting device capable of trapping floating bacteria in air continuously for a long time without decreasing trapping efficiency even if the time before a trapping carrier being replaced is prolonged and a floating bacteria counting method and a floating bacteria counting system using the floating bacteria trapping device are provided. A nozzle (16) is formed of a plurality of pinholes (16a) arranged at equal intervals. If a pitch interval between the pinholes (16a) is d, a driving mechanism (22) causes a support container (20) supporting a trapping carrier (30) to move in a horizontal direction so that the support container (20) draws a circle of less than d in diameter.

Abstract: In order to make a process of capturing and testing air-borne microorganisms more convenient and quick, a capturing device which comprises the capturing carrier comprising a polymer which is in a gel phase at the time of capturing the microorganisms but undergoes a phase transition under heating to a sol phase at the temperature at or less than 40° C. (especially in the temperature range between 15° C. and 37° C.), and a vessel to contain the capturing carrier is used. Further, by comprising a test reagent in the polymer, the test reagent can be eluted upon said phase transition from a gel phase to a sol phase. By heating the capturing carrier, a phase transition to a sol phase can occur at or less than 40° C. As such, since recovery of microorganisms and addition of a test reagent to the microorganisms can be carried out simultaneously, the process can be simplified and the process time can be shortened.

Abstract: An electronic noise attenuation system for attenuating a sound wave propagated from a source of noise by generating another sound wave 180.degree. out of phase and having the same sound pressure with the propagated sound wave from electro-mechanic transducer means disposed in a propagation passage of sound waves. In the electronic noise attenuation system, a drive signal for drive the electro-mechanic transducer means is generated in accordance with output signals respectively output from upstream-side and downstream-side mechano-electric transducer means respectively disposed in the propagation passage with the electro-mechanic transducer means therebetween. Namely, the drive signal is created by performing an operation on a difference signal between the output signal of the upstream mechano-electric transducer means and the drive signal according to a given transfer function.