Abstract: An automatic analysis device includes a processing unit 3 which performs the treatment on a specimen before analysis of the specimen, supply equipment which supplies a reagent to a reaction vessel 11 disposed in the processing unit 3, a liquid temperature adjusting unit 1 which adjusts a temperature of the reagent supplied to the reaction vessel 11 by the supply equipment, a control unit 201, and a first temperature detection unit 4 which detects at least one temperature of a temperature of the air within the processing unit 3 and a temperature of the reagent supplied to the reaction vessel 11, in which the liquid temperature adjusting unit 1 and the control unit 201 execute temperature adjustment of the reagent based on a first temperature detected by the first temperature detection unit 4.

Abstract: The automatic analysis device includes: a reagent tank that holds a reagent container that contains a reagent; and a lid opening/closing device including a lid opening/closing member configured to be movable in a first direction parallel to a vertical direction and a second direction perpendicular to the first direction. The lid opening/closing member having a first member for opening a lid of the reagent container and a second member for closing the lid and configured to be movable between a first position and a second position, the first position located above the reagent container and the second position located below the first position in the first direction such that the bottom surface of the lid opening/closing member comes into contact with the reagent container and configured to be movable between the second position and a third position that is away from the second position in the second direction.

Abstract: An automated analyzer includes a reagent container holder (2) including an openable and closable opening (23) and including a plurality of reagent container holding slots capable of holding reagent containers at internal predetermined positions, and loading assisting means (24) for executing a loading process of conveying the reagent container (3) from outside of the reagent container holder (2) into the reagent container holder (2) via the opening (23) to load the reagent container (3) into the reagent container holding slot (26) and a taking-out process of conveying the reagent container (3) from the reagent container holding slot (26) to outside of the reagent container holder (2) via the opening (23). The loading assisting means (24) is further provided with placing means (33) for the reagent container (3), and an operation handle (34) to be operated for driving the loading assisting means (24).

Abstract: The mixing of reagents with each other in the reagent storage flow paths of an automatic analyzer is suppressed before and after exchange of the reagents, which are capable of being replenished without stopping analysis. An exchangeable reagent container that accommodates a reagent is connected to a reagent storage flow path that stores a portion of the reagent. The reagent storage flow path has first and second flow paths in which the second flow path is branched from the first flow path. A reagent syringe applies a negative or a positive pressure to the first and second flow paths; and a valve controls the flow path through which the reagent is sent. As a result, the reagent supplied to a measurement portion at a predetermined timing is switched from the reagent container to the reagent storage flow path wherein the reagent can be supplied without stopping analysis.

Abstract: Provided is an automated analyzer comprising a temperature regulator that can be made more compact in size while maintaining high-precision temperature regulation. In a temperature-regulating unit (20) of the automated analyzer, a first chemical reservoir (1) is constituted by a large-diameter spiral-shaped pipe, and a second chemical reservoir (2) is constituted by a large-diameter chemical reservoir container. The first chemical reservoir (1), which is positioned upstream of the second chemical reservoir (2), has an internal capacity that is set so as to be greater than the volume of a single discharge of each of syringe pumps (29, 30, 31), and the second chemical reservoir (2) also has an internal capacity (volume) that is set so as to be greater than the volume of a single discharge of each of the respective syringe pumps (29, 30, 31).

Abstract: A countersunk hole is added to a back surface of a dispensing chip mounting position of a sample dispensing chip installation table such that, when the dispensing chip is pulled up from the installation table, the amount of contact of a chip side surface is reduced and the chip is stably mounted. In addition, a posture control member during falling is added to a chip waste position, and the chip is caused to fall vertically and attachment of a sample to a waste route is suppressed. When a dispensing probe moves upward during dispensing chip separation, an upper end of the chip is moved upward up to a position in contact with a base and stopped and then is moved upward again. Thus, the posture of the chip during separation is stable. Further, plural positions for separating the chip are provided such that the position changes depending on waste timing.

Abstract: Provided is an automatic analyzer in which a consumable is appropriately managed and efficiently used. An automatic analyzer includes: a housing container holder portion that holds a housing container housing a consumable; a transport mechanism that transports the consumable housed in the housing container; and a controller, in which the housing container contains a first consumable and a second consumable, and the controller determines a usage state of the housing container relating to the first consumable and a usage state of the housing container relating to the second consumable, determines whether or not the first consumable housed in the housing container is usable based on the usage state of the housing container relating to the first consumable, and determines whether or not the second consumable housed in the housing container is usable based on the usage state of the housing container relating to the second consumable.

Abstract: The present invention provides: a drawer that is supported so as to be horizontally movable in the front-rear direction between an open position and a closed position through a front-face opening; a table that allows an expendable or a processing unit used for analysis to be mounted in the drawer; and a moving-direction transforming means that, while the drawer is moved toward the rear side from the open position to the closed position, moves horizontally until the expendable or the processing unit mounted on the table passes through the front-face opening from the front side to the rear side and moves the table toward the upper side in synchronization with the horizontal movement of the drawer toward the rear side after the expendable or the processing unit mounted on the table passes through the front-face opening. This makes it possible to easily and reliably perform the work of replacing a chip rack.

Abstract: An automated analysis device is provided with a casing accommodating an analysis device. A cover is axially supported with freedom to pivot, between a closed position and an upwardly-open open position, about a support shaft provided at one side of the casing. A closing device is capable of inhibiting opening of the cover in the closed position, and is provided with a lock accepting means, which is a projecting portion that protrudes from a front surface of the cover toward the rear, a lock lever which is axially supported with freedom to pivot about a pivoting support shaft, and which pivots from the work surface in a direction approaching the lock accepting means to engage with the lock accepting means, thereby inhibiting opening of the cover, and a driving means for driving the lock lever. A safety cover can thus be locked securely.

Abstract: A driving mechanism for moving a vessel having a disposal box placed thereon in a front-rear direction the same as an opening/closing direction of a drawer is provided lower than a bottom surface of the vessel. A first rail extended in a movement direction of an operating unit, a second rail extended in a movement direction of the vessel provided in the drawer, and toothed pulleys for rotating a toothed belt within a horizontal plane are arranged. The first rail, the second rail, and the toothed belt are placed side by side without overlapping with each other in a vertical direction. As a result, the operation of taking out the disposal box in which used sample dispensing tips or reaction vessels are accumulated is simple.

Abstract: An object is to provide an automatic analyzer that prevents an effect of various environmental changes on an equilibrium state of an immunological binding reaction. An automatic analyzer of an embodiment of the invention includes a B/F separation unit that executes a B/F separation step separating an unreacted component and a reacted component from a liquid in which a sample and a reagent are reacted, a detection unit that detects a reacted component in the liquid after the B/F separation step, and a temperature maintaining unit that maintains the B/F separation unit and the detection unit in substantially the same temperature environment.

Abstract: The automated analyzer equalizes the temperature inside a reagent container storage apparatus. The automated analyzer is provided with a reagent container storage apparatus that cools a reagent container, the reagent container storage apparatus being provided with: a reagent storage chamber for storing the reagent container, the reagent storage chamber having at least one of the bottom surface and the side surface thereof cooled by a first cooling source; and a transfer member which is arranged to cover the reagent container stored in the reagent storage chamber, and which is thermally connected to the reagent storage chamber.

Abstract: In the case of adopting a configuration in which reagent bottles are radially disposed on a reagent disk and a reagent dispensing mechanism is rotated to access the reagent bottles, one reagent bottle includes a plurality of suction ports in which suction positions are different from each other, resulting in prolonging a step of dispensing a reagent. The invention is directed to an automatic analyzer including: a reagent disk that accommodates a plurality of reagent bottles including a plurality of suction ports and conveys the reagent bottles to a desired position by rotating in a circumferential direction around a central axis; and a reagent dispensing mechanism that rotates around a rotational axis and sucks a reagent of the reagent bottle placed at a predetermined position on the reagent disk. The reagent bottle is accommodated in the reagent disk such that the central axis of the reagent bottle and a diameter of the reagent disk form a predetermined inclination.

Abstract: To provide an automated analyzer capable of shortening analysis time. The automated analyzer includes a vessel which contains a mixed solution of a specimen and a reagent; and a control unit which controls a first operation performed on the vessel, a second operation performed on the vessel after the first operation, and a third operation performed on a predetermined mechanism of the automated analyzer before the second operation, in which the control unit performs the first operation and the third operation in parallel. Alternatively, the automated analyzer includes a control unit which controls a first operation performed on the vessel, a second operation performed on the vessel after the first operation, and a third operation performed on a predetermined mechanism of the automated analyzer after the first operation, in which the control unit performs the second operation and the third operation in parallel.

Abstract: An automatic analyzer which accurately detects a liquid volume of a reagent irrespective of a shape of a reagent container is provided. The invention is directed to an automatic analyzer including: a reagent container that contains a reagent; an emission unit that is provided outside the reagent container and emits light so as to pass inside the reagent container; a light receiving unit that is provided outside the reagent container and receives the light emitted from the emission unit; and a determination unit that, based on the light received by the light receiving unit, detects a liquid level inside the reagent container, and determines whether a liquid volume in the reagent container becomes equal to or less than a predetermined value from the liquid level. A wavelength of the light is determined based on a material of the reagent container and a type of the reagent.

Abstract: When an automatic analysis apparatus has a mechanism that performs an operation of an arcuate trajectory to access a plurality of positions arranged on a straight line, an arc and a straight line cannot coincide with each other. Thus position adjustment is required to minimize the deviation between the arc and the straight line. An automatic analysis apparatus according to the invention includes a reagent disk which accommodates a plurality of reagent bottles in each of which a plurality of suction ports are arranged along a center line, and which rotates around a central axis to transport a reagent bottle to a desired position; and a reagent dispensing mechanism which rotates around a rotation axis to suck a reagent from the reagent bottle at a predetermined suction position on the reagent disk, in which the reagent disk is provided with, at least one mounting position of the reagent bottle on the reagent disk, first and second marks sandwiching the mounting position of the reagent bottle.

Abstract: It is necessary to dispose a plurality of units which have different target temperatures on an apparatus in a more integrated state in order to improve analysis performance and processing capacity per unit space of the apparatus. Therefore, it is necessary to mitigate influence of temperature exerted between units. It is possible to reduce the temperature influence exerted between the units and thus efficiently control temperature by properly disposing the units in the apparatus, based on the relationship between a use environment temperature of the apparatus and a target temperature of each unit and temperature accuracy required for the unit.