Multicuvette rotor for analyzer

1. A method for transferring by centrifugal force a pre-determined quantity of a liquid to an analytical cell which forms part of an analytical rotor wherein said rotor has a plurality of analytical cells located around the periphery of the rotor, each cell having only one aperture which is normally open and is the inlet of the cell, a central distribution chamber, and a plurality of concentrically located portioning cavities, each portioning cavity being adjacent to the central distribution chamber and an analytical cell, wherein the portioning cavity is located between the outer periphery of the central distribution chamber and the analytical cell, each portioning cavity being sized to receive the pre-determined quantity of liquid and having an inlet which connects it to the central distribution chamber and an outlet which connects it to the aperture, in the analytical cell which it is adjacent to, via a capilary passageway which opens into a vertical sidewall of the analytical cell, and the rotor further having at least one overflow reservoir for receiving excess liquid connected to the central distribution chamber by at least one connecting path, said method comprising the steps of:

• (a) introducing a given quantity of liquid greater than the total volume of all the portioning cavities into the distribution chamber of the rotor;
  
  (b) as a result of driving said rotor on a centrifuge at a first rotational speed to exert centrifugal force on the liquid introduced into the central distribution chamber, transferring the pre-determined quantity of liquid into each portioning cavity and into each capillary passageway, forming a meniscus at the end of each capillary passageway where it opens into the vertical wall of the analytical cell which it is connected to hermetically sealing the analytical cell with the meniscus so that air within the analytical cell can no longer flow out thereby creating a resistance to flow of the liquid into the analytical cell, and transfering excess liquid into the overflow reservoir; and
  
  (c) then as a result of driving the rotor at a second rotational speed greater than the first rotational speed, breaking the meniscus which was formed in step (b) at the end of each of the capillary passageways and passing said pre-determined quantity of liquid from each portioning cavity through each corresponding capillary passageway into the analytical cell to which it is connected while allowing air which was trapped in the analytical cells to escape through each of the capillary passageways.