Container supply unit and automated analyzer

The invention claimed is: 1. A container supply unit comprising: a container storage part in which a plurality of containers are stored; a container ejection part which ejects the plurality of containers stored in the container storage part; and a container alignment part which aligns the containers ejected from the container ejection part, wherein the container ejection part includes a circular belt, at least one placement member which is provided on the circular belt and on which the containers are placed, and a belt rotation mechanism which rotates the circular belt in one direction and which forms an outward leg along which the placement member moves upwards and a return leg along which the placement member moves downwards, wherein the placement member carries the containers placed thereon on the outward leg and ejects the containers between the outward leg and the return leg to the container alignment part, wherein an upper portion of the placement member, the upper portion located on an upper side on the outward leg, includes a first inclined surface and a second inclined surface, wherein the first inclined surface has one end provided on a circular belt side and another end separated from the circular belt, and the first inclined surface is inclined upwards on the outward leg towards the other end, and wherein the second inclined surface has one end continuous with the first inclined surface and another end separated from the circular belt, and the second inclined surface is inclined downwards on the outward leg towards the other end. 2. The container supply unit according to claim 1 , wherein the containers each have a cylindrical shape, and wherein a length of the first inclined surface intersecting an inclined direction of the first inclined surface is equal to or smaller than lengths of the containers in an axial direction of the containers. 3. The container supply unit according to claim 1 , wherein the containers each have a cylindrical shape, and wherein a length of the first inclined surface in an inclined direction of the first inclined surface is smaller than a length of each of the containers from one end of the container to a center of gravity of the container in an axial direction of the container. 4. The container supply unit according to claim 1 , wherein the at least one placement member provided on the circular belt includes a plurality of placement members provided on the circular belt, and wherein the placement members include projections in lower portions thereof, the lower portions located on a lower side on the outward leg, the projections are displaced relative to the circular belt between the outward leg and the return leg so as to flick the containers placed on the other containers placed on upper portions of the placement members positioned immediately downstream. 5. A container supply unit comprising: a container storage part in which a plurality of containers are stored; a container ejection part which ejects the plurality of containers stored in the container storage part; and a container alignment part which aligns the containers ejected from the container ejection part, wherein the container ejection part includes a circular belt, at least one placement member which is provided on the circular belt and on which the containers are placed, and a belt rotation mechanism which rotates the circular belt in one direction and which forms an outward leg along which the placement member moves upwards and a return leg along which the placement member moves downwards, wherein the placement member carries the containers placed thereon on the outward leg and ejects the containers between the outward leg and the return leg to the container alignment part, wherein the at least one placement member provided on the circular belt includes a plurality of placement members provided on the circular belt, and wherein the placement members include projections in lower portions thereof, the lower portions located on a lower side on the outward leg, and the projections are displaced relative to the circular belt between the outward leg and the return leg so as to flick the containers placed on the other containers placed on upper portions of the placement members positioned immediately downstream. 6. An automated analyzer which includes a reaction unit which holds containers into which a sample and a reagent are dispensed and a container supply unit which supplies the containers to the reaction unit, wherein the container supply unit includes a container storage part in which a plurality of containers are stored, a container ejection part which ejects the plurality of containers stored in the container storage part, and a container alignment part which aligns the containers ejected from the container ejection part, wherein the container ejection part includes a circular belt, a placement member which is provided on the circular belt and on which the containers are placed, and a belt rotation mechanism which rotates the circular belt in one direction and which forms an outward leg along which the placement member moves upwards and a return leg along which the placement member moves downwards, wherein the placement member carries the containers placed thereon on the outward leg and ejects the containers between the outward leg and the return leg to the container alignment part, wherein an upper portion of the placement member, the upper portion located on an upper side on the outward leg, includes a first inclined surface and a second inclined surface, wherein the first inclined surface has one end provided on a circular belt side and another end separated from the circular belt, and the first inclined surface is inclined upwards on the outward leg towards the other end, and wherein the second inclined surface has one end continuous with the first inclined surface and another end separated from the circular belt, and the second inclined surface is inclined downwards on the outward leg towards the other end. 7. An automated analyzer which includes a reaction unit which holds containers into which a sample and a reagent are dispensed and a container supply unit which supplies the containers to the reaction unit, wherein the container supply unit includes a container storage part in which a plurality of containers are stored, a container ejection part which ejects the plurality of containers stored in the container storage part, and a container alignment part which aligns the containers ejected from the container ejection part, wherein the container ejection part includes a circular belt, at least one placement member which is provided on the circular belt and on which the containers are placed, and a belt rotation mechanism which rotates the circular belt in one direction and which forms an outward leg along which the placement member moves upwards and a return leg along which the placement member moves downwards, wherein the placement member carries the containers placed thereon on the outward leg and ejects the containers between the outward leg and the return leg to the container alignment part, wherein the at least one placement member provided on the circular belt includes a plurality of placement members provided on the circular belt, and wherein the placement members include projections in lower portions thereof, the lower portions located on a lower side on the outward leg, the projections are displaced relative to the circular belt between the outward leg and the return leg so as to flick the containers placed on the other containers placed on upper portions of the placement members positioned immediately downstream.