Ionization method, ionization apparatus, and mass analysis system

The invention claimed is: 1. An ionization method using an ionization unit having a sample holder configured to hold a sample, an ionization unit drive unit configured to drive the ionization unit, a power supply configured to apply a voltage to the ionization unit, and a sample suction tube, the method comprising the steps of: joining the ionization unit to the tube; sucking the sample from a sample container into a sample holder of the ionization unit to hold the sample; moving the ionization unit holding the sample to a detecting unit using the ionization unit drive unit; and separating the ionization unit and the tube and applying a voltage to the ionization unit using the power supply to ionize the sample by electrostatically spraying the sample from the sample holder, wherein the ionization is performed upon opening of one end of the sample holder by the separation of the ionization unit from the tube thereby allowing the sample to drop from the sample holder from another open end of the sample holder due to the force of gravity. 2. The ionization method according to claim 1 , further comprising the step of moving the sample container containing the sample to the ionization unit. 3. The ionization method according to claim 1 , further comprising the step of moving the ionization unit from the detecting unit to discard the ionization unit using the ionization unit drive unit. 4. The ionization method according to claim 1 , wherein: the ionization unit is an ionization needle including a metal capillary and a sample holding container having a tapered opening; and in the joining step, the opening of the sample holding container is joined to the tube. 5. The ionization method according to claim 1 , wherein in the ionization step, sample supplying is started at the same time when the voltage is applied or after the voltage is applied, and application of the voltage is canceled at the same time when sample supplying is stopped or after sample supplying is stopped. 6. The ionization method according to claim 4 , wherein in the ionization step, the tube is detached in a state in which a pressure of the inside of the sample holder of the ionization unit is not reduced. 7. The ionization method according to claim 1 , further comprising a flow velocity controller configured to control a velocity of sample supplying of the ionization unit, wherein in the ionization step, a flow velocity of the sample supplying is controlled using the flow velocity controller. 8. The ionization method according to claim 4 , wherein a velocity of sample supplying is controlled by an inner diameter of the metal capillary, or a velocity of sample supplying is controlled by a slope of the metal capillary. 9. The ionization method according to claim 1 , further comprising a plurality of the ionization units and a plurality of the sample containers, wherein the ionization unit and the sample container are transported using a transport unit. 10. The ionization method according to claim 1 , wherein the ionization unit comprises a needle or a metallic capillary connected to the sample holder, and the method further comprising a step of washing the ionization unit. 11. The ionization method according to claim 6 , wherein the pressure of the inside of the sample holder of the ionization unit is not reduced in the ionization step by a pressure from a pump, a pressure control by a valve, or a horizontally slide of the tube. 12. The ionization method according to claim 7 , wherein the ionization unit has a porous material, and the flow of sample supplying is controlled so that the sample passes through the porous material. 13. An ionization apparatus comprising: an ionization unit having a sample holder configured to hold a sample; an ionization unit drive unit configured to drive the ionization unit; a power supply configured to apply a voltage to the ionization unit; a sample suction tube; a coupling unit configured to join the ionization unit to the tube; a sucking unit configured to suck the sample from a sample container into a sample holder of the ionization unit and hold the sample; a moving unit configured to move the ionization unit holding the sample to a detecting unit using the ionization unit drive unit; and an ion source unit configured to apply a voltage to the ionization unit using the power supply to ionize the sample by electrostatically spraying the sample from the sample holder after the coupling unit separates the ionization unit and the tube, wherein the ion source is configured to perform the ionization upon opening of one end of the sample holder by the coupling unit separating the ionization unit from the tube thereby allowing the sample to drop from the sample holder from another open end of the sample holder due to the force of gravity. 14. A mass analysis system comprising: an ionization unit having a sample holder configured to hold a sample; an ionization unit drive unit configured to drive the ionization unit; a power supply configured to apply a voltage to the ionization unit; a sample suction tube; a coupling unit configured to join the ionization unit to the tube; sucking unit configured to suck the sample from a sample container into a sample holder of the ionization unit and hold the sample; a moving unit configured to move the ionization unit holding the sample to a detecting unit using the ionization unit drive unit; an ion source unit configured to apply a voltage to the ionization unit using the power supply to ionize the sample by electrostatically spraying the sample from the sample holder after the coupling unit separates the ionization unit and the tube; and a mass analyzing unit configured to analyze the ionized sample, wherein the ion source is configured to perform the ionization upon opening of one end of the sample holder by the coupling unit separating the ionization unit from the tube thereby allowing the sample to drop from the sample holder from another open end of the sample holder due to the force of gravity.