Abstract: A droplet forming method, for forming a droplet 27, constituted of a sample liquid 21, on a substrate 5 by applying a pulse voltage P between the sample liquid 21, retained in a nozzle 3, and the substrate 5, disposed opposite a tip of the nozzle 3, to discharge the sample liquid 21 from the tip of the nozzle 3, includes: a waveform measuring step S1 of measuring a temporal waveform of a current I that flows between the sample liquid 21 in the nozzle 3 and the substrate 5; and an application condition determining step S2 of determining, based on the temporal waveform of the current I, an application condition of the pulse voltage P during the forming of the droplet 27 on the substrate 5.

Abstract: A droplet formation method of a mixed liquid is a method that the droplets 71, 72 and 73 are each delivered from each capillary tip to form the droplet 74 of the mixed liquid consisting of a raw material liquid on a substrate by applying a pulse voltage between the raw material liquids stored for each of a plurality of capillaries 1, 2 and 3 and the substrate disposed opposite to each capillary tip. In addition, a droplet formation device of the mixed liquid is provided with a plurality of capillaries for realizing formation of the droplet 74 of the aforementioned mixed liquid, a substrate, a voltage applying device for applying a pulse voltage and a controller for controlling the voltage applying device.

Abstract: The invention provides an ink jet printing method for printing a color image on a printing object by using a plurality of inks, wherein ink nozzles 9a through 9d which house the plurality of inks, respectively, and a dilution nozzle 8 which houses a dilute solution that can dilute the inks are used, the ink is discharged from the ink nozzle 9a by an electrostatic sucking force to form a droplet L on a printing object 4, and then the ink is discharged from the ink nozzle 9b by an electrostatic sucking force and the inks are mixed within the droplet L to form a droplet in an arbitrary additive color. In this case, primary color inks can be accurately mixed within the droplet L.

Abstract: A droplet forming method, for forming a droplet 27, constituted of a sample liquid 21, on a substrate 5 by applying a pulse voltage P between the sample liquid 21, retained in a nozzle 3, and the substrate 5, disposed opposite a tip of the nozzle 3, to discharge the sample liquid 21 from the tip of the nozzle 3, includes: a waveform measuring step S1 of measuring a temporal waveform of a current I that flows between the sample liquid 21 in the nozzle 3 and the substrate 5; and an application condition determining step S2 of determining, based on the temporal waveform of the current I, an application condition of the pulse voltage P during the forming of the droplet 27 on the substrate 5.

Abstract: The invention provides an ink jet printing method for printing a color image on a printing object by using a plurality of inks, wherein ink nozzles 9a through 9d which house the plurality of inks, respectively, and a dilution nozzle 8 which houses a dilute solution that can dilute the inks are used, the ink is discharged from the ink nozzle 9a by an electrostatic sucking force to form a droplet L on a printing object 4, and then the ink is discharged from the ink nozzle 9b by an electrostatic sucking force and the inks are mixed within the droplet L to form a droplet in an arbitrary additive color. In this case, primary color inks can be accurately mixed within the droplet L.

Abstract: A liquid-contained substance analysis device according to this invention comprises: a substrate 14, which is coated on the surface with PVA and which is mirror finished; a first light source 18 for illuminating light onto substrate 14; and light detector 30, which detects the scattered light due to a liquid or a trace of a liquid that exists on substrate 14, and the position of liquid L or trace of liquid L is detected based on the scattered light detected by light detector 30. By then illuminating excitation light from a second light source 20 onto the detected position, the substances contained in liquid L are analyzed.

Abstract: A minute droplet forming apparatus comprises a nozzle 1 for storing therewithin a liquid 2 for forming a droplet 3; a substrate 5, disposed so as to face the tip of the nozzle 1, for mounting the droplet 3 dropped from the tip of the nozzle 1; and a pulse power supply 10 for applying a pulse voltage between an electrode 12 arranged in the liquid 2 within the nozzle 1 and the substrate 5. After a liquid column 2a is formed by projecting the liquid from the nozzle tip by applying the pulse voltage between substrate 5 and the electrode 12, a nickel piece 7 disposed within the nozzle 1 is moved to the tip part of the nozzle 1 by an XYZ stage 9 by way of a magnet 8, so as to enhance the fluid resistance in the nozzle tip part, thereby causing a setback force for returning the liquid 2 into the nozzle 1, by which the droplet 3 is isolated from the liquid column 2a.

Abstract: A droplet formation method of a mixed liquid is a method that the droplets 71, 72 and 73 are each delivered from each capillary tip to form the droplet 74 of the mixed liquid consisting of a raw material liquid on a substrate by applying a pulse voltage between the raw material liquids stored for each of a plurality of capillaries 1, 2 and 3 and the substrate disposed opposite to each capillary tip. In addition, a droplet formation device of the mixed liquid is provided with a plurality of capillaries for realizing formation of the droplet 74 of the aforementioned mixed liquid, a substrate, a voltage applying device for applying a pulse voltage and a controller for controlling the voltage applying device.

Abstract: A liquid-contained substance analysis device according to this invention comprises: a substrate 14, which is coated on the surface with PVA and which is mirror finished; a first light source 18 for illuminating light onto substrate 14; and light detector 30, which detects the scattered light due to a liquid or a trace of a liquid that exists on substrate 14, and the position of liquid L or trace of liquid L is detected based on the scattered light detected by light detector 30. By then illuminating excitation light from a second light source 20 onto the detected position, the substances contained in liquid L are analyzed.

Abstract: A minute droplet forming apparatus comprises a nozzle 1 for storing therewithin a liquid 2 for forming a droplet 3; a substrate 5, disposed so as to face the tip of the nozzle 1, for mounting the droplet 3 dropped from the tip of the nozzle 1; and a pulse power supply 10 for applying a pulse voltage between an electrode 12 arranged in the liquid 2 within the nozzle 1 and the substrate 5. After a liquid column 2a is formed by projecting the liquid from the nozzle tip by applying the pulse voltage between substrate 5 and the electrode 12, a nickel piece 7 disposed within the nozzle 1 is moved to the tip part of the nozzle 1 by an XYZ stage 9 by way of a magnet 8, so as to enhance the fluid resistance in the nozzle tip part, thereby causing a setback force for returning the liquid 2 into the nozzle 1, by which the droplet 3 is isolated from the liquid column 2a.

Abstract: A metal halide lamp comprises a sealed tube containing mercury vapor and halide, and electrodes extending to a center of the sealed tube, supported by sealed portions at both ends of the sealed tube. A notch extending in a direction perpendicular to an axis of the electrode is formed in each electrode. A transverse cross sectional area of a portion where the notch is formed is smaller than the transverse cross sectional area of another portions and functions as a heat dam portion for damming heat. Accordingly, temperature of a proximal portion from the heat dam portion to the support portion is lower than that of the same portion of the conventional electrode, and temperature of a distal end portion is higher than that of the same portion of the conventional electrode. Thus, formation of low-melting alloy due to reaction of the proximal portion of the electrode and the metal halide can be suppressed.