Abstract: A dielectric barrier discharge lamp (14) has an inside electrode (142) in a tube axis direction within the airtight container (141), which has ultraviolet transmission properties and a long tube shape, and an outside electrode (143) having a semicircular shape arranged outside of the airtight container (141) in close contact with it. Besides, an excimer-forming gas is sealed in the airtight container (141). AC voltage supplied from the power source (11) is converted into DC voltage through a converter (12) and outputted. A high-frequency wave is generated by an inverter (13) based on the DC voltage supplied from the converter (12), and a dielectric barrier discharge is induced in the dielectric barrier discharge lamp (14) to irradiate ultraviolet rays. The converter (12) is configured by connecting in series the outputs of DC power sources (121), (122).

Abstract: The lighting device for a discharge lamp includes a bridge type rectifying and converting circuit CR1, feedback circuits FB1, FB2, a chopper circuit CR2, a charge circuit CR3, a resonant circuit CR4 resonates with a high frequency signal and lights discharge lamp DL connected to the output end by the resonant voltage, an inverter circuit CR5 which converts the DC power stored in the charge circuit by an alternate switching action of a pair of switching elements Q1 and Q2 into high frequency AC power, and a switch device connected between a connecting point J3 of capacitors C1, C2 of the charge circuit and a connecting point J2 of a pair of rectifying elements D1, D2. The lighting device for a discharge lamp can correspond to a multiple variation of a power supply voltage by a construction which uses the same switching elements by step-up chopper circuit and by inverter circuit in common and changes duty factor of the switching elements within a predetermined range.

Abstract: A dielectric barrier discharge lamp 14 has an inside electrode 142 in a tube axis direction within the airtight container 141, which has ultraviolet transmission properties and a long tube shape, and an outside electrode 143 having a semicircular shape arranged outside of the airtight container 141 in close contact with it. Besides, an excimer-forming gas is sealed in the airtight container 141. AC voltage supplied from the power source 11 is converted into DC voltage through a converter 12 and outputted. A high-frequency wave is generated by an inverter 13 based on the DC voltage supplied from the converter 12, and a dielectric barrier discharge is induced in the dielectric barrier discharge lamp 14 to irradiate ultraviolet rays. The converter 12 is configured by connecting in series the outputs of DC power sources 121, 122. Optimum luminous efficiency of a dielectric barrier discharge lamp having different specifications is also realized by adjusting the number of DC power sources.

Abstract: An inductor for performing a chopper operation by turning on or off a first switching element MOSFET Q1 and obtaining an increased voltage is arranged on the secondary side of a transformer 112 and on the basis of the turn ratio of the transformer 112, a high voltage at the time of stable lighting can be obtained from a DC power source 111 at a low voltage Vin. Further, when the on-duties of the first and second switching elements MOSFET Q1 and Q2 constituting an inverter circuit are made almost similar, the timings of application of the power to both ends of a lamp 144 can be made similar, so that the life span of the lamp can be improved.

Abstract: An inductor for performing a chopper operation by turning on or off a first switching element MOSFET Q1 and obtaining an increased voltage is arranged on the secondary side of a transformer 112 and on the basis of the turn ratio of the transformer 112, a high voltage at the time of stable lighting can be obtained from a DC power source 111 at a low voltage Vin. Further, when the on-duties of the first and second switching elements MOSFET Q1 and Q2 constituting an inverter circuit are made almost similar, the timings of application of the power to both ends of a lamp 144 can be made similar, so that the life span of the lamp can be improved.

Abstract: An induction heating roller device that keeps leakage current within specifications and prevents the occurrence of erroneous operations caused by common mode noise. The induction heating roller device includes an induction coil, a grounded heating roller magnetically coupled to the induction coil and heated by electro-magnetic induction. A power factor improving capacitor is connected in parallel to and near the induction coil and has a grounded intermediate point. A high-frequency power source biases the induction coil. The leakage current produced by distributed capacitance between the induction coil and the heating roller is returned to the high-frequency power source via the power factor improving capacitor. Thus, the leakage current does not flow out of the induction heating roller device.

Abstract: An induction heating roller device that keeps leakage current within specifications and prevents the occurrence of erroneous operations caused by common mode noise. The induction heating roller device includes an induction coil, a grounded heating roller magnetically coupled to the induction coil and heated by electro-magnetic induction. A power factor improving capacitor is connected in parallel to and near the induction coil and has a grounded intermediate point. A high-frequency power source biases the induction coil. The leakage current produced by distributed capacitance between the induction coil and the heating roller is returned to the high-frequency power source via the power factor improving capacitor. Thus, the leakage current does not flow out of the induction heating roller device.

Abstract: An induction heating roller device that reduces noise emission to the outside and facilitates insulating between induction coils and nearby metal materials. The induction heating roller device includes a heating roller, a plurality of induction coils arranged in the axial direction of the heating roller, and a high-frequency power source for supplying high-frequency power to the plurality of induction coils. The high-frequency power source has a first output terminal set at a stable potential, and a second output terminal set at a non-stable potential. A pair of induction coils are arranged at the ends of the heating roller and a first end of the coils is positioned at the end of the heating roller and a second end of the coils is positioned in the central side of the heating roller. The first end of each of the two induction coils is connected to the first output terminal, and the second end of each of the two induction coils is connected to the second output terminal.