In a discharge generator, a control unit switchably performs a continuous mode and a burst mode based on determination of whether target output power is higher than discharge start power. The burst mode alternately performs a discharge mode and a non-discharge mode. The control unit causes a burst ratio to be set to a value expressed by the following equation b=P.sub.O*/P.sub.fs0 where b represents the burst ratio, P.sub.O* represents the target output power, and P.sub.fs0represents the discharge start power. The burst ratio is defined as a ratio of the discharge period to a burst period. The burst period is the sum of the discharge period and the stop period. The control unit causes, in the burst mode, the switch circuit to output, as the output power, the discharge start power during the discharge period.

An ozone generator with a high voltage electrode and at least one counter electrode which limit a gap in which at least one dielectric is arranged and which is flowed through by a gas flow in the direction of flow. The high voltage electrode and the at least one counter electrode are provided with a connection for an electrical power supply to generate silent discharges. A fabric is arranged in the gas flow. The fabric includes a material combination including at least one wire and at least one electrically non-conductive fiber.

An ozone generating body (3) includes a first electrode (10), a first dielectric (11) that covers the first electrode (10), a second electrode (30), and a second dielectric (31) that covers the second electrode (30). The second dielectric (31) forms a discharge space (DS) between the second dielectric (31) and the first dielectric (11). The ozone generating body (3) further includes a support portion (50) that supports the first dielectric (11) and the second dielectric (31). Young's modulus of the support portion (50) is less than those of the first dielectric (11) and the second dielectric (31).