Fluid sending apparatus

The invention claimed is: 1. A fluid sending apparatus comprising: at least one driving mechanism that includes a diaphragm to apply sending force to fluid, the at least one driving mechanism vibrating the diaphragm; and a signal generator including: a drive signal processor configured to generate a signal to vibrate the diaphragm, and an amplifier amplifying the signal generated by the drive signal processor and transmitting an amplified signal to the at least one driving mechanism, wherein the drive signal processor and the amplifier are configured to: supply the amplified signal driving the diaphragm that applies the sending force to the fluid, the amplified driving signal being an uninterrupted single wave consisting of a single positive voltage component and a single negative voltage damping component, the single positive voltage component and the single negative voltage damping component each having a one-sided waveform and together forming the uninterrupted single wave, move the diaphragm from a resting position by driving the diaphragm in accordance with the one-sided waveform of the single positive voltage component of the amplified signal driving the diaphragm, and return the diaphragm to the resting position by driving the diaphragm in accordance with the one-sided waveform of the single negative voltage damping component of the amplified signal driving the diaphragm, wherein the single positive voltage component consists of a rising component of continuously increasing voltage in a positive voltage direction which increases up to a maximum voltage value, and a falling component extending from the maximum voltage value and having a continuously decreasing positive voltage and terminating with an initiation of a falling component of the single negative voltage damping component, a formation time of the single positive voltage component extending from an initiation of the rising component of the single positive voltage component until a termination of the falling component of the single positive voltage component, and wherein the single negative voltage damping component consists of the falling component which has a continuously decreasing negative voltage from an initiation of the falling component to a most negative voltage and a rising component having a continuously increasing voltage in a positive voltage direction from the most negative voltage value, a formation time of the single negative voltage damping component being smaller than the formation time of the single positive voltage component, the single negative voltage damping component having a voltage that is less than or equal to one-half of a voltage of the positive voltage component, wherein the at least one driving mechanism comprises a plurality of the driving mechanisms, and wherein the plurality of the driving mechanisms is driven individually or independently. 2. A fluid sending apparatus comprising: one or more vibrating units, at least one driving mechanism that includes a diaphragm to apply sending force to fluid, the driving mechanism vibrating the diaphragm; and a signal generator including: a drive signal processor configured to generate a signal to vibrate the diaphragm, and an amplifier amplifying the signal generated by the drive signal processor and transmitting an amplified signal to the driving mechanism, wherein the drive signal processor and the amplifier are configured to: supply the amplified signal driving the diaphragm that applies the sending force to the fluid, the amplified driving signal being an uninterrupted single wave consisting of a single positive voltage component and a single negative voltage damping component, the single positive voltage component and the single negative voltage damping component each having a one-sided waveform and together forming the uninterrupted single wave, move the diaphragm from a resting position by driving the diaphragm in accordance with the one-sided waveform of the single positive voltage component of the amplified signal driving the diaphragm, and return the diaphragm to the resting position by driving the diaphragm in accordance with the one-sided waveform of the single negative voltage damping component of the amplified signal driving the diaphragm, wherein the single positive voltage component consists of a rising component of continuously increasing voltage in a positive voltage direction which increases up to a maximum voltage value, and a falling component extending from the maximum voltage value and having a continuously decreasing positive voltage and terminating with an initiation of a falling component of the single negative voltage damping component, a formation time of the single positive voltage component extending from an initiation of the rising component of the single positive voltage component until a termination of the falling component of the single positive voltage component, and wherein the single negative voltage damping component consists of the falling component which has a continuously decreasing negative voltage from an initiation of the falling component to a most negative voltage and a rising component having a continuously increasing voltage in a positive voltage direction from the most negative voltage value, a formation time of the single negative voltage damping component being smaller than the formation time of the single positive voltage component, the single negative voltage damping component having a voltage that is less than or equal to one-half of a voltage of the positive voltage component, wherein the one or more vibrating units including a diaphragm, which is separate from the diaphragm of the at least one driving mechanism, and a first elastic member in combination, wherein the one or more of the vibrating units is arranged in a space at a front of the at least one driving mechanism, and a rear surface of each of the one or more of the vibrating units is connected through an acoustic path to a front surface of the at least one driving mechanism. 3. The fluid sending apparatus of claim 2 , wherein the one or more of the vibrating units comprises at least two vibrating units, and wherein the acoustic paths have different lengths.