Particle sensor and particle sensing method

The invention claimed is: 1. A particle sensor, comprising: an input, wherein the input is configured to receive a gas flow, wherein the gas flow comprises entrained particles; an electrostatic particle charging section, the electrostatic particle charging section comprising an ionization electrode within an ionization chamber, wherein the gas flow passes past the ionization chamber and partially enters the ionization chamber, wherein the electrostatic particle charging section is configured to charge particles in the ionization chamber; a particle precipitation section, wherein the particle precipitation section is configured to precipitate the charged particles; a sensor circuit, wherein the sensor circuit is arranged to detect the precipitated particles to produce a sensor signal; a flow sensor arrangement, wherein the flow sensor arrangement is arranged to produce a flow signal, wherein the flow signal is representative of an amount of gas flow between the outside of the ionization chamber and the inside of the ionization chamber; and a controller, wherein the controller is arranged to control a gas flow rate through the particle sensor based on the flow signal. 2. The particle sensor as claimed in claim 1 , wherein the flow sensor arrangement comprises an arrangement of flow rate meters. 3. The particle sensor as claimed in claim 2 , wherein the arrangement of flow meters comprises a first flow meter outside the ionization chamber in the vicinity of an inlet end or an outlet end of the particle charging section, and a second flow meter outside the ionization chamber in the vicinity of a tip of the ionization electrode. 4. The particle sensor as claimed in claim 3 , wherein the second flow meter is between the inlet end of the particle charging section and the tip of the ionization electrode. 5. The particle sensor as claimed in claim 1 , wherein the flow sensor arrangement comprises an arrangement of pressure sensors. 6. The particle sensor as claimed in claim 5 , wherein the arrangement of pressure sensors comprises a first pressure sensor inside the ionization chamber and a second pressure sensor outside the ionization chamber. 7. The particle sensor as claimed in claim 6 , wherein the first pressure sensor is at the inlet end of the ionization chamber and the second pressure sensor is at the outlet end of the particle charging section. 8. The particle sensor as claimed in claim 1 , wherein the precipitation section comprises a parallel-plate particle precipitation section. 9. The particle sensor as claimed in claim 1 , further comprising a non-metallic shield in the ionization chamber. 10. The particle sensor as claimed in claim 1 , wherein the controller is further arranged to control a drivel level applied to the ionization electrode based on the flow signal. 11. A particle sensing method, comprising: receiving a gas flow, wherein the gas flow comprises entrained particles; passing the gas flow through an electrostatic particle charging section, wherein the electrostatic particle charging section comprises an ionization electrode within an ionization chamber, wherein the gas flow is provided past the ionization chamber but partially enters the ionization chamber; charging particles in the ionization chamber; using a particle precipitation section to detect the charge of the precipitated particles to produce a sensor signal; generating a flow signal, wherein the flow signal is representative of an amount of gas flow between the outside of the ionization chamber and the inside of the ionization chamber; and controlling a gas flow rate through the particle sensor based on the flow signal. 12. The method as claimed in claim 11 , further comprising measuring a first flow rate outside the ionization chamber in a vicinity of an inlet end or an outlet end of the particle charging section, and measuring a second flow rate outside the ionization chamber in a vicinity of a tip of the ionization electrode, wherein the signal is based on the relative sizes of the first and second flow rates. 13. The method as claimed in claim 11 , further comprising measuring a first pressure inside the ionization chamber and a second pressure sensor outside the ionization chamber, wherein the signal is based on the difference between the first and second pressures. 14. The method as claimed in claim 13 , further comprising measuring the first pressure at the inlet end of the ionization chamber and measuring the second pressure at the outlet end of the particle charging section. 15. The method as claimed in claim 11 , further comprising controlling a drive signal applied to the ionization electrode based on the flow signal. 16. A particle sensor, comprising: an input, wherein the input is configured to receive a gas flow, wherein the gas flow comprises entrained particles; an electrostatic particle charging section, the electrostatic particle charging section comprising an ionization electrode within an ionization chamber, wherein the gas flow passes past the ionization chamber and partially enters the ionization chamber, wherein the electrostatic particle charging section is configured to charge particles in the ionization chamber; a particle precipitation section, wherein the particle precipitation section is configured to precipitate the charged particles; a sensor circuit, wherein the sensor circuit is arranged to detect the precipitated particles to produce a sensor signal; a flow sensor arrangement, wherein the flow sensor arrangement is arranged to produce a flow signal, wherein the flow signal is representative of an amount of gas flow between the outside of the ionization chamber and the inside of the ionization chamber; and a controller, wherein the controller is arranged to control a drive level applied to the ionization electrode based on the flow signal. 17. A particle sensing method, comprising: receiving a gas flow, wherein the gas flow comprises entrained particles; passing the gas flow through an electrostatic particle charging section, wherein the electrostatic particle charging section comprises an ionization electrode within an ionization chamber, wherein the gas flow is provided past the ionization chamber but partially enters the ionization chamber; charging particles in the ionization chamber; using a particle precipitation section to detect the charge of the precipitated particles to produce a sensor signal; generating a flow signal, wherein the flow signal is representative of an amount of gas flow between the outside of the ionization chamber and the inside of the ionization chamber; and controlling a drive level applied to the ionization electrode based on the flow signal.