Electrostatic particle collector

The invention claimed is: 1. An electrostatic precipitator (ESP) particle collector for collecting particles in a particle containing gas stream, comprising an inlet section, a collector section, and an electrode arrangement, the inlet section comprising a flow tube defining a gas flow channel therein bounded by a guide wall extending between an entry end and a collector end that serves as an inlet to the collector section, the entry end comprising an inlet for the particle gas stream and a sheath flow inlet portion for generating a sheath flow around the particle gas stream, the collector section comprising a housing coupled to the flow tube, and a collector plate mounted therein having a particle collection surface, the ESP particle collector configured to allow optical analysis of the collector plate particle collection surface to measure particles collected thereon, the electrode arrangement comprising at least a base electrode positioned below the collection surface and a counter-base electrode positioned at a separation distance L 2 above the collection surface such that an electrical field is generated between the electrodes configured to precipitate said particles on the collection surface, wherein the electric field is in a range of 0.1 kV per mm to 1.5 kV per mm, with an absolute voltage on any said electrode that is less than 10 kV, and wherein a ratio 1 of a radius L 1 of said inlet at the collector end divided by said separation distance L 2 is in a range of 0.8 to 1.2. 2. The ESP particle collector according to claim 1 wherein the collector plate is mounted on a collector plate holder removably mounted in the housing to allow the collector plate to be optically analysed by an external instrument for measurement of particles collected thereon. 3. The ESP particle collector according to claim 1 further comprising a particle measurement instrument arranged in the housing above or below the particle collection surface to measure the particles collected on the particle collection surface. 4. The ESP particle collector according to claim 1 wherein a ratio 2 (L 1 /L 4 ) of the radius L 1 of said inlet divided by a radius L 4 of the base electrode is less than 1. 5. The ESP particle collector according to claim 4 wherein said ratio 2 (L 1 /L 4 ) is less than 0.7, for instance 0.5 or lower. 6. The ESP particle collector according to claim 1 wherein a ratio lim s (Ls/L 1 ) of an inner radius Ls of the said sheath flow relative to the inlet radius L 1 is less than 0.6. 7. The ESP particle collector according to claim 6 wherein said ratio lim s (Ls/L 1 ) is in a range of 0.2 to 0.5. 8. The ESP particle collector according to claim 1 wherein a ratio 3 of the radius L 1 of said inlet divided by a radius L 3 of the collector plate (L 1 /L 3 ) is in a range of 0.05 to 20. 9. The ESP particle collector according to claim 8 wherein said ratio 3 (L 1 /L 3 ) is in a range of 0.1 to 5. 10. The ESP particle collector according to claim 1 wherein the collector plate is made of a transparent conductive or semi-conductor material. 11. An electrostatic precipitator (ESP) particle collector for collecting particles in a particle containing gas stream, comprising an inlet section, a collector section, and an electrode arrangement, the inlet section comprising a flow tube defining a gas flow channel therein bounded by a guide wall extending between an entry end and a collector end that serves as an inlet to the collector section, the entry end comprising an inlet for the particle gas stream and a sheath flow inlet portion for generating a sheath flow around the particle gas stream, the collector section comprising a housing coupled to the flow tube, and a collector plate mounted therein having a particle collection surface, the ESP particle collector configured to allow optical analysis of the collector plate particle collection surface to measure particles collected thereon, the electrode arrangement comprising at least a base electrode positioned below the collection surface and a counter-base electrode positioned at a separation distance L 2 above the collection surface such that an electrical field is generated between the electrodes configured to precipitate said particles on the collection surface, wherein the electric field is in a range of 0.1 kV per mm to 1.5 kV per mm, with an absolute voltage on any said electrode that is less than 10 kV, and wherein a ratio 1 of a radius L 1 of said inlet at the collector end divided by said separation distance L 2 is in a range of 0.8 to 1.2 and wherein the electrode arrangement further comprises a tube electrode around the collector end forming the inlet to the collector section. 12. An electrostatic precipitator (ESP) particle collector for collecting particles in a particle containing gas stream, comprising an inlet section, a collector section, and an electrode arrangement, the inlet section comprising a flow tube defining a gas flow channel therein bounded by a guide wall extending between an entry end and a collector end that serves as an inlet to the collector section, the entry end comprising an inlet for the particle gas stream and a sheath flow inlet portion for generating a sheath flow around the particle gas stream, the collector section comprising a housing coupled to the flow tube, and a collector plate mounted therein having a particle collection surface, the ESP particle collector configured to allow optical analysis of the collector plate particle collection surface to measure particles collected thereon, the electrode arrangement comprising at least a base electrode positioned below the collection surface and a counter-base electrode positioned at a separation distance L 2 above the collection surface such that an electrical field is generated between the electrodes configured to precipitate said particles on the collection surface, wherein the electric field is in a range of 0.1 kV per mm to 1.5 kV per mm, with an absolute voltage on any said electrode that is less than 10 kV, and wherein a ratio 1 of a radius L 1 of said inlet at the collector end divided by said separation distance L 2 is in a range of 0.8 to 1.2 and wherein the sheath flow inlet portion comprises a sheath flow gas inlet, a gas chamber and an annular sheath flow gas outlet surrounding the centre of the flow channel and configured to generate an annular sheath flow along the guide wall of the flow channel surrounding the particle gas stream. 13. An electrostatic precipitator (ESP) particle collector for collecting particles in a particle containing gas stream, comprising an inlet section, a collector section, and an electrode arrangement, the inlet section comprising a flow tube defining a gas flow channel therein bounded by a guide wall extending between an entry end and a collector end that serves as an inlet to the collector section, the entry end comprising an inlet for the particle gas stream and a sheath flow inlet portion for generating a sheath flow around the particle gas stream, the collector section comprising a housing coupled to the flow tube, and a collector plate mounted therein having a particle collection surface, the ESP particle collector configured to allow optical analysis of the collector plate particle collection surface to measure particles collected thereon, the electrode arrangement comprising at least a base electrode positioned below the collection surface and a counter-base electrode positioned at a separation distance L 2 above the collection surface such that an electrical field is generated between the electrodes configured to precipitate said particles on the collection surface, wherein the electric f