Pumps

The claims defining the invention are as follows: 1. A pump assembly including: a pump impeller comprising: a back shroud extending from the hub, the back shroud having an outer surface and an inner surface; a front shroud having an outer surface and an inner surface; a plurality of pumping vanes extending between the respective inner surfaces of the shrouds, an impeller inlet opening in the front shroud coaxial with the rotation axis of the impeller; one or more flow generating elements which extend from the outer surface of the front shroud in the region of the impeller inlet opening; and a plurality of flow inducer elements, each inducer element being in the form of a vane extending from the inner surface of the front shroud and each vane having a free edge portion which is spaced from the central rotation axis; a flow directing device for directing material in relation to the adjacent moving impeller, the device including a main body having an inner side and an outer side, a plurality of passageways extending between the inner side and the outer side of the main body, at least one passageway providing for the in-use delivery of material to an opening of the impeller and at least one other passageway providing for the in-use circulation of a flow of material past the impeller; and a pump casing comprising: a main body section having a pumping chamber therein, and a discharge outlet extending from the pumping chamber; a strainer section having an intake region therein, with one or more inlets located at the intake region; and a feed opening between the intake region and the pumping chamber; wherein a plurality of flow distribution vanes are positioned in the region of the feed opening; and wherein said impeller is mounted for rotation within said pumping chamber of said main body section of said pump casing, said flow directing device being operatively secured to said pump casing. 2. The pump assembly according to claim 1 wherein, for a plurality of said one or more inlets, said plurality of flow distribution vanes extend from the inlets and are arranged in spaced-apart relation. 3. The pump assembly according to claim 1 wherein said main body section includes a back wall and a peripheral side wall depending from said back wall, wherein the intake region extends from said back wall in a direction opposite to the peripheral side wall. 4. The pump assembly according to claim 1 wherein said intake region includes a generally frusto-conical inner side surface, said one or more inlets being disposed in spaced apart relation around said frusto-conical inner side surface. 5. The pump assembly according to claim 1 wherein said intake region includes a generally frusto-conical inner side surface, and the intake region further includes a frusto-conical inner side surface and the one or more inlets are elongate holes or slots arranged in the frusto-conical inner side surface of the intake region. 6. The pump assembly according to claim 1 , wherein said pumping chamber is generally volute in configuration. 7. A method of assembling a pump assembly according to claim 1 , the method including mounting the impeller within the pumping chamber and operatively securing the flow directing device to the pump casing. 8. A pump impeller having a rotational axis and including: a hub; a back shroud extending from the hub, the back shroud having an outer surface and an inner surface; a front shroud having an outer surface and an inner surface, and having an inner edge; a plurality of pumping vanes extending between the respective inner surfaces of the shrouds, each pumping vane of said plurality of pumping vanes having an inner edge, an impeller inlet opening in the front shroud coaxial with the rotation axis of the impeller, and being located at the inner edge of the front shroud; a flow intake region which is located between the inner edge of the front shroud and the inner edge of the pumping vanes of said plurality of pumping vanes; one or more flow generating vanes arranged in spaced apart fashion and which extend from the outer surface of the front shroud in the region of the impeller inlet opening; and a plurality of flow inducer elements located within the flow intake region, each flow inducer element being in the form of a vane extending from the inner surface of the front shroud towards the rotation axis of the impeller and which is positioned adjacent and arranged circumferentially about the impeller inlet opening in the flow intake region, each flow inducer element having a free edge portion which is spaced from the central rotation axis and being configured to create a swirling flow which extends outwardly and away from the impeller inlet opening. 9. The pump impeller according to claim 8 wherein the front shroud includes an annular wall portion and a projecting wall portion depending therefrom, the projecting wall portion being arranged to extend away from the plurality of pumping vanes to terminate at the inner edge of the front shroud, the impeller inlet opening, in the region of the inner edge of the front shroud, being arranged so as to define the flow intake region. 10. The pump impeller according to claim 9 wherein the projecting wall portion tapers inwardly from the annular wall portion when moving in a direction towards the inner edge of the front shroud. 11. The pump impeller according to claim 10 wherein the projecting wall portion is curved. 12. The pump impeller according to claim 9 wherein the flow inducer vanes are on the inner surface of the projecting wall portion adjacent the inner edge of the front shroud. 13. The pump impeller according to claim 9 wherein the one or more flow generating elements that are in the form of vanes are positioned on the outer surface of the projecting wall portion adjacent the inner edge of the front shroud. 14. The pump impeller according to claim 8 further comprising a group of pumping vanes on the outer surface of the back shroud arranged in spaced relation from one another. 15. The pump impeller according to claim 14 wherein each pumping vane of said group of pumping vanes is curved with one end adjacent an outer peripheral edge of the back shroud and extending inwardly therefrom towards the hub. 16. The pump impeller according to claim 8 wherein each of the flow inducer vanes is generally of an aerofoil shape. 17. The pump impeller according to claim 8 wherein the one or more flow generating vanes are generally of an aerofoil shape. 18. The pump impeller according to claim 8 wherein each flow inducer element of the plurality of flow inducer elements extends towards the rotation axis to a point about half the radius of the impeller inlet opening. 19. The pump impeller according to claim 8 wherein the flow inducer elements are positioned diametrically opposite one another. 20. A flow directing device for directing material in relation to an adjacent moving impeller, the flow directing device comprising a main body having an inner side and an outer side and having a chamber, positioned between the inner side and outer side, which is structured to receive an impeller therein, a peripheral side wall section and a plurality of concentrically arranged ring shaped elements operatively connected together and operatively connected to the peripheral side wall section, thereby defining annular spaces between the plurality of ring shaped elements which provide a plurality of passageways that extend between the inner side and the outer side of the main body