Slim pump

What is claimed is: 1. A pump comprising: a frame including an interior separated by a partitioning board into a first chamber and a second chamber, wherein a flow inlet intercommunicates with the first chamber and a flow outlet intercommunicates with the second chamber, and wherein the first chamber is intercommunicated with the second chamber via a communication hole of the partitioning board; a shaft-coupling portion located in the frame; a stator disposed around the shaft-coupling portion and located within an axial extent of the first chamber, wherein the stator is axially aligned with the communication hole; and an impeller including a plurality of blades and an inlet opening located in the second chamber, wherein the inlet opening faces and axially aligns with the communication hole in an axial direction, wherein the communication hole is located between the impeller and the stator in the axial direction. 2. The pump as claimed in claim 1 , wherein the impeller includes a shaft rotatably coupled to the shaft-coupling portion, wherein the shaft is connected to a hub, wherein a top disc is connected to blade top edges of the plurality of blades and the hub, wherein an annular member is connected to blade bottom edges of the plurality of blades, and wherein the inlet opening is formed between an annular inner edge of the annular member and the hub. 3. The pump as claimed in claim 2 , wherein the communication hole is axially aligned within a diametric extent of the annular inner edge of the annular member. 4. The pump as claimed in claim 2 , wherein the top disc includes a disc outer edge, wherein the annular member has an annular outer edge, and wherein the disc outer edge of the top disc and the annular outer edge of the annular member are flush with blade outer edges of the plurality of blades. 5. The pump as claimed in claim 2 , wherein the impeller includes a magnetic member coupled to the hub and disposed around the shaft-coupling portion, and wherein the magnetic member is radially or axially aligned with the stator. 6. The pump as claimed in claim 2 , wherein the frame includes a backstop disposed around the communication hole, and wherein the backstop is located between the partitioning board and the annular member. 7. The pump as claimed in claim 1 , wherein the first chamber is axially adjacent to the second chamber, and wherein the flow inlet and the flow outlet are on a radial side of the frame. 8. The pump as claimed in claim 1 , wherein the stator is located in the first chamber, and wherein the impeller is configured to drive an electrically nonconductive fluid to flow. 9. The pump as claimed in claim 1 , wherein the frame includes a body on which the partitioning board is disposed, a bottom board connected to the body, and a lid connected to the body, wherein the first chamber is formed between the partitioning board and the bottom board, and wherein the second chamber is formed between the lid and the partitioning board. 10. The pump as claimed in claim 9 , wherein the bottom board includes an elevated portion located within the axial extent of the first chamber, and wherein the stator is received in the elevated portion and located outside of the frame. 11. The pump as claimed in claim 6 , wherein the backstop is contiguous to an inner periphery of the communication hole. 12. A slim pump comprising: a frame including an interior separated by a partitioning board into a first chamber and a second chamber, wherein a flow inlet intercommunicates with the first chamber and a flow outlet intercommunicates with the second chamber, and wherein the first chamber is intercommunicated with the second chamber via a communication hole of the partitioning board; a shaft-coupling portion located in the frame; a stator disposed around the shaft-coupling portion and located within an axial extent of the first chamber, wherein the stator is axially aligned with the communication hole; an impeller including a plurality of blades and an inlet opening located in the second chamber, wherein the inlet opening faces and axially aligns with the communication hole, wherein the impeller includes a shaft rotatably coupled to the shaft-coupling portion, wherein the shaft is connected to a hub, wherein a top disc is connected to blade top edges of the plurality of blades and the hub, wherein an annular member is connected to blade bottom edges of the plurality of blades, and wherein the inlet opening is formed between an annular inner edge of the annular member and the hub; and a guiding unit coupled to the impeller to rotate therewith, wherein the guiding unit includes a plurality of auxiliary flow guiding members disposed around the shaft-coupling portion, wherein each two adjacent auxiliary flow guiding members form a passageway therebetween, and wherein the plurality of auxiliary flow guiding members is located within a diametric extent of the communication hole. 13. The pump as claimed in claim 12 , wherein the guiding unit includes a disc seat connected to the hub and an inner edge of each of the plurality of auxiliary flow guiding members. 14. The pump as claimed in claim 13 , wherein the disc seat includes a coupling portion and a sleeve connected to the coupling portion, wherein the coupling portion is connected to the hub, wherein the sleeve is located around the shaft-coupling portion, wherein the inner edges of the plurality of auxiliary flow guiding members are connected to the sleeve, and wherein the inlet opening is located between the plurality of blades and the plurality of auxiliary flow guiding members. 15. The pump as claimed in claim 14 , wherein the plurality of auxiliary flow guiding members extends radially beyond the hub, and wherein an outer edge of each of the plurality of auxiliary flow guiding members is axially aligned with the inlet opening. 16. The pump as claimed in claim 12 , wherein a number of the plurality of auxiliary flow guiding members is greater than a number of the plurality of blades. 17. The pump as claimed in claim 12 , wherein the shaft is coupled to a central disc of the hub, wherein each of the plurality of auxiliary flow guiding members has a top portion coupled to the central disc of the hub, and wherein each of the plurality of auxiliary flow guiding members has a bottom portion extending into the first chamber. 18. The pump as claimed in claim 12 , wherein the guiding unit includes an extension seat connected to an outer edge of each of the plurality of auxiliary flow guiding members, and wherein a magnetic member is coupled to the extension seat and is axially or radially aligned with the stator. 19. A pump comprising: a frame including an interior separated by a partitioning board into a first chamber and a second chamber, wherein a flow inlet intercommunicates with the first chamber and a flow outlet intercommunicates with the second chamber, and wherein the first chamber is intercommunicated with the second chamber via a communication hole of the partitioning board; a shaft-coupling portion located in the frame; a stator disposed around the shaft-coupling portion and located within an axial extent of the first chamber, wherein the stator is axially aligned with the communication hole; and an impeller including a plurality of blades and an inlet opening located in the second chamber, wherein the inlet opening faces and axially aligns with the communication hole, wherein the stator is located in the first chamber, wherein the impeller is configured to drive an electrically nonconductive fl