Spring biased pump stage stack for submersible well pump assembly

The invention claimed is: 1. A submersible well pump, comprising: a housing; a rotatable drive shaft extending along a longitudinal axis of the housing; a plurality of diffusers mounted within the housing; a plurality of impellers, each of the impellers having a hub with an axial hub passage through which the shaft passes; means for mounting the impellers in a stack such that the impellers rotate in unison with the shaft and are axially movable in unison with each other relative to the shaft in response to thrust created by each of the impellers; spacer sleeves located between and in abutment with the hubs of adjacent ones of the impellers, the spacer sleeves and the impellers defining a stack wherein the impellers rotate in unison with the shaft and are axially movable in unison with each other relative to the shaft; a stop shoulder on the shaft that is in abutment with a first end of the stack, enabling thrust caused by the impellers in a first direction to transfer through the stop shoulder to the shaft; and a spring mounted to the shaft in abutment with a second end of the stack, so that when the spring is axially compressed the first end of the stack is urged against the stop shoulder and the spacer sleeves are in abutting contact with hubs of adjacent ones of the impellers. 2. The pump according to claim 1 , further comprising: a first direction gap between each of the impellers and an adjacent one of the diffusers in the first direction, preventing thrust caused by each of the impellers in the first direction from transferring to the adjacent one of the diffusers in the first direction. 3. The pump according to claim 1 , further comprising: a second direction gap between each of the impellers and an adjacent one of the diffusers in the second direction, preventing thrust caused by each of the impellers in the second direction from transferring to the adjacent one of the diffusers in the second direction. 4. The pump according to claim 1 , further comprising: an upstream gap between each of the impellers and an adjacent upstream one of the diffusers, preventing thrust caused by each of the impellers in an upstream direction from transferring to the adjacent upstream one of the diffusers; and a downstream gap between each of the impellers and an adjacent downstream one of the diffusers, preventing thrust caused by each of the impellers in a downstream direction from transferring to the adjacent downstream one of the diffusers. 5. The pump according to claim 4 , wherein: the upstream gap and the downstream gap of each of the impellers have preset dimensions prior to operation of the pump; and the preset dimension of the upstream gap of each of the impellers is larger than the preset dimension of the downstream gap of each of the impellers. 6. The pump according to claim 1 , further comprising: a first direction gap between each of the impellers and an adjacent one of the diffusers in the first direction, preventing thrust caused by each of the impellers in the first direction from transferring to the adjacent one of the diffusers in the first direction; a second direction gap between each of the impellers and an adjacent one of the diffusers in the second direction, preventing thrust caused by each of the impellers in the second direction from transferring to the adjacent one of the diffusers in the second direction; wherein axial movement of the stack in the second direction in response to thrust in the second direction decreases the second direction gap and increases the first direction gap. 7. The pump according to claim 1 , wherein: the first direction is an upstream direction; thrust in the first direction is down thrust; the second direction is a downstream direction; and thrust in the second direction is up thrust. 8. The pump according to claim 1 , wherein the means for mounting the impellers comprises spacer sleeves interspersed between each of the impellers. 9. A submersible well pump, comprising: a housing; a rotatable drive shaft extending along a longitudinal axis of the housing; a plurality of diffusers fixed within the housing for non-movement relative to the housing; a plurality of impellers, that each have a hub with an axial hub passage through which the shaft passes; spacer sleeves located between and in abutment with the hubs of adjacent ones of the impellers, the spacer sleeves and the impellers defining a stack wherein the impellers rotate in unison with the shaft and are axially movable in unison with each other relative to the shaft; a stop shoulder on the shaft, a first end of the stack being in abutment with the stop shoulder, providing a first direction limit for axial movement relative to the shaft in the first direction; a spring mounted in compression around the shaft in abutment with a second end of the stack, the spring urging the first end of the stack against the stop shoulder and urging the spacer sleeves to remain in abutment with the hubs of adjacent ones of the impellers; and wherein movement of the stack in the second direction relative to the shaft requires further compression of the spring. 10. The pump according to claim 9 , wherein the first end of the stack is upstream from the second end of the stack. 11. The pump according to claim 9 , further comprising: an axial up thrust gap between a downstream facing surface of each of the impellers and an upstream facing surface of an adjacent downstream one of the diffusers that is free of any structure that would transfer up thrust between each of the impellers to the adjacent downstream one of the diffusers. 12. The pump according to claim 11 , wherein further compression of the spring from an initial set position in response to axial movement of the stack relative to the shaft reduces but does not close the up thrust gap. 13. The pump according to claim 9 , further comprising: an axial down thrust gap between an upstream facing surface of each of the impellers and a downstream facing surface of an adjacent upstream one of the diffusers that is free of any structure that would transfer down thrust between each of the impellers to the adjacent upstream one of the diffusers. 14. The pump according to claim 13 , wherein further compression of the spring from an initial set position in response to axial movement of the stack relative to the shaft increases the down thrust gap from an initial set position. 15. The pump according to claim 9 , wherein all down thrust caused by operation of the impellers transfers to the stop shoulder and to the shaft. 16. A submersible well pump assembly, comprising: an electrical motor having a drive shaft assembly; a pump driven by the drive shaft assembly of the motor, the pump comprising: a housing; a driven shaft within the housing extending along a longitudinal axis of the housing, the driven shaft being rotated by the drive shaft; a plurality of diffusers immovably fixed within the housing; a stack of impellers that rotates in unison with the driven shaft, each of the impellers having a hub with an axial hub passage through which the driven shaft passes; spacer sleeves being located between and in abutment with the hubs of adjacent ones of the impellers in the stack; a stop shoulder on the driven shaft, a lower end of the stack being in abutment with the stop shoulder, wherein down thrust exerted by the impellers within the stack transfers through the spacer sleeves to the stop shoulder and from the stop shoulder to the driven shaft; a spring mounted around the driven shaft, the spring having an upper end axially