Control system for spool valve avoiding mechanical stresses

The invention claimed is: 1. A spool valve control, comprising: a housing including a first chamber for receiving a control fluid and a second chamber for supporting a spool shaft having an axis, the spool shaft configured to move along the axis; a flexible membrane separating the first and second chambers, configured to form a flexible barrier to the control fluid in the first chamber; a pressure plate in the second chamber against which the flexible membrane presses in response to changes in pressure of the control fluid; a permanent magnet mounted on the pressure plate in the second chamber; and a round head formed on an end of the spool shaft and composed of a ferromagnetic material, configured to be magnetically attracted to the permanent magnet; wherein a magnetic attraction force vector produced on the round head of the spool shaft by the permanent magnet, remains coaxial with the axis of the shaft, when the pressure plate and the magnet are tilted with respect to the axis of the spool shaft. 2. The spool valve control of claim 1 , wherein the attraction force vector produced on the round head of the spool shaft, remains coaxial with the axis of the shaft, when the pressure of the control fluid is reduced in the first chamber. 3. The spool valve control of claim 1 , wherein a force vector produced on the round head of the spool shaft when the pressure of the control fluid is increased in the first chamber, pushing the magnet against the round head of the spool shaft, remains coaxial with the axis of the spool shaft. 4. The spool valve control of claim 1 , wherein the round head formed on the end of the spool shaft is composed of an alloy of iron, cobalt or nickel. 5. The spool valve control of claim 1 , wherein the permanent magnet is composed of an alloy of neodymium, iron and boron. 6. The spool valve control of claim 1 , wherein the composition of the material for the magnet and the composition for the material of the round head maximizes their hardness and resistance to abrasion or sticking due to their surfaces contacting when the pressure of the control fluid is increased in the first chamber. 7. The spool valve control of claim 1 , wherein the round head is contoured to have a hemispherical surface, to minimize any component of force transverse to the axis of the spool shaft when the surface of the magnet pushes against the surface of the round head of the spool shaft. 8. The spool valve control of claim 1 , wherein abrasion or sticking is minimized that is caused by a tilted orientation of the pressure plate forcing lands of the spool shaft to cause abrasion of internally facing surfaces of a cylindrical barrel supporting the spool shaft in the housing. 9. In a spool valve including a flexible membrane separating a control fluid chamber and an interior chamber, and a pressure plate in the interior chamber against which the flexible membrane presses in response to changes in pressure of control fluid in the control fluid chamber, a spool valve control, comprising: a permanent magnet mounted on the pressure plate in the interior chamber; and a round head formed on an end of a spool shaft in the interior chamber, the round head composed of a ferromagnetic material, configured to be magnetically attracted to the permanent magnet; wherein a magnetic attraction force vector produced on the round head of the spool shaft by the permanent magnet, remains coaxial with an axis of the spool shaft, when the pressure plate and the magnet are tilted with respect to the axis of the spool shaft. 10. The spool valve control of claim 9 , wherein the attraction force vector produced on the round head of the spool shaft, remains coaxial with the axis of the shaft, when the pressure of the control fluid is reduced in the first chamber. 11. The spool valve control of claim 9 , wherein a force vector produced on the round head of the spool shaft when the pressure of the control fluid is increased in the first chamber, pushing the magnet against the round head of the spool shaft, remains coaxial with the axis of the spool shaft. 12. The spool valve control of claim 9 , wherein the round head formed on the end of the spool shaft is composed of an alloy of iron, cobalt or nickel. 13. The spool valve control of claim 9 , wherein the permanent magnet is composed of an alloy of neodymium, iron and boron. 14. The spool valve control of claim 9 , wherein the composition of the material for the magnet and the composition for the material of the round head maximizes their hardness and resistance to abrasion or sticking due to their surfaces contacting when the pressure of the control fluid is increased in the first chamber. 15. The spool valve control of claim 9 , wherein the round head is contoured to have a hemispherical surface, to minimize any component of force transverse to the axis of the spool shaft when the surface of the magnet pushes against the surface of the round head of the spool shaft. 16. The spool valve control of claim 9 , wherein abrasion or sticking is minimized that is caused by a tilted orientation of the pressure plate forcing lands of the spool shaft to cause abrasion of internally facing surfaces of a cylindrical barrel supporting the spool shaft in the housing.