Connector for mounting sensor in pressurized fluid system

What is claimed is: 1. A pressurized fluid system comprising: a supply of pressurized fluid; a common rail fluidly connected to the supply of pressurized fluid; a plurality of fluid conduits each including a housing defining a fluid inlet in fluid communication with the common rail, a fluid outlet, and a fluid reservoir extending between the fluid inlet and the fluid outlet, and at least one of the housings having a first set of threads; a connector including a connector body and a tube body positioned within the connector body, the connector body including a second set of threads engaged with the first set of threads such that the tube body is clamped between the connector body and the housing to form a first seal against the connector body and a second seal against the housing; and a sensing mechanism coupled with the connector and forming a third seal with the connector body; the connector further defining a high pressure fluid passage extending through the connector body and the tube body and fluidly connecting the corresponding fluid reservoir with the sensing mechanism, and a low pressure space structured to drain a fluid leaked from the high pressure passage past either of the first seal or the third seal. 2. The fluid system of claim 1 wherein each of the plurality of fluid conduits includes an accumulator, and further comprising a plurality of fluid delivery devices each coupled with one of the accumulators. 3. The fluid system of claim 2 comprising a fuel system wherein each of the plurality of fluid delivery devices includes a fuel injector. 4. The fluid system of claim 3 wherein the sensing mechanism includes a pressure sensor having a sensing element exposed to a fluid pressure of the high pressure passage. 5. The fluid system of claim 3 further comprising a common drain line in fluid communication with each of the plurality of fluid conduits. 6. The fluid system of claim 1 wherein the connector body defines a longitudinal center axis, and the tube body is coaxially arranged within the connector body and includes a first axial end having a first sealing surface formed thereon and extending circumferentially around the longitudinal center axis, and a second axial end having a second sealing surface formed thereon and extending circumferentially around the longitudinal center axis. 7. The fluid system of claim 6 wherein the tube body and the connector body are structured to rotate relative to one another at the first seal relatively more easily, and the tube body and the connector body are structured to rotate relative to one another at the second seal relatively less easily. 8. The fluid system of claim 7 wherein at least one of a surface area of contact, a diameter of contact, or an angle of contact between the tube body and the connector body at the first seal is different from a corresponding surface area of contact, diameter of contact, or angle of contact between the tube body and the housing at the second seal. 9. The fluid system of claim 8 wherein a diameter of the first seal is greater than a diameter of the second seal. 10. The fluid system of claim 1 wherein the connector body has each of a first bore and a second bore formed therein, and the sensing mechanism is positioned within the first bore and the tube body is positioned within the second bore, wherein the connector body further includes an internal dividing wall positioned axially between the first bore and the second bore, and wherein the high pressure passage extends through the internal dividing wall between the first bore and the second bore, and the low pressure space is in fluid communication with each of the first bore and the second bore. 11. A connector for mounting a sensor in a pressurized fluid system comprising: a connector body defining a longitudinal center axis extending between a first axial connector body end having a first bore formed therein and a second axial connector body end having a second bore formed therein, and the connector body further including an internal dividing wall positioned axially between the first bore and the second bore, and a set of threads structured to engage another set of threads in a housing of a fluid reservoir for clamping the connector to the housing; a tube body coaxially arranged with the connector body within the second bore, and including a first axial tube body end having a first sealing surface structured to form a first seal against the internal dividing wall, and a second axial tube body end having a second sealing surface structured to form a second seal against the housing of the fluid reservoir; a high pressure fluid passage for fluidly connecting the fluid reservoir with a sensor mechanism positioned within the first bore, and including a first segment formed in the connector body and extending through the inner dividing wall between the first bore and the second bore, and a second segment formed in the tube body and extending between the first axial tube body end and the second axial tube body end; and a low pressure fluid space formed in the connector body and in fluid communication with each of the first bore and the second bore, for draining a fluid leaked from the high pressure fluid passage. 12. The connector of claim 11 wherein at least one of a surface area, a diameter, or a surface angle of the first sealing surface is different than a corresponding surface area, diameter, or surface angle of the second sealing surface, such that upon engaging the set of threads of the connector body with the set of threads of the housing the first sealing surface rotates more easily against the connector body than the second sealing surface rotates against the housing. 13. The connector of claim 12 wherein a diameter of the first sealing surface is less than a diameter of the second sealing surface. 14. The connector of claim 13 wherein each of the first sealing surface and the second sealing surface has a spherical shape. 15. The connector of claim 14 wherein a spherical radius defined by the first sealing surface is larger than a spherical radius defined by the second sealing surface. 16. The connector of claim 12 wherein the second bore includes an annular cavity extending circumferentially about the tube body at the first axial tube body end, and the low pressure fluid space is in fluid communication with the second bore by way of the annular cavity. 17. The connector of claim 16 wherein the tube body has an annular groove formed therein, and further comprising an O-ring positioned within the annular groove and within the annular cavity such that the tube body is supported within the second bore. 18. The connector of claim 12 wherein the connector body further includes a third sealing surface located on a first axial side of the internal dividing wall and structured to seal against a sensing mechanism positioned within the first bore, and a fourth sealing surface located on a second axial side of the internal dividing wall and structured to seal against the first sealing surface of the tube body. 19. The connector of claim 18 wherein each of the third sealing surface and the fourth sealing surface extends circumferentially around the longitudinal center axis, and the segment of the high pressure passage within the internal dividing wall extends between the first sealing surface and the second sealing surface. 20. A method of coupling a sensing mechanism with a fluid reservoir in a pressurized fluid system comprising: rotating a connector for mounting the sensing mecha