Instrumented cutter

The invention claimed is: 1. A rotary cutting tool for creating or enlarging an underground conduit comprising: a tool body defining a cavity having an open leading end; a cutter fitted into the cavity and attached to the tool body with an axis of the cutter extending into the cavity from the open leading end, the cutter having: a cutter body with an outer end portion exposed at the open leading end of the cavity; and at least one connecting section connecting the cutter to the tool body, a cross-section of the at least one connecting section being smaller than a cross-section of the outer end portion, the at least one connecting section further having greater compliance than the outer end portion, wherein the outer end portion and the at least one connecting section are sufficiently movable within the cavity that movement of the outer end portion transverse to the cavity causes strain of the at least one connecting section but the cavity surrounds at least part of the outer end portion sufficiently closely to limit such transverse movement and limit deformation of the at least one connecting section; at least three sensors attached to the at least one connecting section at different azimuthal positions around the axis and arranged to measure force on the outer end portion acting in a plurality of directions transverse to the axis, which force causes strain of the at least one connecting section; and at least three sensors attached to the at least one connecting section at different azimuthal positions around the axis and arranged to measure force on the outer end portion in the axial direction, which force causes strain of the at least one connecting section. 2. The rotary tool of claim 1 , the at least one cutter body including an inner end portion in the cavity and fixed to the tool body, wherein the at least one connecting section extends between and is rigidly connected to the inner and outer end portions, and the at least one connecting section has a cross-section that is smaller than cross-sections of both the inner and outer end portions, and has greater compliance than both the inner and outer end portions. 3. The rotary tool of claim 2 , wherein the outer end portion of the cutter body is cylindrical and at least part of the inner end portion is other than cylindrical and engages a mating part of the cavity that has a shape restricting rotation of the inner end portion. 4. The rotary tool of claim 2 , the at least one connecting section including a plurality of connecting sections extending between and rigidly connected to the inner and outer end portions. 5. The rotary tool of claim 2 , the at least one connecting section including a single connecting section, which single connecting section defines a cylinder extending between and rigidly connected to the inner and outer end portions. 6. The rotary tool of claim 2 , the at least one connecting section including a single connecting section defining a cylinder extending between and rigidly connected to the inner and outer end portions, and the sensors are a plurality of strain sensors attached to an inside wall of the cylinder. 7. The rotary tool of claim 1 , wherein the cavity surrounds at least part of the outer end portion of the at least one cutter sufficiently closely to prevent deformation of the at least one connecting section beyond elastic strain. 8. The rotary tool of claim 1 , wherein the at least one connecting section and the surrounding cavity of the tool body are dimensioned so that spacing between the at least one connecting section and the wall of the cavity is greater than spacing between the outer end portion and the wall of the cavity. 9. The rotary tool of claim 1 , wherein the outer end portion has a cutting face that is exposed at the open leading end of the cavity and which has a Knoop hardness of at least 1600. 10. The rotary tool of claim 1 , wherein the outer end portion is integral with the at least one connecting section. 11. The rotary tool of claim 1 , wherein the sensors include at least one capacitive or inductive sensor that senses a position of the outer end portion relative to the tool body. 12. The rotary tool of claim 1 , wherein the sensors are one or more of an electrical resistance strain gauge, an optical fiber Bragg grating sensor, or a piezoresistive strain sensor. 13. The rotary tool of claim 1 , wherein the tool body is a drill bit body. 14. The rotary tool of claim 1 , wherein the tool body is a reamer or reamer block body. 15. The rotary tool of claim 1 wherein: the at least three sensors arranged to measure force in a plurality of directions transverse to the axis are chevron gauges connected in a Wheatstone bridge sensitive to shear force on the cutter and insensitive to axial loading and temperature changes of the cutter, each of the chevron gauges including a first gauge with a conductive path at 45° to an axis of the cutter and a second gauge with a conductive path orthogonal to that of the corresponding first gauge. 16. The rotary tool of claim 15 wherein: the at least three sensors arranged to measure force in the axial direction are Poisson gauges which are not connected to any of the chevron gauges, each of the Poisson gauges including a first gauge with a conductive path parallel to the axis and a second gauge perpendicular to the axis. 17. The rotary tool of claim 1 wherein: the sensors arranged to measure force in a plurality of directions transverse to the axis comprise two sensors at opposite ends of a notional diameter perpendicular to the axial direction and a further two sensors at opposite ends of another notional diameter perpendicular to both the axis and the first notional diameter; and the sensors arranged to measure force in the axial direction also comprise two sensors at opposite ends of a notional diameter perpendicular to the axial direction and a further two sensors at opposite ends of another notional diameter perpendicular to both the axis and the first notional diameter. 18. The rotary tool of claim 1 wherein the sensors are optical fiber Bragg grating sensors. 19. A method of observing forces on a cutter of a rotary cutting tool comprising: positioning a rotary tool of claim 1 in a wellbore; and observing or recording data from the at least one sensor while operating the tool within a conduit. 20. A downhole cutting tool, comprising: a tool body defining at least one pocket having an open leading end; a cutter in the pocket and attached to the tool body, the cutter having: a cutter body with an outer end portion exposed at the open leading end of the pocket, the pocket dimensions permitting at least some transverse movement of the outer end portion; a connecting section connecting the cutter to the tool body, the connecting section having a different cross-sectional area when compared to a cross-sectional area of the outer end portion and exhibiting greater compliance than the outer end portion, the pocket surrounding the connecting section and providing higher resistance to transverse movement of the connecting section as compared to the outer end portion; and a plurality of strain gauges coupled to a carrier wrapped around an inner surface of the connecting section, the plurality of strain gauges including: at least four chevron gauges connected in a Wheatstone bridge sensitive to shear force on the cutter and insensitive to axial loading and temperature changes of the cutter, each of the at least four chevron gauges including a first gauge with a conductive pa