Cutting elements for a cutting tool and methods of making and using same

The invention claimed is: 1 . A cutting element for a cutting tool, comprising: a sensor element; a body of super hard material having a working surface; the sensor element being attached to a portion of the super hard material; and one or more conducting wires extending from the sensor element through one or more channels extending through the body of super hard material; wherein the sensor element is bonded to the body of super hard material through a layer of ceramic adhesive; wherein the body of super hard material has the working surface and a cavity in the working surface, the layer of ceramic adhesive coating a region of the body of super hard material defining a wall of the cavity, the sensor element being located in the cavity and bonded to the body of super hard material defining the wall of the cavity through the ceramic adhesive coating the wall defining the cavity. 2 . The cutting element of claim 1 , wherein the ceramic adhesive comprises alumina silicate. 3 . The cutting element of claim 1 , wherein the sensor element comprises an electrochemical sensor. 4 . The cutting element of claim 1 , wherein the sensor element comprises one or more electrodes for detecting changes in one or more parameters to be measured indicative of the condition of the cutting element in use and/or one or more measurements relating to the nature of a formation being drilled in use. 5 . The cutting element of claim 1 , wherein the body of super hard material comprises polycrystalline diamond material. 6 . The cutting element of claim 1 , further comprising a substrate attached to the body of super hard material along an interface spaced from and opposing the working surface. 7 . The cutting element of claim 6 , wherein the substrate comprises a cemented carbide material. 8 . The cutting element of claim 6 , wherein the one or more channels and conducting wire(s) extend through the substrate. 9 . The cutting element of claim 1 , wherein the one or more conducting wires are spaced from a wall of the respective channel(s) through which they extend by a layer of insulating material. 10 . The cutting element of claim 9 , wherein the layer of insulating material is bonded to a region of the wall of the respective channel(s) by a layer of ceramic adhesive. 11 . The cutting element of claim 10 , wherein the layer of ceramic adhesive bonding the insulating material to the wall of the respective channel(s) comprises alumina silicate. 12 . The cutting element of claim 1 , wherein an electrical pathway extends through the super hard portion and any substrate attached thereto and is insulated therefrom. 13 . The cutting element as claimed in claim 1 , wherein the body of super hard material comprises polycrystalline diamond (PCD) material and comprises a surface volume that includes no more than 2 wt. % metallic material. 14 . An earth-boring tool, comprising: a body; at least one cutting element according to claim 1 attached to the body; and a data acquisition module configured to receive a signal from the sensor element in the cutting element, through the one or more conducting wires. 15 . A method of forming a cutting element for a cutting tool comprising: a body of super hard material bonded to a substrate along an interface, the body of super hard material having a working surface spaced from and opposing the interface with the substrate; the cutting element further comprising one or more channels extending through the body of super hard material and substrate; inserting one or more insulated conducting wires in a respective one or more of said channels; applying a layer of ceramic adhesive to a portion of the working surface defining a wall of a cavity therein and/or to at least a portion of the surface defining the wall of a respective channel(s) external to the insulated conducting wire(s); heating the ceramic adhesive to bond the adhesive to the portion of the working surface and portion of the surface defining the wall(s) of the respective channel(s); locating a sensor element in the cavity and applying a heat treatment to bond the sensor element the body of super hard material through the layer of ceramic adhesive and electrically connect the one or more conducting wires to the sensor element. 16 . The method of claim 15 , wherein the method further comprises treating the portion of the working surface defining the wall of the cavity therein to increase surface energy of the portion prior to the step of applying the layer of ceramic adhesive. 17 . The method of claim 16 , wherein the step of treating comprises oxidising the portion of the working surface defining the wall of the cavity therein to form an oxidised surface. 18 . The method of claim 17 further comprising treating the oxidised surface with a mixture of methane and hydrogen (CH 4 /H 2 ). 19 . The method of claim 15 , further comprising treating at least a portion of the surface of the insulated conducting wire(s) to form a layer of oxide on said surface. 20 . The method of claim 15 , wherein the body of super hard material comprises polycrystalline diamond material. 21 . The method of claim 15 , wherein the step of locating the sensor element comprises locating one or more electrodes to form the sensor element. 22 . The method of claim 21 , wherein the step of locating the electrodes comprises inserting a first mass of Ni—Cr powder into the cavity and laser sintering the powder to form a first layer; and applying one or more additional masses and one or more sintering processes to generate a layered sintered structure within the cavity.