Rotary internal combustion engine with pilot subchamber and ignition element

1 . A rotary engine comprising: an outer body having walls surrounding an internal cavity; a rotor body rotatable within the internal cavity and cooperating with the walls of the outer body to define at least one chamber of variable volume; an insert in one of the walls of the outer body, the insert having a pilot subchamber defined therein communicating with the internal cavity and including a subchamber wall surrounding the pilot subchamber; a main fuel injector in communication with the internal cavity at a location spaced apart from the insert; a pilot fuel injector in communication with the pilot subchamber; and a heating element extending within the subchamber wall completely outside of the pilot subchamber, the heating element being in heat transfer communication with the subchamber wall. 2 . The engine as defined in claim 1 , wherein the heating element is elongated and extends along an axis. 3 . The engine as defined in claim 2 , wherein the axis is parallel to a longitudinal axis of the insert. 4 . The engine as defined in claim 1 , wherein the subchamber wall forms an indent protruding within the pilot subchamber, and the heating element extends within the subchamber wall against the indent. 5 . The engine as defined in claim 1 , wherein the heating element includes a heatable wire received in a ceramic outer layer. 6 . The engine as defined in claim 1 , wherein the heating element is coiled around the pilot subchamber. 7 . The engine as defined in claim 1 , wherein the heating element extends closer to an inner surface of the pilot subchamber than to an outer surface of the insert. 8 . The engine as defined in claim 1 , wherein the insert is made of a material having one or both of greater high temperature properties and lower thermal conductivity than that of the one of the walls. 9 . The rotary engine as defined in claim 1 , wherein the rotor body defines three apex portions and is engaged to an eccentric portion of a shaft to rotate and perform orbital revolutions within the internal cavity, the internal cavity having an epichotroid shape defining two lobes. 10 . An outer body for a Wankel engine comprising: interconnected walls surrounding an internal cavity having an epichotroid shape, the internal cavity configured to sealingly engage a rotor receivable therein; an insert in one of the interconnected walls, the insert having a pilot subchamber defined therein in communication with the cavity, the insert having a pilot injector hole defined therein in communication with the pilot subchamber and sized to receive a tip of a pilot fuel injector; and a heating element extending within the insert completely outside of the pilot subchamber, the heating element being in heat transfer communication with a wall of the pilot subchamber. 11 . The outer body as defined in claim 10 , wherein the heating element is elongated and extends along an axis. 12 . The outer body as defined in claim 11 , wherein the axis is parallel to a longitudinal axis of the insert. 13 . The outer body as defined in claim 10 , wherein the wall of the pilot subchamber forms an indent protruding within the pilot subchamber, and the heating element extends within the wall of the pilot subchamber against the indent. 14 . The outer body as defined in claim 10 , wherein the heating element includes a heatable wire received in a ceramic outer layer. 15 . The outer body as defined in claim 10 , wherein the heating element is coiled around the pilot subchamber. 16 . The outer body as defined in claim 10 , wherein the heating element extends closer to an inner surface of the pilot subchamber than to an outer surface of the insert. 17 . The outer body as defined in claim 10 , wherein the insert is made of a material having one or both of greater high temperature properties and lower thermal conductivity than that of the walls. 18 . A method of combusting fuel in a rotary engine having a rotor rotating in a cavity, the method comprising: injecting a minor portion of the fuel into a pilot subchamber defined in an insert located in a wall of the engine; heating a portion of the insert defining a wall of the pilot subchamber by activating a heating element received in the insert adjacent the pilot subchamber, the heating element extending in the insert without extending in the pilot subchamber; igniting the fuel in the pilot subchamber with the heated wall of the pilot subchamber; circulating the ignited fuel from the pilot subchamber to the cavity; and injecting a remainder of the fuel into the cavity independently of and spaced apart from the pilot subchamber. 19 . The method as defined in claim 18 , wherein the fuel is heavy fuel. 20 . The method as defined in claim 18 , wherein the heating element is activated in a discrete manner.