Regulating temperature during tire vulcanization

What is claimed is: 1. A tire vulcanizing system for regulating a temperature of a heating medium, comprising an axially movable plate and a stationary plate connected by a bladder disposed inside a tire to be vulcanized and at least partially delineating a cavity in which a heating medium circulates, with a fan and a heater being immersed in the heating medium and the heater having one or more heating elements that provide energy to the heating medium traversing thereover before egress along an exit path, wherein at least one temperature sensor is disposed along the exit path and mounted on or near the stationary plate immediately proximate an egress from which the fan delivers the heating medium to the exit path, the at least one temperature sensor being configured to detect a temperature of the heating medium in the cavity and to generate one or more temperature signals indicative of detected heating medium temperature in the cavity; and wherein a monitoring system is provided and is configured to receive the one or more temperature signals and to send one or more commands to adjust the heating medium temperature in the cavity during a curing cycle. 2. The tire vulcanizing system of claim 1 , wherein the fan includes a plurality of blades and a predetermined diametrical extent. 3. The tire vulcanizing system of claim 2 , further comprising a fluid path in communication with both the cavity and at least one conduit delineated in a stationary housing body and through which the heating medium is filled into and extracted from the cavity, wherein the at least one temperature sensor is positioned intermediate the housing body and the diametrical extent of the fan. 4. The tire vulcanizing system of claim 1 , further comprising a controllable motor in communication with a rotating shaft so as to effect circumferential rotation of the fan and impart a prescribed tangential velocity to the heating medium ejected from the exit path. 5. The tire vulcanizing system of claim 1 , wherein the at least one temperature sensor is configured to detect the temperature of the heating medium at regular predetermined time intervals and the monitoring system is configured to delay activation or deactivation of the heater until an identified temperature threshold is maintained for a pre-set number of time intervals. 6. The tire vulcanization system of claim 1 , wherein an axially movable plate is moveable between a vulcanization position, in which the bladder abuts an inner surface of the tire to be vulcanized upon the heating medium attaining a vulcanization pressure, and an extraction position, in which the bladder collapses upon extraction of the heating medium from the cavity. 7. The tire vulcanizing system of claim 6 , wherein the bladder is configured, in the extraction position, to avoid contact with the plurality of blades and the at least one temperature sensor. 8. The tire vulcanizing system of claim 1 , wherein the heating medium comprises nitrogen. 9. The tire vulcanizing system of claim 1 , further comprising a mold for removably accommodating the tire to be vulcanized. 10. The tire vulcanizing system of claim 1 , further comprising at least one programmable controller in signal communication with the vulcanization system for programming at least a portion of at least one cure cycle. 11. A method of detecting and adjusting a temperature of a heating medium in a fluid-tight enclosure in an electric vulcanization system, the method comprising: providing the tire vulcanizing system of claim 1 ; detecting the temperature of the heating medium in the cavity with the at least one temperature sensor and generating the one or more temperature signals indicative of detected temperature; receiving the one or more temperature signals; in response to the detected temperature, generating one or more commands; and in response to the one or more commands, adjusting the heating medium temperature in the cavity during a current curing cycle. 12. The method of claim 11 , further comprising at least one of: initiating a timer upon introducing the heating medium into the cavity; on the basis of the detected heating medium temperature, calculating a thermal flux ϕ that traverses the bladder during a subsequent curing cycle as a function of at least the bladder exchange surface area S and the temperature differential ΔT between the bladder and the heating medium; comparing a calculation of the thermal flux ϕ with a required thermal flux to be realized upon commencement of the subsequent cure cycle; and adjusting the heating medium temperature in the cavity when a comparison between the calculated thermal flux and the required thermal flux indicates non-equivalence therebetween. 13. The method of claim 11 , wherein the commands include: commands to increase the heater output when the detected temperature is below a predetermined temperature setpoint; and commands to decrease the heater output when the detected temperature is at or near the predetermined temperature setpoint. 14. The method of claim 11 , further comprising detecting the temperature of the heating medium at regular predetermined time intervals and delaying the commands until an identified temperature threshold is maintained for a pre-set number of time intervals. 15. The method of claim 11 , further comprising: detecting a heating medium temperature in the cavity during a current curing cycle, calculating an energy required to cure the tire being vulcanized is calculated as a function of at least the energy to be supplied for vulcanization of an inner tire surface, energy lost upon opening the mold between the current curing cycle and a subsequent curing cycle, and energy lost by the vulcanization system during curing; and based upon the calculating step, sending an amount of energy to the heater that is needed for vulcanization of the tire in advance of a subsequent curing cycle.