Method of managing the operation of a refrigerated truck for transporting heat-sensitive products by modifying the refrigeration power

What is claimed is: 1. A method for managing the operation of a refrigerated truck for transporting heat-sensitive products, of the indirect injection type, where the truck includes at least one chamber for storing the products, a reserve of cryogenic fluid, a heat exchanger, a fan, at least one temperature sensor, the heat exchanger disposed inside said at least one chamber, cryogenic fluid flowing through said heat exchanger system, and a circuit for pressurization of said reserve, said circuit comprising a line with an upstream portion that is connected to a liquid phase of said cryogenic fluid stored in said reserve and a downstream portion that is connected to gas phase of said cryogenic fluid stored in said reserve, said line including a heater, a valve (EV Rp), and a backpressure regulator (Rp), said method comprising the steps of: using said fan to bring air inside said at least one chamber into contact with cold walls of said heat exchanger system, determining, with said at least one temperature sensor, a temperature (T iniet air ) of air coming into contact with said cold walls on account of said use of said fan; regulating an internal temperature (T int ) of said at least one chamber to a setpoint value (T setpoint ) by: determining, in real time a value ΔT equal to the difference between the temperature (T inlet air ) of air coming into contact with said cold walls on account of said use of said fan and the setpoint value (T setpoint ), and activating said pressurization circuit by opening said valve so as to vaporize some of the liquid phase of said cryogenic fluid inside said heater if ΔT is greater than a top setpoint value (ΔT setpoint H ), the vaporization of said liquid phase causing an increase in a pressure of a gas phase in said reserve. 2. The management method of claim 1 , wherein: the truck includes a gas line having an upstream portion connected to the gas phase of said reserve and a downstream portion connected to a liquid line that feeds a liquid phase of said cryogenic fluid to said heat exchanger system, said gas line including a gas valve (EV Gas CTI); and when ΔT drops below a bottom setpoint value (ΔT setpoint B ), said rapid pressurization circuit is deactivated and said gas circuit is activated by opening said gas valve (EV Gas CTI) of said gas line so as to feed gaseous cryogen to said heat exchanger system and maintain said gaseous cryogen feed until the pressure in the vessel drops to a specified level is obtained in said reserve. 3. The management method of claim 1 , wherein when ΔT drops below a bottom setpoint value (ΔT setpoint B ), said rapid pressurization circuit is deactivated by closing said valve (EV Rp) of said pressurization circuit. 4. The management method of claim 1 , wherein the cryogenic fluid is nitrogen.