Cooling device with compressor cabinet heater and a control method

The invention claimed is: 1. A cooling device comprising: one or more cooling cabinets in which items to be cooled are stored, a compressor cabinet external to the one or more cooling cabinets, the compressor cabinet including: a compressor which compresses a refrigerant into a superheated vapor, and a condenser which receives the superheated vapor from the compressor and by condensing enables the superheated vapor to change to first a liquid-vapor phase, then a liquid phase such that the entire superheated vapor forms a condensed fluid, one or more evaporators provided in the one or more cooling cabinets to which the condensed fluid is delivered, wherein the one or more evaporators enable cooling of the one or more cooling cabinets by the condensed fluid flowing through the one or more evaporators absorb heat of the one or more cooling cabinets, a first temperature sensor that detects a temperature inside the compressor cabinet, a second temperature sensor that detects a temperature inside the one or more cooling cabinets, and a heater positioned in the compressor cabinet which is activated when a difference between a first temperature value detected by the first temperature sensor and a second temperature value detected by the second temperature sensor is greater than a predetermined value to prevent formation of vapor block. 2. The cooling device as in claim 1 , further comprising a fan which provides air flow over the condenser and/or the compressor which is activated or deactivated according to the difference between the first temperature value detected by the first temperature sensor and the second temperature value detected by the second temperature sensor. 3. The cooling device as in claim 1 , wherein the first temperature sensor is positioned on the condenser and detects the temperature of the condenser. 4. The cooling device as in claim 1 , wherein the first temperature sensor is positioned on the compressor and detects the temperature of the compressor. 5. The cooling device as in claim 1 , wherein the second temperature sensor is positioned at a refrigerant inlet of the one or more evaporators and a third temperature sensor is positioned at a refrigerant outlet of the one or more evaporators detecting the temperatures at the refrigerant inlet and outlet of the one or more evaporators. 6. The cooling device as in claim 5 , wherein the cooling device is configured to: increase a rotation rate of the compressor, when double phase flow cannot be accomplished, deactivate a fan and activate the heater if the difference between the refrigerant inlet and outlet temperature values of the evaporator is greater than a certain value, thereby reducing viscosity by increasing a refrigerant amount soluble in oil by enabling the double phase flow of the refrigerant, and provide low viscosity oil to recycle back to the compressor. 7. The cooling device as in claim 1 , wherein the second temperature sensor is positioned at an inlet of a capillary tube provided at an end of a pumping line. 8. The cooling device as in claim 1 , wherein the cooling device is configured to: deactivate a fan and activate the heater if the difference between the first temperature value detected by the first temperature sensor and the second temperature value detected by the second temperature sensor is greater than a certain value, bringing a condensation temperature of the refrigerant and consequently a pressure to a desired value, and preventing formation of vapor block at an inlet of a capillary tube provided at an end of a pumping line. 9. The cooling device as in claim 1 , wherein the heater is activated to increase a condensation temperature of the refrigerant in order to prevent formation of vapor block when the refrigerant enters the one or more cooling cabinets. 10. A cooling device comprising: a cooling cabinet in which items to be cooled are stored, a compressor cabinet external to the cooling cabinet, the compressor cabinet including: a compressor which compresses a refrigerant into a superheated vapor, and a condenser which receives the superheated vapor from the compressor and by condensing enables the superheated vapor to change to first a liquid-vapor phase, then a liquid phase such that the entire superheated vapor forms a condensed fluid, an evaporator provided in the cooling cabinet to which the condensed fluid is delivered, wherein the evaporator enables cooling of the cooling cabinet by the condensed fluid flowing through the evaporator absorb heat of the cooling cabinet, a first temperature sensor that detects a temperature at an inlet of the evaporator, a second temperature sensor that detects a temperature at an outlet of the evaporator such that a rotation rate of the compressor is increased according to a difference between a first temperature value detected by the first temperature sensor and a second temperature value detected by the second temperature sensor in order to start double phase flow, a fan which provides air flow over the condenser and/or the compressor, and a heater positioned in the compressor cabinet which is activated when the difference between the first temperature value detected by the first temperature sensor and the second temperature value detected by the second temperature sensor is greater than a predetermined value to prevent formation of vapor block. 11. The cooling device as in claim 10 , wherein the fan which provides air flow over the condenser and/or the compressor is deactivated if the double phase flow cannot be started. 12. The cooling device as in claim 11 , wherein the heater is activated if the double phase flow cannot be started. 13. The cooling device as in claim 12 , wherein the first temperature sensor is positioned at an inlet of a capillary tube provided at an end of a pumping line. 14. A cooling device comprising: two or more cooling cabinets in which items to be cooled are stored, a compressor cabinet external to the two or more cooling cabinets, the compressor cabinet including: a compressor which compresses a refrigerant into a superheated vapor, and a condenser which receives the superheated vapor from the compressor and by condensing enables the superheated vapor to change to first a liquid-vapor phase, then a liquid phase such that the entire superheated vapor forms a condensed fluid, two or more evaporators provided in the two or more cooling cabinets to which the condensed fluid is delivered, wherein the two or more evaporators enable cooling of the two or more cooling cabinets by the condensed fluid flowing through the two or more evaporators absorb heat of the two or more cooling cabinets, a first temperature sensor that detects a temperature inside the compressor cabinet, a second temperature sensor that detects a temperature inside the two or more cooling cabinets, and a heater positioned in the compressor cabinet which is activated when a difference between a first temperature value detected by the first temperature sensor and a second temperature value detected by the second temperature sensor is greater than a predetermined value to prevent formation of vapor block. 15. The cooling device as in claim 14 , further comprising a fan which provides air flow over the condenser and/or the compressor, wherein the fan is activated or deactivated according to the difference between the first temperature value detected by the first temperature sensor and the second temperature value detected by the second temperature sensor. 16. The cooling device as in claim 14 , wherein the first temperature sensor is positi