Vacuum insulated appliance with pressure monitoring

What is claimed is: 1. A refrigerator, comprising: a vacuum insulated cabinet structure having a refrigerator compartment and an exterior wrapper with an insulating space disposed therebetween, wherein the refrigerator compartment is positioned within the vacuum insulated cabinet structure and includes an interior wall, and further wherein the exterior wrapper includes an exterior wall that is separated from the interior wall of the refrigerator compartment to define a thickness of the insulating space; a first sensor positioned on the interior wall of the refrigerator compartment, wherein the first sensor is configured to sense a first temperature level of the interior wall of the refrigerator compartment; a second sensor positioned on the exterior wall of the exterior wrapper, wherein the second temperature sensor is configured to sense a second temperature level of the exterior wall of the exterior wrapper; a third sensor positioned within the refrigerator compartment, wherein the third temperature sensor is configured to sense an ambient temperature level within the refrigerator compartment; and a controller operably coupled to the first, second and third sensors for receiving temperature level data therefrom, wherein the controller is configured to: calculate an overall heat transfer coefficient (Q) using the ambient temperature level, the first temperature level, and a convective heat transfer coefficient for the interior wall of the storage compartment; calculate a temperature differential between the second temperature level and the first temperature level; determine a conductivity level (K) using the temperature differential, the overall heat transfer coefficient (Q) and the thickness of the insulating space; and determine a pressure level (P) within the insulating space using the conductivity level (K). 2. The refrigerator of claim 1 , wherein the insulating space includes a polyurethane foam insulating material disposed therein. 3. The refrigerator of claim 1 , wherein the second sensor is positioned on the exterior wall of the exterior wrapper of the vacuum insulated cabinet structure in a manner that is opposed to a position of the first sensor on the interior wall of the refrigerator compartment. 4. The refrigerator of claim 1 , including: a fourth sensor positioned on the exterior wall, wherein the fourth sensor is configured to sense an ambient temperature level for an environment in which the vacuum insulated cabinet structure is disposed. 5. The refrigerator of claim 4 , including: a freezer compartment positioned within the vacuum insulated cabinet structure and having an interior wall; and a fifth sensor positioned on the interior wall of the freezer compartment, wherein the fifth sensor is configured to sense a temperature level of the interior wall of the freezer compartment. 6. The refrigerator of claim 5 , including: a sixth sensor positioned within the freezer compartment, wherein the sixth sensor is configured to sense an ambient temperature level within the freezer compartment. 7. A vacuum insulated cabinet structure, comprising: a storage compartment and an insulating space positioned between interior and exterior walls of the storage compartment; a first temperature sensor positioned on the interior wall of the storage compartment, wherein the first temperature sensor is configured to sense a first temperature level of the interior wall of the storage compartment; a second temperature sensor positioned on the exterior wall of the storage compartment, wherein the second temperature sensor is configured to sense a second temperature level of the exterior wall of the storage compartment; a third temperature sensor positioned outside of the storage compartment, wherein the third temperature sensor is configured to sense an ambient temperature level for an environment in which the storage compartment is disposed; a controller operably coupled to the first, second and third temperature sensors for receiving temperature level data therefrom, wherein the controller is configured to: (i) calculate a first temperature differential between the second temperature level and the first temperature level; (ii) calculate an overall heat transfer coefficient (Q) using the ambient temperature level, the second temperature level, and a convective heat transfer coefficient for the exterior wall of the storage compartment; (iii) determine a first conductivity level (K) using the first temperature differential, the overall heat transfer coefficient (Q) and a thickness of the insulating space; and (iv) determine a first pressure level (P) within the insulating space using the first conductivity level (K). 8. The vacuum insulated cabinet structure of claim 7 , wherein the controller is further configured to receive a plurality of temperature differential levels and calculate an average temperature differential using the plurality of temperature differential levels. 9. The vacuum insulated cabinet structure of claim 8 , wherein the controller is further configured to calculate an average conductivity level using the average temperature differential, the overall heat transfer coefficient (Q) and the thickness of the insulating space. 10. The vacuum insulated cabinet structure of claim 9 , wherein the controller is further configured to determine an average pressure level within the insulating space using the average conductivity level (K). 11. The vacuum insulated cabinet structure of claim 7 , wherein the controller includes a reference chart that chart plots conductivity as a function of vacuum pressure. 12. The vacuum insulated cabinet structure of claim 11 , wherein the reference chart includes conductivity levels through a plurality of resistive mediums. 13. The vacuum insulated cabinet structure of claim 12 , wherein the resistive mediums include one or more mediums selected from the group consisting of fumed silica, precipitated silica, polystyrene foam, polyurethane foam, and glass fibers. 14. The method of claim 7 , wherein the third temperature sensor is positioned on the exterior wall of the storage compartment. 15. The method of claim 7 , wherein the third temperature sensor is spaced-apart from the vacuum insulated cabinet structure. 16. A method of measuring insulation performance, the method comprising the steps of: (i) providing a storage compartment surrounded by an insulation space, a first temperature sensor positioned on a first side of the insulation space, a second temperature sensor positioned on a second side of the insulation space, a third temperature sensor positioned within the storage compartment, and a controller operably coupled to the first, second and third temperature sensors; (ii) sensing a first temperature level (T 1 ) using the first temperature sensor; (iii) sensing a second temperature level (T 2 ) using the second temperature sensor; (iv) calculating a temperature differential (ΔT) by subtracting the first temperature level (T 1 ) from the second temperature level (T 2 ); (v) sensing an ambient temperature level (T i ) within the storage compartment using the third temperature sensor; (vi) calculating an overall heat transfer coefficient (Q) using the ambient temperature level (T i ), the first temperature level (T 1 ), and a convective heat transfer coefficient for the first side of the storage compartment; (vii) determining a first conductivity level (K) using the temperature differential (ΔT), the overall heat transfer coefficient (Q) and a thickness of the insulating space; and (viii) determining a first pressure lev