System and method for managing fluid level in a HVAC system

What claimed is: 1. A spill over tank for managing a fluid level in an evaporator of a HVAC system comprising: a reservoir including an inlet and an outlet; a first fluid line connected to the inlet, and configured to direct refrigerant from the evaporator into the inlet of the reservoir; a fluid level sensor disposed inside the reservoir and configured to measure a refrigerant level in the reservoir; wherein the spill over tank is configured to be positioned outside of the evaporator of the HVAC system, and the outlet is configured to direct the refrigerant received in the reservoir to flow out of the spill over tank. 2. The spill over tank of claim 1 , further comprising a second fluid line connected to the outlet, wherein the second fluid line is configured to direct refrigerant to a heat exchanger, the heat exchanger is configured to receive a heat source and help exchange heat between the heat source and the refrigerant directed into the heat exchanger. 3. The spill over tank of claim 1 , further comprising: a fluid flow regulating device, wherein the fluid flow regulating device is configured to regulate a refrigerant flow flowing out of the outlet of the spill over tank. 4. The spill over tank of claim 3 , wherein the fluid flow regulating device is a flow control valve. 5. The spill over tank of claim 3 , wherein the fluid flow regulating device is a standpipe positioned upstream of the outlet, and the standpipe has a plurality of openings along a height of the standpipe, and the openings are configured to meter the refrigerant flow. 6. A HVAC system, comprising: an evaporator having a shell and a spill over port; and a spill over tank positioned outside of the evaporator of the HVAC system, the spill over tank including a reservoir, a first fluid line, a second fluid line, and a fluid level sensor positioned inside the reservoir; wherein the spill over port is positioned at a side of the shell of the evaporator, the spill over port is configured to direct refrigerant to flow out of the evaporator, the reservoir includes an inlet and an outlet, the first fluid line is connected to the spill over port and the inlet, and directs refrigerant from the evaporator into the reservoir, the second fluid line is connected to the outlet and directs refrigerant to flow out of the reservoir, and the fluid level sensor is configured to measure a refrigerant level in the spill over tank. 7. The HVAC system of claim 6 , further comprising: a tube bundle inside the shell of the evaporator; wherein the tube bundle having a top of the tube bundle, and the spill over port is positioned about the top of the tube bundle. 8. The HVAC system of claim 6 further comprising: a heat exchanger; wherein the second fluid line of the spill over tank is coupled to a heat exchanger, the heat exchanger is configured to receive a heat source. 9. The HVAC system of claim 6 further comprising: a fluid flow regulating device, wherein the fluid flow regulating device is configured to regulate the refrigerant flowing out of the outlet of the reservoir. 10. The HVAC system of claim 9 , wherein the fluid flow regulating device is a flow control valve. 11. The HVAC system of claim 9 , wherein the fluid flow regulating device is a standpipe positioned upstream of the second fluid line, and the standpipe has a plurality of openings along a height of the standpipe, the openings are configured to meter the refrigerant flowing to the second fluid line. 12. A method of maintaining a fluid level in the evaporator of the HVAC system of claim 6 comprising: determining a spill over refrigerant level setpoint in the spill over tank positioned outside of the evaporator based on a desired operational refrigerant level in the evaporator; measuring a spill over refrigerant level in the spill over tank with the fluid level sensor positioned inside of the spill over tank; and comparing the spill over refrigerant level in the spill over tank with the spill over refrigerant level setpoint; wherein when the spill over refrigerant level in the spill over tank is higher than the spill over refrigerant level setpoint, decreasing a refrigerant charge to the evaporator; when the spill over refrigerant level in the spill over tank is lower than the spill over refrigerant level setpoint, increasing the refrigerant charge to the evaporator; and when the spill over refrigerant level in the spill over tank is about the same as the refrigerant level setpoint, maintaining the refrigerant charge to the evaporator. 13. A method of regulating a fluid flow to a compressor of the HVAC system of claim 6 comprising: determining a return refrigerant flow to the compressor; determining a refrigerant level inside the spill over tank to achieve the return refrigerant flow to the compressor, the spill over tank being positioned between the compressor and an evaporator of the HVAC system; measuring a refrigerant level in the spill over tank with the fluid level sensor positioned inside of the spill over tank; and comparing the measured refrigerant level in the spill over tank with the determined refrigerant level; wherein when the measured refrigerant level in the spill over tank is lower than the determined refrigerant level, increasing a refrigerant charge to the evaporator; when the measured refrigerant level in the spill over tank is higher than the determined refrigerant level, decreasing the refrigerant charge to the evaporator; and when the measured refrigerant level in the spill over tank is about the same as the determined refrigerant level, maintaining the refrigerant charge to the evaporator. 14. A method of managing a fluid in a HVAC system comprising: determining a desired flow rate setpoint for refrigerant directed out of an evaporator of the HVAC system, wherein a flow rate of the refrigerant directed out of the evaporator indicates an operational refrigerant level in the evaporator; measuring the flow rate of the refrigerant directed out of the evaporator with a flow rate meter; and comparing the flow rate of the refrigerant directed out of the evaporator with a flow rate setpoint, wherein when the flow rate is lower than the flow rate setpoint, increasing a refrigerant charge to the evaporator, when the flow rate is higher than the flow rate setpoint, decreasing the refrigerant charge to the evaporator, and when the flow rate is about the same as the flow rate setpoint, maintaining the refrigerant charge to the evaporator. 15. The method of claim 14 , wherein the desired flow rate setpoint is determined based on a desired operational refrigerant level in the evaporator. 16. The method of claim 14 further comprising: determining a desired flow rate setpoint based on an oil return requirement of a compressor of the HVAC system; and setting the flow rate setpoint to the desired flow rate setpoint based on the oil return requirement of the compressor of the HVAC system. 17. The method of claim 14 , wherein measuring the flow rate of the refrigerant directed out of the evaporator including: collecting the refrigerant directed out of the evaporator in a collecting device, the collecting device being positioned outside of the evaporator; directing the refrigerant collected in the collection device out of the collection device; and measuring a refrigerant level of the refrigerant collected in the collecting device. 18. The method of claim 6 , wherein the spill over port is positioned at a height that is about the same as a refrigerant level to wet a top of