Multiple evaporator control using pwm valve/compressor

The invention claimed is: 1 . An air conditioning system comprising: a compressor having an outlet and an inlet, a condenser operably coupled to the compressor outlet and configured to receive refrigerant fluid from the compressor; a plurality of evaporators each operating and coupled in parallel to the condenser and each having an inlet pressure side and an outlet pressure side and each receiving refrigerant fluid from the condenser via the inlet pressure side and each outputting refrigerant fluid at different evaporator outlet pressures; refrigerant fluid conduits operably coupling the compressor, the condenser and the plurality of evaporators thereby forming a refrigerant fluid circuit for transmission of the refrigerant fluid between the compressor, the condenser, and the plurality of evaporators; and a switch valve operably coupled to the outlet pressure side of each of the plurality of evaporators using the refrigerant fluid conduits, wherein the switch valve is configured to switch between any one evaporator of the plurality of evaporators such that the switch valve provides an inlet pressure of refrigerant fluid to the compressor at a pressure between a highest evaporator outlet pressure and a lowest evaporator outlet pressure of the different outlet pressures of the plurality of evaporators. 2 . The air conditioning system of claim 1 , wherein the compressor is the only compressor operably connected to the air conditioning system. 3 . The air conditioning system of claim 1 , wherein the condenser is the only condenser operably connected to the air conditioning system. 4 . The air conditioning system of claim 3 , wherein the compressor is the only compressor operably connected to the air conditioning system. 5 . The air conditioning system of claim 1 , wherein the switch valve is a pulse width modulation switch valve. 6 . The air conditioning system of claim 5 , wherein the compressor further comprises a pulse width modulation switch that activates and deactivates the compressor. 7 . The air conditioning system of claim 6 , wherein the compressor is a linear compressor and the switch valve is configured to switch between refrigerant flow lines at a rate of at least 30 seconds or faster such that the air conditioning system operates in a non-sequential manner. 8 . The air conditioning system of claim 7 , wherein the switch valve is configured to switch between refrigerant flow lines at a rate of at least about 10 milliseconds or faster and wherein the linear compressor is an oil-less compressor and wherein the system further comprises a plurality of valves, wherein at least one valve is associated with the inlet pressure side of each of the plurality of evaporators and each valve being movable between an open position and closed position in response to a demand signal, and wherein each valve can be simultaneously or individually opened to supply one or more of the plurality of evaporators with refrigerant fluid such that refrigerant fluid is capable of being supplied to one evaporator at a given time or multiple evaporators of the plurality of evaporators at a given time. 9 . The air conditioning system of claim 7 , wherein the linear compressor is an orientation flexible compressor. 10 . The air conditioning system of claim 2 , wherein the compressor is a linear compressor and wherein the switch valve is configured to switch between the refrigerant fluid conduits at a rate of at least about 30 seconds or faster and cause the refrigerant fluid conduits to operate in a sequential manner. 11 . The air conditioning system of claim 10 , wherein the linear compressor is activated and deactivated by a pulse width modulation switching device. 12 . The air conditioning system of claim 11 , wherein the linear compressor is an orientation flexible and oil-less compressor. 13 . The air conditioning system of claim 2 , wherein the compressor is a linear compressor and wherein the switch valve is configured to switch between the refrigerant fluid conduits at a rate of at least about 30 seconds or faster and causes the refrigerant fluid conduits to operate in a sequential manner, thereby allowing the system to emulate a system with the evaporators in parallel. 14 . The air conditioning system of claim 13 , wherein the linear compressor is activated and deactivated by a pulse width modulation switching device. 15 . The air conditioning system of claim 1 , wherein the plurality of evaporators consists of a first evaporator and a second evaporator fluidly connected in parallel in the system and the compressor has a single inlet that receives refrigerant from the first evaporator and the second evaporator after refrigerant passes through a pulse width modulation switch valve operably and fluidly connected to both the first evaporator and the second evaporator. 16 . The air conditioning system of claim 1 , wherein the evaporators of the air conditioning system are spaced within an indoor evaporation and air delivery housing; a first evaporator is associated with a sensible cooling load of a first space to be conditioned and operates at a first refrigerant fluid pressure level; a second evaporator is associated with a latent cooling load of a second space to be conditioned and operates at a second refrigerant fluid pressure level; the compressor is a linear compressor; and wherein the switch valve of the air conditioning system is a pulse width modulation switch valve. 17 . An air conditioning system comprising: an air conditioner cabinet; an evaporation compartment spaced within the air conditioner cabinet for delivering conditioned air to an interior of an enclosure to be conditioned; a condensing system spaced within the air conditioner cabinet for rejecting heat to an exterior of the enclosure to be conditioned, the condensing system comprised of: a condenser; a linear compressor that is activated and deactivated by a pulse width modulation switching device; a pulse width modulation refrigerant flow switch valve having an outlet; at least two evaporators operably connected in parallel with one another with at least one evaporator associated with a sensible cooling load compartment that operates at a first refrigerant fluid pressure and with at least one other evaporator associated with a latent cooling load compartment that operates at a second refrigerant fluid pressure; and a plurality of refrigerant fluid conduits operably connecting the condenser, the linear compressor, and the evaporators into a refrigerant fluid flow circuit such that the evaporators are capable of running simultaneously at different pressure levels and refrigerant flows from the evaporators, to the pulse width modulation refrigerant flow switch valve, and through the pulse width modulation refrigerant flow switch valve; wherein the output fluid pressure from the pulse width modulation refrigerant flow switch valve is delivered to a compressor chamber between the first refrigerant fluid pressure and the second refrigerant fluid pressure. 18 . The air conditioning system of claim 17 , wherein refrigerant is received from the pulse width modulation refrigerant flow switch valve into the compressor through a single inlet of the compressor. 19 . The air conditioning system of claim 17 , wherein the compressor is an oil-less compressor and the air conditioning system further comprises at least one by-pass valve positioned within the refrigerant fluid flow circuit prior to fluid entering each evaporator to regulate flow of refrige