Thermal energy management system with high cooling capacity in idle and high performance passive battery cooling

What is claimed is: 1. An air conditioning and a battery cooling assembly comprising: an A/C coolant circuit and a coolant circuit, as well as a refrigerant circuit, wherein: the A/C coolant circuit and the coolant circuit are coupled together across a 4/2-way coolant valve in such a way that the A/C coolant circuit and the coolant circuit can be operated separately or can receive a flow in a serial manner; and the A/C coolant circuit further comprises at least one A/C coolant radiator for heat transfer to ambient air, a coolant pump and a condenser, by which the A/C coolant circuit is thermally connected to the refrigerant circuit; and the coolant circuit further comprises at least one battery cooler, a first coolant pump, a drivetrain coolant radiator for heat transfer to the ambient air and a chiller, by which the coolant circuit is thermally connected to the refrigerant circuit; and the refrigerant circuit further comprises at least one compressor, the condenser, an ambient heat exchanger for heat transfer to the ambient air or for heat uptake from the ambient air, a first expansion element and the chiller, wherein the 4/2-way coolant valve connects an outlet of the A/C coolant radiator to an inlet of the drivetrain coolant radiator and a first 3/2-way valve is situated at an outlet of the drivetrain coolant radiator with a connection to the A/C coolant circuit. 2. The air conditioning and the battery cooling assembly according to claim 1 , wherein the refrigerant circuit further comprises a refrigerant heating heat exchanger as an internal condenser for heating a passenger compartment, which is situated in the refrigerant circuit and can be switched to operate in parallel to the condenser or operate instead of the condenser. 3. The air conditioning and the battery cooling assembly according to claim 2 , wherein a second coolant pump or an inverter or an E-engine heat exchanger are formed in the coolant circuit and can receive a flow in parallel with the battery cooler. 4. The air conditioning and the battery cooling assembly according to claim 3 , wherein a front evaporator with a corresponding first upstream expansion element or a rear evaporator with a corresponding second upstream expansion element are arranged in the refrigerant circuit, switched in parallel, or a low pressure collector is situated in the refrigerant circuit before the compressor. 5. The air conditioning and the battery cooling assembly according to claim 4 , wherein an auxiliary heating device is situated at the rear evaporator or at the refrigerant heating heat exchanger. 6. The air conditioning and the battery cooling assembly according to claim 1 , wherein the coolant circuit further comprises a heating device, which is connected in series in front of the battery cooler and in that, furthermore, a bypass to the battery cooler or a bypass to the heating device is formed. 7. The air conditioning and the battery cooling assembly according to claim 1 , wherein a second expansion element is situated in the refrigerant circuit downstream of the condenser and upstream of the ambient heat exchanger. 8. The air conditioning and the battery cooling assembly according to claim 1 , wherein two parallel channels are formed in the coolant circuit for cooling of a front drive and a rear drive. 9. A method for operating an air conditioning and a battery cooling assembly according to claim 4 , wherein, when a refrigerating power is required for battery quick charging, the chiller is operated in the refrigerant circuit and a heat of condensation from the refrigerant circuit is transferred partly across the condenser to an AC coolant circuit and partly across the ambient heat exchanger to the ambient air, wherein the coolant circuit is formed from a series connection of the A/C coolant radiator, the 4/2-way coolant valve and the drivetrain coolant radiator and from the first 3/2-way valve as well as the condenser and heat of condensation is given off to the ambient air, wherein the A/C coolant radiator and the drivetrain coolant radiator are connected in series across the 4/2-way coolant valve and the battery cooler forms a separate coolant circuit with the chiller of the refrigerant circuit and the coolant circuit is connected across a bypass in the circuit with the heat exchangers. 10. The method for operating the air conditioning and the battery cooling assembly according to claim 9 , wherein the front evaporator or the rear evaporator are operated in addition in the refrigerant circuit, besides the chiller, in order to generate cold for air conditioning of the passenger compartment. 11. The method for operating the air conditioning and the battery cooling assembly according to claim 9 , wherein, when the refrigerating power is required for air conditioning of the passenger compartment and cooling of the battery, the chiller and the front evaporator or the rear evaporator are operated in the refrigerant circuit and the heat of condensation from the refrigerant circuit is transferred across the ambient heat exchanger to the ambient air and across the condenser to the A/C coolant circuit and across the A/C coolant radiator to the ambient air, wherein the drivetrain coolant radiator surrenders waste heat from the coolant circuit to the ambient air, and wherein the battery cooler forms a separate coolant circuit with the chiller of the refrigerant circuit. 12. The method for operating the air conditioning and the battery cooling assembly according to claim 9 , wherein, when the refrigerating power is required for air conditioning of the passenger compartment, passive electronic drivetrain cooling, and passive battery cooling, the front evaporator or the rear evaporator are operated in the refrigerant circuit and the heat of condensation from the refrigerant circuit is transferred across the ambient heat exchanger to the ambient air, wherein waste heat from the coolant circuit and from the battery cooler switched in parallel with the drivetrain is given off across the series-connected AC coolant radiator and the drivetrain coolant radiator to the ambient air, wherein the coolant circuit is taken from a second 3/2-way valve across the 4/2-way valve, the condenser and the AC coolant radiator to a third 3/2-way valve as a branching point for a drive cooling channel and a battery cooling channel. 13. The method for operating the air conditioning and the battery cooling assembly according to claim 9 , wherein, during passenger compartment heating and battery heating and when the refrigerating power is required for the active electronic drivetrain cooling, the chiller is operated in the refrigerant circuit and the heat of condensation from the refrigerant circuit is given off to the refrigerant heating heat exchanger to the passenger compartment and across the ambient heat exchanger to the ambient air, wherein the battery cooler is connected with a heating device in a separate circuit to the battery heating. 14. The method for operating the air conditioning and the battery cooling assembly according to claim 9 , wherein, during passenger compartment heating, passive electronic drivetrain heating, and active battery cooling, waste heat from the refrigerant circuit is given off to the refrigerant heating heat exchanger, wherein the battery coolant circuit is connected with the battery cooler and the chiller and the coolant circuit is connected in the circuit with passive self-heating across a bypass. 15. The method for operating the air conditioning and the battery cooling assembly according to claim 9 , wherein, during passenger compartment heating and passive E-drivetrain heating