Heating system, electric or hybrid vehicle comprising such a heating system and method for operating a heating system

What is claimed is: 1. A heating system for an electric or hybrid vehicle, to which a high-voltage accumulator is connected, the system comprising: a first refrigerating circuit and a coolant circuit, said coolant circuit having a heating circuit, to which a heating heat exchanger is connected, for air-conditioning an interior of the vehicle, and having a cooling circuit to which a cooler and a heat source are connected, wherein the first refrigerating circuit has an air-conditioning evaporator for air-conditioning the interior, and a first condenser, by which the first refrigerating circuit is thermally coupled to the coolant circuit, for discharging heat from the first refrigerating circuit; and a separate, second refrigerating circuit which is hydraulically separated from the first refrigerating circuit, which has a second condenser and which by way of the second condenser is thermally coupled to the coolant circuit, for discharging heat from the second refrigerating circuit, wherein at least one of the first and second refrigerating circuits has a chiller for discharging heat from the coolant circuit. 2. The heating system as claimed in claim 1 , wherein the first and second condensers are connected in parallel and are connected to the heating circuit upstream of the heating heat exchanger. 3. The heating system as claimed in claim 2 , wherein a first chiller is connected to the first refrigerating circuit, a second chiller is connected to the second refrigerating circuit, and the coolant circuit has an HVA circuit to which the high-voltage accumulator and the first and second chillers are connected, wherein the first and second chillers are disposed downstream of the high-voltage accumulator. 4. The heating system as claimed in claim 1 , wherein one of the first and second condensers is connected to the heating circuit upstream of the heating heat exchanger, and the other of the first and second condensers is connected in an HHE bypass, for bypassing the heating heat exchanger. 5. The heating system as claimed in claim 4 , wherein a first chiller is connected to the first refrigerating circuit, a second chiller is connected to the second refrigerating circuit, and the coolant circuit has an HVA circuit to which the high-voltage accumulator and the first and second chillers are connected, wherein the first and second chillers are disposed downstream of the high-voltage accumulator. 6. The heating system as claimed in claim 1 , wherein the first and second condensers are connected in sequence and are connected to the heating circuit upstream of the heating heat exchanger. 7. The heating system as claimed in claim 6 , wherein a first chiller is connected to the first refrigerating circuit, a second chiller is connected to the second refrigerating circuit, and the coolant circuit has an HVA circuit to which the high-voltage accumulator and the first and second chillers are connected, wherein the first and second chillers are disposed downstream of the high-voltage accumulator. 8. The heating system as claimed in claim 1 , wherein the chiller is connected to the first refrigerating circuit, and an HVA evaporator is connected to the second refrigerating circuit for cooling the high-voltage accumulator. 9. The heating system as claimed in claim 8 , wherein an additional HVA evaporator, which is connected to the first refrigerating circuit, is disposed such that the high-voltage accumulator is connected to both the first and second refrigerating circuits. 10. The heating system as claimed in claim 1 , wherein the chiller is connected to the second refrigerating circuit, and the coolant circuit has an HVA circuit to which the high-voltage accumulator and the chiller are connected, wherein the chiller is disposed downstream of the high-voltage accumulator. 11. The heating system as claimed in claim 1 , wherein a first chiller is connected to the first refrigerating circuit, a second chiller is connected to the second refrigerating circuit, and the coolant circuit has an HVA circuit to which the high-voltage accumulator and the first and second chillers are connected, wherein the first and second chillers are disposed downstream of the high-voltage accumulator. 12. The heating system as claimed in claim 11 , wherein the first and second chillers are connected in sequence. 13. The heating system as claimed in claim 11 , wherein the first and second chillers are connected in parallel. 14. The heating system as claimed in claim 11 , wherein one of the first and second chillers is disposed downstream of the high-voltage accumulator as well as downstream of the heat source, and the other of the first and second chillers is disposed downstream of the high-voltage accumulator and parallel to the heat source. 15. The heating system as claimed in claim 1 , wherein at least one further, separate refrigerating circuit is disposed additionally to the first and second refrigerating circuits, said further refrigerating circuit being separate from the first and second refrigerating circuits and, by way of a further condenser, being thermally connected to the coolant circuit. 16. An electric or hybrid vehicle, comprising: a high-voltage accumulator for supplying power to a drivetrain of the vehicle, and a heating system as claimed in claim 1 , wherein the heating system is configured for air-conditioning the interior as well as for air-conditioning the high-voltage accumulator, and has the first and second refrigerating circuits which are hydraulically separated from one another, and a common coolant circuit, which is thermally coupled to the first and second refrigerating circuits, for exchanging heat with the latter. 17. A method of operating a heating system for an electric or hybrid vehicle, to which a high-voltage accumulator is connected, the heating system comprising: a first refrigerating circuit and a coolant circuit, said coolant circuit having a heating circuit, to which a heating heat exchanger is connected, for air-conditioning an interior of the vehicle, and having a cooling circuit to which a cooler and a heat source are connected, wherein the first refrigerating circuit has an air-conditioning evaporator for air-conditioning the interior, and a first condenser, by which the first refrigerating circuit is thermally coupled to the coolant circuit, for discharging heat from the first refrigerating circuit; and a separate, second refrigerating circuit which is hydraulically separated from the first refrigerating circuit, which has a second condenser and which by way of the second condenser is thermally coupled to the coolant circuit, for discharging heat from the second refrigerating circuit, wherein at least one of the first and second refrigerating circuits has a chiller for discharging heat from the coolant circuit, the method of operating the heating system comprising the acts of: (a) assigning each of the first and second refrigerating circuits a number of air-conditioning tasks having, in each case, one air-conditioning requirement; and (b) activating or deactivating, via a control unit, the first and second refrigerating circuits independently of one another in order for the respective air-conditioning requirement to be met.