This machine is connected to a shaft that allows exchange of mechanical power. All machines connected to one shaft contribute to its inertia - stored mechanical power. When shaft is turning too slow, machines cannot use its power (denoted by red marker) and it needs to be charged up first. When inertia is low, the maximum output is limited and connected machines might not get all the power they need. Similarly, when inertia is too high, the maximum input to the shaft is limited and connected machines may not be able to deliver all produced power to the shaft. The shaft has a maximum throughput of {0}.
This machine is connected to a shaft that allows exchange of mechanical power. All machines connected to one shaft contribute to its inertia - stored mechanical power. When shaft is turning too slow, machines cannot use its power (denoted by red marker) and it needs to be charged up first. When inertia is low, the maximum output is limited and connected machines might not get all the power they need. Similarly, when inertia is too high, the maximum input to the shaft is limited and connected machines may not be able to deliver all produced power to the shaft. The shaft has a maximum throughput of {0}.
This machine is connected to a shaft that allows exchange of mechanical power. All machines connected to one shaft contribute to its inertia - stored mechanical power. When shaft is turning too slow, machines cannot use its power (denoted by red marker) and it needs to be charged up first. When inertia is low, the maximum output is limited and connected machines might not get all the power they need. Similarly, when inertia is too high, the maximum input to the shaft is limited and connected machines may not be able to deliver all produced power to the shaft. The shaft has a maximum throughput of {0}.