Method and device for the energy-efficient control of a plant

The invention claimed is: 1. A method for energy-efficient control of an installation, comprising: providing a plurality of components, at least one component of the plurality of components being configured to adopt at least a first, high-energy active state and a second, low-energy standby state, and individual components in the active state having logical dependencies among one another, each of the plurality of components being switched to the low-energy standby state when they are not required, and each component of the installation having a component-specific interface to one component of the plurality of components, at least one interface to at least one other apparatus and a processing logic unit; storing at each of the plurality of components component-specific time information; ascertaining, by the processing logic unit, non-component-specific time information for at least one component of the plurality of components based on the logical dependencies among each of the plurality of components with respect to at least one other component; and providing, by the processing logic unit, each of the plurality of components with a minimum dwell time which indicates a length of time the at least one component of the plurality of components needs to dwell such that an actual energy savings occurs. 2. The method of claim 1 , wherein said ascertaining the non-component-specific time information occurs via accumulation of suitable component-specific time information. 3. The method of claim 1 , wherein the component-specific time information comprises at least one of: (i) length of time that a component requires to change from the first, high-energy active state to the second, low-energy standby state, (ii) length of time that the component requires to change from the second, low-energy standby state to the first, high-energy active state, and (iii) length of time that the component requires to operate at least in one of the first, high-energy active state and the second, low-energy standby state. 4. The method of claim 1 , wherein at least one of the plurality of components comprises one of an installation component and an infrastructure component. 5. The method of claim 1 , wherein the non-component-specific time information is ascertained by a respective component independently. 6. The method of claim 1 , wherein the calculation of the non-component-specific length of time of a component takes into account the dependencies with respect to other components. 7. The method of claim 1 , wherein the non-component-specific information has a preassigned value, including ∞. 8. The method of claim 1 , wherein the installation is transitioned from a first overall state of energy intake to a second, changed overall state of energy intake by: (i) selecting suitable components by a central controller, (ii) communicating a planned state change to the selected components by suitable control commands, (iii) deciding whether performance of the planned state change by the selected components based on time information stored in the components is possible, and (iv) in an event of a positive decision from the components, performing the state change taking into account known component dependencies. 9. The method of claim 3 , wherein said ascertaining of at least one of the length of time and the performance of the state change that a component requires to change from the second, low-energy standby state to the first, high-energy active state comprises a transgression of an average value of an energy intake during the state change, and wherein said ascertaining is based on increasing a length of time the component requires to change from the second, low-energy standby state to the first, high-energy active state by an additional length of time for modification. 10. The method of claim 1 , wherein, in an event of a malfunction in a component, error handling is made possible, via one of a locally and centrally controlled transfer of control commands from a central controller to the component. 11. An apparatus for performing energy-efficient control in an installation, comprising: a plurality of components, at least one component of the plurality of components being configured to adopt at least a first, high-energy active state and a second, low-energy standby state, individual components in an active state having logical dependencies among one another, each of the plurality of components storing component-specific time information, and each of the plurality of components being switched to the low-energy standby state when they are not required, each component of the installation having: a component-specific interface to component of the plurality of components, at least one interface to at least one other apparatus for performing energy-efficient control, and a processing logic unit configured to: ascertain non-component-specific time information for at least one component of the plurality of components based on logical dependencies among each of the plurality of components with respect to at least one other component, and provide a minimum dwell time which indicates a length of time the at least one component of the plurality of components needs to dwell such that an actual energy savings occurs.