A system for controlling a filling level of a reservoir filled with a liquid includes the reservoir configured to be filled with the liquid at least up to a maximum filling level. The system also includes a probe including a probe body, at least a section of the probe body extending, in a height dimension of the reservoir, from a first position to a second position, the first position being lower than the second position, and the second position being above the maximum filling level, and further including a temperature dependent sensor configured to generate a sensor signal based on a temperature at the second position, the temperature depending on the filling level. The system also includes a controller for controlling the filling level of the reservoir depending on the sensor signal such that the filling level is kept constant.

A system for dispensing feed to a feed bunk can include a dispensing unit and a control module. The dispensing unit can include a feed container to receive feed, and one or more dispensing devices operatively coupled to the feed container. The control module can be in communication with the dispensing unit and configured to receive and store sequence data from a central computer system, the sequence data comprising a delivery sequence according to which one or more feed bunks are to be filled, and one or more system inputs. The control module is configured to disable the dispensing unit if any system input does not correspond to the sequence data.

Methods and apparatus for optimally positioning objects for automated machining are described herein. An example build file generator described herein includes an object file manager to identify a first toolpath volume associated with a first object to be formed via an additive manufacturing (AM) process. The first toolpath volume is based on a first toolpath of a first post-manufacturing process to be used on the first object. The object file manager is also to identify a second toolpath volume associated with a second object to be formed via the AM process. The second toolpath volume is based on a second toolpath of a second post-manufacturing process to be used on the second object. The example build file generator also includes a layout determiner to determine a layout of the first and second objects to be formed on a substrate by the AM process based on the first and second toolpath volumes.

Methods and apparatus for optimally positioning objects for automated machining are described herein. An example build file generator described herein includes an object file manager to identify a first toolpath volume associated with a first object to be formed via an additive manufacturing (AM) process. The first toolpath volume is based on a first toolpath of a first post-manufacturing process to be used on the first object. The object file manager is also to identify a second toolpath volume associated with a second object to be formed via the AM process. The second toolpath volume is based on a second toolpath of a second post-manufacturing process to be used on the second object. The example build file generator also includes a layout determiner to determine a layout of the first and second objects to be formed on a substrate by the AM process based on the first and second toolpath volumes.

Methods and apparatus for optimally positioning objects for automated machining are described herein. An example build file generator described herein includes an object file manager to identify a first toolpath volume associated with a first object to be formed via an additive manufacturing (AM) process. The first toolpath volume is based on a first toolpath of a first post-manufacturing process to be used on the first object. The object file manager is also to identify a second toolpath volume associated with a second object to be formed via the AM process. The second toolpath volume is based on a second toolpath of a second post-manufacturing process to be used on the second object. The example build file generator also includes a layout determiner to determine a layout of the first and second objects to be formed on a substrate by the AM process based on the first and second toolpath volumes.

The present invention relates to a cutting process simulation method and a system thereof which can efficiently optimize the decommissioning process of a nuclear facility, thereby saving costs and time and ensuring safety in the decommissioning process. The cutting process simulation system, according to one embodiment of the present invention, may comprise: a display unit: and a control unit which cuts a cutting target in a nuclear facility by using a design program, displays the cut shape on the display unit, and predicts the amount of secondary waste generated in the process of cutting the cutting target.

A system for controlling a filling level of a reservoir filled with a liquid includes the reservoir configured to be filled with the liquid at least up to a maximum filling level. The system also includes a probe including a probe body, at least a section of the probe body extending, in a height dimension of the reservoir, from a first position to a second position, the first position being lower than the second position, and the second position being above the maximum filling level, and further including a temperature dependent sensor configured to generate a sensor signal based on a temperature at the second position, the temperature depending on the filling level. The system also includes a controller for controlling the filling level of the reservoir depending on the sensor signal such that the filling level is kept constant.

Methods and apparatus for optimally positioning objects for automated machining are described herein. An example build file generator described herein includes an object file manager to identify a first toolpath volume associated with a first object to be formed via an additive manufacturing (AM) process. The first toolpath volume is based on a first toolpath of a first post-manufacturing process to be used on the first object. The object file manager is also to identify a second toolpath volume associated with a second object to be formed via the AM process. The second toolpath volume is based on a second toolpath of a second post-manufacturing process to be used on the second object. The example build file generator also includes a layout determiner to determine a layout of the first and second objects to be formed on a substrate by the AM process based on the first and second toolpath volumes.