The present disclosure describes a method for replacing a photoresist (PR) bottle using a vehicle. An exemplary vehicle includes a processor configured to receive a request signal to replace a first PR bottle. The processor is also configured to transmit an order based on the request signal. The vehicle also includes a plurality of wheels configured to move the vehicle from the first location to a second location, and from the second location to the first location. The vehicle further includes a robotic arm configured to load, at the first location, the first PR bottle into a first container; load a second PR bottle in a second container; remove a cap from the second PR bottle and a socket from the first PR bottle; couple the socket of the first PR bottle to the second PR bottle; and unload the second PR bottle from the second container.

There are provided a printer device, a printing method, and a program that can appropriately output an exposure start signal without requiring a film detection device. A printer device includes a loading chamber into which a film cartridge is to be loaded, an exposure head device that is disposed to face a photosensitive surface of a film discharged from the film cartridge and exposes the film to light, a spreading roller that splits a developer pod of the film to spread a developer to the film, a transport roller that transports the film, and a load measuring device that measures a change in load occurring in a case where the film enters at least the spreading roller or the transport roller.

The present disclosure describes a method for replacing a photoresist (PR) bottle using a vehicle. An exemplary vehicle includes a processor configured to receive a request signal to replace a first PR bottle. The processor is also configured to transmit an order based on the request signal. The vehicle also includes a plurality of wheels configured to move the vehicle from the first location to a second location, and from the second location to the first location. The vehicle further includes a robotic arm configured to load, at the first location, the first PR bottle into a first container; load a second PR bottle in a second container; remove a cap from the second PR bottle and a socket from the first PR bottle; couple the socket of the first PR bottle to the second PR bottle; and unload the second PR bottle from the second container.

The present disclosure describes a leakage handling device and a method for handling a fluid leakage in a semiconductor manufacturing apparatus. The semiconductor manufacturing apparatus can include a lithography apparatus with a chuck configured to hold a substrate, and a photoresist feeder configured to dispatch a coating material on one or more areas of the substrate. The photoresist feeder can include a photoresist cartridge configured to output the coating material, a conduit fluidly connected to the photoresist cartridge, and a fluid leakage handling device disposed above the chuck, where the conduit can be configured to fluidly transport the coating material and circulate a coolant and the fluid leakage handling device can be configured to detect a fluid leakage from the conduit.

An apparatus includes a developing tank, and the developing tank has a sidewall and a bottom. A fluid manifold is adjacent the bottom of the developing tank. The fluid manifold includes a plurality of holes and a plurality of valves. Developer and rinsing fluid flow through the plurality of holes. Each of the plurality of the valves corresponds to a different hole of the plurality of holes, and the plurality of valves allow the developer and the rinsing fluid to flow through the holes when open and prevent the developer and the flowing liquid from flowing through the holes when closed. The developer flows through a developer inlet to the fluid manifold. The rinsing fluid flows through a rinsing fluid inlet to the fluid manifold. A controller is configured to individually control opening and closing of each of the plurality of valves.

The present disclosure describes a method for replacing a photoresist (PR) bottle using a vehicle. An exemplary vehicle includes a processor configured to receive a request signal to replace a first PR bottle. The processor is also configured to transmit an order based on the request signal. The vehicle also includes a plurality of wheels configured to move the vehicle from the first location to a second location, and from the second location to the first location. The vehicle further includes a robotic arm configured to load, at the first location, the first PR bottle into a first container; load a second PR bottle in a second container; remove a cap from the second PR bottle and a socket from the first PR bottle; couple the socket of the first PR bottle to the second PR bottle; and unload the second PR bottle from the second container.

The present disclosure describes a method for replacing a photoresist (PR) bottle using a vehicle. An exemplary vehicle includes a processor configured to receive a request signal to replace a first PR bottle. The processor is also configured to transmit an order based on the request signal. The vehicle also includes a plurality of wheels configured to move the vehicle from the first location to a second location, and from the second location to the first location. The vehicle further includes a robotic arm configured to load, at the first location, the first PR bottle into a first container; load a second PR bottle in a second container; remove a cap from the second PR bottle and a socket from the first PR bottle; couple the socket of the first PR bottle to the second PR bottle; and unload the second PR bottle from the second container.

A system for managing liquid supply is provided. The system includes an air pressure adjustor, a first liquid container, a second liquid container, a first tube, a second tube, an inlet sensor, and an outlet sensor. The first liquid container includes a liquid. The second liquid container includes an inlet and an outlet. The first tube is configured to be connected between the first liquid container and the inlet. The second tube is configured to be connected between the outlet and the air pressure adjustor. The inlet sensor is disposed on the first tube and for detecting the liquid flowing into the inlet. The outlet sensor is disposed on the second tube and for detecting the liquid flowing out from the outlet.

An apparatus includes a developing tank, and the developing tank has a sidewall and a bottom. A fluid manifold is adjacent the bottom of the developing tank. The fluid manifold includes a plurality of holes and a plurality of valves. Developer and rinsing fluid flow through the plurality of holes. Each of the plurality of the valves corresponds to a different hole of the plurality of holes, and the plurality of valves allow the developer and the rinsing fluid to flow through the holes when open and prevent the developer and the flowing liquid from flowing through the holes when closed. The developer flows through a developer inlet to the fluid manifold. The rinsing fluid flows through a rinsing fluid inlet to the fluid manifold. A controller is configured to individually control opening and closing of each of the plurality of valves.

An apparatus includes a developing tank and a fluid manifold in the bottom of the developing tank. The fluid manifold includes a plurality of holes through which developer flows and a plurality of valves corresponding to the plurality of holes. The valves allow developer to flow through the holes when open and prevent developer from flowing through the holes when closed. A trench surrounds the fluid manifold through which developer is drained from the developing tank. A controller is configured to control opening and closing of the valves. In an embodiment, the apparatus includes a clamping mechanism configured to insert the substrate into and remove the substrate from the developing tank.