A transfer system for soft gels is disclosed. It comprises: a blower, having a first air inlet and a first air outlet, and generating an airflow by inhaling air from the first air inlet and discharging air out of the first air outlet; a hopper, having a top opening to catch soft gels manufactured and dropped directly from a soft gel machine and a bottom opening to drop the soft gels; a transfer hose, having a first opening connected to the first air outlet and a second opening, wherein a side-cut opening is formed to connect to the bottom opening, the airflow from the first opening blows the soft gels dropped at the side-cut opening to move the soft gels toward the second opening; a cooling module, having a second air inlet and a second air outlet, cooling down the external air from the second air inlet and discharging the cooled air from the second air outlet; and a connecting hose, connecting the second air outlet and the first air inlet.

A vacuum conveying system has at least two storage locations and at least two consumers connected by supply conduits and discharge conduits to each other. A vacuum source is provided that produces a vacuum flow/air flow. A central material conduit is provided with valves, wherein the supply conduits and the discharge conduits each have one of the valves associated therewith. The valves actuate conveying paths of bulk material from the at least two storage locations to the at least two consumers. The valves have a first position and a second position, wherein in the first position the valves open the material conduit to provide a through passage. In the second position, the valves supply the vacuum flow/air flow to the central material conduit or conduct the vacuum flow/air flow away from the central material conduit.

Provided is a pressurizing system which includes: a pressurizing nozzle configured to supply a pressurizing gas into a hopper (3) where pulverized coal is accumulated; a filter configured to face a space in the hopper (3) where the pulverized coal is accumulated, and to allow the pressurizing gas to pass through the filter, the filter being provided at an end of the pressurizing nozzle; buffer tanks (5a), (5b) in which a pressurizing gas to be supplied to the hopper (3) is collected at a first predetermined pressure; and a pressure control means configured to start, at a time of starting pressurization of the hopper (3), supply of a pressurizing gas at a second predetermined pressure which is lower than the first predetermined pressure of the pressurizing gas collected in the buffer tanks (5a), (5b).

Provided is a pressurizing system which includes: a pressurizing nozzle configured to supply a pressurizing gas into a hopper (3) where pulverized coal is accumulated; a filter configured to face a space in the hopper (3) where the pulverized coal is accumulated, and to allow the pressurizing gas to pass through the filter, the filter being provided at an end of the pressurizing nozzle; buffer tanks (5a), (5b) in which a pressurizing gas to be supplied to the hopper (3) is collected at a first predetermined pressure; and a pressure control means configured to start, at a time of starting pressurization of the hopper (3), supply of a pressurizing gas at a second predetermined pressure which is lower than the first predetermined pressure of the pressurizing gas collected in the buffer tanks (5a), (5b).

In one embodiment, a feed system for distributing fluidized feed material, comprises: a distribution unit configured to fluidize feed material; and a control unit fluidly coupled to the distribution unit, wherein the control unit comprises: a chamber configured to hold the feed material provided from the distribution unit; and a feeder unit fluidly coupled to the chamber: and a second gas inlet configured to provide gas to the chamber; and a material discharge pipe fluidly coupled to the chamber and the second gas inlet.

A robotic processing system and method are disclosed for processing materials using a series of containers stored in an automated storage and picking system. Each of the containers performs a specific function on the materials stored therein. The materials are passed from bin to bin via a suitable dispensing and transferring system. For example, a system is disclosed for delivering ingredients to a micro-brewery, as are methods for brewing small or test batches of beer according to customers' individual requirements.

A robotic processing system and method are disclosed for processing materials using a series of containers stored in an automated storage and picking system. Each of the containers performs a specific function on the materials stored therein. The materials are passed from bin to bin via a suitable dispensing and transferring system. For example, a system is disclosed for delivering ingredients to a micro-brewery, as are methods for brewing small or test batches of beer according to customers' individual requirements.

An agricultural vehicle includes a chassis, a tank carried by the chassis, and at least one meter module coupled to the tank. The at least one meter module has at least one gate. A gate control link is coupled with the at least one gate of the at least one meter module. A control rod is carried by the chassis. A connector couples the control rod to the gate control link at a connection interface such that movement of the control rod controls an open state of the at least one gate of the at least one meter module. The connector has a frangible portion adjacent the connection interface; the control rod and the gate control link uncouples from one another upon a breaking force causing the frangible portion to break.

An agricultural vehicle includes a chassis, a tank carried by the chassis, and at least one meter module coupled to the tank. The at least one meter module has at least one gate. A gate control link is coupled with the at least one gate of the at least one meter module. A control rod is carried by the chassis. A connector couples the control rod to the gate control link at a connection interface such that movement of the control rod controls an open state of the at least one gate of the at least one meter module. The connector has a frangible portion adjacent the connection interface; the control rod and the gate control link uncouples from one another upon a breaking force causing the frangible portion to break.

A vacuum-type powder transfer system capable of quantitatively supplying a constant amount of powder in a wide range from a small amount to a large amount, and a vacuum-type powder transfer method using the vacuum-type powder transfer system are disclosed. In an aspect, the vacuum-type powder transfer system includes a storage part configured to store powder, one or more chamber parts configured to accommodate the powder transferred from the storage part, a hopper part disposed to control fluid communication with the one or more chamber parts, and configured to accommodate the powder transferred from the storage part, and a vacuum pressure forming part configured to provide vacuum pressure to the one or more chamber parts, wherein the powder is split and supplied to the one or more chamber parts or the hopper part.