Provided is a resin pelletizer device capable of monitoring cavitation. A resin pelletizer device (100) includes a die (6) including a die surface (61) in which die holes (63) are formed, rotary blades (21) that rotate on the die surface (61) in the water, thereby cutting resin extruded from the die holes (63) in the water into a pellet form, a sensor (150) that detects an elastic wave generated during the rotation of the rotary blades (21) on the die surface (61), and a determination unit (121) that monitors an output value of the sensor (150), and determines that cavitation occurs when the output value of the sensor (150) becomes less than a predetermined threshold.

In particular embodiments, a process for producing bulked continuous carpet filament from recycled polymer utilizes two vacuum pumps in combination with a single extruder. In various embodiments, the dual vacuum arrangement (e.g., at least two vacuum pumps) operably coupled to the single extruder (e.g., MRS extruder) may be configured remove one or more impurities from recycled polymer as the recycled polymer passes through the extruder such that the process: (1) is more effective than earlier processes in removing contaminates and water from the recycled polymer; (2) allows for an increased throughput through a single extruder, which may result in a doubling of a number of thread lines produced from a single extruder; (3) results in a desired intrinsic viscosity for the extruded recycled polymer at the increased throughput; and/or (4) reduces an amount of downtime of a particular production line as a result of cleaning the two vacuum pumps.

The invention relates to a device and a method for testing materials, and is characterized in that the device comprises application units (2) for interaction modules (1) and an exchange system for the interaction modules, and the device is designed such that the application units (2) automatically feed interaction modules (1) to the exchange system after a control signal and the exchange system is designed to feed the interaction modules to a test position.

An installation for producing a polymer melt for a porous film, in particular for a membrane film, comprises a planetary roller extruder. Said extruder is used to produce a flowable polymer melt from thermoplastics. The planetary roller extruder has a filling opening and a discharge side for delivering the polymer melt. A melt pump is further provided. The discharge side of the planetary roller extruder is connected to a downstream inlet side of the melt pump for further conveying the polymer melt. The connection is in the form of a pressure channel shielded from the ambient atmosphere or a pressure line shielded from the ambient atmosphere. The planetary roller extruder and the melt pump are designed and/or can be driven in such a manner that the polymer melt is applied or can be transferred under pressure at the melt pump on the inlet side.

The invention relates to a device (2) for filtering a liquid plastic, with a housing (4) with an inlet (6) for introducing the plastic and an outlet (8) for discharging the plastic, a screen carrier (12) accommodated in the housing (4) and having a screen chamber (10) for accommodating a filter element (14), a filter element (14) arranged in the screen chamber (10) of the screen carrier (12) and having a filter side (16) and a clean side (18), the filter element (14) being connectable to the inlet (6) and the outlet (8) in such a way that the plastic passes through and is filtered by the filter element (14) in a filtering flow direction (56) from the filter side (16) to the clean side (18) and wherein the filter element (14) can be cleaned by backwashing by plastic flowing counter to the filtering flow direction (56), a backwashing feed channel (20) fluidly connected to the clean side (18) of the filter element (14), which feed channel (20) is set up for this purpose, the filter element (14) against the direction of filtration flow (56), and a backwash discharge channel (22) which is fluid conductively connected to the filter side (16) of the filter element (14) and which is arranged to discharge the backwashed plastic after it has passed the filter element (14). According to the invention, a backwash screen support (24) fluidly connected to the backwash discharge channel (22) is proposed, comprising a screen chamber (26) for receiving a backwash filter element (28) and a backwash filter element (28) arranged in the screen chamber (26) and adapted to filter the backwashed plastic.

A system and method of regulating a pressure of a fluid with a valve block having a valve block inlet in fluid communication with an outlet of an extruder and a valve block outlet in fluid communication with a die. A transducer in fluid communication with the flow channel and in signal communication with a controller of the motor can sense a pressure and communicate the pressure to a controller of a motor. The motor can adjust a position of a valve to regulate the pressure of the fluid.

A device may include a housing having a receptacle for receiving a screen carrier, and having a fluid inlet channel and a fluid outlet channel. In addition, the device may include a screen carrier movably received inside the receptacle and having a screen carrier inlet, a screen carrier outlet and a cavity for receiving a filter element, where the cavity is in fluid communication with the screen carrier inlet and the screen carrier outlet. The screen carrier can be moved from a screen replacement position(S) via a venting position area into a filtering position (F). Moreover, the device may include an accumulator which is fluidically connectable to the screen carrier inlet and/or to the screen carrier outlet and which is configured to store fluid that is fed via the screen carrier inlet and/or the screen carrier outlet and to control a feeding of the fluid into the accumulator.