The electroacoustic transducer (1) is configured for the generation of shock waves for the treatment of the human or animal body. The electroacoustic transducer (1) includes piezoelectric elements (5), which are arranged within a bearer (4) in a housing (2, 3). Between the piezoelectric elements (5) and the housing (2, 3) a free space is formed, which is in-filled with a casting compound (10).

A nozzle assembly for an injection molding system has a nozzle adapter with one or more vent holes therein. A porous metal insert is provided in fluid communication with at least one of the vent holes. The porous metal insert is also in fluid communication with a flow channel through the nozzle assembly. As molten polymeric material advances through the flow channel from a barrel to a mold assembly, gases entrained in the molten polymeric material are vented through the porous metal insert and escape through the one or more vent holes. Pressurized air may be introduced through the vent holes, such as by one or more blow-back modules, to unclog pores of the one or more porous metal inserts between shots of the injection molding system.

A nozzle assembly for an injection molding system has a nozzle adapter with one or more vent holes therein. A porous metal insert is provided in fluid communication with at least one of the vent holes. The porous metal insert is also in fluid communication with a flow channel through the nozzle assembly. As molten polymeric material advances through the flow channel from a barrel to a mold assembly, gases entrained in the molten polymeric material are vented through the porous metal insert and escape through the one or more vent holes. Pressurized air may be introduced through the vent holes, such as by one or more blow-back modules, to unclog pores of the one or more porous metal inserts between shots of the injection molding system.

Resin supply system in which resin material is stored in a pouch (120) in a degassed state ready for use. The pouch comprises a body portion (122) forming a reservoir for resin material and a connector portion (125) in fluid communication therewith. The connector portion includes an outlet (127) which is configured to be connected to an injector head (180) of an injector assembly (100), the injector head being connectable to a mould by means of connecting tubing to provide a resin supply (130) thereto. The pouch is configured to be mountable in a housing (110) of the injector assembly and is compressed by hydrostatic pressure of water surrounding the pouch in a chamber (115) of the housing. The application of pressure by a piston (150) moving in a direction (155) transfers pressure to the water and then to the pouch in a controlled manner to provide the resin supply to the mould. After use, the pouch is removed and discarded thereby substantially eliminating the need for cleaning of the housing after use.

Resin supply system in which resin material is stored in a pouch (120) in a degassed state ready for use. The pouch comprises a body portion (122) forming a reservoir for resin material and a connector portion (125) in fluid communication therewith. The connector portion includes an outlet (127) which is configured to be connected to an injector head (180) of an injector assembly (100), the injector head being connectable to a mould by means of connecting tubing to provide a resin supply (130) thereto. The pouch is configured to be mountable in a housing (110) of the injector assembly and is compressed by hydrostatic pressure of water surrounding the pouch in a chamber (115) of the housing. The application of pressure by a piston (150) moving in a direction (155) transfers pressure to the water and then to the pouch in a controlled manner to provide the resin supply to the mould. After use, the pouch is removed and discarded thereby substantially eliminating the need for cleaning of the housing after use.

Molding methods and molds for making a synthetic resin molded product include disposing a curable liquid resin mixture in a recess of a female mold. The curable liquid resin mixture is then simultaneously agitated and degassed by a mixer while under a partial vacuum. More specifically, at least the female mold is orbited around an orbital axis while being rotated about a rotational axis that is eccentric to the orbital axis. After being thoroughly mixed and degassed, the liquid mixture is then cured in the mold unit.

A nozzle assembly for an injection molding system has a nozzle adapter with one or more vent holes therein. A porous metal insert is provided in fluid communication with at least one of the vent holes. The porous metal insert is also in fluid communication with a flow channel through the nozzle assembly. As molten polymeric material advances through the flow channel from a barrel to a mold assembly, gases entrained in the molten polymeric material are vented through the porous metal insert and escape through the one or more vent holes. Pressurized air may be introduced through the vent holes, such as by one or more blow-back modules, to unclog pores of the one or more porous metal inserts between shots of the injection molding system.

A nozzle assembly for an injection molding system has a nozzle adapter with one or more vent holes therein. A porous metal insert is provided in fluid communication with at least one of the vent holes. The porous metal insert is also in fluid communication with a flow channel through the nozzle assembly. As molten polymeric material advances through the flow channel from a barrel to a mold assembly, gases entrained in the molten polymeric material are vented through the porous metal insert and escape through the one or more vent holes. Pressurized air may be introduced through the vent holes, such as by one or more blow-back modules, to unclog pores of the one or more porous metal inserts between shots of the injection molding system.

The present disclosure relates to a resin injector and oil compactor used to manufacture composite components by RTM and FIP processes. A resin injector comprising an automated resin degassing and charging/discharging station and an in-line heat exchanger. An oil compactor capable of applying a dynamic compaction at a desired frequency, nominal pressure and temperature to an FIP mold. A multi-injection equipment for manufacturing composite parts by RTM and FIP is provided. The multi-injection equipment includes 1 or more cylinder injectors for delivery liquid resin into an RTM or FIP mold cavity. An oil compactor equipment to work with FIP is provided. The oil compactor contains an oil container and a heat exchanger to maintain the oil at a desired temperature. The pre-heated oil is injected into the FIP under pressure after the resin injection to fulfill the impregnation of the fibrous strengthener and consolidate the composite part.

The present disclosure relates to a resin injector and oil compactor used to manufacture composite components by RTM and FIP processes. A resin injector comprising an automated resin degassing and charging/discharging station and an in-line heat exchanger. An oil compactor capable of applying a dynamic compaction at a desired frequency, nominal pressure and temperature to an FIP mold. A multi-injection equipment for manufacturing composite parts by RTM and FIP is provided. The multi-injection equipment includes 1 or more cylinder injectors for delivery liquid resin into an RTM or FIP mold cavity. An oil compactor equipment to work with FIP is provided. The oil compactor contains an oil container and a heat exchanger to maintain the oil at a desired temperature. The pre-heated oil is injected into the FIP under pressure after the resin injection to fulfill the impregnation of the fibrous strengthener and consolidate the composite part.