A shear web mould system for manufacturing a wind turbine component in form of an I-shaped shear web having a web body and a first web foot flange at a first end of the web body and a second web foot flange at a second end of the web body is described. The system comprises a central moulding portion for forming at least a part of the web body, a first moulding plate for forming at least a part of the first web foot flange, and a second moulding plate for forming at least a part of the second web foot flange. The angles of the first moulding plate and the second moulding plate relative to the central moulding portion are adjustable.

In a mold of a tire vulcanization device, a sensor is installed in a state exposed on a tire molding surface, a connector is installed in a state exposed on an attachment surface, the sensor and the connector are connected by a lead wire extending through an interior of the mold. In container components, an inner connector is installed in a state exposed on an opposing surface, and a lead wire connected to the inner connector is extended through an interior of the container components toward an exterior of the container components.

A rapid mold replacing device for use in molding machine includes: a mold having lateral walls at two ends disposed with a pair of bolt slots; a pair of fastening members, having a locking member connected at an outer side of each fastening member, and protruded with a locking bolt, and a top surface of each locking member having an unlocking slot; and an unlocking mechanism, disposed on a top surface of the elevation seat and having at least one first retractable driving device, and a pair of unlocking blades capable of being synchronously driven by the first retractable driving device; when the pair of unlocking blades are inserted in or released from the pair of unlocking slots, the mold can be formed in an un locked or a locked status to the mold.

An object manufacturing system, assembling module making method, and object manufacturing method are provided. The object manufacturing system includes an electronic device. The electronic device includes a database, memory module and processor. The database includes at least one assembly encoding information of at least one assembly mold and at least one combination encoding information of at least one combination mold. The memory module includes a process generating module. The processor executes the process generating module and provides at least one process information. The at least one process information includes at least one assembly encoding information of the at least one assembly mold and corresponds to at least one combination encoding information of the at least one combination mold to indicate positions of the at least one combination mold and the at least one assembly mold coupled together, thereby achieving quick assembly.

A rotor blade mold and a method for manufacturing a rotor blade for a wind energy installation, wherein the rotor blade includes a blade root and a blade tip and wherein the rotor blade extends in a longitudinal direction from the blade root to the blade tip. The mold includes a first rotor blade mold segment adapted for manufacturing a portion of the rotor blade that includes the blade root, a second rotor blade mold segment adapted for manufacturing a portion of the rotor blade that includes the blade tip, and at least a third rotor blade mold segment adapted to be integrated in the rotor blade mold between the first mold segment and the second mold segment, and/or to be removed from the rotor blade mold and thereby lengthen or shorten the rotor blade mold in the longitudinal direction.

A portable molding system is configured for forming insulation on pipes. A set of transportable process modules are configured to be shipped to a molding site, operatively connected together at the molding site to form a site-installed molding system, and subsequently disconnected for transport to another site. The set of transportable process modules includes one or more resin preparation modules configured to prepare resin for being formed into insulation on the pipes. One or more mold modules are configured to define a mold cavity. The one or more mold modules are configured to hold a pipe in the mold cavity, to receive resin prepared by the one or more resin preparation modules in the mold cavity around the pipe, and to form said resin received in the mold cavity into insulation on the pipe.

A template manufacturing method includes preparing a structure including a first substrate and a stacked body that is provided on the first substrate, the stacked body including a first lower layer including a first material, a first upper layer provided on the first lower layer including a second material different from the first material, and a first cover layer provided on a first cover region of the first upper layer and including a third material different from the second material. The method further includes forming a first resist layer on a portion of the first cover layer and on a first portion of the first upper layer, and exposing a second portion of the upper layer. The method yet further includes removing the second portion of the first upper layer using the first cover layer and the first resist layer as a mask.

The disclosed subject matter provides a system and method for facilitating bonding of various turbine blade components, including trailing edge inserts, or flatbacks, to the trailing edge of a wind turbine blade. The system disclosed herein ensures a consistent force is applied from root to top thereby preventing defects, e.g. paste voids, from forming. Additionally, a consistent bonding gap can be achieved due to the consistent application of force from the root to tip of the blade.

The invention relates to a nozzle for use in a device for administering a liquid medical formulation, to a method for producing the nozzle in the form of a microfluidic component and to a tool for producing microstructures of the microfluidic component. The nozzle is formed by a plastics plate with groove-like microstructures which are covered by a plastics cover on the longitudinal side in a fixed manner. The production method includes a moulding process in which a moulding tool is used, which moulding tool has complementary metal microstructures which have been produced from a semiconductor material in an electrodeposition process by means of a master component.

An instrumented mold formed by an assembly of strata includes, within the assembly of strata, a measurement structure provided with at least one pressure sensor and/or at least one temperature sensor or any other sensor capable of measuring a physical quantity, the structure typically being in the form of a flexible support housed between two strata.