The invention relates to a method for producing a compressed-gas container, particularly a compressed-gas container for transporting and for storing liquid gases or natural gas.

Methods of making a composite article, such as a motor housing, are provided herein. The method can include applying a resin-fiber material to a shaped surface to form an intermediate article. The resin-fiber material includes an uncured resin composition and a fiber substrate material. The method further includes solidifying the uncured resin composition present in the intermediate article to form the composite article. Solidifying can be accomplished by applying heat to the intermediate article to initiate an exothermic reaction comprising polymerization, cross-linking, or both of the uncured resin composition. Application of the heat from the heat source can be ceased after initiation of the exothermic reaction, but polymerization, cross-linking or both of remaining uncured resin composition can continue in one or more of a radial, circumferential, or axial direction through a thickness of the resin-fiber material in the absence of heat from the heat source to form the composite article.

A method of determining a void volume during manufacture of a composite pipe formed of concentric layers of adjacently positioned, helical windings of composite tape has the steps of: (a) scanning the surface of a layer of adjacently positioned, helical windings to generate scanning information; (b) using the scanning information to locate gap(s) between adjacent windings and to determine the number of gaps and characteristic dimensions of each gap in the layer; and (c) generating a calculated void volume of the layer, using the number of gaps and the characteristic dimensions of each gap for the layer. The invention also relates to a corresponding apparatus for determining a void volume during manufacture of a composite pipe formed of concentric layers of helically wound composite tape.

A method for manufacturing a high pressure tank capable of uniformly heating a thermosetting resin in a short time is provided. A method for manufacturing a high-pressure tank including: a step (a) of preparing a tank intermediate product including a fiber-reinforced resin layer formed by winding a carbon fiber impregnated with a thermosetting resin around a liner including a cap attached thereto; and a step (b) of performing a process for thermosetting the fiber-reinforced resin layer of the tank intermediate product by induction-heating the fiber-reinforced resin layer using induction-heating means, in which: the induction-heating means includes first induction-heating means for induction-heating a trunk part of the tank intermediate product and second induction-heating means for induction-heating a dome part of the tank intermediate product; and a temperature of the trunk part of the tank intermediate product and a temperature of the dome part thereof are controlled independently.

Methods of making a composite article, such as a motor housing, are provided herein. The method can include applying a resin-fiber material to a shaped surface to form an intermediate article. The resin-fiber material includes an uncured resin composition and a fiber substrate material. The method further includes solidifying the uncured resin composition present in the intermediate article to form the composite article. Solidifying can be accomplished by applying heat to the intermediate article to initiate an exothermic reaction comprising polymerization, cross-linking, or both of the uncured resin composition. Application of the heat from the heat source can be ceased after initiation of the exothermic reaction, but polymerization, cross-linking or both of remaining uncured resin composition can continue in one or more of a radial, circumferential, or axial direction through a thickness of the resin-fiber material in the absence of heat from the heat source to form the composite article.

Methods of making a composite article are provided herein. The method can include an unwinding step including unwinding a fiber substrate material from a creel at an unwinding velocity and an impregnation step including applying an uncured resin composition to the fiber substrate material to form a resin-fiber material. The method further includes a winding step comprising applying the resin-fiber material onto a shaped surface at a winding velocity and a solidifying step comprising applying heat to the resin-fiber material to initiate an exothermic reaction comprising polymerization, cross-linking, or both of the uncured resin composition. Temperature of the resin-fiber material can be monitored during operation of the method and a polymerization front velocity set point (v.sub.pfs) and an operating polymerization front velocity (v.sub.pfo) can be determined. Parameters can be adjusted to maintain a v.sub.pfo that is substantially the same as the v.sub.pfs. Systems for performing said methods are also provided.

A paint roller manufacturing system and method are described. In an embodiment, an inner strip of material and an outer strip of material are wound about a mandrel in offset relation. The inner strip of material and the outer strip of material each comprise material that results in a final paint roller which shrinks by less than 2.5 percent of the final paint roller axial length, or which has shrinkage that varies by less +/0.1%, upon hardening and setting. An adhesive is applied to at least a portion of the outer strip as it is wound about the mandrel. A length of fabric is wound about at least the outer strip to form a paint roller tube, and compression is applied to the paint roller tube while advancing the paint roller tube in a direction parallel to the mandrel. A precision measuring or sensing device is used to control a cutting device causing the cutting device to cut the advancing paint roller tube into pre-selected lengths prior to the paint roller tube hardening and setting.

A sash (62) of a window opening up to 180 and capable of tilting is mounted onto a fixedly installed frame profile (63) and houses a pair of superimposing sashes that fit tightly therein when in closure position, i.e. an upper stationary sash (65) and a lower movable-divertible sash (64), each of the sashes (64,65) provided with laterally extending shafts (49) for connection with sash (62), roller wheels (50) provided onto the shafts (49) of sash (64) that roll within a predefined path created by insert guide profile members (19) and diverter guide members (66,68) to alternately bring sash (64) in a position of superimposing sash (65) and a position of alignment with the same. Lifting mechanisms (46) provided with a regulatory screw (84) for adjusting the pretension of a spring component thereof and thereby the force required by the user for moving the sash (64) are installed within the vertically extending sides of the sash (62).

This invention relates to a flywheel and method of manufacture thereof wherein the flywheel is capable of operation at very high rotational speed without precise balancing.

A method of manufacturing a tank includes: a winding step of winding a fiber impregnated with thermosetting resin before curing on a liner; a shape changing step of making the shape of the liner larger than the shape thereof at the time of the winding step, the shape changing step being performed after the winding step; and a curing step of heating and curing the thermosetting resin while the shape of the liner is increased by the shape changing step.