An additively manufactured thermally insulating structure comprising a base layer and a fire-resistant layer adjacent to the base layer that forms an air gap therebetween. A method for assembling a miniature gas turbine engine includes additively manufacturing an additively manufactured thermally insulating structure onto a static structure of the miniature gas turbine engine.

An additively manufactured thermally insulating structure comprising a base layer and a fire-resistant layer adjacent to the base layer that forms an air gap therebetween. A method for assembling a miniature gas turbine engine includes additively manufacturing an additively manufactured thermally insulating structure onto a static structure of the miniature gas turbine engine.

A hazardous gas monitoring system is provided. The hazardous gas monitoring system includes a panel including multiple sensing lines. Each sensing line is configured to receive and monitor an air sample. Each sensing line includes a water separator to remove condensed moisture, a coalescing filter disposed downstream of the water separator, and a flow and gas monitoring system disposed downstream of the coalescing filter. The hazardous gas monitoring system may be used to monitor the presence of hazardous gases within an enclosure, such as an enclosure for a turbomachine.

A hazardous gas monitoring system is provided. The hazardous gas monitoring system includes a panel including multiple sensing lines. Each sensing line is configured to receive and monitor an air sample. Each sensing line includes a water separator to remove condensed moisture, a coalescing filter disposed downstream of the water separator, and a flow and gas monitoring system disposed downstream of the coalescing filter. The hazardous gas monitoring system may be used to monitor the presence of hazardous gases within an enclosure, such as an enclosure for a turbomachine.

The proposed solution concerns in particular an engine assembly with a casing part extending along a central axis, at least one cover part which at least partially covers an outside of the casing part, and for this, in relation to the central axis, extends along a circumferential direction which points along a circular path around the central axis, and at least one connecting element via which the at least one cover part is fixed relative to the casing part and which compensates for different thermal expansions of the casing part and the at least one cover part. It is proposed amongst others that the connecting element is part of a connecting assembly which comprises, in addition to the at least one connecting element, at least one separate supporting element which has thicker walls than the at least one connecting element and supports the first and second flange portions of the at least one connecting element against each other, and extends between the first and second flange portions with a flexibly formed expansion portion.

The proposed solution concerns in particular an engine assembly with a casing part extending along a central axis, at least one cover part which at least partially covers an outside of the casing part, and for this, in relation to the central axis, extends along a circumferential direction which points along a circular path around the central axis, and at least one connecting element via which the at least one cover part is fixed relative to the casing part and which compensates for different thermal expansions of the casing part and the at least one cover part. It is proposed amongst others that the connecting element is part of a connecting assembly which comprises, in addition to the at least one connecting element, at least one separate supporting element which has thicker walls than the at least one connecting element and supports the first and second flange portions of the at least one connecting element against each other, and extends between the first and second flange portions with a flexibly formed expansion portion.

A fairing for a power generation machine, the fairing comprising: a first layer comprising a metallic material and defining a first surface and a second opposite surface, the first layer being configured to enable the fairing to be coupled to the power generation machine; and a second layer comprising a composite material and defining a first surface and a second opposite surface, the second layer being coupled to the first layer, the second surface of the second layer defining an external surface of the fairing.

A fairing for a power generation machine, the fairing comprising: a first layer comprising a metallic material and defining a first surface and a second opposite surface, the first layer being configured to enable the fairing to be coupled to the power generation machine; and a second layer comprising a composite material and defining a first surface and a second opposite surface, the second layer being coupled to the first layer, the second surface of the second layer defining an external surface of the fairing.

A fracturing device, a firefighting method thereof, and a computer readable storage medium are disclosed. The fracturing device includes a power unit, the power unit includes a muffling compartment, a turbine engine, and a firefighting system; the firefighting system includes a firefighting material generator, at least one firefighting sprayer and at least one firefighting detector, the at least one firefighting sprayer and the at least one firefighting detector are located in the muffling compartment, each of the at least one firefighting sprayer is connected with the firefighting material generator and configured to spray out firefighting material generated by the firefighting material generator.

Disclosed herein is a system and method for monitoring a gaseous fire suppression blend. The system includes a sensor array having a plurality of sensors disposed in a protected space, wherein the sensor array can detect and quantify more than one component of the gaseous fire suppression blend.