The invention relates to the field of non-ferrous metallurgy, and more particularly to the creation of titanium alloys which, by virtue of their properties, are economical to use not only in traditional, particularly military, fields, but also in civilian fields of industry. The alloy contains 0.1-3.0 Al, 0.3-3.0 Fe, 0.1-1.0 Cr, 0.05-1.0 Ni, 0.02-0.3 Si, 0.02-0.2 N, 0.05-0.5 0, 0.02-0.1 C, and the remainder Ti. The technical result is the production of a commercially viable titanium alloy with guaranteed stable, predictable properties which is manufactured using, low-grade titanium sponge. This result is achieved in that the alloying elements used include impurity elements contained in the low-grade sponge, as well as alloying additives, separately added to the charge. The titanium-based alloy has a lower price compared to existing commercial alloys and, furthermore, the composition of the alloy is selected in accordance with a prescribed level of physical and mechanical properties and fabrication characteristics.

The invention relates to the field of non-ferrous metallurgy, and more particularly to the creation of titanium alloys which, by virtue of their properties, are economical to use not only in traditional, particularly military, fields, but also in civilian fields of industry. The alloy contains 0.1-3.0 Al, 0.3-3.0 Fe, 0.1-1.0 Cr, 0.05-1.0 Ni, 0.02-0.3 Si, 0.02-0.2 N, 0.05-0.5 0, 0.02-0.1 C, and the remainder Ti. The technical result is the production of a commercially viable titanium alloy with guaranteed stable, predictable properties which is manufactured using, low-grade titanium sponge. This result is achieved in that the alloying elements used include impurity elements contained in the low-grade sponge, as well as alloying additives, separately added to the charge. The titanium-based alloy has a lower price compared to existing commercial alloys and, furthermore, the composition of the alloy is selected in accordance with a prescribed level of physical and mechanical properties and fabrication characteristics.

A cabinet box comprises a plurality of independent, explosion-proof chambers. A battery wiring assembly for receiving and testing a battery is attached to an inner wall of an explosion-proof door, and an electrical connector is provided on an outer wall of the door. The assembly is placed inside a chamber, and the door seals the chamber. The temperature in each chamber is controlled independently, allowing batteries to be tested simultaneously at different temperatures. An air-circulating temperature-control module can be in a chamber, or a temperature controller with a refrigeration sheet can be integrated with the battery wiring assembly for direct battery contact. Separate, independent explosion-proof chambers effectively eliminate the possibility of a battery explosion in one chamber causing a chain-reaction explosion in another chamber. Modularity allows damaged parts to be replaced easily. An external battery testing machine can connected to the connector on each door.

A cabinet box comprises a plurality of independent, explosion-proof chambers. A battery wiring assembly for receiving and testing a battery is attached to an inner wall of an explosion-proof door, and an electrical connector is provided on an outer wall of the door. The assembly is placed inside a chamber, and the door seals the chamber. The temperature in each chamber is controlled independently, allowing batteries to be tested simultaneously at different temperatures. An air-circulating temperature-control module can be in a chamber, or a temperature controller with a refrigeration sheet can be integrated with the battery wiring assembly for direct battery contact. Separate, independent explosion-proof chambers effectively eliminate the possibility of a battery explosion in one chamber causing a chain-reaction explosion in another chamber. Modularity allows damaged parts to be replaced easily. An external battery testing machine can connected to the connector on each door.

A cabinet box comprises a plurality of independent, explosion-proof chambers. A battery wiring assembly for receiving and testing a battery is attached to an inner wall of an explosion-proof door, and an electrical connector is provided on an outer wall of the door. The assembly is placed inside a chamber, and the door seals the chamber. The temperature in each chamber is controlled independently, allowing batteries to be tested simultaneously at different temperatures. An air-circulating temperature-control module can be in a chamber, or a temperature controller with a refrigeration sheet can be integrated with the battery wiring assembly for direct battery contact. Separate, independent explosion-proof chambers effectively eliminate the possibility of a battery explosion in one chamber causing a chain-reaction explosion in another chamber. Modularity allows damaged parts to be replaced easily. An external battery testing machine can connected to the connector on each door.

A cabinet box comprises a plurality of independent, explosion-proof chambers. A battery wiring assembly for receiving and testing a battery is attached to an inner wall of an explosion-proof door, and an electrical connector is provided on an outer wall of the door. The assembly is placed inside a chamber, and the door seals the chamber. The temperature in each chamber is controlled independently, allowing batteries to be tested simultaneously at different temperatures. An air-circulating temperature-control module can be in a chamber, or a temperature controller with a refrigeration sheet can be integrated with the battery wiring assembly for direct battery contact. Separate, independent explosion-proof chambers effectively eliminate the possibility of a battery explosion in one chamber causing a chain-reaction explosion in another chamber. Modularity allows damaged parts to be replaced easily. An external battery testing machine can connected to the connector on each door.