A temperature-control device for receiving a reaction vessel having a heat-insulated interior space and which is covered by a lid. The reaction vessel has a hollow body and a cap, this hollow body being closed on one side by a base. The base contacts a heatable heating block in order to heat a sample located in the reaction vessel. The hollow body is surrounded by a heatable heating body which communicates with the lid via a heat-conducting contact region so that the heating body heats the hollow body directly and heats the cap indirectly via the lid.

A temperature-control device for receiving a reaction vessel having a heat-insulated interior space and which is covered by a lid. The reaction vessel has a hollow body and a cap, this hollow body being closed on one side by a base. The base contacts a heatable heating block in order to heat a sample located in the reaction vessel. The hollow body is surrounded by a heatable heating body which communicates with the lid via a heat-conducting contact region so that the heating body heats the hollow body directly and heats the cap indirectly via the lid.

The Invention relates to an atmospheric-pressure acetylene carburizing furnace, comprises a reaction chamber, an acetylene intake duct, an exhaust gas duct, a control and metering apparatus, an exhaust gas measurement apparatus, and a computer controller. The computer controller calculates a total amount of carbon in the furnace and an enrichment rate of a workpiece, and adjusts an acetylene intake volume according to the calculation result until process requirements are met. The Invention realizes carburizing with acetylene under atmospheric pressure and reduces the usage costs while improving the equipment efficiency.

The invention relates to a process chamber (10) for carrying out thermal processes in the manufacture of an electronic assembly (30), comprising the following: at least one opening (20) for introducing and/or removing the electronic assembly (30); a device (40) for supplying a gas; a controllable protection device (50) which is arranged on the opening (20) in order to reduce a leakage of gas from the process chamber, wherein the controllable protection device (50) comprises a first movable element (50A) as an integral piece which covers the width between the total width of the opening and the width of the electronic assembly; a device for detecting data relating to the dimensions of the electronic assembly (30); and a controller (60) which can control the protection device (50) on the basis of the data relating to the dimensions of the electronic assembly (30) such that when the electronic assembly (30) passes through the opening (20), a defined spacing is constantly maintained between the electronic assembly and the first movable element (50A).

A graphitization furnace has a furnace structure including a support part within a furnace chamber, and a gate valve. The gate valve in an open state thereof after a graphitization process dumps a pack material within the furnace chamber in a state in which carbon bodies are located within the furnace chamber, and the support part catches the carbon bodies as a level of the carbon bodies lowers with a decrease in an amount of the pack material remaining within the furnace chamber.

A graphitization furnace has a furnace structure including a support part within a furnace chamber, and a gate valve. The gate valve in an open state thereof after a graphitization process dumps a pack material within the furnace chamber in a state in which carbon bodies are located within the furnace chamber, and the support part catches the carbon bodies as a level of the carbon bodies lowers with a decrease in an amount of the pack material remaining within the furnace chamber.

Disclosed are a high-pressure liquid-state or supercritical-state quenching apparatus, comprising a working chamber, a heating device, a cooling device, a vacuum pump set, a storage tank, a buffer tank, a gas booster, a first pressure gauge, and a temperature controller. According to the Invention, vacuum liquid-state or supercritical-state quenching is implemented, which satisfies a quenching requirement of a large workpiece, and can also achieve an effect of high-pressure gas quenching. In addition, clean heat treatment is implemented, which avoids waste gas and waste water pollution, and is energy-saving and environmentally-friendly heat treatment.

The invention concerns a dental furnace, with a furnace base and with a furnace hood, wherein the furnace hood includes a firing chamber for the accommodation of dental restorations, with a temperature sensor that records the temperature of the dental restoration and which is connected to a control device which controls the dental furnace, and the dental furnace (10) includes a drive unit (18) for the furnace hood (16) and the control device (30) controls the drive unit (18) based on the temperature recorded by the temperature sensor (20), namely opens the furnace hood.

The invention concerns a dental furnace, with a furnace base and with a furnace hood, wherein the furnace hood includes a firing chamber for the accommodation of dental restorations, with a temperature sensor that records the temperature of the dental restoration and which is connected to a control device which controls the dental furnace, and the dental furnace (10) includes a drive unit (18) for the furnace hood (16) and the control device (30) controls the drive unit (18) based on the temperature recorded by the temperature sensor (20), namely opens the furnace hood.

The invention relates to a dental pressing furnace for producing a dental restoration element in a muffle (8) by heating and pressing a blank (14). The dental pressing furnace comprises a combustion chamber (6), comprising at least one guide opening (11) that is opened towards the outside and a pressing stamp (4) guided in the guiding opening (11) and protruding into the combustion chamber (6) for applying pressing force to the heated blank (14) in the muffle (8). A temperature transmitter (36) guided at least in part by the pressing stamp (4) is configured to guide a temperature (50) of the blank (14) in the combustion chamber (6) from said combustion chamber, and a temperature sensor (34) connected to the temperature transmitter (36) outside of the combustion chamber captures the temperature (50).