A pipeline has two groups of reinforcing circular ring bodies welded on large flanges at two ends of the pipeline, reinforcing rebar plates and integral reinforcing steel circular pipe fittings are combined and welded symmetrically. Microcrystalline glass lining has level-8 Mohs hardness. By adopting an openable and closeable extra-long horizontal electric heating furnace provided by the present invention and an intelligent temperature control instrument in combination with a new heating-while-rotating process, the extra-large and extra-long integral large micro-crystallized glass-lined pipeline which is high in glass lining layer quality, smooth in circulation, durable, non-corrosive, wear-resistant, high in seismic performance and safe in operation is developed. Various existing pipelines will be inevitably and comprehensively replaced due to comprehensive extra-strong advantages.

Disclosed is a production line and production method for positive electrode material of a lithium-ion battery. The production line comprises a roller kiln; a gas collecting device communicated with the roller kiln and configured to collect gas inside the roller kiln; and a free lithium-measuring device configured to measure content of free lithium in the gas collected by the gas collecting device.

A cooperative emission reduction method for sintering using an energy-carrying composite gas is disclosed. A surface of a sintered material is divided into an ignition section, a heat preservation section, a middle section, a flue gas heating section, and a machine tail section from a machine head to a machine tail of a sintering machine; according to flue gas components, temperature characteristics, and heat requirements of different sections, a hot exhaust gas is introduced to the ignition section for ignition, a hot exhaust gas is introduced to the heat preservation section and a hydrogen-rich gas is cascadingly sprayed synchronously, cascaded spraying of water vapor is coupled based on spraying of a hydrogen-rich gas in the middle section, and the high-temperature flue gas in the machine tail section and the flue gas in the ignition section and/or the heat preservation section are circulated to the heating section.

A non-oxidation heat treatment system having internal Rx gas (endothermic gas) generator includes: a heat treatment furnace whose internal environment kept to an atmosphere of an Rx gas; internal reformers for accommodating reaction catalysts for generating the Rx gas; material supply means for mixing raw gas as a material for generating the Rx gas and air to a given ratio to supply the mixture to the internal reformers; heating means disposed in the heat treatment furnace to heat an internal temperature of the heat treatment furnace to a temperature needed for annealing; and a controller disposed on the outside to control the internal temperature of the heat treatment furnace through the control of the ON/OFF and combustion loads of the of the heating means, wherein the internal reformers are loaded to the interior of the heat treatment furnace and the heating means includes regenerative type radiant tube burners.

Disclosed are fast high-temperature sintering systems and methods. A method of fabrication includes positioning a material at a distance of 0-1 centimeters from a first conductive carbon element and at a distance of 0-1 centimeters from a second conductive carbon element, heating the first conductive carbon element and the second conductive carbon element by electrical current to a temperature between 500 C. and 3000 C., inclusive, and fabricating a sintered material by heating the material with the heated first conductive carbon element and the heated second conductive carbon element for a time period between one second and one hour. Other variations of the fast high-temperature sintering systems and methods are also disclosed. The disclosed systems and methods can quickly fabricate unique structures not feasible with conventional sintering processes.

A method for producing a stabilizing element-containing zirconia sintered body includes heating a zirconia compositional substance containing a stabilizing element from a heating start temperature to a first target temperature of 800 C. or higher and lower than 1400 C. at a heating rate of 150 C./minute or more; elevating the temperature from the first target temperature to a second target temperature of 1400 C. or higher and lower than 1580 C. at a heating rate of more than 30 C./minute and less than 200 C./minute; and retaining the second target temperature.

The present disclosure relates to a status monitoring system and control method for a mesh belt furnace for ceramic sintering. The system includes an acquisition layer, an analysis layer and a regulation and control layer. Image data of products conveyed in the mesh belt furnace is acquired by the acquisition layer, and acquired product image data is further segmented to obtain product images. The analysis layer synchronously receives the product images obtained by segmentation in the acquisition layer, and analyzes a product sintering status corresponding to each group of product images based on the product images. Image data acquisition on sintered products in the mesh belt furnace allows primary data to be provided for monitoring an operation status of the mesh belt furnace; then analysis based on the acquired product image data allows to determine qualification of output products in the mesh belt furnace and evaluate overall quality thereof.

Disclosed are fast high-temperature sintering systems and methods. A method of fabrication includes positioning a material at a distance of 0-1 centimeters from a first conductive carbon element and at a distance of 0-1 centimeters from a second conductive carbon element, heating the first conductive carbon element and the second conductive carbon element by electrical current to a temperature between 500 C. and 3000 C., inclusive, and fabricating a sintered material by heating the material with the heated first conductive carbon element and the heated second conductive carbon element for a time period between one second and one hour. Other variations of the fast high-temperature sintering systems and methods are also disclosed. The disclosed systems and methods can quickly fabricate unique structures not feasible with conventional sintering processes.

The present disclosure discloses a temperature measurement device for detecting the temperature of a processing element, wherein the top wall of the furnace has a furnace chamber top opening, comprising: a temperature detection component configured to detect the temperature of the processing element; a support shroud; and a sealing isolation device connected to the support shroud; wherein the temperature detection component is supported over the support shroud, the sealing isolation device configured to sealingly enclose the shroud cavity from above so that the temperature detection component can be isolated from gas within the furnace chamber. The temperature measurement device of the present disclosure can prevent environmental pollution caused by the outflow of high-temperature gas by providing a sealing isolation device, and better prevent the impact of high-temperature gas on the infrared camera, thereby providing better protection.

Provided is a sintering furnace. The sintering furnace includes: a furnace body and a furnace head cover having a feed inlet, the furnace head cover covering a furnace head of the furnace body, the furnace head cover being axially limited relative to the furnace head, the furnace body being rotatable around a central axis relative to the furnace head cover, and the feed inlet being in communication with an interior of the furnace body; a sliding support structure including a first sliding structure configured to support the furnace head cover, the furnace head cover being fixedly connected to the first sliding structure, and the first sliding structure being slidably arranged in a length direction of the furnace body; and a feeding device in communication with the feed inlet through a flexible connection pipe.