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Designation SSO-10.13/11 Power, kW 72 Diameter, mm 1000 Height, mm 1300

The muffle shaft furnace with digital control SSHOL-70/11 (hereinafter referred to as the "furnace") is designed for firing products, melting and heat treatment of metals. It can be used as a universal laboratory muffle furnace in metallurgical, ceramic, jewelry production, dental, chemical and food laboratories.

Designation: SNO-8.16.8 Temperature: 1200 Open.doors: electromechanical Camera size (w.G.V.):600x1200x400 Regulation zones: 1

Designation: SNO–5.5.6/5-In Power supply: 380+N+PE Power: 18 kW Temperature: 500 Camera size (SHGV): 500x500x600 Door opening: manual Regulation zones: 2 Fan: Yes

KOIDZ-VD kits consist of samples of artificial defects (SAD) and samples of gaps (SG). Samples of artificial defects are made in the form of flat and curved plates and cylinders, on the working surfaces of which defects are made in the form of continuity violations like slits of various depths, opening widths and lengths. The working surfaces of flat SADs are two opposite surfaces on which longitudinal slits are cut by an electroerosion method The working surfaces of the SAD, reproducing a positive curved surface, are samples with a cylindrical surface. The working surface of the SAD reproducing negative curvature is the inner surface of the curved plate — the place of inflection. The KOIDZ-VD kit contains an SAD for determining the influence of various quantities. To determine the effect of the roughness of the working surfaces, the kit contains SADs with different roughness, on which defects of the same depth are made. To determine the effect of positive curvature and surface roughness, the kit contains cylindrical samples with different roughness of working surfaces on which defects of the same depth are made. To determine the simultaneous effect of negative curvature and surface roughness, the kit contains curved plates on which two defects of the same depth are cut, one of which is located on the flat, the other on the curved parts of the sample. To determine the effect of the chemical composition of the material of the controlled products, the kit contains samples of steel 10, steel 20 and steel 45. The same defects are made on each sample. To account for the influence of specific electrical conductivity, the kit contains samples from non-magnetic structural materials: aluminum alloy D16T and titanium alloy VT-23. The same defects are made on each sample. Gap samples are flat and curved plates of different thicknesses made of dielectric material. Technical specifications The range of nominal values of the depth of defects, mm: from 0.1 to 10. The limits of permissible error of the value of the depth of defects, mm: from ± 0.02 to ± 0.25. The range of nominal values of the width of the opening of defects, mm: from 0.03 to 0.15. The limits of the permissible error of the width of the opening of defects, mm: from ± 0.01 to ± 0.05. The range of nominal values of the length of defects, mm: from 6 to 100. The limits of permissible error of the value of the length of defects, mm: from ± 0.5 to ± 1. The range of nominal values of the thickness of the dielectric gap samples, mm: from 0.2 to 10. The limits of the permissible error of the thickness of the samples, mm: from ± 0.02 to ± 0.5. The range of nominal values of the radius of curvature of curved surfaces with defects, mm: - convex: from 13 to 510; - concave: 10.

High-temperature furnaces are capable of heating materials up to 1700 degrees. The scope of their application covers the heat treatment of various materials in an inert medium or vacuum. TULA-TERM furnaces are used for heat treatment of plastics, ceramics, metals, alloys, lacquers and other materials. The equipment allows sintering, annealing, soldering, quenching, drying, burning and molding. In industry, our installations are most often used for quenching parts and sintering hard alloys.

Designation SAT-0.25/7.8 Installed capacity, kW 28 Temperature stability in steady-state mode, °C ± 5

Designation SNO-3 Volume, l 3 The material of the working chamber is ceramic Heating 4 sides Power consumption, W, max 2500 Minimum operating temperature, 0C 100

NanoEducator II, despite its compactness and ease of operation, supports all basic techniques of atomic force and scanning tunneling microscopy, so it can be used for any routine AFM and STM measurements and experiments in scientific research. Here are the results of some experiments in various scientific applications: Study of atomic structures Study of metallic nanostructures Study of magnetic structures Study of polymer objects Study of biological objects Study of carbon nanomaterials

Devices of a new generation, automated stations of continuous radiation monitoring Zastava-1 are designed to organize continuous effective monitoring of the radiation situation and notification of radiation hazards. The stations have up to three independent measurement channels, which allows monitoring simultaneously in several zones. The stations support remote monitoring - they have a connection to a local computer network, Internet access.