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The 2NVBM-400(R)/6000 booster pump consists of housings, a steam line, a trap and a heater. The required effective speed of action of the pre-vacuum pump (pumps) at a pressure of 200 Pa (1.5 mm Hg) at the outlet of the booster pump 2NVBM-400(R)/6000 is not less than 45 l/s. The maximum residual pressure of the pump 2NVBM-400(R)/6000, measured by the PMI-2 manometric ionization converter with nitrogen filled into its trap, is no more than 6.6 × 10-4 Pa (5 × 10-6 mmHg). The pressure of the cooling water at the inlet to the pump 2NVBM-400 (R)/6000 should be from 0.2 to 0.5 MPa (from 2 to 5 kgf / cm2). The drain from the pump should be free with a jet break. Cooling water consumption is 600 l/h. The total amount of working fluid for the 2NVBM-400(R)/6000 pump is 47 liters, the level of working fluid should be between the upper and lower marks of the level gauge. Replacement or refilling of the working fluid depends on the operating mode of the pump (inlet pressure, pumping duration, etc.) and the composition of the pumped medium, so the time after which the working fluid is replaced or refilled can be 100 hours or more. A large flow rate of the working fluid is observed when the pump is operating in the input pressure range from 1.33 to 13.3 Pa (from 1 ·10-2 to 1 ·10-1 mm Hg). The pump operating mode in the range from 13.3 Pa (0.1 mmHg) to the maximum residual pressure is cyclically irregular.

The working condition of the ND-630 diffusion pump depends on the temperature of the working fluid in the pump boiler. During the initial filling, it is recommended to fill the maximum volume of the working fluid. Working fluid is "VACMA OIL 500" vacuum oil (uner technical specifications TU 19.20.29-061-00218526-2019). The total amount of working fluid in the ND-630 diffusion pump is a maximum of 9 liters, a minimum of 6 liters. The viewing window for visual inspection of the working fluid has marks of its maximum and minimum amounts. During normal operation of the pump, the level of the working fluid practically does not change. The temperature of the working fluid when the pump is operating at the maximum residual pressure is about 240°C to 255°C. It is recommended to monitor the operation of heaters in the ND-630 diffusion pump using one temperature sensor. The temperature sensor must be installed in a special radiator socket above the heater. If there is a loss of working fluid and an increase in the temperature of the radiators of the ND-630 diffusion pump up to 360°C, the temperature sensor must give the command to automatically turn off the heaters. The subsequent activation of the pump heaters should not be automatic and should be performed only after cooling the system. Water at the inlet to the cooling systems of the housing and the oil reflector must be supplied with a pressure of 0.3 MPa (3 kgf/cm2) to 0.5 MPa (5 kgf/cm2) and a temperature of plus 4°C to plus 25°C. The recommended cooling water consumption for the housing is 600 l/h, for the oil reflector it is 80 l / h. It is regulated by the outlet water temperature, which should not exceed plus 40°C. The water drain should be free (with a jet break).

The working fluid of the pump is water. These pumps are designed to work with liquids as well as gases and vapors slightly soluble in them that are not aggressive to the materials of the 2VVN1-3M pump design, not explosive and non-toxic. The use of a 2VVN1-3M(H) water-ring vacuum pump for pumping out water-gas mixtures is allowed only if the bulk of the water is separated and discharged at the pump entrance. Failure to comply with this requirement may lead to unacceptable overload of the electric motor and destruction of the working bodies of the 2VVN1-3M(H) pump. The vacuum water ring pump 2VVN1-3M (H) is manufactured in the climatic version of UHL (i.e. for moderate and cold climate) 4 and O4 according to the GOST standard 15150-69, meets the requirements of technical specifications TU 3648-015-00218526-2000, designed and manufactured taking into account the requirements of GOST R 52615-2006. Electricity grid must meet the requrimemnts of GOST 32144-2013

The vacuum membrane pump PL.HM02.02.8 helps speed up the laboratory process by quickly pumping vapors and gases and creating a vacuum. Suitable for working with flammable, toxic and chemically active substances. A special feature of the PL.HM02.02.8 Primelab pump is the ability to customize it for different production tasks: • With a parallel connection, the pumping speed is 76 l/min with a maximum residual pressure of 45 mbar. • With independent connection, 38 l/min at a maximum residual pressure of 45 mbar. • When chambers are connected in series, the flow rate is 38 l/min with a maximum residual pressure of 8 mbar.

Has a number of advantages: High chemical resistance; Excellent quality. The chambers are made of fluoroplastic, all elements are coated with fluoroplastic, and the valves are made of FFKM; Low noise level (up to 75 dBA); Different ways to connect cameras with the ability to change technical characteristics; Compact dimensions; Ease of use. Characteristics Valve(s) material FFKM (Perfluoro rubber) Working medium Gas Country Russia Chemical resistance Yes Overall dimensions, L×W×H, mm 321.5x140x200 Protection class acc. to DIN EN60529 IP20 Noise level, dB 75 dB Power supply 230 V, 50 Hz Ultimate vacuum, mbar abs. 6/ 45/ 45 (serial/parallel/independent connection) Excess pressure, bar. Max. permissible 0.5 bar Capacity, l/min 38/ 76/ 38x2 (series/parallel/independent connection) Drive rotation speed, rpm 1350 Maximum current, A 1.2 Device weight, kg 9 Working chamber material PTFE (polytetrafluoroethylene) Equipment: Vacuum pump, cable, instructions, passport, packaging (vacuum regulator and spare parts are not included in the kit and must be ordered separately).

The vacuum membrane pump PL.HM02.01.4 is a universal device made in Russia from the Primelab company. Made from high-quality materials, including fluoroplastic, used to create sealed chambers, and a protective coating for safe operation of the device. The technical characteristics of the pump depend on the method of connecting the chambers. With a series connection, the performance will be 38 l/min at a maximum vacuum of 4 mbar. Parallel and independent connections will allow you to achieve completely different performance indicators of the device. The vacuum diaphragm pump PL.HM02.01.4 Primelab is convenient to use. It has a light weight of 9 kg, compact dimensions (321.5x160x200 mm) and creates a minimum of noise (up to 75 dB).

The vacuum membrane pump PL.HM01.02.10 Primelab is designed for pumping steam-gas-air media, creating a vacuum, vacuum filtration and drying. The valves are made of FFKM, the chambers are made of fluoroplastic, all connecting elements and parts are coated with fluoroplastic. The pump has good performance despite its compact dimensions (321.5x160x200 mm). At a maximum pressure of 10 mbar it is capable of pumping up to 38 l/min. Does not require constant maintenance. Complies with IP20 protection class. It has a low noise level (up to 75 dB), which does not create discomfort for laboratory staff. Supplied complete with equipment sufficient for assembly and start-up.

The diaphragm vacuum pump PL.HM02.01.10 has extremely high chemical resistance. The working chambers are made of fluoroplastic, and other parts have a fluoroplastic coating. Complies with protection class IP20. Uniqueness: The versatility of the pump allows you to connect the working chambers in three ways and thereby influence the technical characteristics.

The PL.HM03.01.60 Primelab vacuum diaphragm pump is suitable for creating a vacuum up to 60 mbar and a flow rate of 38 l/min. It has a dry design that does not require lubrication. Quite easy to use and does not create any inconvenience during operation. Its noise level does not exceed 75 dB. With a light weight of 6.9 kg, it has compact dimensions (289.5x160x200 mm), allowing the pump to be integrated into an already equipped space. Complies with IP20 protection class. The PL.HM03.01.60 Primelab vacuum diaphragm pump is supplied in the following package: vacuum pump, cable, instructions, passport, packaging (vacuum regulator and spare parts are not included in the kit and must be ordered separately). Warranty and post-warranty service is available in Russia.

Vacuum membrane pump PL.HM03.02.45 Primelab is an effective device for creating a vacuum, pumping gases and vapors. It has a high pumping speed (38 l/min) with a maximum residual pressure of 45 mbar. All materials in contact with the working fluid are made of PTFE. This material has rare chemical and physical properties. In this case, the pump does not require regular maintenance. Ease of use and reliability make the PL.HM03.02.45 diaphragm vacuum pump an ideal option for laboratories of any scale and production that require high-quality and controlled evacuation.

Vacuum membrane pump PL.HM04.02.01 PrimeLab is a compact laboratory device with which you can create a vacuum in the laboratory. It is equipped with innovative membrane technology that ensures high gas pumping speed. Suitable for pumping vapors and gases up to 1 mbar. The PL.HM04.02.01 pump has an excellent safety system. Protection against overheating and overload is provided. All contacting media are made of PTFE, which has rare chemical and physical properties. All control is carried out through vacuum control, which also ensures maximum accuracy and control of all operating parameters. It has a low noise level (75 dB), which does not cause discomfort to the working class.

Our company produces water-jet pumps not only according to our drawings, but also according to the customer’s drawings and technical specifications. How to order The Primelab water jet pump is an effective and simple device that allows you to pump out air from a desiccator, small reactor or evaporator, and organize the functioning of a vacuum line. It does not require electricity to operate, just connect to the water supply. The product is made of high quality heat-resistant tempered glass. The upper outlet is connected to the water supply using a flexible hose; water will be drained through the lower outlet. The side outlet is connected to the device in which it is necessary to create a vacuum. The pump is installed vertically. Tap water is supplied from top to bottom. The upper part of the pump gradually narrows, increasing the speed of water flow. The jet exits the nozzle at the central expansion. According to the laws of physics, as the speed of water flow increases, the pressure drops. Therefore, a vacuum is formed in the central expansion, which draws in air from the side outlet. This air is entrained by the falling water into the lower outlet tube. In this way, air is pumped out from the device or vessel connected to the pump.