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Measurement of electrical conductivity (UEP, UEP25) and salinity of aqueous media, including "ultrapure", in the main and flow modes. Control of water-chemical regimes at thermal and nuclear power facilities, including control of cooling water suction in the turbine condenser.Two channels | Freely programmable measurement ranges. The possibility of independent measurements at two points. Convenience and accuracy of measurement, minimum maintenance | Double automatic thermal compensation. The possibility of placing the converter unit at a remote distance from the sampling point | Up to 100 meters. Communication with external devices | Galvanically isolated current outputs 0-5/4-20/0-20 Ma. RS 485 port. Programmable setpoints with "dry contact" type output. Durable aluminum housing IP65 | The device is reliably protected from dust and moisture. Graphic indicator with backlight | Convenient data presentation format and ease of settings.

Measurement of the activity of hydrogen ions (pH, pH25) of "ultrapure" waters (including water with a reduced electrical conductivity of 0.055 microns /cm) and alkaline waters containing ammonia or amines. Measurement of electrical conductivity (UEP, UEP25), temperature of aqueous media. Control of water-chemical regimes at energy facilities. A new patented measurement method that does not require calibration. The absence of elements that degrade in "ultrapure" water. Convenience and accuracy of measurement | Automatic thermal compensation. Freely programmable measurement ranges. Measurement of conductivity in the range up to 30 microns/cm. Communication with external devices | Galvanically isolated current outputs 0-5/4-20/0-20 Ma. RS 485 port. MODBUS RTU exchange protocol. Relay of "dry" contacts (6 pcs.) with programmable functions. Durable aluminum housing IP65 | The device is reliably protected from dust and moisture. A single protective box that combines the secondary converter and the hydraulic part. Intelligent data processing algorithms. 5.7" graphic touchscreen display, 65535 colors, resolution 640*480 pixels.

It is used in technological processes of nuclear, thermal and electric power plants, boiler houses and other facilities for cooling samples supplied to automatic and manual chemical control devices.Easy-to-clean collapsible structure. Materials with high mechanical properties are used: the coil is made of 316 SS steel, the body is made of 304 steel (or 12X18H10T). It is equipped with crimp fittings for connecting sample lines without welding. It is equipped with a special three-way ball valve for supplying / draining cooling water and a control valve that provides a change in the flow of cooling water through the heat exchanger.

The modular construction principle makes it easy to adapt the devices to the specific requirements of the consumer. The standards are available in four versions – H1-1011, H1-1011/1, H1-1011/2 and H1-1011/3, which differ in metrological characteristics and a set of installed devices (modules). The built-in diagnostic system allows you to quickly determine the operability and condition of the main devices of the standards. On the front panel of the devices H1-1011 and H1-1011/2 there is an LCD display and a control panel, with which you can quickly receive information about the current parameters of the devices included in the devices and adjust the frequency of the output signals. The H1-1011 and H1-1011/2 standards can receive chronometric information from GLONASS and GPS satellite radio navigation systems and use it to synchronize the local time scale and automatically adjust the actual frequency value of the built-in highly stable rubidium frequency standard. The H1-1011 and H1-1011/2 standards include: rubidium frequency standard H1-1014; MPR-01 satellite radio navigation systems receiver module; amplifier module for highly stable sinusoidal signals (at the customer's choice): MUS-01 (3 independent outputs 10 MHz, connector type SR-50-73FV); MUS-02 (3 independent outputs of 5 MHz, connector type SR-50-73FV); MUS-03 (3 independent outputs of 1, 5 and 10 MHz, connector type SR-50-73FV); MUS-04 (6 independent outputs of 1, 5 and 10 MHz in any combination at the customer's choice, SMA connector type); MS synthesizer module with software (SMA connector type) instead of an amplifier module (at the customer's request). The scope of delivery (at the request of the customer) includes an antenna for the SRNS receiver as part of: antenna unit; mounting device; antenna cable (maximum length 60 m). The H1-1011/1 and H1-1011/3 standards include: the rubidium frequency standard H1-1013; two modules of amplifiers of highly stable sinusoidal signals (at the customer's choice): MUS-01 (3 independent outputs 10 MHz, connector type SR-50-73FV); MUS-02 (3 independent outputs of 5 MHz, connector type SR-50-73FV); MUS-03 (3 independent outputs of 1, 5 and 10 MHz, connector type SR-50-73FV); MUS-04 (6 independent outputs of 1, 5 and 10 MHz in any combination at the customer's choice, SMA connector type); MS synthesizer module with software (SMA connector type) instead of an amplifier module (at the customer's request).

On the two high-frequency outputs of the receiver board, the signals of the second mark of the navigation receiver and the RF, which are available for the customer`s use, are generated. When receiving signals from satellites of the GLONASS and GPS radio navigation systems, the board ensures the operation of the RF in the frequency binding mode according to the signals of the second timestamp (the so-called “disciplined” rubidium frequency standard mode) with an error of the actual value of the RF frequency for no more than ± 5.10-12

Designed in the form of a module, standard for RUKNAR CJSC, it can be installed in any modular device of our production, elevating its functionality to a fundamentally new level. The synthesizer module consists of three independent devices: a frequency synthesizer, a standard signal generator and a time scale generator. The module has external control via USB 2.0 interface from a personal or tablet computer.

Pulse duration: ......10-15 microseconds The duration of the leading edge of the pulse:......no more than 20 ns Pulse amplitude: ...... at least 3V at a load of 50 ohms

Mathematical processing of the measurement makes it possible to determine and display on the indicator board the relative systematic change in frequency, the average relative value of the frequency difference, the RMS relative frequency deviation, the RMS relative two-sample frequency deviation.