A universal device capable of measuring alpha, beta, gamma and neutron radiation. The smallest and lightest device in its class.
MKC-RM1401K / KM is a portable complex device that combines the functions of a search device and a dosimeter-radiometer.
PM1401K is equipped with built-in alpha, beta, gamma and neutron radiation detectors. PM1401KM is a lightweight modification equipped with built-in alpha, beta and gamma radiation detectors (without a neutron channel).
Main features:
Detection of ionizing radiation sources - alpha, beta, gamma (both modifications) and neutron (PM1401K only);
Search and localization by photon (X-ray and gamma), alpha, beta (both modifications) and neutron (PM1401K only) radiation;
Measurement of gamma radiation dose rate;
Measuring the degree of surface contamination by alpha and beta sources;
Built-in sound alarm;
External vibration alarm for hidden detection and operation in places with increased noise levels;
Non-volatile memory;
Shockproof metal case;
Low weight and small size.
The device is equipped with built-in detectors, has non-volatile memory, which stores up to 500 history events, including measurement results, facts of detection of sources when alarm thresholds are exceeded and up to 99 accumulated gamma spectra.
A small-sized, sealed, shockproof case, equipped with a fluorescent LCD backlight ensures the operability of the device in harsh and adverse climatic conditions.
The device can be worn on a belt, which makes it convenient to use for customs, border, police, emergency rescue services, etc. Without interfering with the user's direct duties, the device immediately informs him of the appearance of an ionizing radiation source in the control zone.
The device can be additionally equipped with a set of various accessories, including an external vibration alarm, a telescopic extension, which provides for the search and measurement of sources in hard-to-reach places. There is an external neutron moderator, which is a polyethylene chamber, inside which the device is placed. This makes it possible to detect and localize sources of fast neutrons that caused the operation of stationary radiation monitors.