METADATA IN ENGLISH
About the journal
NAUKA I
TEKHNOLOGICHESKIE RAZRABOTKI (SCIENCE AND TECHNOLOGICAL DEVELOPMENTS), ISSN:
2079-5165, eISSN: 2410-7948, DOI: 10.21455/std; https://elibrary.ru/title_about.asp?id=32295; http://std.ifz.ru/. The journal
was founded in 1992.
FIELD TEST RESULTS OF MOCKUPS OF ZDSS-M
AND MDM DIGITAL BOTTOM SEISMIC STATIONS
FOR SECURITY SYSTEMS
© 2017 I.P. Bashilov1, S.G. Volosov2,V.A. Merkulov3, N.P. Rybakov4,
S.Ya. Sukonkin4, S.Yu. Chervinchuk1
1STC
“Geotechfizpribor” of Schmidt Institute of Physics of the Earth of the Russian
Academy
of Sciences, Moscow, Russia
2Institute
of Geosphere Dynamics of the Russian Academy of Sciences, Moscow, Russia
3Federal
State Unitary Enterprise “October”, Sverdlovsk region, Kamensk-Uralskiy, Russia
4Experimental
Design Bureau of Oceanological Engineering of the Russian Academy
of Science, Moscow, Russia
Corresponding
author: I.P. Bashilov, e-mail: direction@ifz.ru
Highlights
‒ Automated seismic systems for
protecting land and sea borders are created
‒ Domestic equipment, software and
methodological support are developed
‒ Based on new solutions, broadband
sensors for large depths of the sea are designed
‒ Bottom station for transit zones based
on molecular-electronic sensors is created
‒ Experiments have confirmed the given
characteristics and reliability of the mockups
Abstract.
The main goal of the study is an experimental verification of the possibilities
of using seismic systems for autonomous monitoring and protection of land and
sea boundaries. The use of seismic systems as an integral part of
signal-guarding complexes, especially in water areas, makes high demands on the
characteristics of seismic equipment. The primary task in the experimental
studies was the development of appropriate domestic equipment and
methodological support, which allow study in terrestrial conditions and water
areas. Therefore, the primary task was to prepare for the study the relevant
domestic equipment and methodological support, which should provide work in
terrestrial conditions and water areas. Production of domestic broadband
equipment with such characteristics, and especially bottom ones, at the time of
setting the task was practically absent. Fundamentally new technical solutions
made it possible to create a number of modern models of seismic modules of the
type SM-5, SM-6, SM-3M. On their basis, one-component and three-component
short-period and broadband prototype seismic sensors of SM-5M, SM-6, TS-5, TS-6MSH
and others were used. These models were used to develop a mockup of a digital
bottom seismic station for large depths. In addition, a ground station for
transit zones was developed and tested based on molecular-electronic sensors,
which have recently developed significantly. The article contains the materials
of the development and the results of tests of mockups of digital bottom
seismic station ZDSS-M for large depths and small-sized bottom module MDM for
transit zones on the basis of a new generation of electrodynamic and
molecular-electronic sensors. The test carried out in the lake Seliger water
area. The results of the analysis of registration materials in various
conditions according to the developed methods have confirmed the specified
characteristics and reliable operation of the mockups and methodological
support in shallow water areas. An important result of the work is organization
of industrial production of TS-5 seismic modules, which solves some problems of
import substitution.
Keywords:
seismic sensor, broadband seismometer, bottom seismic station,
amplitude-frequency characteristic, seismic recorder, seismic channel
sensitivity, electron-molecular geophone, transit zone of the shelf
Cite this
article as:
Bashilov I.P., Volosov S.G., Merkulov V.A., Rybakov N.P.,
Sukonkin S.Ya., Chervinchuk S.Yu. Field test
results of mockups of ZDSS-M and MDM digital bottom seismic stations for
security systems, Nauka i Tekhnologicheskie
Razrabotki (Science and Technological Developments), 2017, Vol. 96,
No. 3, pp. 19–32. [Special issue “Applied Geophysics: New Developments and
Results. Part. 1. Seismology and Seismic Exploration”]. [in Russian].
DOI: 10.21455/std2017.3-2
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About the authors
BASHILOV Igor Porfirievich — Doctor of Technical Sciences, Chief Scientific
Researcher, Scientific and Technical Center “Geofizpribor” of Schmidt Institute
of Physics of the Earth of the Russian Academy of Sciences. 123242, Moscow, ul.
Bolshaya Gruzinskaya 10, stroenie 1. Tel.: (499) 254-30-60. E-mail:
direction@ifz.ru; Web site: http://www.ifz.ru/
(corresponding author)
VOLOSOV Sergey Georgievich — Senior Researcher, Institute of Geosphere Dynamics of
the Russian Academy of Sciences. 119334, Moscow, Leninskii prospect 38,
stroenie 1. Tel.: (499) 137-66-11. E-mail: geospheres@idg.chph.ras.ru; Web
site: http://idg.chph.ras.ru/
MERKULOV Valery Alekseevich — Chief Designer for Instrumental Products, Head of the
Department of Chief Designer, “PA” Oktyabr”. 623400, Sverdlovsk Region,
Kamensk-Uralsky, ul. Ryabova 8. Tel.: (3439) 33-96-88 E-mail:
ogk@neywa.ru; Web site: http://www.neywa.ru/
RYBAKOV Nikolai Pavlovich — Head of the Department of Instruments and Systems of
Experimental Geophysics, Experimental Design Bureau of Oceanological Technology
of the Russian Academy of Sciences. 109387, Moscow, ul. Letnyaya 1,
stroenie 2. Tel.: (495) 350-21-11. E-mail: okb@edboe.ru; Web site:
http://www.edboe.ru/
SUKONKIN Sergey Yakovlevich — Director,
Experimental Design Bureau of Oceanological Technology, of the Russian Academy
of Sciences. 109387, Moscow, ul. Letnyaya, stroenie 2. Tel.: (495)
350-26-12. E-mail: okb@edboe.ru; Web site: http://www.edboe.ru/
CHERVINCHUK Sergey Yuryevich — Senior
Researcher, Scientific and Technical Center “Geofizpribor” of Schmidt Institute
of Physics of the Earth of the Russian Academy of Sciences. 123242, Moscow,
ul. Bolshaya Gruzinskaya 10, stroenie 1. Tel.: (499) 254-30-60.
E-mail: direction@ifz.ru; Web site: http://www.ifz.ru/