The structure of hydraulic structures of power and water management systems includes gates for various purposes, which allow you to regulate and distribute the flow of water in channels and waterworks. The disadvantages of these gates are limited functionality and frequent changes in position in the “working” and “non-working” modes, which require high energy consumption and lead to rapid wear and failure of the gate seals. Existing gate designs do not provide for the possibility of generating electricity from the water energy of the stream passing through them. In order to convert the hydraulic energy of water passing through the gates into electrical energy a new patented design of the gate is proposed which allows using micro-hydroelectric power plants with a Banki turbine to make more rational use of the hydro resources of energy and water management systems. The proposed design solves the problem of expanding the functionality of the gate and increasing the efficiency of micro-hydroelectric power plants with a reduction in its cost. Areas of application of the new design for the combined use of micro-hydroelectric power plants and hydraulic gates at hydroelectric power systems are also proposed. The technique for determining the technical and economic parameters of micro-hydroelectric power plants installed on flat gates of hydraulic structures is given, and theoretical calculations are performed, which showed that the higher the capacity of micro-hydroelectric power plants, the shorter its payback period. It has been established that with a power of micro-hydroelectric power plants more than 10 kW, the design is economically effective and with the help of such installations it is possible to solve the issues of autonomous functioning of gates under various operating modes, issues of energy supply to small consumers, individual and individual farms, problems of energy conservation and preservation of environmental cleanliness.

Topics
Electrical energy, Energy consumption, Energy conservation, Energy production, transmission and distribution, Hydroelectric energy, Hydraulic energy, Hydrology
1.
M.
Mukhammadiev
,
B.
Urishev
,
E.
Mamadiyorov
,
Dzhuraev
K.S.
 Low Power Plants on the Basis of Renewable Energy Sources.
Monograph, T
.:
ToshDTU
, (2015)
F.
De Lillo
,
F.
Cecconi
,
G.
Lacorata
,
A.
Vulpiani
, EPL,
84
(
2008
)
2.
M.
Muhammadiev
,
K.S.
Dzhurayev
,
B.U.
Urishev
.
Increase of Use of Hydropower Potential of Low Power Irrigation Facilities with Application of New Design Gates
.
Journal “Vestnik TashGTU
”, No.
2
, (
2015
)
Google Scholar
 
3.
M.M.
Muhammadiev
,
S.
Klychev
,
K.S.
Dzhuraev
.
Investigation of Water Flow Velocity in Gates of Hydroelectric and Irrigation Facilities
.
Magazine “Vestnik SGASU: Urban Planning and Architecture
”, issue No
2
, (
2016
).
Google Scholar
 
5.
Hydroelectric stations
.
Guide for developers and investors
, (
2010) ww.ifc.org/wps/wcm/connect/06b2df8047420bb4a4f7ec57143498e5/hydropower_report.pdf?mod=ajperes
.
6.
G.I.
Sidorenko
,
I.G.
Kudryasheva
,
V.I.
Pimenov
. Economics of the installations of the non-traditional and renewable energy sources.
Technical and economic analysis: tutorial / Under general
ed. Elistratova,
G.I.
Sidorenko
, S.P.B.:
Politekhi Publisher, Un-ta
, (
2008
).
Google Scholar
 
7.
Hydropower Texnology Roadmar
2012. http://www.iea.org.2012_hydropower_roadmar.pdf (
2012
)
8.
World Small Hydropower Development Report
2016
. www.unido.org/sites/default/files/(2016)11/wshpdr_executive_summary_2016_0.pdf
10.
Asmae
Berrada
,
Zineb
Bouhssine
,
Ameur
Arechkik
.
Optimisation and economic modeling of micro hydropower plant integrated in water distribution system
.
Journal of cleaner production
, volume
232
,
20 September 2019
, (
2019
)
Google Scholar
 
11.
Muhammad
Kamran
,
Rohail
Asghar
,
Muhammad
Mudassar
,
Muhammad Irfan
Abid
.
Designing and economic aspects of run-of-canal based micro-hydro system on Balloki-Sulaimanki link canal-i for remote villages in Punjab, Pakistan
.
Renewable Energy
, volume
141
,
October 2019
, (
2019
)
Google Scholar
 
12.
H.
Bory
,
L.
Vazquez
,
H.
Martínez
,
Y.
Majanne
.
Symmetrical angle switched single-phase and three-phase rectifiers: application to micro Hydro Power Plants
.
Ifac-papersonline
, volume
52
, issue
4
, (
2019
)
https://doi.org/10.1016/j.ifacol.2019.08.182
Google Scholar
 
13.
Petras
Punys
,
Algis
Kvaraciejus
,
Antanas
Dumbrauskas
,
Linas
Šilinis
,
Bogdan
Popa
.
An assessment of micro-hydropower potential at historic watermill, weir, and non-powered dam sites in selected eu countries
.
Renewable energy
, volume
133
, April (
2019
)
https://doi.org/10.1016/j.renene.2018.10.086
Google Scholar
 
14.
T.
Ueda
,
E. S.
Roberts
,
A.
Norton
,
d.
Styles
,
J.
Gallagher
.
A life cycle assessment of the construction phase of eleven micro-hydropower installations in the UK
.
Journal of cleaner production
, volume
218
,
1 May
(
2019
)
Google Scholar
 
15.
Yanlai
Zhou
,
Li-Chiu
Chang
,
Tin-Shuan
Uen
,
Shenglian
Guo
,
Fi-John
Chang
.
Prospect For Small-Hydropower Installation Settled Upon Optimal Water Allocation: An Action To Stimulate Synergies Of Water-Food-Energy Nexus
.
Applied energy
, volume 238,
15 March
(
2019
)
Google Scholar
 
16.
D.
Singh
: “
Micro hydro power
”,
resource assessment handbook
(
2009
).
Google Scholar
 
17.
Small And Micro-Scale Hydropower in Japan
. https://halshs.archives-ouvertes.fr/halshs-01803429/document
18.
Small Hydro Power in India
. http://www.energynext.in/2017/03/small-hydro-power-in-india/
19.
M.
Muhammadiev
,
B.U.
Urishev
,
K.S.
Dzhuraev
,
S.R.
Zhuraev
 and others.
Water Intake Structure with Hydroelectric Power Station
. Patent UZ IAP No 205378, No 4, 28.04.2017.(
2017
)
Google Scholar
 
20.
Shibabrata
Choudhury
,
Adikanda
Parida
,
Rajive Mohan
Pant
,
Saibal
Chatterjee
.
GIS augmented computational intelligence technique for rural cluster electrification through prioritized site selection of micro-hydro power generation system
.
renewable energy
, volume
142
, ovember (
2019
)
https://doi.org/10.1016/j.renene.2019.04.125
Google Scholar
 
21.
Hossein
Iman-Eini
,
David
Frey
,
Seddik
Bacha
,
Cedric
Boudinet
,
Jean-Luc
Schanen
.
Evaluation of loss effect on optimum operation of variable speed micro-hydropower energy conversion systems.
Renewable energy
, volume
131
, february (
2019
)
https://doi.org/10.1016/j.renene.2018.07.122
Google Scholar
 
22.
Elie Bertrand Kengne
Signe
,
Bachirou
Bogno
,
Michel
Aillerie
,
Oumarou
Hamandjoda
.
Performance in feasibility studies of micro hydro power plants. new software development and application cases in Cameroon
.
energy procedia
, volume
157
, january (
2019
)
Google Scholar
 
23.
A.D.
Girgidov
.
Fluid and gas mechanics (hydraulics): textbook
. 2nd ed., pp.
i
dop. -
Moscow
:
Infra-M
, (
2020
)
Google Scholar
 
24.
M.M.
Mukhammadiev
,
K.S.
Dzhuraev
.
2020 Justification of the energy and economic parameters of pumped storage power plants in Uzbekistan
.
International journal “Applied Solar Energy
”, Vol.
56
,
23
, pp.
227
232
.
25.
M.
Mukhammadiev
,
O.
Glovatskiy
,
N.
Nasyrova
,
N.
Karimova
,
A. Abduaziz
uulu
 and
A.
Boliev
.
Assessment of investment technologies for use of hydro – accumulating stations on intermediate channels of irrigation systems and water reservoirs
.
IOP Conf. Series: Earth and Environmental Science
614
(
2020
)
012088
. doi:
https://doi.org/10.1088/1755-1315/614/1/012088
Google Scholar
 
26.
M.
Mukhammadiev
,
K.S
Dzhuraev
,
S.
Juraev
,
N.
Karimova
,
A. Abduaziz
uulu
 and
A.
Makhmudov
.
Methodology for substantiation of technical and economic indicators of PSPP in energy water management systems of Uzbekistan
.
E3S Web of Conferences
264
,
04056
(
2021
).
https://doi.org/10.1051/e3sconf/202126404056
Google Scholar
 
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