Solar Energy

Environmental project «Serial 50 KW Solar vortex power plant

for African village by 2000 USD per one kW» Azerbaijan

The European Bank for Reconstruction and Development -EBRD

The project area

Creating a prototype for vortex power plant mass production.

The aim of the project in a more efficient delivery of electricity to remote zone operation

Maximizing the effectiveness of the project known Solar Chimney.

Garber Foundation-GHP, Schlaih Bergermann und Patrner GMBH.

Work by the implementation of industrial production is beyond the scope of this project.

Targets

Determination of the overall project objectives:

technical objectives: design documentation and field tests of the prototype;

goal of project planning: obtaining comparable Solar Chimney power at least the geometrical dimensions;

objective analysis of project costs: reducing the cost of the project, respectively;

special purpose: obtaining evidence for the efficacy of the theory of vortex.

excluded goals: comparison with the conventional propeller type wind generators.

The final results

The result of the project:

The project implementation will be launching a series of new generation of wind turbines vortex.

Description of customer needs:

Potential customers will be interested enough to buy a high capacity power plant that does not require fuel, quiet, easy to use anywhere and environmentally friendly.

Success Factors

• Aspects that play a key role in the success of the project:

– customer satisfaction and stakeholders in getting the product in demand in the market and its further development in a more powerful power plant;

– achieving the objectives of the project will reduce the cost of electricity kilowatt installation of wind generators;

– completion of the project within the budget calculated in advance and meets all expectations;

– delivery of the project on time guaranteed long-term theoretical research and practical development of experimental design documentation.

Roles and responsibilities of the project team

George Mamulashvili

Georgia

Project manager

Julian

Breinersdorfer Architect

Germany

Zurab Beria

Senior Researcher

Georgia

Gilles Breche

Engineer Mechanic

France

Gogi Gogishvili

Physic

Georgia

Yuri Chahunashvili

Assistant Finansial

Georgia

Rassul Suleiman

Azerbaijan

Mentor

Wolfgang Schell

Mentor

Germany

Introduction

Objectives and actions: perform R & D and transfer the laboratory model and the design documentation to the process engineer;

Procedures: To develop the manufacturing technology for the development of industrial design; produce three samples and conduct field trials; develop a working design documentation based on field tests and pass it into production;

Tools and technologies: fully equipped laboratory aero and hydrodynamics, St. Petersburg State Polytechnic University; super-computers mechanical laboratory of the Department of Applied Mechanics; electrical machines laboratory at St. Petersburg State University of Railways;

Change control process by the project carried out by a team headed by a project manager, who in turn shall report monthly to investors.

Resources

People

Resource 1: Project Group 6 people.

Resource 2: staff aero-hydrodynamic laboratory 5 people.

Resource 3: engineering staff of 200 people for the plant production/.

Notes

Laboratory Equipment

Resource 1 Super-

computer Resource 2 Aero-tube Resource 3

Hydrodynamic pool.

Notes

Location

Resource 1

Petersburg Resource 2

Tbilisi

Resource 3 Stuttgart

Resource 4 Berlin

Notes

Third-party services

Resource 1 SPB Politechnic University Resource 2

Schuttgart university

Resource 3

Potsdam University

Notes

Production

Resource 1

Company Solver – ROC Sant-Petersburg

Resource 2 c/o Mamulashvili

Tbilisi

Notes

Sales

Resource 1

Gazprom-Transgaz Sanrt-

Petersburg Resource 2

Lukoil

Resource 3

Sokar

Notes

Cost analysis

0 €

200 000 €

400 000 €

600 000 €

800 000 €

1 000 000 €

1 200 000 €

1 400 000 €

Spare parts and materials

Manufacturing equipment

Wages Service Office rental Rent warehouse Insurance Benefits and pensions

Transportation Research&Disaign

Annual costs

Schedule and project milestones

Milestone 1

Mathematic modeling

Laboratory test

Field experience

Making pilot batch

Milestone 2

Installation of an experimental batch in different climatic

zones and production tests

Milestone 3

Based on a test pilot in the manufacture of industrial batch

production batch of the product and

market penetration.

Milestone 4

Development of markets for the

country and access to the international

market, the production of new

products on the orders.

Risk Management Plan

Risk Probability Influence Responsible

person Mitigation plan

Budget cuts could lead to layoffs of personnel and affect the area and timing of the project.

Average High Project

manager Phased implementation plan, see appendix.

High cost serial installation Average

Poor

Project manager

Phased implementation plan, see appendix.

Rise in price of materials Average

Poor

Project manager

Phased implementation plan, see appendix.

Quality management and performance

Defining quality management plans: check stage is scheduled for analytical calculations, laboratory tests and field work on the testing of three pilot samples as part of the competent commission of the leading universities from Russia and Germany.

Tracking and controlling costs will be charged the committee of the two participants in the investment process involving the project manager.

Tracking and monitoring compliance with the terms of the project within 3 years will be charged audit committee at the fund Garber with representatives of the German side.

Seven reasons to choose my project for year conditions: 1. Scalable from 1-5 kW to 50-100 kW at the expense only of the dimensions and use of the

diffuser. Next up to 100 MW sharp rise in the volume of construction and other construction

conditions. 2. Slow start for moving and high resistance to storm the wind and the whirlwind up to 200

m/sec due to the pivot bearing. 3. The ability to easily relocate and compact, without any fastener elements through the use of

the lung membrane and composite materials. 4. High manufacturability of all parts, especially blades. 5. Low operating costs due to the use of inexpensive materials and an almost complete lack of

accumulation of condensate. 6. New generator with permanent magnets with the possibility of greater energy than produced

at the turbine shaft due to the large radius. 7. The versatility of working in two environments of the same design without special

modifications of the process of producing electric energy, due to the increased area of the perception of the turbine blades of an air or hydraulic flow.

Consistently shown in the photographs in certain types of stations at the top and bottom of the vortex turbine guide in spiral wind flow.

The internal structure rising up station with spiral vortex turbine and the view at the base, which outlines the installation of electric generator.

Technology of the manufacturing and assembly of the plant consists from three main stages:

the first is the installation of spiral guides, then build on them and finally the building of the

station turbine unit.

The principle of operation of the station is based on the ranking of the Brownian motion of molecules, in which case rotation in the vortex established in the ejection direction of the nozzle

The ANSYS program performed pretreatment data for calculating the capacity of air flow and positive results.

Boundaries conditions

Inlet: T=15 0 Pin=101300 Pa

Outlet: T=15 0 Pout =100700 Pa

H=

50

m

T= -10 0

T= 40 0

RT

HMgPP inout exp

M = 29 kg/kmol – Molar massg = 9.8 m/s2

R = 8,31 gas constant

The pressure values, flow rate and temperature parameters sufficient to show a conversion of wind kinetic energy into potential energy of the powerful

battery charging.

TESTS OF THE MODEL SERIES VORTEX TURBINE Tests were carried out in the laboratory of Saint Petersburg State Polytechnic University.

Laboratory for testing Model vortex turbine 1 kW

BIBLIOGRAPHY

1. http://en.wikipedia.org/wiki/User:Dr._End._George_Mamulashvili 2. http://tpe-toursolaire.skyrock.com/ 3. http://quanthomme.free.fr/energieencore/carnet14.htm 4. http://www.startbase.ru/knowledge/articles/318/ 5. http://www.yasni.ru/top-vip/rossiya 6. http://www.econologie.com/tour-solaire-a-vortex-principe-articles-4052.html 7. http://sans-langue-de-bois.eklablog.fr/energie-libre-et-gratuite-a104695498 8. http://cdurable.info/spip.php?page=imprimersans&id_article=547 9. http://www.tour-solaire.fr/fr/definitions.php 10. https://www.yumpu.com/en/document/view/18573007/air-thermal-power-efficiency-rise-researchgate 11. http://lemoteur.orange.fr/?module=orange&kw=george+mamulashvili&bhv=web_fr 12. http://www.techno-science.net/?onglet=glossaire&definition=7180http://www.economie-denergie.wikibis.com/tour_solaire.php 13. http://fr.academic.ru/dic.nsf/frwiki/1647063 14. http://www.buch-der-synergie.de/c_neu_html/c_08_10_windenergie_aufwind_bis_stauwerk.htm 15. http://webcache.googleusercontent.com/search?q=cache:DjS8BqPhjOsJ:www.energycentral.com/generationstorage/solar/articles/1648/C

ombining-Wind-Power-with-Solar-Chimneys+&cd=13&hl=en&ct=clnk&gl=ru 16. http://www.hydrogen.ru/ISJAEE_05_2008/page_62.htm