TM ETRS-TM35FIN-ETRS89 WTG



Similar documents
WindPRO version Apr 2013 Project:

WindPRO version Sep 2014 Printed/Page :30 / 1. DECIBEL - Main Result Calculation: Wariant I wie a 90 m. Calculation Results

Miljøudvalget MIU Alm.del Bilag 422 Offentligt

Dutch Stereo-RD/NAP 2000 WTG type Shadow data East North Z Row Valid Manufact. Type-generator Power, rated Rotor diameter Hub height Calculation RPM

Trans Bay Cable Project (400 MW) Preliminary Audible Noise Study

WindPRO version jun 2010 Project:

As a minimum, the report must include the following sections in the given sequence:

MCS 020. MCS Planning Standards. For permitted development installations of wind turbines and air source heat pumps on domestic premises

Sound Power measurements according to IEC


Mark Bliss, BKL Consultants Ltd. # Lynn Valley Road, North Vancouver, BC, V7J 2A2 Canada

Annex H6. Clocaenog Forest Wind Farm Cumulative Assessment Figures

Document number #12 DNS Authors #20 Telephone: Date #40 AUGUST 2013

GUIDELINE ON BOUNDARY NOISE LIMIT FOR AIR CONDITIONING AND MECHANICAL VENTILATION SYSTEMS IN NON-INDUSTRIAL BUILDINGS

Acoustic Terms, Definitions and General Information

Measures to increase accuracy and precision of software-based noise prediction

V MW Making wind even more profitable

SPEECH INTELLIGIBILITY and Fire Alarm Voice Communication Systems

Sound Power Measurement

Power output of offshore wind farms in relation to atmospheric stability Laurens Alblas BSc

FLOWSTAR-Energy Validation NoordZee Wind Farm

How Noise is Generated by Wind Turbines The mechanisms of noise generation. Malcolm Hayes Hayes McKenzie Partnership Ltd Machynlleth & Salisbury

Noise from large wind turbines (with focus on low frequencies)

Results of wake simulations at the Horns Rev I and Lillgrund wind farms using the modified Park model

INTERNATIONAL ANNEX III. Technical Details of Sound Signal Appliances

Core Fittings C-Core and CD-Core Fittings

V MW. Your best option for low cost energy production at low and medium wind sites. Federico Gonzalez Vives. Director Technology.

ENERCON WIND TURBINES

Atmospheric Effects On Traffic Noise Propagation Behind Noise Barriers

Spectrum Level and Band Level

Sound Attenuation INTRODUCTION

The BASIS module in WindPRO is necessary for the use of any of the other calculation modules. It contains the four following elements:

HVAC Acoustic Fundamentals

KRUGER ENERGY CHATHAM WIND PROJECT ENVIRONMENTAL SCREENING REPORT / ENVIRONMENTAL IMPACT STATEMENT. Appendix E. Environmental Noise Impact Assessment

Relationship between Sound Pressure and Sound Power Levels

Bergen, Norway BNAM May Modern passenger trains in Norway - are they as quiet as we think?

V MW & V MW (OFFSHORE)

CFD SIMULATIONS OF WAKE EFFECTS AT THE ALPHA VENTUS OFFSHORE WIND FARM

User manual data files meteorological mast NoordzeeWind

Sound Power Level determination of AEG KM880 electrically operated food preparation appliance

Testing laboratory HVAC. Test report No.: HP e

V kw The turbine that goes anywhere

A simple method to compute aircraft noise inside dwellings

Comparison of predicted and measured wind farm noise levels and implications for assessments of new wind farms

DATE: July 12, 2004 SUBJECT: Gaudet School Chiller Noise Survey Results

Radio Frequency Interference (RFI) Shielding Principles

TITLE Quiet City Transport Subproject 5 Noise propagation & receiver perception Work Package

TURBOWENT TULIPAN - rotary chimney cowl Ø150

Fundamentals of Acoustics & Practical HVAC Design Considerations. Demir Doken Acoustic Engineer

Excerpts from: Performance, Duration and Acoustic test reports for the Skystream 3.7 wind generator

Schindler 3300 / Schindler 5300 Information on noise and vibration.

BWEA Summary Report for the C&F Green Energy Small Wind Turbine, Model No. CF20 (Phase A)

10.2 Series and Convergence

What are the Requirements for an Accurate DSL Line Simulator? Paradyne International, France

Measuring of optical output and attenuation

INFLUENCES OF VERTICAL WIND PROFILES ON POWER PERFORMANCE MEASUREMENTS

Estimation of Loudness by Zwicker's Method

Western University. Hearing Protection Program. Prepared by: Occupational Health and Safety

What are Fibre Optics?

PAGE 2. Figure 1: Difference between PWL ins and SPL 1m

Relevance of Modern Optimization Methods in Turbo Machinery Applications

Dynamic sound source for simulating the Lombard effect in room acoustic modeling software

Wind Resource Assessment for BETHEL, ALASKA Date last modified: 2/21/2006 Compiled by: Mia Devine

ENERGY YIELD ASSESSMENT

MEASURES OF VARIATION

Affordable Sports Halls

SYSTEM DESIGN AND THE IMPORTANCE OF ACOUSTICS

INTI National Institute of Industrial Technology. Argentina OBJECTIVES AND AIMS ACTIVITIES

Attractive wind turbines and solar cell facilities

Noise attenuation directly under the flight path in varying atmospheric conditions

ACOUSTICS: The Sounds of Sustainable Design

How To Reduce Noise From A Test Screen

Sweden s leading manufacturer of small-scale wind power stations!

Effects of Underwater Noise

Acoustics & Building Services An back to basics overview

Attaching the PA-A1-ATM Interface Cables

MONKTON PARK, CHIPPENHAM SKATE PARK. Noise Impact Assessment. Wiltshire Council 27 June Page 1 of 32

Acoustic design with wall acoustic solutions

Instructions for the use of E-A-RTONE 3A. Insert Earphones. Revised 1997 per ANSI S and ISO 389-2: /99

INTER-NOISE DECEMBER 2006 HONOLULU, HAWAII, USA

Sound absorption and acoustic surface impedance

VIRTUAL SPACE 4D PROJECT: THE ROOM ACOUSTICAL TOOL. J. Keränen, P. Larm, V. Hongisto

Standex-Meder Electronics. Custom Engineered Solutions for Tomorrow

Nordex SE. Nordex goes Offshore

Conversion of existing road source data to use CNOSSOS-EU

Build Green Schools. Click on this link for more information.

Unico Inverter. Unique and efficient.

Transcription:

DECIBEL - Main Result Calculation: 6 x V126 x HH150 Noise calculation model: ISO 9613-2 General Wind speed: 8,0 m/s Ground attenuation: General, Ground factor: 0,4 Meteorological coefficient, C0: 0,0 db Type of demand in calculation: 1: noise is compared to demand (DK, DE, SE, NL etc.) Noise values in calculation: All noise values are mean values (Lwa) (Normal) Pure tones: Pure and Impulse tone penalty are added to source noise Height above ground level, when no value in NSA object: 4,0 m Don't allow override of model height with height from NSA object Deviation from "official" noise demands. Negative is more restrictive, positive is less restrictive.: 0,0 db(a) s New 22.12.2014 11:35 / 1 Scale 1:100 000 Noise sensitive area Finish TM ETRS-TM35FIN-ETRS89 type Noise data East North Z Row data/description Valid Manufact. Type-generator Power, Rotor Hub Creator Name Wind Status LwA,ref Pure rated diameter height speed tones [m] [kw] [m] [m] [m/s] [db(a)] 1 436 173 6 818 685 135,0 VESTAS V126-3.3 GridStreame 3...Yes VESTAS V126-3.3 GridStreame-3 300 3 300 126,0 150,0 USER Level 0 - - Mode 0-08-2014 8,0 From other hub height 107,5 0 db f 2 436 787 6 818 645 122,5 VESTAS V126-3.3 GridStreame 3...Yes VESTAS V126-3.3 GridStreame-3 300 3 300 126,0 150,0 USER Level 0 - - Mode 0-08-2014 8,0 From other hub height 107,5 0 db f 3 435 641 6 816 915 119,0 VESTAS V126-3.3 GridStreame 3...Yes VESTAS V126-3.3 GridStreame-3 300 3 300 126,0 150,0 USER Level 0 - - Mode 0-08-2014 8,0 From other hub height 107,5 0 db f 4 435 239 6 817 631 125,0 VESTAS V126-3.3 GridStreame 3...Yes VESTAS V126-3.3 GridStreame-3 300 3 300 126,0 150,0 USER Level 0 - - Mode 0-08-2014 8,0 From other hub height 107,5 0 db f 5 434 661 6 818 242 130,0 VESTAS V126-3.3 GridStreame 3...Yes VESTAS V126-3.3 GridStreame-3 300 3 300 126,0 150,0 USER Level 0 - - Mode 0-08-2014 8,0 From other hub height 107,5 0 db f 6 433 831 6 819 616 110,0 VESTAS V126-3.3 GridStreame 3...Yes VESTAS V126-3.3 GridStreame-3 300 3 300 126,0 150,0 USER Level 0 - - Mode 0-08-2014 8,0 From other hub height 107,5 0 db f f) From other hub height Calculation Results Sound Level Noise sensitive area Finish TM ETRS-TM35FIN-ETRS89 Demands Sound Level Demands fulfilled? No. Name East North Z Imission Noise From Distance to Noise height s noise demand [m] [m] [db(a)] [db(a)] [m] A Asuinrakennus (Uusjoutsjärventie 373) 437 181 6 819 012 94,9 4,0 40,0 41,6-105 No B Asuinrakennus (Ahorajantie 64) 437 593 6 817 840 93,6 4,0 40,0 34,8 485 Yes C Asuinrakennus (Uutelantie 82) 436 720 6 816 765 95,0 4,0 40,0 35,5 437 Yes D Lomarakennus (Mikkolanmäentie 24) 435 686 6 815 393 88,9 4,0 40,0 31,0 896 Yes E Lomarakennus (Viitostie) 433 985 6 816 894 96,1 4,0 40,0 34,2 675 Yes F Asuinrakennus (Vanhatie) 432 863 6 820 657 110,0 4,0 40,0 30,7 822 Yes G Lomarakennus (Oksjärventie 160) 435 478 6 820 385 90,3 4,0 40,0 32,0 1 141 Yes Distances (m) NSA 1 2 3 4 5 6 A 1060 539 2602 2383 2635 3404 B 1652 1139 2160 2363 2959 4160 C 1996 1881 1090 1716 2534 4059 D 3328 3434 1523 2283 3028 4613 E 2828 3304 1656 1455 1508 2727 F 3852 4409 4660 3847 3010 1421 G 1837 2177 3474 2764 2293 1818

DECIBEL - Detailed results Assumptions Calculated L(DW) = LWA,ref + K + Dc - (Adiv + Aatm + Agr + Abar + Amisc) - Cmet (when calculated with ground attenuation, then Dc = Domega) LWA,ref: Sound pressure level at K: Pure tone Dc: Directivity correction Adiv: the attenuation due to geometrical divergence Aatm: the attenuation due to atmospheric absorption Agr: the attenuation due to ground effect Abar: the attenuation due to a barrier Amisc: the attenuation due to miscellaneous other effects Cmet: Meteorological correction Calculation Results Noise sensitive area: A Asuinrakennus (Uusjoutsjärventie 373) 1 1 060 1 076 33,41 107,5 0,00 71,64 - - 0,00 0,00-0,00 2 539 566 40,72 107,5 0,00 66,06 - - 0,00 0,00-0,00 3 2 602 2 608 21,67 107,5 0,00 79,32 - - 0,00 0,00-0,00 4 2 383 2 390 22,93 107,5 0,00 78,57 - - 0,00 0,00-0,00 5 2 635 2 642 21,49 107,5 0,00 79,44 - - 0,00 0,00-0,00 6 3 404 3 408 17,69 107,5 0,00 81,65 - - 0,00 0,00-0,00 Sum 41,63 Noise sensitive area: B Asuinrakennus (Ahorajantie 64) 1 1 652 1 663 27,92 107,5 0,00 75,42 - - 0,00 0,00-0,00 2 1 139 1 152 32,58 107,5 0,00 72,23 - - 0,00 0,00-0,00 3 2 160 2 166 24,32 107,5 0,00 77,71 - - 0,00 0,00-0,00 4 2 363 2 369 23,05 107,5 0,00 78,49 - - 0,00 0,00-0,00 5 2 959 2 965 19,79 107,5 0,00 80,44 - - 0,00 0,00-0,00 6 4 160 4 163 14,60 107,5 0,00 83,39 - - 0,00 0,00-0,00 Sum 34,81 Noise sensitive area: C Asuinrakennus (Uutelantie 82) 1 1 996 2 005 25,39 107,5 0,00 77,04 - - 0,00 0,00-0,00 2 1 881 1 889 26,21 107,5 0,00 76,52 - - 0,00 0,00-0,00 3 1 090 1 103 33,11 107,5 0,00 71,85 - - 0,00 0,00-0,00 4 1 716 1 725 27,43 107,5 0,00 75,74 - - 0,00 0,00-0,00 5 2 534 2 541 22,05 107,5 0,00 79,10 - - 0,00 0,00-0,00 6 4 059 4 062 14,99 107,5 0,00 83,18 - - 0,00 0,00-0,00 Sum 35,51 22.12.2014 11:35 / 2

DECIBEL - Detailed results Noise sensitive area: D Lomarakennus (Mikkolanmäentie 24) 1 3 328 3 334 18,02 107,5 0,00 81,46 - - 0,00 0,00-0,00 2 3 434 3 438 17,55 107,5 0,00 81,73 - - 0,00 0,00-0,00 3 1 523 1 533 28,98 107,5 0,00 74,71 - - 0,00 0,00-0,00 4 2 283 2 290 23,54 107,5 0,00 78,20 - - 0,00 0,00-0,00 5 3 028 3 034 19,44 107,5 0,00 80,64 - - 0,00 0,00-0,00 6 4 613 4 616 12,99 107,5 0,00 84,29 - - 0,00 0,00-0,00 Sum 30,95 Noise sensitive area: E Lomarakennus (Viitostie) 1 2 828 2 834 20,46 107,5 0,00 80,05 - - 0,00 0,00-0,00 2 3 304 3 309 18,14 107,5 0,00 81,39 - - 0,00 0,00-0,00 3 1 656 1 665 27,90 107,5 0,00 75,43 - - 0,00 0,00-0,00 4 1 455 1 465 29,57 107,5 0,00 74,32 - - 0,00 0,00-0,00 5 1 508 1 519 29,10 107,5 0,00 74,63 - - 0,00 0,00-0,00 6 2 727 2 731 21,00 107,5 0,00 79,73 - - 0,00 0,00-0,00 Sum 34,21 Noise sensitive area: F Asuinrakennus (Vanhatie) 1 3 852 3 856 15,79 107,5 0,00 82,72 - - 0,00 0,00-0,00 2 4 409 4 412 13,70 107,5 0,00 83,89 - - 0,00 0,00-0,00 3 4 660 4 662 12,85 107,5 0,00 84,37 - - 0,00 0,00-0,00 4 3 847 3 850 15,82 107,5 0,00 82,71 - - 0,00 0,00-0,00 5 3 010 3 015 19,54 107,5 0,00 80,59 - - 0,00 0,00-0,00 6 1 421 1 428 29,89 107,5 0,00 74,10 - - 0,00 0,00-0,00 Sum 30,73 Noise sensitive area: G Lomarakennus (Oksjärventie 160) 1 1 837 1 846 26,52 107,5 0,00 76,33 - - 0,00 0,00-0,00 2 2 177 2 185 24,20 107,5 0,00 77,79 - - 0,00 0,00-0,00 3 3 474 3 478 17,38 107,5 0,00 81,83 - - 0,00 0,00-0,00 4 2 764 2 770 20,79 107,5 0,00 79,85 - - 0,00 0,00-0,00 5 2 293 2 301 23,47 107,5 0,00 78,24 - - 0,00 0,00-0,00 6 1 818 1 825 26,67 107,5 0,00 76,23 - - 0,00 0,00-0,00 Sum 31,97 22.12.2014 11:35 / 3

DECIBEL - Assumptions for noise calculation Noise calculation model: ISO 9613-2 General Wind speed: 8,0 m/s Ground attenuation: General, Ground factor: 0,4 Meteorological coefficient, C0: 0,0 db Type of demand in calculation: 1: noise is compared to demand (DK, DE, SE, NL etc.) Noise values in calculation: All noise values are mean values (Lwa) (Normal) Pure tones: Pure and Impulse tone penalty are added to source noise Height above ground level, when no value in NSA object: 4,0 m Don't allow override of model height with height from NSA object Deviation from "official" noise demands. Negative is more restrictive, positive is less restrictive.: 0,0 db(a) Octave data required Air absorption 63 125 250 500 1 000 2 000 4 000 8 000 [db/km] [db/km] [db/km] [db/km] [db/km] [db/km] [db/km] [db/km] 0,1 0,4 1,1 2,4 4,1 8,8 26,4 93,7 22.12.2014 11:35 / 4 : VESTAS V126-3.3 GridStreame 3300 126.0!O! Noise: Level 0 - - Mode 0-08-2014 Source Source/Date Creator Edited Manufacturer 26.8.2014 USER 23.9.2014 13:11 Based on Document no.: 0046-6685. Octave data Status Hub height Wind speed LwA,ref Pure tones 63 125 250 500 1000 2000 4000 8000 [m] [m/s] [db(a)] [db] [db] [db] [db] [db] [db] [db] [db] From other hub height 150,0 8,0 107,5 No 84,2 91,9 96,5 101,4 103,5 100,5 94,8 80,0 NSA: Asuinrakennus (Uusjoutsjärventie 373)-A NSA: Asuinrakennus (Ahorajantie 64)-B NSA: Asuinrakennus (Uutelantie 82)-C NSA: Lomarakennus (Mikkolanmäentie 24)-D

DECIBEL - Assumptions for noise calculation NSA: Lomarakennus (Viitostie)-E NSA: Asuinrakennus (Vanhatie)-F NSA: Lomarakennus (Oksjärventie 160)-G 22.12.2014 11:35 / 5

DECIBEL - Map 8,0 m/s 22.12.2014 11:35 / 6 Noise [db(a)] 35 40 45 0 500 1000 1500 2000 m Map: Peruskartta, Print scale 1:38 000, Map center Finish TM ETRS-TM35FIN-ETRS89 East: 435 414 North: 6 818 309 New Noise sensitive area Noise calculation model: ISO 9613-2 General. Height above sea level from active line object

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information