| 000 | 05922nam a2200385 i 4500 | ||
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| 001 | 45295 | ||
| 008 | 161008t20162017sz m u000 0 eng d | ||
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_a9783319342412 _q(electronic book) |
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| 020 |
_a331934241X _q(electronic book) |
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| 020 |
_a3319342398 _q(hardcover) |
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| 020 |
_a9783319342399 _q(hardcover) |
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| 035 | _a(OCoLC) | ||
| 040 |
_aEBLCP _beng _epn _cEBLCP _dIDEBK _dYDX _dGW5XE _dAZU _dOCLCF _dOCLCQ _dIDB _dN$T _dUAB _dBAUN |
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| 041 | 1 |
_aeng _hdut |
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| 049 | _aBAUN_MERKEZ | ||
| 050 | 1 | 4 |
_aTH6057.M87 _bA5513 2017 |
| 082 | 0 | 4 | _223 |
| 100 | 1 | _aAnkersmit, Bart. | |
| 240 | 1 | 0 |
_aKlimaatwerk. _lEnglish. |
| 245 | 1 | 0 |
_aManaging indoor climate risks in museums / _cBart Ankersmit, Marc H.L. Stappers. |
| 264 | 1 |
_aCham : _bSpringer, _c[2016] |
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| 264 | 4 | _c©2017 | |
| 300 |
_a335 pages : _billustrations ; _c24 cm. |
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| 336 |
_atext _btxt _2rdacontent. |
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| 337 |
_aunmediated _bn _2rdamedia. |
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| 338 |
_avolume _bnr _2rdacarrier. |
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| 490 | 0 | _aCultural Heritage Science. | |
| 500 | _a8.3 Zoning. | ||
| 505 | 0 | 0 |
_tForeword _tAcknowledgements _tContents _gChapter 1: Introduction _t1.1 Introduction _t1.2 A Short History of Climate Control _t1.3 Nine Steps _tReferences _gChapter 2: Step 1: Towards a Balanced Decision _t2.1 Introduction _t2.2 Starting with Whatś Important _t2.2.1 Using the Mission Statement as a General Basis to Develop Values _t2.2.2 Involving Stakeholders _t2.3 What Do We Really Want? _t2.4 Making Objectives Measurable _t2.5 A Case Study _t2.6 Conclusions _tReferences _gChapter 3: Step 2: Valuing Heritage Assets _t3.1 Introduction _t3.2 Valuing the Building _t3.3 Values _t3.4 Value Classification. _t3.5 Values and Optimizing the Indoor Climate3.6 The Valuing Process _t3.7 Conclusions _tReferences _gChapter 4: Step 3: Assessing the Climate Risks to the Moveable Collection _t4.1 Introduction _t4.2 An Incorrect Relative Humidity _t4.2.1 The Relative Humidity Is Above 0% _t4.2.2 The Relative Humidity Is Above or Below a Critical Value _t4.2.3 The Relative Humidity Is Above 75% _t4.2.4 The Relative Humidity Fluctuates Too Much for Too Long _tWooden Artifacts _tCanvas Paintings _tIvory and Objects Made of Bone _tTextiles _tLibrary and Archival Collections _t4.3 The Proofed Relative Humidity Fluctuation. _t4.4 The Response Time of Hygroscopic Materials4.5 Incorrect Temperature _t4.5.1 The Temperature Is Too High _tHow Can an Old Newspaper Survive? _t4.5.2 The Temperature Is Too Low _t4.5.3 The Temperature Fluctuates Too Much _t4.6 Climate Classes and Risks _t4.7 Conclusion _tReferences _gChapter 5: Step 4: Assessing Building Needs _t5.1 Introduction _t5.2 Moisture _t5.2.1 Wood Decay by Fungi in Buildings _t5.2.2 Typical Species _t5.2.3 Limits for Growth _t5.2.4 Control of Wood Rot _t5.3 Salt Attack _t5.3.1 Damage Mechanism _t5.3.2 Location of Salt Damage _t5.3.3 Sources of Salt Contamination. _t5.3.4 Assessing the Risk of Salt Contamination5.4 Frost Damage _t5.5 Corrosion of Metals _t5.6 Wood Deterioration by Insects in Buildings _t5.7 Decorative Finishes _t5.7.1 Gilt Leather _t5.7.2 Traditional Wallpaper _t5.8 A Case Study _t5.9 Conclusions _tReferences _gChapter 6: Step 5: Assessing Human Comfort Needs _t6.1 Introduction _t6.2 Parameters Influencing Thermal Comfort _t6.3 Fangerś PMV Model _t6.4 Adaptive Comfort _t6.5 Indoor Air Quality _t6.6 Alliesthesia _t6.7 Uniform or Local Conditioning? _t6.8 Conclusions _tReferences _gChapter 7: Step 6: Understanding the Indoor Climate _t7.1 Introduction. _t7.2 First Barrier Principle7.3 Heat _t7.3.1 Understanding Heat Transfer _t7.3.2 Heat Sources _t7.3.3 Thermal Bridges _t7.3.4 Thermal Mass _tSpecial: Roofs in the Tropics _tSpecial: Dew Point and Condensation _t7.4 Air _t7.4.1 Infiltration _t7.4.2 Ventilation _t7.4.3 Air Flow _t7.5 Moisture _t7.5.1 Vapor Transport by Diffusion _t7.5.2 Vapor Transport by Convection _t7.5.3 Water Transport by Capillary Sorption _t7.5.4 Interstitial Condensation _t7.5.5 Hygric Mass _t7.6 Conclusion _tReferences _gChapter 8: Step 7: Defining Climate Specifications _t8.1 Introduction _t8.2 Combining Collection, Building and Human Needs. |
| 520 | _aThis book elaborates on different aspects of the decision making process concerning the management of climate risk in museums and historic houses. The goal of this publication is to assist collection managers and caretakers by providing information that will allow responsible decisions about the museum indoor climate to be made. The focus is not only on the outcome, but also on the equally important process that leads to that outcome. The different steps contribute significantly to the understanding of the needs of movable and immovable heritage. The decision making process to determine the requirements for the museum indoor climate includes nine steps: Step 1. The process to make a balanced decision starts by clarifying the decision context and evaluating what is important to the decision maker by developing clear objectives. In Step 2 the value of all heritage assets that are affected by the decision are evaluated and the significance of the building and the movable collection is made explicit. Step 3. The climate risks to the moveable collection are assessed. Step 4: Those parts of the building that are considered valuable and susceptible to certain climate conditions are identified. Step 5. The human comfort needs for visitors and staff are expressed. Step 6: To understand the indoor climate, the building physics are explored. Step 7. The climate specifications derived from step 3 to 5 are weighed and for each climate zone the optimal climate conditions are specified. Step 8: Within the value framework established in Step 1, the options to optimize the indoor climate are considered and selected. Step 9: All options to reduce the climate collection risks are evaluated by the objectives established in Step 1. | ||
| 650 | 0 |
_aMuseums _xClimatic factors. |
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| 650 | 0 | _aMuseum conservation methods. | |
| 650 | 0 | _aArchitecture and climate. | |
| 700 | 1 | _aStappers, Marc. | |
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_c45704 _d45704 |
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