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Conservation and restoration of plastic objects

February 18, 2024

Conservation and restoration of objects made from plastics is work dedicated to the conservation of objects of historical and personal value made from plastics. When applied to cultural heritage, this activity is generally undertaken by a conservator-restorer.

A variety of plastic objects conserved in a museum (Finland)

Background edit

Within museum collections, there are a variety of artworks and artifacts that are composed of organic plastic materials, either synthetic or semi-synthetic; these were created for a range of uses from artistic, to technical, to domestic use. Plastics have become an integral component of life, and many plastic artifacts have become cultural icons or objects worth preserving for the future. Although relatively new materials for museum collections, having originated in the 19th century, plastics are deteriorating at an alarming rate. This risks the loss not only of the objects themselves, but other nearby materials may also be degraded by outgassing or reactions with other released chemicals.[1][2]

Identification of plastics edit

 
If present, a numeric recycling code may provide clues about an item's composition.

Identification of plastic components of a collection is extremely important, because some plastics may release a harmful toxin or gas that can damage nearby objects. A preservation plan can be established to slow down the effects and protect a collection.[3][4]

Plastics are identified by various methods, including trade name, trademark, or patent number. Depending on the manufacturer, different chemical formulas and materials may have been used to produce the plastic over the years.[1] A recycling code may be present, giving general information about the material composition. Plastic composites or proprietary blends can be more difficult to identify.

If there are no markings to identify the type of plastic used, it may still be identified by using various types of spectroscopic technology such as optical spectrometer, Raman mid-infrared spectroscopy,[4] and near-infrared spectroscopy, along with mass spectrometry.[3] Other forms of identification include elemental analysis or thermal analysis to decipher the composition of plastics.[3]

The Museum of Design in Plastics (MoDiP), has created a guide to plastic objects that includes the manufacturing dates and manufacturing processes, along with its typical characteristics such as feel and smell.[5] If an object in a collection has characteristics that differ from what is expected, it is possible that the piece has begun to deteriorate.

In 2022, the Getty Conservation Institute published a book on the properties of commonly-used plastics and elastomers, including 56 "fact sheets" summarizing important characteristics of the materials, and methods of identification.[6]

Common plastics edit

The list below is of chemical compositions that make up common plastics found in museum collections. These are some plastics that may degrade, but are not seriously harmful to nearby objects:

The following are "malignant" plastic materials that will age rapidly if left untreated, and which have a higher risk of off-gassing or releasing toxic materials that can damage surrounding objects:[3]

Environmental concerns have driven recent changes in plastic manufacturing towards biodegradable plastics,[10] with a potentially negative effect upon the long-term stability of such materials within museum collections.[11][8]

Deterioration edit

 
Over several years, plasticizers in a soft vinyl eraser have migrated to partially dissolve a plastic pen cap.
 
Loss of plasticizers over 50 years caused embrittlement of electrical lampcord.
 
Outdoors UV radiation effects on vulnerable PVC conduit
 
Decayed cellulose nitrate film

A difficult aspect of plastic deterioration is that one cannot see what types of chemical reactions are occurring in the interior of an object, or easily identify the makeup of proprietary plastic composites. Many plastics will give off a distinct odor, ooze liquids, or will begin to shrink or crack in some way as they age.[12] Although deterioration cannot always be stopped, it is important to know the causes and be able to mitigate or slow damage.

Causes edit

The causes of deterioration regarding plastics can be linked to age, chemical composition, storage, and improper handling of the objects:

  • Age – When plastics were first manufactured in the 19th century, they were derived directly from organic materials; over the years these objects have usually deteriorated due to lack of knowledge and improper handling of the early plastics.[1]
  • Chemical – Depending on an object's chemical composition, conservators can understand how it will react over time. Other chemical reactions are driven by heat, oxygen, light, liquids, additives, and biological attacks.[13]
  • Storage – Improper storage of plastic artifacts can allow contamination and deterioration to occur. This often occurs when temperature or relative humidity fluctuate in the storage area, and this may cause the polymers to react to the environment, to deteriorate, and possibly to contaminate surrounding objects. Maintaining stable storage conditions is also important when an object is on exhibit. When the object is lighted and on display, its temperature and humidity can fluctuate. Conditions inside the exhibit case must be monitored and adjusted when necessary, to help prevent any damage.[1]
  • Improper handling – Improper cleaning techniques when using water or solvents on incompatible materials can cause damage.[1] Also, human error when handling objects can occur, causing abrasions or scratches.

Chemical processes edit

Understanding the different types of plastic chemical degradation helps in planning specific measures to protect plastic artifacts. Listed below are types of chemical reactions that accelerate the deterioration of the polymer's structure:

  • Photo-oxidative degradation occurs when plastic degrades from exposure to ultraviolet (UV) or visible light; the most damaging wavelengths depend on the composition of the polymer.[14] In general, plastic will be affected by light, and it is best practice to keep plastic away from light sources as much as possible, especially during longterm storage.
  • Thermal degradation affects the entire bulk volume of the polymer making up an object, and is strongly affected by the temperature and amount of light exposure.[14]
  • Ozone-induced degradation will deteriorate saturated and unsaturated polymers when the plastic is exposed to atmospheric ozone.[14] A test can be conducted to see if the object has been exposed, by taking small samples for analysis using Fourier-transform infrared spectroscopy (FTIR).[14]
  • Catalytic degradation mainly focuses on plastic waste polymers as they are transformed into hydrocarbons.[clarification needed]
  • Biodegradation causes the surface or the strength of the plastic to change; this process eventually decomposes vulnerable materials into carbon dioxide and water as microbes consume components of the material.[14]
  • Hydroperoxide decomposition occurs when metal and metal ions within the plastic material lead to the deterioration of the object[13]
  • Plasticizer migration occurs when additive chemicals intended to keep a plastic resin soft and pliable gradually move to the surface or are shed from an object. The loss of these chemicals causes the plastic to revert to a brittle state, often shrinking or distorting in shape. The migrating chemicals may cause other nearby objects to deform or otherwise degrade. In addition, many plasticizers, such as phthalates or bisphenol A (BPA) may be toxic, hormone disruptors, or carcinogenic in their biological effects.
Effects of UV, light, moisture and pollutants (including solvents) on plastics[3]
Plastic UV radiation and excess light (photolysis, photo-oxidation) Moisture (high relative humidity) and moisture fluctuations (hydrolysis, swelling, shrinkage) Pollutants Effects on other nearby materials (stains, corrosion, stickiness, gases)
Acrylics resistant resistant dissolved, swelled, stress, cracking none
Casein-formaldehyde, protein derivatives formaldehyde gas, cracking due to swelling/shrinking, moldy appearance, brittle when dry swell by water, resistant to organics formaldehyde, hydrogen sulfide, other sulfur-containing gases
Cellulose acetate yellowed, brittle hydrolysis produces acetic acid oily plasticized liquids. White powder residue may also be visible[15] dissolved swelled acetic acid gas, oily plasticizer and degradation products on surface
Cellulose nitrate yellowed, brittle hydrolysis produces acidic and oxidizing nitrogen oxide gases dissolved, swelled acidic and oxidizing nitrogen oxide gases, plasticizer, and degradation products on surface; material is explosively flammable
Nylon (polyamide) yellowed, brittle potential hydrolysis at extreme conditions softened, swelled none
Phenolics

(phenol formaldehyde)

discolored and more matte discolored and more matte fillers swell and surface mottles with solvents phenol and formaldehyde with severe degradation
Polyolefin

(polyethylene, polypropylene)

yellowed, brittle resistant swollen by some organics none
Polystyrene yellowed, brittled resistant dissolved, swelled, stress cracked none
Polyurethane yellowed, brittle, sticky, crumbles yellowed, brittle, sticky, crumbles swelled, stress cracked nitrogenous organic gases and liquids
Polyvinyl chloride yellowed, brittle resistant dissolved, swelled, embrittled by plasticizer extraction oily plasticizer liquids, maybe hydrochloric acid gas under extreme conditions of moisture and light exposure
Rubber, ebonite, vulcanite brittle, discolored, increase in matteness hydrogen sulfide and other gases, sulfuric acid on surfaces surface mottled by solvents hydrogen sulfide and other sulfur-containing gases, sulfuric acid on surfaces
All plastics (and organics) should be considered as prone to damage by ultraviolet radiation usually resulting in yellowing and embrittlement condensation plastics like esters, amides, and urethanes are subject to hydrolysis with subsequent weakening thermoplastics may dissolve, thermosets may swell, stress cracking harmful gases from plastics with chlorine, sulfur, and pendant (not main chain) ester groups

Additional effects of deterioration:

Plastics composed of cellulose acetate, when exposed to water, often will give off a smell of vinegar (vinegar syndrome); the surface will have a white powder residue and will begin to shrink.[15]

Cellulose acetate butyrate (CAB) and cellulose butyrate will produce butyric acid which has a "vomit odor".[3][16]

Polyvinyl chloride may cause a "blooming" effect, white powder on the surface that can contaminate nearby materials.[3]

Preventive care edit

A yearly checkup of plastic artifacts can help monitor their condition, as well as the condition of the surrounding objects to verify that they have not been cross-contaminated.[17]

Safe handling edit

Impermeable safety gloves such as those made of nitrile can help prevent toxins from entering the skin when handling plastic objects.[1] Dust masks, respirators, or other personal protective equipment may be required for protection from outgassing or airborne microplastic dusts produced by some decaying plastics.

Storage environment edit

Plastics are best stored with a relative humidity level of 50%, at a storage temperature of 18 °C (64 °F), in light-proof enclosures.[17] Because the composition of each plastic material can be different, it is difficult to designate a single uniform storage care plan; understanding the specific composition of a plastic artifact can help determine its preferred climate conditions.[17] Keeping plastics at a stable low temperature and placing these objects either in cold storage or in oxygen-impermeable bags helps to slow degradation.

Monitoring plastics in their storage environment is done by tracking their status and condition by using log entries on spreadsheets or in another database. Monitoring the temperature environment is done using data logger hardware which tracks hourly changes in temperature (and optionally, humidity). Objects composed of flammable and unstable cellulose nitrate especially benefit from cold storage, to reduce their rate of decay.[3]

Long-term storage supplies edit

Adsorbents such as activated carbon, silica gel, and zeolites are used to absorb gases that are released from plastics.[17] These absorbents can also be used when the object is on display to prevent and off-gassing that could occur, whether the object is on exhibit or in long-term storage. Absorbents along with acid-free boxes can help slow down the process of degradation and vinegar syndrome which is common in certain types of film, Lego plastics, and artwork.

Oxygen-impermeable bags are used to exclude atmospheric oxygen. In combination with oxygen absorbers, this prevents oxidation and deterioration of the contents.[17]

Conservation edit

The process of conservation and restoration of plastics requires an understanding of chemical composition of the material and an appreciation for the possible methods of restoration and their limitations, as well as development of a post-treatment preventive care plan for the object.

Cleaning edit

The process of cleaning plastics is done with the use of appropriate solvents, after identifying the polymers that make up the composition of the plastic.[18] A spot test can be performed if there is uncertainty how the object will react to water or solvents.

Scratch removal edit

Within the field of contemporary art, where the surface finish is part of the artist's intent, the removal of scratches may need to be more nuanced, compared to simply compensating for accidental damage to social-historical artifacts. Conservators have developed and scientifically investigated a variety of methods for scratch removal.[19]

Filling edit

Fillings may be needed if an object has suffered considerable loss of material due to accidental damage or chemical deterioration. The process of filling depends on the object's chemical composition, and requires consideration of refractive indexes, transparency, viscosity, and its compatibility with the rest of the object.[20]

See also edit

References edit

  1. ^ a b c d e f "Care and Identification of Objects Made from Plastic" (PDF). Conserve O Gram. 2010 – via National Park Service.
  2. ^ Thompson, Richard (2009). "Our Plastic Age". Philosophical Transactions of the Royal Society B: Biological Sciences. 364 (1526): 1973–1976. doi:10.1098/rstb.2009.0054. PMC 2874019. PMID 19528049.
  3. ^ a b c d e f g h Williams, Scott (2002). "Care of Plastics: Malignant Plastics". WAAC Newsletter. 24 – via COOL Database.
  4. ^ a b França de Sá, Susana; da Cruz, Sara Marques; Callapez, Maria Elvira; Carvalho, Vânia (13 May 2020). "Plastics that made history - the contribution of conservation science for the history of the Portuguese Plastics Industry". Conservar Património. 35: 85–100. doi:10.14568/cp2019017. hdl:10362/117046.
  5. ^ . Museum of Design in Plastics (MoDiP). Archived from the original on 2018-03-25. Retrieved 2018-04-08.
  6. ^ Oosten, Thea van (2022). Properties of plastics : a guide for conservators. Los Angeles: Getty Publications. ISBN 978-1-60606-693-5.
  7. ^ a b Staff, Creative Mechanisms. "Everything You Need To Know About PVC Plastic". Retrieved 2018-04-04.
  8. ^ a b c "Preserving Plastics: An Evolving Material a Maturing Profession (Feature)". www.getty.edu. Retrieved 2018-03-31.
  9. ^ "Preservation of Plastics". www.getty.edu. Getty Conservation Institute. Retrieved 2022-09-18.
  10. ^ "What You Can Do to Keep Plastic out of the Ocean". response.restoration.noaa.gov. Retrieved 2018-04-07.
  11. ^ Madden, Odile (Spring 2014). "Preserving Plastics: An Evolving Material, a Maturing Profession spring 2014. Conservation of plastics" (PDF). Conservation Perspectives the GCI Newsletter: 4–9 – via The Getty Conservation Institute.
  12. ^ "Identification of plastics by looking, touching and smelling". Blog. Retrieved 2018-04-08.
  13. ^ a b "Physical and Chemical processes leading to deterioration of original properties of plastic" (PDF). Processes Leading to the Deterioration of Plastics. 2012 – via POPART.
  14. ^ a b c d e Singh, Balijit (2007). "Mechanistic Implications of Plastic Degradation". Polymer Degradation and Stability. 93 (3): 561–584. doi:10.1016/j.polymdegradstab.2007.11.008.
  15. ^ a b . www.modip.ac.uk. Archived from the original on 2018-06-10. Retrieved 2018-04-07.
  16. ^ Alberge, Dalya (18 May 2015). "V&A conservators race to preserve art and design classics in plastic". The Guardian. Retrieved 2021-09-13.
  17. ^ a b c d e Shashoua, Yvonne (2014). "A Safe Space Storage Strategies for Plastics". Conservation Perspectives. Vol. 29.
  18. ^ Shashoua, Yvonne (2012). Studies in Active Conservation of Plastic Artefacts in Museums (PDF). POPART. p. 222.
  19. ^ Laganà, Ana; Rivenc, Rachel; Langenbacher, Julia; Griswold, John; Learner, Tom (2014). "Looking through Plastics: Investigating options for the treatment of scratches, abrasions, and losses in cast unsaturated polyester works of art" (PDF). ICOM-CC 17th Triennial Conference Preprints.
  20. ^ "The use of lasers in the conservation of museum objects made from plastics". Blog. Retrieved 2018-03-31.

Further reading edit

  • Oosten, Thea van (2022). Properties of plastics : a guide for conservators. Los Angeles: Getty Publications. ISBN 978-1-60606-693-5.
  • Shashoua, Yvonne (2012) [2008]. Conservation of Plastics. Routledge. ISBN 978-1-136-41515-9.
  • Keneghan, Brenda; Betts, Louise; Egan, Louise, eds. (2008). Plastics: Looking at the Future and Learning from the Past: Papers from the Conference Held at the Victoria and Albert Museum, London, 23-25 May 2007. Archetype. ISBN 978-1-904982-43-2.
  • Quye, Anita; Williamson, Colin (November 2005). Plastics: Collecting and Conserving. DIANE Publishing. ISBN 978-0-7567-9729-4.
  • Shashoua, Y.; Ward, C. (1995). "Plastics: Modern Resins with Ageing Problems". In Wright, Margot M. (ed.). Resins Ancient and Modern: Pre-prints of the SSCR's 2nd Conference Held at the Department of Zoology, University of Aberdeen, 13-14 September 1995. Scottish Society for Conservation & Restoration. pp. 33–37. ISBN 978-0-9526415-0-6.
  • Shashoua, Y. (1996). "A Passive Approach to the Conservation of Polyvinyl Chloride". ICOM Committee for Conservation. 11th Triennial Meeting, Edinburgh, Scotland, 1-6 September 1996: Preprints. James & James. pp. 961–6. ISBN 978-1-873936-50-4.
  • Winsor, P. (September 1999). "Conservation of Plastics Collections". MGC Fact Sheets. London: Museums and Galleries Commission.
  • Young, L.; Young, A. (2001). "The Preservation, Storage and Display of Spacesuits". Collections Care Report. Washington, DC: Smithsonian National Air and Space Museum. 5.
  • Blank, Sharon (1990). "An introduction to plastics and rubbers in collections". Studies in Conservation. 35 (2): 53–63. doi:10.1179/sic.1990.35.2.53.
  • Martuscelli, E. (2010). The chemistry of degradation and conservation of plastic artefacts. Paideia Firenze. ISBN 978-88-87410-48-8.
  • Martuscelli, Ezio (2012). Degradation and preservation of artefacts in synthetic plastics. Paideia. ISBN 978-88-87410-51-8.

External links edit

  • POPART: an international collaborative research project about the preservation of plastic artefacts in museums
  • Conservation of plastics
  • Safe Handling of Plastics in a Museum Environment
  • Deutsches Kunsstoff Museum
  • Conservation of rubber
  • THE CONSERVATION OF A PLASTIC MASK BY MARISOL
  • Care of plastics:Malignant Plastics
  • MoDiP
  • The Getty Conservation Institute

February 18, 2024
conservation, restoration, plastic, objects, conservation, restoration, objects, made, from, plastics, work, dedicated, conservation, objects, historical, personal, value, made, from, plastics, when, applied, cultural, heritage, this, activity, generally, unde. Conservation and restoration of objects made from plastics is work dedicated to the conservation of objects of historical and personal value made from plastics When applied to cultural heritage this activity is generally undertaken by a conservator restorer A variety of plastic objects conserved in a museum Finland Contents 1 Background 2 Identification of plastics 3 Common plastics 4 Deterioration 4 1 Causes 4 2 Chemical processes 5 Preventive care 5 1 Safe handling 5 2 Storage environment 5 3 Long term storage supplies 6 Conservation 6 1 Cleaning 6 2 Scratch removal 6 3 Filling 7 See also 8 References 9 Further reading 10 External linksBackground editWithin museum collections there are a variety of artworks and artifacts that are composed of organic plastic materials either synthetic or semi synthetic these were created for a range of uses from artistic to technical to domestic use Plastics have become an integral component of life and many plastic artifacts have become cultural icons or objects worth preserving for the future Although relatively new materials for museum collections having originated in the 19th century plastics are deteriorating at an alarming rate This risks the loss not only of the objects themselves but other nearby materials may also be degraded by outgassing or reactions with other released chemicals 1 2 Identification of plastics edit nbsp If present a numeric recycling code may provide clues about an item s composition Identification of plastic components of a collection is extremely important because some plastics may release a harmful toxin or gas that can damage nearby objects A preservation plan can be established to slow down the effects and protect a collection 3 4 Plastics are identified by various methods including trade name trademark or patent number Depending on the manufacturer different chemical formulas and materials may have been used to produce the plastic over the years 1 A recycling code may be present giving general information about the material composition Plastic composites or proprietary blends can be more difficult to identify If there are no markings to identify the type of plastic used it may still be identified by using various types of spectroscopic technology such as optical spectrometer Raman mid infrared spectroscopy 4 and near infrared spectroscopy along with mass spectrometry 3 Other forms of identification include elemental analysis or thermal analysis to decipher the composition of plastics 3 The Museum of Design in Plastics MoDiP has created a guide to plastic objects that includes the manufacturing dates and manufacturing processes along with its typical characteristics such as feel and smell 5 If an object in a collection has characteristics that differ from what is expected it is possible that the piece has begun to deteriorate In 2022 the Getty Conservation Institute published a book on the properties of commonly used plastics and elastomers including 56 fact sheets summarizing important characteristics of the materials and methods of identification 6 Common plastics editThe list below is of chemical compositions that make up common plastics found in museum collections These are some plastics that may degrade but are not seriously harmful to nearby objects Non plasticized rigid polyvinyl chloride PVC 7 The following are malignant plastic materials that will age rapidly if left untreated and which have a higher risk of off gassing or releasing toxic materials that can damage surrounding objects 3 Polyvinyl chloride treated with plasticizers 8 7 Polyurethane Cellulose esters including cellulose nitrate and cellulose acetate 9 8 Vulcanized rubber Biodegradable plasticsEnvironmental concerns have driven recent changes in plastic manufacturing towards biodegradable plastics 10 with a potentially negative effect upon the long term stability of such materials within museum collections 11 8 Deterioration edit nbsp Over several years plasticizers in a soft vinyl eraser have migrated to partially dissolve a plastic pen cap nbsp Loss of plasticizers over 50 years caused embrittlement of electrical lampcord nbsp Outdoors UV radiation effects on vulnerable PVC conduit nbsp Decayed cellulose nitrate filmA difficult aspect of plastic deterioration is that one cannot see what types of chemical reactions are occurring in the interior of an object or easily identify the makeup of proprietary plastic composites Many plastics will give off a distinct odor ooze liquids or will begin to shrink or crack in some way as they age 12 Although deterioration cannot always be stopped it is important to know the causes and be able to mitigate or slow damage Causes edit The causes of deterioration regarding plastics can be linked to age chemical composition storage and improper handling of the objects Age When plastics were first manufactured in the 19th century they were derived directly from organic materials over the years these objects have usually deteriorated due to lack of knowledge and improper handling of the early plastics 1 Chemical Depending on an object s chemical composition conservators can understand how it will react over time Other chemical reactions are driven by heat oxygen light liquids additives and biological attacks 13 Storage Improper storage of plastic artifacts can allow contamination and deterioration to occur This often occurs when temperature or relative humidity fluctuate in the storage area and this may cause the polymers to react to the environment to deteriorate and possibly to contaminate surrounding objects Maintaining stable storage conditions is also important when an object is on exhibit When the object is lighted and on display its temperature and humidity can fluctuate Conditions inside the exhibit case must be monitored and adjusted when necessary to help prevent any damage 1 Improper handling Improper cleaning techniques when using water or solvents on incompatible materials can cause damage 1 Also human error when handling objects can occur causing abrasions or scratches Chemical processes edit Understanding the different types of plastic chemical degradation helps in planning specific measures to protect plastic artifacts Listed below are types of chemical reactions that accelerate the deterioration of the polymer s structure Photo oxidative degradation occurs when plastic degrades from exposure to ultraviolet UV or visible light the most damaging wavelengths depend on the composition of the polymer 14 In general plastic will be affected by light and it is best practice to keep plastic away from light sources as much as possible especially during longterm storage Thermal degradation affects the entire bulk volume of the polymer making up an object and is strongly affected by the temperature and amount of light exposure 14 Ozone induced degradation will deteriorate saturated and unsaturated polymers when the plastic is exposed to atmospheric ozone 14 A test can be conducted to see if the object has been exposed by taking small samples for analysis using Fourier transform infrared spectroscopy FTIR 14 Catalytic degradation mainly focuses on plastic waste polymers as they are transformed into hydrocarbons clarification needed Biodegradation causes the surface or the strength of the plastic to change this process eventually decomposes vulnerable materials into carbon dioxide and water as microbes consume components of the material 14 Hydroperoxide decomposition occurs when metal and metal ions within the plastic material lead to the deterioration of the object 13 Plasticizer migration occurs when additive chemicals intended to keep a plastic resin soft and pliable gradually move to the surface or are shed from an object The loss of these chemicals causes the plastic to revert to a brittle state often shrinking or distorting in shape The migrating chemicals may cause other nearby objects to deform or otherwise degrade In addition many plasticizers such as phthalates or bisphenol A BPA may be toxic hormone disruptors or carcinogenic in their biological effects Effects of UV light moisture and pollutants including solvents on plastics 3 Plastic UV radiation and excess light photolysis photo oxidation Moisture high relative humidity and moisture fluctuations hydrolysis swelling shrinkage Pollutants Effects on other nearby materials stains corrosion stickiness gases Acrylics resistant resistant dissolved swelled stress cracking noneCasein formaldehyde protein derivatives formaldehyde gas cracking due to swelling shrinking moldy appearance brittle when dry swell by water resistant to organics formaldehyde hydrogen sulfide other sulfur containing gasesCellulose acetate yellowed brittle hydrolysis produces acetic acid oily plasticized liquids White powder residue may also be visible 15 dissolved swelled acetic acid gas oily plasticizer and degradation products on surfaceCellulose nitrate yellowed brittle hydrolysis produces acidic and oxidizing nitrogen oxide gases dissolved swelled acidic and oxidizing nitrogen oxide gases plasticizer and degradation products on surface material is explosively flammableNylon polyamide yellowed brittle potential hydrolysis at extreme conditions softened swelled nonePhenolics phenol formaldehyde discolored and more matte discolored and more matte fillers swell and surface mottles with solvents phenol and formaldehyde with severe degradationPolyolefin polyethylene polypropylene yellowed brittle resistant swollen by some organics nonePolystyrene yellowed brittled resistant dissolved swelled stress cracked nonePolyurethane yellowed brittle sticky crumbles yellowed brittle sticky crumbles swelled stress cracked nitrogenous organic gases and liquidsPolyvinyl chloride yellowed brittle resistant dissolved swelled embrittled by plasticizer extraction oily plasticizer liquids maybe hydrochloric acid gas under extreme conditions of moisture and light exposureRubber ebonite vulcanite brittle discolored increase in matteness hydrogen sulfide and other gases sulfuric acid on surfaces surface mottled by solvents hydrogen sulfide and other sulfur containing gases sulfuric acid on surfacesAll plastics and organics should be considered as prone to damage by ultraviolet radiation usually resulting in yellowing and embrittlement condensation plastics like esters amides and urethanes are subject to hydrolysis with subsequent weakening thermoplastics may dissolve thermosets may swell stress cracking harmful gases from plastics with chlorine sulfur and pendant not main chain ester groupsAdditional effects of deterioration Plastics composed of cellulose acetate when exposed to water often will give off a smell of vinegar vinegar syndrome the surface will have a white powder residue and will begin to shrink 15 Cellulose acetate butyrate CAB and cellulose butyrate will produce butyric acid which has a vomit odor 3 16 Polyvinyl chloride may cause a blooming effect white powder on the surface that can contaminate nearby materials 3 Preventive care editA yearly checkup of plastic artifacts can help monitor their condition as well as the condition of the surrounding objects to verify that they have not been cross contaminated 17 Safe handling edit Impermeable safety gloves such as those made of nitrile can help prevent toxins from entering the skin when handling plastic objects 1 Dust masks respirators or other personal protective equipment may be required for protection from outgassing or airborne microplastic dusts produced by some decaying plastics Storage environment edit Plastics are best stored with a relative humidity level of 50 at a storage temperature of 18 C 64 F in light proof enclosures 17 Because the composition of each plastic material can be different it is difficult to designate a single uniform storage care plan understanding the specific composition of a plastic artifact can help determine its preferred climate conditions 17 Keeping plastics at a stable low temperature and placing these objects either in cold storage or in oxygen impermeable bags helps to slow degradation Monitoring plastics in their storage environment is done by tracking their status and condition by using log entries on spreadsheets or in another database Monitoring the temperature environment is done using data logger hardware which tracks hourly changes in temperature and optionally humidity Objects composed of flammable and unstable cellulose nitrate especially benefit from cold storage to reduce their rate of decay 3 Long term storage supplies edit Adsorbents such as activated carbon silica gel and zeolites are used to absorb gases that are released from plastics 17 These absorbents can also be used when the object is on display to prevent and off gassing that could occur whether the object is on exhibit or in long term storage Absorbents along with acid free boxes can help slow down the process of degradation and vinegar syndrome which is common in certain types of film Lego plastics and artwork Oxygen impermeable bags are used to exclude atmospheric oxygen In combination with oxygen absorbers this prevents oxidation and deterioration of the contents 17 Conservation editThe process of conservation and restoration of plastics requires an understanding of chemical composition of the material and an appreciation for the possible methods of restoration and their limitations as well as development of a post treatment preventive care plan for the object Cleaning edit The process of cleaning plastics is done with the use of appropriate solvents after identifying the polymers that make up the composition of the plastic 18 A spot test can be performed if there is uncertainty how the object will react to water or solvents Scratch removal edit Within the field of contemporary art where the surface finish is part of the artist s intent the removal of scratches may need to be more nuanced compared to simply compensating for accidental damage to social historical artifacts Conservators have developed and scientifically investigated a variety of methods for scratch removal 19 Filling edit Fillings may be needed if an object has suffered considerable loss of material due to accidental damage or chemical deterioration The process of filling depends on the object s chemical composition and requires consideration of refractive indexes transparency viscosity and its compatibility with the rest of the object 20 See also editDisc rotReferences edit a b c d e f Care and Identification of Objects Made from Plastic PDF Conserve O Gram 2010 via National Park Service Thompson Richard 2009 Our Plastic Age Philosophical Transactions of the Royal Society B Biological Sciences 364 1526 1973 1976 doi 10 1098 rstb 2009 0054 PMC 2874019 PMID 19528049 a b c d e f g h Williams Scott 2002 Care of Plastics Malignant Plastics WAAC Newsletter 24 via COOL Database a b Franca de Sa Susana da Cruz Sara Marques Callapez Maria Elvira Carvalho Vania 13 May 2020 Plastics that made history the contribution of conservation science for the history of the Portuguese Plastics Industry Conservar Patrimonio 35 85 100 doi 10 14568 cp2019017 hdl 10362 117046 A Z of plastics materials Museum of Design in Plastics MoDiP Archived from the original on 2018 03 25 Retrieved 2018 04 08 Oosten Thea van 2022 Properties of plastics a guide for conservators Los Angeles Getty Publications ISBN 978 1 60606 693 5 a b Staff Creative Mechanisms Everything You Need To Know About PVC Plastic Retrieved 2018 04 04 a b c Preserving Plastics An Evolving Material a Maturing Profession Feature www getty edu Retrieved 2018 03 31 Preservation of Plastics www getty edu Getty Conservation Institute Retrieved 2022 09 18 What You Can Do to Keep Plastic out of the Ocean response restoration noaa gov Retrieved 2018 04 07 Madden Odile Spring 2014 Preserving Plastics An Evolving Material a Maturing Profession spring 2014 Conservation of plastics PDF Conservation Perspectives the GCI Newsletter 4 9 via The Getty Conservation Institute Identification of plastics by looking touching and smelling Blog Retrieved 2018 04 08 a b Physical and Chemical processes leading to deterioration of original properties of plastic PDF Processes Leading to the Deterioration of Plastics 2012 via POPART a b c d e Singh Balijit 2007 Mechanistic Implications of Plastic Degradation Polymer Degradation and Stability 93 3 561 584 doi 10 1016 j polymdegradstab 2007 11 008 a b Care of plastics Museum of Design in Plastics MoDiP www modip ac uk Archived from the original on 2018 06 10 Retrieved 2018 04 07 Alberge Dalya 18 May 2015 V amp A conservators race to preserve art and design classics in plastic The Guardian Retrieved 2021 09 13 a b c d e Shashoua Yvonne 2014 A Safe Space Storage Strategies for Plastics Conservation Perspectives Vol 29 Shashoua Yvonne 2012 Studies in Active Conservation of Plastic Artefacts in Museums PDF POPART p 222 Lagana Ana Rivenc Rachel Langenbacher Julia Griswold John Learner Tom 2014 Looking through Plastics Investigating options for the treatment of scratches abrasions and losses in cast unsaturated polyester works of art PDF ICOM CC 17th Triennial Conference Preprints The use of lasers in the conservation of museum objects made from plastics Blog Retrieved 2018 03 31 Further reading editOosten Thea van 2022 Properties of plastics a guide for conservators Los Angeles Getty Publications ISBN 978 1 60606 693 5 Shashoua Yvonne 2012 2008 Conservation of Plastics Routledge ISBN 978 1 136 41515 9 Keneghan Brenda Betts Louise Egan Louise eds 2008 Plastics Looking at the Future and Learning from the Past Papers from the Conference Held at the Victoria and Albert Museum London 23 25 May 2007 Archetype ISBN 978 1 904982 43 2 Quye Anita Williamson Colin November 2005 Plastics Collecting and Conserving DIANE Publishing ISBN 978 0 7567 9729 4 Shashoua Y Ward C 1995 Plastics Modern Resins with Ageing Problems In Wright Margot M ed Resins Ancient and Modern Pre prints of the SSCR s 2nd Conference Held at the Department of Zoology University of Aberdeen 13 14 September 1995 Scottish Society for Conservation amp Restoration pp 33 37 ISBN 978 0 9526415 0 6 Shashoua Y 1996 A Passive Approach to the Conservation of Polyvinyl Chloride ICOM Committee for Conservation 11th Triennial Meeting Edinburgh Scotland 1 6 September 1996 Preprints James amp James pp 961 6 ISBN 978 1 873936 50 4 Winsor P September 1999 Conservation of Plastics Collections MGC Fact Sheets London Museums and Galleries Commission Young L Young A 2001 The Preservation Storage and Display of Spacesuits Collections Care Report Washington DC Smithsonian National Air and Space Museum 5 Blank Sharon 1990 An introduction to plastics and rubbers in collections Studies in Conservation 35 2 53 63 doi 10 1179 sic 1990 35 2 53 Martuscelli E 2010 The chemistry of degradation and conservation of plastic artefacts Paideia Firenze ISBN 978 88 87410 48 8 Martuscelli Ezio 2012 Degradation and preservation of artefacts in synthetic plastics Paideia ISBN 978 88 87410 51 8 External links editPOPART an international collaborative research project about the preservation of plastic artefacts in museums Conservation of plastics Safe Handling of Plastics in a Museum Environment Deutsches Kunsstoff Museum PlArt museo Conservation of rubber THE CONSERVATION OF A PLASTIC MASK BY MARISOL Care of plastics Malignant Plastics Care of Objects Made from Rubber and Plastic MoDiP The Getty Conservation Institute Retrieved from https en wikipedia org w index php title Conservation and restoration of plastic objects amp oldid 1193556132, wikipedia, wiki, book, books, library,

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