Relevant bibliographies by topics / Hospital waste management system

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Academic literature on the topic 'Hospital waste management system'

Author: Grafiati
Published: 4 June 2021
Last updated: 18 February 2022

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Journal articles on the topic "Hospital waste management system"

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Elsayed, Amna, Manal Ibrahem, and Gehan Diab. "Hospital Waste Management System." Menoufia Nursing Journal 5, no. 1 (May 1, 2020): 17–22. http://dx.doi.org/10.21608/menj.2020.122681.

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Santos, Elci de Souza, Karla Magna dos Santos Gonçalves, and Marcos Paulo Gomes Mol. "Healthcare waste management in a Brazilian university public hospital." Waste Management & Research: The Journal for a Sustainable Circular Economy 37, no. 3 (December 19, 2018): 278–86. http://dx.doi.org/10.1177/0734242x18815949.

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Some healthcare waste presents hazardousness characteristics and requires specific procedures to ensure the safety management. Waste segregation is an important action to control the risks of each type of waste. Healthcare waste indicators also may improve the waste management system. The aim of this article was to evaluate the healthcare waste management in a Brazilian university hospital, as well as the waste indicators, quantifying and qualifying the waste generation. Weighing of wastes occurred by sampling occurred sampling of seven consecutive days or daily, between 2011 and 2017. General wastes represent more than 55.6% of the total generated, followed by infectious, sharps and chemicals wastes, respectively, 39.1%, 2.9% and 2.4%. The generation rate in 2017 was 4.09 kg bed−1 day−1, including all types of wastes. Non-dangerous wastes represented around 93.3%, including infectious wastes with low potential risks, while dangerous was represented by high infectious risk (1.4%), chemicals (2.4%) and sharps (2.9%). Healthcare waste indicators may favour the risk identification and improve the waste management system, in particular when involving hazardous wastes. Failures in healthcare waste segregation could represent, in addition to the health risks, unnecessary expenses.
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Debalkie, Desta, and Abera Kumie. "Healthcare Waste Management: The Current Issue in Menellik II Referral Hospital, Ethiopia." Current World Environment 12, no. 1 (April 25, 2017): 42–52. http://dx.doi.org/10.12944/cwe.12.1.06.

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Healthcare wastes generated in Hospitals from medical activities have not given sufficient attention. In developing countries, healthcare wastes are still handled and disposed indiscriminately creating an immense threat to the public health and the environment. This situation is much worse in Ethiopia where there is paucity of convincing evidence about healthcare waste generation rate and management system. A crossectional study was conducted in Menellik II hospital to evaluate the healthcare waste management system. Primary data on the healthcare waste management system was collected using observational checklist. Key informant interview guide was also employed on 11 selected informants to assess waste management practice and analyzed by thematic framework. The results revealed that there was no segregation of healthcare waste by type at the point of generation and disinfection of infectious waste before disposal. The main HCW treatment and disposal mechanism was incineration using low temperature, single chamber incinerator; open burning; burring in to amputation pit and open dumping on municipal dumping site as well as on the hospital back yard. Furthermore, there was negligence, attitudinal problem and low level of awareness about safe healthcare waste management. To diminish the risk of healthcare waste on public health and environment, a cost effective interventions include providing better medical waste management facilities, adherence to national regulatory and rising awareness of all concerned need to adopt in the hospital.
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Abidar, Nadia, Sofia Tiskat, and Maryami Zohra. "Chemical Waste Management in Hospital; Impact on Environment and Health." Journal Wetenskap Health 1, no. 2 (December 5, 2020): 36–41. http://dx.doi.org/10.48173/jwh.v1i2.36.

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This article discusses the chemical management of wastewater in hospitals. Liquid waste is all wastewater including feces originating from hospital activities which may contain pathogenic microorganisms, toxic chemicals and radioactive substances that are harmful to health. Therefore, the potential impact of hospital wastewater on public health is very large, so each hospital is required to treat its wastewater until it meets the applicable standard requirements. Good wastewater management is not only for sharp medical wastes but covers hospital waste as a whole. With the increasing number of health service facilities, it will result in an increasing potential for environmental pollution, because waste disposal activities, especially waste water, will contribute to decreasing the level of human health. Hospital waste is all waste generated from hospital activities in the form of solid, liquid and gas. It is better if hospital waste has a waste storage and treats the waste first before discharging it into the environment, so that the environment is not polluted and the government should build a monitoring system.
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Wilson, Joseph H., David N. Lasiter, and Randall G. McKee. "Hospital waste disposal system." Nuclear and Chemical Waste Management 8, no. 4 (January 1988): x. http://dx.doi.org/10.1016/0191-815x(88)90063-0.

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Ghimire, Hari Prasad, and A. Dhungana. "A Critical Analysis on Hospital Waste Management at Bandipur Hospital, Bandipur, Tanahu District, Nepal." Journal of Gandaki Medical College-Nepal 11, no. 02 (December 31, 2018): 41–45. http://dx.doi.org/10.3126/jgmcn.v11i02.22961.

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Background: Hospitals generate large volumes of wastes as a byproduct of a variety of health services and procedures carried out such as surgery, dressing of the wounds, dialysis, deliveries, laboratory and dental procedures, postmortem procedures etc. Such a waste may be infectious or non-infectious. If such a waste is not collected, transported and disposed off, it not only results in causation of ‘Hospital Acquired Infections” but also poses a major public health hazard by causing pollution of air, water and soil. Objective: This study objective was to critically analyze current waste management system in Bandipur Hospital, Tanahu District, Nepal and critically review the findings. Methods: For the critical analysis on waste management, literature review on hospital waste management was done. The techniques used for critical analysis were observation using observation checklist and interview with hospital manager, doctors, staff nurses, and local people living nearby the hospital. Tool of this critical analysis was SWOT analysis. Results: It can be seen from SWOT analysis that, most of the waste of the hospital is not managed in an appropriate way. Appropriate segregation and disposal of biodegradable and non biodegradable, infectious and non-infectious wastes is important to avoid health hazards caused by poor waste management such as vector borne diseases, pollution of air, water and soil contamination. In Bandipur Hospital, waste disposal is not according to WHO standard. Physical infrastructures do not meet the requirements. Available dustbins are not according to WHO color coding, no basin at Emergency room, no trolley to carry waste and open dumping practice. The reason behind most of these problems is the management of the hospital, staffs of the hospital and the stakeholders who are not giving any attention to proper waste management process. The other reason beyond this is inadequate budget allocation for waste management in the hospital. Conclusion: If the waste management of the hospital is done properly, environment of the hospital will become clean and hospital can provide quality health services to the patient. For this there is necessity of strong committment from the hospital management, the hospital staffs, hospital development committee and the Government.
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Chaerul, Mochammad, Masaru Tanaka, and Ashok V. Shekdar. "A system dynamics approach for hospital waste management." Waste Management 28, no. 2 (January 2008): 442–49. http://dx.doi.org/10.1016/j.wasman.2007.01.007.

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Islam, Nazimul, Parvin Akter Khanam, Shahidul Hoque Mollik, and Nazmun Nahar. "Exploring the Effective Management of Medical Waste of BIRDEM General Hospital." BIRDEM Medical Journal 8, no. 1 (December 27, 2017): 56–62. http://dx.doi.org/10.3329/birdem.v8i1.35041.

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Background: Medical waste can be generated in hospitals or clinics where diagnosis and treatment are conducted. The management of these wastes are of public concern and health threats are associated with such wastes. The study assessed to explore the current situation of medical waste management and level of awareness related to impact of medical waste and its management among the different levels of professionals.Methods: A descriptive cross-sectional study was done and data were collected from September 2012 to December 2012 at BIRDEM General Hospital. Data were collected by simple random sampling method and semi-structured questionnaire were used in this study. The questionnaire included socio-demographic information, source of hospital waste, description of hospital waste, segregation of waste and assessment of medical waste management system. The questionnaires were interviewed to the doctors, nurses, paramedical staff and cleaners who were related to waste management practices.Results: A total of 186 participants were interviewed in this study. The mean and SD of age was 37.9 ± 10.4 years and the age range from 22 to 65 years respectively. The male and female subjects were 28.0% and 72.0% respectively. Of the total participants, doctors, nurses, paramedical staff and cleaners were 15.1%, 55.4%, 12.9% and 16.7% respectively. To assess the perception of the respondents about hospital waste management, the nurses (100.0%) and cleaners (100.0%) were found in a better position to follow color-coding system (CCS) and to use of protective bags while segregating primary waste, while doctors (21.4%) and paramedical staff’s (29.2%) practice were not encouraging. However, in terms of constituents of medical waste doctors and paramedical staff’s perception was better than the nurses and cleaners. Doctors (92.9%), nurses (96.1%) and paramedical staff (95.8%) were very comfortable about the present color coding system than compared with cleaners (74.2%), although the doctors are less compliant to follow the color-coding system (78.6% compliant) in practice. A substantial proportion of the doctors (71.4%) sometimes put waste in wrong bins as opposed to 51.5% nurses and 33.3% paramedical staff. Few of the respondents would consider the waste if some medical waste is accidentally put to the general waste bin, 85.7% of the doctors, 95.1% nurses, 66.7% paramedical staff and 100% cleaners told that they would consider the waste as medical waste. Nurse’s perception was also better compared to other occupants in sealing waste-bin for disposal. In view of improving the existing waste management system, most of the respondents of different categories were in favor on waste management system. Majority of the respondents think that there should be designated person (97.8%) or rules (97.8%) or monitoring (96.8%) at the administrative level for organizing and managing of waste collection, handling, storage and disposal of waste who will follow a definite rule during all these processes.Conclusion: The study observed that there is lack of knowledge affiliate and practice among the doctors, nurses, paramedical staff and cleaners in segregating hospital waste at the primary source of collection. However, nurses and cleaners were more aware than the doctors and paramedical staff in terms of practice of segregating primary waste. The study also found that perception of waste management was better in doctors and paramedical staff than compared with cleaners and other staffs. To improve the waste management system, it is needed to make policy and regulation guidelines to well-organized system of collecting and treating waste in the hospital.Birdem Med J 2018; 8(1): 56-62
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Manjunatha, M., VC Sunil Kumar, Badami Vijetha, and P. R. Pradeep. "Biomedical Waste Management: A Review." Journal of Oral Health and Community Dentistry 6, no. 3 (2012): 141–44. http://dx.doi.org/10.5005/johcd-6-3-141.

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ABSTRACT Various national and international agencies have shown their concern towards proper handling, treatment and disposal of biomedical waste, as they may cause serious infectious diseases like hepatitis, tuberculosis and HIV/AIDS. Most of the hospitals do not have effective disposal system leading to complex problem of hygiene and sanitation in hospitals. The use of disposable items has reduced the rate of infection but at the same time has increased the volume of the waste which needs to be disposed properly. Effective waste disposal can be achieved only by considering the various components of the waste management system and this should be made an integral part of hospital planning and designing.
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Ruoyan Gai, Chushi Kuroiwa, Lingzhong Xu, Xingzhou Wang, Yufei Zhang, Huijuan Li, Chengchao Zhou, et al. "Hospital medical waste management in Shandong Province, China." Waste Management & Research: The Journal for a Sustainable Circular Economy 27, no. 4 (June 2009): 336–42. http://dx.doi.org/10.1177/0734242x09104384.

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Medical waste refers to those hazardous waste materials generated by healthcare activities, including a broad range of materials, and remains as an issue on both public health and environment. In China, there was inadequate information on the implementation of management systems in hospitals based on the national regulatory framework. The objectives of this study were to assess the current situation of medical waste management and to identify factors determining the implementation of a management system based on the national regulatory framework in hospitals. We investigated 23 general hospitals in both urban and rural areas of Shandong Province, China, by both quantitative and qualitative approaches. The medical waste generation rate was 0.744, 0.558 and 1.534 kg bed— 1 day—1 in tertiary hospitals, urban secondary hospitals and county hospitals, respectively. There is a wide disparity between implementation in tertiary, secondary and county hospitals. With increasing financial, technological, and materials investment, a management system has been established in tertiary and secondary hospitals. Financial support and administrative monitoring by the government is urgently needed to build a sound management system in hospitals located at remote and less-developed areas. In those areas issues in the financial, administrative and technical aspects should be further examined.
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Dissertations / Theses on the topic "Hospital waste management system"

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Fonseca, Sofia Alexandra Alves da. "Práticas de logística inversa dos resíduos nos hospitais do distrito de Setúbal." Master's thesis, Instituto Politécnico de Setúbal. Escola Superior de Ciências Empresariais, 2017. http://hdl.handle.net/10400.26/19779.

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Dissertação apresentada para cumprimento dos requisitos necessários à obtenção do grau de Mestre em Ciências Empresariais - ramos Gestão Logística
A logística inversa dos resíduos surge como uma importante atividade na minimização do impacto causado no meio ambiente. A produção de resíduos é uma das maiores preocupações existentes na atualidade. Sendo os hospitais uma grande fonte de produção de resíduos, é importante o seu tratamento que difere consoante os graus de perigosidade. O presente estudo tem como objetivo estudar as práticas de logística inversa dos resíduos, levadas a cabo pelos hospitais do distrito de Setúbal, em Portugal. Para a concretização deste objetivo utilizou-se o método quantitativo de recolha de dados, nomeadamente, um inquérito por questionário, enviado por correio eletrónico. O estudo engloba, para além de questões gerais sobre logística inversa, as etapas da gestão de resíduos, nomeadamente, a triagem e acondicionamento, a recolha e o transporte interno e o armazenamento interno. Conclui-se que a maioria das práticas decorre do imperativo legal, existindo ainda muito a fazer na área da logística inversa hospitalar. Os resultados obtidos permitem concluir que, de uma forma geral, é feito muito pouco para além do que é obrigatório por lei.
The reverse logistics of waste emerged as an important activity in minimizing the impact on the environment. The production of waste is one of the biggest concerns that exist today. Having in consideration that hospitals have a great responsibility in terms of waste production, it is important to grant that the waste is treated considering it’s classification due to the hazardousness level. The objective of this study is to investigate the several reverse logistics waste practices, carried out by hospitals, in Setúbal district, in Portugal. In order to fulfill the objective of the present study, it was used a quantitative data collection method, namely, questionnaires sent by electronic mail. Apart from general reverse logistics questions, this study also analyses questions related with the waste management step: sorting and waste conditioning, the waste collecting system, the internal transport and storage system. It is concluded that the majority of practices resumes itself to the legal requirements, and there is a lot of work to be done in this area. The results obtained, allow us to conclude that in general is done very little beyond what is legally required.
The reverse logistics of waste emerged as an important activity in minimizing the impact on the environment. The production of waste is one of the biggest concerns that exist today. Having in consideration that hospitals have a great responsibility in terms of waste production, it is important to grant that the waste is treated considering it’s classification due to the hazardousness level. The objective of this study is to investigate the several reverse logistics waste practices, carried out by hospitals, in Setúbal district, in Portugal. In order to fulfill the objective of the present study, it was used a quantitative data collection method, namely, questionnaires sent by electronic mail. Apart from general reverse logistics questions, this study also analyses questions related with the waste management step: sorting and waste conditioning, the waste collecting system, the internal transport and storage system. It is concluded that the majority of practices resumes itself to the legal requirements, and there is a lot of work to be done in this area. The results obtained, allow us to conclude that in general is done very little beyond what is legally required.
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Chiu, Shih-Feng. "The Effect of Changing Batch Frequency, Lead Time and Installing an I.V. Workflow Management System on Intravenous Admixture Operations in a Pediatric Hospital." University of Cincinnati / OhioLINK, 2014. http://rave.ohiolink.edu/etdc/view?acc_num=ucin1397736409.

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Rosberg, Philip. "Waste management at Electrolux : Proposals for a New Waste Management- and Waste Reporting System." Thesis, KTH, Industriell ekologi, 2017. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-202577.

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There has been an increased trend and awareness, during the past two decades, for global companies to assess their environmental impact. And when it comes to waste management, there are at this point few disarmaments that an increased awareness of companies’ resource-, and waste streams can have positive financial outcomes, if actions are taken. A lot of these ideas have already been implemented within Electrolux. By developing an energy and water management plan, Green Spirit, they have successfully improved their operations with reducing their energy intensity with 17% (2011-2015) and water intensity with 35% (2011- 2015) (Electrolux Sustainability, 2016). This study has the main objective how to improve and reduce waste in Electrolux´s production facilities, and to help Electrolux understand their waste streams. By assessing the waste performance at Electrolux, and by comparing environmental KPIs between Electrolux and a selection of competitors, a basis for decision was developed. Literature studies of legislative frameworks in geographical regions where Electrolux have a strong presence have helped to understand how companies can work with regulatory entities to solve greater issues. By joining forces with other companies and governments, Electrolux will be able to set an example of how waste performance and profitability can be achieved. By sharing best practice, and engaging with stakeholders and developers, Electrolux can help improve waste performance and save natural resources. This thesis has lead to the development of a new management system, a new reporting system, and a transparent way to rank and keep track of waste performance at Electrolux factories. A way to understand and address issues related to zero waste is also presented.
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Setty, Rahul Sridhar. "Sensor-less Smart Waste Management System." Thesis, Uppsala universitet, Institutionen för informationsteknologi, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-393301.

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In order to improve the municipal solid waste management efficiency, smart management approaches have been proposed such as wireless sensor network architecture solution which includes the use of sensors to detect the garbage bin fill levels and vehicle route optimization techniques. Experimental results show that we can save up to 35% of the operational cost by improving the efficiency of solid waste management. In this thesis, a new low-cost architecture solution is proposed for improving the efficiency of municipal solid waste management without the use of sensors. Instead, a messaging application is used to ask the customers for pick up of garbage. Based on their reply, the prototype architecture uses a cluster-first route-second method that implements a clustering algorithm with truck capacity as the constraint and solves a travelling salesman algorithm in each cluster. The prototype architecture consists of a back-end server that implements sweep clustering algorithm for clustering the customers by their location and solves travelling salesman problem with dynamic programming method in each cluster, firebase realtime database and front-end using android application for the mobile. The experimental results show that the prototype system can adapt to the change in dataset size and truck capacity constraints. We have observed that with an increase in truck capacity constraint, the number of clusters formed for the data set decreases. Forward and backward sweep clustering methods have been compared where there is no significant difference in the results produced. The dataset has been generated manually due to unavailability of real data from various sources. As a future work, we need to test the prototype with the real data in order to produce more accurate results.
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Yilmaz, Ozge. "Hazardous Waste Management System Design For Turkey." Phd thesis, METU, 2011. http://etd.lib.metu.edu.tr/upload/12613116/index.pdf.

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Hazardous waste management demands detailed planning due to the risks posed by hazardous wastes on public and environment and high investments required. This study aims to provide a framework that leads Ministry of Environment and Forestry (MoEF) in planning of hazardous waste facilities to be built. This framework considers the facility and transport cost along with impacts of hazardous waste management. The linear optimization models for several scenarios are developed in order to evaluate possible approaches in management of hazardous wastes. During cost calculations economy of scale principle is considered. Estimation of impact includes not only population impact but also environmental impact for which a methodology is developed in the scope of this study. This methodology considers the effect of hazardous waste transportation on lakes, rivers, dams, seashores, forests and agricultural areas, which are defined as vulnerable environmental elements. Evaluation of the results suggests that establishment of designated hazardous waste facilities with co-incineration practices and use of transfer stations give most satisfactory outcome. Co-incineration practices decrease incineration costs, which has the highest contribution to overall cost while transfer stations provide great improvement in total impact. Locations for recovery, treatment, incineration facilities and landfills are selected. These selections both confirm decisions made in the past regarding existing locations and become suggestions for locations for new facilities. It is observed that integrated facilities are favored. The importance of countrywide planning should also be underlined. It is believed that results of this study provides a basis to evaluate possible alternatives for further improvement of hazardous waste management system in Turkey that would be most useful to MoEF.
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Quiroga, Ekman Maria Eugenia. "Waste Management System Assessment in the North of Argentina." Thesis, KTH, Hållbar utveckling, miljövetenskap och teknik, 2017. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-219315.

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During the last decades, solid waste management has been going through a lot of changes regarding, regulation and applications of models and systems. New practices to solve environmental problems have been approached in different scenarios, situations and in different countries. Today the problem of waste management requires the application of broader approach including new methodologies, systems, practices and models to continue the development toward sustainable systems. The objective of this thesis to assess the waste management situation in the Provinces of Jujuy (Municipality of San Salvador de Jujuy) and Salta (Municipality of Salta Capital) located in the north of Argentina and to provide technical recommendations to implement or improve their waste management system. To carry out the technical and environmental assessment of the waste situation in the municipalities in Jujuy and Salta, the Integrated Waste Management (IWM) approach from UN-HABITAT and UNEP, Global Waste Management Outlook is applied; as well as the chronological and practical methodology WHAT (Waste Holistic Assessment Tool) from the Municipal Association in Sweden “Gästrike Återvinnare” based on ten (15) aspects that, according to praxis in Sweden, are considered relevant in order to assess the waste management system in a municipality. The Province of Jujuy and Salta are facing environmental problems as contamination of soil and groundwater, landfills producing greenhouse gas emissions and social problems of people living at the landfill that need to be addressed. The result of this thesis shows that in the province of Jujuy the waste management situation need to be prioritized. At the capital of Jujuy, there are produced 400 tonnes of household waste per day. The level of knowledge of the system perspective is very low and they need the creation of goals, objectives and policies for the implementation of a sustainable system. It is also necessary the assessment of the type and quality of the waste produced, to have a picture of the situation based on facts. The collection and transport need improvements on infrastructure and regarding the workers at the landfill. There is a lack of sorting system or sorting stations. Sorting of waste and recycling is only based on the activity of the informal workers living at the landfill. The construction of a sorting plant at Chanchillos is positive but the lack of separation system limit the usefulness of the equipment. Regarding the financing aspects, there is a system in place for charging the customers for services provided regarding collection of waste, but there is a problem with financing, to cover not only the costs for the daily services but to secure financing for needed investments in infrastructure, treatment facilities etc. In conclusion, the most important aspects with high priority In Jujuy to start with the implementation of an integrated waste management system in Jujuy are: system goals, source and quality of waste, waste sorting, waste treatment, cooperation, planning, financing, knowledge, socio economic aspects and environmental aspects. The results with lower priority are collection and transport, law and regulations, public awareness and business opportunities. On the other hand, the legislative framework shows that the legislation is in place concerning the issues of waste and environmental protection as well the legislative framework at national and provincial level. However, it is necessary to develop a specific legislation, regarding waste management practices, considering, waste hierarchy as well as the development guidelines regarding extended producer responsibility (EPR). In relation to the technical aspects of the landfill, the results show that there is a potential to implement two different solutions for waste treatment a) The capturing of the landfill gas to reduce gas emissions from the landfill. b) Possibility to build up a biogas plant with electricity generation or biodiesel production taking advantage of the raw material of the place as manure. The results in the Province of Salta shows the implementation of an integrated system is in place but it is necessary the improvement of the system. At the capital of the Province of Salta, there are produced 600 tonnes waste a day, that is deposited in a controlled landfill with biogas extraction and only a small percentage of the waste is sent for recycling. Regarding the waste collection and separation there are similarities with the problems of infrastructure described in the Province of Jujuy, such as the lack of trash cans, that makes the collection difficult and the lack of a separation system is a common deficit. The municipality does not have an update data of the quality and quantity of waste since 2003. In relation to public awareness there is a cooperative in cooperation with a private company that oversees the waste sorting. This program is a good initiative but it only covers 2000 blocks of the city and 14 000 households representing only the 10% of the total area. Regarding the financing there is a problem with financing, to cover not only the costs for the daily services but to secure financing for needed investments in infrastructure, treatment facilities, etc. The waste is transported to the landfill, which is using the cell method and is well constructed, considering important aspects as the size of the cells, quantity and variation of rainfall, the absorptive capacity of the waste as well as the control of the capacity of the cells for high degree compaction. However, the controlled landfill has technical problems during the extraction of biogas with leachates and oxygen that ingress into the holes where methane gas is extracted. In conclusion, the aspects with high priority in Salta are: classification of source and type of waste, cooperation, planning, financing, business opportunities and socio-economic aspects. The aspects with low priority are: system goals, collection and transport, waste treatment, law and regulations, public awareness, knowledge, environmental aspects. This shows that the government strategy is working positively regarding instruments and legislation. However, the control and financial system need improvement to afford the costs of the waste management system. The controlled landfill has technical problems during the extraction of biogas with leachates and oxygen that enter the holes where methane gas is extracted. There is also a potential to a) upgrade the biogas to biofuel or b) for generation of energy which is highly demanded in the Province. The conclusions of the assessment show that today the problem of waste management requires a broader approach and new methodologies to understand the situation of the decision makers in the area of waste management. Where not only the physical or technical aspects on a waste management system are considered but also broader and deeply oriented aspects that include other factors that describe the cause of the problems. The methodology applied in this thesis called WHAT (Waste Holistic Assessment Tool) can be used as a practical assessment tool in the future, for the analysis of the conditions for the establishment and development of integrated waste management system in a municipality. After the application of the WHAT methodology in this thesis it can be noticed that there is a potential of future improvements of the methodology as a) the inclusion of the Swedish knowledge and knowhow in the area.  b) potential to development of a software to provide a quick assessment in a municipality. c)  the inclusion of a database for the implementation of waste management. d) potential to include a financial tool with cost and benefits of the investments. According to the concept of sustainable waste management, the system needs to ensure health and safety aspects but in addition it must also be environmentally, effective, economically affordable and socially acceptable.
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Vitanza, Daniele. "Carbon flows of waste management system in Denmark." Master's thesis, Alma Mater Studiorum - Università di Bologna, 2010. http://amslaurea.unibo.it/1494/.

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Carrillo, Silva Diana. "Here and Within: A Local Waste Management System." Thesis, KTH, Skolan för arkitektur och samhällsbyggnad (ABE), 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-280003.

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This work is a critique to the stigmatisation of trash as something we should not live close together with. Due to this derogative conceptualisation of waste together with the inherent characteristics of landfills, Mexico City’s government implemented a “far and out” policy locating the final disposal areas distant and out from the city. Then, the proposal is the opposite approach: a local waste management system. So waste that usually ends kilometers away is handled in the community where it was produced in order to lengthen the life cycle of materials. The project is developed in Xochimilco for the challenges regarding the door-to-door collection of waste in this municipality. The local system focuses in the sorting process; being the most inefficient part of the current system as this activity is primarily executed by informal workforce. Besides, the type of waste that the community is able to manage completely locally is organic materials which are the principal element of the system for the regeneration of wetlands.
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Szabo, Florian Akos. "Modelling of secure communication system for IoT enabled waste management system." Thesis, Luleå tekniska universitet, Datavetenskap, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:ltu:diva-76028.

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Urban expansion is a key driving force of our modern world. Increasing environmental footprint is an example issue that is directly caused by it. The city of St. Petersburg employs on average almost 500 garbage trucks on a daily basis and spends more than 1 million US Dollars every year to collect, process and manage waste. In order for megacities, such as St. Petersburg, to cope with its effects, new ideas are needed. This seems to be an obvious area in which technology can be used to improve current practices and help save resources. In this study, we investigate how the Internet of Things, blockchain and Quantum Key Distribution systems can be integrated to provide a safe and efficient method for improving the waste management process in the context of Smart City projects. Our implemented simulations in Mininet show that there are some clear challenges with regards to the adoption of blockchain technology in an IoT environment. However, the integration of quantum channels and the use of Quantum Key Distribution within the blockchain infrastructure shows good potential for balancing the advantages and disadvantages of blockchain. With the implemented simulations we demonstrate the superior capabilities of the Proof of Infrastructure blockchain solution, which can facilitate secure transactions within the waste management scenario.
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Abor, Patience Aseweh. "Medical waste management at Tygerberg hospital in the Western Cape, South Africa." Thesis, Cape Peninsula University of Technology, 2007. http://hdl.handle.net/20.500.11838/782.

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Thesis (MTech (Environmental Health))--Cape Peninsula University of Technology, 2007
This study examined the medical waste management practices of Tygerberg Hospital. The researcher made use of both primary and secondaiy data. Since this was a is study, the analysis is essentially descriptive.The results of this study revealed that both general and medical wastes are generated in the hospital. Tygerberg Hospital does not quantify medical waste. Segregation of medical wastes into infectious medical waste and non-infectious medical waste is not conducted according to definite rules and standards. The hospital does not label infectious waste with Biohazard symbol. Separation of medical waste and municipal waste is however practiced to a satisfactory extent. Wheeled trolleys are used for on-site transportation of waste from the points of production (different wards) to the temporary storage area. Staff responsible for collecting medical waste use almost complete personal protective equipment. The results of this study indicated that off-site transportation of the hospital waste is undertaken by a private waste management company. Waste is transported daily and small pickups are mainly used by the waste management company for transporting the waste to an off-site area for treatment and disposal. The final disposal of the medical waste is done by the private waste management company. The main treatment method used in the final disposal of infectious waste is incineration. Non-infectious waste is disposed of using land disposal method. The hospital does not recycle medical waste materials except white office paper and mixed office paper and the use of empty containers of antiseptics for the collection and temporary storage of sharps.The hospital does not provide training for staff members on the health and environmental effects of infectious waste. The waste management company's workers have also not received any formal training with regards to medical waste management. The study showed that Tygerberg Hospital does not have a policy and plan in place for managing medical waste. There is no definite policy or plan for purchasing the necessary equipment and for providing the facilities for the correct management of medical waste in the hospital. There are also no policies and guidelines regarding the recycling of medical waste products. There are a number of problems the hospital faces in terms of medical waste management, including; lack of necessary rules, regulations and instructions on the different aspects of collection and disposal of waste, intermingling of hazardous wastes with domestic waste in the hospital sometimes, failure to quantify the waste generated in reliable records, lack of use of coloured bags by limiting the bags to only one colour for all waste, the absence of a dedicated waste manager, the supervisor in charge of general services has waste management as part of his job schedule, and there is no committee responsible for monitoring the management of medical waste. From the results of this study, it is obvious that medical waste management is not practiced according to the World Health Organisation's (WHO's) recommended standards. There are some areas where medical wastes are not properly managed. It is imperative for significant investment in the proper management of medical waste in order to reduce the health risk it poses.
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Books on the topic "Hospital waste management system"

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Younger, Patricia A. Hospital waste management. Gaithersburg, Md: Aspen Publishers, 1993.

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Palnitkar, Sneha. Training module on hospital waste management. Mumbai: Regional Centre for Urban and Environmental Studies, All India Institute of Local Self-Government, 2007.

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Palnitkar, Sneha. Training module on hospital waste management. Mumbai: Regional Centre for Urban and Environmental Studies, All India Institute of Local Self-Government, 2007.

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Palnitkar, Sneha. Training module on hospital waste management. Mumbai: Regional Centre for Urban and Environmental Studies, All India Institute of Local Self-Government, 2007.

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Corporation, Ontario Waste Management. Environmental assessment for a waste management system. [Toronto]: Ontario Waste Management Corporation, 1988.

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Newhall, J. Waste combustion system analysis: Project summary. Research Triangle Park, NC: U.S. Environmental Protection Agency, Air and Energy Engineering Research Laboratory, 1992.

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United States. Dept. of Energy. Office of Civilian Radioactive Waste Management. Program management system manual. 3rd ed. Washington, DC: U.S. Dept. of Energy, Office of Civilian Radioactive Waste Management, 1989.

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M, Layman Carl, ed. Community recycling: System design to management. Englewood Cliffs, N.J: Prentice Hall, 1992.

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Towards a sustainable waste management system: Discussion paper. [Toronto]: Ontario, Environment, 1990.

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Infectious waste management: A practical guide. Boca Raton, Fla: Lewis Publishers, 1995.

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Book chapters on the topic "Hospital waste management system"

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Pavan, Ivo, Elena Herrero Hernandez, and Enrico Pira. "Hospital Waste Management." In Sustainable Development and Environmental Management, 187–92. Dordrecht: Springer Netherlands, 2008. http://dx.doi.org/10.1007/978-1-4020-6598-9_13.

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Pavan, Ivo, Elena Herrero Hernandez, and Enrico Pira. "Hospital Waste Management." In Sustainable Development and Environmental Management, 187–92. Dordrecht: Springer Netherlands, 2008. http://dx.doi.org/10.1007/978-1-4020-8229-0_13.

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Theodore, Mary K., and Louis Theodore. "Hospital Waste Management." In Introduction to Environmental Management, 233–39. 2nd ed. Second Edition. | Boca Raton ; London: CRC Press, 2021. | “First edition published by CRC Press 2009”—T.p. verso.: CRC Press, 2021. http://dx.doi.org/10.1201/9781003171126-29.

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Ancillamercy, A. "Waste Management System." In Emerging Trends in Computing and Expert Technology, 305–9. Cham: Springer International Publishing, 2019. http://dx.doi.org/10.1007/978-3-030-32150-5_32.

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Sindhu, Rakesh K., Gagandeep Kaur, and Arashmeet Kaur. "Industrial Waste Management System." In Zero Waste, 115–30. Boca Raton : Taylor & Francis, a CRC title, part of the Taylor & Francis imprint, a member of the Taylor & Francis Group, the academic division of T&F Informa, plc, 2020.: CRC Press, 2019. http://dx.doi.org/10.1201/9780429059247-8.

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Mathur, Purva. "Role of Hospital Housekeeping and Materials Management Including Disinfection and Waste Management." In Hospital Infection Prevention, 81–89. New Delhi: Springer India, 2013. http://dx.doi.org/10.1007/978-81-322-1608-7_8.

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Zaman, Atiq, and Tahmina Ahsan. "Background of Waste Management System." In Zero-Waste, 11–32. Abingdon, Oxon ; New York, NY : Routledge, 2020.: Routledge, 2019. http://dx.doi.org/10.4324/9781315436296-2.

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Van de Velde, Rudi. "The Patient Management System." In Hospital Information Systems — The Next Generation, 123–37. Berlin, Heidelberg: Springer Berlin Heidelberg, 1992. http://dx.doi.org/10.1007/978-3-642-77617-5_11.

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Pharino, Chanathip. "Integrated Waste Management System Overview." In SpringerBriefs on Case Studies of Sustainable Development, 1–13. Singapore: Springer Singapore, 2017. http://dx.doi.org/10.1007/978-981-10-4631-5_1.

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Larichev, Oleg I., and David L. Olson. "Solid Waste Management System Selection." In Multiple Criteria Analysis in Strategic Siting Problems, 111–39. Boston, MA: Springer US, 2001. http://dx.doi.org/10.1007/978-1-4757-3245-0_6.

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Conference papers on the topic "Hospital waste management system"

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Verma, L. K., and J. N. Srivastava. "System application using 'multi-option' for hospital waste management in a hospital in India." In 4th IET Seminar on Appropriate Healthcare Technologies for Developing Countries. IET, 2006. http://dx.doi.org/10.1049/ic.2006.0656.

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Afriyanto, Somsak Pitaksanurat, Rittirong Junggoth, and Noor Alis Setiyadi. "Factors Affecting the Infectious Waste Management System on Practice Disposal Waste Among Health Workers in Bengkulu Hospital." In 2nd Sriwijaya International Conference of Public Health (SICPH 2019). Paris, France: Atlantis Press, 2020. http://dx.doi.org/10.2991/ahsr.k.200612.013.

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Zhao, Wei. "Notice of Retraction: Comparative Environmental Assessments of Hospital Waste Management Systems." In 2011 5th International Conference on Bioinformatics and Biomedical Engineering. IEEE, 2011. http://dx.doi.org/10.1109/icbbe.2011.5781386.

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Karasioğlu, Fehmi, and İbrahim Emre Göktürk. "The Applicability of Responsibility Accounting System within the Scope of Increasing Efficiency in Hospital Bussinesses in Turkey." In International Conference on Eurasian Economies. Eurasian Economists Association, 2013. http://dx.doi.org/10.36880/c04.00796.

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In order to reduce the waste of resources of health to minimum level, The most important sub-system of the system must take the necessary precautions in hospitals. Improving the quality of services provided in hospitals, ensuring cost control in hospitals, increasing competition, promotion of private initiatives are important elements which help these bussinesses to increase their effectiveness. Because of human health is a matter of priority in health services, the businesses which offer this services should think the economic priorities for second plan. This is a policy based on hospital establishments with income instead of providing added value to the costs without compromising on quality to ensure a minimum to decrease the cost, with the creation of the control system will be possible.The complex and the complex structure of hospitals also complicates the management of these enterprises.With the centrifugal organization structure and the sparation of management in the responsibility fields, management of this complex structure can be provided more efficiently.The most important problems in Turkey, in hospitals, professional management and cost control as a responsibility accounting system is a system that will produce a solution to the problem proposed.
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Cantarella, Jacques, and Ingrid Verstraeten. "National Decommissioning Management System: Experience and Lessons Learned." In ASME 2003 9th International Conference on Radioactive Waste Management and Environmental Remediation. ASMEDC, 2003. http://dx.doi.org/10.1115/icem2003-4809.

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Since 1980, the National Agency ONDRAF/NIRAS has been responsible by law for the safe management of all radioactive waste produced in Belgium, including decommissioning waste. In 1991, its responsibility was extended by Royal Decree of 16.10.91 to the field of decommissioning, its main specific assignments being: • The collection and evaluation of data (physical and radiological inventories) from nuclear plants; • The approval of decommissioning programmes, including decommissioning cost evaluations and mechanisms of funding. Already in the early 90s, ONDRAF/NIRAS started with the implementation of its own integrated data processing system, recording the physical and radiological inventories of nuclear plants and allowing the evaluation of the quantities of decommissioning materials and waste as well as of the decommissioning costs of the plants. In 1997, the law on the inventory of nuclear liabilities of 12.12.97 completed and enforced the decree of 1991, stating that the agency will: • Draw up a register specifying the location and condition of all nuclear facilities and all sites containing radioactive substances on Belgian territory; • Estimate the cost of decommissioning and cleaning up these facilities and sites; • Evaluate the availability of sufficient funds to carry out these future or ongoing operations; • Update the inventory every five years. As a result, during these last few years, ONDRAF/NIRAS had to deal with an increasing amount of decommissioning data (submission of inventories, new decommissioning plans and also a first batch of five-yearly revisions) concerning a larger diversity of facility types (enlargement of activities to “smaller” licensees, like universities, hospitals, etc). Simultaneously and consequently, ONDRAF/NIRAS faced the need to integrate a larger range of field-experienced decontamination and dismantling techniques, performed by different decommissioning companies, in order to obtain more refined and “pertinent” cost evaluations. For the same purposes, it appeared necessary to consider alternative waste processing possibilities, especially for very low-level waster arising from decommissioning activities. In 2000, ONDRAF/NIRAS started to upgrade its Decommissioning Management System (DMS) in order to enhance the quality of the database (integrity, intrinsic validity, extrinsic validity, completeness and accuracy) and simultaneously to develop the flexibility and the abilities of the evaluation functions. This paper presents and describes the latest version of the ONDRAF/NIRAS DMS (the data model, interface facilities, and the calculation and reporting possibilities) putting emphasis on experience gained and on some of the first lessons learned. The two first sections of this paper give an overview of the National Agency’s main missions and outline the information and data collection process in the framework of decommissioning and inventory. Indeed, the context in which the updated DMS was developed and the difficulties encountered during the data collection process should inform the reader about the way the upgrading of the data system has been thought out and the alternatives the National Agency had to deal with. In the third section, the main functionalities of the DMS modules are set out in concrete terms, the main modules being: • The “Inventories” module, recording their physical and radiological inventories for the sites that fall within the scope; • The “Techniques” module, integrating measurement, decontamination, dismantling and special recycling techniques, as well as their unit cost elements; • The “Waste” module, integrating standard and special waste categories, their packaging, transportation and processing possibilities, as well as their unit cost elements; • The “Nominal Forecast” module, linking an inventory to selected techniques and waste costs, associated with the “best estimate” reference calculation scenario; • The “Scenario” module, dealing with the storage and evaluation of alternative scenarios (pessimistic or optimistic ones, deferred dismantling, etc). The last section focuses on experience gained through developing the upgraded DMS and putting it into operation. Some potentialities of the upgraded DMS are also discussed.
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Myers, Eric R., and Jay Lehr. "Implementing and Managing a Practical Corporate Wide Legionella Risk Reduction Strategy for Industrial Water Systems." In 15th Annual North American Waste-to-Energy Conference. ASMEDC, 2007. http://dx.doi.org/10.1115/nawtec15-3217.

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Experts believe that Legionella may be present in 25% of cooling towers at any time, even with normal water treatment programs in place. This could pose a risk to employees and others working near cooling towers, and it could pose a risk to neighboring facilities such as schools, hospitals, public facilities, other businesses, or residential communities. The goal is to reduce the risk of Legionella, more specifically Legionella pnuemophila, which is the bacterium that causes a potentially fatal pneumonia known as Legionenaires’ Disease or legionellosis. Reducing the risk of Legionella requires more than water treatment alone, it requires a strategic plan based on recommended industry best practices that considers the mechanical, operational, and chemical control of cooling water systems. Implementing a corporate wide policy for Legionella risk reduction is challenging for waste-to-energy facility cooling towers. While a corporate policy for managing the risk due to Legionella is prudent, application of such a policy should not be wholly applied across all facilities or plant locations because not all water systems are equal or operated the same. Implementation starts with a plan that involves a multidisciplinary team including third party consultation and expertise. The first step of the Legionella risk reduction strategy is to evaluate current equipment and practices at each plant through a risk assessment process. The second step is to prepare a written Management Plan based on the risk assessment that clearly details risk reduction practices. The third step is to implement the management plan and monitor the system to ensure practices remain effective. And finally, all documentation should be periodically reviewed and adjustments made as necessary. This presentation will describe a process for implementing a corporate Legionella risk reduction policy, and it will highlight some of the major experiences learned.
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John, Gordon H., Nigel Reeves, Amy C. Nisbet, Clive R. Williams, and Andrew Garnet. "UK Surplus Source Disposal Programme." In ASME 2009 12th International Conference on Environmental Remediation and Radioactive Waste Management. ASMEDC, 2009. http://dx.doi.org/10.1115/icem2009-16097.

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The UK Surplus Source Disposal Programme (SSDP), managed by the Environment Agency, was designed to remove redundant radioactive sources from the public domain. The UK Government Department for Environment, Food and Rural Affairs (Defra) was concerned that disused sources were being retained by hospitals, universities and businesses, posing a risk to public health and the environment. AMEC provided a range of technical and administrative services to support the SSDP. A questionnaire was issued to registered source holders and the submitted returns compiled to assess the scale of the project. A member of AMEC staff was seconded to the Environment Agency to provide technical support and liaise directly with source holders during funding applications, which would cover disposal costs. Funding for disposal of different sources was partially based on a sliding scale of risk as determined by the IAEA hazard categorisation system. This funding was also sector dependent. The SSDP was subsequently expanded to include the disposal of luminised aircraft instruments from aviation museums across the UK. These museums often hold significant radiological inventories, with many items being unused and in a poor state of repair. These instruments were fully characterised on site by assessing surface dose rate, dimensions, source integrity and potential contamination issues. Calculations using the Microshield computer code allowed gamma radiation measurements to be converted into total activity estimates for each source. More than 11,000 sources were disposed of under the programme from across the medical, industrial, museum and academic sectors. The total activity disposed of was more than 8.5E+14 Bq, and the project was delivered under budget.
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Zirna, Gabriela, Daniela Saru, and Stefan Mocanu. "Sustainable Waste Management System." In 2021 12th International Symposium on Advanced Topics in Electrical Engineering (ATEE). IEEE, 2021. http://dx.doi.org/10.1109/atee52255.2021.9425240.

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Lindberg, Maria, Joakim Lo¨vstrand, and Karin von Kronhelm. "35 Years of Incineration in Studsvik: Lessons Learned and Recent Modifications and Improvements." In ASME 2011 14th International Conference on Environmental Remediation and Radioactive Waste Management. ASMEDC, 2011. http://dx.doi.org/10.1115/icem2011-59264.

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Since the incinerator in Studsvik was taken into operation in 1976 it has been operating at a level of 350–500 tonnes per year. The incinerator treats waste from both the nuclear industry and from other sectors generating radioactive waste such as hospitals, research companies/facilities and academic institutions. The incineration facility has been upgraded several times during its lifetime. The upgrades includes, change of off gas treatment as well as new control systems and currently the commissioning of a sister pyrolysis plant. Several new waste streams have also been approved for treatment in the last few years.
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Koyuncu, Baki, and Hakan Koyuncu. "Intelligent Hospital Management System (IHMS)." In 2015 International Conference on Computational Intelligence and Communication Networks (CICN). IEEE, 2015. http://dx.doi.org/10.1109/cicn.2015.305.

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Reports on the topic "Hospital waste management system"

1

Conkle, H. N. Deployable Waste Management System. Fort Belvoir, VA: Defense Technical Information Center, June 1999. http://dx.doi.org/10.21236/ada388210.

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Anderson, G. S., and H. S. Konynenbelt. 1995 Baseline solid waste management system description. Office of Scientific and Technical Information (OSTI), September 1995. http://dx.doi.org/10.2172/110175.

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Armacost, L. L., R. A. Fowler, and H. S. Konynenbelt. 1993 baseline solid waste management system description. Office of Scientific and Technical Information (OSTI), February 1994. http://dx.doi.org/10.2172/10135485.

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C.A. Kouts. Civilian Radioactive Waste Management System Requirements Document. Office of Scientific and Technical Information (OSTI), May 2006. http://dx.doi.org/10.2172/893537.

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Vann, J. M. Tank waste remediation system configuration management plan. Office of Scientific and Technical Information (OSTI), January 1998. http://dx.doi.org/10.2172/10154154.

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R. E. Broz. Waste Management Information System (WMIS) User Guide. Office of Scientific and Technical Information (OSTI), December 2008. http://dx.doi.org/10.2172/945220.

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Collard, L. B. Tank waste remediation system risk management list. Office of Scientific and Technical Information (OSTI), October 1995. http://dx.doi.org/10.2172/409861.

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Klimper, S. C. Tank waste remediation system tank waste retrieval risk management plan. Office of Scientific and Technical Information (OSTI), November 1997. http://dx.doi.org/10.2172/362359.

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Peck, L. G. Tank waste remediation system systems engineering management plan. Office of Scientific and Technical Information (OSTI), February 1996. http://dx.doi.org/10.2172/492093.

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Peck, L. G. Tank waste remediation system systems engineering management plan. Office of Scientific and Technical Information (OSTI), January 1998. http://dx.doi.org/10.2172/10148111.

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