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Sökning: WFRF:(Holmér Ingvar) > Gao Chuansi

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31.
  • Holmér, Ingvar, et al. (författare)
  • Thermal stress on firefighters in extreme heat exposure
  • 2006
  • Ingår i: Protective clothing - towards balanced protection : : Proceedings of the 3rd European Conference on Protective Clothing (ECPC) and NOKOBETEF 8, Gdynia, 10-12 May 2006 - Proceedings of the 3rd European Conference on Protective Clothing (ECPC) and NOKOBETEF 8, Gdynia, 10-12 May 2006.
  • Konferensbidrag (refereegranskat)abstract
    • Five students of a rescue training school cycled at 50 W for 20 minutes at 20 °C before walking up to 30 minutes in a climatic chamber at 55 °C and 30 % relative humidity. Four different types of clothing ensembles were used differing in terms of thickness and thermal insulation value were tested on separate days. All subjects completed 28-30 minutes in light clothing, but quitted after 20-27 minutes in three firefighter ensembles due to a rectal temperature of 39.0 °C or subjective fatigue. No difference in the evolution of mean skin or rectal temperature was seen for the three turnout ensembles. Sweat production amounted to about 1000 g in the turnout gears of which less than 20 % evaporated. It was concluded that the small differences between the turnout gears in terms of design, thickness and insulation value had no effect on the resulting physiological strain for the given experimental conditions.
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32.
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33.
  • Kuklane, Kalev, et al. (författare)
  • Calculation of Clothing Insulation by Serial and Parallel Methods: Effects on Clothing Choice by IREQ and Thermal Responses in the Cold
  • 2007
  • Ingår i: International Journal of Occupational Safety and Ergonomics. - : Informa UK Limited. - 2376-9130 .- 1080-3548. ; 13:2, s. 103-116
  • Tidskriftsartikel (refereegranskat)abstract
    • Cold protective clothing was studied in 2 European Union projects. The objectives were (a) to examine different insulation calculation methods as measured on a manikin (serial or parallel), for the prediction of cold stress (IREQ); (b) to consider the effects of cold protective clothing on metabolic rate; (c) to evaluate the movement and wind correction of clothing insulation values. Tests were carried out on 8 subjects. The results showed the possibility of incorporating the effect of increases in metabolic rate values due to thick cold protective clothing into the IREQ model. Using the higher thermal insulation value from the serial method in the IREQ prediction, would lead to unacceptable cooling of the users. Thus, only the parallel insulation calculation method in EN 342:2004 should be used. The wind and motion correction equation (No. 2) gave realistic values for total resultant insulation; dynamic testing according to EN 342:2004 may be omitted.
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34.
  • Kuklane, Kalev, et al. (författare)
  • Effects of natural solar radiation on manikin heat exchange
  • 2006
  • Ingår i: Protective clothing - towards balanced protection : : Proceedings of the 3rd European Conference on Protective Clothing (ECPC) and NOKOBETEF 8, Gdynia, 10-12 May 2006 - Proceedings of the 3rd European Conference on Protective Clothing (ECPC) and NOKOBETEF 8, Gdynia, 10-12 May 2006.
  • Konferensbidrag (refereegranskat)abstract
    • The main objective was to compare short wave radiation from Thorn lamp to solar radiation. In sun all manikin front zones get more or less evenly radiated but in the lab the radiated power reaches some zones more than others. Tests were carried out on the thermal manikin Tore under clear sky in a building corner facing the sun. The manikin was turned so that in the end of each trial the sun faced manikin front. Basic tests without radiation were carried out in homogenous conditions in the climatic chamber. 4 sets of clothing were tested: black Nomex (BN), orange Nomex (ON), white cotton (WC) and reflective Nomex (RN). Helly-Hansen underwear (super stretch, polypropylene) was used under all coveralls. Thermocouples were fixed at chest on underwear inner and outer surfaces and outer layer inner and outer surfaces for textile surface temperature measurements. From basic tests there were estimated the heat losses for particular outdoor conditions. The insulation values were corrected for air velocity according to EN 342 (2004). The difference between the calculated heat losses and actual measured heat losses outdoors gave heat gain from sun for those particular conditions. There was a clear difference between BN and the other suits and RN and the other suits, however, ON and WC were quite similar. The highest textile temperatures were recorded for BN and lowest for RN. A difference between ON and WC was present, too. The curves followed the same pattern as observed from the manikin tests with solar lamps in the climatic chambers: underwear had often the highest temperatures.
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35.
  • Kuklane, Kalev, et al. (författare)
  • European manikin standards and models to calculate thermal insulation
  • 2010
  • Ingår i: 8I3M : Eighth International Meeting for Manikins and Modeling : Victoria, BC, Canada, August 22-26, 2010 - Eighth International Meeting for Manikins and Modeling : Victoria, BC, Canada, August 22-26, 2010.
  • Konferensbidrag (refereegranskat)abstract
    • ISO 9920 defines three insulation calculation methods: global, parallel and serial. It considers global method a general one that works in any situation, and parallel and serial could be used in specific cases. EN ISO 15831 is the basic manikin testing standard. It gives only two possibilities: parallel and serial. The specific requirements for equations’ use are not set as in ISO 9920, e.g. uniform heat loss or surface temperature. The parallel method is defined similarly to the global in ISO 9920. Thus, the calculation methods’ definitions in the standards differ. EN 342, EN 14058 and EN 13537 for testing cold protective clothing or equipment refer to the methods in EN ISO 15831. Calculation of insulation by any method or using the average insulation of both methods is allowed depending on the test results with reference calibration ensembles. However, several issues need to be considered when using serial method. EN 511 Protective gloves against cold gives its own equation assuming that the whole hand is just one zone. In the case of one zone the serial and the parallel model give the same result. More zones increase the insulation difference between the methods. With uniform surface temperature (required by EN ISO 15831) the parallel method provides the same insulation value with any number of zones while the serial method provides higher value with more zones compared to one zone. EN 342 (cold) and EN 14058 (cool) use the same measuring principles and the same calibration garments. In the case of evenly distributed insulation, the differences in serial and parallel methods are relatively small, and proportional. However, with more insulation layers overlapping in heavy cold protective ensembles the differences increase, and don’t follow the linear relationship any more. The calibration ensembles are selected to represent proper cold protective garments. Thus, if a garment piece does not represent a proper cold protective ensemble (faulty design, manufacturing error) the calibration does not have to be valid. Lately a study on insulation measurements with electrically heated vest was presented. The vest provided an additional 10 W totally to torso region, and turned results from serial method to impossible 83 clo. It may be argued that manikin test is not meant to measure clothing with auxiliary heating. However, what happens if components of an ensemble do employ smart textile technology? A standard should avoid allowing any unrealistic results. EN 13537 Requirements for sleeping bags utilizes the physiological model that has been developed assuming serial values to be correct. It works with properly manufactured sleeping bags. It would be a considerable work to replace the method, although, equally good models are available. Such a major change requires good will and participation from several labs including the ones outside Europe, too.
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36.
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37.
  • Kuklane, Kalev, et al. (författare)
  • Parallel and serial methods of calculating thermal insulation in European manikin standards
  • 2012
  • Ingår i: International Journal of Occupational Safety and Ergonomics. - 2376-9130. ; 18:2, s. 171-179
  • Tidskriftsartikel (refereegranskat)abstract
    • Standard No. EN 15831:2004 provides 2 methods of calculating insulation: parallel and serial. The parallel method is similar to the global one defined in Standard No. ISO 9920:2007. Standards No. EN 342:2004, EN 14058:2004 and EN 13537:2002 refer to the methods defined in Standard No. EN ISO 15831:2004 for testing cold protective clothing or equipment. However, it is necessary to consider several issues, e.g., referring to measuring human subjects, when using the serial method. With one zone, there is no serial–parallel issue as the results are the same, while more zones increase the difference in insulation value between the methods. If insulation is evenly distributed, differences between the serial and parallel method are relatively small and proportional. However, with more insulation layers overlapping in heavy cold protective ensembles, the serial method produces higher insulation values than the parallel one and human studies. Therefore, the parallel method is recommended for standard testing.
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38.
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39.
  • Kuklane, Kalev, et al. (författare)
  • Ventilation solutions in clothing
  • 2012
  • Ingår i: Innovations in textile materials & protective clothing. - 9788372834935 ; , s. 205-212
  • Konferensbidrag (refereegranskat)abstract
    • There are several solutions to keep the workers at good thermal state at hot or cold workplaces, for example, PCM (phase change materials) and ice; electrically heated clothing; increase/decrease clothing insulation, e.g. with smart textiles; water based cooling/heating; air based systems, ventilated clothes. Following methods can be used to increase the ventilation in the clothes: use of air permeable clothes; increase possibilities for ventilation (design solutions); active ventilation (e.g. fans) etc. Polluted atmosphere may not allow to use the methods above. Ventilation in protective clothing, e.g. for CBRN protection may require inlet air filtering or a separate (compressed) air source. Various solutions have been tested with natural and forced ventilations, and flow rates. Dry and wet tests were carried out. Ventilation is an effective way to increase heat loss. Ventilation utilizes body own capacity (sweating) to regulate heat loss. At extremely high temperatures considerable air flows are required for sufficient cooling: 100 l/min may not be enough. The larger is the ventilated skin area, the more effective it is due to enhanced evaporation.
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40.
  • Lin, Li-Yen, et al. (författare)
  • A laboratory validation study of comfort and limit temperatures of four sleeping bags defined according to EN 13537 (2002)
  • 2013
  • Ingår i: Applied Ergonomics. - : Elsevier BV. - 1872-9126 .- 0003-6870. ; 44:2, s. 321-326
  • Tidskriftsartikel (refereegranskat)abstract
    • In this study, we validated comfort and limit temperatures of four sleeping bags with different levels of insulation defined according to EN 13537. Six male subjects and four female subjects underwent totally 20 two-hour exposures in four sleeping bags at four intended testing temperatures: 11.2, 3.8, 2.1 and -9.0 degrees C. The subjective perceptions and physiological responses of these subjects were reported and analyzed. It was found that the EN 13537 defined comfort temperature and limit temperature were underestimated for sleeping bags MA3, HAG and MAM. The predictions are so conservative that further revision may be required to meet the requirements of both manufacturers and consumers. In contrast, for the sleeping bag MAO with a low level of insulation, the limit temperature defined by EN 13537 was slightly overestimated. In addition, two individual case studies (-28.0 and -32.0 degrees C) demonstrated that low toe temperatures were widely observed among the male and female subjects, although the mean skin temperatures were almost within the thermoneutrality range (32.0-34.0 degrees C). It seems that the IREQ model (ISO 11079) overestimated both the comfort and limit temperatures of the sleeping bags. Finally, traditional sleeping bags may be required to be re-designed to provide consumers both whole body comfort as well as local thermal comfort at feet/toes or users need to be made aware of the higher need for their insulation. (C) 2012 Elsevier Ltd and The Ergonomics Society. All rights reserved.
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