Post on 07-Feb-2023
Noise exposure in school gymnasia and swimming poolsLuigi Maffeia), Gino Iannanceb), Massimiliano Masullob) and Pietro Natalettic)
(Received: 26 August 2008; Revised: 6 January 2009; Accepted: 8 January 2009)
School gymnasia and swimming pools are generally environments affected bypoor acoustic conditions due to absence of sound absorbing materials, noisysport activities, presence of many students at the same time and intensive use ofblowing whistles to enforce the communication.The consequence is that physicaleducation teachers can not only show long term stress but they can also beexposed to noise risk to noise-induced hearing loss. Investigation has shown thatthe problem is quite large as 20–25% of physical education teachers can beaffected by a noise exposure higher than acceptable limits. It is then necessary toanalyze in detail all factors that can influence the noise in these special schoolenvironments in order to develop simple acoustical guidelines useful for schoolofficials for stress management and hearing conservation programs.© 2009 Institute of Noise Control Engineering.
Primary subject classification: 51.1.4; Secondary subject classification: 25
1 INTRODUCTION
School environments are complex systems. Theyhave to absolve different functions such as speech,study, sport, music and recreation with different levelof concentration and involvement for both students andteachers.
Acoustic conditions in these environments are alsocomplex. Classrooms and gymnasia can be exposed tonoise sources external to the buildings such as road andrail road traffic, airports1,2 and external equipments butalso to internal noise sources such as activities inadjacent rooms and corridors or mechanical systems,mostly HVAC systems, or personal computer, printerand portable equipment3. Several national and interna-tional regulation and guidelines4–7 recommend limitingbackground noise to certain values and suggest and/orimpose to stakeholders (architects, builders, publicauthorities) values in terms of sound insulationbetween rooms, of sound insulation of façades, impactnoise, reverberation time and equipment noiseemissions.
But the main concern is the noise generated by thestudents during their day activities. In literature manystudies and surveys have been published on this topic.
Results are quite variable. Shield1 reports on noisesurveys carried out in 16 primary schools with noisemeasurements in 110 occupied classrooms. Resultsshow variation of internal noise with number of pupils,age and activity. Going from classrooms with 18 pupilsto classrooms with 32 pupils, the average ambient levelLAeq can increase by more than 10 dB�A� and LA90
(background noise) by almost 20 dB�A�. Activityinfluence seems also to be important. Going from a“quietest” activity (children sitting at tables doingsilent reading or tests) to the “noisiest” activity(children working in groups, moving around the class-room, with some talking), LAeq increases of 20 dB�A��56.0 to 77.0 dB�A�� and L90 of 22 dB�A��42.0 to 64.0 dBA�. According to this study theaverage LAeq of occupied teaching spaces, which couldbe assumed to be the average exposure of a child or ofa teacher at school, is 72 dB LAeq. The external noiseappears to have little effect on the internal noiseenvironment. Lower values were found recently bySato and Bradley8. They investigated the room acous-tics characteristics and noise environment of 27primary school classrooms during activities and regis-tered that students experience an average noise levelsof 49.1 dB�A� with a teacher speech levels of60.4 dB�A�. In an active classroom the noise generatedby students can increase the noise level in the quiet butoccupied condition by 10 dB. Tiesler and Oberdörster9
found out that the sound pressure level �LAeq,5 min� in aprimary classroom during the day is quite variable butthere were overall increases of 11 dB�A� from the firsthours (average 60 dB�A�) to the last hours (average71 dB�A�) of the school day.
a) Built Environment Control Laboratory Ri.A.S., SecondUniversity of Naple, Via S. Lorenzo, 81031 Aversa (Ce),ITALY; email: luigi.maffei@uninu2.it.
b) Built Environment Control Laboratory Ri.A.S., SecondUniversity of Naple, Via S. Lorenzo, 81031 Aversa (Ce),ITALY
c) Department of Occupational Hygiene, ISPESL, MontePorzio Catone, 00040 Rome ITALY.
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Noise Control Eng. J. 57 (6), Nov-Dec 2009 1
Data on sound pressure level inside classroomsduring school activities depends on background noise,configuration of the room, presence of sound absorbingmaterials, the grade of occupants, age of students butalso, and not less important, social and pedagogicalreasons.
While excessive external and internal noise in class-rooms seems to have a detrimental impact uponacademic performance and attainments of primaryschools students10, Enmarker and Boam11 in a study onnoise annoyance responses conducted on 207 pupils,aged 13–14 years, and 166 teachers concluded thatalthough students rated themselves more irritable tonoise, teachers are more sensitive and perceive moresleeping-problems, tinnitus and tension. It is significanttherefore that a relevant percentage (80%) of teachers9
have cited “noise in schools” as a stress-inducing factorand during school day they show an increase of theirheart rate as classroom noise increase. Indeed consid-ering the noise levels inside a classroom and a signal-to-ratio of 15 dB for good communication12, for mosttime during the day in different schools teachers haveto raise their voice up to 75–80 dB�A� and dysphonicproblems can occur13,14. This generally uncomfortableworking conditions is the main reason that leads moreteachers to request audiometric tests, in spite of the factthat noise levels are under 80 dB�A� and are compa-rable to other non occupational noise exposures associ-ated with routine activities15.
Music teachers can be the exposed more to noise. Infact in a noise exposure survey with dosimeter Behar etal.16 found out that for 78% of the 18 music teachersfrom 15 schools the measured Leq exceeded 85 dB�A�.
Gymnasia and swimming pools are generally builtwith acoustically poor materials (facing concrete andplaster), sport activities can be very noisy (rebounds ofballs, calls, cries, run, etc.) and more classes (students)can perform their sport activities at the same time. Asconsequence of the low speech intelligibility physicaleducation (PE) teachers are forced to use blowingwhistles to communicate with gymnasia and swimmingpools users. Jiang17 reported a case study of a PEteacher with a noise-induced hearing loss (NIHL). Toinvestigate its cause a noise study was conducted in thegymnasium where the PE teachers worked. The noiselevels were quite variable (between 72 and 119 dB�A�)during lessons but the dosimeter worn by the teacherfor 73 min registered an LAeq of 90.8 dB�A�. Dosim-eters worn by four students for 1 /2 hour periodsshowed values of LAeq between 95 and 106 dB�A�.More recently PJkala and Leśna18 examined the acous-tic environment in 16 school gymnasia. They registeredvariable sound levels for different activities: warm-upwithout balls �50–80 dB�A��, exercises with a couple
of balls �55–90 dB�A��, matches of volleyball, basket-ball, football �77–93 dB�A�� and athletics, games,gymnastics �70–90 dB�A��. The measurements werefollowed by a survey with a questionnaire submitted to85 PE teachers. 78% of them judged the acousticenvironment in the gymnasium as average or moreannoying and 38% reported a larynx disease.
In 2005 the Italian National Institute of Occupa-tional Safety and Prevention (ISPESL), in conjunctionwith the acoustic research group of the Second Univer-sity of Naples, began a new project on noise controland hearing conservation in special school environ-ments, such as school gymnasia and swimming pools,in which noisy activities and low acoustical standardscan generate high noise levels and PE teachers canshow stress and/or different health diseases.
Considering that in Italy there are more than 35.000PE teachers, the aim of the research was: a) to investi-gate on how large the problem of noise exposureamong the PE category could be; b) to analyse thecontribution of all factors that can influence the acous-tic environment; c) to build up simple guidelines toincrease the awareness of the school’s management insolving the problem. The research was conductedthrough large acoustic surveys, simulated tests, inter-views with PE teachers and school managements.Preliminary results of the survey were reported in Ref.19 and 20. In this paper global results of the programare presented and discussed.
2 FIELD SURVEY
The field survey started in year 2005 and wascompleted in year 2007. Seventy five PE teachers of 16primary and/or secondary schools and 2 universitieswere involved.
Architectural characteristics of 15 gymnasia and 3swimming pools were chosen in order to cover allpossible sport building configurations and activitiespresent in schools at different grades (primary, second-ary, university). Volumes of the buildings variedbetween 320 m3 (small gymnasium in a primaryschool) to 26000 m3 (a large university swimmingpool). Although the gymnasia and swimming poolsconstruction ages were not old, only some buildings(about 20% of the total investigated) contained soundabsorbing material on the ceiling and or on the walls.The general absence of sound absorbing material inthis type of building is confirmed in Ref. 18. Table 1presents data on architectural features of the investi-gated gymnasia and swimming pools.
The field survey was conducted following four steps,with results from each step presented in the sectionbelow.
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2 Noise Control Eng. J. 57 (6), Nov-Dec 2009
2.1 Measurements of the AcousticsCharacteristics of the Buildings
The reverberation time T30 in the central frequen-cies of 1 /3 octave bands was measured according toISO 338221 using the Maximum Length Sequences(MLS) technique. Digitally synthesized binarysequences are generated in the room under test by aloudspeaker. The cross-correlation with the outputsignal gives the impulse response of the room. Thesound source was placed in two different roompositions. For each position, the impulse responseswere recorded in six different points with a micro-phone. The same microphone positions were also usedto measure the background noise levels in terms ofLAeq�15 min�. Further measurements were performed toevaluate the speech transmission index22 at the distanceof approximately 10 m from the PE teacher position.All measurements were performed with empty rooms(Fig. 1).
Figure 2 reports the average values of the reverbera-tion time in the central frequencies of 1 /3 octave bandspectrum for each investigated place. The averagevalues of the reverberation time between 250 and2000 Hz referred to the volume of the buildings arereported in Fig. 3.
Although national and international standards andregulations5–7 recommend or impose average values ofthe reverberation time inside school gymnasia and
swimming pools lower than 2.0 sec, it was found outthat only two small gymnasia fulfilled this requirementand only other four others presented an average rever-beration time between 2.0 and 4.0 sec.
Most of the gymnasia and swimming pools areequipped with a ventilation system and some of themare close to road traffic but the background noise withno activities was always below 45 dB�A�. Measure-ments of the speech transmission index (STI) was notrealistic with no activities, but it is symptomatic thatalthough the background noise levels were low, due tothe high reverberation times, STI values were alwaysbetween 0.3 and 0.6 (poor-fair).
2.2 Meetings and Interviews
Meetings with the school managements and PEteachers were organized in order to receive data on theweekly school time schedules in terms of classrooms
Table 1—Gymnasia and swimming pools of the field survey. Architecturaland acoustics features. C(ceiling), W(side walls).
Id. V �m3� FormType
of material Type of schoolGym 1 2470 rectangular C—W: reflecting secondaryGym 2 9500 rectangular C—W: reflecting secondaryGym 3 10750 trapezoidal C—W: reflecting secondaryGym 4 9200 trapezoidal C—W: reflecting secondaryGym 5 590 rectangular C—W: reflecting primaryGym 6 320 rectangular C—W: reflecting primaryGym 7 356 rectangular C: Absorbing—W: reflecting primaryGym 8 3520 rectangular C—W: reflecting primaryGym 9 7000 horseshoe C: Absorbing—W: reflecting universityGym 10 450 square C: Absorbing—W: reflecting universityGym 11 1675 rectangular C—W: reflecting universityGym 12 7875 rectangular C—W: reflecting universityGym 13 1650 rectangular C—W: reflecting primaryGym 14 6000 rectangular C—W: reflecting secondaryGym 15 3120 rectangular C—W: reflecting secondarySw. P. 1 26000 rectangular C—W: reflecting universitySw. P. 2 3800 rectangular C—W: reflecting primarySw. P. 3 5460 rectangular C—W: Absorbing university
Fig. 1—Examples of gymnasia and swimmingpools investigated during no activities.
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and students present each hour and day in the gymnasiaand/or swimming pools, name of the associated PEteacher, activities performed, instruments used (e.g.whistles, megaphone), weekly working hours for eachPE teacher. After that personal interviews wereconducted with the 75 PE teachers. Questions werelimited to evaluating the presence of general stressfactors rather than going specifically to noise inducedhealth problems. More than 50% of them consideredstress of the presence of more classes contemporane-
ously (more students), particularly in the last hours ofthe school day, connecting this to the difficulty ofgiving vocal instructions. Some affirmed that to protecttheir voice in these situations they make more use of ablowing whistle, while others tried to activate sportswithout balls. Almost all imputed stress problems to theschool management rather than to their teachingorganization, to students’ behavior or to other environ-
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gym1 gym2 gym3 gym4 gym5 gym6 gym7 gym8 gym9gym10 gym11 gym12 gym13 gym14 gym15 sw p 1 sw p 2 sw p 3
Fig. 2—Average values of the reverberation time in the central frequencies of 1/3 octave band.
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Fig. 3—Reverberation times (average values between 250 and 2000 Hz) as function of the volume of thebuildings investigated.
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mental factors. Very few had some knowledge ofacoustic phenomena and parameters such as reverbera-tion time, sound levels and NIHL.
2.3 Sound Level Measurements
Operational conditions were identified for eachgymnasium and swimming pool in terms of activitiesperformed (e.g. artistic gymnastic, volleyball, divesand music.) and occupancy (e.g. one classes or twoclasses) during the week. During each of these schoolactivity hours, sound levels �LAeq,1 h� was measured inproximity to the position occupied by the PE teacherduring the lesson (e.g. Fig. 4). The type of activities,number of students present and use of the whistlewhere registered.
The continuous equivalent A-weighted soundpressure level LAeq,1 h measured during differentlessons was quite variable reaching values between 70�LAeq,min� dB(A) and 87 �LAeq,max� dB(A). LMAXpeak
varied between 85 and 135 dB.
2.4 Calculation of the Weekly Noise Exposure„LEX,week…
The Directive 2003/10/EC of the European Parlia-ment and of the Council23 fixes the minimum healthand safety requirements regarding the exposure ofworkers to the risks arising from noise. It introducesthree physical parameters used as risk predictors:
a) peak sound pressure �ppeak�: maximum value ofthe ‘C’-frequency weighted instantaneous noisepressure;
b) daily noise exposure level �LEX,8 h� (dB(A) re.20 µPa): time-weighted average of the noiseexposure levels for a nominal eight-hour workingday as defined by international standard ISO1999: 199024, point 3.6. It covers all noisespresent at work, including impulsive noise. If thework is such that the daily exposure consists ofmore periods with different sound levels, LEX,8 h
the combination of periods is ascertained usingthe formula:
LEX,8h = 10 log��i=1M 100,1LAeq,TiTi
T0� �1�
where: M is the number of individual periods in theworking day;
Ti is the duration of period i;LAeq,Ti
is the equivalent continuous A-weightedsound pressure level that represents the sound theperson is exposed to during period i;T0 is 28,800 seconds �8 hours�.c) weekly noise exposure level �LEX,w�:
time-weighted average of the daily noise exposurelevels for a nominal week of five eight-hourworking days as defined by international standardISO 1999:199024, point 3.6 (note 2). LEX,w is usedwhen the exposure of an employee to noise variesmarkedly from day to day.
Table 2 reports the exposure limit values andexposure action values defined in the Directive2003/10/EC23.
On the basis of the time schedule received by theschools’ management and of the sound levels registeredduring the different school activity hours (periods)LAeq,1 h, it was possible to associate to each of the 75PE teachers the relative average sound equivalent levelduring the week activities LAeq,w.
LEW,w was obtained considering for each teacher theeffective number of working hours per week �Tw�which is typically less than 40 �T0�.
LEX,w = LAeq,w + 10 log�Tw
T0� �2�
All data for each teacher are reported in Fig. 5.Although the 75 PE teachers are engaged in activities
Fig. 4—A gymnasium during activities.
Table 2—Exposure limit values and exposure action values defined in theDirective 2003/10/EC23.
LEX,8 h ppeak
Exposure Limit Values: 87 dB�A� 200 Pa (140 dB (C) in relation to 20 µPa)Upper Exposure Action Values: 85 dB�A� 140 Pa (137 dB (C) in relation to 20 µPa)Lower Exposure Action Values: 80 dB�A� 112 Pa (135 dB (C) in relation to 20 µPa)
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Noise Control Eng. J. 57 (6), Nov-Dec 2009 5
inside gymnasia and swimming pools for less than35 hours/week (average value 20 hours), 80% of themhave a LEX,w higher than 75 dB�A� and for 25% ofthem LEX,w exceeds 80 dB�A�.
3 SIMULATED TESTS
The results of this “field survey” was alarmingconsidering that none of the investigated PE teacherswear individual hear protectors. Investigation of themain factors that influence the noise exposure was thenconsidered.
Evaluating all of the data from the field survey it wasfound out that a weekly noise exposure LEX,w higherthan 80 dB�A� occurs when at least 3 of the followingconditions are present: (a) number of pupils �30(presence of more than one class); (b) time exposure�25 hours per week; (c) rebounds of balls duringactivities; (d) intensive use of blowing whistles; (e)reverberation time �5 s. The age of the students seemsto have less influence.
To verify these assumptions it was decided toconduct controlled tests with the simulation of thedifferent types of exposition situations for the PEteachers. For the tests the gymnasium n.14 of Table 1(Fig. 6) was used. The gymnasium, with a volume of6000 m3, has side walls and ceiling covered with
plaster; the average reverberation time between 250and 2000 Hz is 5.1 sec.
Five possible activities, and combination of theseactivities were performed by students and PE teachersduring lessons: 1) speech/yell, S; 2) gymnastic, G; 3)hand clapping, HC; 4) blowing whistles, W; 5) gameswith rebounding balls, R. During the simulation tests itwas difficult to control the intensity of the differentactivities, therefore a qualitative scale was used inTable 3 to estimate their intensity as observed byexperimenters. One with on one class (number studentsless than 30) and one with more than one class (numberof students greater than 30) were included. Thestudents’ age for this school was between 14 and
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hours of exposure per weekLEX.,wLAeq,w
Fig. 5—Average sound equivalent level during the week LAeq,w and weekly noise exposure LEX,w of the75 PE teachers.
Fig. 6—Gymnasium used for the simulated tests.
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18 years. The only fixed parameter was the reverbera-tion time of the gymnasium.
Each simulation test lasted 2 hours (typical lessontime). PE teachers and students were asked to followthe experimenters’ instructions. A sound level meterwas positioned in proximity of the PE teacher,normally located in centre of the gymnasium, and at1,70 m above the floor. At the same time the audiosignal was recorded as.wav file �44100 Hz-16 bit� witha 2-channel recording device and a binaural micro-phone set. The audio recording permitted subsequentlistening to analyze the events and their intensity.
Globally 14 combinations of gymnasium occupancyand activities, at different intensity levels, wereanalyzed. Tables 4 and 5 report a summary of data, theequivalent sound levels LAeq during the lesson time foreach combination and the evaluation of the weeklynoise exposure level LEX,w for two different PE teacherworking conditions: 25 h per week and 30 h per week.The comparison between the evaluated LEX,w for eachcombination and the lower Threshold Limit Value(TLV) �80 dB�A�� as defined by the European Direc-tive 2003/10/CE23 are reported in Figs. 7 and 8.
Some measurements were repeated where the PEteachers were asked to wear a dosimeter. With whistleblowing, the LAeq is 5–7 dB�A� higher than the values
Table 3—Qualitative intensity levels of each simu-lated activity.
LEGENDA
Low intensity Medium intensity High intensity
Use of whistle
Rebounds of balls
Speech\Yell
Hand Clapping
Table 4—Simulation tests with less than 30 students in the gymnasium.
Simulationnumber 1 2 3 4 5 6 7
Reverberationtime, RT > 5 s > 5 s > 5 s > 5 s > 5 s > 5 s > 5 s
Number ofstudents, N
< 30 < 30 < 30 < 30 < 30 < 30 < 30
Lesson time,T 2 h 2 h 2 h 2 h 2 h 2 h 2 h
Activity 1:speech/yell, S NO
Activity 2:gymnastic, G NO YES YES YES YES YES YES
Activity 3:teacher handclapping, HC
NO NO NO NO NO
Activity 4:use ofwhistle, W
NO NO NO NO NO
Activity 5:games withrebounds ofballs, R
NO NO NO NO NO
LA,eq, 73,6 78.9 73,1 75,7 81.2 81.5 83.8
LEXw 25 h 71.6 76.8 71.1 73.7 79.2 79.5 81.8
LEXw 30 h 72.4 77.6 71.9 74.4 80.0 80.3 82.6
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given in Figs. 7 and 8; thus there is a potential that thevalues in Figs. 7 and 8 underestimate the exposure.
Simulated tests confirmed that in a gymnasium withhigh reverberation time, if other two factors occursimultaneously such as the presence of more than one
class, rebounds of balls, intensive use of the whistleand time exposure �25 hours per week, the probabilitythat the lower Threshold Limit Value is exceeded isquite high.
Table 5—Simulation tests with more than 30 students in the gymnasium.
Simulationnumber 8 9 10 11 12 13 14
Reverberationtime, RT > 5 s > 5 s > 5 s > 5 s > 5 s > 5 s > 5 s
Numbers ofstudents, N > 30 > 30 > 30 > 30 > 30 > 30 > 30
Lesson time,T 2 h 2 h 2 h 2 h 2 h 2 h 2 h
Activity 1:speech/yell, S NO NO NO
Activity 2:gymnastic, G NO YES YES YES YES YES YES
Activity 3:teacher handclapping, HC
NO NO NO NO NO NO NO
Activity 4: useof whistles, W NO NO NO NO NO
Activity 5:games withrebounds ofballs, R
NO NO NO NO NO
LA,eq 78,6 81.3 81.3 86,0 85,6 83.5 85,1
LEXw 25 h 76.6 79.3 79.3 84.0 83.6 81.5 83.0
LEXw 30 h 77.4 80.1 80.1 84.8 84.4 82.3 83.8
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1 2 3 4 5 6 7Simulation tes t number
LEX,wdB(A)
LEX,w (25 hours per week)
LEX,w (30 hours per week)
LTLV
Fig. 7—LEX,w and lower Threshold Limit Value for each simulated test with �30 students
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4 QUESTONNARIE SURVEY ANDGUIDELINES
School managements are identified as “employer”according to the European Directive 2003/10/CE23.They should provide adequate training to reduce noiseexposure and should determine appropriate workschedules with adequate rest periods. They should also
identify the reasons why overexposures has occurredwith the consultation and participation of workers.
The school management were only slightly aware ofthe PE teachers’ noise risk. For this reason an electronicquestionnaire (Fig. 9) was prepared to be sent to allschool managements. Questions are prepared to receiveinformation on architectural features of the school
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8 9 10 11 12 13 14Simulation tes t number
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LTLV
Fig. 8—LEX,w and lower Threshold Limit Value for each simulated test with �30 students.
School:
lenght large heightDimensions of the gymnasium (in meters)
Main Materials plaster/concrete wood gypson board windowperforated metalsheet with wool
on backAcoustic tiles
internal surface of walls is mainly made of (insert X):internal face of ceiling is mainly made of (insert X):
Time schedule
Number of students that occupy gymnasium during PE lessons <10 <20 <30 >30
Percentage of time respect to the week time
Activity in gymnasium Volley Basketball Gymnastic Dancing OtherPercentage of time of this activity respect to the week time
PE teachersNumber of hours per week of activity in gymnasium 10 h 15 h 20 h 25 h 30 h
Do PE teachers use blowing whistles? Yes Noinsert X
How many times in one hour
Fig. 9—Electronic survey sent to school management.
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gymnasium or swimming pools, on activitiesperformed and on PE teachers’ time exposure. To eachanswer a score is automatically attributed whichincreases with the degree of negative influence on theexpected LEX,w.
According to the answers and final score, thequestionnaire ends with warnings and guidelines (e.g.reduce number of pupils, forbid blowing whistles, etc.).The questionnaire is a valid support for school manage-ments in planning activities and for the early stageassessment.
This electronic questionnaire was sent to 200 schoolmanagements receiving a 70% feedback. Answerssuggest that 20–25% of the PE teachers can suffer aweekly noise exposure level higher than 80 dB�A�.
5 CONCLUSIONS
The noise exposure of PE teachers in school gymna-sia and swimming pools is a problem that has beengenerally underestimated. A percentage of 20–25% PEteachers could achieve a weekly noise exposure higherthan 80 dB�A�. The survey, followed by simulatedtests, identified the specific influence on the globalnoise exposure of the different activities performed inthe gymnasia and swimming pools, of the school timeschedule management and of the architectural acous-tics characteristics.
An electronic questionnaire, with connected guide-lines, is presented. It can be used by school manage-ments for early stage noise exposure assessment andfor mitigation action plan.
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10 Noise Control Eng. J. 57 (6), Nov-Dec 2009