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EN15251 specifies indoor environmental input parameters for design and assessment of energy performance of buildings addressing indoor air quality, thermal environment, lighting and acoustics. This standard has now been available for 5 years and will be revised. The paper presents several issues to be discussed in the planned revision. The presented issues are dealing with the thermal environment (when to use adaptive model and criteria for personalized systems), indoor air quality (ventilation effectiveness, air cleaning, adapted/non-adapted occupants, and personalized ventilation), acoustic (introduction of categories), lighting (introduction of categories, daylight factor) and finally occupant behaviour.
Keywords: Thermal comfort, indoor air quality, ventilation, illumination, acoustic, criteria.
Energy consumption of buildings depends significantly on the criteria used for the indoor environment (temperature, ventilation and lighting) and building (including systems) design and operation. Indoor environment also affects health, productivity and comfort of the occupants. Recent studies have shown that costs of poor indoor environment for the employer, the building owner and for society, as a whole are often considerable higher than the cost of the energy used in the same building. It has also been shown that good indoor environmental quality can improve overall work and learning performance and reduce absenteeism. In addition uncomfortable occupants are likely to take actions to make themselves comfortable which may have energy implications. An energy declaration without a declaration related to the indoor environment makes no sense. Thus there is a need for specifying indoor environmental criteria for design, energy calculations, performance and operation of buildings.
EN15251 specifies how design criteria can be established and used for dimensioning of systems. The standard how to establish and the main parameters to be used as input for building energy calculation and long term evaluation of the indoor environment. Finally the standard identifies parameters to be used for monitoring and displaying of the indoor environment as recommended in the Energy Performance of Buildings Directive.
The standard is now up for review and there is a wish also to adopt this standard at the ISO level. The revision must be based on experience gathered from application of the standard both in the field and by more theoretical studies.
The following issues must be discussed during the revision of the standard.
· Clear differentiation between the adapted and PMV-PPD approach
· Personalized systems
· Local thermal comfort parameters
The use of the standard has shown it is needed to make it clearer when the adapted concept can be used (residential buildings, passive cooling). When comparing the two concepts in more temperate climates like Copenhagen it can be seen (Figure 1) that the adapted approach specifies lower room temperatures in early and late summer. For sedentary occupation the requirements for mechanical condition buildings (based on the PMV-PPD index) is an operative temperature range in winter 20‑24°C and summer 23‑26°C, which is shown in Figure 1 with the blue and yellow squares. The adapted approach in 15251 shows a little more variations (running mean outside temperature) than ASHRAE-55 (monthly average outside temperature). The maximum temperature during summer is almost the same for the two approaches. During the summer period (May-October) the adapted approach do however specify room temperatures lower than 26°C and thus a stricter requirement.
Figure 1. Recommended requirements for the indoor operative temperature based on the adapted approach and PMV-index from ASHRAE-55 and EN15251. ASHRAE adapted approach is based on a monthly average outside temperature, in EN15251 it is based on a weekly weighted outside temperature.
In the present standard the PMV-PPD index is mainly presented by giving recommended temperature intervals for the different categories of thermal environment. More emphasis should be put on how to use the PMV-PPD index in a more flexible way i.e. taking into account the cooling effect of increased air velocity.
During the last decade several systems for providing a high quality personal indoor environment have been studied and tested. Also several products/systems are now available on the market. The existing standards with criteria for the indoor environment (thermal, air quality, noise , light) are all based on criteria for the whole occupied zone (ISO EN 7730, EN15251, ASHRAE-55, ASHRAE-62.1). Can these criteria be directly applied also to a personal system, where the occupants try to meet their own preferences? If the occupants have a personalized system is it then possible to relax on the requirements to the general environment? These are some of the issues that will be discussed in the revision of the standard. Based on the many studies found in the literature on personalized systems for control of thermal comfort, air quality, lighting and noise a set of criteria for the personalized environment should be established. At the same time recommended changes in the existing criteria for the general environment should be made.
Personalized indoor environmental systems can provide the occupant with an individual control of thermal comfort, perceived air quality, illumination and masking of noise. In general for illumination and noise you can use the same criteria for a personalized environment as for a general environment. Most personalized systems blow air towards the occupant (Figure 1)
This set-up will mainly influence the
perceived air quality and increase cooling due to an increased air velocity and
may be lower air temperature of the supply air. But also the classification of
the Indoor environment will be influenced due to better CO2-level within the Personalized Environmental zone. As
shown in Figure 2 a personalized system may divide the
space in two zones, one close to the occupant and a general zone. The question
is if it should be allowed to relax the indoor environmental criteria for the
general zone if a personalized system is available. The increased ventilation effectiveness should
allow a decrease of the supply ventilation rate. This can be taken into account
by correcting the required ventilation rates in the standard tables (based on
complete mixing) with the ventilation effectiveness (see below).
Figure 2. Typical set-up of personalized ventilation system.
In the present standard local thermal comfort parameters like asymmetric radiant temperature, draught, vertical air temperature differences and surface temperatures are not included as these parameters may not have a direct influence on the energy consumption in buildings. They do however have an influence on the design and dimensioning of buildings and HVAC systems and then also on the energy consumption.
The standards approach to indoor air quality is to specify a recommended level of ventilation (outside air), depending on number of occupants in the space and a contribution depending on the floor area of the space. There is however a need for some clarification and new concepts regarding these issues:
· Ventilation for Non-adapted or adapted occupants
· Use of increased CO2 level as IAQ indicator
· Air cleaning as substitute for outside air
· Ventilation effectiveness
· Personalized ventilation
For the prescriptive
method, a minimum ventilation rate per person and a minimum ventilation rate
per square metre floor area are required. The two ventilation
rates are then added. The person-related ventilation rate should take care of
pollution emitted from the person (odour and other bio effluents) and the
ventilation rate based on the person’s activity and the floor area should cover
emissions from the building, furnishing, HVAC system, etc.
The design outdoor
airflow required in the breathing zone of the occupied space or spaces in a
zone, i.e., the breathing zone outdoor airflow (Vbz), is determined
in accordance with the equation:
Vbz = RpPz + RaAz (1)
Where:
Az = Zone floor area: the net occupied floor area of the zone m²,
Pz = Zone population: the greatest number of people expected to occupy the zone during typical usage.
Rp = Outdoor airflow rate required per person: these values are based on un-adapted occupants in EN15251 and adapted in ASHRAE-62.1.
Ra = Outdoor airflow rate required per unit area.
In the standard different methods for calculating the recommended ventilation rate are included. As a minimum it must be ventilated to dilute the bio effluents from the occupants (people component, Rp, see Table 1). These rates are in EN15251 specified for three categories of indoor air quality, based on the prediction that a certain percentage of visitors will find the air quality unacceptable. The design levels are thus adequate for people who walk into a space. It is debatable if this should always be the case. People adapt very quickly to the odour (bio effluents) in a space while there is less adaption to emissions from building materials and tobacco smoke (odour and irritants, [2]). To provide an acceptable perceived air quality for occupants (who have adapted to the air quality for at least 15 min.) it is estimated that one third of the ventilation rate is sufficient i.e. for category II 2,5 instead of 7 l/s per person. The ASHRAE Standard 62.1 for ventilation and indoor air quality defines ventilation levels for adapted persons (occupants). In addition, the minimum recommended ventilation is increased with a building-related ventilation rate, in order to take into account the emissions from the building and its systems (see Table 1). There is, however no general agreement on whether the contribution from the building should be added in full. Several studies indicate this is the best approximation, but it may not be valid for all types of pollutants. Here it is the contribution to the odour and irritation (perceived air quality) which must be taken into account. So it can be argued that they all influence one organ (the nose) and so should be added. When the health risk is considered a simple addition can be made for the same chemical component; but not for different chemical components if they influence different body organs.
Table 1 shows the required ventilation rates from standard EN15251 compared to ASHRAE 62.1.
Table 1. Smoking free spaces in commercial buildings according to ASHRAE 62.1 and EN15251.
Type of building/ | Occupancy person/m² | Category EN | Minimum ventilation rate, i.e. for occupants only l/s person | Additional ventilation for building l/s×m² | Total l/s×m² | |||||
ASHRAE Rp | EN | EN Very low-pollut. | EN Low-pollut. | EN Not low-pollut. | ASHRAE Ra | EN Low Pol. | ASHRAE | |||
Single office | 0,1 | I | 2,5 | 10 | 10 | 1,0 | 2,0 | 0,3 | 2 | 0,55 |
II | 7 | 7 | 0,7 | 1,4 | 1,4 | |||||
III | 4 | 4 | 0,4 | 0,8 | 0,8 | |||||
Land-scaped office | 0,07 | I | 2,5 | 10 | 10 | 1,0 | 2,0 | 0,3 | 1,7 | 0,48 |
II | 7 | 7 | 0,7 | 1,4 | 1,2 | |||||
III | 4 | 4 | 0,4 | 0,8 | 0,7 | |||||
Confe-rence room | 0,5 | I | 2,5 | 10 | 10 | 1,0 | 2,0 | 0,3 | 6 | 1,55 |
II | 7 | 7 | 0,7 | 1,4 | 4,2 | |||||
III | 4 | 4 | 0,4 | 0,8 | 2,4 | |||||
Class-room | 0,5 | I | 3,8 | 10 | 10 | 1,0 | 2,0 | 0,3 | 6 | 2,2 |
II | 7 | 7 | 0,7 | 1,4 | 4,2 | |||||
III | 4 | 4 | 0,4 | 0,8 | 2,4 |
There are quite big differences between the European recommendations and those listed by ASHRAE. One major reason is that ASHRAE requirements are minimum code requirements, where the basis for design is adapted people, while the European recommendations are for un-adapted people(visitors). Who should we ventilate for? For people just entering the room (un-adapted) or for people already occupying a room (adapted)? Here the philosophy adopted by ASHRAE 62.1 and EN15251 differs. But should it really be one or the other? In a conference room, auditorium or lecture room most people enter at the same time. It then takes some time before the odour level has reached an unacceptable level and meanwhile people adapt. In this case it may be appropriate to require a ventilation rate based on adapted persons. There may be other spaces where you would design for un-adapted people, e.g. in a first class restaurant, offices, and department stores. It seems logical that more differentiated criteria could be used.
In the standard are also listed a CO2 criteria for three categories; but the values are not consistent with the required ventilation rates listed in Table 1. Knowing the CO2 production from the occupants it is possible to calculate the increased CO2 level compared to outside, which corresponds to the total ventilation rates (see Table 2).
Table 2. Equivalent increase in CO2 levels indoor for the total ventilation rates specified in Table 1.
Very
low-polluting | low-polluting | Not
low-polluting | ||
Type of room or building | Category | ΔCO2 [ppm] | ΔCO2 [ppm] | ΔCO2 [ppm] |
Single office | I | 375 | 280 | 190 |
| II | 560 | 400 | 265 |
| III | 930 | 695 | 465 |
Landscape office | I | 310 | 220 | 140 |
| II | 465 | 310 | 195 |
| III | 745 | 530 | 340 |
Conference room | I | 510 | 465 | 400 |
| II | 735 | 665 | 570 |
| III | 1265 | 1160 | 995 |
Class room | I | 510 | 465 | 400 |
| II | 735 | 665 | 570 |
| III | 1265 | 1160 | 995 |
Air cleaning is not taken into account at all in EN15251, while ASHRAE 62.1 by using the analytical procedure allows some credits for air cleaning. There is an increased interest in the development of air cleaning equipment. This may be an acceptable way of reducing the amount of outside air, saving energy and still have an acceptable indoor air quality. However, better test methods for air cleaners are required, because at present the test is usually based on chemical measurements and the resulting effect on odour or perceived air quality is not taken into account. It is also very important to specify which kind of “pollutants” should be used when testing. Some air cleaners may work well on VOC’s (emission from materials) but have zero or even a negative effect if the source is people (bio effluents). There is an increasing development of methods and products for gas phase air cleaning including both adsorptions filters and air cleaners using a chemical reaction to remove certain gasses (PCO-Photo Catalytic Oxidisation). CEN-ISO and ASHRAE are developing standard test methods, which will measure the air cleaning efficiency or the equivalent amount of outside air called Clean Air Delivery Rate, CADR
If we work with classes one option could be that even with air cleaning you must have a level of ventilation corresponding to the lowest class. With air cleaning you can then reach a higher class without increasing the amount of outside air. It is therefore recommended that the standard specifying indoor air quality as a certain ventilation rate open up for the possibility to partly use air cleaning as a substitute for outside air.
One serious problem is how to ventilate if a building is located in an area with poor outside air quality or if there is a time of the day (e.g. rush hour) when the outside air quality is unacceptable. In some cases it might even be better to reduce ventilation under these circumstances. For testing gas phase air cleaning a known gas is used to simulate pollution (i.e. toluene to simulate VOC’s). The concentration is measured before and after the air cleaner. The air cleaning efficiency is calculated as:
εclean = (CU – CD)/CU·100 %
where
εclean = air cleaning efficiency
CU = gas
concentration before air cleaner
CD = gas concentration after air cleaner
The criteria for the ventilation rates shown in Table 1 are mainly based on perceived air quality PAQ, which is measured by a human test panel. It is therefore also important to be able to test the air cleaning efficiency in relation to the perceived air quality. The air cleaning efficiency can be expressed as:
εPAQ =Qo/QAP·(PAQ/PAQAP-1)·100 %
where
εPAQ = air cleaning efficiency for perceived air quality
Qo = ventilations rate in l/s
QAP = air flow through the air cleaner l/s
PAQ = perceived air quality without the air cleaner, decipol
PAQAP = perceived air quality with the air cleaner, decipol
The Clean Air Delivery Rate is calculated as:
CADR = εPAQ·QAP·(3,6/V) h-1
where
QAP· air flow through the air cleaner l/s
V volume of the room m3.
If the air cleaner has been tested based on chemical measurements it should then be allowed to reduce the pollution contribution due to the building in Table 1 with a factor based on the measured air cleaning efficiency:
qb,clean = εclean·qb l/s per m²
If the efficiency is 50% the contribution from the building in Table 1 is then reduced to half, which corresponds to a change in the building category from low-polluting to very low polluting when using Table 1.
The ventilation rates specified in the standards (Table 1) are the required rates at breathing level in the occupied zone. The required ventilation rate at the room supply diffusers are calculated as:
Total ventilation rate V = Vbz
/ev (2)
Where:
Vbz = breathing zone ventilation
Where:
ev = Ventilation effectiveness
Ce =
Pollutant concentration in extract air
Cs= Pollutant concentration in supply air
Ci= Pollutant concentration at breathing level
The ventilation effectiveness depends on the air distribution efficiency and the type and position of the pollution source(s), so this value is not only a system characteristic. In most cases it is assumed that the pollutant emission is uniform, so the ventilation effectiveness is the same as the air distribution effectiveness. For a fully-mixed ventilation system the value is 1 and the ventilation rates in Table 1 can be used for the design of the supply grills. The ventilation effectiveness or air distribution efficiency is a function of the position and type of supply and return grills, and depends on the difference between supply and room temperature and on the total amount of airflow through the supply grill. The air distribution effectiveness can be calculated numerically or measured experimentally. Typical examples of ventilation effectiveness/air distribution effectiveness are shown in Figure 3.
Figure 3. Typical examples of
ventilation/air distribution effectiveness. ( CEN TR 1752)
The rates given in the Tables of standards are based on full mixing and in practice the ventilation effectiveness is very seldom taken into account. One complication is that some systems may have a different ventilation effectiveness summer and winter. If the supply temperature is lower than room temperature the ventilation effectiveness is normally 1 or higher, but if the ventilation system is used for heating in winter the ventilation effectiveness could be as low as 0.5, and the ventilation rates should really be doubled. More information and a greater emphasis on this factor are required.
To use ventilation effectiveness can be one way of taking into account personalized ventilation; but we need also to look at issues like acceptance of higher air velocities and less strict requirements to the general environment if the person is equipped with a personal system.
The air distribution effectiveness takes into account the air distribution in a space, but does not take into account how effectively the outside air is transported through the ducts to the space. If the system has any air leakage, the amount of ventilation air must be increased. This is not dealt with in EN15251, but is mentioned in ASHRAE 62.1.
The criteria in EN15251 are only specified at one level of luminance. The following additional criteria for daylight factor (Table 3) and seasonal affective disorder (SAD, Table 4) should be discussed for inclusion in the standard.
For rooms that are used during the day (work places, living rooms, dining rooms, kitchens, or child’s play rooms) the minimum daylight factor is:
Table 3. Recommended criteria for the daylight factor.
I | II | III | |
Daylight factor | > 5% on average | > 3% on average | > 2% on average |
To reduce the prevalence of SAD (Seasonal Affective Disorder; “winter depression”), higher light levels are particularly important during winter. For minimum one of the main habitable rooms in residential buildings direct sunlight should be available from fall to spring equinox.
Table 4. Recommended criteria for SAD (Seasonal Affective Disorder).
I | II | III | |
Direct sunlight availability, percentage of probable sunlight hours | > 10% | > 7,5% | > 5% |
The section on acoustic needs to be revised. Again it would be recommendable if experts could suggest different categories of requirements.
The occupant behaviour will have a significant influence on the energy consumption in buildings. In dynamic computer simulations of indoor environment and energy consumption in buildings certain occupant behaviour (temperature set-point, time of occupancy, solar shading etc.) significantly influences the results. Therefore there is a need to specify some “standard” patterns of occupant behaviour.
EN15251 is the first European standard that includes criteria for the four indoor environmental factors: Thermal comfort, air quality, lighting, and acoustic. This standard has been widely used in practice and several scientific papers have been published dealing with issues related to the standard. The present paper has highlighted some of the issues that must be discussed in the future revision of the standard.
ASHRAE Standard 55-2007. Thermal environment conditions for human occupancy. ASHRAE, Atlanta.
ASHRAE-62.1(2010) Ventilation for acceptable indoor air quality, Atlanta, GA, American Society of Heating, Refrigerating and Air-Conditioning Engineers.
CEN TR 1752 1998. Ventilation for Buildings: Design Criteria for the Indoor Environment. CEN.
EN 15251 (2007) Indoor environmental input parameters for design and assessment of energy performance of buildings- addressing indoor air quality, thermal environment, lighting and acoustics. CEN, Brussels.
EN 7730 (2005) Analytical determination and interpretation of thermal comfort using calculation of the PMV and PPD indices and local thermal.
EN ISO 13790, Energy
performance of buildings – Calculation of energy use for space heating and
cooling.
Abstract: EN15251 specifies indoor environmental input parameters for design and assessment of energy performance of buildings addressing indoor air quality, thermal environment, lighting and acoustics. This standard has now been available for 5 years and will be revised. The paper presents several issues to be discussed in the planned revision. The presented issues are dealing with the thermal environment (when to use adaptive model and criteria for personalized systems), indoor air quality (ventilation effectiveness, air cleaning, adapted/non-adapted occupants, and personalized ventilation), acoustic (introduction of categories), lighting (introduction of categories, daylight factor) and finally occupant behaviour.
Author:
Bjarne W. Olesen Professor International Centre for Indoor Environment and Energy, Department of Civil Engineering, Technical University of Denmark bwo@byg.dtu.dk
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