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Article

A Proposal for New Microclimate Indexes for the Evaluation of Indoor Air Quality in Museums

Department of Energy, Systems, Territory and Construction Engineering, University of Pisa, Largo Lucio Lazzarino, 56122 Pisa, Italy
*
Author to whom correspondence should be addressed.
Buildings 2016, 6(4), 41; https://doi.org/10.3390/buildings6040041
Submission received: 22 August 2016 / Revised: 23 September 2016 / Accepted: 10 October 2016 / Published: 15 October 2016

Abstract

:
A correct artwork preservation requires strict values of several microclimate parameters, in particular temperature, humidity, and light. In existing museums, the evaluation of the effectiveness of current building plant systems and management is essential to avoid artwork deterioration. In this work, we propose the use of five simple performance indexes that use monitored data to estimate the suitability of the whole museum system in the maintenance of benchmark values of temperature, humidity, and light. The new indexes also take into account microclimate daily span and spatial homogeneity, which can represent a criticality in the preservative process. We apply these new indexes to the results of a monitoring campaign in Palazzo Blu, a museum in Pisa, which lasted for almost four months during a temporary exhibition on Toulouse-Lautrec works. The indexes show a mainly acceptable instantaneous microclimate, but HVAC (Heating, Ventilating and Air Conditioning) system improvement is necessary to avoid high thermo-hygrometric daily span. This methodology is useful for the identification of microclimate criticalities and can help the cooperation between conservation experts and professionals giving hints to improve museum internal microclimate. In case ofalready optimal microclimate, these indexes can be useful in more complex analyses, including simulations of possible retrofit actions, keeping microclimate suitability as a constraint.

1. On Microclimate for Artwork Preservation

Artworks need strict microclimate conditions to be preserved. Each typology of artwork (e.g., paper, frescoes, paintings, stones) needs specific microclimate conditions for their preservation; in general, typical environmental parameters to be controlled are:
  • mean temperature (°C);
  • maximum daily and seasonal temperature difference (°C);
  • mean relative humidity (%);
  • maximum daily and seasonal relative humidity difference (%);
  • maximum allowed illuminance (lx).
For each type of artwork, standards suggest suitable microclimate intervals [1,2,3]; in some cases, however, if the artifact has been acclimatized to a particular historical climate environment, it is preferable to maintain these conditions instead of standard intervals, to avoid climatic shocks of the artwork [4,5]. Technical standard UNI 10829 [1] lists acceptable values for illuminance and optimal and acceptable ranges for temperature and relative humidity (in some cases, it is not possible to achieve, at the same time, visitor comfort and correct conditions for artwork preservation [6]). The presence of dust and gaseous pollutants and microbial and UV radiations can also threaten artwork integrity [7,8,9].
Technical standards [1] discuss the complexity of the degradation issue, depending on the reciprocal interaction among artworks and the whole microclimate set. The technical standard helps technicians, suggesting two ranges of temperature and relative humidity to be maintained: a strict range and a more tolerability range. If microclimate is in the strict range, degradation of artworks does not occur. If microclimate is in the tolerability range, degradation does not occur if temperature and relative humidity variations are not too wide or frequent. In any case, the appropriate set of microclimate parameters to be maintained should be stated by experts on the basis of the actual conservation status, to minimize preservation risks.
In the past centuries, several artworks were damaged by inappropriate indoor air conditions. One of the most famous cases of damaged artworks is Leonardo’s Last Supper, in Milan, Italy. The used painting technique is highly sensitive to humidity: unfortunately, the painting was subject for centuries to large and frequent changes in temperature and relative humidity [10]. High values of relative humidity caused the deterioration of the paintings on the Scrovegni Chapel walls (in Padua, Italy) [11,12] and wooden objects in Rosslyn Chapel (in Edinburgh, UK) [13,14]. Several other examples of artworks damaged by inappropriate microclimate can be found in [7,8].

2. Existing Buildings as Museums

Existing and historical buildings are often used, especially in the Mediterranean area, for artwork hosting and exhibition. Differently from new museums (which are designed for the specific exhibition purpose), the use of existing buildings as museums needs a deep analysis. Historical buildings are characterized by high-mass walls and limited glass surfaces. Consequently, the daily changes in temperature are straightened due to thermal inertia; moreover, superheating of surfaces due to natural light is limited and a better control of the artwork lighting is possible (for example, using ambient light instead of point light, or low-IR and low-UV bulbs). On the other hand, historical buildings are often characterized by surface or interstitial condensation and cannot passively cope with abrupt microclimate changes, for example due to a high number of visitors, thus requiring the installation of new technical equipment. However, as these buildings are often protected as “works of art” themselves, the installation and use of Heating, Ventilating and Air Conditioning (HVAC) systems is often a complex issue. In some cases, in the last century, simple heating solutions were installed, but the non-optimal design of these systems can also be responsible for inadequate microclimate (in particular spatial and temporal gradients of temperature and relative humidity) [15,16,17,18,19]. A series of European Projects [20,21,22] dealt with the retrofit actions of several existing museums to improve both internal air quality and energy efficiency. These projects show that solutions must be carefully chosen on the basis of the correlation between external climate, collections preservation state, building envelope characteristics and technical equipment: each museum hence represents a unique case [6]. The relationship between external climate change and preservation of historic buildings, including museums, was the object of the European Project “Climate for Culture” [23]. The project analyzed several existing buildings in Europe and Egypt, simulating the risk of conservation and the energy demand in case of changing external climate.
An Italian piece of research [24,25] points out that more than 80% of museums in the province of Siena are equipped with heating systems and about 40% with both heating and cooling systems. In the province of Florence, instead, about 90% of the museums are placed in historical buildings and most of them have no HVAC system [26]. As a consequence, the maintenance of suitable microclimate in terms of temperature and relative humidity is linked to thermal inertia and infiltration and ventilation losses.
The monitoring of the parameters of interest in artwork conservation (temperature, relative humidity, and light) is a useful tool for the evaluation of the effectiveness of installed technologies. During the last two decades, monitoring campaigns have been carried out in several famous museums and historic buildings [27,28,29,30,31], finding criticalities in the building plant system that might lead to artwork deterioration or identifying the best strategies to improve microclimate.

3. The Need of Microclimate Suitability Indexes

Several protocols [32,33] and methodologies [30,34,35,36,37] were proposed to evaluate the environmental suitability for artwork preservation. Some of them only focus on instantaneous microclimate, other ones highlight the importance of little microclimate variation on daily or seasonal basis. However, a procedure including new, simple and comprehensive indexes seems necessary, to take into account the whole set of parameters that affect artwork conservation, verify the suitability of the current building plant system, and identify criticalities and possible solutions to improve the maintenance of optimal microclimate.

3.1. A Proposal for New Microclimate Suitability Indexes

Performance Index (P.I.), defined in [34], is the percentage of time in which temperature and relative humidity values (in a significant point of the hall) are within the strict range reported in [1]. P.I. is a single effective index in highlighting the microclimate criticalities in terms of temperature and relative humidity, especially if the index is plotted in a graph like the one in Figure 1. In graphs like this, each marker represents a monitoring acquisition and the solid lines identify the optimal microclimate area. The representation of different conditions during the monitoring campaign with different colors or markers (e.g., the data acquired during the opening hours of the museum in red and during the closing hours in blue) can be a good practice to help experts in conservation identify critical periods.
However, instantaneous values of temperature and relative humidity in suggested ranges are not the only important parameters in artifacts preservation. As reported in Section 1, technical standards identify other parameters to be controlled:
  • maximum allowed illuminance, an important parameter, especially in the case of organic materials;
  • daily variation of temperature and relative humidity: even if microclimate is maintained in suggested ranges, temperature and relative humidity can significantly vary on a daily basis and these cycles can cause artwork deterioration [38];
  • spatial homogeneity of microclimate parameters: as reported in [1], the measuring points virtual grid has to be tightened in case of significant spatial microclimate variation.
Performance Index, as defined in [34], can be usefully applied in any environment that requires strict microclimate control, but new performance indexes specifically tailored to museum requirements should also take into account all the involved parameters in artifact preservation. Similarly to the Performance Index in [34], we propose four additional indexes that conservation experts can use to evaluate the effectiveness of the museum HVAC plant in maintaining the desired microclimate, according to the mentioned literature and standards:
  • Performance Index related to the wider range (P.I.*), which identifies the percentage of time in which microclimate—in terms of temperature and relative humidity—occurs in the monitored environment remaining within the more tolerant range;
  • Light Suitability Index (L.S.I.), which identifies the percentage of time in which illuminance does not exceed the maximum allowed limit;
  • Daily Span Index (D.S.I.), which identifies the percentage of days in which the maximum values of temperature and relative humidity span do not exceed the allowed limits;
  • Spatial Homogeneity Index (S.H.I.), which identifies the percentage of time in which microclimate is sufficiently homogeneous in the defined volume, according to the allowed spatial variations.
It is left to conservation experts to choose the most appropriate microclimate set to be considered as benchmark conditions for the preservation of the specific exposed artworks.

3.2. Importance of the Application of the New Methodology

As reported in Section 1, it is not possible to correlate index values with a specific damage probability; however, the use of this procedure can highlight the ability for the whole building plant system to reach the suggested microclimate intervals. The proposed methodology is usually easily implementable if the museum is already provided with monitoring sensors. According to [1], sensors should be placed in significant spatial points and the monitoring campaign should last for the necessary time period to identify temporal profiles of the main microclimate parameters ([1], at least one month per season is suggested). The data acquisition frequency should be chosen to record the rapid changes in temperature and relative humidity due to internal gains (e.g., 15 min). The method application can provide relevant information on the museum microclimate suitability and give hints on a better management of all the systems in a museum. At the same time, it is obvious that a detailed knowledge of the whole system is necessary for the correct procedure application, as several different causes can result in the same effects on microclimate. For example, a low value of S.H.I. can reveal presence of punctual sources or sinks of heat or moisture, or a poor air circulation, which can be improved with a change in the Air Handling Unit (AHU) or fancoil damper position, if possible. A low value of P.I. or P.I.* can be caused by undersizing of the generators or heat exchangers in the AHU or inadequate choice of control parameters (e.g., supply air set-points, switching-on periods of the HVAC system): the analysis of a graphical representation of the indexes can help in the identification of the problem that causes low-quality microclimate. Figure 1, for example, shows a high number of acquisitions characterized by acceptable temperature but undesirable relative humidity during nights. This can be ascribed to the utilization of heating system during nights, while the ventilation system is switched off: a possible solution can be the use of humidifiers or the use of AHU for a few hours before the museum opening (when circulation between the halls and effects of moisture penetration in walls cause the lowest relative humidity values). Finally, a low value of L.S.I. can suggest the need of more diffused lighting. These indexes can be useful in museums housed in existing buildings, as the design of technical equipment is usually non-optimal. In any case, this methodology can be also applied in new museums, to verify the effectiveness of the whole system. Another useful application can be the comparison of different retrofit solutions in museums that already have suitable microclimate, aimed at improving other aspects (e.g., visitor comfort, energy efficiency), using physical models of the building plant system, such as in [39,40].
Several pieces of research report multi-objective analysis of museums: these studies aim to identify retrofit actions to reduce energy demand or enhance thermal comfort, the maintenance or improvement of indoor microclimate being constraints [41,42,43].
Figure 2 shows a possible application of the indexes in case of retrofit action choice. Experts in conservation define benchmark values for the five indexes; several solutions are tested, comparing the indexes values from simulation with benchmark values, thus identifying the best retrofit action to apply.

4. A Practical Application

We applied the proposed methodology starting a monitoring campaign in Palazzo Blu, an important museum in Pisa. The monitoring campaign took place for almost four months, the whole period of a temporary exhibition on Toulouse-Lautrec’s drawings. According to UNI 10829 [1], the reference microclimate for an optimal preservation of this type of artworks is the following:
  • internal temperature between 18 °C and 22 °C (temperature is still considered acceptable between 16.5 °C and 23.5 °C);
  • internal relative humidity between 40% and 55% (relative humidity is still considered acceptable between 34% and 61%);
  • maximum allowed illuminance up to 50 lx.
In the following sections, we present a brief description of the museum and of the installed sensors, and we discuss the results of the monitoring campaign on the basis of the proposed procedure.

4.1. Description of Palazzo Blu and of the Monitored Rooms

Palazzo Blu is a museum located in the center of Pisa, alongside the Arno River. The museum hosts two permanent exhibitions and two temporary exhibitions (a “winter” and a “summer” exhibition) every year. Strict microclimate control is necessary for the correct preservation of the high cultural value of the exposed artworks: thus, a complex system is used, including:
  • an AHU, which provides fresh air from 8 a.m. to 9 p.m. every day, containing filters, two heating elements, a cooling element, a vaporizer, and a blower; the air flow rate is 2800 m3/h and the set-point supply temperature is 18 °C;
  • an air-to-water heat pump, which provides alternatively heating or cooling, with fan coils as emitting system; this system is switched on from 7 a.m. to 10 p.m.;
  • a management system measures temperature and relative humidity in the rooms, controlling the HVAC system to maintain the chosen set points and coping with the abrupt variations of microclimate due to internal loads (i.e., visitors).
The last temporary exhibition took place from 17 October 2015, to 14 February 2016: more than 180 artworks by Henri de Toulouse-Lautrec were displayed. During this period, the museum was open every day, from 10 a.m. to 7 p.m. (from Monday to Friday) or from 10 a.m. to 8 p.m. (on Saturdays and Sundays). Almost 90,000 people visited Palazzo Blu during the 122 days of exhibition period, with an average daily number of 700 visitors and up to 2000 during weekends. The daily trend of tickets sold shows afternoon peaks. In accordance with the curators, four rooms of this zone were selected for a monitoring campaign: these rooms hosted the most famous exposed works by Toulouse-Lautrec. However, in the following sections, we will present the analysis of the two adjacent rooms on the first floor (Reference Rooms, RRs) with the highest presence of visitors, due to the relevance of the exposed artworks: their volume is about 340 m3 (8.5 m by 10 m, height: 4 m). These rooms are characterized by masonry external walls (average total thickness: 70 cm, thermal transmittance: 0 . 9 W m 2 K ) and no glazed area.

4.2. Position and Characteristics of the Installed Sensors

The monitoring campaign in the two RRs was carried out using the following sensors:
  • two SIEMENS DESIGO sensors (SIEMENS AG, Berlin and Munich, Germany), which acquire temperature to control the technical equipment through the management system (mean temperature accuracy: ± 0.7 K , mean relative humidity accuracy: ± 3 % );
  • two 4-noks ZED-THL-M sensors (4-NOKS, Mossa, Gorizia, Italy), which acquire data on temperature, relative humidity, and illuminance (mean temperature accuracy: ± 0.2 K , mean relative humidity accuracy: ± 3 % );
  • two pair of SEMITEC NTC 103AT-2 sensors (SEMITEC Corporation, Tokyo, Japan), each acquiring temperature at two different heights of the hall, 1.5 m and 2.5 m height (mean temperature accuracy: ± 0.2 K , mean relative humidity accuracy: ± 3 % ).
An analogous set of sensors was positioned in the other two monitored rooms on the ground floor and additional temperature data were collected from the AHU dampers and from the rooms adjacent to the monitored ones. DESIGO sensors collect data every 15 min, while SEMITEC and 4-nok sensors acquire the signal every 6 min. A linear interpolation was used to estimate acquisition data within a 15 min time step instead of a 6 min time step, thus allowing synchronization and comparison of the data acquired by the different sensors.
The data-gathering lasted for the whole exhibition period and data were automatically saved and available on a wireless network, allowing remote check and download. More detailed information on the monitoring system is reported in Appendix A.

4.3. Main Results of the Monitoring Campaign

The monitoring campaign showed that, even if an acceptable microclimate occurs most of the time, there is room for improvement of microclimate conditions. Figure 3 shows the mean values of temperature and relative humidity in RRs during the whole monitored period: each marker identifies an acquisition, recorded every 6 min (about 30,000 total data points). The red cross markers identify the data referring to the opening hours of the museum, while the blue circle markers identify the data related to the closing hours. The black rectangle identifies the optimal microclimate for preservation, while the larger cyan rectangle identifies the acceptable microclimate. It can be noted that the highest values of relative humidity and temperature are recorded at the opening hours of the exhibition (when the presence of visitors most influences internal microclimate): in fact, the mean values of temperature and relative humidity during the opening hours are, respectively, 21.0 °C and 51.2%, while the same values monitored during the closing hours are, respectively, 20.3 °C and 49.5%.
On the basis of the monitored data, we calculated the value of P.I. (65%), P.I.* (98%) and L.S.I. (100%). These values well highlight the suitability of the HVAC system in maintaining a microclimate that does not cause deterioration of the artworks and a correct design of the artificial lighting (mean illuminance value: 15 lx). In Figure 4, the daily span of temperature and relative humidity in the RRs is shown: the blue star markers identify the data referring to weekdays, while the red circle markers identify data referring to weekends. The gray area identifies the suggested maximum values of microclimate span, according to [38]. On the basis of these monitored data, we calculated the D.S.I., which is 48%. The D.S.I. value highlights a criticality in the RRs: the daily span of temperature and relative humidity is particularly high during weekends. This can be ascribed to the absence of dehumidification in the AHU components. In fact, chilled coils cannot be employed because, during winter, the heat pump can provide only hot water; however, especially during weekends, dehumidification coils are needed due to the high number of visitors. In any case, the high thermal inertia of the envelope is useful in reducing the temperature gap in the daily cycle, as the HVAC system is switched off during the night. The positive effect of the high mass walls is shown in Figure 5, where external and internal temperature are compared for a reference week (from 14 to 20 December). Internal temperature does not show relevant variation on a daily cycle.
For the evaluation of the S.H.I., we referred to the perimeter of the RRs. We measured the maximum span of temperature and relative humidity along the perimeter of the rooms in December. The resulting value of S.H.I. is 74%. Figure 6 represents the spatial span, with the gray area representing the suggested values for spatial homogeneity as reported in [1]. Blue star markers identify the data referred to the closing hours of the museum, while red circle markers identify data referred to the opening hours. Figure 6 shows that unacceptable spatial temperature span occurs usually during the opening hours of the museum, while relative humidity can be considered homogeneous in space. It is worth noting that there is no inconsistency among the indexes values on relative humidity: this parameter sometimes exceeds the acceptable instantaneous limits and significantly changes on daily cycles, but instantaneously does not vary in space.
The presence of visitors strongly influences temperature and relative humidity in the halls: in particular, visitors are responsible for high relative humidity values on the opening hours, even if the monitoring campaign does not show relevant spatial variation of this parameter in the analyzed volume. On the contrary, temperature significantly varies along the perimeter. This effect is visible in Figure 7, displaying the internal temperature profile (monitored at a 1.5 m height) along the perimeter of the two rooms at the first floor, during a benchmark week (from 14 to 21 December). We report a parametrization of the perimeter of the two rooms with the blue line in Figure 8; the red rectangles represent the AHU dampers and the central black rectangles represent the fan coil units. In Figure 7, two higher-temperature areas are identified: the first is at x values between 0 and 10 m along the perimeter, and the second is between 25 and 30 m. The higher temperatures are due to internal heat gain caused by visitors that gather in the vicinity of the famous posters and artworks by Toulouse-Lautrec (for example, Reine de joie and La Passagere du 54), which attracted more visitors.
The typical heating due to visitors’ presence is clearly visible on a daily basis, and it is more marked during the afternoon hours. It is worth noticing that, during the weekend, temperatures along the whole perimeter were higher, revealing a higher number of visitors. These results, highlighted by the monitoring campaign, are confirmed by the hourly profile of sold tickets during the benchmark week, as shown in Figure 9, which shows the average number of sold tickets during the benchmark week, differentiating a typical weekday from a weekend.
The values of the proposed indexes for the monitored rooms are summarized in Table 1 and graphically represented in Figure 10. Indeed, these indexes are capable of showing, in a concise and effective fashion, the microclimate suitability of museum environments. In this particular case, as already discussed, they highlight that the HVAC system is effective in maintaining instantaneous suitable conditions for artwork preservation, but improvements are necessary to reduce the variation of microclimate parameters on daily cycles.

5. Conclusions

In this work, we showed that new performance indexes are necessary to evaluate the microclimate suitability in museums, as the currently used index does not take into account the whole set of microclimatic parameters that are important in artwork preservation. The five indexes (one already defined and four new indexes) are easy to evaluate and they provide a comprehensive view of the museum microclimate: starting from a monitoring campaign, the indexes estimate the suitability of the lighting system and the effectiveness of the building’s HVAC system in the maintenance of optimal range, acceptable range, daily span, and spatial homogeneity of internal temperature and humidity. These indexes can help in the identification of periods and zones where the internal microclimate is most influenced by external factors (e.g., visitor presence), which can potentially be critical for artwork preservation. The proposed methodology was applied carrying out a monitoring campaign of the four main rooms of Palazzo Blu, during a temporary exhibition. The analysis of the indexes revealed that the instantaneous current microclimate is mainly acceptable for artwork preservation, but the daily span should be reduced. In particular, relative humidity needs a stricter control, to cope with the high crowding of visitors, which would require dehumidifation of the air supply even during winter. This process is not possible at the moment, due to the configuration of the heat pump and AHU systems. This information can help the curators in the choice of correct actions in favor of preventive conservation: one could think of new crowding management (for example, imposing a maximum number of visitors present at the same time in the room, or limiting the stay in the room) or the concurrent use of heating and cooling coils of the AHU. The interaction between the building plant system and artwork preventive conservation is well-known and proved by several examples. The application of these simple indexes can highlight the typical criticalities that experts in conservation can encounter in their work and also suggest possible causes and retrofit actions to improve microclimate. Moreover, the methodology can be used in a more general framework, such as multi-objective analyses aimed at identifying optimized management strategies for concurrent achievement of different goals (for example, preventive conservation and visitor comfort or energy efficiency).

Acknowledgments

We gratefully acknowledge the Fondazione Palazzo Blu, in particular the President, Cosimo Bracci Torsi, and Riccardo Moschetti, for allowing us to conduct the microclimate monitoring campaign. We also want to thank our department technologist Davide Della Vista, for setting-up the wireless monitoring system.

Author Contributions

The paper summarizes a substantial part of Eva Schito’s doctoral activities. Daniele Testi and Walter Grassi supervised all the phases of the research work.

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

The following abbreviations are used in this manuscript:
AHUAir Handling Unit
D.S.I.Daily Span Index
HVACHeating, Ventilating and Air Conditioning
IRInfrared
L.S.I.Light Suitability Index
P.I.Performance Index
P.I.*Performance Index related to a wider range
RRsReference Rooms
S.H.I.Spatial Homogeneity Index
UVUltraviolet

Appendix A. Description of the Monitoring System

The four monitored rooms are provided with four SIEMENS DESIGO sensors, collecting data every 15 min on temperature and relative humidity values, thus controlling the technical equipment through the management system. For the specific purpose of the monitoring campaign, we also collected data from the adjacent rooms (to record the temperature values as boundary conditions), from the AHU dampers, and from the return duct to the heat pump. Then, we used additional sensors (4-nok sensors and SEMITEC sensors) in the rooms, to verify the spatial homogeneity of the environmental variables and the microclimate suitability in the artworks proximity: all these sensors acquired data every 6 min. Another temperature and relative humidity sensor (DICKSON, Addison, IL, USA) was posed at the AHU inlet, acquiring data every 15 min. DESIGO sensors send data to the management system, from which the download is possible. DICKSON sensor is provided with an internal flash memory, which allows data transfer. The other installed sensors are connected to the datalogger via a wireless network based on the ZigBee standard. Each node sends the sensor signal to a coordinator device that creates the network, maintains the wireless traffic among the sensors, and transfers data to the datalogger via Modbus (4-noks, AstreGroup, Mossa, Gorizia, Italy). The datalogger acts as a server, allowing remote control and data downloading. To increase the accuracy of the additional temperature sensors, calibration in an incubator (BINDER KB240 model, BINDER GmbH, Tuttlingen, GERMANY) was performed prior to their installation: the temperature in the incubator was measured through a reference Pt100 resistance temperature detector (Minco S7933 model, MINCO Products, Minneapolis, MN, USA) and compared with the values measured by the additional temperature sensors in the range 5–40 °C , revealing an accuracy of ± 0 . 2 K for 4-noks and SEMITEC sensors, and ± 0 . 2 K for the DICKSON sensor. We calculated the specific humidity uncertainty from the uncertainties of temperature and relative humidity sensors, with traditional propagation of error expressions ( ± 0 . 1 g/kg in the range 1.5–20 g/kg) [44].
Table A1 and Table A2 summarize the models and characteristics of all the monitoring sensors and Figure A1 shows the location of the ones placed in the rooms. In Table A1 and Table A2, the acronyms T and R.H. refer to temperature and relative humidity, respectively.
Table A1. Specifics of the SIEMENS sensors.
Table A1. Specifics of the SIEMENS sensors.
ModelPositionMonitored ParameterMeasuring RangeAccuracyAcquisition Period
QFA2001Room no. 1T0...50 °C ± 0 . 7 K in the range 15...35 °C15 min
R.H.0...100% ± 3 % in the range 0...100%
QAA24Room no. 2T−50...+80 °C ± 0 . 6 K in the range −5...30 °C15 min
Rooms no. 3 and no. 4
Room no. 5
QFM21160AHU dampersT0...50 °C ± 0 . 7 K in the range 15...35 °C15 min
R.H.0...100% ± 3 % in the range 0...100%
Table A2. Specifics of the additional sensors.
Table A2. Specifics of the additional sensors.
ModelPositionMonitored ParameterMeasuring RangeAccuracyAcquisition Period
4-noks
ZED-THL-M
Room no. 2
Rooms no. 3 and no. 4
T−40...+120 °C ± 0 . 2 K in the range 5...40 °C6 min
R.H.0...100% ± 3 % in the range 0...100%
I0...1000 lx ± 5 %
SEMITECRooms no. 1 and no. 2T−50...+110 °C ± 0 . 2 K in the range 5...40 °C6 min
NTCRooms no. 3 and no. 4
103AT-2Room no. 6
DICKSON
TM325
AHU entranceT−20...+70 °C ± 0 . 5 K in the range 5...40 °C15 min
R.H.0...95% ± 3 % in the range 0...95%
Figure A1. Sensor position in the four rooms. The round black marker identifies the QFA2001 sensor, the red triangle markers identify QAA24 sensors, the blue square markers identify 103AT-2 sensors (for the measure of temperature at 1.5 m and 2.5 m height), the orange diamond markers identify ZED-THL-M sensors, the inverted purple triangle marker identifies the 103AT-2 sensor for the measurement of temperature at 1.5 m height in the adjacent room.
Figure A1. Sensor position in the four rooms. The round black marker identifies the QFA2001 sensor, the red triangle markers identify QAA24 sensors, the blue square markers identify 103AT-2 sensors (for the measure of temperature at 1.5 m and 2.5 m height), the orange diamond markers identify ZED-THL-M sensors, the inverted purple triangle marker identifies the 103AT-2 sensor for the measurement of temperature at 1.5 m height in the adjacent room.
Buildings 06 00041 g011

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Figure 1. Example of graphical representation of P.I. Red markers identify data acquired during museum opening hours, while blue markers identify closing hours data.
Figure 1. Example of graphical representation of P.I. Red markers identify data acquired during museum opening hours, while blue markers identify closing hours data.
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Figure 2. Example of application of the proposed procedure in the case of simulation of several retrofit actions.
Figure 2. Example of application of the proposed procedure in the case of simulation of several retrofit actions.
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Figure 3. Monitored values of temperature and relative humidity in the RR. Red cross markers identify data collected during the museum opening hours, while blue circle markers identify data collected during closing hours.
Figure 3. Monitored values of temperature and relative humidity in the RR. Red cross markers identify data collected during the museum opening hours, while blue circle markers identify data collected during closing hours.
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Figure 4. Daily variation of temperature and relative humidity in the RRs. Each marker identifies the variation of temperature and relative humidity during an exhibition day (122 monitored days). Blue markers identify weekdays, red markers identify weekends. The gray area represents the suggested maximum daily span for the two microclimate parameters to preserve artworks.
Figure 4. Daily variation of temperature and relative humidity in the RRs. Each marker identifies the variation of temperature and relative humidity during an exhibition day (122 monitored days). Blue markers identify weekdays, red markers identify weekends. The gray area represents the suggested maximum daily span for the two microclimate parameters to preserve artworks.
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Figure 5. Internal and external temperature on a reference week. Thermal inertia reduces the effects of a wide temperature gap between days and nights.
Figure 5. Internal and external temperature on a reference week. Thermal inertia reduces the effects of a wide temperature gap between days and nights.
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Figure 6. Representation of the spatial homogeneity of temperature and relative humidity. Red markers refer to data acquired during opening hours, blue markers identify data during closing hours. The gray area represents the suggested values for spatial homogeneity.
Figure 6. Representation of the spatial homogeneity of temperature and relative humidity. Red markers refer to data acquired during opening hours, blue markers identify data during closing hours. The gray area represents the suggested values for spatial homogeneity.
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Figure 7. Space-temporal profile of temperature in the two rooms at the first floor. Point A of Figure 8 is at the origin of the x-axis, while point B is at x = 35 m.
Figure 7. Space-temporal profile of temperature in the two rooms at the first floor. Point A of Figure 8 is at the origin of the x-axis, while point B is at x = 35 m.
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Figure 8. Parameterization of the perimeter of the RRs.
Figure 8. Parameterization of the perimeter of the RRs.
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Figure 9. Number of visitors during the opening hours in the benchmark week.
Figure 9. Number of visitors during the opening hours in the benchmark week.
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Figure 10. Representation of the five indexes on a radar plot.
Figure 10. Representation of the five indexes on a radar plot.
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Table 1. Values of the proposed indexes resulting from the monitoring campaign of the RRs.
Table 1. Values of the proposed indexes resulting from the monitoring campaign of the RRs.
IndexValue
P.I.60 %
P.I.*98 %
L.S.I.100 %
D.S.I.48 %
S.H.I.74 %

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Schito, E.; Testi, D.; Grassi, W. A Proposal for New Microclimate Indexes for the Evaluation of Indoor Air Quality in Museums. Buildings 2016, 6, 41. https://doi.org/10.3390/buildings6040041

AMA Style

Schito E, Testi D, Grassi W. A Proposal for New Microclimate Indexes for the Evaluation of Indoor Air Quality in Museums. Buildings. 2016; 6(4):41. https://doi.org/10.3390/buildings6040041

Chicago/Turabian Style

Schito, Eva, Daniele Testi, and Walter Grassi. 2016. "A Proposal for New Microclimate Indexes for the Evaluation of Indoor Air Quality in Museums" Buildings 6, no. 4: 41. https://doi.org/10.3390/buildings6040041

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