Criteria for a comfortable indoor environment in buildings

1. 1. The major purpose of buildings is to provide a healthy and comfortable environment for occupants.

2. 2. The indoor environment is a complex system including factors like thermal, visual and acoustic conditions, indoor air quality, electromagnetic fields, static electricity and vibration.

3. 3. To obtain an indoor environment that is acceptable in terms of health as well as comfort, criteria for these factors need to be established.

4. 4. The present paper gives an overview of the criteria recommended in current existing standards and guidelines.

5. 5. As most studies to date have focussed on thermal conditions and indoor air quality, these two factors are described in more detail.

Thermal comfort studies in hungary

1. 1. Thermal comfort investigations have been carried out in Hungary from the second half of the 1970s, partly in laboratories and partly in the field, with humans and thermal manikins.

2. 2. The most important series of measurements have been made in the following fields: comparison of different heating systems from the point of view of thermal comfort, energy consumption and local discomfort; comparison of different heat and sunshine protection formulations; determination of acceptable temperature for different activities; checking different kinds of ventilation; examination of the thermal comfort conditions of disabled persons; determination of different clothing, e.g. the clo values of uniforms and polar suits, etc.

3. 3. This paper deals with the methods and results of laboratory and site examinations.

Indoor environmental study and post occupancy evaluation in an office environment

1. 1. The objective of this paper is to investigate the indoor environment from the viewpoint of interaction between physical environment and the human responses. The field survey has been conducted over 1 year.

2. 2. A continuous measurement has been carried out for 1 week and distribution of variables have been measured for 1 day.

3. 3. The attitude of workers was investigated by a questionnaire.

4. 4. As the result, average luminance represented more than 1000 lx in the new building, in contrast with less tha 300 lx in the existing building.

5. 5. There was a significant difference of the occupants' response to the light environment between the two buildings.

6. 6. Measured thermal conditions are on the edge of the ASHRAE comfort envelope in summer, and in the neighborhood of the lower dry limit of the envelope in spring.

7. 7. The occupants' evaluations were remarkably changed before and after the moving. The office environment is better than that of the factory.

Comparison of thermal responses with and without cold protective clothing in a warm environment after severe cold exposures

1. 1. Ten male students remained in a severely cold room (-25°C) for 20 min. thereafter, they transferred in a warm room (25°C) for 20 min.

2. 2. This pattern was repeated three times, total cold exposure time amounting to 60 min.

3. 3. In the warm room, the subjects removed their cold-protective jackets, or wore them continously.

4. 4. Rectal temperature, skin temperatures, manual performance and thermal comfort were measured during the experiment.

5. 5. Removing cold-protective jackets after severe cold exposure increased peripheral skin temperatures and reduced the discomfort in the warm room.

6. 6. However, these results were accompanied by a greater decrease in rectal temperature and manual performance.

7. 7. It is recommended that workers continue to wear cold-protective clothing in the warm areas outside of the cold storage to prevent decreases in deep body temperature and work efficiency caused by repated cold exposures.

Numerical analysis of thermal structure in heated room

1. 1. Two-dimensional numerical analysis is carried out on the thermal structure in an empty heated room of actual size under a steady state.

2. 2. Three types of heater, floor heating, side-wall heating and hot-air heating were used.

3. 3. The thermal structure in a room formed by each heating type is investigated in consideration of the energy transfer through the window of the room.

4. 4. The results indicate that floor heating is most suitable in a room without window from a viewpoint of the thermal comfort.

5. 5. In a windowed room, it is desirable that a heater should be located by the side of the window to prevent the cold draft.

Skin temperatures, thermosensory and pleasantness estimates in case of heterogeneity in the thermal environment

1. 1. Seven thermal conditions were imposed on male sitting subjects (slightly clothed: 0.6 clo).

2. 2. A thermal mannikin was also used to determine the exact operative temperature, T₀.

3. 3. Conditions were: uniform (UN: all parameters at 24.5°C, air velocity at 0.15 ms⁻¹), heated ceiling (HC at 45°C), heated floor (HF at 34°C), cold floor (CF at 14°C), two conditions of one cold wall at 6°C (CW1 and CW2 respectively with and without air temperature compensation) and increased air velocity (AV at 0.4 ms⁻¹).

4. 4. Local skin temperatures and answers to questionnaires were obtained.

5. 5. Skin temperature variations were affected by conditions and slight T₀ changes.

6. 6. Comfort judgments were fairly well related to T₀, especially when expressed as differences between actual non-uniform environment and the uniform one.

7. 7. It is concluded that, in case of non-uniform environments close to thermoneutral zone, thermal comfort or discomfort reflects the climate alterations better than the thermal sensation does.

Relationship between cerebrovascular disease and indoor thermal environment in two selected towns in Miyagi Prefecture, Japan

1. 1. This paper describes the results of an investigation of the relationship between mortality from cerebrovascular disease (hereafter called stroke) and the indoor thermal environment in two selected towns with different socioeconomic compositions: Shiwahime, an agricultura town with relatively high stroke mortality, and Karakuwa, a fishing town with relatively low stroke mortality, using a case-control research design.

2. 2. The measurement of the indoor thermal environments were conducted and the surveyed with a questionnaire during the winter of 1986.

3. 3. The findings are summarized as detailed below.

4. 4. Room temperatures in the control households were generally higher than those in the case households by up to 1.3°C.

5. 5. The thermal conditions of the housing in the case households were a little inferior to those in the control households.

6. 6. Despite much lower room temperatures than the so-called comfort temperature, members of both the case and the control households did not express feelings of being cold in the rooms.

7. 7. It is concluded, including the survey results from other literature, that improvements in the indoor thermal environment should receive more attention with respect of the reduction in stroke mortality, particularly in areas of cold climates.

A theory of evaluation applied to human-environment systems

1. 1. The writers present the general theory of evaluation that is being developed by their group.

2. 2. The evaluation of a human environment is a complex mental process.

3. 3. In an effort to express numerically the quality of an environment, one tends to oversimplify the complex aspects of it and the entailing problems in relation to its inhabitants.

4. 4. In this paper, some examples are taken in the evaluation of thermal environments, wherein much has been said and done in setting up numerical scales to express human comfort, and yet neither clear-cut explanations nor convincing logic seem to exist to terminate the argument over the widely scattered and sometimes seemingly contradicting experimental data.

5. 5. The writers suggest that many of the reasons for this confusion may be traced back to the oversimplified notion of evaluation.

6. 6. It is shown that there are various possibilities when looking at the scales of evaluation.

7. 7.|The nominal scale, least studied of all the four traditional scales, may be given a prominent place in evaluating a thermal environment. The pseudo-interval order scale is another example.

Transient response of the human-clothing system

1. 1. A transient clothing model which considers the effects of adsorption and thermal capacitance on the dynamic thermal response of clothing was developed.

2. 2. Moisture adsorption and desorption by the fabric are the major factors that affect the transient response of clothing.

3. 3. This moisture can come from evaporated sweat or from the environment.

4. 4. The clothing model was combined with a modified version of the two-node thermal model of the human body.

5. 5. The combined model shows that, during transients, the mix of latent and sensible heat flow from the skin may differ considerably from the corresponding heat flows from the clothing surface to the environment.

6. 6. The alteration of the heat flows can have a significant impact on the thermal response of the body by changing the sweat rate required to achieve the heat loss necessary to maintain thermal balance.

An experimental study on the effect of humidity on thermal sensations of people in summer

1. 1. The authors propose humidity reduction instead of lowering room temperature in order to reduce cooling syndrome.

2. 2. They conducted experiments with subjects in the rooms, one with controlling humidity to about 40% r.h. and another without humidity control. Air-conditioning system with humidity control has a greater promise in making a comfortable environment, even at the temperature as high as 30°C, in comparison with conventional means using temperature control alone.

3. 3. Relationship of actual mean votes on temperature sensation and comfort sensation with PMV and SET, respectively, suggests that Japanese people might be more sensitive to humidity than Westerners and so different methods from those used in the western countries should be required for human thermal environmental studies with respect to the hot humid summer in Japan.

Conventional vs CO2 demand-controlled ventilation systems

1. 1. The feasibility of controlling the ventilation system using the occupant-generated carbon dioxide as an indicator of ventilation rate and indoor air quality has been investigated in an eleven storey office building.

2. 2. The study compares the indoor environment created by two different types of ventilation control systems.

3. 3. The two ventilation systems tested consisted of: a conventional system controlled by outdoor temperatures, and a demand-controlled system regulated by indoor carbon dioxide concentration.

4. 4. The results show that the CO₂-based demand-controlled ventilation system does not worsen indoor air quality and thermal comfort. It was also noticed that an energy saving of 12% was achieved using the CO₂ control system.

5. 5. The occupants perceived that their productivity is proportional to their perception of the indoor environment; indicating that higher productivity rates can be achieved by better controlling the working environment above satisfactory levels.

A study on body temperature regulation and residential thermal environments of the elderly—I. whole country survey of residential thermal environment and evaluation methods: RTE-index

1. 1. As part of “research on environmental comfort,” that is, research which aims to make people's living environment more comfortable, we attempted to clarify the relation between the living environment of elderly people and physiological and psychological factors. We carried out a comprehensive study with a view to establishing comfort standards for the residential thermal environment, and for creating evaluation and control systems.

2. 2. The comfort of the living environment is closely related to the thermal environment and the temperature-regulation ability of the human body. This ability of the body to regulate temperature develops during childhood and recedes as the adult ages.

3. 3. We therefore carried out: (a) experiments on body-temperature regulation and on special characteristics of the body-temperature regulation of elderly people, (b) a nationwide survey of the actual residential thermal environments of elderly people and (c) a survey of the daily activities of elderly people, and how elderly people's physiological and psychological conditions change when they are engaged in these activities.

4. 4. As a result of these experiments and surveys, we were able to: (d) formulate standards for evaluation of the residential thermal environment and (e) numerically express the results of systematic evaluation of residential thermal environments of elderly people, by means of a RTE-index.

The effects of wind and thermal radiation on thermal responses during rest and exercise in a cold environment

1. 1. The purpose of this study was to investigate the effects of thermal radiation and wind on thermal responses at rest and during exercise in a cold environment.

2. 2. The experimental conditions were radiation and wind (R + W), no radiation and wind (W), radiation and no wind (R), no radiation and no wind (C).

3. 3. The air temperature was −5°C. Thermal radiation was 360 W/m². Air velocities were 0.76, 1.73 and 2.8 m/s. Rectal and skin temperatures, heart rate and oxygen consumption were recorded. Thermal and comfort sensations were questioned.

4. 4. There are no significant effects of thermal radiation and wind on the physiological responses except the mean skin temperature. There are significant effects on the mean skin temperature (P < 0.01) and thermal sensation (P < 0.05).

A pilot experiment on a method for evaluating acceptability of a daylit luminous environment

1. 1. We propose a hierarchical model as a hypothesis to evaluate comfort in lighting environments.

2. 2. The model consists of physical quantities such as stimuli, and visual sensations as the first response, and then overall evaluation.

3. 3. A pilot experiment in a side-lit classroom usng 147 subjects was made to examine this model.

4. 4. It was found that in the side-lit classroom the most effective answers for discrimination between “acceptable” and “not acceptable” were “the surface of desk was not considered dark” and “not to experience any reflectance of lighting on the sheet of paper on which they wrote”.

5. 5. Moreover all of the effective items relate to the task area, namely desk and blackboard, and this meant that subjects gave priority to workability in the classroom.

Physiological and psychological thermal response to local cooling of human body

1. 1. In order to investigate the thermoregulatory responses to the non-uniform thermal environment of the human body, the effects of cooling 10 different body regions were compared by circulating cool water to the neck, breast, back, loin, upper-arms, lower-arms, hands, thighs, legs and feet, respectively. Tympanic temperature, regional (11 sites) and mean skin temperature, and the thermal sensations were measured during experiment in which 30 min local coolings were applied on 5 female students in a climatic chamber controlled at 30°C and 50% r.h.

2. 2. The skin temperature beneath the cooling pad decreased in the order of arms, legs, hands and feet, and trunk.

3. 3. The temperature drop was significantly correlated with the thermal sensation of the region itself.

4. 4. On the other hand, the tympanic temperature increased once by any local cooling. The increase of it was correlated with the change of the general thermal sensation.

5. 5. Results of principal component analysis of skin temperature showed that the peripheral cooling affected the skin temperature in the limited peripheral regions, while the effects of cooling of the breast and the back extended to both the central and peripheral.

Diel thermoregulation of the crawfish Procambarus Clarkii (crustacea, cambaridae)

1. 1. In a diel cycle Procambarus clarkii has two preferred temperatures: 24.0 ± 0.15 SEM °C during the day and 26.7 ± 0.13 SEM °C at night.

2. 2. The preferred temperatures are independent from the weight of the organisms.

3. 3. In the photophase the animals are dispersed, in the scotophase they congregate.

4. 4. The crawfish seem to feed during the thermal interphases.

5. 5. Animals in a constantly dark condition maintain a diel preferendum of temperature.

Thermal resistance of the ciliary activity in the gills of the fresh water mussel Anodonta anatina

1. 1.|The thermal resistance of the activity of frontal cilia in the median gills of the fresh water mussel Anodonta anatina was studied.

2. 2.|The resistance acclimation appeared in 2 days in the gills of intact animals, but not in the isolated gills kept at 4, 14 and 24°C, for between 1 to 3 days.

3. 3.|Warm-acclimation increased the ACh sensitivity of the gills of intact mussels.

4. 4.|Isolation of the gills enhanced the thermal resistance.

5. 5.|ACh, choline and tetramethylammonium enhanced the thermal resistance in the isolated gills. whereas atropine and physostigmine diminished it.

6. 6.|It is concluded that in A. anatina the control if the thermal resistance is probably neural.

Sleep and the temperature field of the bed

1. 1. In order to find a correlation between the thermal conditions in bed and the quality of sleep, 5 young, healthy persons were tested in a thermal climate chamber.

2. 2. The sleep of each person was thoroughly monitored during 5 nights (stages I to IV, REM, awake) with continuous registration of 14 temperatures, 12 distributed in the bed, the distal skin temperature and the ambient temperature.

3. 3. Shortly after the test persons went to bed and shortly after they woke up their blood pressure and pulse were taken and they were asked to fill in a questionnaire.

4. 4. The results of this pilot project show a correlation between the quality of sleep and the variations of temperature and that larger fluctuations of temperature in the bed are connected to a shorter deep-sleep time.

5. 5. In order to investigate the thermal comfort it is recommended to undertake detailed analyses of the time and exact interplay between the local thermal conditions during sleep and changes of the sleep-EEG.

Comparison of thermoregulatory responses to heat between Japanese Brazilians and Japanese

1. 1. Eight male Japanese Brazilians and 11 male Japanese volunteered for this study. Each one sat on a chair for 45 min at 40°C (r.h. 50%).

2. 2. Then, they exercised using a bicycle ergometer in a semi-reclining position for 45 min at 40% of maximal oxygen uptake.

3. 3. Thermal and comfort sensation confirmed that Japanese Brazilians felt cooler and more comfortable in 40°C environment than the Japanese.

4. 4. Oxygen uptake, sweat rate and body weight loss for both groups were not significantly different.

5. 5. Forearm blood flow and heart rate for Brazilians were significantly lower than those for Japanese.

6. 6. Skin temperature at chest region for Brazilians was found to be significantly higher than that for Japanese.

7. 7. Thus the thermoregulatory responses observed in Japanese Brazilians may be largely attributed to the climate in their native places located on the Tropic of Capricorn.

8. 8. These results may indicate that environment condition is the important factor in determining the thermoregulatory responses.

Estimation of thermal sensation using PMV and SET under high air movement conditions

1. 1. Our previous experimental results showed the thermal sensation vote was much less than the values of PMV and SET^* at air velocities above 0.5 m/s.

2. 2. The method to modify SET^* is presented from the results of subjective experiments taking account of decrease in clo value of summer clothing and decrease in skin wettedness due to increased air velocity.

3. 3. Thermal resistance under increased air movement on a standard summer clothing ensemble was measured. Basic thermal insulation of the summer ensemble was reduced by 25% at air velocity of 1.0 m/s.

4. 4. Thirty-two subjects were exposed at operative temperatures of 27 and 30°C under 1 m/s air movement in order to determine the amount of skin diffusion. Measured evaporation heat loss from skin surface was much smaller at air velocity of 1 m/s than that predicted by SET^*.

5. 5. Estimated thermal sensation vote using modified SET^* agreed well with our previous experimental results under different air velocities for the same clothing.