This paper presents a recent status quo of HVAC airside design for the airconditioned spaces under holistic approach. The present review summarizes the current status, future requirements, and expectations. It has been found that, the experimental investigations should be considered in the new trend of energy investigations, not to merely to validate the numerical tools, but also to provide a complete database of the airflow characteristics in the airconditioned spaces. Based on this analysis and the vast progress of computers and associated software, the artificial intelligent technique is sought as a prominent competitor candidate to the experimental and numerical techniques. Finally, the researches that relate between the different designs of the HVAC systems and energy consumption should concern with the optimization of airside design as the expected target to enhance the indoor environment.
In attempts to adequately design an optimum HVAC airside system that furnishes comfort and air quality in the air-conditioned spaces with efficient energy consumption is a great challenge. Air conditioning identifies the conditioning of air for maintaining specific conditions of temperature, humidity, and dust level inside an enclosed space. The conditions to be maintained are dictated by the need for which the conditioned space is intended and comfort of users. So, the air conditioning embraces more than cooling or heating. The comfort air conditioning is defined as “the process of treating air to control simultaneously its temperature, humidity, clean liness, and distribution to meet the comfort requirements of the occupants of the conditioned space” [
In the holistic approach, the totality of the effects of the heat sink and sources in the building and the technical building systems that are recoverable for space conditioning, are typically considered in the calculation of the thermal energy needs.
As the technical building thermal systems losses depend on the energy input, which itself depends on the recovered system thermal sources, iteration might be required.
The calculation procedure can be devised as follows:
1) Sub-system calculations are first performed as per prevailing standards and that will be followed by determination of the recoverable thermal system losses;
2) The recoverable thermal system losses are then added to the other recoverable heat sources already included (e.g. solar and internal heat gains, recoverable thermal losses from lighting and/or other technical building systems like domestic hot water) in the calculation of the needs for heating and cooling;
3) Thermal energy needs for heating and cooling are then recalculated;
4) Iterations are performed from step 1 until the calculated changes of the energy needs between two successive iterations are less than a defined limit (e.g. 1%) or stop calculations after a specified number of iterations;
5) Continue to calculate the difference between the energy at the start of the iterations and the end; these are the recovered system thermal losses.
Thermal comfort is that condition of mind that expresses satisfaction with the thermal environment. Because there are large variations, both physiologically and psychologically, from person to person, it is difficult to satisfy everyone in a space. The environmental conditions required for comfort are not the same for everyone. Extensive laboratory and field data have been collected that provide the necessary statistical data to define conditions that a specified percentage of occupants will find thermally comfortable. Section 5 of this standard is used to determine the thermal environmental conditions in a space that are necessary to achieve acceptance by a specified percentage of occupants of that space. There are six primary factors that must be addressed when defining conditions for thermal comfort. A number of other, secondary factors affect comfort in some circumstances [
The temperature regulatory centre in the brain is about 36.8˚C at rest in comfort and increases to about 37.4˚C when walking and 37.9˚C when jogging [
Many of the HVAC applications suffer from the poor distribution of the indoor air temperature and relative humidity as well as the incorrect airflow velocities. This poor distribution arises from the poor airflow distribution and the presence of the thermal drift due to the buoyancy effect.
In the present time, most of researches recommend the experimental and numerical simulation as the perfect tools to obtain the optimum design. The optimization procedure of the HVAC airside design depends on the predictions of the air temperature distribution based on the simulation of different parametric designs using experimentally verified numerical tools. The influence of various ventilation strategies and vapour generation rate on the characteristics of temperature and moisture distribution is investigated [
Airside design and room furnishing were found influential in order to ensure a comfortable environment, especially in the displacement ventilation configuration [
The comfort conditions depend on many factors beyond the indoor air temperature, relative humidity, and airflow velocity. Comfort conditions depend also on the air distribution pattern and the air movement [
Most of guidelines consider the air quality is the result of a collaborative effort of environmental conditions those presented in the introduction section. Indeed, in the present literature the air quality is specified by the result of a collaborative effort of the pressure relationship, air movement efficiency, and contaminant concentration. These conditions play an important role to achieve the optimum air quality. Simply, design of ventilation system must, as much as possible, provide air movement from the clean to the less-clean areas. This rule requires a great careful to design the airside system and to select the design of airside system of the neighbourhoods. There are relative interactions between the conditioned neighbouring spaces. The air distribution and movement efficiency can be considered as the indicator of the comfort and air quality simultaneously. There are several important considerations that characterize the air distribution in airconditioned spaces, namely first, the flow is generally
turbulent and buoyancy effects are often significant. Then the transverse transport effects are of particular interest in these flows. Combined heat and mass transfer processes prevail in that case and coupled transport mechanisms are generally present. Undesirable airflow between rooms and floors is often difficult to control because of open doors, movement of staff and patients, temperature differentials, and stack effect. While some of these factors are beyond practical control, the effect of others may be minimized by terminating shaft openings in enclosed rooms and by designing and balancing air systems to create positive or negative air pressure within certain rooms and certain areas.
Contaminants can be classified in four broad headings, each of which represents a wide variety of pollutants; Organic & Inorganic Compounds; Particulate Matter; and Biological Contaminants. It should be understood that these classifications are intended to facilitate the categorization of contaminants. Although the pollutants are classified into these categories, certain contaminants may belong to two or more classifications, depending upon their nature. The classification of organic compounds represents chemical compounds that contain carbon-hydrogen bonds in their basic molecular structure. Their sources can be either natural products or synthetics; especially those derived from oil, gas, and coal. Organic contaminants may exist in the form of gas (vapour), liquid or as solid particles in the atmosphere, food and/or water. Inorganic compounds are those which do not contain carbon-hydrogen bonds in their molecular structure.
The danger of particulate matter is their ability to become contaminated by other ambient sources, increasing health risks to individuals who are exposed to Respirable Suspended Particles (RSP). Particles following into this category are, usually, less than 10 mm in aerodynamic diameter. As mentioned previously, particles smaller than 5 mm are capable of bypassing the respiratory defences. Biological contaminants are generally referred to as microbes or micro organisms. Biological contaminants are minute particles of living matter produced from a variety of sources. The variety of biological compounds that may be present in the ambient environment is immense. Sources of pollution exist in both the internal and external environment. The air quality is controlled by removal of the contaminant or by dilution. ASHRAE [
The contaminant concentration mainly depends on the two factors, air pressure relationship, and the air movement efficiency. So the optimum design of these two factors leads to accepted concentration and safe distribution of the contaminant. Actually, most of guidelines, known to date, don’t restrict any airside design for each application. This gives a large tolerance and many designs alternatives, which are not totally perfect.
The comfort and air quality is investigated with the aid of experimental and numerical techniques, to represent the relation between the thermal conditions and the air quality [
Air movement efficiency is mainly based on two factors, which are; the air pressure relationship with the other neighbourhood spaces, and the airside design. Differential air pressure can be maintained only in an entirely sealed room. Therefore, it is important to obtain a reasonably close fit of all doors and seal all walls and floor penetrations between pressurized areas. This is best accomplished by using weather stripping and drop bottoms on doors. The opening of a door between two areas instantaneously reduces any existing pressure differential between them to such a degree that its effectiveness is nullified. When such openings occur, a natural interchange of air takes place between the two rooms due to turbulence created by the door opening and closing combined with personal ingress/egress.
Energy crisis in the early 1970s forced the development of energy conserving strategies in a variety of industries. Sustainability and energy efficiency continue to be strong issues in this time of limited resources. Therefore, the implementation of energy conserving strategies in the HVAC systems must be balanced with occupant comfort and health. Few guidelines gave specific recommendations about the energy saving in the HVAC systems, but these recommendations don't meet all requirements and design varieties. Indeed, in the hot and humid climate the outdoor conditions play important role in the energy consumption.
Till now, the guidelines and design standards don’t provide restricted utilization strategies of the conditioned air in the spaces. Indeed, this situation creates several inefficient systems and consequently expensive energy invoice. In some critical facilities, such as hospitals, HVAC designers face the problem of balancing between the healthy conditions and the energy utilization. The assessment of the overall energy performance of a particular building, including the technical building systems, comprises a number of successive steps, which can be schematically visualized as a pyramid.
The relation between the HVAC system designs and the optimum conditions and optimum energy utilization is still under investigation up today. In recent researches [
As the optimization of the energy consumption is new trend, the achievement of this level needs new investigation trend in the scientific researches. Actually, the energy utilization mainly depends on the optimum utilization of the conditioned air in the conditioned spaces. Sets of common terms, definitions and symbols are essential for all segments from top to bottom. These cover terms such as energy needs, technical building systems,
auxiliary energy use, recoverable system losses, primary energy and renewable energy.
In theory, if properly applied, every system can be successful in any building. However, in practice, such factors as initial and operating costs, space allocation, architectural design, location, and the engineer’s evaluation and experience limit the proper choices for a given building type. Heating and air-conditioning systems should be: simple in design and, of proper size for a given building, of generally fairly low maintenance; of low operating costs; of optimum inherent thermal control as is economically possible. Such control might include materials with high thermal properties, insulation, and multiple or special glazing and shading devices.
An example of Commercial buildings applications is provided here for libraries and museums.
In general, libraries have storage areas, working and office areas, a main circulation desk, reading rooms, rare book vaults, and small study rooms. In general, museums would have exhibit areas, work areas, back offices, and storage areas. Some larger museums may have souvenir shops, a restaurant or cafeterias, etc.
Many libraries, especially college libraries, operate up to 12 h per day and may run the air conditioning equipment about 4200 h per year. Such constant usage requires the selection of heavy duty, long-life equipment, which requires little maintenance. Museums are generally open about 8 to 10 h per day, 5 to 7 days per week. The ambient conditions should not vary in temperature or relative humidity. The conditions should remain constant 24 h per day, year-round. Cold or hot walls and windows, and hot steam or water pipes should be avoided. Object humidity may be destructive, even if the ambient relative humidity is under control.
Sun Gain. Libraries and museums usually have windows, sometimes of stained glass, and skylights-more in traffic areas, than in book stacks or storage areas. Care must be taken to minimize the effects of the sun; shortwave (actinic) rays are particularly injurious. Heat gain from skylights, often over artificially lighted frosted glass ceilings, can be reduced by a separate forced ventilation system.
Transmission. In winter, effects on objects located close to outside walls and possible condensation of moisture on the objects and the surface of outside walls must be evaluated. In summer, possible radiant effects from exposure should be considered.
People. Some areas may have concentrations as high as 1.0 m2 per person, while office space will have closer to 10 or 15 m2 per person, and book stack areas up to 100 m2 per person.
Lights. Careful analyses of the required lighting intensity should be made in various rooms and in view of day lighting availability.
Stratification. In reading rooms, large entrance halls, and large art galleries with high natural or false ceilings, air temperature may stratify.
All-air ducted systems are preferred in library public areas, careful evaluation of relative humidity is essential. This is also true for museums, because exhibit items are generally irreplaceable. In museums, people loads vary, depending on whether there is a new exhibit, the time of day, weather, and other factors. Thus, individually controlled zones are required to maintain optimal environmental conditions. Attempts to establish a modular system for partitions have been only partially successful because of the wide range of sizes of items in the exhibits. In art museums, particularly, partitions may create local pockets with hot air supply or exhaust; transfer grilles may be placed in the partitions to obtain some air flow movement. Another problem is the location of room thermostats and humidistats.
Many old manuscripts, books and artifacts have been damaged or destroyed because they were not kept in a properly air-conditioned environment. The need for better preservation of such valuable materials, together with a rising popular interest in the use of libraries and museums, requires that most of them, whether new or existing, be air-conditioned. Air-conditioning problems for museums and libraries are generally similar, but differ in design concept and application.
In an average library or museum, less stringent design criteria are usually provided than for archives, because the value of the books and collections does not justify the higher initial and operating costs. Low-efficiency air filters are often provided. Relative humidity is held below 55%. Room temperatures are held within the 20˚C to 21.5˚C range. Archival libraries and museums should have 85% or better air filtration, a relative humidity of 35% for books, and temperatures of 16˚C in book stacks and 20˚C in reading rooms.
Museums contents and collections reaction to room conditions should be carefully considered and critically examined. For example, paper used in books and manuscripts prior to the eighteenth century is very stable and is not significantly affected by the room environment. For archival preservation, this paper should be stored at very low temperatures. It is estimated that for each 5˚C dry bulb the room temperature is lowered, the life of the paper will double, and that any humidity reduction will also lengthen the life of paper.
The temperature and, particularly, the relative humidity of the air have a marked influence on the appearance, behaviour, and general quality of hygroscopic materials such as paper, textiles, wood, and leather, because the moisture content of these substances comes into equilibrium with the moisture content of the surrounding air. The object humidity is usually defined as the relative humidity of the thin film of air in close contact with the surface of an object and at a temperature cooler or warmer than the ambient dry bulb. If artifacts are permitted to cool overnight, the next day they will be enveloped by layers of air having progressively higher relative humidities. These may range from the ambient of 45 to 60% to 97% immediately next to the object surface, thus effecting a change in material regain or even condensation. This, combined with the hygroscopic or salty dust often found on objects recovered from excavations, can be destructive.
Air-conditioning equipment should be treated with sound and vibration isolation to ensure quiet comfort for visitors and staff as per the ASHRAE standards and local environmental laws.
The evaluation indices of the comfort, air quality, and energy utilization efficiency can be divided to two main categories, empirical indices based on the experimental techniques, and numerical indices based on the numerical techniques. The most common indices provide the required evaluation of the air characteristics at individual positions (or in other scope, at individual points) in the indoor environment.
Until now, the evaluation of the comfort, air quality, and energy utilization efficiency performed only at individual position (locally evaluation). Still there is no general global evaluation index for several characteristics such as the airflow movement and the contaminant concentration and its influence on the occupancy health. Actually, the air flow distribution pattern plays the role of global evaluation index up today. On the other hand, there is noglobal evaluation index capable of evaluating comfort, air quality, and energy utilization efficiency simultaneously. Actually, this global index will aid the HVAC designers to achieve the optimum design according to the optimum indoor air quality levels [19,20].
Energy efficiency is better characterised in buildings through the energy efficiency ratio EER. An index that is
mandatory in all air conditioning and refrigeration system. Defined as the useful output divided by the energy input, a form of COP (coefficient of Performance). The International standards dictate that EER is greater than a preset value in an energy label as shown here in
Countries [
The minimum efficiencies of mechanical systems are commonly known as MEPS and are also set to rationalize the energy use in fossil fuel equipment and to reduce the carbon footprint. Assessment of the energy performance of the buildings as a whole are generally through the energy rating systems, an example is the GRPS (green Pyramids Rating System), [
The GPRS Green Pyramid Category Weightings are as specified as follows:
1) Sustainable Site, Accessibility and Ecology 10%;
2) Energy Efficiency 20%;
3) Water utilization Efficiency 30%;
4) Materials and Resources 10%;
5) Indoor Environmental Quality 10%;
6) Management 10%;
7) Innovation and Added Value 10%.
The first group of assessment points go to site and ecology. These were set to encourage development in desert areas, redevelopment in informal areas and avoid projects which negatively affect archaeological, historical and protected areas. This is also to minimize pollution and traffic congestion from car use and to conserve non-renewable energy by encouraging public and alternative transport. Ultimately this would minimize the environmental impact of the project on the site and its surroundings; to protect existing natural systems, such as fauna and flora (including wildlife corridors and seasonaluses), soil, hydrology and groundwater from damage and to promote biodiversity. 10 points were given for that group, while 20 points for energy efficient building designs utilizing the concepts highlighted here and by Van Dijk et al. [16,17] and Khalil [
dedicated by human thermal comfort and acoustics, natural and artificial lighting were given 10 points as well. Proper management and innovation harvest the remaining 20 points. With these rating systems a balance of all the important and influential factors was accounted for. The Building would be certified green if attaining a minimum of 80 points and will be just certified if attaining up to 49 points as indicated in
The final credits are calculated and are categorized within the following rating:
GPRS Certified: 40 - 49 credits;
Silver Pyramid: 50 - 59 credits;
Gold Pyramid: 60 - 79 credits;
Green Pyramid: 80 credits and above.
As the optimization of the energy consumption is new trend, the achievement of this level needs new investigation trend in the scientific researches. Actually, the energy utilization mainly depends on the optimum utilization of the conditioned air in the conditioned spaces. Sets of common terms, definitions and symbols are essential for all segments from top to bottom.
The target of this work is to highlight procedures to control the alteration, repair, maintenance and operation of existing building sites and the alteration to building site improvements where additions are made to, or changes of occupancy occur within, the existing buildings on the site. Building sites shall be operated and maintainedin conformance with the national green building code. The owner or the owner’s designated agent shall be responsible for the operation and maintenance of building sites. The requirements of the green building code shall be incorporated and implemented in new and renovation work. Alterations and repairs to building sites shall comply with the code provisions. Building materials used for building site development shall comply with the re-
quirements of the code Materials and systems already in use on a building site in conformance with the requirements or approvals in effect at the time of their installation shall be permitted to remain in use unless determined by the code official to be dangerous to the environment, life, health or safety. Where such conditions are determined to be dangerous to the environment, life, health or safety, they shall be mitigated or made safe.
The author would like to acknowledge the technical support of his colleagues at HBRC and in Particular Prof. Dr. G. B. Hanna, Dr. A. M. Medhat. Author acknowledges the assistance of his colleague Dr. Ramiz Kameel who helped with the analyses.