The green building fad plays a key role in promoting energy savings, but does it do so at the expense of human health?

In the last 6 years, there has been a significant shift in the U.S. Green Building Council LEED rating system. This shift has been marked by an increased emphasis on energy efficiency over indoor environmental quality (IEQ). This shift was first noted in LEED 2009, with the IEQ Category decreasing from 71.7% (second most) available points to 13.6% (barely third most) points, while the energy category increased from 24.6% to 31.8%. These ratings remain similar in LEED version 4. The only requirements regarding IEQ according to LEED are related to controlling the environmental tobacco smoke and providing the ASHRAE minimum amount of outdoor air.   This is the precedent for many other rating systems as well. 

If your air quality isn't up to par, one of the reasons below could be your culprit. 

Reasons for Poor Indoor Air Quality 

1. Non-Cleanable Interior Ventilation Surfaces 
2. Too Much Outdoor Air 
3. Cellulose Materials In High Water Use Areas
4. Roof Pollutant Sources Near Air Intakes 
5. Construction of Dirt and Debris Left on New Building Ventilation Surfaces 
6. Ventilation Fan Cycling On And Off 
7. Using Hazardous Materials in New Buildings 
8. Building Envelope Issues 
9. Air Handling Units With Poor Access
10. AHU Condensate Lines in Bad Locations or Improperly Installed 
11. Inadequate and Improper Use of Products Identified as Low Emitting 
12. Inappropriate Air Quality Evaluation Parameters and Methods for New Green Building Pre-occupancy 
13. Depending Too Much on Building Flush Out 
14. Filers Not Performing Per Rating Due to AHU Design Or Maintenance/Installation Issues 
15. Installing Drywall Before Roof Or Windows are in Place 
16. Not Designing or Constructing for Radon Mitigation 
17. Exposed Fiberglass Insulation In Return Air Plenum Above Ceiling Tiles 
18. Plumbing Construction Defects 
19. Ventilation Supply and Return Short Circuits
20. Not Negatively Pressurizing Rooms with Pollutants Source 

For More Information: "20 Reasons your Green Building may not have Green Indoor Air." Engineered Systems. January 2014. 

Sick? Your Air Conditioning Could be the Cause

Is your air conditioning making you and your family sick? 

For many, air conditioning is the embodiment of comfort living, particularly in the summer months when the heat index can be unbearable.  But could your air conditioning be causing more harm than good? 

According to the Director of the Common Cold Centre at Cardiff University in Wales, Professor Rob Eccles, exposing the body to extreme temperatures could actually make you sick. 

 Here's Why: 

As warm blooded animals, the human body's optimal temperature is around 98 degrees Fahrenheit. In extreme cold environments the body will fight to maintain this body temperature.

Cold temperatures cause blood vessels
 to  constrict and diminish number 
of white blood cells.

One of the body's defense mechanisms against the cold is the thermal regulator in the brain. As soon as it receives a message from the temperature sensors in the skin, the blood vessels are alerted to constrict. This immediately causes a person's skin to become ashen or mottle, which is quickly followed by shivering in order to generate heat to raise the body temperature. 

As a result, the blood vessels in the nose and throat, both of which are favorite locations for bacteria and viruses to hide, will constrict therefore limiting blood flow. 

As the blood flow diminishes, the white blood cells that typically fight bacteria and viruses do too. This allows these dormant risks to develop in to colds. Low blood flow to the throat means that there isn't enough white blood cells to ward off infection. 

Sweating exacerbates the problem because it keeps the body colder. This makes it more of a challenge for the body to maintain its optimal temperature. 

Going from hot to cold environments could put
you at risk for a cold. 

Professor Eccles emphasizes that a cold will only develop if the bacteria or virus is already present in the body.  

This phenomenon occurs when going from a hot environment to a cold atmosphere not the other way around. Though, Professor Eccles recommends limiting the number of times you go from a cold environment to the hot outside as when your body acclimates to the heat and steps back inside the chilling cycle will begin again. 

This article was derived from the headline "Does Going from Hot to Cold Cause Colds?" which appeared on August 20, 2013, in the U.S. edition of The Wall Street Journal. 

How to Avoid Costly Air Quality Problems

           As I approached the club's main entrance, the automatic doors opened and a rush of air filled the lobby. I noticed the receptionist's hair rustle as she placed her hand on the papers on the desk to keep them from blowing on the floor. As I waited for the club manager, I could smell a slight mustiness in the air, furnishings felt sticky, and the air conditioning diffusers were sweating. Discussions with the club manager revealed that members complained frequently of being warm. The card rooms were stuffy and the humidity was so high in the locker rooms that mold was growing on some of the golf shoes. Further investigation revealed that the building was operating under a severely negative pressure condition.

Few things damage a clubhouse more profoundly than a negatively balanced HVAC system. It is most acute in humid, Southern climates.Operating a clubhouse with severely negative pressure can set off an avalanche of bad things that can result in serious indoor air quality problems over time. Correcting these problems after the microbial growth has started can be a very expensive process.The good news is that these problems can be averted with proper HVAC equipment selection and a good maintenance program.

How it Happens

      A negatively pressurized building draws unconditioned outside air through every available opening. The lobby area is usually the first to feel the impact. Automatic doors opening and closing allow a huge amount of humid air to enter with each cycle, making the receptionist sweat in the summer and freeze in the winter.The lobby diffusers begin to sweat and soak into the surrounding hard ceiling where mold starts to grow.The humidity level everywhere inside the building rises.

Members feel warm because the evaporative cooling they get naturally from their skin under lower humidity conditions is reduced, so they call the facilities manager to lower the temperature in the space. Under elevated humidity conditions, the temperature usually needs to be maintained at 68-69 degrees for the majority of people to feel comfortable. When this happens, the building is in its most dangerous state for microbial growth. When the interior temperature of the building maintained is lower than the outdoor dew point temperature for a significant amount of time, water vapor will be drawn through the exterior walls. It usually condenses on the first impervious membrane it encounters. This can be the back of the wall board or some vinyl wallpaper. Once condensation occurs, mold, and the inevitable remediation costs, will not be far behind.
              Negative pressure is a condition found in clubhouses with alarming frequency. Clubhouse buildings, by their nature, employ significant numbers of constant volume exhaust fans. Usually the largest component of exhaust is located in the food service facility. It is not unusual for a major cooking facility to be exhausting 10,000-20,000 cubic feet per minute (CFM) of air from the cooking hoods. A properly balanced cooking hood system should be replacing approximately 80 percent of the exhausted air with fresh make-up air. This is usually supplied through a make-up air plenum located near the front of the hood. This leaves a net exhaust of 3,000-4,000 CFM from the kitchen area.

Add to this another 600-1,200 CFM from the dishwasher hood and another 500-1,000 from a display kitchen hood, and the aggregate exhaust can be in excess of 6,000 CFM from the food preparation area alone. Another 2,000-3,000 CFM likely will be added from the locker rooms and restrooms throughout the building. The net result is that a large clubhouse building can have a constant volume exhaust rate of 8,000-10,000 CFM. This is particularly problematic for clubhouse buildings because the exhaust rate is large compared with the square footage of the building, and units are run continuously.
To counteract the exhaust and maintain a neutral or preferably positive pressure in the building, an offsetting amount of outside air must be introduced. Because exhaust fans are at

Operating a clubhouse building with severely negative pressure can set off an avalanche of bad things that can result in serious indoor air quality problems over time.

constant volume (which means they run continuously with no variation in the flow rate), the make-up air also must be introduced in a similar manner.This is done through the air conditioning system- and therein lies the challenge.In humid Southern climates the humidity in the outside air is normally very high and goes through dramatic seasonal swings.The HVAC engineer is faced with the daunting task of providing a stable temperature and humidity condition inside the building with wildly varying outdoor temperature and humidity conditions.

Air conditioning systems maintain inside conditions normally by increasing or decreasing the air flow and/or the supply air temperature.There are a number of techniques engineers use to accomplish this task and some are more successful than others. Chilled water systems can use variable frequency drives on the air handlers to vary the air flow. Direct expansion systems, such as package roof top units, simply turn on and off based on the sensible demand. The challenge for clubhouse engineers is that neither of these methods are effective in maintaining neutral or positive pressure in the building when exhaust fans are running continuously.

What to Do?

Clubhouse buildings must be equipped with a dedicated 100 percent outside air pre-conditioner. This unit runs continuously and supplies a constant and equal volume of dehumidified outside air to the building. It should be interlocked to run when the cooking hood exhaust system runs. There are a number of manufacturers that produce this type of equipment. It can be done with chilled water or direct expansion equipment. The units are designed to remove large amounts of moisture from the air stream.

 The units also include a method of reheating the supply air to prevent overcooling the space. It can be done with a non-energy absorbing hot gas reheat coil or with electric heat. Sizing the unit is a subject of design as long as it can deliver an amount of outside air at least equal to the exhaust.

A very useful system to include is a cooking hood variable air volume system. This system uses variable frequency drives on the exhaust and make-up air fans to slow the exhaust rate down when there is no significant cooking being done on the line. The reality is that a fairly small amount of the hood's total daily operating time involves heavy grease and smoke-laden cooking. There is no need for the hood to be running full speed when there is no smoke being generated.

To provide comfort at the cooking line, it is advisable to provide temperature control for the hood make-up air. In the summer, the ambient air temperature can easily be 95 degrees plus. Dumping this air down on the chef at the cooking line can raise the temperature in this area to 110 degrees. This alone frequently drives the chef to turn the make-up air fan breaker off. Cooling half of the makeup air stream to 55 degrees and re-mixing with the remaining air will drop the temperature from 95 degrees in the summer to 75 degrees and 70-80 percent humidity.

With the basic equipment in place, the unit needs to be maintained regularly. All of the above discussed equipment can fail due to lack of maintenance and put the building into a negative air balance. The problem is that the equipment can fail and not be immediately noticed until serious problems start to develop. An aggressive maintenance program will keep the building properly balanced and healthy for many years.

About the Author

Robert Davenport is president and principal Engineer of RGD & Associates Inc., a South Florida firm specializing in clubhouse construction and renovation projects. 

 For more information about our services, visit RGD Consulting Engineers corporate website.