HVAC Engineering Clarendon Park Chicago, IL2018-10-29T10:58:59+00:00

What Can Our HVAC Engineers in Clarendon Park Chicago Do For You?

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When you’re searching for a reliable HVAC Chicago? The one to go to is New York Engineers. Not only for HVAC Chicago but also Architectural Engineering and Sprinkler Design Engineering throughout Clarendon Park Chicago. Contact us at (+1) (312) 767.6877

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Over the last decade the majority of real estate investors throughout Plattsburgh, New York already know that NY-Engineers.Com is the engineering company to contact if you’re searching for Mechanical Engineering in New York City. What many local construction companies have not realized is the NY-Engineers.Com is also your top choice if you are searching for HVAC Engineering services in Clarendon Park Chicago, IL. Those who need to understand more about what Clarendon Park Chicago HVAC design engineers do? This really is a unique trade which inclides an extensive selection of responsibilities. An HVAC design personel will be asked to get through a variety of challenges to eliminate the core issue. This task requires distinct talent, competence, and the opportunity to deal with time prudently.

The moment an HVAC personel is licensed to function, they are going to sign on with an engineering company and begin to operate various heating, cooling, and refrigeration systems. Their role is always to draw up new and replacement selections depending on their client’s requests. Each client will have an exclusive set of needs whether or not it is related to constructing codes or personal performance expectations. Using all of this information, the engineer sets off on a trek towards building something which is eco-friendly, energy-efficient and well suited for the location it’s going to be utilized in – (industrial, commercial or residential. They are usually accountable for the initial creations and managing the actual installation.

On the whole, an HVAC design engineer in Clarendon Park Chicago is going to be seen working with a design business or perhaps in a consulting team according to their numerous years of skill. Many engineers move in to a consulting job as they become older and acquire a better idea of what is expected of them.

Comparing HVAC Technician Versus HVAC Engineer

HVAC Engineer and HVAC Technician are usually confused with each other. Nevertheless, they do have separate job functions when it comes to managing HVAC systems. It is essential to are aware of the difference both as a client also as a professional

An HVAC technician in Clarendon Park Chicago carries a more practical job, meaning they are often seen on the way to a client’s house to deal with their existing system. They often handle the installations, repairs, and over-all upkeep which is needed every once in awhile. Almost all of their jobs are done together with the client, which implies they must learn how to interact with people properly.

By having an HVAC engineer, they are responsible for creating a whole new HVAC system and ensuring that it fits just what a client is after. It has to fit what the home owner wants whether or not it involves their setup, property, or anything else linked to new system. They are also introduced to consult on HVAC creations to make certain things are in step with the highest standards. This is the reason they can wind up hanging out in consulting firms or at neighborhood engineering firms. This is the distinction between these occupation; HVAC Technician vs HVAC Engineer. There is only so much you can save this page if you would like more info on the HVAC Engineering services in Clarendon Park Chicago, IL by NY-Engineers.Com we invite you to stop by at our Clarendon Park Chicago Energy Modeling blog.

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How HVAC Engineers Make Indoor Air Quality Better than Outdoors

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When building managers are considering hiring HVAC engineers to make improvements for their HVAC systems, energy efficiency tends to receive more attention that indoor air quality (IAQ). This can be explained by the fact than saving energy impacts the bottom line directly, while the benefits are not so evident for indoor air quality. However, IAQ can be just as important as energy efficiency, if not more, and has a significant impact on productivity, comfort and most importantly human health. A key example of what poor air quality can do is Sick Building Syndrome, when the health of occupants deteriorates in proportion to how much time they spend indoors and improves when they are away.

To improve indoor air quality, two complementary approaches are necessary, and HVAC systems play a very important role in both cases:

  • Maintaining the physical properties of indoor air at values that are optimal for human occupancy. The three main variables to control are temperature, humidity and air speed. In the case of temperature, it is also important to ensure stability – if the average temperature value is as required, but fluctuates between warm and cool, it can cause both discomfort and health issues.
  • Keeping indoor air free from hazardous pollutants such as carbon monoxide, radon, mold spores, dust, pollen and volatile organic compounds (VOCs). These compounds must be monitored and eliminated. Unpleasant odors should also be controlled; they don’t have the same health impact as direct exposure to pollutants, but can cause great discomfort.

Indoor air quality benefits from a properly designed HVAC system and using sensors that detect pollutants. Of course, all of this should be complemented with habits that enhance IAQ, and there are various plant species that improve IAQ by removing common pollutants.

Controlling the Physical Properties of Indoor Air

The functions of an HVAC system go far beyond heating indoor air in the winter and cooling it in the summer; it is also necessary to control humidity and air speed to provide comfortable and healthy conditions for humans.

Issues with air speed and relative humidity often arise when HVAC systems are designed by HVAC engineers with only temperature in mind. Oversized cooling equipment tends to cause excessive humidity, while oversized heating equipment tends to dry the air more than necessary. In both cases, indoor air draftiness is also common because fan horsepower is too high for the application.

Temperature

Temperature issues are common when heating or cooling equipment is oversized, since the unit tends to run on a short cycle and causes the temperature to fluctuate above and below the desired value. Properly-sized HVAC equipment provides a more constant air temperature and lasts longer, since it is not subject to the wear caused by frequent cycling.

Relative Humidity

ASHRAE recommends that indoor air relative humidity be kept at values within the range of 30 to 60 percent. When relative humidity falls outside this range there are several consequences that are detrimental for indoor air quality:

  • Low relative humidity tends to irritate the respiratory tract, eyes and skin.
  • On the other hand, high relative humidity can cause air conditioned spaces to feel cold and humid like a refrigerator, which causes discomfort and potentially health issues. Humidity also stimulates the growth of fungi and bacteria.
  • Viruses are notorious for their ability to proliferate at both low and high humidity values. The optimal relative humidity range recommended by ASHRAE (30 to 60%) minimizes the spread of viral infections.

As stated before, these issues can be prevented in great part with proper HVAC design. If the existing HVAC installation is only capable of controlling temperature properly, it can be complemented with an air dryer or humidifier.

Using “rules of thumb” in HVAC design almost always causes issues with oversized equipment, inadequate humidity values and drafty indoor environments. Systems end up being more expensive than necessary while performing poorly.

Air Speed

When indoor air moves at excessive speed, it generally causes two types of problems:

  • Air ducts can become noisy, which is detrimental for concentration.
  • Fast-moving air enhances thermal sensation. For example, if the air in a room is being cooled more than necessary, fast-moving air will only make it feel colder.

Air speed can be controlled by sizing HVAC equipment properly, especially fans and air-handling units. For greater effect, speed control measures can be deployed, ensuring the airflow provided matches demand. Variable frequency drives are effective for controlling fans above 1 HP, while electronically-commutated motors (ECM) provide the best speed control solution for fractional horsepower motors.

HVAC System Integration

Ideally, an HVAC system should keep temperature and relative humidity at values that enhance comfort and prevent the proliferation of fungi, bacteria and viruses. At the same time, speed control for ventilation equipment minimizes noise and prevents uncomfortable air drafts. Once this point is reached, the next step is eliminating air pollutants.

HVAC Engineers Must be Mindful of Controlling Indoor Air Pollutants

ASHRAE has determined that pollutant concentrations are 2 to 5 times higher indoors than outdoors, and this applies even for urban areas with heavy traffic. Modern humans spend most of their time indoors, and therefore it is important to ensure that pollutants are kept under check.

One of the most important steps to prevent the accumulation of indoor air pollutants is meeting the ventilation requirements as set forth in building codes. The NYC Mechanical Code establishes the requirements depending on the type of occupancy, generally in terms of cubic feet per minute (CFM) or air changes per hour (ACH). These values are often specified in terms of the number of occupants.

Silent Killers: Carbon Monoxide and Radon

Although many compounds are detrimental for indoor air quality, there are two that require special attention due to how damaging they can be for humans: carbon monoxide and radon.

  • Carbon monoxide is an odorless and colorless combustion product, making it impossible to detect with human senses alone. However, it can cause nausea and dizziness within minutes, or even coma and death if the concentration is high enough. To prevent carbon monoxide leaks, it is very important to ensure that the exhaust systems of combustion-based appliances are properly designed. Sensors should also be deployed to detect leaks, since the gas is impossible to see and smell.
  • Radon is a radioactive gas that leaks out of the ground and is also colorless and odorless. Radon does not have drastic immediate effects on humans like carbon monoxide but can be as damaging as cigarette smoke in the long run – the only difference is that radon is invisible and lacks the unpleasant smell, making it more difficult to avoid. Measuring radon concentrations in indoor air is the only surefire way to detect the gas. It is also important to note that radon concentrations change throughout the year, so one-time measurements are not enough to keep it under watch. Radon concentrations are site-specific.

Other notorious air pollutants to monitor include allergens such as dust, mold and pollen; as well as volatile organic compounds (VOCs), which are often found in artificial fragrances, aerosol sprays and other cleaning products.

Mold tends to grow very fast whenever there is accumulated moisture, especially in poorly-maintained air ducts. The best way to control mold is to control humidity, since it is required by spores.

General Measures to Control Indoor Air Pollutants

Indoor air pollutants can be controlled in great part with a properly designed ventilation system. It also helps to implement habits that reduce the presence of pollutants, while using plants that can absorb them.

The department of buildings provides a series of guidelines to enhance a ventilation system’s ability to remove pollutants and odors from indoor spaces. The following are some general recommendations:

  • Some areas are notorious for their release of odors and compounds, and the extraction system serving them should be designed to exhaust the air directly outdoors, without passing through other areas. Some examples of areas that require dedicated extraction systems include generator rooms, kitchens, bathrooms and laundries.
  • Designing the ventilation system to keep a slightly positive pressure also prevents the accumulation of pollutants that may leak in from outdoors or from other building areas. Likewise, a poorly-designed ventilation system that does not account for negative pressures can have the opposite effect, drawing in odors and pollutants from the surroundings. Positive pressure is very effective for preventing the ingress of dust and pollen.

In addition to properly designed HVAC systems, volatile organic compounds (VOCs) can be controlled in great part by reducing the use of products that release them. For example, aromatic plants can be used instead of synthetic spray fragrances. Dry cleaning processes normally impregnate clothes with VOCs, so it is recommended that dry-cleaned clothes be kept outside for a while, to let the VOCs dissipate.

Many plant species are known for their ability to filter harmful compounds from the air. NASA has studied this subject to determine how plants can improve air quality in space stations, and has concluded that the following ten are solid choices:

  • Aloe Vera
  • Peace lily
  • Spider plant
  • English ivy
  • Boston fern
  • Heart leaf philodendron
  • Eucalyptus
  • African violet
  • Chinese evergreen
  • Chrysanthemum

All these plants are effective pollutant filters, and can greatly improve indoor air quality if present in residential and commercial buildings.

Concluding Remarks

Indoor air quality starts with a proper HVAC design, capable of controlling humidity to prevent the proliferation of fungi, viruses and bacteria. It is very important to meet airflow requirements as specified in the applicable building codes, and positive pressure can help keep airborne particles out of occupied spaces. Experienced HVAC engineers know the ins and outs of these matters. Some air pollutants can be lethal, and their presence must be monitored on an ongoing basis; carbon monoxide and radon are the two main examples.

It is also possible to improve IAQ through passive measures, such as the use of plants that are capable of filtering toxins and pollutants from the air. The use of cleaning products that emit VOCs should be minimized as well.

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