HVAC Engineering Cicero Chicago, IL 2018-10-03T23:49:44+00:00

What Can Our HVAC Engineers in Cicero Chicago Do For You?

Electrical Engineering Degree

Since 2011 a lot of developers throughout Syosset, New York already know that NY-Engineers.Com is the engineering firm to call when you’re ooking for Fire Protection Engineering in NYC. What many local developers have not realized is the New York Engineers is also your best choice if you’re looking for HVAC Engineering services in Cicero Chicago, Illinois. Those who want more information on what Cicero Chicago HVAC design engineers do? This can be an exclusive job that come with an extensive list of duties. An HVAC design contractor will have to work through several problems to settle the original issue. This task calls for superior talent, competence, and the cabability to manage time wisely.

Once an HVAC engineer is certified to work, they are going to sign on with an engineering company and begin to work on many heating, cooling, and refrigeration systems. Their role is to create new and additional options according to their client’s requirements. Each client will have an exclusive set of wants whether or not it is related to building codes or personal performance prospects. Using all of this info, the engineer sets off on a trek towards building something that is eco-friendly, energy-efficient and suitable for the place it might be utilized in – (industrial, commercial or residential. They are generally responsible for the initial drawings and overseeing the particular installation.

Generally speaking, an HVAC design engineer in Cicero Chicago is going to be seen working with a design company or maybe in a consulting firm according to their numerous years of expertise. Most engineers shift into a consulting job because they get older and acquire a better knowledge of what is required of them.

Comparing HVAC Technician vs HVAC Engineer

HVAC Engineer and HVAC Technician are usually mistaken for each other. However, they have got separate tasks in terms of working with HVAC systems. It is essential to are aware of the variance both as being a client as well as a specialist

An HVAC technician in Cicero Chicago has a more direct job, which means they are usually seen visiting a owner’s home to see their existing system. They frequently keep up with the repairs, installations, and general keep which is required ever so often. Almost all of their jobs are done alongside the customer, which suggests they must learn how to connect to people in the right way.

Having an HVAC engineer, they are accountable for designing a fresh HVAC system and making certain it meets exactly what a client wants. It needs to fit precisely what the home owner wants whether or not this has to do with their setup, property, or everything associated with new system. Also, they are introduced to talk on HVAC creations to ensure everything is consistent with the highest standards. This is why they are able to find themselves passing time in consulting firms or at neighborhood engineering companies. That is basically the distinction between those two vocation choices; HVAC Engineer vs HVAC Technician. Even with all of this information you would like additional info about the HVAC Engineering services in Cicero Chicago, IL by New York Engineers we invite you to take a look at our Cicero Chicago CAD to Revit Modeling blog.

Cicero Chicago HVAC Engineering Related Blog Article

Electrical Safety and Power Quality: A Short Guide for Electrical Engineering

Electricity is one of the cornerstones of modern society, but it can be very dangerous if handled incorrectly. Therefore, governments have introduced stringent codes to regulate its use and ensure safety for occupants. A building’s power supply must be safe to use, and it must also have the voltage and frequency required by the electrical appliances in the building. The electrical engineering systems that provide electrical safety and power quality are typically hidden from sight, but they play a fundamental role in buildings.

Electrical issues are more common in pre-war apartment buildings and other old constructions. Always make sure you get the installation checked before moving into an existing property, but especially if it very aged.

Electrical Protection Devices

The main function of electrical protections is to disconnect the power supply when dangerous operating conditions are present. The main types of electrical faults found in electrical engineering systems are the following:

  • Overload or overcurrent
  • Short circuit
  • Ground fault
  • Line-to-line fault
  • Transient or voltage surge

Plug-in circuit breakers are perhaps the best-known electrical protection devices, commonly used in residential and light commercial applications (below 100 Amperes). Molded-case circuit breakers are generally larger and reach higher current ratings, while motor circuit protectors and thermal overload relays are designed for the protection needs of electric motors. Other than the plug-in configuration, there are protection devices designed for a DIN rail mount or for bolted connections.

An overload occurs when an electrical circuit is drawing current above its rated value for an excessively long period. It is important to note that short-duration overcurrent is common in some types of equipment. For example, three-phase electric motors may draw up to eight times their rated current during startup, but only for a short time – typically fractions of a second. Some types of lighting also draw an inrush current, especially if they have ballasts.

Circuit breakers typically use a thermal interruption mechanism to protect circuits from overload while allowing short-duration current peaks. The thermal protection mechanism uses a metallic contact that expands when heated by current, and it is calibrated to allow the circuit breaker’s rated current but not higher values. However, since inrush currents occur too quickly, their heating effect is not enough to expand and disconnect the thermal protection mechanism. On the other hand, an overload eventually trips the breaker; as current magnitude increases, the thermal protection contact expands faster and disconnects the circuit in less time.

A short circuit occurs when a live conductor touches a neutral conductor, causing a very high current. The magnitude of a short circuit fault is very high, typically thousands of amperes, so it must be disconnected as quickly as possible. In this case the response of thermal protection is too slow, so the protection mechanisms that clear short circuit faults are based on electromagnetic induction – the intense current induces a strong magnetic field that disconnects the circuit breaker.

A ground fault, also known as a line-to-ground fault, occurs when a live conductor touches a conductive element that is not part of the electric circuit. This also creates a very high current due to the low contact resistance, activating the magnetic protection mechanism of the respective circuit breaker. A line-to-line fault occurs when two live conductors at different voltage touch each other, also causing a high-magnitude current. In both cases, the same magnetic protection mechanism that clears short circuit faults responds and trips the circuit breaker.

All the faults described above are characterized by excessive current. When a high voltage peak occurs, the fault is called a transient or a voltage surge. Voltage surges normally occur when large equipment is switched, and can also be caused by lightning. Since circuit breakers are not designed to protect installations from voltage surges, you must use a surge protection devices (SPD) or transient voltage surge suppressor (TVSS). One of the most common types of TVSS use a variable resistance (varistor) connected between the live conductors and the ground – its resistance is high under normal operating conditions, but drops to a very low value in response to voltage peaks, discharging the fault to the ground before it reaches sensitive equipment.

Improving Power Quality in Electrical Engineering Systems

Electric power systems may also suffer from issues that are not faults strictly speaking, but which are also detrimental for performance. Two of the main issues are low power factor and harmonics.

Power factor is a very abstract concept, but the following is a simple way to visualize it. Some types of electrical equipment draw current in such a way where not all the power drawn from the voltage supply is really consumed. In these cases, the term “real power” is used to describe the power that is actually used, and the term “reactive power” is used to describe the portion that oscillates back and forth between the equipment and the power supply without being used. Some of the most common loads associated with reactive power are electric motors, transformers and ballasts. The power factor is the ratio of the real power used and the apparent power – the direct multiplication product of voltage and current.

  • Assume a single-phase motor consumes 900 W of electric power while drawing 5 amperes at 240 volts.
  • The apparent power is 1,200 volt-amperes (240V x 5A).
  • The power factor is 0.75 (900W / 1200 VA). It can also be reported as 75%.
  • The maximum possible value is 1.00 or 100%, where all the power drawn from the voltage source is consumed. Purely resistive loads such as incandescent lamps and resistance heaters behave this way.

Low power factor increases the current drawn by a building, and this creates an extra burden for the grid. Therefore, utility companies typically penalize users that allow their power factor to drop below a specified value. Low power factor is corrected by installing capacitors, which are similar to batteries but designed for a much faster cycle – the oscillating current that characterizes reactive power is supplied locally by the capacitor, and not drawn from the power grid, sparing the user from extra charges.

Power factor correction is characterized by its quick payback period, typically less than one year.

Harmonics are voltage and current signals whose frequency is a multiple of the service frequency – 60 Hz in the USA. Harmonics are produced by nonlinear loads such as magnetic cores and digital equipment, and they tend to overheat circuits, especially the neutral conductor. Excessive harmonics can also cause some types of electronic equipment to malfunction. Harmonic filters are devices that are tuned for a specific harmonic frequency, and when installed in a power system they prevent the propagation of harmonics beyond the equipment that generates them.

Conclusion

The best recommendation to keep all these electrical issues under control is to seek professional assistance from an electrical engineering profession. In new constructions, protection and power quality can be addressed from the design stage. For existing buildings, power monitoring equipment can be used to detect harmonics or low power factor, and the measurement results are then used to specify harmonic filters and capacitors. If circuit breakers are tripping frequently, get an inspection to determine the cause: there could be an electrical fault, but the breaker itself could also be damaged.

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