HVAC Engineering River West Chicago, IL 2018-10-03T03:59:44+00:00

What Can Our HVAC Engineers in River West Chicago Do For You?

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For more than ten years a great number of construction companies throughout East Northport, NY already know that New York Engineers is the engineering company to call when you are ooking for Architectural Engineering in New York. What many local property owners have not realized is the NY Engineers is also your top choice if you’re looking for HVAC Engineering services in River West Chicago, Illinois. Those who want to understand more about what River West Chicago HVAC design engineers do? This really is an exceptional job that has an extensive listing of responsibilities. An HVAC design contractor will have to go through numerous challenges to eliminate the original issue. This job requires superior expertise, proficieny, and the capability to handle time cleverly.

The moment an HVAC personel is licensed to function, they will be hired by an engineering business and start to operate many cooling, heating and refrigeration systems. Their responsibility would be to create new and replacement selections based on their client’s requirements. Every single customer is going to have an original set of wishes whether or not it is related to building codes or individual performance prospects. Making use of this data, the engineer goes on a trek towards creating something that’s eco-friendly, energy-efficient and suitable for the setting it is going to be utilized in – (industrial, commercial or residential. They are often liable for the original creations and managing the specific installation.

Generally, an HVAC design engineer in River West Chicago will likely be seen working with a design business or even in a consulting firm depending on their years of expertise. Many engineers move right into a consulting job because they get older and acquire a better idea of what is required of them.

Comparison: HVAC Engineer Versus HVAC Technician

HVAC Technician and HVAC Engineer are frequently confused with each other. Still, they have different tasks with regards to managing HVAC systems. It is essential to know the variance both as a client and as a specialist

An HVAC technician in River West Chicago carries a more direct job, which suggests they are often seen on the way to a owner’s house to see their current system. They often times take care of the installations, repairs, and over-all maintenance which is required every once in awhile. Most of their work is done in conjunction with the client, which suggests they need to learn how to interact with people in the right way.

By having an HVAC engineer, they are accountable for creating a fresh HVAC system and ensuring it meets just what a client is after. It needs to fit just what the home owner needs whether it has to do with their setup, property, or anything else linked to new system. They are also brought in to consult on HVAC creations to ensure things are in line with the latest standards. For this reason they could end up spending time in consulting tasks or at neighborhood engineering companies. That is basically the distinction between these two occupation; HVAC Engineer Versus HVAC Technician. There’s only so much you can save this page if you would like more info on the HVAC Engineering services in River West Chicago, Illinois by NY Engineers you should visit at our blog.

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An Electrical Engineer’s Guide to Circuit Breakers: Overview and Applications

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Circuit breakers are fundamental elements for a safe and code-compliant electrical installation. Conductors and electrical equipment are exposed to damage and malfunction, and there is always a risk that someone may connect a device incorrectly or use it for the wrong application. Electrical engineers see these issues frequently in their line of work. These conditions can cause a device to draw current above its rated value, and the corresponding circuit breaker trips to disconnect the fault.

Before providing an overview of circuit breakers, it is important to understand the difference between the two main current conditions that cause a circuit breaker to trip.

  • An overload current occurs when a device draws current above its rated value, but not by a drastic margin. For example, a motor that is rated at 60 Amperes but drawing 75 Amperes is likely suffering an overload condition.
  • A fault current is orders of magnitude higher than the rated current of a circuit, and it occurs when a live conductor touches another at a different voltage (short circuit), or a conductive surface (ground fault). There is a high-magnitude current in both cases, since low-resistance contact is established across a voltage difference. For example, a residential circuit normally carrying 20 Amperes may experience a few thousand Amperes during a fault.

A circuit breaker must trip under both conditions, but the ideal trip response is different for each case:

  • The response to an overload current should have a time delay. Some types of equipment draw current above their rated value for short periods of time as part of their normal operation. For example, electric motors draw an inrush current up to 8 times their rated current when they start.
  • The response to a fault current should be instantaneous. These currents are not normal under any operating conditions, and they must be cleared immediately when detected.

Given this combination of performance requirements, most circuit breakers actually have two protection mechanisms in a single device. There is a thermal protection mechanism that responds to overload current, and a magnetic protection mechanism that responds to fault currents.

Thermal and Magnetic Protection

The thermal protection mechanism in a circuit breaker is based on an expanding contact: the circuit is interrupted once the contact expands beyond a certain point. The circuit breaker is calibrated so that the contact will not open below rated current, but any current conditions exceeding it will eventually cause a trip. Since current is the heat source that expands the contact, more severe overload conditions cause a faster expansion and a shorter trip time.

The magnetic protection mechanism is based on induction. Current passes through a coil inside the circuit breaker, creating a magnetic field that opens the connection. The field is too weak to trip the breaker under normal operating conditions, but high-magnitude currents cause a strong magnetic field that forces the breaker open.

Main Types of Circuit Breakers, as Explained by Electrical Engineers

Most circuit breakers found in residential and commercial buildings are either miniature circuit breakers (MCB) or molded-case circuit breakers (MCCB). MCBs are more compact as implied by their name, but MCCBs are available in much higher current ratings and come with additional performance features. MCBs are normally available with a current rating of up to 100 amperes, while MCCBs reach up to 2,500 amperes.

You will probably not find MCCBs in small homes and businesses, according to many electrical engineers, but they are common in larger constructions, such as the high rise multi-family and office buildings found throughout larger cities.

Miniature Circuit Breakers

Miniature circuit breakers come in two main versions: DIN-rail mountable MCBs can be installed along with other protection and control devices that also use DIN rails, while plug-in MCBs are inserted on load centers with specially designed slots. Keep in mind that DIN-rail MCBs are designed for standard rails, while plug-in MCBs only fit into matching load centers from the same manufacturer.

Plug-in MCBs have one to three poles, depending on the number of live conductors in the circuit being protected. DIN-rail MCBs can have up to 4 poles, in order to disconnect the neutral conductor along with the live conductors. Regardless of the type of circuit breaker, it is important to select an adequate rated current and breaking capacity.

  • The rated current is determined by the circuit being protected. Any value above this eventually trips the thermal protection mechanism.
  • The breaking capacity is the largest fault current that the unit can interrupt without suffering permanent damage. Should a fault exceed this value, there is an ultimate breaking capacity where the breaker can still clear the fault but is permanently damaged. Any fault above the ultimate breaking capacity cannot be cleared by the circuit breaker, and must be handled by a higher capacity protection system connected upstream.

Miniature circuit breakers are also classified into three types based on their response to fault currents: Type B, C and D. The type determines the threshold where the magnetic protection takes over the thermal protection, causing an instantaneous trip.

Molded Case Circuit Breakers

MCCBs are bulkier than MCBs and are available with higher current ratings. Many models also feature adjustable trip settings, allowing a very accurate protection response if a specific load needs it.

Some MCCBs also come with a removable trip unit that can be replaced with a smaller capacity unit, to recondition the breaker for a load with reduced current. However, you cannot upgrade to a larger trip unit that exceeds the frame size of the MCCB.

There are modern MCCBs that do not use the conventional thermal-magnetic mechanism, but instead use an electronic circuit that measures current and simulates the trip response. This allows a very precise adjustment of protection settings.

Two subtypes of MCCB are designed specifically for the protection needs of electric motors: Motor protection circuit breakers (MPCB) and motor circuit protectors (MCP). The main difference is that an MPCB includes both thermal and magnetic protection, while an MCP only comes with magnetic protection and needs an external overload relay to offer full protection.

Conclusion

Electrical engineers must select the right type of circuit breaker, as it is very important to ensure the safe operation of building systems that include electrical components. Undersized breakers trip continuously and disrupt equipment operation, while oversized breakers do not provide reliable protection against overload current. If an overload is not interrupted, the heating effect can damage conductor insulation and eventually cause a ground fault or short circuit.

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