NO and NC Contacts | Normally Closed vs Normally Open Sensors

NO and NC Contacts | Normally Closed vs Normally Open Sensors

Normally Open vs. Normally Closed Contacts

Let’s learn how to choose and use the NO and NC sensors and switches in the industry.

We all know how normally closed and normally open sensors and contacts work and how they differ from each other.

But have you ever noticed that why in emergency push buttons and stop push buttons we always use Normally Closed contacts? Or do you know what is the best solution for being aware of damage in a level switch cable?

In this article, you’ll find out the answer to these questions by some real-world examples and much more about NO and NC contacts.

In a previous video, we have written a PLC program for a process and we have considered all the level switch sensors as Normally Open switches.

But in the real-world conditions when we are choosing the instrument switches or other types of discrete equipment for a process, we have to select which one should be exactly a Normally Open sensor and which one should be a Normally Closed sensor.

Types of Digital Signals in the Industry

Generally speaking, there are three types of digital or discrete signals in the industry.

– First, the Instrument Switches like Level switches, Flow switches, and so on.

– Second, Operator Push buttons like Start and Stop push buttons, Emergency push buttons, and so on.

– Third, the Digital Feedbacks from Contactors and relays.

The Open and Closed contacts can be integrated into any of these three equipment types.

Types of Digital Signals

NO and NC Contacts of a Contactor

As an example, let’s consider the auxiliary contacts of a contactor.

NO and NC Contacts of a Contactor

These auxiliary contacts are used to send feedback to the PLC to make sure that the contactor is healthy and operational.

NO vs NC Contact

All auxiliary contacts of the contactor maintain their normal condition unless the main coil of the contactor becomes energized.

NO vs NC Relay

If so happens, all of the auxiliary contacts change their state in a fraction of a second.

The Normally Open contacts will become closed and the Normally Closed contacts become open despite us connecting a voltage to them or not.

NC vs NO Contactor

NO and NC Contacts of a Sensor

As another example consider this process in which the bearings of a 1MW electric motor are being lubricated and cooled automatically.

NO and NC Contacts of a Sensor

In this case, the normal level of the oil is between the Low and High-level switches.

Let’s assume that the Low-level switch of the tank is a Normally Closed switch.

NC vs NO Switch

when the oil reaches below this switch (due to leakage for example), it is supposed to send a true signal or a 24-volt DC signal to the PLC.

As a result, the PLC turns off the electric motor.

Simultaneously PLC sends an alarm to operators to become aware of the reason and fill in the tank with oil.

Difference between Normally Closed and Normally Open

But what if the cable of this level switch is damaged and no one is aware of that?

As you might guess, no one will be informed of the leakage and the low level of the oil inside the tank.

So, the bearings of an expensive electric motor could be damaged due to a wrong selection and design.

Normally Open Normally Closed Explained

Now, let’s consider the Low-Level Switch is a Normally Open one and when the oil level is normal, the switch is sending a 24-V DC signal to the PLC.

Normally Open Level Switch

In this case, if we lose the active signal from the low-level switch, due to the cable damage OR because of the oil reduction inside the tank, then everyone will be informed through HMI and safety systems and the electric motor will be shut down instantly.

In this way, the system will be protected correctly.

Normally Closed vs Normally Open Switch

Now, what about the High-Level Switch of the tank? Is it a Normally Closed switch or a Normally Open contact?

Let’s leave this question to discuss in the comments and see what we can learn about the operator push buttons as another type of discrete signals.

NO and NC Contacts of an Operator Push Button

As we mentioned at the beginning of this article, stop push buttons are always considered as normally closed contacts.

NO and NC Contacts of a Push Button

When we activate them, they will open the power circuit and the process will stop immediately.

Stop Pushbutton

So why normally closed contacts?

As these types of actuators are mostly used in case of emergency and safety, then we should always be confident about their circuit functionality.

To do so, we use normally closed contacts, and therefore the same as the previous example, when any cable damage happens, the circuit will be opened and the process will be stopped.

Having our process stopped is far better to risk and run the process with a non-functional emergency circuit.

Normally Closed Contact

What is a NAMUR Sensor (Switch)?

As the last point, in all of these examples that we have reviewed together, the PLC cannot distinguish the cable damage from changing the pushbutton status or instrument switch status.

Why Use Namur Sensor

In this case, we can use a specific type of switch called the NAMUR switch.

I should briefly say that a NAMUR switch is a type of switch mainly used for hazardous areas to limit the voltage and current and therefore prevent sparking during the switching.

Namur Sensor

The NAMUR switches are based on milliampere signaling and not voltage levels.

NAMUR Sensor Output

OK, that’s it for this post. Thanks for reading another article. Please spread the word by sharing this article:

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