Skip to main content

Normally-open and Normally-closed Switch Contacts

 Perhaps the most confusing aspect of discrete sensors is the definition of a sensor’s normal status.


Electrical switch contacts are typically classified as either normally-open or normally-closed, referring to the open or closed status of the contacts under “normal” conditions. But what exactly defines “normal” for a switch?


The answer is not complex, but is often misunderstood due to the ambiguous nature of the word normal.


The “normal” status for a switch is the status its electrical contacts are in during a condition of no physical stimulation. Another way to think of the “normal” status is to think in terms of the switch being at rest.


For a momentary-contact pushbutton switch, this would be the status of the switch contact when it is not being pressed. Electrical switches are always drawn in schematic diagrams in their “normal” statuses, regardless of their application.


Normally-open and Normally-closed

For instance, the following diagram shows a normally-open pushbutton switch controlling a lamp on a 120 volt AC circuit (the “hot” and “neutral” poles of the AC power source labeled L1 and L2, respectively):

We can tell this switch is a normally-open (NO) switch because it is drawn in an open position.

The lamp will energize only if someone presses the switch, holding its normally-open contacts in the “closed” position. Normally-open switch contacts are sometimes referred to in the electrical industry as form-A contacts.

If we had used a normally-closed pushbutton switch instead, the behavior would be exactly opposite. The lamp would energize if the switch was left alone, but it would turn off if anyone pressed the switch.

Normally-closed switch contacts are sometimes referred to in the electrical industry as form-B contacts:
This seems rather simple, don’t you think? What could possibly be confusing about the “normal” status of a switch?

The confusion becomes evident, though, when you begin to consider process switches (i.e. switches actuated by process measurements such as pressure, flow, level, etc.).

In order to better understand this concept, we will consider a simple application of a flow switch: a switch built to actuate when a sufficient rate of fluid flows through a pipe.

A flow switch is built to detect fluid flow through a pipe. In a schematic diagram, the switch symbol appears to be a toggle switch with a “flag” hanging below.

Example
The schematic diagram, of course, only shows the circuitry and not the pipe where the switch is physically mounted:


This particular flow switch is used to trigger an alarm light if coolant flow through the pipe ever falls to a dangerously low level, and the contacts are normally-closed as evidenced by the closed status in the diagram.

Here is where things get confusing: even though this switch is designated as “normally-closed,” it will spend most of its lifetime being held in the open status by the presence of adequate coolant flow through the pipe.

Only when the flow through the pipe slows down enough will this switch return to its “normal” status and conduct electrical power to the lamp.

In other words, the “normal” status for this switch (closed) is actually an abnormal status for the process it operates within (low flow), for the simple reason that the switch should be stimulated and not at rest while the process is operating as it should.
We often wonder why process switch contacts are labeled according to this convention of “no stimulation” instead of according to the typical status of the process in which the switch is used.

The answer to this question is that the manufacturer of the switch has no idea whatsoever as to your intended use.

A flow switch manufacturer does not know or care whether their product gets used as a low-flow detector or as a high-flow detector.

In other words, the manufacturer cannot predict what the typical status of your process will be, and so the definition of “normal” status for the switch must be founded on some common criterion unrelated to your particular application.

That common criterion is the resting status: when the sensor is exposed to the least (or no) amount of stimulation from the process it senses.

Here is a listing of “normal” definitions for various process switch types:

*Limit switch: target not contacting the switch
*Proximity switch: target far away
*Pressure switch: low pressure (or even a vacuum)
*Level switch: low level (empty)
*Temperature switch: low temperature (cold)
*Flow switch: low flow rate (fluid stopped)

These are the conditions represented by the switch statuses shown in a schematic diagram. These may very well not be the statuses of the switches when they are exposed to typical operating conditions in the process.

A helpful tip to remember about process switches and their respective schematic diagram symbols is that the symbols are conventionally drawn in such a way that an upward motion of the movable switch element represents increasing stimulus.

Here are some examples of this, showing various.

Process switch types and NO/NC contact configurations, comparing their states with no stimulus versus when the stimulus exceeds the each switch’s threshold or “trip” setting.

The normal status of each switch as defined by the manufacturer is labeled in green text:
It is imperative to remember that the way a switch is drawn in a schematic diagram merely represents its “normal” status as defined by the manufacturer.

This may or may not be the switch’s status during “typical” operation of the process, and it may or may not be the status of that switch at the time of concern when you are examining the schematic!

The “normal” status of a switch means just one thing: what that switch will do when subjected to minimum stimulus – that is to say, what it will do when its stimulus is less than the actuation threshold of the switch.

Comments

Popular posts from this blog

PLC Program for Mixing Tank

 Create a ladder diagram for controlling a batch mixing process. Implement a PLC program for mixing tank or Mixing Process using PLC Ladder Logic. PLC Program for Mixing Tank Fig : Mixing tank A tank is used to mix two liquids. The required control circuit operates as follows: A. When the START button is pressed, solenoids A and B energize. This permits the two liquids to begin filling the tank. B. When the tank is filled, the float switch trips. This de-energizes solenoids A and B and starts the motor used to mix the liquids together. C. The motor is permitted to run for 1 minute. After 1 minute has elapsed, the motor turns off and solenoid C energizes to drain the tank. D. When the tank is empty, the float switch de- energizes solenoid C. E. A STOP button can be used to stop the process at any point. F. If the motor becomes overloaded, the action of the entire circuit will stop. G. Once the circuit has been energized, it will continue to operate until it is manually stopped. Solution : A

What is Relay? How it Works? Types, Applications, Testing

 We use relays for a wide range of applications such as home automation, cars and bikes (automobiles), industrial applications, DIY Projects, test and measurement equipment, and many more. But what is Relay? How a Relay Works? What are the Applications of Relays? Let us explore more about relays in this guide. What is a Relay? A Relay is a simple electromechanical switch. While we use normal switches to close or open a circuit manually, a Relay is also a switch that connects or disconnects two circuits. But instead of a manual operation, a relay uses an electrical signal to control an electromagnet, which in turn connects or disconnects another circuit. Relays can be of different types like electromechanical, solid state. Electromechanical relays are frequently used. Let us see the internal parts of this relay before knowing about it working. Although many different types of relay were present, their working is same. Every electromechanical relay consists of an consists of an Electroma

Chlorine dioxide Analyzer Principle

 Chlorine dioxide measurement Chlorine dioxide (ClO2) is an instable, non-storable, toxic gas with a characteristic scent. The molecule consists of one chlorine atom and two oxygen atoms – represented in the chemical formula ClO2. It is very reactive. To avoid the risk of spontaneous explosions of gaseous chlorine dioxide or concentrated solutions, it is generally handled in dilution with low concentrations. ClO2 is soluble in water, but tends to evaporate quickly. Typically it is prepared on site, for example from hydrochloric acid and sodium chlorite. The procedure provides solutions with approx. 2 g/l ClO2 that can be safely handled and stored for several days. Image Credits : krohne Sensor Parts : Reference electrode Applied chlorine dioxide specific potential Current needed to maintain the constant potential Counter electrode Measuring electrode The disinfection effect of ClO2 is due to the transfer of oxygen instead of chlorine, so that no chlorinated byproducts are formed. ClO2