Wiring of Latching / Holding Circuit using 8-Pins PLA Relay
Relays are essential components in electronic and electrical systems that enable the control of high-power circuits through low-power control signals. One common application of relays is to create a holding circuit, which maintains the state of a circuit even after the control signal is removed. In this article, we will delve into the concept of a holding circuit using an 8-pin relay, its working principle, components, and practical considerations.
What is an 8-pin relay?
An 8-pin relay (also known as 2C/O Relay i.e. 2 commons and outputs) is an electromechanical or solid-state device that serves as a switch to control large electrical circuits using a low-power control signal. It typically has eight pins or terminals that facilitate its operation and connection within a larger electrical system. The fundamental components of an 8-pin relay include a coil, normally open (NO) contacts, and normally closed (NC) contacts.
Coil: The coil is an electromagnetic winding that generates a magnetic field when a voltage is applied to it terminals (2 & 7). When the coil is energized, the magnetic field causes a movable armature or relay switch to be attracted towards it.
Normally Open (NO) Contacts: These are switch contacts (3 & 6) that are normally open (disconnected) when the relay is in its resting state or not energized. When the coil is energized, the armature moves to close the NO contacts, allowing current to flow through the circuit.
Normally Closed (NC) Contacts: These contacts (4 & 5) are normally closed (connected) when the relay is in its resting state. When the coil is energized, the armature moves to open the NC contacts, interrupting the current flow through the circuit.
As shown in fig, the 8-pin relay terminals are interconnected with the following pin configuration:
Pins 2, 7: Relay’s Coil Connections ( L or + and N or – = energizing the coil)
Pin Common (COM) 1 is Normally Closed (NC) with 4 and Normally Open (NO) with 3.
Pin Common (COM) 8 is normally closed (NC) with 5 and Normally Open (NO) with 6.
Working Principle of an 8-Pin Relay
An 8-pin relay consists of a coil, a set of normally open (NO) contacts, and a set of normally closed (NC) contacts. The coil is energized by applying a voltage across its terminals, which generates a magnetic field that attracts a movable armature. This action causes the contacts to switch from their normal positions.
When the coil is de-energized, the armature returns to its initial position due to spring action, and the contacts revert to their normal states. This fundamental behavior of relays forms the basis for creating holding circuits.
How to Wire an 8 PIN Relay?
In the following wiring diagram, two light bulbs are controlled using an 8-pin relay, where both bulbs will either glow or turn off simultaneously during relay operation. For instance, when the relay labeled CB is in the OFF state, both light bulbs will be off since they are connected to the NO (Normally Open) contacts of the relay. Conversely, when the relay is turned ON, both light bulbs will illuminate.
Different wiring configurations and controls can be employed according to the circuit’s requirements. For instance, if you want to switch ON the RED bulb while turning OFF the BLUE bulb, simply connect the Blue light bulb to the 5th terminal (NC – Normally Closed) of the relay, instead of the 6th terminal (NO – Normally Open) .
In this setup, when the relay is ON due to the activation of the MCB (Miniature Circuit Breaker), the NO contact of the relay will become NC, and vice versa. As a result, the Red bulb will illuminate while the Blue bulb will be turned off. This process will reverse when the relay is turned OFF—meaning the Red bulb will turn off while the Blue bulb will start glowing.
What is a Holding Circuit?
Holding circuits, also known as latch circuits, are designed to maintain the current state of a circuit after the control signal is removed. This functionality is particularly useful in situations where consistent circuit states are required, such as in safety systems or power distribution networks.
Operation of Holding Circuits
When the coil is energized by the control signal by pressing the GREEN NO pushbutton, it causes the NO contact to close, completing the circuit to the load. Once the coil is energized, even if the control signal is removed (by releasing the Green NO push button), the NO contact remains closed due to the mechanical latching action of the relay (as the terminal #3 is directly connected to the phase supply ). This keeps the load powered and the circuit closed. The NC contact is opened simultaneously, ensuring that the load is not connected to the negative terminal.
To reset the circuit, the control signal is applied again by pressing the RED NC pushbutton, which de-energizes the coil. This opensthe NO contact and closes the NC contact, turning off the load.
Practical Applications
Holding circuits find applications in various domains, including industrial automation, safety systems, automotive electronics, and home appliances. For example, a holding circuit can be used to maintain the state of a motor even after releasing the button that initially started it.
Wiring of Latching / Holding Circuit using 8-Pins PLA Relay
Relays are essential components in electronic and electrical systems that enable the control of high-power circuits through low-power control signals. One common application of relays is to create a holding circuit, which maintains the state of a circuit even after the control signal is removed. In this article, we will delve into the concept of a holding circuit using an 8-pin relay, its working principle, components, and practical considerations.
What is an 8-pin relay?
An 8-pin relay (also known as 2C/O Relay i.e. 2 commons and outputs) is an electromechanical or solid-state device that serves as a switch to control large electrical circuits using a low-power control signal. It typically has eight pins or terminals that facilitate its operation and connection within a larger electrical system. The fundamental components of an 8-pin relay include a coil, normally open (NO) contacts, and normally closed (NC) contacts.
Coil: The coil is an electromagnetic winding that generates a magnetic field when a voltage is applied to it terminals (2 & 7). When the coil is energized, the magnetic field causes a movable armature or relay switch to be attracted towards it.
Normally Open (NO) Contacts: These are switch contacts (3 & 6) that are normally open (disconnected) when the relay is in its resting state or not energized. When the coil is energized, the armature moves to close the NO contacts, allowing current to flow through the circuit.
Normally Closed (NC) Contacts: These contacts (4 & 5) are normally closed (connected) when the relay is in its resting state. When the coil is energized, the armature moves to open the NC contacts, interrupting the current flow through the circuit.
As shown in fig, the 8-pin relay terminals are interconnected with the following pin configuration:
Pins 2, 7: Relay’s Coil Connections ( L or + and N or – = energizing the coil)
Pin Common (COM) 1 is Normally Closed (NC) with 4 and Normally Open (NO) with 3.
Pin Common (COM) 8 is normally closed (NC) with 5 and Normally Open (NO) with 6.
Working Principle of an 8-Pin Relay
An 8-pin relay consists of a coil, a set of normally open (NO) contacts, and a set of normally closed (NC) contacts. The coil is energized by applying a voltage across its terminals, which generates a magnetic field that attracts a movable armature. This action causes the contacts to switch from their normal positions.
When the coil is de-energized, the armature returns to its initial position due to spring action, and the contacts revert to their normal states. This fundamental behavior of relays forms the basis for creating holding circuits.
How to Wire an 8 PIN Relay?
In the following wiring diagram, two light bulbs are controlled using an 8-pin relay, where both bulbs will either glow or turn off simultaneously during relay operation. For instance, when the relay labeled CB is in the OFF state, both light bulbs will be off since they are connected to the NO (Normally Open) contacts of the relay. Conversely, when the relay is turned ON, both light bulbs will illuminate.
Different wiring configurations and controls can be employed according to the circuit’s requirements. For instance, if you want to switch ON the RED bulb while turning OFF the BLUE bulb, simply connect the Blue light bulb to the 5th terminal (NC – Normally Closed) of the relay, instead of the 6th terminal (NO – Normally Open) .
In this setup, when the relay is ON due to the activation of the MCB (Miniature Circuit Breaker), the NO contact of the relay will become NC, and vice versa. As a result, the Red bulb will illuminate while the Blue bulb will be turned off. This process will reverse when the relay is turned OFF—meaning the Red bulb will turn off while the Blue bulb will start glowing.
What is a Holding Circuit?
Holding circuits, also known as latch circuits, are designed to maintain the current state of a circuit after the control signal is removed. This functionality is particularly useful in situations where consistent circuit states are required, such as in safety systems or power distribution networks.
Operation of Holding Circuits
When the coil is energized by the control signal by pressing the GREEN NO pushbutton, it causes the NO contact to close, completing the circuit to the load. Once the coil is energized, even if the control signal is removed (by releasing the Green NO push button), the NO contact remains closed due to the mechanical latching action of the relay (as the terminal #3 is directly connected to the phase supply ). This keeps the load powered and the circuit closed. The NC contact is opened simultaneously, ensuring that the load is not connected to the negative terminal.
To reset the circuit, the control signal is applied again by pressing the RED NC pushbutton, which de-energizes the coil. This opensthe NO contact and closes the NC contact, turning off the load.
Practical Applications
Holding circuits find applications in various domains, including industrial automation, safety systems, automotive electronics, and home appliances. For example, a holding circuit can be used to maintain the state of a motor even after releasing the button that initially started it.
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