Electrical switches can adapt to misunderstandings in the application / application to ensure no leakage current and make them available in multiple circuits, actuators, and housing styles. Disadvantages include their number, limited communication life cycle, large size and slow response.

Solid Switch

Solid switches electric appliances that do not have aging moving parts. They are able to switch quickly without any spark between contacts or problems with communication rust. Their disadvantages include high construction costs at current very high rates.

When selecting a level switch, the user needs to determine if the power circuit needs a switch that is usually open or closed.

Normally Open (NO)

The switches do not currently allow for free access. They need to “create” a contact in order to activate it.

Normally Closed (NC)

The switches currently allow free access and require a “break” contact (open) to be activated.

Stick / Throw

Most switches have one or two poles and one or two throws, but some manufacturers will produce custom-level switches for specialized apps. The number of poles indicates the number of different circuits that can be switched on at the same time.

The cast number describes the number of circuits each pole can control. This is indicated by a circuit configuration (NO / NC). Pause is a circuit breaker caused by contacts that are separated by a switch that introduces each circuit that opens or interrupts the circuit.

Electrical Changing System and Types

Single Pole, One Throw (SPST)

Single pole, single throw switches (SPST) make or break a single conductor connection in a single branch circuit. They usually have two terminals and are called single-pole switches

Single pole, Double Throw (SPDT)

A single pole, dual switches (SPDT) makes or breaks a single conductor connection with one of two conductors. They usually have three terminals and are usually used in pairs. SPDT switches are sometimes called three-way switches.

Double Pole, Single Throw (DPST)

Double pole, single throw switches (DPST) make or break the connection of two circuit conductors in a single branch circuit. They usually have six terminals and are available in both temporary and maintenance communication versions.

Double Pole, Double Throw (DPDT)

Double pole switches, double throw (DPDT) make or break the connection of two conductors in two different circuits. They usually have six terminals and are available in both temporary and maintenance communication versions.

Electrical switch contacts are either normally-open or normally-closed, depending upon the open or closed status of the contacts under “normal” conditions.

But what exactly defines “normal” for a switch? The answer is not complicated, but it is often misunderstood because of the ambiguous nature of the common word.

The “normal” state of the switch is the state of electrical contacts in the state of non-physical regeneration. One way to think of a “normal” situation is to think of a change in relaxation.

With the change of the temporary contact button, this may be the status of the switch contact if it is not pressed. Electric switches are always designed with scheme drawings in their “normal” conditions, regardless of the type of operation.

The “normal” state of the switch (closed) is actually an abnormal state of the internal process (low flow), for the simple reason that the switch should be stimulated and not rested while the process is running. as it should.

Below 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)

Symbols of electrical switches

1. Point level measurement and
2. Continuous level measuring.

Point level measurement indicates when a product is present at a certain point and continuous level measuring indicates the continuous level of a product as it rises and falls. The sensors for point level indication are “Capacitance”, “Optical”, “Conductivity”,“ Vibrating” (Tuning Fork) and “Float Switch”.

The sensors for continuous level measuring are “Ultrasonic” and “Radar” ( Microwave). We will talk about how they work and which applications are best suited for their technology, as well as their limitations in certain applications. Let’s talk about point level indication sensors first. Starting with capacitance level sensors. A capacitance sensor is a proximity sensor that gives off an electrical field and detects a level by the effect on its electrical field. These sensors are small, less expensive than other sensors, invasive to the product, accurate, and have no moving parts. However, they do have to be calibrated and will only detect certain liquids.

Capacitance sensors can be used in liquid storage tanks. A water treatment facility that has storage tanks would be an ideal use for a capacitance sensor.

The next point level sensor we will talk about is an optical level sensor. Optical sensors work by converting light rays into electrical signals which measure a physical quantity of light then translate it into a measurement. These sensors have no moving parts, they are not affected by high pressure or temperature, are small in size, and can be used in liquid applications. However, if the lens gets coated or dirty they would require cleaning. They can be used as low-level indicators to prevent run dry conditions when using oil, coolant, or hydraulics.

Another style of point level sensor is conductivity or resistance. A conductivity or resistance sensor uses a probe to read conductivity. The probe has a pair of electrodes and applies alternating current to them. When a liquid covers the probe its electrodes form a part on an electric circuit, causing current to flow which signals a high or low level. The advantages of using a conductivity level sensor are there are no moving parts, they are low cost, and fairly easy to use. The disadvantages are they are invasive, meaning they must touch the product being sensed, they only sense conductive liquids, and the probe will erode over time. Appropriate use for these sensors would be for signaling high or low levels.

Vibrating or tuning forks is another type of point level sensor. They use a fork-shaped sensing element with two tines. The fork vibrates at its natural resonant frequency. As the level changes, the frequency of the fork will change detecting the level. These sensors are cost effective and are also compact. They are invasive to the product, meaning they have to touch the material to sense the level. These sensors are easy to install and are essentially maintenance-free. They have unlimited uses based on the material that they can sense. Mining, food and beverage, and chemical processing industries use these sensors for their applications.

The last point level sensor that we will talk about is a float switch. Float switches use a float, a device that will raise or lower when a product is applied or removed, which will open or close a circuit as the level raises or lowers moving the float. The advantages of a float switch are that it is a non powered device, it provides a direct indication, and they are inexpensive. The disadvantages are they are invasive to the product, they have moving parts, and can be large in size. Float switches will only give an indication for a high or low level they cannot measure a variable level. A great use for float switches is in liquid storage tanks for high or low-level indication.

Now, let’s talk about continuous level measurement sensors. We will start with ultrasonic sensors. They work by emitting and receiving ultrasonic waves. The time it takes for the waves to reflect back is how distance is measured. These sensors have no moving parts, are compact, and reliable. The disadvantage of using this type of sensor is that they can be expensive and in some situations, the environment can have a negative effect on them. The benefits of ultrasonic sensors are that they are non-invasive, or non-contact, they are unaffected by the properties of the material they are sensing, and they are self-cleaning because of the vibrations they give off. An example application is a hot asphalt tank in a shingle manufacturing plant. The ultrasonic sensor would be placed in the top of the tank away from the hot asphalt and used to sense the level in order to send a fill request for the tank.

Radar or microwave is also a continuous level sensor. These sensors transmit microwaves by an antenna on the radar sensor. The product that is being sensed reflects these microwaves back to the antenna and the time from emission to reception of the signal is proportional to the level of the product. Radar sensors are not affected by temperature, pressure or dust. They can also measure liquids, pastes, powders, and solids. They are very accurate and require no calibration. This type of level sensor is also non-invasive because it does not have to touch the product that it is sensing. The disadvantages of radar sensors are that they are expensive as well as have a limited detection range. If we go back to our shingle manufacturing plant example a Radar level sensor could be an ideal solution. Much like the ultrasonic sensor, radar sensors are ideal for hot liquid storage tanks.

Her, we talked about seven different types of level switches and their applications. Some of their applications can overlap and when deciding on a sensor it is important to identify the product that you are sensing and the type of feedback that your application requires. Sensors like conductivity or resistance, capacitance, float switches, and optical level sensors can be used to indicate a high or low level. While ultrasonic, and radar level sensors can measure your level to give specific feedback to how much of product is in a tank.