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Best Six Months Industrial Training in Delhi Provider Innovic India

In today’s situation in world the technology is regularly changes in for the Industrial experts. So for engineers is ready to absorb the new changes which one establish in the system. Certification  is compulsory in the Industry which will run our Industrial Automation Training Institute in Delhi that increases the knowledge and creates better growth and standpoint for yours in the industry.

6 Months Industrial training

Seeking the job is crucial at that time. Innovic India Pvt. Ltd creates the opportunity for the best six months industrial training in Delhi which one gives by the Industrial trainer. We, Innovic are pioneer in Industrial Automation Training Industry along with placement.

In our institutes we provide the Industrial Automation Training Development Institute in Delhi. We also running the various Industrial Automation courses including PLC, SCADA, DCS, HMI, VFD, AutoCAD, Panel Designing, Instrumentation, P&ID and PLC SCADA Training that elaborated by industry expert. All of the courses have great requirement in process industries according to our Industrial experts.

So without wasting times join for making your future bright.

For more Information, Call: +91-9555405045

Email: group.innovic@gmail.com

Visit: http://www.innovicindia.com

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PLC SCADA Training in Noida

Aiming for high is not bad, as far as growth is concerned. And if you are looking to get jobs in Delhi NCR region, then it is a must to brush up your skills. But, after graduation, most of the students are not clear what to do and what not to. But if automation is in your mind or plc training is in your mind, then Innovic is the best place to get training. Innovic has the best trainers, that is not all, they have the latest pieces of equipment. Altogether, they make the best centre which offers automation training in Noida.

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Apart from offering automation training, they are also offering, PLC training in Noida, Scada training in Noida and Plc Scada training in Noida. Plc (programming logic control), the demand for it is increasing day by day, as it helps in increasing productivity and improving quality. Maintenance costs are also reduced, and thus increases the profit. This, in turn, increases the demand of engineers in the company. Innovic thrives for providing quality education along with superb training, combined together helps students in getting jobs faster.

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Innovic is also helping students with 100% placement Guarantee. The placement cell conducts the interview as well, so that, students are ready to face any interviews. Innovic is training thousands of students by offering excellent PLC SCADA courses at reasonable rates. One of the most profound aspects of joining Innovic is that the fees are very affordable, hence attracting a large number of students. They train the students by offering skills such as automation concept, PLC programming, PCL’S introduction and many more.

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Benefits of joining Innovic:
Affordable fees.
• Quality education is given to the students.
• Excellent job assistance is given to the students, so that they take money with them, right after the completion of the course.
• Corporate trainers teach the students as per the latest market standards so that the students are on par with other students.

Fesher Engineering Jobs, PLC programming, PLC SCADA Training In Noida, DelhiNCR, SCADA sYSTEM, Uncategorized

Six-months Industrial Training

There is good news for professionals as well as students in the final year of engineering students. Innovic India Pvt. Ltd. is ready with a 6 months certification training programme on Industrial Automation and Design Learning which will allow the professionals to brush up their skills on the new-age technology.

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The course will commence on March 11 with centres initially at New Delhi. The six-month programme will cover foundational concepts as well as industrial application of Automation with a mix of classroom teaching and practical learning.

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“The Industrial Automation wave has been touted as the fourth industrial revolution and there is a growing perception that it will disrupt almost every sector. But it will also create many more. There is an increasing need for skilled Automation professionals in order to create and augment Automation systems. Around 2 lakh jobs are expected to be created by 2020 in the Automation field in India,” said Industrial Experts.

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“The certificate programme by Innovic India is aimed at strengthening India’s talent pool in Machine Learning and Industrial Automation. The trainees will be selected from working professionals and senior students. In the first batch, 30-40 aspirants will be allowed to enroll for the course.

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The classes will be taken by faculty experts from Industry. Students will have the opportunity to work on live projects. A certificate will be awarded based on successful completion of the modules. A rigorous Automation program for professionals is the need of the hour. This program has been designed by Innovic India faculty in consultation with industry experts. The course is the first of several certificate courses being launched by Innovic India to deliver high quality Automation training.

For More Information, Call@ 9555405045/9811253572

or Visit: http://www.innovicindia.com

Fesher Engineering Jobs, PLC programming, PLC SCADA Training In Noida, DelhiNCR, SCADA sYSTEM, Uncategorized

PLC SCADA Training In Noida, Delhi NCR

Industrial Automation is a lot of advancements that outcomes in activity of machines and frameworks without human mediation to a huge degree. It empowers industrial facilities to accomplish execution better than manual activity. Though ‘control’ is another arrangement of advancements that accomplishes wanted examples of varieties of operational parameters and successions for machines and frameworks by giving the information signals important.

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PLC or Programmable Logic Controller is a modern advanced PC and PLC course makes you prepared for the Industrial computerization process in assembling units and development structures. You can utilize your ability for the dynamic improvement, resulting control, counters and clocks, programming simplicity and control. PLC is commonly utilized in enterprises which wipes out the hard wiring contrasted and standard hand-off control circuits, improving efficiency. PLC is a Robust Industrial PC which is only a planned errand of perusing field devices and controlling actuators.

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SCADA is an arrangement of equipment and programming that joins modern automation and control. Short for Supervisory Control And Data Acquisition, SCADA are the foundation of present day industry. It enables enterprises to screen, accumulate, and process information; collaborate with and control machines and gadgets, for example, valves, siphons, engines, and that’s only the tip of the iceberg, which are associated through HMI (human-machine interface) programming, and record occasions into a log document.

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For More Information Call or Whats app us on: +91-955405045 / +91-9811253572

Visit: http://www.innovicindia.com

Fesher Engineering Jobs, PLC programming, SCADA sYSTEM, Uncategorized

Ladder Logic Programming Basics

One of the best visual programming languages is a PLC programming language. It’s called ladder logic or ladder diagram (LD) and you can learn it very fast.

The smart thing about ladder logic is that it looks very similar to electrical relay circuits. So if you already know a little bit about relay control and electrical circuits, you can learn ladder logic even faster.

In this ladder logic tutorial you will learn everything you need to know about the ladder diagram PLC programming language. You will be able to start making real PLC programs with ladder logic in almost any PLC programming software. After reading this tutorial I strongly recommend that you continue with one of the PLC programming courses.

Let’s get started!

Ladder Logic PLC Programming Tutorial

What is Ladder Logic?

Ladder logic is a PLC programming language. It is really called ladder diagram or just LD, but most people refer to it as ladder logic. That is also what I will call it in this tutorial. There’s a very simple reason for its name. Ladder logic is made out of rungs making what looks like a ladder. It is possible to scale a PLC analog input for example, but ladder logic is mainly for bit logic operations.

The people or the organization that sets the standards for ladder logic is PLCOpen. Ladder logic is not only a programming language for PLC’s. It is one of the standardized PLC programming languages. This simply means that ladder logic is described in a standard. That standard is called IEC 61131-3. But for now, the only thing you need to know, is that there is a standard describing this programming language.

 

Introduction to Ladder Logic

To get you started with ladder logic there are a few things you should know about the programming language. You should know why ladder logic was invented, because then it will be much easier for you to understand it. Especially if you have prior experience with electrical circuits and relays or some boolean logic.

 

Invented for Technicians

Ladder logic is a graphical programming language which means that instead of text, the programming is done by combining different graphic elements. These graphic elements are called symbols.

One of the smart things about the ladder logic symbols is that they are made to look like electrical symbols. Ladder logic was originally created for technicians, electricians and people with an electrical background. People who are used to look at electrical diagrams and schematics.

Take a look at the symbols and see if you think they look familiar.

Just as in electrical diagrams ladder logic have symbols for contacts and relays (which are called coils in ladder logic). The symbols may look a little different from the ones you find in electrical schematics, but they have almost the same functions.

 

How to Read Ladder Logic

Another difference between ladder logic diagrams and electrical schematics is the way they are drawn. Where electrical schematics is often drawn horizontal, ladder logic diagrams are drawn vertically.

The best explanations for drawing ladder logic vertical instead of horizontal I can give you are these:

1. Easier to read

First of all it makes ladder logic easier to read because it is natural for the eye to go from the left to right and then down to the next line. Just like when you are reading. Of course this applies only to people living in countries where the reading is done from left to right.

2. Drawn on computer

When you draw ladder logic on a computer you will make one line at a time. As you draw more and more lines (in ladder logic called rungs) they will stack on top of each other, making up what looks like a ladder. The best way to look at a large ladder diagram with many lines is to scroll vertically along the screen.

3. Order of execution

The last reason for drawing ladder logic horizontal is to set the order of execution. Order of execution is how the PLC will run your ladder logic. To be more precise in what order your ladder logic instructions will be executed by the PLC. A PLC will always start at the top of your ladder logic and then execute its way down.

Relay Ladder Logic

As I said before ladder diagrams can look a lot like electrical schematics going vertical. Most people learn to draw ladder logic diagrams this way – by building them as electrical schematics. But there are some differences. This is why I will advice you to learn it in a different way.

I will explain this way in this ladder logic tutorial.

The problem here is that electrical control systems and the PLC works in different ways. Here are the biggest differences:

  • The PLC takes one ladder logic line (rung) and executes that and then goes to the next line
  • In electrical systems multiple lines (current pathways) can be executed (activated) at the same time

With these crucial differences in mind, let’s get into it. It’s time to learn some ladder logic.

Ladder Logic Basics

The first thing you will see when you create a new piece of ladder logic are two vertical lines. It is in between these two lines your ladder logic goes. When you draw ladder logic, you will draw vertical connections between these two lines. Each of those are called a rung. Just like on a physical ladder.

Ladder Logic with Horizontal Lines called Rungs

 

In these rungs you can put any of the ladder logic symbols to create the logic you want. As you can see above, I have put numbers on each rung. This is to understand how the PLC will execute the ladder logic. You may be familiar with the PLC scan time or scan cycle. Roughly said, the PLC will first scan all it’s inputs, then execute the program to set outputs.

But how does the PLC execute our ladder logic?

One rung at a time.

This might be one of the most important rules of ladder logic. The PLC only executes one rung at a time, then executes the next. In fact, the PLC only executes one symbol at a time.

 

Ladder Logic Programming with Instructions

Each symbol in ladder logic is an instruction. This can, in the beginning, be rather confusing. But don’t worry. I will explain this with simple examples. Let me start by giving you a simple example. In this first example you will be introduced to the two first ladder logic symbols.

So what are these instructions or symbols?

They are basically logic instructions, that makes you able to create a piece of logic. That piece of logic is your ladder logic or PLC program. If you take a closer look at the example below, you will see two instructions (symbols).

Two Instructions in One Ladder Logic Rung

 

Examine if Closed

The first instruction here is called examine if closed. The symbol for the instruction looks like this:

Examine if Closed Instruction

This is a conditional instruction. It means that you can use it to check if something is true. For example check if a bit is on.

As you can see there is a name above the instruction symbol – I0.0.

This is the address of the specific bit, this instruction will examine. In this case, a digital input. It could also just be an internal memory bit or even an output.

Examine if closed is also known as normally open. It works basically the same way as a normally open contact in en electrical circuit. Of course, the normally open contact has no memory bit as a condition. The condition is whether the contact is activated or not. So the condition could be a finger pressing a button.

The main point here is that, each instruction has to be assigned an address in the PLC.

Yes, inputs and outputs are also bits of memory in the PLC. In the example above, the examine if closed instruction has been given memory address I0.0 as a condition. This address belongs to the first input of the PLC.

Here’s how that works:

  • When the PLC scan cycle starts, the PLC will check the states of all its inputs.
  • It will then write in memory the boolean value for these states (0 or 1).
  • If an input is LOW the bit will be set to 0.
  • And if an input is HIGH the memory bit will be set to 1.

Output Coil

The instruction itself even has a place in the PLC memory. What the PLC will put there is the result of the instruction. To see what the PLC uses that result for, we have to look at the next instruction:

Ladder Logic Output Coil

 

An output coil is used to turn a bit on and off.

As you can see, the symbol is placed in the right side of the rung. This means, that all the instructions that come before (in the same rung) act as a condition for that instruction. In our example that will be the result of the examine if closed instruction.

Let’s check out what the results of that instruction could be, to see how it works:

  1. PLC scan | Inputs -> I0 byte
  2. Program runs | I0.0 -> XiC result

Ladder Logic Inputs and Outputs with PLC scan

 

In the animation above you can see that the PLC first scans all its inputs. The states of these inputs are then saved in a memory byte. A memory byte is just 8 bits next to each other. For now, you don’t have to think too much about it. But placing the bits next to each other is very smart. I’ll come back to that later.

When the PLC has the states of all inputs saved, the program will start to run. First instruction to be executed is the examine if closed (normally open). The result of this instruction will be the same as the state of the memory bit. It makes sense to call the instruction normally open. In a normal state (where the memory bit is 0) the contact will be open, and the result be 0. But if the memory bit is 1 the contact will close and yield the result 1.

At last, let’s look at the output rung:

  1. XiC result -> Output coil
  2. Output coil -> Output byte

Now, the output coil uses the result of the previous instruction as a condition.This is called RLO (result of logic operation). The RLO is stored in a special place in PLC memory. In Siemens S7 PLC’s that place is called the status word.

A word in PLC terms is 16 bits next to each other or 2 bytes.

The output coil works in a simple way. It simply sets the bit to the same value as its condition (RLO).

In the PLC all the digital outputs are also assigned to bits in memory. We’ll call that the output byte (Q0), so the bits Q0.0 – Q0.7. The result of the output coil will be put in memory bit Q0.0.

When the PLC has executed the whole program, it will set the outputs. The state of each output is set to the same state as the output bits.

This whole scan cycle is very important to keep in mind, when you’re programming in ladder logic. Otherwise, your program might act a bit strange. This will be illustrated in the next example. At the same time, you will also learn about 3 other ladder logic instructions.

 

Output Latch

In the previous example, you learned how to read the state of a digital input and set a digital output to the same state. Let’s say that digital input is a momentary pushbutton. It is called momentary because it has a spring inside. This means, that the pushbutton will only be active as long as you press it.

The ladder program above works just fine. But as you might have noticed, the output will only be active as long as the input is active. You will have to hold your finger on the button to keep the output activated. But let’s say that the output controls a fan for a ventilation system. It would not be very convenient for the operator to hold down the button all the time. We need a way to keep the output active, even though the operator releases the pushbutton.

In ladder logic there are two ways to do that:

Output latch in ladder logic

 

If you are familiar with electrical schematics, you may find this familiar. This is called a latch or a self-hold.

The name reveals how this works. The coil simply holds itself. Let’s take it step-by-step to see how that works:

When the PLC runs this ladder logic program the first time (with the button pressed), the output will be activated. This is just like the example before. The fun happens the second or third time the PLC runs the ladder logic. Since this is a momentary pushbutton, it will not be active for long. Depending on how long time the PLC takes to execute the program, the button might be deactivated again the second, third or fourth time.

Let’s jump forward to the first scan cycle where the button is no longer pressed.

The output is still active, since the pushbutton was pressed in the last scan cycle. This time the PLC will, again, read the inputs and save them in the memory byte. In memory bit I0.0 the PLC will now save a “0”. The first examine if closed instruction with I0.0 as condition will be evaluated to false or “0”.

But as you can see, there’s another examine if closed instruction parallel to the other. But this one has the output memory bit as condition. This will therefore be evaluated as true or “1”, since the output is still active. As long as the output memory bit is “1”, the output will be activated. It acts as a condition for itself.

The reason that the self-holding instruction is put in parallel to the other instruction is to make it an OR condition. I will come back to that later. Important to know here is that either I0.0 OR Q0.0 has to be true to activate the output.

 

Examine if Open

Well, congratulations!

You just learned how to make a functioning ladder PLC program. A pushbutton that activates an output. In our example this would be connected to a contactor giving supply to a fan. The output then holds itself.

But there is a practical problem with this program. How do we stop the fan?

We want, somehow to be able to turn off the output again. The simplest way to do that, would be to add a stop button. The button will be connected to the second input. Thereby giving it the memory address I0.1.

The question is now; which instruction should we use for the stop button?

And even more important; where should we place it in out ladder logic?

To answer the first question, let me introduce you to another ladder logic instruction: examine if open.

Here’s how the examine if open symbol looks like:

Examine if Open Instruction

 

This instruction works the exact opposite way of the examine if closed instruction. The result of this instruction will be the inverted condition. It simply means that, if the condition is “0” the result will be “1”. Vice versa of course, so with condition “1” the result will be “0”.

If you think about it, this is precisely how we want to stop button to work. To turn off the output coil we must somehow give it the condition “0”.

Now to the second question. Where to place it?

We have to place it after the self-holding instruction. Said in another way – serial connected. Otherwise the latch would still give a “1” condition to the output coil, when stop button is pressed.

Now, we end up with this ladder logic:

Output latch with XIO to break the latch

 

You can see that it inverts the condition to the output coil. This will break the latch. To activate the latch again, the start button has to be pressed.

In the example above i used the examine if open instruction for a stop button.

This is not good practice!

Because in order for the stop button to work when its pressed, we have to use a normally open contact on the button itself. You can read more about why you have to use normally closed contact for stop buttons in my article about it. In short, it is to make sure that the system stops when a wire to the button breaks.

After using this good practice our ladder logic will look like this:

Output latch with stop

 

Although we changed the instruction, the ladder will still work in the same way. It’s because we also changed the way the physical stop button works.

You now learned how to set an output and hold it until a stop button is pressed. But there are other ways to do this. Latching is not the only way.

For Further Information Call@ +91-9555405045/+91-9718474287

or Visit: http://www.innovicindia.com

 

 

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Job Opportunity for Engineers having more than 2 years Gap after Engineering

Are you a BE/B.Tech or Diploma Pass out Engineer? Having 2 years or more career gap?
Don’t worry, just forget the gap.

golden opportunities for the engineers having career gap more than 2 years. (2)

Innovic India Pvt. Ltd., a leading training and placement company in Delhi NCR starts an unique skill development program for engineers having more than 2 years gap. This program is for those Electrical, Electronics, Mechanical & Instrumentation Engineers who has completed their BE/B.Tech/Diploma in 2016 or before that. The aim of this Skill Development training program is developing employable engineering skill for Industry.

Innovic India does not give only theoretical training but Industry Need Based  Skill Developement Training. Innovic India provides Industry Need Based Skill Development Training on PLC, SCADA, Drives, Panel Designing, Auto-CAD and MS-Projects, Embedded, VLSI, Robotics and Designing so that Fresher Electrical, Mechanical, Electronic and Instrumentation Engineers having more than 2 years gap can get easily placement in the Industry as per there requirements and qualifications. Before Innovic India, automation training was just a lab based theoretical training. Innovic made automation training as an Experience Added Working Training in Industrial Automation field. through which engineers having gap more than 2 years can get job easily.

For more details, Contact us on, +91-9555405045/+91-9718474287.

 

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Applications of SCADA

SCADA is widely used in different areas from chemical, gas, water, communications and power systems. The list of applications of SCADA can be listed as follows.

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1. Electric power generation, transmission and distribution: Electric utilities use SCADA systems to detect current flow and line voltage, to monitor the operation of circuit breakers, and to take sections of the power grid online or offline.
2. Water, Waste Water Utilities and Sewage: State and municipal water utilities use SCADA to monitor and regulate water flow, reservoir levels, pipe pressure and other factors.
3. Buildings, facilities and environments: Facility managers use SCADA to control HVAC, refrigeration units, lighting and entry systems.
4. Oil and Gas Trans & Distributions:
5. Wind Power Generation
6. Communication Networks:
7. Industrial Plans and Process Control:
8. Manufacturing: SCADA systems manage parts inventories for just-in-time manufacturing, regulate industrial automation and robots, and monitor process and quality control.
9. Mass transit and Railway Traction: Transit authorities use SCADA to regulate electricity to subways, trams and trolley buses; to automate traffic signals for rail systems; to track and locate trains and buses; and to control railroad crossing gates.
10. Traffic signals: SCADA regulates traffic lights, controls traffic flow and detects out-of-order signals.

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SCADA in Power Systems:
SCADA is widely used in power systems. The applications for SCADA keep increasing day after day. Some of the applications are:

Comprehensive operational planning and control
Fuel resource scheduling
Optimum power flow
Network security
Economic dispatch
Generation dispatch control

Expected Benefits of SCADA for Power Systems:

Improved quality of service
Improved reliability
Reduced operating costs
Maintenance /Expansion of customer base
Ability to defer capacity addition projects
High value service providers
Improved information for engineering decision
value added services
Flexible billing option
Improved customer information access
Reduced system implementation costs
Reduced manpower requirements

Typical features of a substation SCADA system are as under Substation parameter monitoring:

Controlling electrical network components remotely
Safety tagging
High resolution time stamping
Sequence of event reporting for post event analysis
Additional features of substation control system
Demand side management
Volt/VAR control
Preventive maintenance
Fault detection isolation and restoration

scada

SCADA for Power Utility Network:

The aim of power network utilities(PNU) software is to provide the electrical utility with tools which will enhance the operation of the system in a very cost effective way.in the present scenario of low budgets for power utilities to produce and distribute quality power at the minimum cost.This goal can be achieved by proper operation of the electrical network and at the same time having real time data about state of the network.This real time data can then be used for supervisory controlled changes of
the network parameters with effective guidance from distribution automation tools.The PNU software utilizes the real time SCADA data.the real time network topology network component details & user defined strategies to achieve the above mentioned goals.PNU uses a combination of mathematical and logical techniques to provide the user with a host of applications for the purpose of distribution automation.

Features of Power Network Utilities:
Component Modeling
State Estimation
Bad data suppression
Contingency analysis
Fault isolation/islanding
Load shedding
Volt/Var scheduling
Dispatcher power flow
Short circuit analysis
Network topology processor

Objectives:
There are many objectives of SCADA System.
1. Improved overall System efficiency (capital & energy)
2. Increased penetration energy sources including renewable energy sources.
3. Reduced Energy Requirements in both the Transmission and Generation
4. Increased Relativity of sequence to essential loads.

Components of SCADA:

There are many parts or components of a SCADA system, which include hardware (input and output), controllers, networks, user interface, communications equipment and software. All together, the term SCADA refers to the entire central system. The central system usually monitors data from various sensors that are either in close proximity or off site (sometimes miles away).

An industrial SCADA consisting of the following
1) a central host or master station unit or, master terminal unit (MTU);
2) one or more field data gathering and control units or remotes (usually called remote stations, remote terminal units, or RTU’s);
3) a collection of standard and/or custom software used to monitor and control remotely located field data elements.

Contemporary SCADA systems exhibit predominantly open-loop control characteristics and utilize predominantly long distance communications, although some elements of closed-loop control and/or short distance communications may also be present.
Major components of SCADA:

1) A collection of equipments that is provide the operator at remote location with enough
information to determine the status of particular piece of equipment or entire substation or a plant or a dynamic network and cause actions to take place regarding that equipment or network without being physically present.
2) An arrangement for operator control and separation of remotely located apparatus using multiplexing techniques once a relatively small number of interconnecting channels.
3) Collecting Data from remote electrical equipment and controlling then through suitable communication medium.

Functions of SCADA:
A SCADA system performs four functions:
1. Data acquisition
2. Networked data communication
3. Data presentation
4. Control
These functions are performed by four kinds of SCADA components:
1. Sensors (either digital or analog) and control relays that directly interface with the managed system.
2. Remote telemetry units (RTUs). These are small computerized units deployed in the field at specific sites and locations. RTUs serve as local collection points for gathering reports from sensors and delivering commands to control relays.
3. SCADA master units. These are larger computer consoles that serve as the central processor for the SCADA system. Master units provide a human interface to the system and automatically regulate the managed system in response to sensor inputs.
4. The communications network that connects the SCADA master unit to the RTUs in the field.

If you require more information about SCADA, feel free to Contact us

@+91-9555405045 / 9718474287