Our client is a leading solutions provider in the Radiant cooling and heating industry. They are awarded the prestigious WWF Climate Solver for their radiant cooling solutions. Over a decade, they have provided innovative, sustainable, and scalable energy efficiency solutions in various sectors ranging from Pharma, Food, Construction, IT, Manufacturing, Warehousing, Defense, Power, etc.
Challenge
Radiant cooling systems are an efficient and effective way to regulate the temperature in a building or space. These systems work by circulating cool water through pipes or tubes beneath a structure’s floor, walls, or ceiling. This cool water absorbs heat from the surrounding air, helping keep the space comfortable. The challenge with radiant cooling systems is accurately monitoring and controlling the temperature of the floor surface. If the floor is too cold, it can be uncomfortable for occupants and may result in decreased energy efficiency. On the other hand, if the floor is too warm, it may not effectively cool the space. Another one is to monitor the temperature for a wide floor surface area.
To address the challenge of accurately monitoring and controlling the temperature of a radiant cooling system, a custom solution has been designed using Bluetooth Low Energy (BLE) surface temperature beacons, a wireless thermostat, and a 7-channel actuator controller (gateway).
Install BLE surface temperature beacons on the floor in a representative location. These beacons continuously measure the temperature and transmit the readings at a fixed interval (1 minute by default).
Data received from wireless surface temperature beacons are sent to the thermostat, and the thermostat will transfer the data to the 7-channel actuator controller (gateway)
Program the wireless thermostat to control the temperature of the space based on the temperature readings from the wireless surface temperature beacon and to measure the space’s humidity to prevent floor condensation.
Program the 7-channel actuator controller (gateway) to receive temperature readings from the thermostat and to control the flow of cool water through the radiant cooling system based on these readings.
Monitor the system’s performance using the thermostat and the 7-channel actuator controller (gateway). Adjust the settings as needed to ensure that the floor’s temperature is maintained within a comfortable range.
This solution offers precise temperature control, energy efficiency, comfort for occupants, and easy maintenance and calibration. By accurately controlling the floor’s temperature, the radiant cooling system can operate at maximum efficiency, reducing energy consumption and costs while ensuring the comfort of the space’s occupants. Wireless technologies also simplify the installation and maintenance of the system, as it eliminates the need for wiring between the various components.
Outcome
Precise temperature control: The wireless surface temperature beacon allows for real-time temperature monitoring of the floor surface, ensuring that the radiant cooling system operates optimally.
Energy efficiency: By accurately controlling the floor’s temperature, the radiant cooling system can operate at maximum efficiency, reducing energy consumption and costs.
Comfort: By maintaining a comfortable temperature range, the radiant cooling system helps ensure the convenience of the space’s occupants.
Easy maintenance and calibration: The BLE surface temperature beacon, thermostat, and 7-channel actuator controller (gateway) are easy to access for maintenance and calibration, ensuring the system operates at its best.
You will discover that nearly every industry around you runs through a SCADA system. It is a system upon which all industrial work largely relies. We can even say that SCADA is an automated control system that gives managers information about the state of the enterprise. It is operated in nearly all industrial verticals to access the whole plant from the control room. Let’s learn more about SCADA and its existence in previous years.
Before SCADA, the Industrial Revolution took a dramatic turn in the form of Industry 3.0, which began with partial automation, with industrialists using memory-programmable controls and computers. During this revolution, the Internet was a breakthrough for everything around us. The invention of computers and software has been hailed as revolutionary and led to task automation, also known as intelligent automation.
About SCADA
The SCADA system is the supervisory control and data acquisition system of software and hardware that allows enterprises to manage processing from regional and outlying locations. It helped industries monitor and control industrial equipment in every segment, like development, manufacturing, production, and fabrication. Many sectors like water, wastewater systems, power, oil and gas, manufacturing, and food production use SCADA systems to collect, monitor, and real-time data. Furthermore, with the introduction of SCADA, it was much simpler to manage industrial processes and directly interact with devices like valves, pumps, & motors.
A basic SCADA system comprises to form a functional SCADA system.
A human-machine interface is an input-output device allowing a human operator to control the data.
The supervisory system approach is a communication server that connects the human-machine interface with other equipment like plc and sensor devices.
Remote terminal units transmit the recorded data to the supervisory systems.
Programmable logic controllers (PLCs) work through sensors and provide real-time industrial processing monitoring.
Communication infrastructure
SCADA programming
How does the Scada system work?
Data Acquisitions:
SCADA systems are essential and reliable because they provide a wealth of data to make intelligent business decisions. Sensors, controllers, and real-time units play an important role in data collection. The real-time system consists of many sensors that collect real-time data. And for the whole system to work perfectly, it is essential to monitor these sensors.
Data Communication:
SCADA uses a wired network for communicating effectively between sensor devices and users. It securely fetches data from sensors for effective data communication and improves efficiency.
Data Presentation:
Since a large amount of data are collected via sensor devices, converting this data into valuable information evolves the most critical task. As it becomes complex to handle a large no. of sensors simultaneously, At the same time, the SCADA system uses a human-machine interface (HMI) to collect all sensor data and convert it into usable information.
HMI:
As SCADA utilizes Human Machine interfaces, the communicated data ought to be observed by humans. It delivers access to numerous control units and PLCs.
Controlling and monitoring :
SCADA systems use controllers to operate each device. These controllers help turn ON/OFF each device, and it works automatically without human intervention, but in specific conditions, it is to handle manually.
Regarding technology, the future of industrial automation is evolving, so robots are replacing people. And now, it is the time for a more extraordinary revolution with the introduction of Industry 4.0
IoT is an evolved concept that enterprises now widely accepted due to sensor-based techniques and data-driven methods. It allows manufacturers to develop their business reasoning and improve their loopholes to serve better quality. For example, if a SCADA system produces complex reports, an IoT solution can improve the format and deliver them more simply and efficiently. Moreover, technology solutions help to share information directly with the head office or any specific person.
How is IoT Carried over SCADA and PLC?
Programmable logic controller(PLC) is the technology that has been a pal to SCADA Over the past few years. But obsolete because of technical improvement. It can automatically initiate and prevent operations and generate alarms if a malfunction occurs. Even PLCs acquire data from sensors, which process and dispatch it further per the programmed parameters.
Most of the statistics from many industries have concluded that the power of SCADA systems was essential to the Industry 4.0 revolution. Still, it is limited to having an utterly connected ecosystem to handle the rest of the business. However, the Industrial IoT (Internet of Things) has entered the market and has evolved into a superior technology compared to traditional SCADA and PLCs. Undoubtedly, its intellectual capabilities are easily adaptable to today’s modern industries.
The Industrial Internet of Things emerged as a technology implemented on top of SCADA. Parameters such as scalability, and data analytics, appeared with the advent of disruptive IoT technology.
The Internet of Things has brought a wave of new business to change the SCADA landscape. The data generated by SCADA systems is still the data source for Industrial IoT. Industrial IoT focuses on analyzing detailed machine data to improve performance, whereas SCADA used to focus on monitoring and control.
How IoT Differs from SCADA
Features
SCADA
IOT
1
Scalability
In SCADA systems, due to the standard architecture, when the number of users increases, it stains performance drastically. It also carries comprehensive reports from factories in different nations and areas from the significant plant.
IoT can receive and process a vast amount of sensor data and allows you to connect everything that matters using protocols such as MQTT, HTTPS, XMPP, COAP, REST, Etc. which provide on-demand scalability through a serverless architecture
2
Data Analytics
The primary SCADA usage is for day-by-day plant operation and ingestion and storage of a finite amount of data without preserving historical data for deeper analytics.
IoT involves long-term data retention to further analyze the data to predict maintenance schedules, reduce overall downtime, and extend equipment life. On top of predictive analysis and preventive maintenance, capabilities are part of it supported by the Machine Learning module.
3
Standardization
SCADA systems mainly use Open platform communications to collect data, a model that has stood the test of time. Still, its main disadvantages are DCOM technology and devices cannot contain/exchange data with each other regardless of the footprint.
The main goal of Industrial IoT is to standardize sensor networks, data collection, and aggregation. IoT standards such as OPC UA are already being used to define secure, real-time communications across the enterprise with various control devices and sensors from multiple vendors. Security is built into IoT standards with support for MQTT, HTTPS, RAML, etc.
4
Interoperability
SCADA systems cannot be easily integrated with devices from different manufacturers. Sometimes even different versions from the same manufacturer make them difficult to interchange. Thus, SCADA provides distributed business processes that operate independently.
Industrial IoT ecosystems remain fragmented, but protocols such as MQTT allow platforms to connect across all devices, regardless of vendor.
What will happen next after comparative analysis?
In summary, both SCADA and IoT involve sensors and data acquisition. They differ in many aspects but share a common goal. SCADA is not a complete control system, but the Industrial Internet of Things comprises many interconnected devices. It enables remote control of appliances across different networks and architectures. But integrating IoT with a SCADA system provides a comprehensive understanding of the entire industrial premises more straightforwardly. In SCADA, while you have to generate analytical reports manually, with an IoT-powered solution, you can automate this process to save time and get quality output.
Our customer is the most significant component manufacturing company with over 50 years of background. It has three main divisions; brake, foundry, and polymer. The comprehensive product portfolio includes calipers, actuation, drum brakes, valves, hose ABS and brake fluid for passenger vehicles, s-cam, hydraulic drum brakes, disk brakes, and electro magnetic retarders for commercial vehicles, and dry and wet multiple plate disk brakes for agricultural tractors.
Project summary :
The company is looking to monitor their resources like energy and water in different cases like
1) Chillers units’ energy Monitoring
2) Overall, factory energy’s monitoring
2) Water monitoring like water consumption and quality
Challenge:
Lack of real-time data – Industries often rely on manual processes for collecting and analyzing data, which can be time-consuming and prone to errors. This makes it challenging to gain real-time insights into operations, leading to suboptimal decision-making.
BT Products we use
LoRaWAN RS485 Transciever
Industrial LoRaWan Gateway
Solution
We proposed a wireless utilities monitoring solution that covers energy and water monitoring based on loRaWan technology along with IoT platform provided in just four weeks. Establish LPWAN networks with our gateways & Rs485 End nodes to collect data continuously from electrical & water meters and get data visualization with clear and insightful analytics to help understand manufacturing usage.
Out comes
Improved efficiency and reliability of utility systems
Reduced downtime and maintenance costs
Enhanced customer satisfaction and service levels
Greater transparency and accountability in the management of utilities
Better data-driven decision-making and planning for future growth and expansion.
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