Showing posts with label IBMS. Show all posts
Showing posts with label IBMS. Show all posts

Sunday, November 1, 2020

Understand the Basic concept of BMS system

Understand the Basic concept of BMS system 

What is a BMS or Building Management System?
In a nutshell, BMS otherwise called as BAS or building automation is computer-based control system which reduces the manpower, automate the system, and saving the energy consumption in building by monitoring and controlling the mechanical and electrical equipment in modern day buildings or any industrial plants.
Not only that but BMS helps to
·        Increasing productivity.
·        Increasing the equipment lifetime and better performance.
·        Identifying the systems faults earliest.
·        Managing the hotel tenants in an effective manner.
Nowadays any modern-day buildings built with BMS to support facilities management to accomplish the maintenance and save the energy in building from one place of computers.

Any BMS software or system must provide the following facility to the operator

  • Monitoring and controlling connected equipment in the building. 
  • The alarm should be a popup in operator workstation for any critical faults in the system. 
  • Any types of equipment on, off status and alarm should be logged or stored in PC to retrieve later.
  • Scheduling the equipment to on and off automatically by preset time. 
  • User interface graphics should be available in order to visualize the field equipment to monitor for BMS operator easily. 

BMS or BAS system monitor and/or controls the following system in buildings

  • HVAC (Heating, Ventilation, and Air-conditioning or all supply and exhaust fans, ACs etc). 
  • Lighting control system. 
  • Fire alarm system. 
  • Firefighting system. 
  • Security control system. 
  • CCTV system.
  • Lift control system. 
  • Pumping system. 
  • Water tanks level. 
  • Irrigation system. 
  • Electrical meters.
  • Water Leak detection system.
  • Split units. 
  • UPS units.
  • VFD-Variable frequency drives. 
  • VRF/VRV-Variable refrigerant flow or volume (both are same but each term copyrighted by a different vendor) 
  • And any other system which has provision for BMS to control and monitor. 

Main components of the BMS System

1.     Hardware
·        DDC-Direct digital controller
·        Sensors
·        Actuators
·        Cables to connect sensors, actuators to DDC.
·        HMI display-Human machine interface.
·        PC Workstation
·        Server to save the large database.
  1. Software
  1. Networking protocols
·        Programming or configuration tools.
·        Graphics or User interface.
·        TCP/IP– Transfer control protocols/Internet Protocol.
·        BACnet– Building automation controller network-ASHRAE
·        Modbus
·        LONworks
·        CANbus
·        and numerous protocols available.
Don’t worry about the various protocols, this all protocol doing the same task to transfer data from one device to another device. 

BMS System architecture in the modern-day building

However, BMS System controls and monitor all the electrical and mechanical systems in buildings from BMS workstation or HMI(Human Machine Interfaces), but not directly because each system has its own functionality and unique purpose like

  • HVAC System helps to facilitate and provide comfortable and healthy air conditioning to tenants.
  • The lighting control system which has a variety of lightings in buildings that needs to be on and off effectively and save energy while tenants not available.
  • CCTV helps to facility management to secure the building
  • Access control systems may also be used to control access into certain areas located within the interior of buildings.
  • A fire alarm system is the life safety system to warn people by audio and visual to protect their lives from fires, smoke, carbon mono oxide and other toxic elements for the human.
  • In case of fire Firefighting system aims to protect human life and property in the building by a large amount of water and other gas.
  • UPS is to provide to the uninterrupted power supply in the building for electrical equipment.
  • Pumping system used in the building to pump the water to the required area.
  • still tons of systems evolved in the modern-day building to facilitate the people.

All systems have its own controllers and processing system due to the different functionality of each system.

So BMS controllers or device designed for controlling and monitoring the HVAC system and other small systems and integrate all other systems through dedicated networking protocols like BACnet, Modbus etc.

General BMS System architecture with Levels

  • Management Level: This is the front end for operator and engineer used to visualize the graphics for controlling and monitoring the systems which have computer workstation, server, web browser, printers.
  • Automation Level: BMS Router and other main controllers connected in building network integrate third-party system and connect BMS devices
  • Field devices Level: this is Level where BMS controllers connect to field systems sensors, actuators, and other panel circuits to monitor and control.

Simple Real Time example for BMS System

Any modern day building client provides huge specifications for BMS System, whereas here I am going to take simple requirement to monitor and control the sequence of Air Handling unit. 

Let us see below the requirement of the client to monitor and control the sequence in BMS System.

Before we go detailed about how to design the BMS System for the requirement. let us see some basics components of the AHU-Air handling unit.

AHU is an HVAC system which consists of the duct, fan, filter, cooling coil, heating element,humidifier, sound attenuators, dampers, valves and many more to regulate the air into the room by heating, ventilation and conditioning to distributes the conditioned air through the building and returns it to the AHU and also called as centralised AC in modern-day building.

Duct – It is the collection of metallic tubes that interconnected and distributes the heated/cooled air to the required rooms.

In order to monitor the duct air temperature in fresh, return and supply duct. we have to install the duct temperature sensor in the duct.

Fan Motor– Blower is used to circulate the air from fresh and return duct to the supply duct.

This fan motor controlled and monitored by the separate electrical panel by the designed electrical circuit with help of electrical relay and contactor and providing an option to BMS system to
  • On/Off the fan.
  • Monitor the fan running status.
  • Monitor the Fan motor overload fault status and many more.

Filter– It is one of the main components in AHU to prevent the dust and dirt particles to enter in the AHU.

When the AHU fan motor started, the fresh outside air supplied into the duct where filter components used to filter the dirty particles continuously and in order to monitor the filter extreme dirty condition,

DPS switch is used to install across the filter and provide a signal to BMS when the filter gets dirty(technically DPS-Differential pressure switch will send the signal to BMS when the pressure reached more than pre-set across the filter and this same function can be used to monitor the fan status.

Now we Read about How DPS used to monitor fan and filter status

Heating/Cooling element- It is used to cool or heat the water that entered in the coil so that air in the duct can be heated or cooled based on the user requirement.

Either heating or cooling water enters into the coils are controlled and monitored by valves on the pipe with help of valve actuator.

Dampers- An HVAC damper is a movable plate, located in the ductwork, that regulates airflow and directs it to areas that need it most.

Damper opening and closing position controlled electrically with the help of damper actuators and this actuators have terminal for control from BMS and terminal to monitor the feedback of position.

System Description:

The variable speeds Air Handling Units are used to serve air conditioning need for all area of buildings

The Air Handling Unit comprises:

·        Variable Speed Supply Fan

·        Chilled water coil with the 2-Way modulating control valve

·        Duct mounted supply air pressure sensor

·        Outdoor & re-circulating Air modulating damper

·        Carbon dioxide sensor.

·        Supply and Return Air temperature sensors

·        Supply air differential pressure switch

·        Differential pressure switches for 2 set of filters

System Monitoring and Alarm:

      ·        Software alarms shall be generated at the operator workstation whenever the run status of the supply fan (with differential pressure switch) does not match the current command state.
·        A failure alarm shall occur when the run status of the load shows no operation and the load has been commanded to be on.
·        An advisory alarm shall occur when the run status of the load shows operation and the load has been commanded to be off. All alarms shall be recorded in an alarm log for future review. Provide 15 seconds (adjustable) time delays before generating an alarm.

The sequence of Operation

a. Auto Mode:

When the AHU start is in AUTO mode (i.e. selector switch installed in the MCC must be in Auto Position), the unit is started and stopped from the BMS via a time schedule or BMS override command. When the start for the AHU is initiated, the control program residing in the controller follows the following sequence

Start-Up:

The following sequence follows with a preset time interval per interlock equipment start-up:
1) Check Supply fan trip signal – Normal State
2) Supply Air Damper –Open Position
3) Outdoor Air Damper –Open Position
4) Return Air Damper – Open Position

5) Once the above conditions are satisfied, AHU is enabled to start in Auto mode or using a plant enable button on the graphics in manual mode by the operator. Once enabled, BMS will automatically command supply fan to start.

6) Supply Fan shall start and it’s associated Interlock equipment in sequence. Through the signal from the Diff. Airflow Switch, if airflow is detected, the System will continuously run, if No airflow is detected by the DP Switch, the Supply Fan will de-activated and send an Alarm to the DDC – for “No Airflow” and shut down the whole system including its associated interlocks. If the Air flow switch signal is proved ‘ON’ then BMS will enable control loops.

b. Shutdown Mode:

When the shutdown command for the AHU is initiated, the control program residing in the controller follows the following sequence.
1) Send Stop command to stop the supply fan
2) The outdoor air, return and supply air damper move to close
3) Move chilled water valve to close position

c. Manual (Hand) Mode:

When the AHU is the manual mode, the fans are started and stopped from the AHU control panel. Other control except for fan on/off control shall function as per the Auto mode.

d. Fire / Smoke Mode:

Fire condition is determined by the Fire Alarm Control Panel. AHU will automatically shutdowns the whole system with associated interlocks.

AHU Control

The control program, on the feedback of air handling unit operation, initiates the control algorithm. This algorithm consists of three controls. Each temperature, pressure and ventilation control has its own control loop. The pressure control loop is used to modulate the speed of the supply air fan hence supply air flow. The control loops design to function as per following explanation:

a. Temperature Control loop:

The supply air temperature installed in the duct will relay the measured signal (temperature) to the DDC controller, the DDC controller compares this signal with set-point (adjustable by the operator from BMS central) and generates an analog output to the 2-way modulating cooling valve. Based on the difference between the two values, a proportional-integral program will determine the percentage of the cooling coil valves opening to achieve the desired condition. The default set-point value for the supply air temperature is 13ºC (Adjustable).

b. Pressure Control loop:

The supply air pressure sensor shall be installed in the duct  will relay the measured signal (static pressure) to the DDC controller, the DDC controller compares this signal with the set-point (adjustable by the operator from BMS central) and generates an analog output to the variable frequency drive (VFD) of the supply air fan. Based on the difference between the two values, a Proportional-Integral program will determine the percentage of the fan speed to achieve the desired pressure. The set-point value for the supply air pressure for each AHU shall be adjusted.

c. Ventilation Control loop:

Demand control ventilation employs return air carbon dioxide controlling strategy.

A single carbon dioxide sensor sense carbon dioxide concentration in the return air duct and sent to the DDC controller, the DDC controller compares the signals with return air carbon dioxide concentration (Default carbon dioxide level difference value 400 ppm).

Then DDC controller generates an analogue output to the outside air dampers and returns air damper to modulate, based on the difference between the values, the Proportional integral program will determine the percentage of the modulation of outdoor and return air dampers.

Minimum outdoor air quantity shall be governed either by building pressurization requirement (Input from Building differential pressure sensor) or 20% of the Maximum outdoor requirement of the AHU.

Alarms:

The following minimum alarms shall be generated on BMS
1) Filter Dirty Alarm: This is generated when pressure drop on each filter exceeds the set value to indicate dirt accumulate at filters.
2) Fan Trip Alarm: A normally open “NO” volt free contact at the MCC panel when closed will generate an alarm at the BMS indicating that the fan is tripped
3) Fan Fail: In case the supply air fan fails to start or if the differential pressure switch across

supply fan is not giving the signal according to the command due to any reason then alarm shall be generated. In case of a fan fail alarm on the BMS, due to abnormal behaviour, the DDC controller will latch the alarm. The operator has to acknowledge (reset) the alarm on the BMS once the trouble has been checked and removed. The operator shall not be able to start the AHU until the alarm s acknowledged and reset.

4) Temperature High & Low: Temperature HIGH and LOW alarms shall be generated if the supply/return air temperature rises above or falls below the supply /return air temperature alarm limit.

List of Input and output points are required for the above-discussed sequence of operation for AHU

Some basic terms of digital electronics

  • Analog Input: Analog inputs can come from a variety of sensors and transmitters. You can measure a whole bunch of different things. The job of the sensor or transmitter is to transform that into an electrical signal. Here are a few of the things you can measure with analog sensors:

·        Level

·        Flow

·        Distance

·        Viscosity

·        Temperature

  • Digital Input: It allows a microcontroller to detect logic states either 1 or 0 otherwise called as VFC-Volt free contact.
  • Analog Output: In automation and process control applications, the analogue output module transmits analogue signals (voltage or current) that operate controls such as hydraulic actuators, solenoids, and motor starters.
  • Binary Output: it is nothing but relay output from the controller to trigger on and off any equipment.

Now its time to choose the DDC controllers based on the above input and output point list.

Any BMS controllers manufacturer must have the basic controllers types of analogue input-output, binary input, and output controllers either dedicated controllers or mixed of all types in a single controller.

For the above applications, we need to choose controllers that should accommodate 17 AI, 6 BI, 5 AO, and 1 BO(Note that temperature and humidity are two different analogue input)

Once controllers are designed, we need to calculate power load for each controller (available in controller datasheet) and field devices to choose the right transformer rating for our DDC panel.

Next things are to write a program for our controllers to accomplish the above sequence,

First, we need to change English words into the flowchart then we can change it later on the different programming language that required for BMS vendors either ladder logic or functional block or plain English and etc.

Whatever it is any BMS program functionality that will not go beyond the basic digital logic gates.

Flowchart for AHU Control sequence of operation




Monday, November 11, 2019

Increase of BMS cables sale

Increase of BMS cables sale

The global IBMS market is highly fragmented with the presence of several global and local vendors. Global vendors mostly operate as original equipment manufacturers (OEMs), catering to the requirements of the end-user through distributors/dealers or system integrators. Technical knowledge and ability to customize based on end-user requirement by vendors will hold the key to a strong foothold in the market.

Building management system cables also commonly known as BMS cables, intelligent building cables or automation cables are used to automate all of the systems in place within a building or home. Research suggesting the BMS market will reach $19.25 million by 2023; it’s even more of an opportunity for electrical contractors to capitalize.

The global IBMS market will continue to grow at a healthy pace throughout the forecast period. Apart from energy and cost savings, other important drivers are the degree of flexibility provided by open IBMS solutions, the high degree of productivity it provides, and a higher return on investment along with enhanced security. These factors are attractive to many businesses, thus driving the market growth.

An advance Building Management System can control the safety in homes and offices, monitoring doors and windows for alarm systems and detect floods and fires. Equipment and installations are designed for the control, monitoring and optimization of various functions and services provided in a building that includes: heating, ventilation, air-conditioning, lighting, security systems and the operation of electric / electronic applications. 

A shielded cable that is not grounded does not work effectively. Any disruptions in the path can raise the impedance and lower the shielding effectiveness. Firstly make sure you have a cable with sufficient shielding for the application's needs. In moderately noisy environments, a foil alone may provide adequate protection. screened cable (plural screened cables) Wire for the transmission of electricity or electronic signals, protected by an enclosing web of earthed wire mesh to avoid electromagnetic interference from (or to) other signals. Grounding: a point in contact with the ground, a common return in an electric circuit and a arbitrary point of zero voltage potential. It also provides personal safety and protects the equipment. Control the voltages developed on the ground when the earth-phase short circuit returns through a near or distant source. Provide a stable voltage reference to signals and circuits. Minimize Electromagnetic Emission (EMI) effects.

Shielding: The shield must be connected to the signal reference potential of what is being protected. When there are multiple segments keep them connected, ensuring the same reference potential. The shielding is only efficient when it establishes a low impedance path to the ground. A floating shielding does not protect against interference. The use of non-magnetic metals around conductors does not shield against magnetic fields.

The cabling of the industrial communication systems (Modbus RS485) is different in some ways from the cabling used for power cabling and the electrician may experience some difficulties if he is not an expert in Modbus communication networks. A Modbus RS485 connects a Master device to one or more Slave devices. Henceforth, we shall consider Slave devices to be measuring instruments with serial communication, even if the cabling is similar for all Modbus devices.

Cable Selection
You should consider the following:
·         How many conductors do you need?
A minimum of three conductors, but the shield may be used as the common conductor, so shielded two conductor cable may be used. If you do not use shielded cable, then at least three conductors are required. Some RS-485 devices do not use a common connection, but we recommend always connecting common for reliable performance and to avoid damage due to surges.
·         What wire gauge do you need?
·         For unterminated networks, the current will generally be less than 10 mA and any gauge should work; we recommend #24 AWG to 18 AWG.
·         For terminated networks, the current can be 60 mA or higher, so heavier gauge wire may be needed for very long runs.
·         We recommend #22 to #20 AWG for runs up to 1000 ft. (~300 m).
·         We recommend #20 to #16 AWG for runs up to 4000 ft.(~1200 m).
·         What should the cable impedance and capacitance be?
Cables suitable for use in an RS-485 network should have an impedance of between 100 and 130 ohms, a capacitance between conductors of less than 30 pF per foot (100 pF per meter), and a capacitance between conductors and shield less than 60 pF per foot (200 pF per meter).
·         Do you need shielding?
Because RS-485 is differential, it is less susceptible to interference, so shielding is not always necessary. However, we recommend shielding for long runs and if there is electrically noisy equipment nearby like variable speed drives. If you use shielded cable, connect the shield to earth ground at one end (generally the PC or RS-485 master).
·         Do you need twisted wires?
Yes, especially for non-shielded cable.
·         What voltage rating do you need?
We recommend wire or cable rated for the highest voltage present. So if you are monitoring a 120/208 Vac panel, you should use 300 V rated cable. If you are monitoring a 480Y/277 volt circuit, use 600 V rated cable. If you have the WattNode in a separate enclosure and there is no way the mains wires can contact the Modbus output cable, then you could safely use lower voltage rated cable, such as 150 V or lower. Long runs of 300 V or 600 V rated cable may be expensive, so it may be more economical to use lower voltage rated cable and use a protective jacket in the regions where the cable is in the vicinity of dangerous voltages.
·         Can you run the RS-485 network cable adjacent to or in the same conduit with mains wires?
We strongly recommend against this. There may be interference from the high voltages and currents present on the mains wires, and if there is any insulation fault, arcing, etc. on the mains wires, it could put dangerous voltages on the low-voltage RS-485 network cable.

Most modern buildings now incorporate some form of BMS, focusing primarily on energy efficiency and saving costs. Whether that’s through proximity sensor lighting, climate control, door entry or security, they all work to achieve the same goal.

Efficient lighting control in a BMS system is just one way of reducing energy and saving costs for building owners. Using BMS, lighting can be automatically adjusted, depending on natural light detected or amount of people in the building. These cables are available in Low Smoke Halogen Free (LSHF), meaning they give off minimal smoke and toxic fumes. This is ideal for installation in public buildings such as schools, hospitals or airports where evacuation may be difficult in the event of a fire.

Unlike what happens in many energy distribution systems, the manner in which the devices are connected in parallel is important. The RS-485 system used for Modbus communication provides a main cable (Bus or backbone), to which all the devices have to be connected with branches (also known as stubs) that are as short as possible. The branches must be no longer than 1200 mtr.
Maximum distance and maximum number of devices. The main cable must be no longer than 700 m! This distance does not include the branches (which must nevertheless be short). The maximum number of devices that can be connected to a main cable is 32, including the Master.


In order to increase the extent of the Modbus network, repeaters can be used; and signal amplifying and regenerating devices provided with two communication ports that transfer to each what they receive from the other.
The cable shield must be earthed only in one point. Normally, this connection is made at one end of the main cable.
In order to avoid signal reflections, a 120 Ohm termination resistance must be fitted on each end of the main cable. The end resistance must be used only at the ends of the main cable. If the total length of the main cable is less than 50 m termination resistances can be avoided at the ends of the main cable.
Fire safety is another major reason why owners may consider installing a BMS system into their building. High performance fire survival cables provide an excellent solution for connecting BMS with fire systems. The data and coaxial ranges are designed to carry on functioning in the event of a fire and provide vital signals to voice alarm, CCTV and allow systems to be shut down in an orderly fashion. Meeting specific fire resistance requirements.