Boiler Notes 20-21 PDF

Summary

These notes provide an overview of boiler unit operations, including different boiler types, design, working principles, and instrumentation. They cover key components like steam drums, superheaters, and economizers, along with control systems for steam temperature and pressure.

Full Transcript

Unit IV Unit Operations

Boilers
A boiler is a device used to generate steam at desired pressure and temperature by burning
fuel to water to change it to steam.

There are two main categories of boilers, and each can further be subdivided to several types:
 Fire-tube boiler - Hot gas in several tubes is used to heat the surrounding water.
 Water-tube boiler - Water in the tubes is heated by the surrounding hot gas.
Boilers are widely used in domestic and industrial applications such as:
 Thermal power plants
 Industrial processes
 Heating
 Sanitation
 Sterilizing equipment

Water tube boiler design and working

In a typical Water tube boiler design as shown in the figure, it consists of two drums the
steam drum and the water or mud drum. They are connected with number of tubes called as
down comers (which bring down the cold water from steam drum to mud drum) and risers
which carry steam from mud drum to steam drum. The temperature of the steam (being in
contact with water) cannot be increased beyond its saturation point and hence it is separated
from water and separately heated in super heaters (a series of heat exchangers).
The feed water is fed by feed water pump and valve. This supply of water is taken from dm
(demineralisation) plant to avoid scaling.
Water tube boiler parts and their functions

There are many pressure parts and non pressure parts in a water tube boiler we only discuss
main water tube boiler parts and function.
Steam drum
Steam drum is a collection vessel for steam & water. Here water & steam is separated. It has
steam separators. Steam goes from top side to superheater & water goes from the bottom
through down comer Mud drum, then to furnace bottom ring headers (bottom of furnace
water wall).
Super heater
If the temperature of the steam is above its saturation temperature then it is called
superheated steam. The super heater (heat exchanger) is used to increase the temperature of
the steam. These are bundles of high strength tube which can bear temperature 600C
Depending upon the material of tubes
Economizer
Economizer (heat exchanger) is the boiler accessory used to recover the heat of flue gas that
leaving the boiler by heating feed water. The efficiency of a boiler can be increased with an
economizer.
Air Heater
Air supplied to a boiler for combustion is pre heated with the help of air heater by recovering
the heat of waste flue gas that leaves the economizer.
Boiler Fans
For combustion of fuel in the boiler furnace air is drawn from the atmosphere and pushed
through the ducts with forced draught fan to furnace where air reacts with fuel and become
flue gas, the flue gas is then extracted from the furnace with the help of Induced draught fan.
The fan used in large water tube boilers are FD fans, ID fans, Primary air fans, Secondary air
fans and Gas recirculation fans.

Boiler Instrumentation involves control of the following parameters:

1) Boiler Drum level control
2) Combustion Control
3) Steam Temperature control
4) Steam Pressure Control
1) Boiler Drum level control
It must be designed to maintain mass balance so that the drum level remains within limits of
its safe and efficient operation. There are 3 schemes for the feed water control
I Single element control

A single element control only uses the drum level signal as the control process variable. After
calculating the level deviation from the set point, the output of the controller is then passed
to the boiler feed water valve, which then controls the level of feed water flow into the boiler
drum.
Single Element Control recommended on small boilers with a relatively large water volume
and steady loads. This scheme is ineffective control option because of the swelling and
shrinking effect*.

*Swelling and Shrinking effect
As steam demand increases, there is an initial lowering of the drum pressure resulting in an
artificial rise in drum level as the steam bubbles expand and swell the drum water level. This
phenomenon sends a false control signal to reduce feed water flow, when in fact the feed
water flow should be increasing to maintain mass balance. Conversely, on a loss of steam
demand, there is an initial rising of steam drum pressure which acts to lower the drum level
by compressing the steam bubbles and shrinking the drum water level. This sends a false
signal to increase feed water flow when in fact it should be decreasing to maintain mass
balance.
II Two element control
The term 'two-element' is derived from measurement of two variables: steam flow and drum
level that influence on the feed water valve position. It is sometimes referred as a
combination 'feed-forward feedback' system because the steam flow demand is fed forward
and the drum level signal becomes the feedback for controlling/manipulating feed water to
boiler drum.
The two-element drum level control shown in following figure. Steam flow is measured by
the steam flow transmitter (FT-1), its signal is fed to the feed water flow computer (FC-1)
after processing through the square root extractor (FY-1). As in the single-element level
control, the drum level is measured by the level transmitter (LT- 1) and its signal is
transmitted to the drum level controller (LC1).
In the drum level controller, the process signal is compared to the drum level set-point, where
a required corrective output signal to maintain the drum level is produced. This corrective
signal is sent to the feed water flow computer. The feed water flow computer combines the
signal from the two variables, and produces an output signal to the feed water control valve
(FCV- 1).
Auto/Manual transfer of the feed water control valve is accomplished via FK-1.

Two Element Control isl recommended on small to medium boilers with moderate changes in
steam demand.
III Three Element Control

The term 'three-element' is derived from measurement of three variables: steam flow, drum
level and feed water flow that influence on the feed water valve position. Figure below shows
the control scheme for three-element drum level control. To the left of the dotted line, the
instrumentation is the same as that for the two-element drum level control, with one
exception: the output of the feed water flow computer now becomes the set-point of the feed
water flow controller (FIC-2).
Equipment required to complete our three-element drum level control scheme includes an
additional flow device (FE-2) and differential pressure transmitter (FT-2)The area to the left
of the dotted line in following figure functions the same as that of a two element drum level
control.
We can pick up the operation for this scheme where the output signal of the feed water flow
computer (the combination of steam flow and drum level) enters the feed water controller
(FIC-2). This in effect becomes the set-point to this controller. Feed water flow Is measured
by the transmitter (FT- 2). The output signal of the feed water flow transmitter is linearized
by the square root extractor, (FY-2).
This signal is the process variable to the feed water controller and is compared to the output
of the feed water flow computer (set-point).
The feed water flow controller produces the necessary corrective signal to maintain feed
water flow at its set-point by the adjustment of the feedwater control valve (FCV-1).
2) Combustion Control
Objective of combustion control is to adjust the heat input to the boiler in terms of fuel and
air supplied in relation to output or steam demand. Steam Pressure is taken as an indicator of
boiler load (it decreases when the steam demand increases)
There are 3 types of combustion control schemes.
1) Series
2) Parallel
3) Series-Parallel
Series Combustion control
A change in the steam Pressure causes a change in the air flow rate which in turn changes the
fuel flow rate. In the following diagram fuel flow becomes the secondary variable , however,
it may be interchanged with fuel becoming the primary variable. This scheme is used for
boilers with constant steam load and with fuels having constant efficiency

Steam
Pressure

Air Flow

Fuel
Flow

SERIES
Parallel Combustion Scheme
This is the most commonly used scheme for boilers of any size using fuels of constant
calorific value. The steam flow simultaneously adjusts both the fuel as well as air flow rates

Steam
Pressure

Air Flow Fuel Flow

Series-Parallel combustion control
If a boiler uses solid fuels (Coal firing scheme) the feed forward signal from the steam
pressure controller is also given to combustion air control. Steam pressure variations are used
to adjust the fuel flow. However, as steam flow is directly related to the heat released of the
fuel, it can not be used to control the air flow rate.

Steam Steam Flow
Pressure

Fuel Flow Air Flow
3) Steam Temperature Control
To control the temperature of steam, cold water is directly injected in the steam with the help
of attemperator device. It can be mixed at any one of the following 3 locations i) At the outlet
of Boiler Drum ii) Between the successive stages of Superheaters iii) After the last stage of
superheaters The second option is widely used and is shown in the figure above. Steam
temperature is measured and after comparing it with the set point, the TRC generates
actuating signal for the desuperheater water flow valve.

4) Steam Pressure Control

The actual steam flow at any point is not necessarily a true indication of demand. According
to Shinskey, the true load on a boiler can be approximated by where h is the differential
developed by a flow element and p is the steam pressure. Figure 8.6s describes a boiler-
pressure control system using this type of feedforward model. The pressure controller adjusts
the ratio of firing rate to estimated load.

In the firing rate control system shown in Figure 8.6s, the loops 101 and 102 measure the
pressure and flow of the generated steam, respectively. The firing rate demand signal is
generated in a feedback manner by the pressure controller PIC-101. In order to speed up the
response of this loop to load changes, a feedforward trim is added. This trim is based on
steam flow, because this flow is the first to respond to load changes. Therefore, as soon as the
demand for steam changes, FY-102 will trim the firing demand signal, without waiting for
the steam pressure to change.
 Feedback, Feed Forward and cascade control demonstrated in 3 element
feed Water Control
The term “3-element control” refers to the number of process variables (PVs) that are
measured to effect control of the boiler feedwater control valve. These measured PVs are:
▪ liquid level in the boiler drum,
▪ flow of feedwater to the boiler drum, and
▪ flow of steam leaving the boiler drum.

If the boiler drum liquid level is low, the level controller will call for an increase in feedwater
flow. But consider that if at this moment, the feedwater supply pressure were to drop. The
level controller could be opening the valve, yet the falling supply pressure could actually
cause a decreased flow through the valve and into the drum.
Thus, it is not enough for the level controller to directly open or close the valve. Rather, it
must decide whether it needs more or less feed flow to the boiler drum. The level controller
transmits its target flow as a set point to a flow controller. The flow controller then decides
how much to open or close the valve as supply pressure swings to meet the set point target.
This is a “2-element” (boiler liquid level to feedwater flow rate) cascade control strategy.
The flow controller will immediately sense any variations in the supply conditions which
produce a change in feedwater flow. The flow controller will adjust the boiler feedwater
valve position to restore the flow to its set point before the boiler drum liquid level is even
affected.
The level controller is the primary controller (sometimes referred to as the master controller)
in this cascade, adjusting the set point of the flow controller, which is the secondary
controller (sometimes identified as the slave controller).

The third element in a “3-element control” system is the flow of steam leaving the steam
drum. The variation in demand from the steam header is the most common disturbance to the
boiler level control system in an industrial steam system.

By measuring the steam flow, the magnitude of demand changes can be used as a feed
forward signal to the level control system. The feed forward signal can be added into the
output of the level controller to adjust the flow control loop set point, or can be added into the
output of the flow control loop to directly manipulate the boiler feedwater control valve. The
majority of boiler level control systems add the feed forward signal into the level controller
output to the secondary (feedwater flow) controller set point. This approach eliminates the
need for characterizing the feed forward signal to match the control valve characteristic.
Safety interlocks for boilers

1. Purge Interlock: Prevents fuel from being admitted to unfired furnace until furnace has
been thoroughly purged.
2. Low Air Flow Interlock: Fuel is shut off upon loss of air flow and / or combustion air fan.
3. Low fuel supply Interlock: Fuel is shut off upon loss of fuel supply otherwise unstable
flame condition results.
4. Loss of flame Interlock: All fuel is shut off upon loss of flame.
5. Fan Interlock: Stop of F.D. fan upon loss of I.D. fan