[IMMAJ] Marine Boiler Water - CH.1 - Part 1.pdf

Transcript

Chapter

1

Marine Boiler Water Management

010

1

Marine Boiler Water Management

Importance of marine boiler water quality management

Treatment of water used for marine boiler plants is conducted for the following purposes:
(1) Scale prevention
(2) Corrosion prevention
(3) Carry-over prevention
Management of boiler plant water quality is an important duty for operators of marine boilers.
As part of their normal duties, operators must: carefully analyze feed water/condensate and
boiler water; determine a course of action based on the results of this analysis; and then take
the steps dictated by the course of action.
When analysis results dif fer from predicted values – even if the results fall within
acceptable limits – the cause of the discrepancy must be investigated. To ensure that their
vessel is always supplied with water that meets operational requirements, the marine boiler
operator responsible for water quality must demonstrate comprehensive knowledge of the
principles of boiler plant water quality.

FO SETT TK

46°C

136°C

61°C

METAL

METAL

91°C

53°C

70°C

212°C

58°C

109°C

FROM
FOTANKS
BURNG
PUMP

2.184MPa

NO1 SH STM
0.507MPa
75°C

HEADER
0.947MPa

(S)

44°C

NO2 SH STM
2.089MPa
422°C

ASSIST
STM
0.165MPa

38°C
(P)

S W TEMP
25°C
E /R TEMP
45°C

DSH
STM
2.037MPa

51°C

AIR

FWC

184kPA

NO.2 BLR

2

0.568MPa

AIR
-12kPA

FEED WTR
3.021MPa
179°C

NO.1 BLR
FO CONSUMPTION

ASSIST
STM
0.002MPa

HEADER
0.058MPa

1

STM
FO HTR

3.672MPa
108°C

1094L/4HR

Fig.1

2

Marine boiler overview

2-1

Marine boiler types

Ships use the following types of steam generators and each has a specific purpose:

1) Auxiliary boilers (1MPaG class or less)
Auxiliary boilers for common diesel ships produce 0.7MPaG-class saturated steam that is used
to operate auxiliary machinery and equipment; to heat fuel oil, lubricating oil and fresh water;
and for air-conditioning equipment, galley and miscellaneous purposes.
① Vertical Cylindrical Smoke Tube Boiler
• Standard design pressure: 0.8MPaG
• Furnace: Full water-cooled type (~ 7,000 kg/h)

• Evaporation: 600 ~ 1,500 kg/h
• Heating surface: Smoke tube

BURNING
GAS
OUTLET
STEAM SPACE
N. W. L.

INSULATION

SMOKE TUBE
MANHOKE

BRTNER
FURNACE

Fig.2

011

Marine Boiler Water Management

Water management criteria vary according to boiler working pressure.
Marine boilers are broadly classified into three groups based on working pressure: main
boilers for steam turbine ships (for LNG tankers); auxiliary boilers for diesel ships (for very large
crude oil carriers – VLCCs); and auxiliary boilers for general diesel ships.
The recent trend toward increasingly more sophisticated and complex marine boilers has
highlighted the importance of boiler water quality management.
To prevent accidents resulting from boiler plant water, you must understand the
importance of water treatment – because doing so will allow you to ensure that feed water,
condensate and boiler water all meet the requisite quality standards. You must also be able to
acquire the practical knowledge and ability required to manage and maintain water quality.
Please note that the main boiler feed water/condensate for turbine ships is used in a closed
system. As such, integrated management and control of water quality is imperative if turbine
plant accidents are to be prevented.

Chapter

Marine Boiler Water Management

012

1

② Vertical Cylindrical Smoke Tube Composite Boiler
• Standard design pressure: 0.8MPaG
• Furnace: Full water-cooled type
• Evaporation – Oil firing side: 300 ~ 3,000 kg/h
– Exhaust gas side: 300 ~ 3,000 kg/h
• Heating surface: Smoke tube
(For both the oil firing and exhaust gas sides)

M/E EXH. GAS
OUTLET

BURNING
GAS
OUTLET

CLEANING
HOLE

STEAM SPACE
N. W. L.
SMOKE TUBE

SMOLE TUBE

MANHOKE
INSULATION

BURNER
FURNACE
CLEANING
HOLE

M/E EXH. GAS
INTLET

Fig.3

③ Vertical Cylindrical Water Tube Composite Boiler
• Standard design pressure: 0.8MPaG
• Furnace: Large combustion chamber with base of refractory material at its bottom
• Evaporation – Oil firing side: 1,200 ~ 1,500 kg/h
– Exhaust gas side: 950 ~ 1,500 kg/h
OE VC 2 .a i
STEAM SPACE
INSULATION
M/E
EXH, GAS
OUTLET

MANHOLE
WATER TUBE

M/E
EXH, GAS
INLET

N. W. L.

SMOKE
BOX

SMOKE
BOX

CLEANING
HOLE

CLEANING
HOLE

MANHOLE

BURNING
GAS OUTLET
SMOKE BOX

CLEANING DOOR
WATER TUBE

DOWNCOMER TUBE
FURNACE
BURNER

Fig.4

OEV.ai
Marine Boiler Water Management

STEAM SPACE
INSULATION
BURNING
GAS
OUTLET

MANHOKE
N. W. L.

CLEANING
HOLE

CLEANING
DOOR
SMOKE
BOX
WATER
TUBE

013

DOWNCOMER TUBE
MANHOLE

FURNACE

Fig.5

④ Vertical Cylindrical Water Tube Boiler
• Standard design pressure: 0.8MPaG
• Waste oil incinerator: Optional

• Furnace: Large combustion chamber with
base of refractory material at its bottom
• Evaporation: 1,000 ~ 1,800 kg/h

2) Auxiliary boilers (2MPaG class)
Auxiliary boilers for diesel VLCCs (double-drum water tube boilers without superheaters)
Double-drum water tube boilers produce steam in the 1.57 ~ 2.0MPaG pressure spectrum that
is used to drive cargo oil pump turbines. This type of boiler has two or more different operating
modes and adjustable pressure settings for use at sea and in port (for loading/unloading).

Gas
Outlet

Steam
Outlet

F.O.Burner
Steam Separator

Wind Box
Combustion Air Inlet
Steam
Drum

Generating Tube
Soot Blower

Partition water wall

Combustion Gas Flow
Baffle Plate
Screen Tube

Front (Rear)
Wall Tube

Water
Drum

Fig.6

Fig.6 shows a Mitsubishi MAC-B auxiliary boiler.
Its main specifications (MAC-B 80 Tanker Mode) are:
• Steam pressure: 1.57MPa
• Max. evaporation: 82,000 kg/h
• Steam temperature: 203.4˚C (SAT)

Marine Boiler Water Management

BURNER

Chapter

1

3) Main boilers (6MPaG class)
Main boilers (6.0MPaG×525˚C, 6.2MPaG×515˚C, etc.) for steam turbine ships are mainly used on
LNG carriers.

Superheated
steam tube

Combustion
Chamber

Steam
drum

Furnace

Marine Boiler Water Management

014

Downcomer

Water drum

Fig.7

Fig.7 shows the model of Kawasaki Heavy Industries’ marine boiler UMG 17/14.
• Steam pressure: 41.5 kg/cm2
• Steam temperature: 454˚C
• Max. evaporation: 17,000 kg/h

Marine Boiler Water Management

4) Fin tube-type exhaust gas economizer
The fin tube-type exhaust gas economizer is used to recover thermal energy from the exhaust
gas of a large main diesel engine; and to generate saturated steam and superheated steam that
it supplies to the turbo generator system.
015

• Exhaust gas boiler and exhaust gas economizer

• Forced-circulation water tube type exhaust gas economizer
A tube (bare or spiral) is located in the exhaust gas flue. When the main engine is being run, a
boiler water circulation pump – found between the exhaust gas economizer and the auxiliary
boiler – is used to recover heat and generate steam.
Large systems, meanwhile, feature a low-pressure steam generator, a high-pressure steam
generator and a superheater between the exhaust gas outlet and exhaust gas inlet.

M/E EXH. GAS
OUTLET

S/G
OUTLET
HEADER

MANHOKE
S/G
INLET
HEADER
S/H
INLET
HEADER

INSPECTION
HOLE

S/H
OUTLET
HEADER
INSULATION

M/E EXH. GAS
INLET

Fig.8

Marine Boiler Water Management

These are found in the exhaust gas flue, where they are used to recover residual heat from the
exhaust gas of the main diesel engine.
The exhaust gas economizer is connected to the auxiliary boiler and uses the latter’s drum
to separate steam from water.
Meanwhile, the exhaust gas boiler has its own drum for separating steam.

Chapter

016

1

2-2

Marine boiler plants

2 - 2 -1

Auxiliary boilers (1MPaG class or below)
Auxiliary boilers for common diesel ships (for 0.7MPaG saturated steam)

Marine Boiler Water Management

Steam & Feed Water Flow for Diesel Ship(1).ai
2013_01_26

1) Steam and feed water flow diagram
• Steam & Feed Water Flow for Diesel Ship(1)

0.6MPaG Saturated Steam

Accomodation
F.O./L.O. Tank Heating

Aux.
Boiler
(Composite)
&
E.G.E.

F.O. Heaters
F.O. Storage Tank
Steam Trace
Others

Main Eng.
Exh. Gas Sampling
Overboard

Aux.
Condenser

To
Clean Drain
Tank

Chemical
Injection
Tank

F
Inspection
Tank

Cascade Tank

To Bilge
Tank

P

Boiler
Feed
Water
Pump

F.W. Pressure
Tank

F.W. Tank

Fresh Water Generator

Fig.9

The Fig. above shows the steam and feed water flow diagram for a composite boiler. Saturated
steam generated by the auxiliary boiler (while in port and reheating while at sea) or by the
exhaust gas economizer (exhaust gas from the main engine while at sea) is used as a heat
source for fuel oil (FO) and lubricating oil (LO) tanks, for heating FO pipes and for galley use,
and its drain returns to the cascade tank via the auxiliary condenser and the inspection tanak.
You can confirm the presence/absence of oil content on the inspection tank surface.
Drain accumulates in the cascade tank, and shortages, if any, are made up for with fresh
(distilled) water from the fresh water pressure tank, which is conveyed to the auxiliary boiler by
the feed water pump via a feed water control valve. Boiler compounds are injected either by a
chemicals feeder prior to feed water pumping, or are injected directly into the cascade tank
after being dissolved.
Proper boiler water management includes sample testing, followed as necessary, by
blowing off of boiler water and/or injecting of boiler compounds.

Marine Boiler Water Management

As shown in Fig.10 below, there is also a system for independently setting an auxiliary boiler
and exhaust gas economizer. This system, used at sea, generates steam with the auxiliary
boiler by means of a boiler water circulation pump that circulates boiler water between the
boiler and economizer.
017

• Steam & Feed Water Flow for Diesel Ship (2)

Drain

Steam
E.G.E

Aux.
Boiler

Marine Boiler Water Management

FO/LO Heating etc

Drain Cooler
Chemical

F
Inspection
Tank

Main Engine
Exh. Gas Boiler Water
Cir.Pump
Overboard

Cascade
Tank
Fead Water
Pump
Sampling

F.W. Pressure
Tank
F.W. Tank
F.W. Generator
Fig.10

2) Boiler water quality management procedures and related equipment
① Injection of boiler compounds
If deemed necessary following boiler water testing, dissolve boiler compounds and inject them
into the cascade tank.
② Sampling
Take a boiler water sample from the piping attached to the auxiliary boiler, and place it into the
dedicated container.
③ Inspection tank
In the drain (superheated steam, etc.) return line, an inspection tank has been placed on this
side of the cascade tank; look into the tank to confirm the presence/absence of floating matter
(oil, etc.).
④ Blow-off pipe
Based on the results of the boiler water test, you can drain boiler water overboard to reduce
enrichment or remove impurities.

Chapter

1

2-2-2

Auxiliary boilers (2.0MPaG class)
Auxiliary boilers for diesel VLCCs (double-drum water tube boilers without
superheaters)
(Used for driving cargo oil pump turbines; 1.57MPaG saturated steam)

Marine Boiler Water Management

018

1) Steam and feed water flow diagram
• Steam & Feed Water Flow Diagram for Diesel Ships (VLCCs)
SLOP TANK C
CARGO OIL STRIP PUMP D
WORK SHOP
AUX. BOILER

AIR EJECTOR
SC

1.57/0.92
TO SOOT BLOWER

SAMPLE
COOLER

ATOMIZING STEAM
PURGE STEAM

TANK
CLEAN PUMP
TURBINE

AIR EJECTOR
COND.

NO.1
CARGO OIL
PUMP TURBINE

B

AUX. COND.

0.92/0.29
MPaG

F.O./L.O. TANK HEATING

COMPOUND
TANK

NO.3
CARGO OIL
PUMP TURBINE

ATMOS.
COND.
DISTILLED WATER TANK

SUPER HEATER

SC

A

EXHAUST
GAS
VACUUM
PUMP

CONDENSATE
PUMP
D

EXHAUST GAS
ECONOMIZER
(E.G.E.)
(EGE)

0.29
MPaG

NO.2
CARGO OIL
PUMP TURBINE

P

C

OTHERS

H.P.EVAPORATOR

0.92
MPaG

F.O. HEATER

F.O. SERV./SETT. TANK

L.P.EVAPORATOR

A

SC

ACCOMODATION

STEAM SEPA.
DRUM

T/G

F.W.

B

INSPECTION
TANK

P

CASCADE
TANK

HYDRAZINE
TANK & PUMP

P
T/G COND.

TO E.G.E.
CLEANING
T/G CONDS.PUMP

SC

H.P. BOILER W.
CIRC. PUMP
P

P
L.P. BOILER W.
CIRC. PUMP

OVER
BOARD

P
SC :SALINITY INDICATOR CELL

EGE I ST STAGE
FEED WATER HEATER

:CONTROL VALVE

AUX. FEED PUMP

FRESH
WATER
GEN.
F.W.TANK
DRINKING
WATER TANK

2ND STAGE
FEED WATER HEATER
P

(Sterilizer)

FEED PUMP

Fig.11

Feed water is supplied to the cascade tank from the distilled water tank, where low-salt (10ppm
or less) distilled water produced by the onboard distilling plant is stored.
While at sea, this boiler is operated in exhaust gas economizer (EGE) mode. Saturated
steam generated by the auxiliary boiler passes through the EGE superheater to become
superheated steam, which is then supplied to the turbo generator (T/G). Pressure-reduced
saturated steam, meanwhile, is used for heating the FO/LO and water.
Exhaust gas from T/G is seawater-cooled into condensate in the vacuum T/G condenser and
then pumped back into the cascade tank by the T/G condenser pump, returning via the feed
water heater.

Marine Boiler Water Management

Steam used for heating is returned to the atmospheric condenser, seawater-cooled into
drain and then returned to the cascade tank via the inspection tank.
The auxiliary feed pump moves feed water from the cascade tank via the second stage feed
heater and the feed water control valve to either the steam separator drum or the auxiliary
boiler.

Exhaust gas from the main diesel engine is used to heat the evaporators, producing lowpressure steam in the low-pressure steam separator drum and medium-pressure steam in the
auxiliary boiler. This steam is then supplied where it is needed.
When the vessel is in port undergoing cargo operations, the boiler is operated in tanker mode
(pressure setting: 1.57MPaG) and saturated steam is used both to drive the cargo oil pump
turbines to unload cargo (crude oil, etc.) and for heating the slop tank.
Exhaust gas from the cargo oil pump turbines is introduced into the auxiliary condenser, where
a vacuum has been created using an ejector; here seawater cools the steam into drain, which is
returned to the cascade tank.
The EGE’s superheater cannot be used while the ship is in port, so desuperheated steam is
supplied to the turbo generator (T/G). Boiler load increases when cargo handling equipment is
in use, so feed water is supplied to the auxiliary boiler using the main feed pump.

2) Boiler water quality management
① Injection of boiler compounds
Boiler compounds, diluted with feed water, are injected into the compound tank located along the
feed water pipe between the feed water pump and the steam separator drum or auxiliary boiler.
Hydrazine, an oxygen scavenger, is diluted in the hydrazine tank using distilled water from
the distilled water tank and then injected into the cascade tank using a dedicated pump.
② Water sampling
Boiler water samples are taken after the auxiliary boiler water temperature has been lowered
using a sample cooler set in the vessel’s work shop.
③ Salinity indicator
Salinity indicator cells are located on the outlet-side condensate line for the auxiliary condenser,
the atmospheric condenser and the T/G condenser as well as on the air ejector outlet line for
the auxiliary condenser. These cells are used to watch for seawater ingress and sound an alarm
when salinity levels exceed a permissible range.

Marine Boiler Water Management

The low-pressure boiler water circulating pump circulates feed water between the exhaust gas
economizer (EGE)’s low-pressure steam generator and the steam separator drum while the
high-pressure boiler water circulating pump circulates feed water between the EGE’s highpressure steam generator and the auxiliary boiler to generate steam in the steam separator
drum and auxiliary boiler, respectively.

019

Chapter

1

④ Inspection tank
An inspection tank is located on this side of the cascade tank on the drain (heated steam, etc.)
return line; look inside the tank to check for floating matter (oil content, etc.).
⑤ Blow-off pipe
Boiler water inside the steam separator tank and the auxiliary boiler can be drained overboard
as necessary to reduce the enrichment of or remove impurities from boiler water.

Main boilers (6.0MPaG class)
Main boilers for steam turbine ships (double-drum water tube boilers with
superheaters)

2-2-3

1) Steam and feed water flow diagram
• Steam & Feed Water Flow Diagram for Turbine Ships
GLAND STEAM
CONDENSATE PUMP
H.P.
TURBINE

MAIN
COND.

L.P.
TURBINE

1ST BLEED

(CONDENSATE WATER)

P

3RD
BLEED

B

DUMP
COND.

DESUPERHEATED
STEAM

DUMP EXT.
DSH

B

STEAM
AIR
HEATER

STEAM
DRUM

NO.1
DIST.
PLANT

TO MAIN COND.
or DUMP COND.

GLAND STEAM

SUPER
HEATER

C

MAIN
BOILER

C

STEAM TEMP.
CONTROL EXT.DSH.
WATER
DRUM
FROM OTHER BOILER

A

BOILER
COMPOUND
TANKS
& INJECTION
PUMP
PUMP
TO BOILER STEAM DRUM

3RD.FEED
HEATER
OVER BOARD

CONTINUOUS
BOILER WATER
MEASURING UNIT

C

OTHERS
ACCOMODATION

SC

GREASE
EXTRACTOR

GLAND LEAK
1ST. FEED
HEATER

GLAND
COND.
SPILL

A

TO ATMOS.
DRAIN TANK
or MAIN COND.

CHEMICAL
METERING
TANK & PUMP

SC :SALINITY INDICATOR CELL

F.O. TANK HEATING

MAKE UP

SC

P

COOLING F.W.

CARGO MACHINERY HEATERS

P

2ND DEAER.
FEED HEATER

TO GLAND
COND.

TO 1ST FEED
HEATER or DEAER.

F.O. / L.O. HEATERS
SHIP SERV.
EXT. D.S.H.

DRAIN
PUMP

MAIN
FEED
PUMP
TURNINE

TO 1ST FEED
HEATER

FROM
DRAIN TANK

ATMOS.
DRAIN TANK

TO SOOT BLOWERS

ECONOMIZER

NO.2
DIST.
PLANT

TO MAIN COND.
or DUMP COND.
CLEAN DRAIN

TURBO
GENERATOR

SC

CONTAMINATED
DRAIN

TO GLAND COND.

TO BURNER
ATOMIZER

PUMP

SC

A

2ND BLEED

GLAND LEAK

SUPERHEATED STEAM

Marine Boiler Water Management

020

DISTILLED
WATER TANK

:CONTROL VALVE

DRAIN COOLER

DRAIN TANK

DE-OILER
DRAIN COOLER

DE-OILER

SAMPLE COOLER
TO ATMOS. DRAIN TANK
(CLEAN DRAIN)

DISTILLED
WATER TANK

TO ATMOS. DRAIN TANK
(CLEAN DRAIN)

F.W. TANK

DRAIN INSPECT.TANK
TO ATMOS. DRAIN TANK
(CONTAMINATED DRAIN)
OIL CONTENT MONITOR

DRINKING
WATER TANK
(Sterilizer)

TO OTHER BOILER STEAM DRUM

Fig.12

Marine Boiler Water Management

For ships using a steam turbine as the main engine, the plant is operated in a state that
resembles a closed feed system; a high vacuum is maintained in the condenser; and dissolved
oxygen amounts to 1ppm or less with a similar amount of oxygen dissolved from the
atmospheric drain tank.

Condensate in the main condenser is pumped by the condensate water pump into the distilling
plant, the gland condenser, first feed heater and the second deaerator feed heater (in this order)
to be heated. Dissolved oxygen in the feed water is deaerated in the second deaerator feed
heater.
Feed water is then steam-heated in the third feed heater using the main feed water pump.
After the boiler water level has been adjusted by the feed water control valve, the feed water is
supplied to the boiler via the economizer. By the time it reaches the boiler inlet, the feed water
has been heated to about 200˚C.
Some of superheated steam is sent to the steam drum, where it produces the desuperheated
steam (approx. 5.85MPaG×320˚C) used for driving the soot blower, heating FO and LO and for
cargo machinery heaters. Most of the desuperheated steam then reverts to drain and is
recovered in the atmospheric drain tank. Drain recovery rate inside the plant is said to be
greater than 99%.
The amount of water inside the plant system is controlled by the deaerator feed heater’s water
level. If the water level falls, low-salinity (1ppm or less) distilled water produced by the onboard
distilling plant is moved from the distilled water tanks (ex. 200m3×2) into the atmospheric drain
tank (Make-up). When the water level rises, the surplus is dumped back into the distilled water
tanks (Spill).
It is customary on board LNG tankers to use the boiler to burn boil-off gas generated in the
tanks and seawater-cool the resulting steam into drain. This is done for the purpose of adjusting
the internal pressure of the LNG tanks prior to entering port for unloading operations.

021

Marine Boiler Water Management

Saturated steam generated in the boiler’s steam drum is transformed into superheated steam
(ex. 5.85MPa×525˚C) in the superheater and then used to drive the main turbines (HP and LP),
the turbo generator turbine (T/G) and the feed water pump turbine.
Exhaust gas that has expanded in the turbine is cooled by seawater in the high-vacuum
main condenser; this condensate water (approx. 35˚C) is then used as boiler feed water.

Chapter

1

2) Boiler water quality management

Marine Boiler Water Management

022

① Injection of boiler compounds
Boiler compounds are dissolved into condensate provided by the condensate system; this
mixture is then supplied to the boiler using a dedicated pump.
Hydrazine, an oxygen scavenger, is diluted with condensate supplied from the chemical
metering tank and then supplied to the line in front of the feed water pump using a dedicated
pump.
② Water sampling
Boiler water samples taken from the steam drum of each boiler and a feed water sample taken
at the third feed heater outlet are cooled with fresh water and automatically monitored by a
continuous boiler water measuring instrument.
Meanwhile, some items are measured and automatically monitored by a continuous, automatic
boiler water analyzer.
③ Salinity indicator
Salinity indicators (each one) are located on the outlet-side condensate line for the main
condenser pump, on the outlet-side drain line for the dump condenser and atmospheric drain
pump, and on the feed water line in front of the feed water pump. They monitor boiler water
and sound an alarm if salinity reaches a pre-determined level.
Care should be taken regarding the maintenance of salinity indicators.
④ De-oiler and oil content monitor
Due to tube damage or for other reasons, oil can find its way into the drain produced from
steam that was used to heat fuel oil and lubricating oil. A de-oiler is located in the drain return
line to address this problem, removing any oil content that it encounters.
In addition, drain exiting the drain cooler in the drain return line is monitored by an oil content
monitor, which can detect and determine the concentration of oil content.
⑤ Grease extractor
Drain that has returned to the atmospheric drain tank is sent by the drain pump to the feed
water line in front of the gland condenser. Since the drain has passed through an open tank, the
feed water line is fitted with a grease extractor designed to remove oil content. The grease
extractor is subject to periodic inspection and maintenance.
⑥ Blow-off pipe
Some boiler water is drained overboard by means of surface blow from the steam drum and
bottom blow from the water drum.