Scribd
Upload
283 views39 pages

Liquid Fluids Atomization

The document discusses different mechanisms and types of liquid atomization. It describes how liquid jets can be destabilized and disintegrated into filaments and droplets through forces like surface tension, centrifugal forces, and external mechanical forces. It then focuses on specific types of atomizers used for liquid fuels, including pressure atomizers, plain-orifice atomizers, swirl atomizers, pneumatic atomizers, and rotating atomizers. The key parameters that characterize atomization quality and nozzle performance are also covered.

Uploaded by

Veky Pamintu
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
Available Formats
Download as PDF, TXT or read online on Scribd
283 views39 pages

Liquid Fluids Atomization

The document discusses different mechanisms and types of liquid atomization. It describes how liquid jets can be destabilized and disintegrated into filaments and droplets through forces like surface tension, centrifugal forces, and external mechanical forces. It then focuses on specific types of atomizers used for liquid fuels, including pressure atomizers, plain-orifice atomizers, swirl atomizers, pneumatic atomizers, and rotating atomizers. The key parameters that characterize atomization quality and nozzle performance are also covered.

Uploaded by

Veky Pamintu
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
Available Formats
Download as PDF, TXT or read online on Scribd
You are on page 1/ 39

ATOMIZATION OF LIQUID FUELS

COMBUSTION AND FUELS

THE PRINCIPLE OF LIQIUDS ATOMIZATION


Atomisation is the process whereby bulk liquid is transformed into a collection of drops. This transformation goes through the break-up of liquid jet into number of filaments, which in turn transform into droplets.

COMBUSTION AND FUELS

MECHANISMS OF LIQIUDS ATOMIZATION


Three mechanisms:
Disintegration of a liquid jet into a number of filaments, and then into small droplets, requires the surface tension forces of liquid to be overcome. It may happen on the three ways: by surface tension between moving liquid jet and steady air which destabilise the jet and causes its disintegration into filaments, by centrifugal forces of swirled liquid jet,

outer mechanical and electrostatic forces and by supersonic acoustic.

COMBUSTION AND FUELS

FLUID ATOMIZATION WITH DIFFERENT ENERGY

COMBUSTION AND FUELS

JETS DISINTEGRATION AND DROPLETS BREAKUP

Primary liquid jet disintegration

Droplets break-up

COMBUSTION AND FUELS

RANGE OF LIQUID ATOMIZATION

Re = (UL)/ We = (U2L)/ - the surface tension


coefficient

COMBUSTION AND FUELS

INFLUENCE OF PRESSURE-INJETION ON ATOMIZATION EFFECTIVENESS


5 bars

10 bars

15 bars

TORCH OF PLAIN-ORIFICE ATOMIZED OIL

LIQIUD SHEET BREAKUP

Swirled jet

COMBUSTION AND FUELS

TYPES OF OIL INJECTORS/ATOMISERS


Types of atomizers: - pressure
plain-orifice
swirl type Y type

- pneumatics
with x- cross shape flow

- rotating
COMBUSTION AND FUELS

PRESSURE INJECTORS

COMBUSTION AND FUELS

PLAIN-ORIFICE ATOMISER
Do > 0.5 mm p = 0.3-1(5) MPa = 5-15o Simple construction, Low quality of atomisation

COMBUSTION AND FUELS

SWIRL ATOMIZERS

COMBUSTION AND FUELS

HOW A SWIRL NOZZLE WORKS

COMBUSTION AND FUELS

SWIRL NOZZLE:

DESIGN
do = 2-6 mm p = 0.6-1.0 MPa = 45-90o Simple construction High reliability High quality of atomisation Low energy consumption

COMBUSTION AND FUELS

SWIRL NOZZLE: AN EXAMPLE

COMBUSTION AND FUELS

COMPACT SWIRL ATOMISER

COMBUSTION AND FUELS

TYPE OF FUEL CONES

Delavan COMBUSTION AND FUELS

SWIRL ATOMISER IN OPERATION

Dispersed oil jet COMBUSTION AND FUELS

PNEUMATIC ATOMISERS

COMBUSTION AND FUELS

PNEUMATIC ATOMISER: PRICIPLE OF OPERATION


liquid fuel atomizing medium air / steam
recirculating small droplets

air jet layer of fuel around the atomizing medium

deformation wave of fuel small droplets formed outside of the stream dispersion of the stream small droplets formed from the stream big droplets formed from the disintegration of the stream abut 5 x diameter of atomizing nozzle

abut 40 x diameter of atomizing nozzle

Consumption of atomising medium: =0.06-0,1 kg/kg COMBUSTION AND FUELS

PNEUMATIC ATOMISER OF Y TYPE

Pneumatic atomizer of Y type: 1 oil, 2 gas, 3 atomising head, 4 nozzles

COMBUSTION AND FUELS

PNEUMATIC ATOMISER OF CROSS-SHAPE FLOW TYPE

Pneumatic atomizer of the cross-shape flow type: 1 oil, 2 gas, 3 oil injection, 4 gas injection, 5 mixing chamber, 6 - nozzles

COMBUSTION AND FUELS

ROTATING ATOMISERS

COMBUSTION AND FUELS

How does operate rotating atomizer?

OIL BURNER WITH ROTATING ATOMISER

SAACKE

COMBUSTION AND FUELS

CONTROL OF OIL FLOW RATE

COMBUSTION AND FUELS

ATOMISATION PRESSURE VARIATION


1. The simplest way for oil output/consumption control is variation of pressure of atomisation. 2. Disadvantage of this method of output control is loss of atomisation quality due to reduction of atomisation pressure. Rate of oil output (p)0.5

COMBUSTION AND FUELS

Two-step control of oil flow rate


Scheme of single chamber two-step oil atomizer: 1 valve, 2, 3 recalculating pipes

COMBUSTION AND FUELS

CIRCLE MECHANICAL (RETURN- FLOW) ATOMIZER


Oil tank

Fuel nozzle

Valve

Nozzle Pump COMBUSTION AND FUELS

RETURN OIL INNER CIRCLE ATOMIZER

CIRCLE OIL ADJUSTING VALVE

1 VALVE, 2 SWIRL CHAMBER, 3 OIL CIRCLE HOLES

COMBUSTION AND FUELS

TWO-NOZZLES ATOMIZER
I nozzle II - nozzle

COMBUSTION AND FUELS

QUALITY OF ATOMISATION

COMBUSTION AND FUELS

PARAMETERS OF ATOMIZATION
output, kg/s angle of dispersion, deg droplets distribution, mean diameter of dispersion, m.

COMBUSTION AND FUELS

CHARACTERISTICS OF ATOMIZING NOZZLE

COMBUSTION AND FUELS

OUTPUT of PRESSURE ATOMIZERS

Output m of pressure atomizers is defined as follows:

m = A(2c p)0,5
where: A is the area of nozzle output, p is pressure and is the outflow coefficient.

COMBUSTION AND FUELS

DROP SIZE DISTRIBUTION

Drop size distribution curves

COMBUSTION AND FUELS

CHARACTERISTIC OF DROPLETS SIZE Mean drop size:


mean drop size SRK = [(nD3/nD)]0,5, mean drop size of Sauter SMD = nD3/ nD2.
COMBUSTION AND FUELS

You might also like