1. Introduction 7.17. 28.8.18.28. 2

1. Introduction

7.1
7. 2

8.
8.1
8.2
8. 2.1
8. 2. 2

Examination of the kettle
Carrying out kettle repairs

Putting into service an idle furnace
Pumping over
Care of zinc pumps
Dietermann zinc pumps
Screw pumps

33 The cost effectiveness of hot dip galvanizing and the quality of
34 zinc coatings is dependant upon not only the applied technology,
but the kettle life. The premature wear or failure of a kettle
34 alway•s results in higher costs of energy, zinc consumption and
34 production losses. The financial losses are even higher when a
36 disaster occurs whereby zinc runs out of the kettle, known
36 generally as a 'run-out'. Safely heating and cooling the kettle
37 and operating under normal safe working conditions is the main
function of a well designed galvanizing furnace.

9. Zinc run outs 37


Literature

Figures

39 Short lifetimes of galvanizing kettles are always caused by
41 shortcomings during the installation of a new kettle, by local overheating, too high zinc temperature, or too high heat transfer rates for the size of the kettle. Since rapid wear
of the interior surface is always connected with a high iron loss not only will zinc consumption be high (1 g iron to 25 g zinc) but also the efficiency of the galvanizing process is impaired by high dross production.


In addition to this are the extra costs due to higher zinc consumption, more frequent dressing, pumping out of the liquid zinc, removal of the worn kettle and installing a new one, plus loss of production for several days and usually repairs to the furnace. Also the quality of the zinc coating is impaired by the higher dross production. The following up to date advice will prevent premature wear of the zinc kettle making a more efficient galvanizing process possible.





2

2. The Kettle

The kettle holds the liquid molten zinc used for general galvanizing of steel articles conforming to the valid standards (BS 729 or CEN 262). The kettles are made from special steel plates, normally 50 rom thick and when in operation are heated in special furnaces. The inside surface of the kettle due to the chemical reaction between zinc and steel is attacked by the zinc causing wear to this surface.

The demand put to a kettle is on of a long life at a high production rate. A kettle failure results in high costs mainly because of the loss of production, loss of zinc, costs of repair and new investment. Today these requirements can be fulfilled by the use of suitable kettle materials with an appropriate steel th ckness, the use of suitable construction and fabrication techniques adapted to the use of the kettle as well as carefully designed heating systems. During the heating up phase it is necessary to keep to the prescribed temperature to minimise the stresses in the steel of the kettle. In the last 30 years the demand for a longer kettle life has resulted in a kettle which can be used at high production rates without trouble until it needs to be replaced to at the end of its service life. The materia1 used, the construction and the manufacture of the kettle are all of equal importance.


2.1 Kettle•material

For a long kettle life it is necessary to slow down the reaction between the steel and the liquid zinc to a minimum. Therefore only steel with a low carbon and silicon content can be used. All other alloying elements must also be low. Segrations (doublings) in the steel are not allowed.


2.2 Kettle construction (Practical hints) Kettle Wall Thickness
- Common (approved) steel thickness: 50 mm
- Other thicknesses: 30 to 40 mm (only for small and shallow kettles}
For higher production rates (for instance coil or wire galvanizing kettles) thicker kettle walls may be needed oi walls which have been made thicker by weld cladding
- Thickness of the kettle flange is normally the same as the
thickness of the kettle wall •


3

Geometric shape

The following variants are most common: Variant 1
Depending on its length the kettle is constructed from 1 or more preformed U steel sections welded together with 2 ends,.which have been bent on three edges. In this way no welds are in the danger zones nor at the transistion between bottom and walls or in the vertical corners of the plate. This kettle shape makes it possible to use modern automatic electroslag welding techniques to make welds with low silicon material, which is virtually identical to the steel f the kettle.


Variant 2

Here the two walls, together with the two preformed end plates, are welded on a flat base plate..Because the side walls stand on the base plate the welds at the bottom can only be made by electro hand welding or by oxy-acetylene welding and because they are situated in the critical load zone, the welds are in danger especially with deep kettles. This method of construction is out dated and is seldom ever used.




4 5

2.3 Kettle size

The size of the kettle must be suitable for the articles to be galvanized, the heating system and the hourly throughput. The zinc, surface must be as small as possible to minimise the heat losses due to heat radiation. Keeping to this not only improves fuel efficiency but also the zinc ash production is reduced because of the smaller area being oxidised. By reducing the heat radiation from the zinc surface the heat through the kettle walls can be reduced too, which can result in a long er kettle life.








Vo.rto.nt 1





















Vo.rto.nt 2



Figure 1: Construction of go.lvo.nizing kettles o.nd the loco. tion of' the welds


The heat load on the-walls is determined by the required depth of the kettle and the hourly throughput. The heat load is also the determining factor for the lifetime of the kettl'e. The heat load through the, walls should not exceed 24 kW/m2h (about 86,000 kJ/m2h, 7670 Btu/2ft). The average must not be taken into consideration but the local and the temporal peak heat load, which is of more importance for the life of the kettle. The heat load is not only composed of th'e necessary amount of heat to warm the articles being galvanized but also of the heat required to melt the zinc make up put into the bath, the radiation losses from the surface of the liquid zinc and the heat to warm up the baskets or dipping frames.

To avoid variations in the temperature of the zinc, cause•"l by occasional higher production, the zinc must act as a heat buffer. The kettle content must compensate for the small temperature differences caused by the heat taken out of the bath and the heat put into it to maintain the nominal zinc temperature. For this reason the kettle content should be about 30 to 40 times the hourly weight of the articles put into the zinc, including the weight of the jigs, racks, etc. When the temperature regulation is very sensitive it is possible to reduce the zinc weight to about 20 times.


2.4 Kettle Life

In the lifetime of a zinc kettle a differentiation is made between .the serviceability (premature breakdown caused by a rupture or by holes due to a local reaction of the zinc with the steel walls of the kettle) and the service life of the kettle
{dissolving of iron from the steel walls by the liquid zinc).

The life-time of a galvanizing kettle is not only dependant on the throughput and the inside kettle wall temperature, but also on . the type of steel the kettle is made from, the surface condition of the inside walls of the new kettle and the quality of the construction. Depending on kettle load and maintenace the life of a kettle can be several months for continuous strip galvanizing kettles and up to ten years for general galvanizing kettles.







,.

I


6

3.Installation


The installation for hot dip galvanizing consists of

the heating system {galvanizing furnace)
the galvanizing kettle to hold the z1nc
- equipment for measuring and controlling the temperature (this
is normally an integral part of the galvanizing furnace)


The construction, the materials used, the manufacture and assembly of the heating system and the kettle as well as the

7

3.1 Gas and oil heating systems

When using gas and oil the heat is supplied through burners mounted in the furnace walls. The number ,of burners depends on the fuel (gas or oil), the size of the kettle and the throughput.
'
Heating systems for steel kettles:

Indirect heating over plates
The galvanizing kettle is protected against a direct contact of
as flames by fire plates. The energy efficiency is very poor.

- Forced circulation heating system

quality of the equipment for temperature measurement and control

To improve the energy efficiency the

hot gasses are blown

have an influence on the lifetime of the kettle. They also affect the costs and the efficiency of the galvanizing process.


Different heating systems have been developed to suit energy sources available i.e. gas {natural, town, propane, butane etc), electricity and oil. The installed heating system and its construction has a great influence on the lifetime of the kettle. The demand for a long kettle life, which is closely connected with the.reduction of unwanted dissolving of iron, has led to the development of heating systems with this as the principal aim. When carefully designed the available heat will be uniformly distributed over the kettle walls preventing hot spots and critical temperatures at the inside of the kettle walls.


Because it is not advisable to exceed the critical heat load on the kettle walls a uniform distribution of the heat over the whole heating surface is required for maximum utilisation of the zinc kettle area available. Earlier recommendations to distribute the heat unevenly over the heated surfaces are therefore not correct. The low.est part of the heated surface must be about
10.0 mm above the su