Selection criteria for continuous valves, Selection.criteria.for.continuous.valves, 1) p p q k – Burkert Type 8793 User Manual

238

Additional technical information

39.

SELECTION CRITERIA FOR CONTINUOUS
VALVES

The following criteria are crucial for optimum control behavior and to ensure that the required maximum flow is reached:

• the correct selection of the flow coefficient which is defined primarily by the orifice of the valve;

• close coordination between the nominal width of the valve and the pressure conditions in consideration of the

remaining flow resistance in the equipment.

Design guidelines can be given on the basis of the flow coefficient (k

V

value). The k

V

value refers to standardised

conditions with respect to pressure, temperature and media properties.

The k

V

value describes the flow rate of water through a component in m³/h at a pressure difference of ∆p = 1 bar

and T = 20 °C.

The “k

VS

value” is also used for continuous valves. This indicates the k

V

value when the continuous valve is fully open.

Depending on the specified data, it is necessary to differentiate between the two following cases when selecting
the valve:

a) The pressure values p1 and p2, known before and after the valve, represent the required maximum flow-rate
Q

max

which is to be reached:

The required k

VS

value is calculated as follows:

(1)

p

p

Q

k

0

0

max

s

v

ρ

ρ

⋅

∆

∆

=

⋅

Meaning of the symbols:
k

VS

flow coefficient of the continuous valve when fully open [m³/h]

Q

max

maximum volume flow rate [m³/h]

∆p

0

= 1 bar; pressure loss on the valve according to the definition of the k

V

value

ρ

0

= 1000 kg/m³; density of water (according to the definition of the k

V

value)

∆p pressure loss on the valve [bar]
ρ density of the medium [kg/m³]

b) The pressure values, known at the input and output of the entire equipment (p

1

and p

2

), represent the required

maximum flow-rate Q

max

which is to be reached:

1st step: Calculate the flow coefficient of the entire equipment k

Vges

according to equation (1).

2nd step: Determine the flow-rate through the equipment without the continuous valve

(e.g. by "short-circuiting" the line at the installation location of the continuous valve).

3rd step: Calculate the flow coefficient of the equipment without the continuous valve (k

Va

)

according to equation (1).

4th step: Calculate the required k

VS

value of the continuous valve according to equation (2):

(2)

²

k

1

²

k

1

1

k

a

V

Vges

s

v

−

=

english

Type 8792, 8793