QT114 Datasheet, PDF(3/12 Page) Quantum Research Group

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QT114 Datasheet, PDF (3/12 Pages) Quantum Research Group – CHARGE-TRANSFER QLEVEL SENSOR IC

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for example due to changes in Cs or Cx over the operating

temperature range.

Signal

Figure 2-2 shows the response from a horizontal strip of

the same surface area; the signal exhibits a very rapid rise

in signal between points l1 and l2. Variations in circuit l2

gain or signal drift have much less of an effect on the trip

point with this orientation.

In some cases (thin walled vessels for example) it may be

sufficient to have a small round or square electrode patch

on the exterior.

Figure 2-3 shows the response from a twin-level external

electrode set. The use of two horizontal electrode planes

or tiers creates well-defined trip points that can be used to

sense both 'low' and 'high' levels. A crossing of threshold

T1 will be reflected in the OUT1 signal, while T2 will be

reflected on OUT2.

Level

Figure 2-1 Signal vs. Level for an External Vertical Strip

S ig na l

2.1 EXTERNAL ELECTRODES

External electrodes should be electrically conductive;

metal foils and conductive carbon are both possible. Care

should be taken that other objects or people near the

vessel will not touch the electrode; in some cases

shielding around the electrode with grounded metal will be

l1 l2

required to prevent disturbances. If used, the shield

element should be spaced apart from the electrode by an

air gap or a low-density foam to reduce Cx loading.

Level

l1 l2

The required surface area of the external electrode will

depend on the amount of signal needed to bracket the

Figure 2-2 Signal vs. Level for an External Horizontal Strip

detection threshold, which in turn will depend in part on Cs

and stray Cx. External electrodes sensing through thick

Signal

walls and/or sensing low permittivity fluids will require

larger surface areas than those sensing water through thin

plastic, for example. External electrodes are more likely to

require potentiometer trimming to achieve reliable

operation (Figure 1-1, also Section 3.2).

l3 l4

Note that external electrodes used with conductive

solutions (i.e. aqueous liquids) do not measure the

permittivity of the fluid: they actually measure the

permittivity of the vessel wall, between 2 plates: the

l1 l2

electrode (plate 1) and the fluid (plate 2, effectively a

variable-area ground plate): if the fluid were to be replaced

T1 T1

l1 l2

l3 l4

Level

with mercury the signal would be unchanged. A 20%

thickness variation in the vessel wall will therefore

Figure 2-3 Signal vs. Level for Twin Horizontal Strips

introduce about a 20% variation in the resulting

capacitance; if the vessel wall cannot be controlled

accurately enough in production, serious sensing errors may

occur.

When external electrodes are used to sense non-aqueous

substances (like oils or gasoline), the vessel wall dielectric

becomes a lessor contributor to the overall signal, which is

then heavily dominated by the permittivity of the fluid. The

lower the permittivity of the fluid the greater its dominance.

2.2 INTERNAL PROBES

When used with aqueous fluids or other electrically

conducting liquids, internal probes should be insulated with a

plastic layer. See also Section 2.1 for a discussion of

electrodes when used with conductive fluids. Aqueous

probes should be 100% insulated, even on the cut end of a

wire probe. The slightest pinhole of exposed metal anywhere

2.2.1 DISC PROBES

The simplest internal geometry is probably a disc probe

(Figure 2-4), having at least one planar surface ('tier')

parallel to the fluid surface. The sensing error can be

minimized by making the tier thin, so that the signal

transitions abruptly higher (see Figure 2-2) as the fluid

covers the tier.

A notable difficulty with disc probes is the task of insulating

them with a uniform, repeatable thickness of insulation.

2.2.2 SPIRAL WIRE PROBES

A spiral solid-wire probe is simple to construct (Figure 2-5),

and has the advantage of being pre-insulated in a wide

choice of plastics from inexpensive PVC to PTFE. These

probe types provide a large step-function of capacitance

localized at the desired trip point, and are easy to form.

on an immersed part of the probe will immediately convert Spiral wire probes are most effective in water-based fluids;

the probe into a bare-metal probe (see Section 2.2.5).

they are not as effective in oils and other nonconductive

Numerous types of internal point-level probes are possible. substances.

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