Level Switches

Overview

These devices equip electrodes to detect liquid levels. They have been widely used in water works and sewers for buildings and housing complexes, industrial facilities and equipment, water treatment plants and sewage treatment facilities, and many other applications.

Overview of Level Switches

Floatless Level Controllers (61F) are electronic liquid level detectors used in a wide range of applications such as water and sewer services for office and apartment buildings, industrial applications for iron and steel, food, chemical, pharmaceutical, and semiconductor industries, and liquid level control for agricultural water, water treatment plants, and wastewater plants. When the electrodes are in contact with liquid, the circuit is closed (the liquid completes the path for electricity to flow) and the electrical current that flows in this circuit is used to detect the level of the liquid. A variety of conductive liquids can be controlled using this method. Detecting the resistance between the electrodes and comparing it to see if it is larger or smaller than a reference resistance is used to detect the surface of the liquid.

Operating Principle

The operating principle is explained using a case where water is supplied from the water mains.

Office and apartment buildings normally have a ground tank and an elevated tank. Water is supplied from the water mains into the ground tank, pumped up to the elevated tank, then distributed to each floor.

When the water level in the elevated tank is low, water is pumped up from the ground tank to supplement it. When the water level reaches a certain level, the pump stops. (See figure 1.)

Elevated tanks are controlled in this manner to maintain the water level within upper and lower limits as shown below.

Figure 1. Water Supply Control

Pump Control According to Water Level (Two-pole Method)

When electrode E₁ is not in contact with the conductive liquid as shown in figure 2, the electrical circuit is open, and no current flows between electrodes E₁ and E₃. Consequently relay X does not operate and the contact remains at the b side.
When electrode E₁ is in contact with the conductive liquid as shown in figure 3, the circuit closes due to the conductive fluid completing the circuit between E₁ and E₃. Relay X operates and switches to the a side.
By connecting the relay contacts to a contactor, the pump can be turned ON and OFF.
However in practice, with only two electrodes, ripples on the surface of the liquid cause the relay to switch rapidly. This problem can be solved by forming a self-holding circuit. (The configuration shown in figures 2 and 3 can be used as water level alarms.)

Figure 2. Low Water Level

Low Water Level

Figure 3. High Water Level

High Water Level

Liquid Level Control with Self-Holding Circuit (Three-pole Method)

An extra electrode E₂ is added, and E₁ and E₂ are connected via contact a2 as shown in figure 4. When electrode E₁ is in contact with the conductive liquid (as in point 2 of previous section), relay X operates and switches to the a side. Even if the liquid level falls below E₁, the electrical circuit made through the liquid and the electrodes is retained by E₂ and E₃, as long as contact a2 is closed.

This kind of circuit made from electrode E₂ and a contact is called a self-holding circuit.

When the liquid level falls below E₂, the circuit made through the electrode circuit opens, which de-energizes relay X, thus closing the NC contact of X. This enables control of relay X to be switched ON and OFF between E₁ and E₂.

Figure 5 shows the timing chart of this mechanism.

Operating as simply as it does, possible applications of the Floatless Level Controller other than liquid level control include applications as leakage detection, and object size discrimination.

Figure 4. Self-holding Circuit

Self-holding Circuit

Figure 5. Timing Chart

Timing Chart

Note: Non-conductive liquids, such as oil, cannot be controlled using this method.

Level Controller Selection Criteria

Categories (Reference Information)

Categorized by Fluid Types

Applicable liquids	Electrode	Electrode Holders	Relay Unit
Acid/alkaline solutions	Select electrodes based on corrosion resistance Table 4. (Separators are not used.)	Electrodes in BS-IT are outlined in Table 4. Separate each electrode with insulation.	Low-sensitivity 61F-[][]ND Level Controller (61F-11ND or equivalent, however depending on the cable length, the long-distance 61F-11NL Level Controller may be required.)
Boiler	SUS316 (The materials used make the water alkaline.)	BS-1 (Subject to high temperature and pressure.)	Standard 61F-[][] Level Controller
Tap water	SUS304, SUS316	PS, BF. No other specific requirements.	Standard 61F-[][] Level Controller, but when it is over a long distance, use a long-distance 61F-[][]L Level Controller.
Pure water (Ion-exchanged water)	Titanium (Maintains the purity level of water.)	BS-1T Titanium	May require a high-sensitivity Level Controller depending on conductivity 61F- [][]NH (61F-11NH) Ultra-high-sensitivity 61F-UHS Level Controller
Bubbles (Detection)	SUS304, SUS316, Titanium (Separators are not used.)	PS, BF	High-sensitivity 61F-GP-NH Level Controller or equivalent
Bubbles (No detection)	As above (Separators are not used.)	As above	Low-sensitivity 61F-[][]ND Level Controller
Wastewater	SUS304 (Low sainity) (Separators are not used.)	BF-1 is used with each electrodes separated.	Low-sensitivity 61F-[][]ND Level Controller
Oil mixed in water	SUS304	PS, BF use pipes to guard against the oil.	Standard 61F-[][] Level Controller
Steam	SUS316	PS-1, BF-1 If there is enough pressure to be able to separate the electrodes, use the BS-1.	Standard 61F-[][] Level Controller

Categorized by Installation Conditions of Electrodes

Installation Condition	Electrode	Electrode Holder
Confined space	PH underwater electrodes	--
Protect against rainwater	SUS304, SUS316	PS + F03-11 Protective Cover + F03-12 Frame
Objects from wastewater (i.e., clothing) get tangled	SUS304	The BF-1; separates the distance between electrode holders
Wastewater, contaminated water, or areas with clusters of grease	SUS304 or SUS316	As above
Elevated tank	SUS304 or SUS316	PS
Ground tank	SUS304 or SUS316, F03-05 Electrode Band, PH underwater electrodes	PS
Sewer, drains (manhole)	SUS304, SUS316	PS (Place the electrodes in a pipe in areas that accumulate grease, e.g., underground, factory pits)
Septic tank (Flushed matter)	SUS304	BF-1
Measurements at a depth like water wells	PH underwater electrodes	--
Areas where ice forms	PH underwater electrodes	--
High temperature (hot water tank)	SUS316	Temperatures under 50 °C, BS-1S2 No model is suitable for temperatures above 250 °C (Must be made by the user.)

Selection Criteria for 61F Level Controllers

Specific Resistance and Model Selection Criteria

The limit for specific resistance of liquid that can be controlled with a generic Level Controller is 30 kΩcm when using a PS-3S Electrode Holder within a submersion depth of 30 mm. For any fluid with specific resistance higher than this value, use a high-sensitivity Level Controller (H type). (See note.)

Table 1 and Table 2 shown upper and Table 3 below show specific resistances for typical liquids. Use these when selecting a model.

Note:
1. The high-sensitivity Level Controllers may suffer from resetting problems when used with certain types of water. In some cases it cannot substitute for the standard Level Controllers or Low-sensitivity Level Controllers. Be sure to select the model appropriate for the application.

2. The circuit configuration of the High-sensitivity 61F-[ ]H Level Controller is designed so that the relay is reset when there is water present between the electrodes. When power supply voltage is applied, the internal relay switches to the NO contact and, when there is conductivity between electrodes E1 and E3, the relay is reset to the NC contact.

This contact operation is reversed for models other than the high-sensitivity models. Although the internal relay operates (and operation indicator turns ON) simply when the power supply voltage is applied, this operation is normal. (The relay in the 61F-[ ]NH energizes when there is water present between the electrodes.)

Note: For the ultra high-sensitivity variable 61F-HSL Level Switch, malfunction due to electric corrosion may occur in the DC electrode circuit. Be careful not to use the product where current constantly flows between electrodes.

Table 1: Specific Resistance of Water (General Guideline)

Type of water

Specific Conductance

Tap water

5 to 10 kΩ · cm

Well water

2 to 5 kΩ · cm

River water

5 to 15 kΩ · cm

Rainwater

15 to 25 kΩ · cm

Seawater

0.03 kΩ · cm

Sewage

0.5 to 2 kΩ · cm

Distilled water

250 to 300 kΩ · cm min.

Table 2: Detectable Specific Resistance (Guideline)

Type of water

Specific resistance (recommended value)

Long distance (4 km)

5 kΩ · cm max.

Long distance (2 km)

10 kΩ · cm max.

Low sensitivity

10 kΩ · cm max.

Two-wire

10 kΩ · cm max.

General-purpose

10 to 30 kΩ · cm

High-temperature

10 to 30 kΩ · cm

High-sensitivity (COMPACT plug-in type)

30 to 200 kΩ · cm

High-sensitivity (base type)

30 to 300 kΩ · cm

Ultra high-sensitivity

100 kΩ to 10 MΩ · cm

Note: The specific resistance of liquids are those that can be controlled using the PS-3S when the submersion depth is 30 mm or less.

Conductance

Conductance is a scale describing how easily current can flow. The relationship of Conductance and resistance is defined by the following equation.

Conductance equals to 1 per resistance.
Table 1 can be modified to contain the corresponding conductance as shown in Table 1A.

Table 1A: Specific Conductance of Water (Guideline)

Type of water

Specific Conductance

Tap water

100 to 200 μS/cm

Well water

200 to 500 μS/cm

River water

67 to 200 μS/cm

Rainwater

40 to 67 μS/cm

Seawater

33,300 μS/cm

Sewage

500 to 2,000 μS/cm

Distilled water

3.3 to 4 μS/cm max.

Table 3: Specific Resistance of Various Liquids

Type of liquid

Temperature (°C)

Concentration (%)

Specific resistance (Ω· cm)

Beer (Company A)
Port wine (Company K)
Whisky (Company T)
Barium hydroxide Ba (OH)₂

12
12
12
12

---
---
---
---

830.0
966.0
14,608.0
1,743.0

Silver nitrate AgNO₃

18

5.0
60.0

39.5
4.8

Barium hydroxide Ba (OH)₂

18

1.25
2.5

40.0
20.9

Calcium chloride CaCl₂

18

5.0
20.0
35.0

15.6
5.8
7.3

Cadmium chloride CdCl₂

18

1.0
20.0
50.0

181.0
33.5
73.0

Cadmium sulfate CdSO₄

18

1.0
5.0
35.0

240.0
68.5
23.8

Nitric acid HNO₃

18
15
15

5.0
31.0
62.0

3.9
1.3
2.0

Phosphoric acid H₃PO₄

15

10.0
60.0
87.0

17.7
5.5
14.1

Sulphuric acid H2SO₄

18

5.0
30.0
97.0
99.4

4.8
1.4
12.5
117.6

Potassium bromide KBr

15

5.0
36.0

14.5
2.9

Potassium chloride KCI

18

5.0
21.0

14.5
3.6

Potassium chlorate KClO₃

15

5

27.2

Potassium cyanide KCN

15

3.25
6.5

19.0
9.8

Potassium carbonate K₂CO₃

15

5.0
30.0
50.0

17.8
4.5
6.8

Potassium fluoride KF

18

5.0
40.0

15.3
4.0

Potassium iodide KI

18

5.0
55.0

31.4
2.4

Potassium nitrate KNO₃

18

5.0
22.0

22.1
6.2

Potassium hydroxide KOH

15

4.2
33.6
42.0

6.8
1.9
2.4

Potassium monosulfide K₂S

18

3.18
29.97
47.26

11.8
2.2
3.9

Copper sulfate CuSO₄

18

2.5
17.5

92.6
21.8

Ferrous sulfate FeSO₄

18

0.5
3.0

65.0
21.7

Hydrogen bromide HBr

15

5.0
15.0

5.2
2.0

Hydrochloric acid HCl

15

5.0
20.0
40.0

2.5
1.3
1.9

Hydrogen fluoride HF

18

0.004
0.015
0.242
298.0

4,000.0
2,000.0
275.0
2.9

Mercuric chloride HgCl₂

18

0.229
5.08

22,727.0
2,375.0

Hydrogen iodide HI

15

5

7.5

Potassium sulfate K₂SO₄

18

5.0
10.0

21.8
11.6

Sodium chloride NaCl

18

5.0
25.0

14.9
5.6

Sodium carbonate Na₂CO₃

18

5.0
15.0

22.2
12.0

Sodium iodide NaI

18

22.2
12.0

33.6
4.7

Sodium nitrate NaNO₃

18

5.0
30.0

22.9
6.2

Sodium hydroxide NaOH

15

2.5
20.0
42.0

9.2
2.9
8.4

Sodium sulfate Na₂SO₄

18

5.0
15.0

24.4
11.3

Ammonia NH₃

15

0.1
4.01
3.05

3,984.0
913.0
5,181.0

Ammonium chloride NH₄Cl

18

5.0
25.0

50.5
2.5

Ammonium nitrate NH₄NO₃

15

5.0
50.0

16.9
2.7

Ammonium sulfate (NH₄)₂SO₄

15

5.0
31.0

18.1
4.3

Zinc chloride ZnCl₂

15

2.5
30.0
60.0

36.2
10.8
27.1

Zinc sulfate ZNSO₄

18

5.0
30.0

52.4
22.5

Selecting Electrode Material According to Resistance against Corrosion

To get the most out of the electrodes, refer to Table 4 to select the best material.

Table 4: Resistance to Corrosion of Electrode Material

Aqueous Solution

Electrodematerial

Type

Concentration (%)

Temperature (°C)

SUS
304

SUS
316

Titanium

HAS
B

HAS
C

SulphurousacidH₂SO₃

6

30

E

C

A

B

B

Sulphuric acid H₂SO₄

1

30

A

A

A

A

A

1

BP

E

D

E

B

C

3

30

B

A

A

A

A

3

BP

E

E

E

C

C

5

30

D

B

D

B

A

5

BP

E

E

E

D

D

10

30

E

C

E

A

A

10

BP

E

E

D

C

E

20

30

E

E

C

C

B

20

BP

E

E

D

D

E

40

30

E

E

D

B

B

40

BP

E

E

D

E

E

60

30

E

E

D

B

C

60

BP

E

E

D

C

D

70

30

E

E

D

B

B

70

BP

E

E

D

C

D

80

30

E

E

D

B

B

80

BP

E

E

D

D

D

90

30

E

E

D

B

B

90

BP

E

E

D

D

D

95

30

E

D

D

B

B

95

BP

E

E

D

D

D

Hydrochloric acid HCl

1

30

E

D

B

B

A

1

BP

E

E

E

D

C

3

30

E

E

B

B

A

3

BP

E

E

E

D

C

5

30

E

E

C

C

A

5

BP

E

E

E

E

D

10

30

E

E

E

C

C

10

BP

E

E

E

E

E

15

30

E

E

E

C

C

15

BP

E

E

E

E

E

20

30

E

E

E

C

D

20

BP

E

E

E

E

E

37

30

E

E

E

C

E

37

BP

E

E

E

E

E

Chromium oxide CrO₃

10

BP

D

C

A

B

C

20

30

C

B

A

B

B

36.5

90

E

E

C

C

C

Nitric acid HNO₃

10

30

B

A

A

D

A

10

BP

B

B

B

D

C

20

290

B

B

C

D

D

65

175

C

C

B

E

E

68

30

C

C

A

D

D

68

BP

D

D

B

E

E

90

80

E

E

A

E

E

Hydrogenfluoride HF

5

30

E

E

D

D

C

100

30

E

D

C

C

C

PhosphoricacidH₃PO₄

10to85

RT

B

B

C

B

C

AceticacidCH₃COOH

5to50

RT

A

A

A

A

A

100

RT

A

A

A

A

A

100

BP

C

B

A

A

A

Formicacid H·COOH

All

BP

D

D

D

A

A

Acetone CH₃·CO·CH₃

All

RT

B

B

A

A

A

Alum

All

RT

E

E

D

B

B

Aluminum sulfate

50

BP

D

C

B

C

A

Ammonium chloride NH₄Cl

5

BP

D

D

A

B

B

Ammonium nitrate NH₄NO₃

All

BP

A

A

A

B

B

Ammonium sulfate (NH₄)₂SO₄

5

RT

E

D

B

B

C

10

BP

E

E

B

B

C

Ammonia NH₃

100

100

C

C

A

B

B

10

BP

C

B

B

B

C

28

60

C

B

A

B

B

Potassiumhydroxide KOH

25

BP

B

A

C

B

C

Sodiumhydroxide NaOH

30

60

A

A

B

A

B

50

65

B

A

C

A

C

Sodium carbonate Na₂CO₃

25

BP

B

B

B

B

B

Potassium carbonate K₂CO₃

20

BP

B

B

B

B

B

Zinc chloride ZnCl₂

50

150

D

C

B

B

C

Calcium chlorideCaCl₂

25

BP

C

C

A

A

A

Sodium chloride NaCl

25

BP

C

B

A

B

B

Ferric chloride

30

RT

E

E

A

E

B

Copper chloride

30

RT

E

E

A

E

B

Sea water

RT

C

C

A

B

A

Hydrogenperoxide H₂O₂

10

RT

B

B

B

B

B

Sodium sulfite

10

RT

B

B

A

B

B

Citric acid

All

RT

B

A

C

A

A

Oxalicacid CO₂H·CO₂H

All

RT

B

A

D

B

B

Sodium hypochlorite

10

RT

E

D

A

C

C

Potassium dichromate

10

BP

C

B

A

B

C

Magnesium chloride

30

RT

C

B

A

A

A

Magnesium sulfate

10

RT

B

B

A

A

A

Note:

1. RT: Room temperature; BP: Boiling point

2.

A: Adequate resistance to corrosion
B: Resistive to corrosion, erosion rate is less than 0.8 mm/year
C: Low resistance to corrosion, erosion rate is less than 1.8 mm/year
D: Highly corrosive, not usable
E: No resistance to corrosion, not usable

3. The table above is used for reference when selecting the electrodes. Even if the material has adequate corrosion resistance, it doesn't mean that it is not subject to corrosion.
Check regularly once a month to see if corrosion is occurring. If it is, replace the electrodes.

Reference

When selecting an Electrode Holder, make sure that you consider the corrosion resistance of the material of electrode holders as it may be exposed to the liquid inside the water tank.

Level Switch Glossary >>

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