KEM Küppers flowmeters include the ZHM round gear PD meter

Litre Meter are the exclusive UK distributors for KEM Küppers.  These include the ZHM, SRZ positive displacement, HM turbine and the Tricor coriolis series. Sign up for FlowSight, the Litre Meter newsletter.

KEM ZHM01/3 gear meter
KEM ZHM01/3 gear meter

The ZHM series is highly engineered round gear PD flowmeter suitable for a slew of different applications such as hydraulic oil, automotive paint and chemical dispense measurement.

  • From 0.002 to 1 LPM to 1,000 LPM
  • Ratings to 315, 414, 690 bar and higher
  • Accuracy: ±0.5% of reading or better
  • Repeatability: ±0.05% of reading
  • Can be installed in any orientation
  • Cartridge, compact & aluminium options.

All of these units are manufactured in Germany by Litre Meter’s sister company, KEM Kueppers GmbH.



Low Flow Calibration – limits

The accuracy of the flowmeter can be determined by the change in the pulses per litre value over a flow rate range selected from the calibration certificate.  (This source document is also available for download from

  • Repeatability is better than ±0.1% of reading over the top 99% of range.
  • Accuracy with linearisation is better than ±0.5% of reading.

The minimum flow rate achievable depends on many variables but can be reduced to two factors:

  • the viscosity of the fluid. The higher the viscosity, the lower the low flow rate ability.
  • the perfection of the meter dimensions and components.
  1. Standard (STD) calibration rates can be achieved 99 times out of a 100. No special selection required
  2. Low Flow (LF) calibration requires matched parts and more calibration time
  3. Ultra Low Flow (ULF) calibration requires the best parts and the most patience by our calibration engineers. It is highly unlikely we can provide a batch of ULF meters due to their scarcity.

In particular, for LF03, LF05 and LF15, we can compare the low flow limits both on a linear scale and, secondly, on a logarithmic scale, as well as in a traditional table. The respective maxima are 18, 30 and 90 litres per hour:

Describes the low flow performance of the LF15
VFF flowmeter LF15 – flow range on various viscosities STD vs. LF vs. ULF
Describes the low flow performance of the LF05
VFF flowmeter LF05 – flow range on various viscosities STD vs. LF vs. ULF
Describes the low flow performance of the LF03
VFF flowmeter LF03 – flow range on various viscosities STD vs. LF vs. ULF

These tables were all updated in August 2019; rounding of some of the flow rate values understated the flowmeters’ abilities.

Additionally, work is underway to improve availability of the LF and ULF calibration bands.  Each rotor and chamber is now pre-calibrated on a nominal viscosity when first received. In actual fact, they are not calibrated as such but the low flow is determined using a custom flow programme on our automatic calibration lab.  This low flow value then enables the chamber and rotor to be categorised into one of the three bands. When an order is received with flow range and viscosity parameters the best chamber and rotor can then be selected with a high confidence level.

Reverse flow measurement – an expert view

Most flowmeters are setup for forward flow measurement. That is, they have a preferred direction for operation and that is adopted by the manufacturer/designer and advised to the customer.

Some flowmeters are symmetrical in the forward and reverse direction and will work in the reverse direction, too. Some are symmetrical and may not function or function well, due to meter design or principle, in reverse.

Finally, some meters may detect that the flow is in reverse and, better still, measure in either direction to the same accuracy.

We use the term flowmeter generically. When discussing flow direction and measurement we should consider the instrumentation as well as the flow sensor itself.


Type A – not designed for Reverse flow, may cause damage:
Type B – can accept reverse flow, no detection
Type C – can accept reverse flow, detects direction of flow
Type D – Can accept reverse flow, measures accurately but doesn’t output direction
Type E – Accepts reverse flow and provides flow velocity and direction

B, C, D, E may need special instrumentation to extract the desired information.  The type designation just helps us understand the designs – it isn’t used outside of this article.

Flowmeter element Type
Orifice plate B, C, D or E
Wedge B, C, D or E
Venturi tube B, C, D or E
Flow Nozzle B or C
Pitot tube B
Elbow meter B, C, D or E
Target meter B or C
VA A or E (E with a special meter)
Positive Displacement A, B, C, D or E depends on design and sensing
Turbine A, B, C, D or E depends on design and sensing
Pelton A, B, C, D or E depends on design and sensing
Vortex A or B
Electromagnetic B, C, D or E – most units would be E
Ultrasonic(Doppler) B, C, D or E – most units would be E
Ultrasonic(Time-of-travel) B, C, D or E – most units would be E
Mass Coriolis B, C, D or E – most units would be E
Thermal Mass Insertion B
Thermal Mass Capillary B
Weir A
Flume B


Litre Meter flowmeters

Pelton Wheel

The LM range have a jet (apart from the LM220 and LM330). With a jet concentrating the flow onto the rotor, a reverse flow is very inefficient and the rate of rotation is much reduced for the same flow. The 220 and 330 are broadly symmetrical in some models and have different pipe layouts in most versions. These have never been fitted with technology to provide direction.

The same can be said of the larger, orifice plate based, MM meter. The inlet and outlet holes to the pelton wheel chamber are much different in size, so function poorly in reverse. A sole MM was manufactured with two pelton wheels and two sensors facing in different directions. By comparing the magnitude of the signals it was simple to tell which direction was active.


All VFF (rotary piston positive displacement) meters are perfectly symmetrical in design with rotors able to rotate clockwise or anticlockwise. There are small differences in machining so there are small differences in meter performance forward and reverse. There is a prescribed forward direction (purely for consistency) but the client can select the other direction as forward.

With a standard sensor the output is the same whether the flow is forward or reverse – just a series of pulses. When two sensors are fitted then the direction and magnitude of flow can be determined if the right instrumentation is used.

There are two suitable instruments used by Litre Meter and at least one system used by clients with varying degrees of sophistication. Sometimes two sensors are fitted for redundancy purposes. The instrument monitors one sensor. After a certain time period, if there isn’t a pulse attention is switched to the other sensor. The period is set to be a few seconds longer than the frequency for lowest flow achievable or the clients lowest expected flow.

Litre Meter use two sensor setups both based on reed switch sensing of the magnet in the VFF rotor. Litre Meter are developing a 3-D magnetometer based field sensor that can determine the position of the rotor in the chamber for finer pulse output.

If reed A switches before reed B then direction is forward. If B before A then direction is reverse.

The two reed switch setups are similar in concept but packaged differently. The original reed switch is situated in a sensor hole. When two reeds are used there are two parallel holes generally situated along the radius of gyration of the magnet. They are spaced to produce a clear lead or lag depending on rotor direction. The Fluidwell F115 is designed to interpret the lead/lag to produce a display with directionality.

With the introduction in 2015 of the CIFM versions of the VFF and the Litre Meter FlowPod the sensor was repackaged, with two reeds as standard, in an M8 stainless sensor body. Only one sensor hole is required as the reeds are side by side. The F115 and FlowPod can both interpret the CIFM sensor output.


Fluidwell manufacture a wide range of instrumentation which Litre Meter have used since 2002. The F115 version is specifically designed for directionality. It does not have linearisation.


The flow rate / totalizer model F115-P is a microprocessor driven instrument designed to show the flow rate, the total and the accumulated total. This model is able to detect the flow direction and to show a positive or negative flow rate, the totals for both directions and the cumulative totals.
This product has been designed with a focus on:

  1. ultra-low power consumption to allow long-life battery powered applications (type PB/PC),
  2. intrinsic safety for use in hazardous applications (type XI);
  3. several mounting possibilities with aluminum or GRP enclosures for harsh industrial surroundings;
  4. ability to process all types of flowmeter signals;
  5. transmitting possibilities with analog / pulse and communication outputs.
Flowmeter input

Two sensors with a phase difference of 90 or 270 degrees, can be connected to the F115-P.

Standard outputs
  1. Pulse output to transmit a pulse that represents a totalized quantity as programmed.
  2. Negative / positive pulse output indication – i.e. a flag.
  3. Linear 4-20mA analog output to represent the actual flow rate as programmed. The 4-20mA signal limits can be tuned.



The FlowPod was designed from the outset with the CIFM sensor which is fitted with two closely positioned reed switches in one M8 stainless steel package. They are positioned in the flowmeter to provide a two separate pulses along the path of the spinning rotor. They are fairly close together such that there is a distinct time difference between reed A and B depending on direction.

In most installations the second reed is for redundancy purposes. The FlowPod monitors reed A. After a certain time period, if there isn’t a pulse, attention is switched to reed B. The period is set to be a few seconds longer than the frequency for lowest flow achievable or the lowest expected flow.

For directionality the FlowPod monitors reed A and B and interprets lead and lag to determine flow direction. Within the software forward direction can be set as ‘A before B’ or vice versa. Redundancy is still offered, although, of course, without direction.

Linearisation is standard on the FlowPod. The curve of flow rate versus frequency is similar in forward and reverse.


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