Product guide
Bare wire technology
The Zip ES, CEX, DEX and DBX models
feature bare wire heating technology using
stainless steel elements directly immersed
in the water flow path.This system achieves
maximum efficiency by means of direct
contact with the water flow plus the fastest
possible heat up times.
Unlimited supply of hot water *
Zip InLine will deliver a continuous supply at
the selected temperature.
Easy installation
Zip InLine products simply connect to
standard closed outlet taps without the need
for unvented water controls.
Smart design
The unit’s compact size enables it to fit
neatly and unobtrusively in any location.
Water conservation
Zip InLine is designed for installation close
to the point of use, avoiding the need
for water to be run off before achieving
temperature.
Savings per draw off compared to
centralised systems with long pipe runs are
as follows:
Why Zip InLine instantaneous
water heating?
Zip InLine instantaneous water heaters are
the most energy efficient way of directly
heating water electrically.
Using the very latest German technology,
Zip InLine offers a host of Specifier, Installer
and End User benefits:
• Unrivalled energy efficiency
- no standing heat loss.
• Sophisticated electronic control.
• Unlimited hot water supply.
• Easy to install.
• Compatible with standard tapware.
• Neat compact design.
• Tangible water savings.
Energy efficiency
Zip InLine saves energy by:
• Heating only the water drawn off.
• Avoiding stored water heat losses.
When comparing the energy used over 24
hrs to deliver 75 litres of water at 38°C
(assuming 12°C supply) typical savings of
23% can be achieved.
N.B. Percentage savings may be less with
increased demand but more during periods
without draw off.
68 69
Zip InLine
instantaneous water heating
The inside story
Product Energy Usage
15 litre storage water heater 3.0kWh
Zip InLine 2.3kWh
Traditional system Litres saved
pipe run 15mm per draw off
10 metres 3.2
* Subject to sufficient power being available to achieve the required
temperature and outlet flow under local conditions.
Hot water
Hot water