Olimpia Splendid Sherpa Aquadue S3

Revolutionize your home’s comfort and efficiency with the Olimpia Splendid Sherpa Aquadue S3, a cutting-edge air-to-water heat pump featuring R32 refrigerant and patented AQUADUE® technology. This multi-purpose system delivers seamless cooling, heating, and high-temperature domestic hot water production up to 75°C—all from a single solution. Whether it's managing year-round comfort or ensuring ample hot water, the Olimpia Splendid Sherpa Aquadue S3 excels in performance and sustainability.

The innovative dual refrigeration circuit of the Olimpia Splendid Sherpa Aquadue S3 enables simultaneous operation of heating, cooling, and hot water production without compromising comfort. Its advanced design minimizes energy peaks by storing high-temperature water, eliminating the need for frequent anti-legionella cycles. This not only reduces electricity consumption but also allows for a more compact boiler system, saving up to 30% in space while delivering the same amount of hot water.

With its eco-friendly R32 refrigerant and versatile functionality, the Olimpia Splendid Sherpa Aquadue S3, product ID Sherpa Aquadue S3, is a powerful and efficient choice for modern living. Transform your indoor climate control and hot water management with this state-of-the-art solution, tailored for ultimate convenience and sustainability.

FEATURES

• Inverter air-water heat pump with R32 refrigerant
• Energy efficiency class in average climate heating up to: A+++ (35°C) and A++
(55°C)
• Powers available: 10 powers with refrigerant R32 single-phase (4-6-8-10-12-14-16
kW) and three-phase (12-14-16 kW).
• Production of DHW (Domestic Hot Water) at high temperature, up to 75°C.
• DHW management: a water/water heat pump unit integrated in the internal
unit supplies domestic hot water at high temperature regardless of the external
climatic conditions.
• Absolute continuity availability of DHW: guaranteed by the redundancy of the
double refrigerantion circuit
• Anti-legionella cycles that can be avoided using the high temperature
refrigeration cycle.
• Double stage electric heating elements as standard: activation of single or double
heating element to support the heat pump by means of a simple electronic control
configuration. Each stage is activated according to the actual need for thermal
power, in order to optimise electricity consumption (supplied disabled by default).

• Configurable set points: two set points in cooling, Three set points in heating (one
of which for DHW): the set points can also be selected via remote contact.
• Holiday and weekly programmer: heating/cooling, DHW, night-time.
• Climatic curves with external air temperature probe: two curves available, one for
cooling and one for heating. The climatic curves are used to vary the temperature
of the water supplying the system according to the external climatic conditions,
adjusting the thermal needs of the building, in order to achieve energy savings.
• Refrigerant gases: R32* for the reversible circuit dedicated to air conditioning and
R134a** for the high temperature circuit dedicated to the production of DHW.
• Built-in 150 L high efficiency storage tank (tower version) with an exchange
battery surface equal to 1.5 m2.
• Operating limits: down to -25°C, +43°C (see technical manuals for details).
• Integrated heating cable to prevent freezing of water in the tray for sizes 12-14-16
and 12T-14T-16T. The heating cable intervenes during machine defrost operations
or when the ambient air is below -7°C and cuts out when it exceeds 4°C (85W
power consumption).

DHW AND COMFORT AT THE SAME TIME
The two interconnected refrigerator cycles allow the
decoupling of the heating/cooling from the DHW
production, enabling them to operate in parallel, avoiding
thus interruptions in the domestic comfort supply.
DOMESTIC HOT WATER UP TO 75°C
The storage of DHW at high temperature makes
it possible to reduce the volume of the storage
tank by up to 30%, and to avoid energy-intensive
consumption of the anti-Legionnaire’s disease
cycles, since they are normally carried out by the use
of electric heating elements.
PHOTOVOLTAIC INTEGRATION
Thanks to the appropriate contact, it is possible to
activate an increase in the heating/DHW temperature
and a decrease in the cooling temperature, thereby
accumulating thermal energy in the event of
overproduction of the photovoltaic system.