Dimplex SI 130TU Water Heat Pump Instruction Manual
- June 13, 2024
- Dimplex
Table of Contents
- Safety notes
- Intended use of the heat pump
- Basic device
- Accessories
- Transport
- Installation
- Installation
- Commissioning
- Cleaning / maintenance
- Faults / troubleshooting
- Decommissioning / disposal
- Device information
- Product information as per Regulation (EU) No 813/ 2013, Annex II, Table
- Read User Manual Online (PDF format)
- Download This Manual (PDF format)
Dimplex SI 130TU Water Heat Pump Instruction Manual
Safety notes
Symbols and markings
Particularly important information in these instructions is marked with
CAUTION! and NOTE.
CAUTION
Immediate danger to life or danger of severe personal injury or significant
damage to property.
NOTE
Risk of damage to property or minor personal injury or important information
with no further risk of personal injury or damage to property.
Intended use
This device is only intended for use as specified by the manufacturer. Any
other use beyond that intended by the manufacturer is prohibited. This
requires the user to abide by the relevant project planning documents. Please
refrain from tampering with or altering the device.
Legal regulations and directives
This heat pump is designed for use in a domestic environment according to
Article 1, Paragraph 2 k) of EU directive 2006/42/ EC (machinery directive)
and is thus subject to the requirements of EU directive 2014/35/EU (low-
voltage directive). It is thus also intended for use by non-professionals for
heating shops, offices and other similar working environments, agricultural
establishments and hotels, guesthouses and other residential buildings. This
heat pump conforms to all relevant DIN/VDE regulations and EU directives.
Refer to the EC Declaration of Conformity in the appendix for details. The
heat pump must be connected to the power supply in compliance with all
relevant VDE, EN and IEC standards. Any further connection requirements
stipulated by local utility companies must also be observed. The heat pump is
to be connected to the heat source system and the heating system in accordance
with all applicable regulations. This unit can be used by children aged 8 and
over and by persons with limited physical, sensory or mentalaptitude or lack
of experience and/or knowledge, providing they are supervised or have been
instructed in the safe use of the unit and understand the associated potential
dangers. Children must not play with the device. Cleaning and user maintenance
must not be carried out by children without supervision
CAUTION!
Work on the heat pump must only be performed by authorised and qualified
after-sales service technicians!
CAUTION!
When operating or maintaining a heat pump, the legal requirements of the
country where the heat pump is operated apply. Depending on the refrigerant
fill quantity, the heat pump must be inspected for leaks at regular intervals
by a certified technician, and these inspections must be recorded.
Energy-efficient use of the heat pump
By operating this heat pump you are helping to protect our environment. Both
the heating system and the heat source must be properly designed and
dimensioned to ensure efficient operation. It is particularly important to
keep water flow temperatures as low as possible. All connected heat consumers
should therefore be suitable for low flow temperatures. Raising the heating
water temperature by 1 K corresponds to an increase in electricity consumption
of approx. 2.5 %. Low-temperature heating systems with flow temperatures
between 30 °C and 50 °C are particularly well-suited for energy-efficient
operation.
Intended use of the heat pump
Intended purpose
The brine-to-water heat pump is to be used exclusively for the heating of
heating water. It can be used in new or existing heating systems. A mixture of
water and frost protection (brine) is used as a heat transfer medium in the
heat source system. Borehole heat exchangers, ground heat collectors or
similar systems can be used as the heat source system.
Operating principle
The heat generated by the sun, wind and rain is stored in the ground. This
heat stored in the ground is collected at a low temperature by the brine
circulating in the ground heat collector, the borehole heat exchanger or a
similar system. A circulating pump then conveys the “heated” brine to the
evaporator of the heat pump. There the heat is given off to the refrigerant in
the refrigeration circuit. This cools the brine so that it can once again
absorb thermal energy in the brine circuit. The refrigerant is drawn in by the
electrically driven compressor, compressed and “pumped” to a higher
temperature level. The electrical power needed to run the compressor is not
lost in this process. Most of it is absorbed by the refrigerant. The
refrigerant subsequently passes through the liquifier where it transfers its
thermal energy to the heating water. Depending on the set operating point, the
heating water can thus be heated up to a max. of 62 °C.
Basic device
The basic device consists of a heat pump for indoor installation
wired ready for use with metal casing, switch box and integrated heat pump
manager. The refrigeration circuit is “hermetically sealed” and contains the
fluorinated refrigerant R410A included in the Kyoto protocol. Information on
the GWP value and CO2 equivalent of the refrigerant can be found in the
chapter Device information. The refrigerant is CFC free, non-ozone depleting
and non-combustible. All components required for the operation of the heat
pump are located in the switch box. An outside temperature sensor including
fixing accessories and a dirt trap are supplied with the heat pump. The supply
for the supply voltage and the control voltage must be installed by the
customer. The circulating pumps (brine and heating water side) included in
the scope of supply must be installed in accordance with the hydraulic
diagrams (see Cap. 4 on pag. XII) or the development documents. The electrical
connection of the circulating pumps must be established in accordance with
Cap. 7.5.3 on pag. 8. The customer must provide both the heat source system
and the brine circuit manifold.
- Switch box
- Evaporator
- Liquefier
- Filter dryer
- Compressor 1
- Compressor 2
- Expansion valve
- Economiser
Accessories
Connection flange
The device can optionally be switched to flange connection using the flat-
sealing connection flange.
Remote control
A remote display adds convenience and is available as a special accessory.
Operation and menu navigation are identical to those of the heat pump manager.
Connection takes place via an interface (special accessories) with RJ 12
Western plug.
NOTE
In the case of heating controllers with a removable control panel, this can
also be used directly as a remote display.
Building management system
The heat pump manager can be connected to a building management system network
via supplementation of the relevant interface plug-in card. The supplementary
installation instructions of the interface card must be consulted regarding
the exact connection and parameterisation of the interface.
The following network connections can be made on the heat pump manager:
- Modbus
- EIB, KNX
- Ethernet
CAUTION!
If the heat pump or circulating pumps are controlled externally, a flow rate
switch is required to prevent the compressor from being switched on when there
is no volume flow.
Transport
A lift truck is suited for transporting the unit on a level surface. Carrying
straps may be used if the heat pump needs to be trans-ported on an uneven
surface or carried up or down stairs. These straps can be passed directly
underneath the pallet.
CAUTION!
The heat pump must not be tilted more than 45° (in any direction).
Use the holes provided in the sides of the frame to lift the unit without the
pallet. The side panel assemblies must be removed for this purpose. Any
commercially available length of pipe can be used as a carrying aid. After
transportation, the transport fastening in the device is to be removed from
both sides of the base.
CAUTION!
Before commissioning, the transport fastening must be removed.
All panelling can be removed to allow accessing the inside of the device. To remove the panelling, open the individual covers by unscrew-ing the respective turn-lock fasteners and then gently tilting the covers away from the device. Then lift them up out of the mount-ings.
Installation
General Information
The brine-to-water heat pump must be installed in a frost-free, dry room on an
even, smooth and horizontal surface. The entire base of the frame should lie
directly on the floor to ensure an adequate soundproof seal. If this is not
the case, additional sound insulation measures may be necessary. The heat pump
must be installed so that maintenance work can be carried out without
hindrance. This can be ensured by maintaining a clearance of approx. 1 m in
front of the heat pump.
Neither frost nor temperatures higher than 35 °C must occur in the installation location at any time of the year.
NOTE
The heat pump is not intended for use over 2000 metres above sea level.
Acoustic Emissions
The heat pump operates silently due to efficient sound insulation. Internal
insulation measures should be carried out to prevent vibrations from being
transmitted to the foundation or to the heating system.
Installation
General
The following connections need to be established on the heat pump. The
hydraulic integration diagram must be adhered to:
- Flow and return of the brine (heat source system)
- Flow and return of the heating system
- Temperature sensor
- Voltage supply
Connection on the heating side
CAUTION!
Flush the heating system prior to connecting the heat pump.
Before connecting the heating water system to the heat pump, the heating system must be flushed to remove any impurities, residue from sealants, etc. Any accumulation of deposits in the liquifier could cause the heat pump to completely break down. Once the heat pump has been connected to the heating system, it must be filled, de-aerated and pressure-tested.
CAUTION!
The maximum test pressure in the heating circuit and the brine circuit is 6.0
bar. This value must not be exceeded.
The following points must be observed when filling the system:
- Untreated filling water and make-up water must be of drinking water quality. (colourless, clear, free of sediments)
- Filling water and make-up water must be pre-filtered (max. pore size 5 µm).
Scale formation in domestic hot water heating systems cannot be avoided, but in systems with flow temperatures below 60 °C, the problem can be disregarded. With high-temperature heat pumps and in particular with bivalent systems in the higher performance range (heat pump + boiler combination), flow temperatures of 60 °C and more can be achieved. The following standard values should therefore be adhered to with regard to the filling and make-up water according to VDI 2035, sheet 1: The total hardness values can be found in the table.
Total heat output in kW| Total alkaline earths in
mol/m³ and/or mmol/l| Specific system volume (VDI 2035) in l/kW
---|---|---
< 20| ³ 20 < 50| ³ 50
Total hardness in °dH
< 50| £ 2.0| £ 16.8| £ 11.2| < 0.111
50 – 200| £ 2.0| £ 11.2| £ 8.4
200 – 600| £ 1.5| £ 8.4| < 0.111
600| < 0.02| < 0.111
- This value lies outside the permissible value for heat exchangers in heat pumps.
Fig. 7.1: Guideline values for filling and make-up water in accordance
with VDI 2035
For systems with an above-average specific system volume of 50 l/kW, VDI 2035
recommends using fully demineralized water and a pH stabiliser to minimize the
risk of corrosion in the heat pump and the heating system.
CAUTION!
With fully demineralized water, it is important to ensure that the minimum
permissible pH value of 7.5 (minimum permissible value for copper) is complied
with. Failure to comply with this value can result in the heat pump being
destroyed.
Minimum heating water flow rate
The minimum heating water flow rate through the heat pump must be assured in
all operating states of the heating system. This can be accomplished, for
example, by installing a dual differential pressureless manifold.
The frost protection function of the heat pump manager is active whenever the heat pump manager and the heat circulating pumps are ready for operation. The system must be drained if the heat pump is taken out of service or in the event of a power failure. If heat pump systems are implemented in buildings where a power failure cannot be detected (holiday homes etc.), the heating circuit should be operated with suitable frost protection.
Heat source connection
The following procedure must be observed when making the connection:
Connect the brine pipe to the heat source flow and return of the heat pump.
The hydraulic integration diagram must be adhered to.
CAUTION!
The supplied dirt trap must be inserted in the heat source inlet of the heat
pump to protect the evaporator against the ingress of impurities.
The brine must be produced prior to charging the system. The brine concentration must be at least 25 %. This guarantees frost protection up to approx. -14 °C. Only monoethylene glycol or propylene glycol-based antifreeze may be used. The heat source system must be de-aerated and checked for leaks.
CAUTION!
The brine must contain at least a 25 % concentration of a monoethylene glycol
or propylene glycol-based antifreeze, which must be mixed before filling.
** NOTE**
If necessary, the operating range can be extended to a brine inlet temperature
of -10 °C. In this case, the minimum brine concentration must be adjusted to
30 %. (Freezing temperature -17 C°).
CAUTION!
The maximum test pressure in the heating circuit and the brine circuit is 6.0
bar. This value must not be exceeded.
CAUTION!
A suitable de-aerator (micro bubble air separator) must be installed in the
heat source circuit by the customer.
Temperature sensor
The following temperature sensors are already installed or must be installed
additionally:
- Outside temperature sensor (R1) supplied (NTC-2)
- Return temperature secondary circuit (R2) installed (NTC-10)
- Return temperature primary circuit (R24) installed (NTC10)
- Flow temperature secondary circuit (R9) installed (NTC-10)
- Flow temperature primary circuit (R6) installed (NTC-10)
Sensor characteristic curves
Temperature in °C| -20| -15| -10| -5| 0| 5|
10
---|---|---|---|---|---|---|---
NTC-2 in k W| 14.6| 11.4| 8.9| 7.1| 5.6| 4.5| 3.7
NTC-10 in k W| 67.7| 53.4| 42.3| 33.9| 27.3| 22.1| 18.0
15| 20| 25| 30| 35| 40| 45| 50|
55| 60
2.9| 2.4| 2.0| 1.7| 1.4| 1.1| 1.0| 0.8| 0.7| 0.6
14.9| 12.1| 10.0| 8..4| 7.0| 5.9| 5.0| 4.2| 3.6| 3.1
The temperature sensors to be connected to the heat pump manager must
correspond to the sensor characteristic curve illustrated in Fig. 7.2. The
only exception is the outside temperature sensor included in the scope of
supply of the heat pump (see Fig. 7.3)
Fig. 7.2:Sensor characteristic curve NTC-10
Fig. 7.3: Sensor characteristic curve NTC-2 according to DIN 44574 Outside temperature sensor
Mounting the outside temperature sensor
The temperature sensor must be mounted in such a way that all weather
conditions are taken into consideration and the measured value is not
falsified.
- On the external wall of a heated room used as living space, if possible on the north or north-west side of the building
- Do not install in a “sheltered position” (e.g. in a wall niche or under a balcony)
- Not in the vicinity of windows, doors, exhaust air vents, external lighting or heat pumps
- Not to be exposed to direct sunlight at any time of year
Dimensioning parameter sensor lead
Conductor material| Cu
Cable-length| 50 m
Ambient temperature| 35 °C
Laying system| B2 (DIN VDE 0298-4 / IEC 60364-5-52)
External diameter| 4-8 mm
Installing the strap-on sensor
It is only necessary to mount the strap-on sensors if they are included in the
scope of supply of the heat pump but have not yet been installed.
The strap-on sensors can be fitted as pipe-mounted sensors or installed in the
immersion sleeve of the compact manifold.
Mounting as a pipe-mounted sensor
- Remove paint, rust and scale from heating pipe.
- Coat the cleaned surface with heat transfer compound (apply sparingly).
- Attach the sensor with a hose clip (tighten firmly, as loose sensors can cause malfunctions) and thermally insulate.
Hydraulic distribution system
The compact manifold and the dual differential pressureless manifold function
as an interface between the heat pump, the heating distribution system, the
buffer tank and, in some cases, even the domestic hot water cylinder. A
compact system is used to simplify the installation process, so that a lot of
different components do not have to be installed individually. Further
information can be found in the relevant installation instructions.
Compact manifold
The return sensor can remain in the heat pump, or should be installed in the
immersion sleeve. The remaining empty space between the sensor and the
immersion sleeve must be filled completely with heat transfer compound.
Dual differential pressureless manifold
In order for the heating circuit pumps of the generator and consumer circuits
to supply the flow to the return sensor, this must be installed in the
immersion sleeve of the dual differential pressureless manifold.
Electrical connection
General
All electrical installation work must be carried out by a trained electrician
or a specialist for the specified tasks in accordance with the
- installation and operating instructions,
- country-specific installation regulations (e.g. VDE 0100),
- technical connection conditions of the energy suppliers and supply grid operators (e.g. TAB) and
- local conditions.
To ensure that the frost protection function of the heat pump works properly, the heat pump manager must remain connected to the power supply and the flow must be maintained through the heat pump at all times. The switching contacts of the output relay are interferencesuppressed. Therefore, depending on the internal resistance of the measuring instrument, a voltage can also be measured when the contacts are open. However, this will be much lower than the line voltage.Extra-low voltage is connected to controller terminals N1-J1 to N1-J11; N1-J19 to N1-J20; N1-J23 to N1-J26 and the terminal strips X3. If, due to a wiring error, the line voltage is mistakenly connected to these terminals, the heat pump manager will be destroyed.
NOTE
For installation work on the switch box, ensure that the mains cable and
signal cables are inserted separately into the switch box. The specially
arranged switch box inlets must be used for this purpose (see Fig.7.4 on pag.
7). The mains cables and signal cables must also always be laid separately in
the switch box during wiring work.
Electrical installation work
-
The four-core electrical supply cable for the heat pump power part is fed from the heat pump electricity meter into the heat pump via the utility company blocking contactor (if required) (for supply voltage, see heat pump manual). The mains cable is connected to the heat pump contact plate via terminals X1: L1/L2/L3/PE.
CAUTION!
Ensure that there is a clockwise rotating field: With incorrect wiring the starting of the heat pump is prevented. A corresponding warning is indicated on the display of the heat pump manager (adjust wiring).
An all-pole disconnecting device with a contact gap of at least 3 mm (e.g. utility company blocking contactor or power contactor) and an all-pole circuit breaker with common tripping for all external conductors must be installed in the power supply for the heat pump (tripping current and characteristic in compliance with the device information). -
The three-core supply cable for the heat pump manager (heating controller N1) is fed into the heat pump. Connection of the control cable to the contact plate of the heat pump via terminal X2: L/N/PE. The (L/N/PE~230 V, 50 Hz) supply cable for the heat pump manager must have a continuous voltage. For this reason, it should be tapped upstream from the utility company blocking contactor or be connected to the household current, as important protection functions could otherwise be lost during a utility block.
-
The utility company blocking contactor (K22) with main contacts and an auxiliary contact must be designed and provided by the customer in accordance with the heat pump output. The NO contact of the utility company blocking contactor is looped from the terminal strip X3/G to the plug-in terminal X3/ID3. CAUTION! Extra-low voltage!
-
The contactor (K20) for the immersion heater (E10) of mono energy systems (HG2) should be dimensioned according to the radiator output and must be supplied by the customer. It is controlled (230 V AC) by the heat pump manager via terminals X2/N and X2/K20.
-
The contactor (K21) for the flange heater (E9) in the domestic hot water cylinder should be dimensioned according to the radiator output and must be supplied by the customer. It is controlled (230 V AC) by the heat pump manager via terminals X2/N and X2/K21.
-
The contactors mentioned above in points 3, 4 and 5 are installed in the electrical distribution system.
-
All installed electric cables must have permanent wiring.
-
The heat circulating pump (M13) is activated via the contact N1-J13/NO5. The connection points for the pump are X2/M13 and X2/N. When using pumps where the switching capacity exceeds the output, a coupling relay must be interposed.
-
The auxiliary circulating pump (M16) is activated via the contact N1-J16/NO9. The connection points for the pump are X2/M16 and X2/N. A coupling relay is already integrated in this output.
-
The domestic hot water circulating pump (M18) is activated via the contact N1-J13/NO6. The connection points for the pump are X2/M18 and X2/N. When using pumps where the switching capacity exceeds the output, a coupling relay must be interposed.
-
The brine or well pump (M11) is activated via the contact N1-J12/NO3. The connection points for the pump are X2/ M11 and X2/N. A coupling relay is already integrated in this output.
-
The return sensor (R2) is integrated in the heat pumps for indoor installation. The heat pump manager is connected via the following terminals: X3/GND and X3/U2.
-
The external sensor (R1) is connected to terminals X3/GND and X3/U1.
-
The domestic hot water sensor (R3) is included with the domestic hot water cylinder and is connected to terminals GND and X3/U3.
Connection of electronically regulated circulating pumps
Electronically regulated circulating pumps have high starting currents, which
may shorten the service life of the heat pump manager. For this reason, a
coupling relay is installed or must be installed between the output of the
heat pump manager and the electronically regulated circulating pump. This is
not necessary if the permissible operating current of 2 A and a maximum
starting current of 12 A are not exceeded in the electronically regulated
circulating pump or if express approval has been issued by the pump
manufacturer.
CAUTION!
It is not permitted to connect more than one electronically regulated
circulating pump via a relay output.
Commissioning
General Information
To ensure that commissioning is performed correctly, it should only be carried
out by an after-sales service technician authorised by the manufacturer. This
may be a condition for an additional guarantee (see “Warranty service”).
Preparation
The following items must be checked prior to commissioning:
- All of the heat pump connections must be installed as described in chapter 7.
- The heat source system and the heating circuit must have been filled and checked.
- The dirt trap must be inserted in the brine inlet of the heat pump.
- All valves that could impair proper flow in the brine and heating circuits must be open.
- The heat pump manager must be adapted to the heating system in accordance with the controller’s operating instructions.
Commissioning procedure
The heat pump is commissioned via the heat pump manager.
CAUTION!
Start-up must be performed in accordance with the installation and operating
instructions of the heat pump manager.
Cleaning / maintenance
Maintenance
To prevent faults due to sediment in the heat exchangers, care must be taken
to ensure that no impurities can enter either the heat source system or the
heating system. In the event that operating malfunctions due to contamination
occur nevertheless, the system should be cleaned as described below.
Cleaning the heating system
The ingress of oxygen into the heating water circuit may result in the
formation of oxidation products (rust), particularly if steel components are
used. These enter the heating system via the valves, the circulating pumps
and/or plastic pipes. A diffusionresistant installation is therefore
essential, especially with regard to the piping of underfloor heating systems.
NOTE
We recommend the installation of a suitable corrosion protection system to
prevent the formation of deposits (e.g. rust) in the condenser of the heat
pump. Residue from lubricants and sealants may also contaminate the heating
water.
In the event of severe contamination leading to a reduction in the performance of the liquefier in the heat pump, the system must be cleaned by a heating technician. Based on current information, we recommend using a 5 % phosphoric acid solution for cleaning purposes. However, if cleaning needs to be performed more frequently, a 5 % formic acid solution should be used. In both cases, the cleaning fluid should be at room temperature. We recommend flushing the heat exchanger inthe direction opposite to the normal flow direction. To prevent acidic cleaning agents from entering the heating system circuit, we recommend connecting the flushing device directly to the flow and return of the liquefier of the heat pump. It is then important that the system be thoroughly flushed using appropriate neutralising agents to prevent any damage from being caused by cleaning agent residue remaining in the system.
Acids must be used with care and the regulations of the employers liability insurance associations must be adhered to. The instructions of the cleaning agent manufacturer must always be observed.
Cleaning the heat source system
CAUTION!
The supplied dirt trap must be inserted in the heat source inlet of the heat
pump to protect the evaporator against the ingress of impurities.
The filter sieve of the dirt trap should be cleaned one day after start-up. Further checks must be set according to the level of dirt. If no more signs of contamination are evident, the filter can be removed to reduce pressure drops.
Faults / troubleshooting
This heat pump is a quality product and is designed for troublefree operation.
In the event that a fault should occur, it will be indicated on the heat pump
manager display. In this case, consult the “Faults and troubleshooting” page
in the operating instructions of the heat pump manager.
If you cannot correct the fault yourself, please contact your after-sales
service technician.
CAUTION!
Before opening the device, ensure that all circuits are disconnected from the
power supply! After disconnecting the power supply, always wait for at least 5
minutes to allow stored electric charges to dissipate.
CAUTION!
Work on the heat pump must only be performed by authorised and qualified
after-sales service technicians!
Decommissioning / disposal
Before removing the heat pump, disconnect it from the power source and close all valves. The heat pump must be dismantled by trained personnel. All environmentally-relevant requirements regarding the recovery, recycling and disposal of materials and components should be observed in accordance with the applicable standards. Particular attention should be paid to the proper disposal of refrigerants and refrigerant oils
Device information
1 | Type and order code | SI 130TU |
---|---|---|
2 | Design | |
Heat source | Brine | |
2.1 **Model** | Universal | |
2.2 **Controller** | integrated | |
2.3 **Thermal energy meter** | Integrated | |
2.4 **Installation location** | Indoors | |
2.5 **Performance levels** | 2 | |
3 | Operating limits | |
3.1 **Heating water flow 1 2** | °C | 20 to 62 ± 2 |
3.2 **Brine (heat source) 1 2** | °C | -5 to +25 |
3.3 **Antifreeze** | Monoethylene glycol | |
3.4 **Minimum brine concentration (-13 °C freezing temperature)** |
25 %
4| Flow / sound| |
4.1 **Heating water flow / free compression (max).|
Nominal flow in accordance at B0…-3 / W35…28| m³/h /
Pa| 17.2 / 58000
at B0…-3 / W45…38| m³/h / Pa| 16.5 / 60000
at B0…-3 / W55…45| m³/h / Pa| 11.4 / 77000
Minimum heating water flow| m³/h / Pa| 11.4 / 77000
4.2 ****Brine flow rate / free compression (max).|
Nominal flow in accordance at B0…-3 / W35…28| m³/h /
Pa| 33.1 / 63000
at B0…-3 / W45…38| m³/h / Pa| 30.2 / 79000
at B0…-3 / W55…45| m³/h / Pa| 27.3 / 91000
Minimum brine flow rate| m³/h / Pa| 27.3 / 91000
4.3 ****Sound power level according to EN 12102| dB(A)| 70
4.4 ****Sound pressure level at a distance of 1m 3| dB(A)| 55
5| Dimensions, weight and filling quantity| |
5.1 ****Device dimensions 4| H x W x L mm| 1890 x 1350 x 750
5.2 ****Weight of the transportable unit(s) incl. packaging| kg|
824
5.3 ****Device connections for heating| inches| Rp 2½“
5.4 ****Device connections for heat source| Inches| Rp 3“
5.5 ****Refrigerant / total filling weight|
type/kg| R410A / 19.5
5.6 ****GWP value / CO 2 equivalent| — / t| 2088 / 41
5.7 ****Refrigeration circuit hermetically sealed| yes
5.8 ****Lubricant / total filling quantity| type/litres|
Polyolester (POE) / 14.6
5.9 ****Volume of heating water in device| Litres| 26
5.10 Volume of heat transfer medium in device| Litres| 26
6| Electrical connection| |
6.1 ****Supply voltage / fuse protection / RCD-Type| 3~/PE 400 V (50
Hz) / C 100A / A
6.2 ****Control voltage / fuse protection / RCD-Type| 1~/N/PE 230 V
(50 Hz) / C 13A / A
6.3 ****Degree of protection according to EN 60 529| IP 21
6.4 ****Starting current with soft starter| A| 110
6.5 ****Nominal power consumption B0 W35 / max. power consumption
5kW| 30.0 / 57.5
6.6 ****Nominal current B0 W35 / cos j| A / —| 54.1 / 0.8
6.7 ****Power consumption of compressor protection (per compressor)|
****W| 150 / thermostatically controlled
6.8 ****Power consumption of pumps| kW| up to 1.8
7 Complies with the European safety regulations| 6
8 Additional model features|
8.1 ****Water in device is protected against
freezing 7| Yes
8.2 ****Max. operating overpressure (heat source/heat sink) bar|
3.0
9 Heat output / COP|
9.1 ****Heat output / coefficient of performance (COP) 5 8|
Performance level| 1| 2
at B-5 / W45 kW / —| 58.3 / 3.2| 117.0 / 3.3
at B0 / W55 kW / —| 65.0 / 3.0| 129.6 / 3.1
at B0 / W45 kW / —| 67.2 / 3.7| 132.1 / 3.7
at B0 / W35 kW / —**| 70.7 / 4.7| 138.1 / 4.6
- If necessary, the operating range can be extended to a brine inlet temperature of -10 °C. In this case, the minimum brine concentration must be adjusted to 30%. (Freezing temperature -17 °C) For brine inlet temperatures of -10 °C to -5 °C, flow temperature increasing from 50 °C to 60 °C. For brine inlet temperatures of -5 °C to 0°C, flow temperature increasing from 60 °C to 62 °C.
- Operation is possible at brine inlet temperatures of up to +35 °C. For brine inlet temperatures of 25 °C to 35 °C, flow temperature decreasing from 62 °C to 58 °C.
- The specified sound pressure level corresponds to the operating noise of the heat pump in heating operation at 55 °C flow temperature. The specified sound pressure level represents the free sound area level. The measured value can deviate by up to 16 dB(A), depending on the installation location.
- Note that additional space is required for pipe connections, operation and maintenance.
- These data indicate the size and capacity of the system. For an analysis of the economic and energy efficiency of the system, the bivalence point and regulation should be taken into consideration. These specifications can only be achieved with clean heat exchangers. Information on maintenance, commissioning and operation can be found in the respective sections of the installation and operating instructions. The specified values, e.g. B0 / W55, have the following meaning: Heat source temperature 0 °C and heating water flow temperature 55 °C.
- See CE declaration of conformity
- The heat circulating pump and the heat pump manager must always be ready for operation.
- The coefficients of performance are valid with the circulating pumps included in the scope of supply.
Product information as per Regulation (EU) No 813/ 2013, Annex II, Table
2
Information requirements for heat pump space heaters and heat pump combination heaters
Model SI
130TU
Air-to-water heat pump no
Water-to-water heat pump no
Brine-to-water heat pump yes
Low-temperature heat pump no
Equipped with a supplementary heater no
Heat pump combination heater no
Parameters shall be declared for medium-temperature application, except for
low-temperature heat pumps. For low- temperature heat pumps, parametersshall
be declared for low-temperature application.
Parameters shall be declared for average climate conditions:
Item Symbol Value Unit
Item Symbol Value Unit
Rated heat output (*) Prated 130 kW| Seasonal
space heating energy ηs 138 % efficiency
Declared capacity for heating foer part load at indoor temperature 20°C and
outdoor temperature T j Tj = – 7°C
P dh kWTj = + 2°C P dh kWTj = +
7°C P dh kWTj = + 12°C
P dh kWTj = bivalent temperature P dh kWTj =
operation limit temperature P dh kW For air-to-water heat
pumps| Declared coefficient of performance or primary energy ratio for part
load at indoor temperature 20 °C and outdoor temperature T j Tj = – 7°C
COP d -Tj = + 2°C COP d -Tj = +
7°C COP d -Tj = + 12°C
COP d -Tj = bivalent temperature COP d -Tj =
operation limit temperature COP d – For air-to-water heat pumps:
Tj = -15°C (if TOL < -20°C) P dh Bivalent temperature
TbivCycling interval capacity for heating
P cych Degradation co-efficient () C dh| 129,6| kW°C
kW –| Tj = -15°C (if TOL < -20°C) COP d For air-
to-water heat pumps: TOL Operation limit temperature
Cycling interval efficiency COP cyc Heating water
operating limit WTOL temperature| 3,10| -°C – * °C
-10| -10
–| –
0,90| 62
Power consumption in modes other than active mode| Supplementary heater
Off mode POFFThermostat-off mode
PTOStandby mode PSBCrankcase heater mode
PCK| 0,015| kW kW kWkW| Rated heat output () P
sup| 0| kW
0,020| Type of energy input| eletrical
0,015
0,300
Other items|
Capacity control| fixed| For air-to-water heat pumps: Rated – air
flow rate, outdoorsFor water-/brine-to-water heat – pumps:
Rated brine or water flowrate, outdoor heat exchanger| — 11,4| m³ /h **
m³ /h
Sound power level, indoors/ outdoors LWA Emissions of nitrogen
oxides NOx| 70/–| dBmg/kWh
–
For heat pump combination heater:
Declared load profile| —| Water heating energy efficiency ηwh **
Daily fuel consumption Qfuel| —| % * kWh
Daily electricity consumption Qelec| — kWh|
—
Contact details| Glen Dimplex Deutschland GmbH, Am Goldenen Feld 18, 95326
Kulmbach
() For heat pump space heaters and heat pump combination heaters, the rated
output P rated is equal to the design load for heating P designh , and the
rated heat output of a supplementary capacity for heating sup( Tj ).() If
C dh is not determined by measurement nthen the default degradation is C
dh = 0,9 (–) not applicable
Read User Manual Online (PDF format)
Read User Manual Online (PDF format) >>