Best practice examples of District Cooling systems
This report was elaborated in the framework of the RESCUE project
co-funded by the Intelligent Energy Europe Programme of the
European Union Report prepared by:
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DISCLAIMER
The sole responsibility for the content of this report lies with the authors. It does not necessarily reflect the opinion of the European Union. Neither the EASME nor the European Commission are responsible for any use that may be made of the information contained therein.
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Content
1 Preface .........................................................4
2 Project description ......................................4
3 Nomenclature ..............................................6
4 Summary......................................................7
5 Background ..................................................8
6 Selection of different systems .....................9
7 District Cooling system and technical practices 10
7.1 Key drivers - why District Cooling has been developed 10
7.2 Technical aspects ...................................... 11
7.3 Why was the specific technical solution chosen 11
7.3.1 Paris .......................................................... 12
7.3.2 Vienna ....................................................... 13
7.3.3 Stockholm ................................................. 14
7.3.4 Solna / Sundbyberg ................................... 16
7.3.5 Helsinki ..................................................... 17
7.3.6 Växjö ......................................................... 18
8 Lesson learnt - Good practices ................. 19
8.1 Market driven development .................... 19
8.2 Robustness and flexibility in production .. 20
8.3 Stakeholders and Financial issues ............ 22
8.4 Distribution practices, early actions ......... 22
9 Lesson learnt - Barriers and common failures 23
9.1 Too low market focus ............................... 23
9.2 Access and interest from top management23
9.3 Overestimation of customers cooling demand 24
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9.4 Choose the optimal production solution for the DC system 24
9.5 Too little attention on ΔT risks ................. 25
9.6 Lack of respect for the time plan.............. 26
9.7 To little focus on permit issues................. 26
9.8 Pipes surveillance system not adapted for cooling distribution 26
10 Final discussion ......................................... 26
11 Key Performance Indicators ..................... 27
11.1 Market indicators ..................................... 27
11.2 Technology/ sourcing indicators .............. 27
11.3 Environmental indicators ......................... 28
12 Bibliography .............................................. 29
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1 PREFACE
This report has been elaborated within the RESCUE (Renewable Smart Cooling in Urban Europe) project. This IEE (Intelligent Energy Europe) co-funded project is scheduled from June 2012 to May 2015.
The sole responsibility for the content of this report lies with the authors. It does not necessarily reflect the opinion of the European Community. The European Commission is not responsible for any use that may be made of the information contained therein.
Project Coordinator: Prof. Clemens Felsmann, Technische Universität Dresden, Professorship of Building Energy Systems and Heat supply
Principal Authors of this report: Henrik Frohm, Anders Tvärne from Capital Cooling Energy Service AB, Sweden. Kosti Koski from Helsinki Energy, Finland.
With Contribution by the RESCUE partners:
– TU Dresden ([email protected])
– Capital Cooling Energy Service AB (www.capitalcooling.se)
– Climespace (www.climespace.fr)
– Helsinki Energy (www.helen.fi)
– AGFW (www.agfw.de)
– Euroheat & Power (www.euroheat.org)
– ICLEI Europe (www.iclei‐europe.org)
– Regional Energy Agency of Liguria (www.areliguria.it)
If you would like to know more about RESCUE project please visit our website [email protected].
2 PROJECT DESC RIP TIO N
Cooling energy demand within Europe, especially in urban regions, is rising significantly, mainly caused by building design, internal heat loads, heat island effects, and comfort reasons. If served conventionally using small scale and distributed electric driven compressor chillers this would result in a significant rise of primary energy consumption, greenhouse gas emissions and peak electricity demand.
The RESCUE project focuses on the key challenges for further development and implementation of District Cooling (DC) using low and zero carbon emitting sources, thereby enabling local communities to reap the environmental and economic benefits of this mature technology. Although DC allows the application of high efficient industrial chillers or absorption chillers driven by waste heat it is estimated that DC market share today is about 1-2 % in the service sector (which is about 3 TWh) but less than 1 % of the
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total present existing European cooling market including residential sector. The main steps to extend the use of smart, energy efficient and renewable DC Systems are:
1. Dissemination of essential background information.
2. Decision making based on (pre-) feasibility studies exploring cooling options.
3. Implementation, Monitoring and Optimization.
The RESCUE project focuses on steps 1 and 2 within the project duration addressing main actors and target groups, i.e. Local Authorities (LA), utility companies, building owners, and the financing sector. The main project objectives are as follows:
– Promote district cooling as a sustainable energy solution with a potential.
– Increase familiarity and reliability of information available to decision makers and local authorities about the DC business.
– Improve networking activities and experience exchange.
A key action of the project is to provide a number of target cities with a decision-making support package assisting local authorities to account for DC in their planning policies and to guide them when looking for cooling options fitting best to their Sustainable Energy Action Plan (SEAP).
Key outputs and main deliverables of the project, available to the public, are:
– An impact calculator which shows the key figures in comparison between Central and Distributed solutions.
– A set of guidelines and handbooks related to the DC business and the decision making process.
– Reports describing the cooling energy market, the energy performance evaluation as well as DC best practice and show cases.
The RESCUE project consists of seven Work Packages (WP), whereas WPs 1, 6 and 7 are dedicated for project management and communication, WP2 is dedicated to conducting a market survey for cooling in Europe and to establish how DC can contribute to the 20-20-20 targets. WP3 is to showcase examples of DC systems in Europe in order to demonstrate their performance and to provide details on the use of renewable energy sources (RES), improvements in energy efficiency and CO2-savings. Within WP4 a “Decision Making Support Package” is developed, applied and enhanced to guide and assist LA in their decision processes regarding cooling issues in local energy concepts. The purpose of WP 5 is to provide practical information related to start-up of DC systems and the DC business in general.
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3 NOMENCL ATU RE
Abbreviation Description
AC Air Conditioning
CHP Combined Heat and Power
CoM Covenant of Mayors
DC District Cooling
DCS District Cooling System
DH District Heating
EC European Commission
ECI European Cooling Index
LA Local Authorities
LCC Life Cycle Cost
LG Local Government
PEF Primary Energy Factor
RES Renewable Energy Sources
SEAP Sustainable Energy Action Plan
WP Work Package
NZEB Nearly Zero Energy Buildings
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4 SUMM ARY
This report is based on collected information and experience from two Southern and four Northern Europe District Cooling (DC) systems which represent typical cases that can be seen across Europe. Many DC systems have now been in operation for around 20 years. From these systems a lot of useful information related to the early period of cooling business is very valuable for the cities that are considering their own District Cooling system.
One common feature of the six DC systems is that they all utilise natural cooling resources to some extent (sea, lake or river), thereby greatly improving their performance. Still, natural cooling sources are not a must-have in order to develop DC systems. However, it should also be noted that major cities in Europe are usually located near lakes, seas and rivers, and therefore a huge potential was identified for developing sustainable DC solutions.
There are many reasons why municipalities and energy companies in the selected six DC systems have started up District Cooling schemes, the most common reasons given by the interviewed DC providers are:
• Top management that believes in the District Cooling business
• Competition – be able to sell both heating and cooling
• A new sustainable and environmental product on the market
• Sight of a potential profitable business
• Sell more district heating and to be able to produce electricity longer in the summer period
• The aesthetic concept of a city as re-cooling devices disfigures facades and roofs. Among other aspects: health, reducing noise and removing cooling towers from the city centre.
It is very important to understand and identify smart local solutions based on the local conditions. For all six examples of DC systems described in this report, the choice of the DC production technology was based on the locally available sources. The production mix was optimised for local conditions and is based on calculated development plans. The key in all systems depicted in this report is covering cooling demand at a local market. It is essential to understand the whole market potential so the right technical solution that is feasible can be evaluated in order to be able to present a competitive District Cooling solution. Successful DC systems are not only dependent on the smart choice of technical solutions, but possibly even more on a strong sales and market focus during the development phase.
A more detailed description of the DC system in Paris, Vienna, Stockholm, Solna/Sundbyberg, Helsinki and Växjö can be found in respective sections of this report.
A common success factor for the examples is that key stakeholders had clear roles in the DC development schemes. The local energy companies have been able to develop the DC scheme with their own cash flow and then use loans from local, regional, national or European institutions, like EIB or Green loans. Many of the companies have also introduced front fees (access fees) to lower their negative cash flows.
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In general, lessons learnt from the successful DC system development schemes can be listed as follows:
• A High Market Focus Access is essential to develop a successful DC Business.
• Secure the connection of key customers first.
• Access and interest from top management: it is crucial to have the upper hand of the progress of the project development. Implementing adequate steering and control models at an early stage is absolutely necessary. Efficient decision processes and interest from the top management is needed.
• Overestimation of customer cooling demand is a common mistake that should be avoided by evaluating demand carefully.
• An optimal production solution for the DC system should be chosen, taking into account the locally available sources and local conditions.
• Always pay attention to the temperature differential ( ΔT) risks
• It is important to keep the time plan on track.
• Always give high importance to permitting issues is also a common and costly mistake that delays the system development
• The pipe surveillance system has to be adapted for cooling distribution, with special requirements compared to heating distribution.
5 BACKG ROU N D
There are several cities operating DC systems around Europe. Many systems have now been in operation for around 20 years. A lot of useful information related to the early period of cooling business can be given by these systems. They can be of high value for the cities that consider developing their own District Cooling system and are interested in key issues to address when starting to develop a DC system.
This report is based on collected information and experience of a few selected systems both from Central and Northern Europe and will represent typical cases that can be seen across Europe, taking into account the characteristics of different locations at which the various sources (river, sea, lake, etc.) are available to produce cooling. The scale of municipalities will be from large cities to mid-sized towns. The focus is put on technology – outlining good practices and what makes these systems “good”.
The focus in this report is put on the period when district cooling is being established, it is not focused on the experiences in operation. However, some advice is included on issues that need attention on future operation.
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6 SELECT IO N O F DI FFE RE NT SYSTEM S
Five types of systems around Europe are covered in this report:
• Large and small • Northern, Central and Southern systems • Different technical solutions
In order to fulfil this aim six different DC systems have been described as the main source of information, see Table 1. Some general experience from other projects and cities has also been included into the report.
City 4) Country Inner city inhabitants
(approx.)
North / South
Starting year of DC supply
Technical solution for DC supply
Paris 1) France 2 200 000 Central (South) 1978 Electrical chillers, river, Geothermal and grey water Heat Pumps,
Vienna Austria 1 700 000 Central (South) 2009 Absorption, electrical chillers, river
Stockholm 2)
Sweden 900 000 North 1995 Sea water, heat pumps, electrical chillers
Solna / Sundbyberg
Sweden 110 000 North 1995 Sea water, heat pumps, electrical chillers
Helsinki Finland 700 000 North 1998 Sea water, absorption, heat pumps, electrical chillers
Växjö 3) Sweden 60 000 North 2011 Absorption, electrical chillers and lake
Table 1: List of different types of DC systems described in this report.
Note 1: The system in Paris is operated by Climespace. (Outside of Paris, one more district cooling system can be found in the La Defence area.)
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Note 2: The Stockholm system is here only showing info regarding the main, large central system (Fortum also operates a number of mid and small DC systems, which are not included here.)
Note 3: The Växjö system use un-insulated pipes (on the return) located in lakes for connecting different areas. Natural cooling is then achieved by the un-insulated pipes function as a heat exchanger.
Note 4: An alternative to the systems of Helsinki, Växjö and Solna/Sundbyberg would be the cities of Gothenburg, Helsingborg, Halmstad, Linköping, Borås, Umeå, Lund and Jönköping, all from Sweden. Experiences, results and conclusions would be similar from these cities as from the ones Rescue chose to include.
The ambition was initially to include a system from the South of Europe. However there are very few systems there that have experience to share as good practices. Most of the Southern Europe DC systems are small and not growing or showing low development indications. The financial situation in south of Europe is presently not a foundation for project development. The DC systems in both Barcelona and Lisbon have limited resources and, for various reasons, not a possibility to participate as sources of information and experience in this project. Cities in Germany and Italy are also excluded since there are no cities with DC schemes that are interested in sharing information. The DC schemes are also very few in these countries. However, a positive point is that cities in these countries are very good potentials for target cities of developing DC, with support from Rescue.
The focus will therefore be on DC systems in in North and Central Europe countries. The Rescue project is convinced that experience from systems there will best serve the scope in this report.
An interesting fact to observe is that six systems that have been chosen have some kind of natural cooling included, sea, lake or river. This is very natural if there are locally available sources of cold water, at least some part of the year. DC systems are excellent in utilising local sustainable sources and solutions. However it is not a deal breaker that natural cooling must be available if DC should be developed.
The fact that all DC systems that have been analysed do have natural cooling is not so surprising; the history of a city and why people have gathered there in the past shows that it was because of the geographical aspect, and more specifically, the presence of water. Today, many of the cities in Europe are located near the coast, near lakes or near rivers. So from a DC perspective it is actually a huge potential for developing sustainable DC solutions.
7 DI ST RI CT COOL ING SYSTE M A ND TEC HN ICA L P R ACT I CES
7.1 KEY DRIVERS - WHY DISTRICT COOLING HAS BEEN DEVELOPED
There are many reasons why municipalities and energy companies have started up District Cooling schemes but here is a summary of the most common reasons from the interview DC providers ( (Tvärne, Anders; Capital Cooling) 2014):
• Top management that believes in the District Cooling business
• Competition – be able to sell both heating and cooling (e.g. in comparison with heat pumps).
• New interesting product(s) on the market
• Outlook of a potential profitable business
• Sell more DH and to be able to produce electricity longer in the summer period
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• A new sustainable product that strengthens the company’s environmental profile
• Demand from building owners (these serve as DC customers then) possibly caused by restrictions from the municipality (concerning facades and re-cooling devices)
Almost all energy companies that have DC systems tell this story and this means that there is a lot business and market driven approach. Additionally, district cooling assists to improve the environmental profile of the company. In Sweden and in Finland, a strong driving force has been the competition on District Heating from heat pumps and the ability to produce more electricity during summer period using excess heat.
7.2 TECHNICAL ASPECTS
Actually there are no major differences if a DC system is located in the North or South of Europe, if it is a small or a large system or the choice of technical solution. The main objective is to understand and to satisfy a customer market demand DC operates on a local market. The common driver is that the system design and technical solution is based on local conditions. Then it is important to understand and identify smart solutions available on the market. If the system shall be successful, the management skills of developing the business are essential. The business analysis should include optimisation of the prevailing technical options.
A key issue is to find and utilise production facilities near the market. Long transition pipes should be avoided.
The first step is to identify all possible sources of natural cooling. The next step is to identify possibility of waste energy. It can be from industrial processes, waste incineration or heat from CHP plants and then used as heat for absorption chillers. Apart from that, high efficiency electrical chillers are also used. If there is a demand of a DH system, heat pumps can also be a solution.
It is very rare that DC systems utilising natural cooling will have unlimited sources of cooling. None of the ones described here have. The source of natural cooling does not provide enough energy or the temperature is not low enough over time. Every system must have a mix of different cooling production solutions to be able to deliver the quality the customers demand.
The sources of natural cooling are basically huge storages of cold energy. For peak reasons or capacity in transition pipes, the systems often use storages (day and night). Then operations can be reduced with electrical chillers during peak in day time. Cold-water storage is also valuable for restarting a system after an electrical power failure etc.
7.3 WHY WAS THE SPECIFIC TECHNICAL SOLUTION CHOSEN
For all of the examples of DC systems described in the following section, the choice of the DC production has been based on locally available sources. The production needs to be optimised in respect to local conditions and calculated development plans. Normally it takes many years to develop DC systems. The development period depends on both customer’s interest to actually connect and the utility companies scheduling. A planned phasing in respect to what is financial possible sets the framework for the development plan.
District cooling is characterised by high investments and low operational costs. It is financially tough to build simultaneously both the network and production plants. A smart use of simple temporary solutions
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can bridge the gap between the customer demand and the time when the customer can be connected to the main network.
When DC has been accepted on the local market, even more customers can be interested in DC. It can also not be excluded that the cooling market actually could have been under-estimated. A second expansion phase will be possible. The production capacity will in that case probably not be sufficent. It cannot be excluded that totally new market conditions may prevail. This could lead into a different technical optimal solution compared to the first phase. It is therefore very important that each project is analysed as a new project. Therefore, experiences from other projects must be evaluated very carefully before being implemented. Risk assessments and security of supply studies have also been included.
7.3.1 PARIS
The Paris District Cooling dates back to 1968, at the time when the Paris City council decided to renovate an area in which the shopping centre of Forum Les Halles was to be built. A centralised heating and cooling system has been adopted as technical solution to recover the energy, to avoid electricity peaks and to ensure security of power supply to the consumers in the area.
In order for the district energy system to be economically feasible, it needed to supply other buildings and hence, the Louvre museum has been connected to the system.
Due to its central city location, far from any natural resource, the technology solution chosen was the installation of electrical centrifugal chillers with cooling towers installed on the top of the building and the ice energy storage.
Believing in the technology and in an increase of the cooling demand, in the 1991, Climespace became a shareholder with the idea to expand the existing District Cooling system.
As the system expanded, with the increasing number of new clients’ connections, the installation of other energy plants such as Opera and the increase of the distribution network, etc. it became economically feasible.
In fact, river water provides better thermal performance for heat rejection when compared to a cooling tower, due to its temperature stability and better specific heat capacity, and offers the opportunity to exploit free cooling which led to the construction of 3 others energy plants.
Paris is a very dense city and the location to accommodate the plants also posed some constraints, which led to alternative solutions. This case is better represented by the construction of Canada energy plant, which has been created completely underground or Tokyo energy plant which was built under Tokyo palace and required structural adaptation in order to build the plant underground the building.
With the increase of technology and the discovery of large geothermal energy source in Paris, Climespace has recently constructed an energy plant that uses geothermal energy.
Through the means of heat pumps and the synergy with CPCU, that operates the District Heating system of Paris, the energy plant is capable to provide simultaneously heating and cooling energy for DH and DC.
Legislation in France also influenced the technical solution adopted for cooling production such as the restriction of the use of ammonia as a cooling refrigerant.
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Another important factor was that in the city centre of Paris there are not any incinerator plants what excluded the use of surplus heat.
Paris has a very developed underground tunnel which in some areas created some advantages by facilitating the poses of pipework whereas in some others it poses some constraint due to the limited space available.
Climespace is currently installing an energy plant in the Paris City Council building that uses the Paris grey water system as a source of heat rejection and recuperation which by means of reversible heat pumps will be capable of producing cooling and heating.
As shown in Figure 1 , Climespace now operates 3 separate District Cooling Systems. Each system consists of at least 2 energy plants to provide and deliver the chilled water. This corresponds to a decentralised approach of the energy production, implying the dynamic operation of the plants of the same network.
Figure 1: Paris District cooling system (Source (Climespace, 2013))
7.3.2 VIENNA
There are a few main quarter stones that set the framework for the cooling market in Austria and especially in Vienna. There is electricity peak production demand in the summer period. For these peaks, fossil fuel is used. However, the global EU framework leads to a need of reducing the use of fossil fuels.
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The floor area for office is increasing in Vienna. According to the Executive Office for Strategic Energy Affairs, the floor area will grow by 18 % between 2005 and 2030. Most of this additional space will be built, by default, already fully or partially air-conditioned. The trend is also clear that the cooling demand is increasing in current office buildings.
Connected to the existing DH system, there were a few customers that for many years have used local absorption chillers (driven by heat from DH network). The business had been sleeping for years with no indication of any interest from the stakeholders.
Feasibility studies identified areas of cooling demand with an interesting potential for developing full scale DC system. A system design study showed options for mixed production with natural cooling, absorption chillers and electrical chillers. The decision to develop district cooling was taken in 2006.
Fernwärme Wien has long experience with waste incineration at the Spittelau plant. The base load for DH in Vienna is based on this plant. In the summer period there was a surplus of waste leading to cooling demand to get rid of excess heat when the head demand was too low. This could now be used for heat driven absorption chillers. In the spring period the flow in the river Danube is high and the water temperature is then cold enough for DC supply. Accordingly, natural cooling can be used during parts of the year. During periods when the air is cool enough, additional free cooling can also be produced. Remaining DC is produced with electrical chillers.
Expansions to other areas will use similar concepts as in Spittelau DCP. New production capacity is developed in Rudolfstiftung Hospital, Reingasse, TownTown office complex, Krankenhaus Nord and Central railway station. All these units use a mix of natural cooling, absorption chillers and electrical chillers. The approach is to develop local DC islands. Some are integrated with nearby DC islands. With a number of production sites near local demands the need for large DC transition pipes is reduced.
7.3.3 STOCKHOLM
Stockholm is located at the Baltic Sea. Utilising deep sea water is of course the base source of DC. The depth of the sea in the harbour and sea water temperature variations during the year result in a supplementary need to cool the sea water for the DC supply. Existing large heat pumps could be used for securing the supply temperature as well as as peak production. The heat pumps use sea water. Initially, the city centre DC projects were aiming on a market corresponding to a capacity of 60 MW. For the city system it was aimed at a capacity possible to transfer in pipes that could be located inside an existing tunnel.
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Figure 2: District Cooling system in Stockholm (Fortum Värme AB)
The successful growth of the system led to a higher demand from the customers. A second north complementary transmission network and extra production capacity has therefore also been built. Local aquifer storage has been utilised in the city centre. The blue marked areas in Figure 2 show the areas now served by DC in Stockholm city area.
For the second area of Södermalm, there was a separate DC system built up a few years after the initial city centre system. In the Södermalm DC system, existing heat pumps in Hammarbyverket were used. The Södermalm and the city centre system are now connected by pipes located in the lake Mälaren.
The west area of Kungsholmen has been connected to the city centre’s system with DC pipes under a bridge. In Kungsholmen rock tunnel, cold water storage has been built. There are plans to include the second sea water intake into the system in order to boost the capacity.
A separate mid size DC system using heat pumps is also operated in Kista, the Swedish IT centre. Apart from this a few small satellites in gallerias/malls are also operated by Fortum.
The use of production by heat pumps and not by absorption chillers is from a historical perspective a natural development path. The heat pumps were already installations in operaion. Utilising energy from both the hot and cold side is then very cost efficient. At the time of the design in 1994 the electricity price levels in Sweden were then lower than today’s market prices. Neither the emissions trade system, nor the
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Swedish green electricity certificates exist. The energy taxation was not in favour of operating CHP plants. Compared to 1994 the electricity production from CHP in Sweden has increased by 250-300 %.
Stockholm has had waste incineration plant with energy recovery to District Heating since 1970. The capacity has of course increased since then. The waste incineration plant is not close to the DC production locations. The DH network do have bottlenecks plus also that the base load demand is higher than what the waste incineration can produce. If absorption chillers would be used in the city centre system it would therefore be supplied with other, more expensive sources than waste incineration.
7.3.4 SOLNA / SUNDBYBERG
Norrenergi operates the DC system in Solna and Sundbyberg, which are two communities located in the North of Stockholm. The DC system was planned at the same time as the Stockholm system in 1994.
Norrenergi also had large existing heat pumps (treating sewage water) in their DC production. Heat pumps were the initial technology to utilise for the DC production. When the DC system had reached a market penetration as well as a capacity large enough, a sea water supply system was feasible.
Now, electrical chillers are also included in the production for peak and reserve. A cold water storage (CWS) is also included in the production facilities and located at the production site, Solnaverket. When the cooling demand is low, during nights, the CWS is charged with the sea water for natural cooling. When the DC pipe system is inter-connected, operation with electrical chillers for day time peaks can be reduced.
Further expansion of the DC system will also be utilised by adding chillers at the DH plant in Sundbybergsverket. The sea water pipe system is already utilised at the maximum capacity.
The DH system is also operated by Norrenergi. There is not any industrial waste energy included in the DH production. There is no CHP plant included in the production of DH. Absorption chillers are therefore not an interesting alternative for DC production.
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Figure 3: Layout of DC distribution system in Solna/Sundbyberg and location of DCPs. (Norrenergi AB)
The approach on developing DC in Solna/Sundbyberg was to start with utilising energy also from the cold side of existing heat pumps. The waste heat used in the heat pumps is treated sewage-water. One of the Stockholm area main sewage tunnels is close to the Sundbyberg production plant. The sewage water does have a rather constant flow during the year.
Area 1 in Figure 3 was in the first stage developed with the mix of heat pumps and electrical chillers. With the success of providing district cooling, the waste energy (in the heat pumps) was utilised to maximum capacity. For any new customer, the dependency on electrical chillers was too high.
Area 2 in Figure 3 is covering one of the most expensive areas for developing office surfaces. These modern commercial buildings do all need AC, so DC is an attractive product in the area. For this area sea water cooling was possible to develop.
When integrating area 2 with area 1, more of natural cooling (sea water) could also be boosted into area 1. Since the cooling from existing heat pumps in area 1 already was used to the maximum. With the interconnection of the two areas the production with sea water cooling could be raised with the use of the CWS.
7.3.5 HELSINKI
Helsinki Figure 4 is the capital of Finland with around 700 000 inhabitants and located by the Baltic Sea. The experience of district energy supply in Helsinki has a long history, starting in 1953. DH was a success from the beginning. District cooling supply started in 1998. The implementation of DC was easy as real estate owners were already experienced with DH. The DC production is a mix of sea water cooling (natural cooling for 6 months of the year), absorption chillers and heat pumps.
More than 80 % of production is based on energy that otherwise would be wasted.
Figure 4. City centre of Helsinki. (Koski, Kosti; Helsinki Energia OY)
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The Katri Vala heating and cooling plant is the largest in the world to use heat pumps to produce District Heat and District Cooling from purified sewage water and sea water. Its output is 60 MW of District Cooling and 90 MW of District Heating. The DH capacity would fit to supply heat to a small town. The plant is located in a rocky space and in the tunnels underneath the Katri Vala park in the district of Sörnäinen.
The second DC plant use is located at the Salmisaari cooling centre and has a capacity of 10x3.5 MW absorption chillers and two compressor chillers. The heat source for the absorption technology is +85°C District heating water.
The production mix is chosen to utilise the local energy sources efficiently. Figure 5 show the mix of DC production from both Katri Vala and Salmisaari DC plants. The photo shows one of the heat pumps 18 MW heat and 12 MW cooling.
Figure 5. Production in Helsinki (Koski, Kosti; Helsinki Energia OY)
7.3.6 VÄXJÖ
Växjö is a small city with a population of only 60,000 in the city centre. The location of Växjö is inland in an area of good availability of biomass waste from the local forestry. A biomass CHP plant was taken in operation in 1997. Today, over 90 % of all district heat is produced by biomass.
A number of key-customers that were already connected District Heating indicated an interest in supply of District Cooling. Växjö is a spread out city and a few lakes are nearby. All the lakes are shallow, so only surface water is available for cooling purposes. The lakes are beneficial for distribution purposes because of the lower investments cost for lake location instead of ordinary ground constructions.
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Figure 6. DC distribution system in Växjö. (Växjö Energi AB, 2012)
Figure 6 shows the DC distribution system in Växjö. The DC distribution system use uninsulated pipes (on the return) located in lakes for connecting different areas. The uninsulated pipes function as a heat exchanger. The water from the lake is then taken up by the DC pipes. (So it is not an open – “once through” – open lake water system, with separate lake water pipes.).
The City of Växjö aims to become a fossil fuel-free municipality. Sustainable production of electricity with biomass is encouraged. District Heating is now produced in a biomass CHP plant build in 1997. A new biomass CHP plant was taken into operation at the end of 2014. In Sweden and Norway there is a market that aims at introducing sustainable production of electricity, “electricity certificates” (Elcert). New CHP plants with biomass can then during a period of 15 years achieve Elcert. The level of Elcert is set by the price on market place, by auctioning. It is now attractive to produce electricity during the summer period, and then CHP combined with heat driven absorption chiller is a feasible option for District Cooling.
8 LES SO N LEAR N T - GOOD P RACT ICES
8.1 MARKET DRIVEN DEVELOPMENT
The common success factor for successful DC schemes is their strong focus on market and sales during the development phase.
The DC product is mainly meant for commercial facilities and official buildings. It is therefore important to identify the market needs and understand market challenges. What are each customer’s specific needs? The District Cooling offer has to be equal or lower priced than the alternatives when all benefits are added. A higher price level linked to the added values is often hard to succeed in selling.
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Successful district cooling system is profitable. However, it must be remembered that DC is an infrastructure. Infrastructure investments are characterised by high initial investments, slow long term but steady income.
The key is satisfying the local market demand. It is essential to understand the whole market potential so the right technical solution that is feasible can be evaluated in order to be able to come up with a competitive District Cooling solution.
Securing key customers is essential. The DC distribution system is expensive. Customers located along the pipe routing are essential to connect. If not it will be difficult to achieve a high DC saturation. However there
is a possibility to move up on the value chain with additional services, see Figure 7.
Not securing a high enough penetration rate before investment decision will lead into a high profit dip during the first years.
Some customers can be supplied with temporary solutions so they do not have to invest in their own on-site local cooling solutions that would block DC connection for many years to come.
Figure 8: Value chain (Frohm, Henrik; Capital Cooling)
8.2 ROBUSTNESS AND FLEXIBILITY IN PRODUCTION
The choice for this technical solution and a specific production mix for a DC scheme always depend on local energy sources and conditions.
The basic business foundations for DC are linked to capacity costs and less on energy related costs. The successful DC business is characterized by having sufficient production capacity. With local solutions customers do need stand-by redundant capacity in each building.
It is important to have the knowledge of current realistic cooling demands in different types of buildings when establishing a DC business. Too high capacity estimations will lead to huge fixed costs. Experience is that many customers report over estimations on customer demand, usually evaluated from consultants. The knowledge of the current maximum capacity need for a building is often unknown. That is not the same as the number of chillers in the building reduced by the reserve capacity need. Investment
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decisions in DC production capacity solely based on customers calculations is a risk of standing with too much unused capacity and high capital expenditures.
Energy Efficiency
To be able to cover the high capital costs for distribution of a DC system, principles of the economy of scale should be applied and the production system has to be energy efficient. Establishing a small DC system can be financially challenging, if potential customers are located far from each other the DC pipe distribution system will be expensive.
High energy efficiency can be reached by using free natural cooling sources as, lake, river or seawater or by using waste heat from CHP, industrial processes or waste heat for absorption chillers, see Figure 9.
Figure 9. Energy balance for a District Cooling system. (Frohm, Henrik; Capital Cooling)
If high energy efficiency is reached, the primary energy factor will be low and the DC product will have a stronger environmental profile than the competitors on the market and the product will be easier to sell. However even with a strong PEF it is essential to offer a competitive price level in order to succeed with the DC business.
To be able to get a profitable DC scheme, it is essential that area is quite dense so the cooling demands will be high enough and that the connection speed is high to be able to cope with the high capital costs.
Using a benchmark on market demand per meter of distribution (kW/m of piping) will give an indication whether it is economically feasible to deliver DC to a certain area. This benchmark value will vary for each local market, depending on production costs, ECI etc. but should in most cases not be lower than 2 kW/m.
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8.3 STAKEHOLDERS AND FINANCIAL ISSUES
Figure 10. Stakeholders in a DC Scheme. (Frohm, Henrik; Capital Cooling)
One common success factor for the good practice examples is that the key stakeholders, see Figure 10, have had clear roles and where the local authority and local municipality/energy company have taken a clear role in developing the DC scheme. The local energy company has been able to develop the DC scheme with its own cash flow and then been able to use beneficial loans, from for example EIB or Green loans. Many of the companies have also introduced connection fees (access fees) to lower their negative cash flows in the start-up phase, Figure 11 show an example of the impact of the cash-flow by using an 20% access fee, on a typical 60 MW DC system.
Figure 11. Cash flow for a DC scheme. (Frohm, Henrik; Capital Cooling)
8.4 DISTRIBUTION PRACTICES, EARLY ACTIONS
The investment in a DC distribution system is often in the same range as the investments in the production plants. It is essential with a smart initial planning in order to save costs. What has been buried in the ground already is extremely expensive to replace later on. Identifying possible bottlenecks and obstacles in the early planning is essential in order to reduce the risk of costly surprises. Routing where the civil works are cheaper can lead to huge cost savings.
A DC pipe system is generally complex and need redundancy supply with alternative routings (loops). Considerations for start-up planning operations also need attention. Due to the complexity it is essential to implement the pipe system into a hydraulic model at an early stage.
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Strategic decisions on quality measures can be taken in the planning stage. One important issue is the type of pipe material in respect to, pressure requirements, temperature losses etc. Pre-insulated steel pipes are the most common type. Certified pipes according to the EN253 standard are then recommended. Linked to EN253 a lot of other normative standards do also apply.
Trenchless excavation methods or laying pipes directly on the bottom of lakes and seas can often lead to smart solutions and cost saving.
One often early identified obstacle when presenting leads of District Cooling systems is the disturbance on traffic during the excavations, this is especially common in cities with no experience of district energy. One common question is often how to handle the disturbance of digging up the roads. However the time for having open excavations is actually of a limited time frame. A control question can often be how was handled the construction work for new or refurbished infrastructure distribution lines in the street.
The disturbance on traffic can often be limited. One example is the use of temporary bridges that can reduce inconveniences.
A planning with minimising time for open excavations is recommended. There are also good examples on information during the construction works; “Excuse the mess. We are building for sustainable DC”.
There are cities with local legislation that limits time for open excavations. Checking local regulations is therefore recommended. Being forced to build very short distances before back-filling will lead to high costs. It will also complicate pressure testing of welds, joints and preservation actions linked to the filling up system with water.
9 LES SO N LEAR N T - BAR RIE RS A ND COMMO N FA ILU RES
9.1 TOO LOW MARKET FOCUS
Focus too much on the technical issues on the DC scheme and too little on the market. This leads to a technically superb DC system but with poor profitability because of low incomes per year. A common failure is often that the technical solution for the production of DC is chosen before the feasibility study stage. Not evaluating the impact of different options will not lead to an optimal solution.
9.2 ACCESS AND INTEREST FROM TOP MANAGEMENT
A common failure is a misjudgement of the needed management resources. It is very important to have control over the progress of the development of the project. Implementing adequate steering and control models at an early stage is absolutely necessary.
When a new product is set on the market, a lot of fast decisions have to be made and then a efficient decision process and interest from the top management is needed.
With auditing the progress early warning can steer the project on track again. Repeating expensive mistakes can be avoided. It is essential to identify problems early and giving attention to them. Letting problems wait will only escalate them.
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9.3 OVERESTIMATION OF CUSTOMERS COOLING DEMAND
It has been mentioned earlier in this report the risk of overestimating cooling capacity demands. Most property owners do not have a clear knowledge of their cooling demand. However, their knowledge of the maximum peak demand is more common than their knowledge regarding their annual cooling energy usage.
At contract negotiations, customers often report a higher demand than they actually have, based on their installed capacity but forgetting originally installed back-up capacity.
An overestimation of the peak demand may lead to overinvestments in the DC production plant and distribution network. If this is balanced by a higher connection fee from the customer, based on the customer building’s stated peak demand, the negative effects become less for the producer. Using a transparent connection fee linked to capacity is recommended.
Overestimation of the annual cooling energy usage is worse and may have a serious impact on project economics if too high annual income is calculated and not realised in practice. However, by benchmarking with other similar customers in other projects, climate data and careful inventory of the properties many uncertainness be clarified.
9.4 CHOOSE THE OPTIMAL PRODUCTION SOLUTION FOR THE DC SYSTEM
“Decentralised absorption chiller solutions”. Some energy companies in Sweden, Austria and Germany have started cooling business by providing decentralised absorption chiller solutions. Examples can be found in cities like Gothenburg, Vienna, Berlin, Düsseldorf and Munich. Some cities also have stand-alone installations of small local institutional solutions in airports.
A decentralised absorption chiller solution stands for an absorption chiller driven by heat from the current District Heating network is located in a sub-area or in the customers’ buildings. The idea with this solution is to avoid installation of a DC pipe network. Initially it sounds great, however there are issues that must be considered.
There are some advantages with this solution:
• Excess capacity in the production of District Heating system can be used. • Positive on the electricity balance. Electricity for chillers can be avoided and higher CHP production
possibility. • Environmental strength due to saving electricity that would otherwise power chillers. • Avoiding investments in a District Cooling network
But these advantages are balanced by disadvantages which often are disregarded:
• The District Heating network temperature is in general lower than required for operation of absorption chillers during the summer season with high cooling demand. The network temperature must be raised resulting in increased energy losses.
• Low ΔT in the District Heating circuit driving the absorption chiller; will damage the District Heating network return temperature. This will decrease heat recovery in the flue gas condenser and make it generally harder to use waste energy and heat pumps for District Heating production. Higher return temperature also leads to reduced power production in CHP-plants.
• The customer will lose the added value associated with District Cooling connections; simplicity, flexibility, saving local space and improved local environmental conditions.
• Difficult to achieve profitability in the local small business
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• Complicated permitting issues • Need of placing cooling towers on a roof top. Since COP for absorption chillers is lower, the cooling
towers will be much larger than for electrical chillers • Always need reserve chillers on site compared to District Cooling
One general observation is that providing cooling by decentralised absorption does not lead to a market penetration and the business usually is stagnant. The cooling deliveries never correspond to the potential each city has. Cities with large scale DC and only 100,000 inhabitants have cooling market shares that cities with 1,000,000 inhabitants and using decentralised absorption have hard time to reach. No energy company providing only decentralised absorption presented positive financial results.
Institutional District Cooling (stand-alone solutions for one customer) like airports are generally hard to integrate into larger District Cooling systems, due to the distance to other customers.
Providing decentralised absorption should only be used for customers that are not reachable within the DC network. The conditions are also that the energy company must have a stable large scale DC business. Only then is it possible to distribute fixed costs on many customers.
The second problem is keeping competence in the utility company on a non-expanding product. The interest of working with cooling will be low. Expanding and challenging assignments are always more interesting than business as usual. There are even cases when the energy company only sell heat to the customer. It is not known how much is used for heating and cooling. The customers then need to solve all O&M themselves. Basically it is then just the same case as having their-own alternative chiller solution.
9.5 TOO LITTLE ATTENTION ON ΔT RISKS
Lack of quality control on approving customer’s installations and reducing low ΔT problems is hard to correct at a later stage since the project team will be occupied with other on-going activities. When a customer shows too low return temperature, a prompt action is required. Do not wait until it is too late and the system suffers from lack of capacity due to too high flow and low return temperature.
Many examples exist of systems where the supplier initially not focuses on the ΔT, for the first customers. The pipe system still has no capacity limitations. It can even be so that the supplier is so eager on connecting customers that they do not deal with the problem.
It is essential to have technical requirements for DC connections. Technical requirements on how the building should be connected to the DC system. Adaptation of the building cooling systems must have high attention and be enforced. No DC system is better than the return temperature that the customer’s installations perform.
Too low ∆T in a DC-system have mainly three negative consequences; lack of capacity in the distribution network, high pumping energy costs and reduced utilisation of natural cooling resources. This leads to higher costs, decreased efficiency and lower environmental benefits.
A DC-system with bottlenecks due to excessive flow will restrict possibilities of connecting future customers and hereby reducing the potential income. Natural cooling resources, such as lake- or sea water, etc., will also be limited.
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9.6 LACK OF RESPECT FOR THE TIME PLAN
The process to develop a DC system is long with a number of milestones on the way. The time-plan shall be realistic. If it is realistic there is no reason not to follow it.
It is recommended to hang up the time plan on activities that are possible to influence, such as; “send in permit application” instead of “permit application approved”. Then it is also possible to work with a slightly aggressive time plan.
A usual situation is that the start of an activity is dependent of the end of another activity, but it is also so that in many cases it is possible to start a new activity although some uncertainties remain from previous activities.
Work hard to reach identified milestones in time, in case of delays; see if activities planned for a later stage can be started up earlier.
9.7 TO LITTLE FOCUS ON PERMIT ISSUES
When a DC-project involves circulation of sea-, lake- or river water one or more environmental permits are required. One of the prerequisites will be that an Environmental Impact Assessment study is carried out and presented, the recommendation is to start immediately with the EIS.
Important input data is annual and maximum water flow, temperatures, construction period, etc. Make sure that the volumes of water, temperature differences, etc. applied for are sufficient but make sure that, especially the temperature program, does not exceed existing regulations.
Start the permit activities immediately and make sure that the personnel or consultants which are handling the activities have the necessary knowledge and time available.
9.8 PIPES SURVEILLANCE SYSTEM NOT ADAPTED FOR COOLING DISTRIBUTION
If steel pipes with PUR insulation and HDPE jacket pipe are used for the distribution network the built-in surveillance system must be adapted for cooling. It has shown that traditional surveillance systems with uninsulated copper wires moulded into the foam give too many false alarms when used for cold water pipes. In surveillance systems for cooling water pipes are insulated wires on fixed distance between each other used; moisture is detected by measuring the change of impedance between the wires.
10 FI N AL DI SCU S SIO N
In all the good practise cities all had their share of both good practices, barriers and failures.
The main thing that is common for all the DC schemes are, that to be able to get it profitable three things are needed:
• Strong market focus so that the right capacity and energy are sold to the customers to the correct price.
• Chosen technology that is optimal for the local conditions. It has been flexible and robust so it can grow with the market demand and also survive changes in prices for
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energy sources. Key issues for this is using local energy sources and “Economy of scale” to maintain a low (Opex) operation expenditures.
• Strong local stakeholders that have believed in the DC product and made it happen. The municipality or the local energy companies have been able to develop the product with its own cash flow.
Cities that have successfully developed DC schemes have had a long experience in distributed energy (District Heating). This knowledge should also not be underestimated. Both the customers and the cities know the local energy company and trust the DH product. They know that it works, so why should DC be any different? The LA and local energy company also have longstanding experience in distributed energy and then the step to develop DC is not that high. This can be one reason why for example Paris has a District Cooling system and London does not.
11 KEY PE R FORM A NCE I N DIC ATO RS
What kind of technical solution and business concept that are used to develop a DC scheme is as said much depending on the local conditions in form of market density, local energy sources and the cost of using these sources.
For cities/ municipalities that are interested in study a DC scheme already in operation should study a city that have the same conditions as the good practice system has.
11.1 MARKET INDICATORS
The city or a part of the city should be in the right size and density. This means that there should be a high density of cooling demand on a limited ground area as the good practice cities have.
Key performance indicator: [number of inhabitants]
• Market potential, rough estimate of the total cooling potential in the city area
o Key performance indicator: [MW]
• How does the outdoor climate affects the comfort cooling demand in the city
o Key performance indicator: ECI (European Cooling Index) [-]
11.2 TECHNOLOGY/ SOURCING INDICATORS
Does the prospect city have an access to any natural cooling sources as sea, river or lake water as some of the good practise cities have. The city may also have access to some kind of waste heat from CHP, industrial process or waste incineration.
• Possible energy source to utilise
o Key performance indicator: Type of source, ex. Sea water [-]
The city/ municipality can be densely populated with buildings with high cooling demand or the cooling demand can be more widely spread in the city area.
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• Length of distribution system
o Key performance indicator: Distribution system length [km]
11.3 ENVIRONMENTAL INDICATORS
The DC product must have a better environmental profile and performance then the alternatives.
• High environmental performance of the DC product.
o Key performance indicators:
Primary Energy Factor (PEF), [ - ]
Carbon dioxide emissions, [kg/MWh]
From a cooling perspective the primary energy and carbon dioxide emissions are the most important indicators due to the fact that RES is already considered in non-renewable primary energy factors and is not required as separate criteria. For more information about environmental factors from a cooling perspective see (Rescue-project, 2013).
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12 BIBL I OGR AP HY
Climespace. (2013).
Fortum Värme AB. (n.d.).
Frohm, Henrik; Capital Cooling. (n.d.).
Koski, Kosti; Helsinki Energia OY. (n.d.). Finland.
Norrenergi AB. (n.d.). Retrieved from www.norrenergi.se
Rescue-project. (2013). Environmental factors from a cooling perspective. Stockholm: Rescue-project.
Tvärne, Anders; Capital Cooling. (n.d.).
Växjö Energi AB. (2012). www.veab.se. Retrieved from http://www.veab.se/Fjaerrkyla/Utbyggnadsplaner.aspx
APPENDIX 1: Description of the six selected good practice systems
Paris
Vienna
Stockholm
Solna/Sundbyberg
Helsinki
Växjö
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Description of system
Under the concession agreement with the City of Paris, Climespace develops manages and operates since 1991 the district cooling system which today consists of 10 production sites and 3 energy storage sites, with a total nominal cooling capacity of 290 MW delivering around 400 GWh per annum of cooling to over 550 buildings. However the first production and distribution of district cooling in the City of Paris has been operated since 1978 serving le Forum des Halles shopping centre and Le Louvre.
The production sites mainly use electrical centrifugal chillers for the cooling production. 3 of them use River Seine Water: Bercy, Canada and Tokyo plants from which Free cooling is also exploited. 5 others use cooling towers: Etoile, Auber, Opera, Les Halles and Philharmonie. Last, Paris Nord Est plant uses geothermal energy capable of producing simultaneous Cooling and Heating by means of Heat Pumps. However, in the outskirt of Paris there are others District cooling networks such as La Defense, Stade de France, Airports of Orly, Levallois, Boulogne and Charles de Gaulle and
etc. operated by other companies than CLIMESPACE. Facts and figures 2012
• 285 MW nominal cooling capacity • 360 MW subscribed power • 410 GWh annual cooling supply • 520 customers are connected with DC • Length of pipe system is 71 km • Supplied floor area approximately • 5,000,000 m2 • Population in city area approximately
2.2 million • 1 Central Control Station 24/7
monitoring
Development The Climespace District Cooling system has undergone a substantial development over its 20 years of operation, with an annual growth of about 15 MW additional subscribed powers as well as the development of new District Cooling plants such as the recently Paris Nord Est commissioned in 2013 and Philharmonie plant which will be commissioned in 2014. Together they accounts for an approximately
62% 9%
10%
8%
7%
4% 0%
Customer's profile 2012
Offices
Financial Institution
Retail
Hotel-Restaurant
Museum-Theater
Office + Retail
Residential
District Cooling show case -‐ Paris
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extra 10 MW of nominal cooling production capacity.
Lessons learned
• The implementation of local resources such as river water free cooling, geothermal energy coupled with energy storage systems can significantly contribute to reduce the need of extra installed cooling capacity and to decrease peak electricity demand and therefore strengthen the electricity infrastructures.
• Following the lessons learned from the Bercy energy plant, Climespace developed 2 new plants near the River Seine in order to exploit river water free cooling: Canada and Tokyo which were commissioned in 2003 and 2007 respectively
• The important savings and benefits brought by this type free cooling resulted also in daily energy plants operation strategy that tends to give priority instead of these operating via Cooling Towers
• Working closely with local public and private stakeholders is important for the implementation and construction of a DC system.
Critical success factors
• Being able to utilize local sites for new production energy plant within the perimeter of the concession agreement and the proximity of cooling energy demand.
• The availability to use the existing underground sewage and gallery systems and the permission to pass pipe network through the city streets.
• The cultural heritage of beautiful building facades supported by the city of Paris city by not allowing the installation of outdoor air conditioning units on the walls visible to the public eye.
• The availability to use local natural resources such as geothermal energy and the Seine river water.
Political decision to phase out the usage of CFC, HFC and HCFC had very positive influence for customers to choose DC instead of own chillers.
0
50
100
150
200
250
300
350
400
Subscribed Power MW
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Description of system
Initially Wien Energie Fernwärme had a few customers having their own absorption chillers supplied by the district heating pipe system. It was for many years no development of cooling supply. A feasibility study showed the possibility of supplying district cooling (DC) to different market areas. The possibility of using river water (Donau) during periods was also recommended. The first large scale DC system was taken into operation in 2009. The basis of the production is large absorption chillers. DC is produced mainly in absorption chillers using exclusively waste heat from co-‐generation plants, waste incinerators, biomass power station, and geothermal energy sources leading to huge emissions and fossil fuels reduction between four to tenfold. Spittelau waste incineration plant together with river water from Donau which corresponds to 20-‐25% of the annual cooling supply, ensures a sustainable DC production. First development phase with 17 MW cooling capacity has been in operation since 2009. Rudolfstiftung Hospital has a total installed cooling capacity of 7.8 MW with absorption chillers and electrical chillers plus also heat
pumps using the rejected heat from the server room. Re-‐cooling on the roof of the hospital is done with open cooling towers (‘free cooling’).
District energy schematics in Vienna. -‐ SOURCE: Wien Energie Annual Report 2011/2012 In Renngasse, a historical part of Vienna, 6 MW cooling capacity is in service since October 2012. Now the new Schottenring project, an underground garage with a cooling plant, has been in operation since April 2013 and aims to provide 15 MW cooling capacity with absorption chillers and compression chillers, and also with re-‐cooling with water out of Donau (‘free cooling’). DC in the downtown office complex serves 21 objects with a peak load of 10 MW supplied by 6.5 MW absorption chillers and 3.5 MW compressor chillers. A new DC project in Krankenhaus Nord (Hospital) with cooling capacity of 3.4 MW absorption chillers and 6.4 MW electrical chillers plus a ‘free cooling’ capacity of 4.0 MW (open cooling towers) is scheduled for completion in August 2014. The Central Railway Station project with cooling capacity of 20 MW and open cooling towers in Schweizergarten is scheduled for completion in March 2014. Austria has a dependency on thermal production plants for peak electricity production in the summer. Using absorption
District Cooling show case – Vienna
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chillers now reduces electricity for cooling substantially.
Facts and figures
• 65 MW (as of 1.12.2013) • 72 GWh (2011/2012) • Number of customers • Presently 4.8 km DC pipe system • ~ 1,1 Mio. m² supplied floor area • 1 757 000 citizens in city area • European Cooling Index ECI = 106 • Specific cooling Key factor 50 kWh/m2
Development Wien EnergieFernwärme currently supplies the downtown office complex, the Skyline office block, the University of Natural Resources and Applied Life Sciences, Vienna General Hospital (AKH) and the SMZ Ost hospital with DC. The initial DC system had a capacity of 17 MW. The second stage of the development included some additional capacity on 50 MW. Wien EnergieFernwärme has set itself the strategic objective of achieving a DC output of 200 MW by 2020. Currently installed cooling capacity is 65 MW. It is expected that a 50% DC market share of the cooling demand in Vienna will be reached in 2020.
Planned development of District Cooling connection capacity in Vienna Lessons learned
• Size matters. A large system leads to better economy. Allocating resources for small local cooling islands supply results in poor economy.
• Wien EnergieFernwärme takes investment decisions depending on agreements with base load customers.
Critical success factors • Peoples and customer’s acceptance
on waste incineration and district energy supply has been very positive.
• Need of reducing existing peak production on electricity (fossil fuels) has had a positive influence on developing DC. Cooling demand is constantly growing. DC offers a production with low primary energy use.
• Focus on areas with a high concentration of cooling demand.
Each project is individual and the designing effort must be adapted accordingly. This effort is necessary to provide customers with a competitive DC offer.
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Description of system District heating has been provided in Stockholm since 1953. District cooling first started in 1995. The systems are owned and operated by Fortum. The fact that all customers were familiar with district heating already has been an important issue for the implementation of district cooling. The supply of DC is dominated with the city centre system, which now also has been integrated to the islands of Kungsholmen and Södermalm plus the Globe area at the mainland in the south.
Central DC system in Stockholm The production is a mix of DSWC, heat pumps and chillers. To reduce the need of production capacity two types of local storages has been incorporated. One aquifer storage and one underground cold water storage. The cold water storage is located in bedrock space in a tunnel system.
Apart from the city system Fortum also have other separate DC systems in Stockholm. The second largest system in Stockholm is located in the Kista area which is Sweden’s IT-‐centre. The cooling demand in Kista is 50 MW. Apart from this local systems also exist in Vilunda, Skärholmen, Tensta, Älvsjö, Lidingö, Farsta and Nacka, with a total capacity of 30 MW.
Kista DC system Facts and figures
• Production capacity approx. 280 MW (not including storages capacities)
• Energy per year 426 GWh (2013) • SSEER = 6.9
District Cooling show case – Stockholm
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• Over 600 buildings are served • Length of pipe system 200 km • Supplied floor area 7 million m2 • 870 000 inhabitants in city area • European Cooling Index ECI = 73
Development When the first DC delivery started in 1995, the target for the DC business development was to reach a capacity of 70 MW. DC was very positively accepted by the customers and a further expansion was possible. However in 2000-‐2001 the expansion was temporary put on hold due to lack of production capacity. Today the city system have a production capacity of more than 200 MW, excluding capacity from storages.
Lessons learned • Do not use direct customer
connections. The improvement of ΔT without heat exchanger cannot counter-‐weight the risk and damages by primary system leakages.
• Pumping water through aquifer storages was complicated. Due to a high content of fine sand in the aquifer the pumping capacity was reduced, which lead to lower storage capacity.
• Investments of electricity grid inside the city area could be avoided. Without DC the requirements of electricity for local chillers would have been 5 times higher.
Critical success factors • Customers were already familiar with
district heating supply • Political decisions during the 90-‐ies on
phasing out refrigerants CFC and HCFCs had a very positive influence for customers to choose DC instead of own chillers.
• Reduce distribution investment by utilising location existing rock tunnel for district heating. Avoiding building production in the city and utilising location area by the quay at the sea-‐side.
• Utilising space for production at strategic locations.
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Description of system Solna and Sundbyberg are two communities located directly north of Stockholm. Norrenergi is the company that developed and operates the DC systems. Heat pumps were the initial source to utilize the DC production. When the DC system had reached a large enough market penetration and capacity it was feasible to build a sea water supply system. For peak and reserve are now also electrical chillers included in the production. A cold water storage (CWS) is also included in the production facilities and located at the production site, Solnaverket. When the cooling demand is low, during nights, the CWS is charged with the sea water free cooling. Further expansion of the DC system will be utilized by also adding chillers at the DH plant in Sundbybergsverket. The sea water pipe system is already utilized to the maximum capacity. Frösunda SWAC station
- 10 MW free cooling - 13 MW chillers
Sundbybergsverket – DC plant
• Chillers 6.5 MWc Solnaverket – DC plant
- Heatpumps 2*10MWc - Chillers 2*5 MW - CWS 6500 m3, 75 MWh energy
storage capacity
Facts and figures
• 43 MW in 2013 • 69 GWh (2013) • Number of customers • DC pipe system 32 km • Supplied floor area • 108 000 citizens in the 2 cities Solna &
Sundbyberg • ECI=77
Development The DC system was planned at the same time as the Stockholm system in 1994. The approach on developing DC in Solna/Sundbyberg was to start with utilizing energy also from the cold side of existing heat pumps. The waste heat used in the heat pumps is treated sewage-‐water.
District Cooling show case – Solna / Syndbyberg
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Layout of DC distribution system in Solna/Sundbyberg and location of DCPs. (Norrenergi AB) Area 1, above, was in the first stage developed with the mix of heat pumps and electrical chillers. With the success of providing DC the waste energy (in the heat pumps) was utilized to maximum capacity. For new customer the dependency on electrical chillers was too high. Area 2 is covering one of the most expansive areas for developing office areas. These modern commercial buildings do all need AC, so DC is an attractive product in the area. For this area sea water cooling was possible to develop.
District cooling energy sales 2007-‐2013. Lessons learned
• Strong focus on market and sales and solving the customers problems
• Dedicated personnel with the right competence that could develop the DC scheme
• Use of Climate Investments Subsidies (KLIMP) for the DC development
• Don’t underestimate the market growth potential in the market areas
Critical success factors
• Customers already familiar with DH do easier understand the benefits with DC
• Strong commitment from top management that believed in the DC product
• Beneficial location of dense office buildings
• Successful usage of existing infrastructure, waste energy and free cooling
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Description of system
The experience of district energy supply in Helsinki has a long history. District heating (DH) production in Helsinki started in 1953. DH was a success from the beginning. District cooling (DC) supply started in 1998. The implementation of DC was easy since real estate owners already were experienced with DH. The DC production is a mix of sea water cooling (free cooling) during 6 months of a year, absorption chillers and heat pumps.
More than 80 % of production is based on energy that otherwise would be wasted. The Katri Vala heating and cooling plant is the largest in the world to use heat pumps to produce District Heat and District Cooling form both purified sewage water and sea water. Its output is 90 MW of District Heat
and 60 MW of District cooling which is enough to heat a small town. The plant is located in a rock space and tunnels underneath the Katri Vala park in the district of Sörnäinen.
The production with sea water and absorption chillers is located at the Salmisaari cooling center and has a capacity of 10 x 3.5 MW absorption chillers and two compressor chillers. The heat source for the absorption technique is +85°C district heating water.
Facts and figures
• 180 MW • 130 GWh (2014) • 300 connections to the system • 65 km DC pipe system • 50 000 m3 dc energy storages • More than 14 000 000 m2 floor area
is now supplied with DC • 738 000 citizens in city area
District Cooling show case -‐ Helsinki
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• European Cooling Index ECI=72 Development
Lessons learned
• In Helsinki the rock under the city is very solid. Both piping and production plants could be built under the ground. The disturbance of excavation of roads was then limited. Drilling tunnels reduces pipe length. It is possible to cross-‐cut instead of following the position of the roads.
Critical success factors
• Rapid growth is based on customers’ own will to choose District Cooling in a free market. DC must then always be competitive.
• The barrier to start a District cooling business much lower, when there is an existing energy company that already had a lot of experience and knowledge about successful district heating (DH).
• Offering outsourced cooling solution that helps the building owners to
concentrate on their key business and therefore boost the productivity of their business.
• It was noticed that district cooling provides the easiest way to improve energy efficiency and reduce the CO2 emissions for a building located in Helsinki.
In Helsinki there is demand for heating and cooling at the same time. Combined heating and cooling with large-‐scale heat pump stations is both economically and environmentally competitive solution.
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Description of system
In 1970 Växjö Energy started to build the first district heating network. The production initially was based on oil. Today over 90% of the district heating comes from biomass (wood waste from the local forestry). The first biomass CHP plant was built in 1997. The municipality is growing. A new biomass CHP plant 38MWe and 62 MW heat is now under construction, and will be taken into operation in the end of year 2014. Then oil will be totally phased out from the DH production.
Existing DH and CHP production plant at Sandviksverket. SOURCE: VEAB homepage
The first feasibility studies for district cooling network were taken in 2006. In 2007, a 300 kW pilot absorption cooling unit was installed. In 2010, the first stage of the district cooling network was established. The main production of DC is based on absorption chillers located at the CHP plant. The DC pipe network is partly located in lakes. That is also why excavation work and disturbance on
land has been reduced. Both for pedestrians, traffic on roads and also for the railway. Facts and figures
• DC supply 13 MW • 11 GWh (2013) • Around 20 buildings are served • Length of pipe system 13 km • Population in municipalty 78’000 and
60’000 in the city area • No ECI available. Estimated ECI = 70
Development The DC business case is aiming on a cooling market of 25 MW. The DC system will have a potential of a future expansion up to 35 MW.
The first development phase in 2010 and 2011 consisted of establishment of local DC areas. One system covers the city centre and the eastern part of Växjö. In May 2011, two absorption chiller units with capacity of 2 MW each were installed in the CHP plant. The total production capacity with one more unit will in the future be 6 MW absorption chillers plus 2 MW extra from the 2’500 m3 cold water storage. In parallel with the central and east DC system the second system for the sports arena city was developed with supply 8 MW from compressor chillers. Initially mobile temporary solutions were used.
District Cooling show case – Vaxjö
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Construction work of DC pipes in the lake Trummen
In 2012 a permanent DCP was in operations. The connection of the university is with DC pipes in the lake Trummen. Växjö Energy did also take over existing local chillers, 2 MW, at the central hospital, located near the city centre. In the system free cooling from air is also when it is cold enough possible to use, 0.5 MW from cooling towers plus 2 MW from dry coolers. When the lake surface water is cold enough up the 1 MW can be utilized, directly by heat transfer from the lake water into the DC return pipe.
District cooling energy sales 2007-‐2013 The plan is now to connect the two systems into one large common DC system. Depending on interest of new DC customers the connection will be finalized during 2014 and 2015. The production mix will be:
• Compressor chillers 24%
• Absorption chillers 32% • Natural cooling: 44%
Production mix for Växjö DC system Lessons learned
• District cooling based on absorption technics poses an opportunity with biomass fired CHP. However the fuel price must then be low, or a high value of the electricity from CHP.
• Transfer of the district cooling practice from Växjö is particularly interesting for towns/municipalities with possible synergies of pipes for district heating and district cooling system can be simultaneously built.
Critical success factors • Strong initial interest of cooling
supply from large key customers like the University and Hospital.
• Political leadership and consensus are one of the key factors, to be able to take necessary decisions. One was in 1996 to not use fossil fuels in the activities of the Municipality.
• Broad collaboration with all stakeholders for around common goals has strengthened the regional competitiveness.
Distribution of production
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