Remaining scientific uncertainties include the exact degree of climate change expected in the future, and especially how changes will vary from region to
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region across the globe. A hotly contested political and public debate also has yet to be resolved, regarding whether anything should be done, and what could be cost-effectively done to reduce or reverse future warming, or to deal with the expected consequences. Most national governments have signed and ratified the Kyoto Protocol aimed at combating global warming. Relative to the period 18601900, global temperatures on both land and sea have increased by 0.75 C (1.4 F), according to the instrumental temperature record; the urban heat island is not believed to be significant. Since 1979, land temperatures have increased about twice as fast as ocean temperatures (0.25 C/decade against 0.13 C/decade) (Smith, 2005). Temperatures in the lower troposphere have increased between 0.12 and 0.22 C (0.22 and 0.4 F) per decade since 1979, according to satellite temperature measurements. Over the one or two thousand years before 1850, temperature is believed to have been relatively stable, with possibly regional fluctuations such as the Medieval Warm Period or the Little Ice Age. Based on estimates by NASA's Goddard Institute for Space Studies, 2005 was the warmest year since reliable, widespread instrumental measurements became available in the late 1800s, exceeding the previous record set in 1998 by a few hundredths of a degree. Estimates prepared by the World Meteorological Organization and the UK Climatic Research Unit concluded that 2005 was the second warmest year, behind 1998. The attribution of recent climate change is clearest for the most recent period of the last 50 years, for which the most detailed data are available. Note that the anthropogenic emissions of other pollutantsnotably sulphate aerosolsexert a cooling effect; this partially accounts for the plateau/cooling seen in the temperature record in the middle of the twentieth century, though this may also be due to intervening natural cycles. The climate system varies through natural, internal processes and in response to variations in external "forcing" from both human and natural causes. These forcing factors include solar activity, volcanic emissions, variations in the earth's orbit (orbital forcing) and greenhouse gases. The detailed causes of the recent warming remain an active field of research, but the scientific consensus identifies greenhouse gases as the main influence. Contrasting with this consensus view, other hypotheses have been proposed to explain all or most of the observed increase in global temperatures, including: the warming is within the range of natural variation; the warming is a consequence of coming out of a prior cool period, namely the Little Ice Age; and the warming is primarily a result of variances in solar radiation.

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molecules of interest more challenging. Careful laboratory spectroscopic measurements, rather than ab initio quantum mechanical computations, provide the basis for most of the radiative transfer calculations used in studies of the atmosphere. The molecules/atoms that constitute the bulk of the atmosphere; oxygen (O2), nitrogen (N2) and argon; do not interact with infrared radiation significantly. While the oxygen and nitrogen molecules can vibrate, because of their symmetry these vibrations do not create any transient charge separation that enhances the interaction with radiation. In the Earths atmosphere, the dominant infrared absorbing gases are water vapor, carbon dioxide, and ozone (O3), these molecules being floppier so that their rotation/vibration modes are more easily excited. For example, carbon dioxide is a linear molecule, but it has an important vibrational mode in which the molecule bends with the carbon in the middle moving one way and the oxygens on the ends moving the other way, creating some charge separation, a dipole moment. A substantial part of the greenhouse effect due to carbon dioxide exists because this vibration is easily excited by infrared radiation. Clouds are also very important infrared absorbers. Therefore, water has multiple effects on infrared radiation, through its vapor phase and through its condensed phases. Other absorbers of significance include methane, nitrous oxide and the chlorofluorocarbons. Discussion of the relative importance of different infrared absorbers are confused by the overlap between the spectral lines due to different gases, widened by pressure broadening. As a result, the absorption due to one gas cannot be thought of as independent of the presence of other gases. One convenient approach is to remove the chosen constituent, leaving all other absorbers, and the temperatures, untouched, and monitoring the infrared radiation escaping to space. The reduction in infrared absorption is then a measure of the importance of that constituent. More precisely, define the greenhouse effect (GE) to be the difference between the infrared radiation that the surface would radiate to space if there were no atmosphere and the actual infrared radiation escaping to space. Then compute the percentage reduction in GE when a constituent is removed. The table below is computed by this method, using a particular 1-dimensional model of the atmosphere. More recent 3D computations lead to similar results.

In Spain there is a Renewal Plan which encourages with discounts the purchase of efficient home appliances in the retailers. This Plan varies depending on the autonomous region.
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LIFE CYCLE MANAGEMENT Life cycle management are tools which allow analysing the impact against the environment of all the appliances along their useful life ( production, distribution, use and end of use). Certain analysis show that more than 90% of the environmental impact of the products take place during the use of the appliances at homes, due mainly to the consume of energy. For that reason, most of Teka appliances are A class.
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8. PRO EUROPE

PRO EUROPE s.p.r.l. (PACKAGING RECOVERY ORGANISATION EUROPE), founded in 1995, is the umbrella organisation for European packaging and packaging waste recovery and recycling schemes which mainly use the "Green Dot" trademark as a financing symbol. In its primary role, PRO EUROPE is the general licensor of the "Green Dot" trademark. It also acts as the authoritative voice and common policy platform representing the interests of all packaging recovery and recycling organisations founded and run by or on behalf of obliged industry. These national recovery organisations are pursuing similar goals, essentially finding themselves and their stakeholders in a similar situation. They have set themselves the task of relieving industrial companies and commercial enterprises of their individual obligation to take back used sales packaging through the operation of a scheme which fulfils these obligations on a nationwide basis on behalf of their member companies. The aim is to ensure the recovery and recycling of packaging waste in the most economically efficient and ecologically sound manner. Apart from requiring the co-ordination and alignment of individual member positions, the task of safeguarding common interests involves the projection of a coherent, unified policy and image to the outside world. The "Green Dot" has evolved into a proven concept in many countries as implementation of Producer Responsibility. Industry in twenty-five nations is now using the "Green Dot" as the financing symbol for the organisation of recovery, sorting and recycling of sales packaging. Private-sector compliance schemes working toward this objective are today in place in twenty-two EU member states, viz., Austria, Belgium, Bulgaria, Cyprus, Czech Republic, Estonia, France, Germany, Greece, Hungary, Ireland, Latvia, Lithuania, Luxembourg, Malta, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, and Sweden as well as additional countries include Norway (as an EEA member), Croatia and Turkey. Moreover, PRO EUROPE has concluded co-operation agreements with similar systems in UK (VALPAK), Canada (CSR), Iceland (IRF), Finland (PYR) and Ukraine (UkrPec) so that they are part of the common network as well. VALPAK and CSR are taking care for the Green Dot in UK and the NAFTA region to ensure that all licensees of the Green Dot may use labelled packaging without problems throughout the world. The members of PRO EUROPE wish to demonstrate that the recycling of used packaging is an important step on the path towards the sustainable development that is necessary to safeguard our planet for future generations.

Population Inhabitants incorporated to selective collection 44.1 Million inhabitants (2005) More than 41.4 million inhabitants in paper/cardboard selective collection and more than 39 million inhabitants for light weight packaging selective collection. 904 billion (2005) 7.4 million tons (2004) included wood, other materials and glass. - 237 million Euros ECOEMBES (2005 ) - 49.9 million Euros ECOVIDRIO (2005 ) Household packaging. Commercial packaging is accepted under voluntary agreement
Gross domestic product Total packages on market

Turnover

Types of packaging
Financing Ecoembalajes Espaa ( Ecoembes) is a non-profit company. Its activity is financed by the contributions made by the packaging companies belonging to
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the IMS, according to the number of packages put for the first-time on the Spanish market and the material used to make them. All this packaged products are identified with the Green Dot logo. Ecoembes uses these contributions to finance the extra-cost that the selective collection, transport, classification and subsequent recycling and recovery of the packaging waste means to the local authorities. The packaging companies that want to belong to Ecoembes's IMS in order to comply with the law, enter into a Membership Contract and fill in an annual return regarding the packing put on the Spanish market, from which their contribution to the IMS is deducted.
Green dot is an official distinctive present in the EU in plastics, cans, tetra briks, paper and glass. It guarantees that that the packing which has it fulfils the Law of packings and packing residues which forces the packager to recover the residues generated by its activity and that its producer adheres to the IMS.
The Moebius triangle or Moebius circle is in almost all the plastic packings. A code or a number under it indicates what type of material it is. It identifies the recycling of materials. The arrows represent the three states of recycling: collection, conversion in a new recycled product and packing. It avoids different materials getting mixed. Tariffs

HOODS All our chimney hoods fulfil ROHS Norm, being an indispensable condition to be our electric or electronic supplier that all the materials fulfil Rohs Norm.
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Introduction: Environmental protection is a determinant factor in the development of our activity and we are committed with the compliance of the environmental legislation in force and other environmental requirements which involve environmental benefit for the society. Continued improvement is the main performance principle, setting minimising plans of residues and spillages. Optimising human resources and materials, including raw materials directed to the permanent improvement regarding environment, preventing pollution.
Processes: Currently in all the processes implemented, somehow capable to alter environment balance, due to atmosphere emissions, generation of dangerous residues or water pollution, have been applied and still are implemented the best techniques available in the sector (MTD) according to the document BREF issued by the European Commission in September 2005 and according the legislation in force. These techniques are based on prevention, minimising and control of pollution. Furthermore we have final treatments to avoid negative impacts on the environment. All the waters which can pollute the environment are treated in our facilities through a system of physical and chemical purification. The gases before their emission pass through a wash tower. Hazardous residues are managed through an authorised manager. Product: By definition, hoods are the only home appliance whose main function is environmentally friendly, since its operation is designed to purify the fumes and odours before being emitted outside. 1.- All Teka hoods are designed to incorporate in all the models the recirculation system. This system allows filtering the air before being expelled outside, reducing the emission of grease particles and other gases suspended 2.- We have hoods with humidity detector, as well as stop delay what makes the appliance operate only when it is necessary, avoiding unnecessary consume of energy and loss of heating / air conditioning. 3.- The packaging of our products are environmentally friendly having as a priority the following items:
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Our inner protections are made with compounds which do not bring heavy metals. They have a minimum consumption of material and a lower product emission for recycling. For this product there are ways of recycling and reusing, apart from inner reusing in packaging of other products, this material is used again once treated for insulating buildings, etc. 4.- The design of the motors avoid the outer/inner flow, avoiding air conditioning losses and the access of smoke from outside. Furthermore the electric consume is very low. 5 The no return airflow flaps available in all our traditional hoods are valves situated in the air vent of traditional hoods, in the joint with the air conduct, which prevents fumes or odours revoke in the kitchen when the hood fan is not operating. This automatic valve closes when the hood is not working avoiding unnecessary flow of air. This avoids drop phenomenon in the enclosure attracting the air from outside through the hood causing the cooling of the room and the eventual air entrance polluting the adjacent hoods.

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purifier: this, apart from protecting the washing machine from the damages caused by lime, reduces the energy consume. And if not, the efficiency of the detergent can be improved without increasing its consume, adding a small quantity of some specific product against the lime. These measures reduce considerably the necessity of repairs. But, how to know if the water is hard? Simply immersing the strips that are sold with that purpose in aquariums, ironmongers or stores that sell household goods, paint, etc. To know the water hardness degree is useful because the quantity of calcium salts and magnesium present influences particularly the washing results. To decrease its negative action, the detergents have special components which have the function to counteract it, for that reason the quantity of detergent which must be used increases in function of the water hardness. Not for nothing, the instructions in the detergent indicate the right dose according to the water hardness: if its soft (lower than 15 French ) is enough a smaller dose than necessary if the water is hard (higher than 25 French). The white clothes and the colour clothes must be washed separately. It is advisable to assemble the small clothes like sockets in a special cover for these garments. Once the wash is over and the clothes pulled out is convenient to let the gasket dry and leave for some time, the door ajar. To get a perfect wash of the clothes, never exceed the maximum quantity recommended by the producer. This way, the clothes will move with looseness bringing a wash and a spinning of more quality. Check if the clothes have objects in the pockets like coins, pins, etc, that way you will avoid the obstruction of the pump in the discharge area.
The new washing machines TKE 1260 S, LI 1260 S, LI 1060 S and LSE 1200 S are equipped with a double water inlet for cold and warm water in order to go along with the new legislations about new building construction. This allows saving energy.
Dishwashers tips and advices to save energy Generally speaking, according to the habits of an average European family, the dishwasher consumes 1,2-1,8 Kwh and 20-30 grammes of detergent in the cycles of wash at 65 ( apart from the added expense of 0,08 euros for the rinse aid and the salt automatically measured out). Firstly, put the dishwasher only when it is full, learning how to place crockery properly taking advantage of the space, avoiding piling up which do not leave water pass through all the surfaces. This way, the wash cycle can be reduced in 1/3 even in . Also regarding the water
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consumption, a full load of crockery dishwashed needs less water than the same crockery washed by hand. Except in particular cases, you have to avoid the prewash, which apart from consuming energy, doubles the water consumption. If you leave the wash for the following day, you can choose the previous soak button. Chose intermediate and short programmes, with not very high temperatures. When there is not too much crockery to wash, quick cold wash is ok. Reserve long cycles only for especially dirty pans. To rinse well the plates before placing it in the dishwasher is a useless waste of water and time, what evidently reduces the advantages of using a dishwasher: it is enough to immerse them lightly in the sink with a little water and make sure that there are no melonpits or watermelonpits, fishbones or similar residues because they would probably stuck the holes of the arms where the water comes out, altering the washing efficiency. Clean regularly and carefully the filter: the rests which lodge hamper the water outlet and make they do not clean well. Eliminate the drying function with hot air: when opening the door just finishing the wash, the simple natural circulation of air is enough to dry the crockery quickly, so it reduces the cycle at least 15 minutes and we get 45 % energy saving. Also, you have to use the half load very now and then: the washing efficiency is lower than the standard programme, while the consume and water consumption is higher. Fill regularly the salt deposit to increase the efficiency of the detergent and avoid the build-up of lime incrustations. Use exclusively specific detergents for dishwashers and in small quantities without exceeding the dose advised by the producer. Utilizar exclusivamente detergentes especficos para lavavajillas y en pequeas cantidades, sin superar nunca la dosis aconsejada por el fabricante. Today there are very good ecologic detergents which apart from polluting less, they have less guarantee for the health in case of residues in the crockery. As we have said before regarding washing machines, in the case of dishwashers you do not have to exaggerate with the dose of detergent, because their steams pollute the inner air and the residues in the plates are harmful for the health. The dishwashers clean very well with less detergent in comparison with the others ( an average of 20-25 grammes against 40-50 grammes in the past). Place the biggest and dirtiest pieces in the lower trays. This way, the water will circulate freely and we will get a better wash. Rinse the crockery with cold water in order dirtiness not to dry thoroughly.

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Did you know that? More than half of the green house effect created by the human being is due to the C02 emissions. We also produce C02 at home. For every Kw/h energy we consume, 400 gr C02 are emitted to the atmosphere. An A+ refrigerator can consume 53% less than a C Class one. This involves along the useful life of an appliance more than 400 Euros saving and avoiding the emission to the atmosphere of 1.5 tons CO2 Home appliances are responsible of more than 50% electric consume. The refrigerator is responsible of more than 18% of the electric bill. If all the refrigerators in Spain change to A Class there would be a saving of energy equivalent to disconnect around 700,000 homes, a city like Valencia. An A Class dishwasher can allow a family a yearly saving of more than 30,000 litres of water versus handwash. The consumption of water in the world has doubled between 1960 and 2000 and it is esteemed that in 2002 was used more than 50% of the total sweet water available. A study at Bonn University estimates that the Spaniards consume averagely 106 litres handwashing the crockery. An A class dishwasher represents 85% water saving, getting a better cleaning. Induction hobs consume 33% less than vitroceramic hobs. Along its cycle of life induction saves the energy equivalent to the consumption of a family during more than 9 months (cost of 270 Euros) and avoids the emission to the atmosphere of more than 1 ton of C02. In 2002 the human consume exceeded 20% the biological capacity of the Earth and we estimate that in 2050 we will exceed it between 80%-120%. Currently, the quantity of Co2 emitted every year is between 6,000- 7,000 million tons. Each home is responsible to produce up to 5 yearly tons of Co2. An A class washing machine consumes 40% less than a D class one. This means along the useful life of an appliance to avoid the emission to the atmosphere of more than half ton of Co2 as well as more than 200 Euros saving in the electric bill. Moreover, more than 35,000 litres of water would be saved.
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An A class washing machine consumes 30% less than a C class one. With the energy saved, you could iron for more than 700 hours. Furthermore, the emission of more than half a ton of C02 would be avoided.
An A+ refrigerator can consume 44% less than a B class one. That is, along its useful life, we will have saved almost one ton of C02 and save approximately 65 Euros.
Average cost of the refrigerator 650 Euros 500 Euros The A+ refrigerator is 150 Euros more expensive Energy consumption in 10 years 2680 Euros 4825 Euros The A+ refrigerator consumes 44% less Cost of energy in 10 years 268 Euros 482 Euros The A+ refrigerator consumes 214,5 Euros less

-1021 kWh -80,87

-2246 kWh -177,92

-3063 kWh -242,62

-3812 kWh -301,93

-4628 kWh -366,63

-5105 kWh -404,37
The energy consume of an A class appliance means:

A class A

Energy consumption <55%
Consumption level Low energy consumption
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CALCULATOR WASHING MACHINES
An A class washing machine consumes 214 kwh yearly, 48% less than a D class washing machine and 63% less than one G class washing machine. Foreseeing a useful life of 10 years, it would consume 3718 kwh less than a G class washing machine, avoiding the emission to the atmosphere of 1,561 kg Co2 and it would save 294 Euros. The rest of energy classes would involve an additional expense with respect to an A class washing machine.

-715 kWh -56,64

-1430 kWh -113,27

-2002 kWh -158,58

-2574 kWh -203,89

-3146 kWh -249,2

-3718 kWh -294,51
Calculations considering a use of 5 times a week and 5,5 kg load
The consumption of an A class appliance: Energy class A Energy consumption <55% Level of consumption Low level of energy
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CALCULATOR DRIERS

An A class drier consumes 412 kwh/ year, 36% less than a D class and 52% less than a G class. Foreseeing a useful life of 10 years, it would consume 4537 kwh less than a G class drier, avoiding the emission to the atmosphere of 1,905 kg Co2 and they would save 359 Euros. The rest of the energy classes would cause an additional consumption with respect to an A class drier.
Calculations considering 5,5 kg capacity condenser driers and a use of 5 times a week, except in summer months.

-825 kWh -65,35

-1568 kWh -124,17

-2310 kWh -182,98

-3052 kWh -241,8

-3795 kWh -300,61

-4538 kWh -359,43
The energy consumption of an A class drier means:

Energy class A

Consumption level Low level of energy

-429 kWh -33,98

-944 kWh -74,76

-1459 kWh -115,54

-2145 kWh -169,91

-2488 kWh -197,1

-3003 kWh -237,88
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CALCULATOR DISHWASHERS

An A class dishwasher consumes 257 kw/h yearly, 36% less than a D class one and 54% less than a G class one. Foreseeing a useful life of 10 years it would consume 3003 kw/h yearly less than a G class dishwasher, avoiding the emission to the atmosphere of 1261 kg Co2 and it would save 238 Euros. The rest of energy classes would imply an additional expense with respect to an A class dishwasher.

-3003 kWh -237,88

Calculations considering a dishwasher with a capacity of 12 place settings and a use of 5 times a week. The energy consumption of an A class appliance means:
Appliance Washing machine ( 5 washes/ week) Electric built-oven ( 3 hours / week) Microwaves Freezer Dishwasher ( 5 washes / week) Bottom freezer refrigerator
Average consumption (yearly kwh ) 312 Euros 3119 Kw/h
Average electric bill Spanish consumers 2005 Average electric consumption or energy demand
Power hired % Vitroceramic hob / Total electric expense Number of homes Monthly expense electricity vitroceramic hob Induction Vitroceramic hobs Efficiency Induction/Vitroceramic hobs Saving Induction Vs Vitroceramic hobs Saving Induction Vs Vitroceramic hobs 10 years
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4 Kw 9% 22.000.000 28,08 Euros 0,17 Kw/hour 0,22 Kw/hour 29,41% 8,14 Euros/year 81,4 Euros
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COLD DATABASE

NO FROST ENERGY CLASS A, A+ or A++ A A A A A A+ A A A A A A A A A+ A A A A A A A A A A A A A A A A+ A A A A A A A A A A+ A+ A+ A+ A+ A+ A+ A+ A+ A NO NO NO YES YES NO NO YES YES YES YES YES NO YES NO NO NO NO NO NO YES YES NO NO NO YES YES NO NO NO NO NO NO NO NO YES YES NO NO NO NO YES NO NO NO NO NO NO NO NO According to RD label Yes or No ENERGY CONSUMPTION (kWh/year) OUTER DIMENSIONS Height (mm) OUTER DIMENSIONS Widht (mm) OUTER DIMENSIONS Depth (mm)

PRODUCER

PRODUCT

TRADEMARK

Name of the company

Trademark

TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL
Category according to RD label fridge freezer **** Multidoors and others Multidoors and others Multidoors and others Multidoors and others fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** Fridge without stars Upright freezer fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** Fridge without stars Upright freezer fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** Fridge without stars fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** Multidoors and others Multidoors and others fridge freezer **** fridge freezer **** fridge freezer **** fridge freezer **** Upright freezer Fridge without stars fridge freezer **** fridge freezer **** fridge freezer **** Fridge without stars fridge freezer **** fridge freezer **** Fridge without stars

TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA THOR THOR THOR KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH KPPERSBUSCH
TS 450 INOX NF 650 INOX NF 620 INOX NFINOX NFINOX CB 340 S CB 375 NFNFNF 340 C VR 01 NF 450 INOX NF 380 INOX TSINOX TGF 270 INOX TSINOX CBFI 280 FT 240 FTFTNFNFE-320 TSE-342 TKI-145.1 D TGI-120.1 D NF 347 NF 340 D CBTSE 365 e-inox TSE 400 TS 136.3 VR01 CI 340 TFTFTFC 190 KE 590-I-2 T KE 580-I-2 T KE 370-I-2 T KE 360-I-2 T IKE 329-7 Z 3 IKEF 308-5 Z 3 ITE 239-0 IKE 339-0 IKE 308-6 T 2 IKE 318-5-2 T IKE 238-5 IKE 248-5 IKE 159-6 ITE 109-6 IKU 168-6
* You can consult any time you want the uptdated data base of our products at this link:http://www.idae.es
WASHING MACHINES DATA BASE
ENERGY CLASS ENERGY CONSUMPTION (kWh/cycle) WASHING EFFICIENCY SPINNING EFFICIENCY CAPACITY (kg) ENERGY CONSUMPTION (kWh/kg) WATER CONSUMPTION (l) OUTER DIMENSIONS Height (mm) OUTER DIMENSIONS Width (mm) OUTER DIMENSIONS Depth (mm)
Consumption used for the definition of energy class
PRODUCER A According to the label A A to G According to the label

SPINNING SPEED (rpm)

Washing machine Front load.

According to R.D. label

TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL
WASHING MACHINE F.L WASHING MACHINE F.L WASHING MACHINE F.L WASHING MACHINE F.L WASHING MACHINE F.L WASHING MACHINE F.L WASHING MACHINE F.L WASHING MACHINE F.L WASHING MACHINE F.L WASHING MACHINE F.L WASHING MACHINE F.L
TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA TEKA THOR KPPERSBUSCH
LIE LIE LIE TKE 1200 T TKX 1000 T TKX 800 T TKE 1260 S LI 1060 S LI 1260 S TLIW 1409.I

A A A A A A A A A A A

1,14 1,14 1,14 1,48 1,14 1,14 1,13 1,14 1,14 1,14 0,85

B C D B C D B B C C B

6 7,6 5
0,19 0,19 0,19 0,20 0,19 0,19 0,19 0,19 0,19 0,19 0,17

DISHWASHERS DATABASE

PLACE SETTINGS MODEL Model A According to the label A or B A to G Number of place settings ENERGY CLASS ENERGY CONSUMPTION WASHING DRYING (kWh/cycle) EFFICIENCY EFFICIENCY WATER CONSUMPTION (l) OUTER DIMENSIONS Height (mm) OUTER OUTER DIMENSIONS DIMENSIONS Width (mm) Depth (mm)

Dishwasher

TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL TEKA INDUSTRIAL

DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS DISHWASHERS
TEKA DWFI TEKA DWFI TEKA DWFI TEKA DWFI TEKA DWFI TEKA DWFI TEKA LP 800 S TEKA LP 760 TEKA DWS TEKA DWS TEKA LPTEKA LPTEKA LPTEKA LPTEKA LPTEKA LPTEKA LPVR 01 TEKA LPTHOR TLVTHOR TLVINOX THOR TLVTHOR TLVKPPERSBUSCH IGV 699.3 KPPERSBUSCH IGV 659.5 KPPERSBUSCH IGV 657.2 KPPERSBUSCH IGV 656.I KPPERSBUSCH IGVS 659.5 KPPERSBUSCH IGVS 657.2 KPPERSBUSCH IG 6508.I KPPERSBUSCH IG 657.3 KPPERSBUSCH IGS 644.1 KPPERSBUSCH IG 644.6 KPPERSBUSCH IG 634.5 KPPERSBUSCH IG 6504.0 KPPERSBUSCH IGV 459.I KPPERSBUSCH IGV 445.0 KPPERSBUSCH IG 459.6 KPPERSBUSCH IG 447.0
A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A A
1,05 1,05 1,05 1,05 1,01 0,81 1,05 1,05 1,05 1,01 1,05 1,05 1,05 1,05 1,05 1,01 1,10 1,10 0,81 1,05 1,05 1,05 0,90 1,05 1,05 1,05 1,05 1,05 1,05 1,05 1,05 1,05 1,05 1,05 0,8 0,8 0,8 0,8
A A A A A A A A A A A A A A B B A A B A B A A A A A A A A A A A A A A A A A
A A B A A A A B B A A A B B B B A A B B B A A A A A A A A A A A A A A B A B

820 818

448 446

570 570

Consume used for the definition of energy class

DRIERS DATABASE

ENERGY CLASS ENERGY CONSUMPTION (kWh/cycle) CAPACITY (kg) CONSUMO DE ENERGA (kWh/kg) OUTER DIMENSIONS Height (mm) OUTER DIMENSIONS Width (mm) OUTER DIMENSIONS Depth (mm)
PRODUCER A or B According to the label According to the label
Air evacuation drier Condenser drier

Model Comercial

WASHER DRIERS DATABASE
ENERGY CONSUMPTION (kWh/kg) (l) ENERGY CONSUMPTION (kWh) WASHING EFFICIENCY DRYING CAPACITY ENERGY CONSUMPTION WATER CONSUMPTION WASHING CAPACITY (kg) OUTER DIMENSIONS Height (mm) OUTER DIMENSIONS Width (mm) OUTER DIMENSIONS Depth (mm)
PRODUCER According to the label
(kWh) According to the label

TEKA INDUSTRIAL Conventional Conventional Conventional Fan traditional cooking Fan traditional cooking Conventional Conventional Fan traditional cooking Fan traditional cooking Fan traditional cooking Conventional Conventional Conventional Conventional Conventional Conventional Conventional Conventional Fan traditional cooking Fan traditional cooking Conventional Conventional Conventional Conventional Conventional Conventional Conventional Conventional Conventional Conventional Fan traditional cooking Fan traditional cooking Fan traditional cooking Fan traditional cooking Fan traditional cooking Fan traditional cooking Fan traditional cooking 562
HI-659 Fan traditional cooking 562

HI-75E

HI-585

HA-850

HA-890

HR-600ME

HR-600

HR-800ME

HR-800

HR-800E

HC-521ME

HI-521ME

HI-621

HI-625

HI-625 ME

HA-820

HA-830

HA-840

HA-850 C

HA-890 C

HC-560

HC-600

HI-560

HM-815

HM-815 ME

HA-845

HR-700

HI-609

HK-500
HK-700 KPPERSBUSCH EEB 6800.5
KPPERSBUSCH EEB 6600.5 KPPERSBUSCH EEB 6500.5

590 590

550 550
KPPERSBUSCH EEB 6450.5 KPPERSBUSCH EEB 6300.5
Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven Oven
KPPERSBUSCH EEB 6200.5 KPPERSBUSCH EEB 6150.5
Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium Medium
0,79 0,79 0,79 0,76 0,79 0,78 0,78 0,78 0,79 0,79 0,79 0,79 0,79 0,76 0,79 0,79 0,78 0,78 0,78 0,79 0,78 0,79 0,79 0,79 0,78 0,78 0,78 0,79 0,76 0,75 0,74 0,78 0,78 0,78 0,79 0,79 0,79 0,79
Energy efficiency begins at home with efficient appliances

March 2007

Business as usual is not sustainable
Potential of reducing CO2 emissions by 22 million tons per year
Significant improvements over the past 20+ years
The average washing machine today consumes 44% less energy and 62% less water compared to the average machine of 1985. Todays best refrigerator consumes only one fourth of a typical refrigerator from 1990.