DE3401524A1 - Energy-saving and environmentally friendly heating method - Google Patents

Abstract

The method is for the recovery of heat, preferably for heating purposes. No combustion process is necessary. Not heat, but work, is supplied to atmospheric air or another gas. Such a nearly adiabatic compression brings the air to both a higher pressure and a higher temperature. The increase in temperature serves for heat recovery. The pressure increase is utilised by a polytropic or approximately isothermal expansion machine. It recovers a large portion of the initially invested compression energy. Additional mechanical work can be recovered from a heat engine which diverts and converts a portion of the compression heat per se. In the most favourable embodiment of the machine system, the work to be used (compressor) is approximately equal to the recovered work (expansion machine and heat engine), so that the desired heat emerges from the process almost cost-free.

Description

Energy-saving and environmentally friendly heating bottom.

The invention relates to a new method of heating for the most diverse Buildings and purposes to produce. Apartments, homes, greenhouses, etc.

are supposed to be heated in a convenient, cheap and environmentally friendly way can be. Even desalination plants for seawater can be used with the one obtained in this way Never operate in an extremely energy-saving manner.

According to the current state of the art, apartments are heated and buildings still predominantly by simply burning fossil fuels. Every year there are multi-digit billions for imported mineral oil and natural gas is spent in valuable foreign exchange. Native coal is added to then afterwards to burn everything in millions of households.

I) these conventional Leiz methods, which have been known for a long time Combustion processes not only cause enormous foreign exchange losses today the state and high running costs for the homeowner, but also generate tremendous amounts of pollutants that get into the atmosphere and nature damage.

The use of nuclear energy to generate energy is also an issue unresolved environmental and disposal problems are increasingly facing resistance.

Alternative heating methods, such as solar cell roofs and heat collectors could not make a noteworthy contribution to the Saving primary energies. Especially in winter, when a lot of heating is needed is in Central Europe between latitudes the required solar irradiation far too weak and of too short a duration. Such a heating system then fails at night completely off.

Heat pump systems are also quite dubious in terms of their efficiency. Your energy savings are usually too insignificant for the high investment costs to justify such an investment.

The invention is now based on the task of a modern Iieizverfahren to create that 1. decisively helps to drastically reduce expensive energy imports reduce and save foreign currency, 2. cause far fewer costs for the citizen than before, to heat one's living space comfortably and adequately, 3. does not emit any pollutants and does not pollute the environment in any other way and 4. can be used anywhere, that the ideal goal could be striven for in its further technical development, To make buildings completely self-sufficient in terms of their energy supply.

According to the invention, this task is realized by a machine process, which works as follows: am adiabatic compressor compresses atmospheric Air, which means that compression work has to be applied first. The consequence of this What happens is that the air has both a higher pressure and a higher temperature accepts.

The resulting temperature can now drop in whole or in part a heat exchanger or radiator can be made usable for heating purposes.

Although the temperature of the air drops as a result of the heat dissipation, koninit there is no pressure drop here, as is usual with gases, according to the Gay-bussac rule Law.

Rather, it is a dynamic process in which the compressor constantly pushes in air at full pressure.

A subsequent expansion machine now uses the pressure gradient and recovers a large part of the compression work initially invested.

This machine should expand isothermally as possible because this The type of room change produces the greatest useful work. Depending on the - given - temperature conditions but it can also happen that the polytropic expansion has to be chosen.

The missing part of the work that is still needed for the machine process to keep going, must be applied by a third machine, for example can be a mains powered electric motor.

This electric motor consumes external energy and thus causes the actual operating costs of the entire process and heat recovery.

As a rule, however, the entire temperature gradient is that of the adiabatic Compressor generated, can not be fully used for heat generation. It offers therefore the possibility of this otherwise lost (poor, also machine to use.

There is also a steam engine in sight, but in most of them Cases not with water, but with working media with a lower boiling point, such as ammonia or Frigen will be operated. Like any other heat engine, can even they do not convert the entire amount of heat offered to them into useful mechanical work. According to its Oarnot1schen or thermal efficiency, it only uses one Part of it, while most of the rest is lost as waste heat.

Despite the low efficiency of the steam engine, it could they generate work together with the expansion machine = e: mr than from the compressor has been consumed. This would keep the machine process going without the need for an electric motor fed with external energy.

In practice, however, it is likely because of the inevitable mechanical and thermal losses cannot do without external energy input. The changes in space in the air can never be ideally adiabatic or isothermal realize.

What is certain, however, is that the ratio of energy used to energy gained Thermal energy is many times better than with today's heat pump systems.

With the described method for heat recovery will be safe Huge amounts of primary energy can be saved in the future. The pickling of buildings, apartments and greenhouses is again possible at low prices be. Damage to the environment is avoided entirely.

Three application examples of the invention are shown with drawings and are described in more detail below: Fig. 1: An adiabatic compressor (2) Sucks in atmospheric air with a temperature of -200C and a pressure of 1 b at (1). The compressor compresses so that the air leaves it at + 750C (3). With purely adiabatic compression, this results in a pressure of 3.05 b. The expended Machine work, consisting of room change work and pushing out work, is 95,380 Nm per kg of air (4).

The warm, compressed air now enters the Building (5) into the radiator (6) and leaves it wiecior with + 45 ° C (7). So it has cooled by 30 ° C, which is equivalent to a dew release of the radiator to the living space of 30,120 J per kb of air. Exactly this amount of heat is provided by the living space back to the environment through its insulation losses (9).

The air enters the expansion machine at + 45 ° C and 3.05 b (7) (io) a. If the expansion were adiabatic here, the initial values would be -41.8 ° E and 1 b.

Despite the cold outside air of -20 ° C is under these conditions at least a heat transfer to the expansion machine is still possible so that the expansion can run polytropically. The heat input from the atmosphere is 25,731 J. per kg of air, with a calculated polytropic exponent of 1.2579. As useful work (13) 90.991 Nm / kg are achieved. After the compressor work is 95.380 Nm / kg has, but the expansion machine has only recovered 90.991Nm / kg, the the missing 4,390 Nm / kg from another machine contributed. will. In practice it will be a mains-powered electric motor, which is not shown here.

If one assumes that with an outside temperature of 2000 the building has a Has a heat demand - expressed in output - of 20 kW, then 0.664 per second kg of air are passed through. The compressor therefore needs drive power of 63.33 kW, the polytropical expansion machine has an output of 60.42 kW and the additional motor must raise the difference of 2.91 kW.

In this example, 2.91 kW must be used for 2G kW heat output can be taken from the lighting network, which corresponds to a utilization ratio of 1: 6.9.

Fig. 2: In this application example, a variant is wrote, which does not have a radiator. Like an air conditioning system, the heating air is direct blown into the building.

The compressed, heated air must have a pressure of exactly here 1 b. This in turn means that the adiabatic compressor (15) from the Must suck vacuum area in order to generate the required pressure ratio. Assuming an outside temperature of -20 ° C, as in the previous example, in the suction line (14) has a pressure of 0.562 b when at the compressor outlet (16) 1 b should be reached at + 250C. The compressor work (17) is 45,180 Nm / kg. After leaving the building (18) the air has reached + 15 ° C at 1 b (19) cooled down. This means that a heat quantity of 10,040 J / kg has been given off to the building (20).

The subsequent polytropic expansion (21) of + 15 ° C / 1 b -20 ° C / 0.562 b requires a heat absorption from the environment of 9,256 J / kg (22). The work gained is 44,396 Nm / kg (23).

In terms of power, only 1.56 kW are missing, which is the electric motor must add. With 20 kW gained heat output, it corresponds to a utilization ratio from 1: 12.8.

Fig. 3: This third application example follows on from the first, where but a steam engine provides additional useful work.

Atmospheric air, also at -20 ° C / 1 b (24), becomes adiabatic compressed (25) so that it warms up to + 115 ° C, whereby it has a pressure of 4.46 b assumes (26). The work required is 135,540 Nm / kg (27).

Before the air is now fed to the radiator (31) of the building (30) is, it flows through the superheater of the steam engine (28) and there part of their heat, as a result of which the temperature drops to + 75 ° C (29).

The release of 30,120 J / kg of heat (32) to the building (30) and its passing on to the environment (33) causes a further decrease in temperature, up to + 45 ° C (34).

After subtracting the amount of heating energy, the steam power machine (35) over a heat quantity of 105,420 J / kg (36).

To calculate the thermal efficiency, however, the entire Temperature gradient of + 115 ° C, down to the outside temperature of -20 ° C in the calculation can be used. The result is 34.78. Thus 36,665 J heat becomes 36,665 Nm work (37). The rest of 68,755 J is lost as waste heat. These numbers too are based on an air throughput of 1 kg.

The expansion machine (40) must relax isothermally here because the Air enters at -200C / 1 b (39) and therefore its temperature is the same as that of the outside air is.

The heat absorbed from the environment (41) of 108,632 J / kg corresponds with isothermal expansion quantitatively precisely with the work gained (42) 108,632 Nm / kg.

The air exits at atmospheric conditions at -20 ° C / 1 b the machine from (43).

If one now adds the work gained to the steam engine 36,655 Nm / kg and that of the expansion machine to 108,632 Nm / kg, this results together 145,297 m / kg.

The compressor consumed 135,540 Nm / kg, so here even gives a surplus of useful work of 9,757 Nm / kg.

Expressed in power, with 20 kW of heating power gained, an additional 6.48 kW mechanical useful power gained. The correctness of this result proves that Energy balance. The sum of the energies entering (27), (41) is identical to the sum of the emerging energies (53), (37), (38), (42): 27: 135,540 Nm / kg 33: 30,120 J / kg 41: 108,632 J / kg 37: 36,665 Nm / kg 38: 68,755 J / kg 42: 108,632 Nm / kg 244,172 J or Nm / kg 244,172 J or Nm / kg total / input total / output 1 J = 1 Nm = 1 Ws. Three exemplary embodiments were based on ideal machines and ideal heat transfers. In reality comes But there is always heat loss, which, however, is largely due to skillful reconstruction the machine process or the heating can benefit. Even the mechanical ones Losses such as friction or eddies in the air flow ultimately turn into heat over and don't have to be lost.

Despite these considerations, one will in practice of the indicated Calculation examples have to make some compromises. But it still appears in the Area of the possible to lie that one after the heating method according to the invention, Heat could be obtained almost free of charge. The technical advancement of the machine system will be of great importance in this.

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Claims (1)

P A T E N T A N S P R Ü C H E: 1. Machine system and process for energy-saving and environmentally friendly generation of heat, d a d u r c h g It is not clear that this heat is generated when a gas is compressed and the compression work to be applied for this by a subsequent one Expansion machine is largely recovered. 2. Machine system and method according to claim 1, d a d u r c h g I do not know that a heat engine or a thermocouple battery recovers more work by taking some of the heat of compression to itself branches off and recycled. 9. Machine system and method according to claim 1, d a d u r c h g It is not noted that the gas used is tuft from the atmosphere.