DE2916530A1 - METHOD AND DEVICE FOR GENERATING AND DISTRIBUTING THERMAL ENERGY WITH COMPENSATION TRANSFER IN GEOTHERMAL LAYERS - Google Patents

Description

Process and device for the generation and distribution of thermal energy with compensation relocation in geothermal layers -

It is common to use low temperature thermal energy for cooling or space heating purposes by using thermal pumps to increase the either refrigeration - then it is a question of refrigeration compressors - or heat - then it is heat pumps or, even better, deliver both at the same time - then you have cold-heat pumps.

It is known that the coefficient of performance of a pump is that the ratio between the usable thermal power and the consumed electrical power is higher than the Difference between the two temperatures of the heat source and the cold source are smaller and you can use it if possible of the heat and cold energies given off by the condenser or evaporator of the pump.

In practice, thermal pumps only use one of these. Energies, be it in heating systems, where the thermal Exploits primary energy supplied by geothermal layers, solar panels or the ambient air, be it that it is a refrigeration system where the primary energy is taken from a cooling medium, e.g. air or water.

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There are few systems that use the heating energy and the cooling energy that are given off by the pump at the same time, because it seldom happens that the heating and cooling requirements are the same, and even when this is the case, the greatest heating requirement occurs in the cold season, while the greatest need for cooling falls in the summer, so that additional cooling systems are necessary to be provided in order to dissipate the excess heat energy of the condenser during the hot season.

If it is about the transmission of solar energy, the heat must be stored for a fairly long period of time, which is usually done in artificial ones near the ground Saving does. This requires large storage volumes that are expensive to produce, the heat return efficiency of which is all the worse. the longer the storage lasts, because as the ambient temperature is generally lower than that of the stored medium, the peripheral losses are very significant.

In addition, because of the size of the storage volume and the surface the solar collectors, which are normally designed for weak sunlight in winter, are such a heating system only serve subordinate purposes, for which the cooling requirement is generally negligible.

In heating systems with geothermal transmission one has so far the geothermal energy has been used like fossil energy, so that

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in order to avoid a significant weakening of the thermal potential of the layers, the exploitation must be limited, which, by itself if it is profitable, it can only meet the peripheral needs of densely populated areas.

In contrast, an installation according to the present invention, e.g. a city district heating and cooling system with compensation shifting into geothermal, preferably lukewarm, layers, as will be seen, through an extensive distribution of thermal Production that satisfies both the needs of the heat consumers and those of the cold consumers scattered across the metropolitan area; by exploiting a geothermal layer in their area Temperature equilibrium, in that one in the hot season by supplying heat that took place in the cold season Heat draw off is compensated by the optimal utilization over a longer period, e.g. one year, of the energy sources, for example of solar panels together with the recovery of the thermal energy of the pumps and the compensation of the distributed Cooling energy have an extraordinarily high degree of efficiency, both from an energy point of view because of the high Pump efficiency through simultaneous supply of heat and cold, as well as from an economic point of view through the Optimization of investment costs, especially those for high-performance pumps, solar collectors with maximum recovery the solar energy obtained annually, that for the exploitation of geothermal energy because of its intensive character as well as because of their extensive possibilities within a metropolitan area, whereby both the one and the other to the

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thermal reconstruction of the layer are bound.

The invention relates to a cyclic heat exchange process between a heat dispersal circuit and a heat recovery circuit (or cold distribution circuit). This The method is characterized by the fact that a heat exchange circuit is provided with a heat distribution and recovery circuit, as well as a natural lukewarm geothermal layer is connected to that the heat vertexification cycle takes a certain amount of heat from the shift during part of the annual cycle, which is at most a temperature drop by a few degrees compared to the natural state of thermal equilibrium and that of the shift in the course of the same annual cycle roughly again through the heat recovery cycle is supplied so that at the end of the cycle the temperature is again at its starting value at the beginning of the cycle.

In order to get the submitted! and regained energies To balance, a transfer circuit is provided which connects the heat dewatering circuit directly to the recovery circuit connects to supply the available energy in the recovery cycle to the distribution cycle.

In other words: according to the invention there is a cyclical, thermal Exchange procedure planned between:

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1. a transmission circuit, the two energy distribution circuits charged, one with warmth, the other with cold,

2. at least one external heat source,

3. a geothermal cycle that works with a natural Layer is connected,

and this procedure is characterized by:

- the fact above all that the balance between the

from the transfer circuit to the heat or cold distribution circuit The energy given off is obtained through an exchange between the group of these three cycles and the geothermal Circulation; '

- in the second place by the fact that the external heat sources Supply the geothermal cycle with an amount of heat that, from one annual cycle to the next, roughly covers the layer keep the same energy level.

The procedure is designed to keep the energy needs low Levels (heating and cooling) in residential areas.

At a given point in time, the following sequence is given:

1. There is not enough heat available to meet the demand of the heat distribution cycle, i.e. if the

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νοη external and internal sources (e.g. heat equivalents of mechanical energy from pumps and motors) are lower than the need for the heat distribution circuit, so the geothermal layer provides the balance.

2. There is an excess of heat compared to the demand of the heat distribution circuit, so the geothermal absorbs Layer the excess.

In the course of a cyclical period, roughly the same amount of heat is supplied to the layer as is drawn off (e.g. in the Within a year).

The natural temperature equilibrium should favorably of the underground layer are around 30 ° C, which corresponds to a layer at medium depth.

According to the invention, the devices for thermal production and distribution are preferably:

- First and foremost, the thermal transfer circuit with at least one transfer pump, of which at least one condenser runs the heat distribution circuit and at least one Evaporator supplies the cold distribution circuit,

- in the second line, at least one geothermal circuit with at least one extraction well and at least one return well into the geothermal layer, whereby the water of the geo-

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thermal cycle in one and / or the other thermal Exchange system circulates, one of which is connected to the heat distribution circuit and the other is connected to the refrigeration distribution circuit,

- in the third line, a line system with short-circuit options and / or pumps with variable delivery rates, which facilitate the thermal exchange between the geothermal circuit and the heat and regulate cold distribution circuits,

- in the fourth line, at least one recovery circuit that collects the waste heat from external heat sources and from them each with at least one of the aforementioned circuits, i.e. the geothermal, the heat and the cold distribution circuit, is connected by at least one thermal exchanger,

- in the fifth line, at least one line system with the possibility of short-circuiting and / or variable flow pump for regulating the thermal exchange between the recovery circuit and at least one of the three aforementioned cycles,

- in the sixth line, a control system for the entire plant.

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The control of each system according to the invention becomes progressive performed by measuring the flow rates of thermogenic media each Transfer pump, the short circuit lines and / or the circulation pumps influenced thereby to achieve an economically optimal distribution of the thermal energy, which the heat distribution, must be fed to the cold distribution and geothermal circuit.

The entirety of the heat recovery system from external sources is designed as optimally as possible, so during a natural Cycle, the geothermal layer is supplied with an amount of energy that corresponds to that withdrawn, so that the average temperature of the layer is kept in equilibrium. The protection The present invention also relates to the combination of the individual claims with one another and not only to the subject matter of the respective claim. To the method and the devices according to the invention to represent clearly and to show how the thermal exchange between the individual circuits and the control system, the following is a non-exclusive example of the application in an urban heating system. and refrigeration and distribution systems. This system, shown schematically in the single figure, consists of:

- a thermal exchange circuit A,

- a geothermal circuit B,

- a heat distribution circuit C,

- a refrigeration distribution circuit D,

- a solar collector circuit E,

- a circuit for the recovery of industrial waste heat F.

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Exchange circuit A: a compressor 1 conveys a thermogenic medium (eg ammonia) to the condenser 2, which gives off the heat of condensation to the heat distribution circuit C; the medium then flows through a throttle 3 and reaches the evaporator 4, where the cold distribution circuit supplies the heat of evaporation. As a variant, a plurality of exchange circuits with several exchange stages, each of which has its compressor with variable flow rates, its evaporator, its throttle and its condenser, can be used, whereby a higher performance value is achieved.

Geothermal circuit B: a conveying well 5 supplies hot water to the return well 6. This water first flows through the heat exchanger 7 of the heat distribution circuit C, then the heat exchanger 8 of the circuit for recovering industrial waste heat F, and finally the heat exchanger 9 of the cold distribution circuit D.

The exchange between the three circuits is done with short-circuit lines regulated, with which certain circuits can be separated if the exchange conditions are unfavorable.

Notwithstanding this, the circuit B can consist of several parallel geothermal circles exist, the total delivery of which is designed so that with the layer either the maximum amount of heat

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or the ma.χ. Amount of cold can be exchanged without the Temperature fluctuations of the thermal water exceed the limits of the distribution temperature of heating water and cooling water (e.g. 48 ° C and 12 ° C). In addition, the heat output of the thermal water can be optimally adapted by controlling the delivery rate, in that only some of the delivery and return pumps are operated, which reduces the consumption of electrical Energy is restricted.

Heat distributor circuit C:

The warm distribution water leaves the condenser 2 at a sufficiently high temperature (eg 48 ^° C.) for the sanitary requirements and the operation of building heating systems with a low flow temperature.

The distribution water is supplied by circulation pumps, e.g. 1o Heating elements, e.g. 11 promoted, their heat dissipation through Regulating elements, e.g. 12 is regulated.

For the sanitary needs, distribution water is supplied directly to the sanitary appliances e.g. 12, its pressure and delivery being ensured by the municipal water supply (see below).

After outflow from the consumers, the distribution water first flows through the heat exchanger 14 of the circuit for the recovery of industrial waste heat. then, at heat

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Demand peaks via the three-way valve 15 through the buffer 16 which is provided to reduce the peaks. A pressure switch 17 controls refilling with tap water via the slide 18.

On the other hand, the warm distribution water is fed through the three-way valve fed to the heat exchanger 7 in the following two cases: a) - if its inlet temperature in 7 is lower than that of the thermal water coming from the shaft 6 is: the heat exchanger thus preheats the distribution water and thereby relieves the influence of the exchange cycle A,

b) - if the difference between the thermal powers required by the two distribution circuits C and D causes heating of the geothermal circuit B requires.

Refrigerant distributor circuit D: cold water (eg 12 ° C) flows out of the evaporator 4, the temperature should preferably be chosen such that it corresponds to the cooling water requirements of air conditioning and food refrigeration and for freezing plants (with, for example - 18 ⁰ C) serve as a source of hot water can which could almost double their performance.

Circulation pumps such as 2o distribute cold water to cooling elements, such as 21, the regulation of which is carried out with slides such as 22 will"

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The cold water supplies chilled water directly to consumers, such as 23, with its printing and delivery being ensured by the municipal waterworks (see below).

The cold water is pumped through a number of circulating pumps, such as 24, heat exchangers such as 25, which work with the solar collector circuit E. In general several solar collector ice runs, such as E, are provided.

The cold distribution water is refluxed first Via the heat exchanger 35 with the circuit for recovering industrial waste heat F and then the three-way valve enables 36, in the event of thermal demand peaks, to pass it through the cold buffer 32, which is provided to reduce the peaks. A pressure switch 33 controls the refilling with tap water via the slide 34.

If the difference is the required by the two distribution circuits thermal power requires cooling of the geothermal circuit, the three-way valve 37 allows the cold distribution water through the heat exchanger 9 with the geothermal circuit B lead.

Solar collector circuit E: The solar energy captured by the solar collector circuit E has a significant influence on the annual restoration of the potential of the geothermal layer, because the industrially recoverable amount of heat is often only that which results from waste incineration and which represents only a small part of the total requirement.

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According to the invention, the circuit E, in this particular one, is not exclusive arrangement, coupled with the Kälteverteilerkrexslauf D. By this arrangement, in which that in the solar panels circulated medium (e.g. water with antifreeze) is quite cold, it is possible to cover the total area of the solar panels to be reduced, since the energy that can be used annually increases rapidly as the mean temperature drops.

The use of an antifreeze makes it necessary to connect circuit E to circuit D via an exchanger system associate.

The non-freezing medium, in the example in the figure, is closed by a circulating pump 26 when it exits the heat exchanger 25 the solar collectors 28, the delivery rate being controlled via the slide 27 as a function of the solar radiation.

When exiting 28, a slide 29 allows an exchanger 3o supplied amount to regulate with which the power peaks are reduced that the circuit D cannot absorb directly. For this purpose, the secondary water, the 3o, is from the circulation pump 31 promoted, flowed through, fed to the cold buffer 32, the role of which is to reduce power peaks, both of come from the solar collectors as well as from the cold distribution circuit. The energy stored in this way is later used again by the cold distribution circuit Pfunter the regulating effect of the three-way cock 36 added.

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The inventive system contains a certain number of Solar collector circuits created by the installation options is determined.

Circuit for the recovery of industrial waste heat F; The outflow from the heat dispenser 38 flows, conveyed by the circulating pump 39, past the exchangers 14 with the circuit C, 8 with the circuit B and 35 with the circuit D in succession. Three three-way cocks, 4o for exchanger 14, 41, for 8 and 42 for 35 allow the waste heat circuit to be connected to these heat exchangers only when the conditions are favorable. Tap 4o will keep circuit F separated from circuit C when it does not require any additional heat, for example in summer when the waste heat temperature is lower than that of the warm water flowing back. Tap 41 will keep circuit F separated from circuit B when it does not need to be heated or when the temperature of the waste heat is lower than that of the thermal water in exchanger 8. Hahn 42 will keep the circuit F separated from the circuit D when this can no longer accept additional heat, for example in the case of strong sunlight.

In order to optimize the function of the system at the nominal distribution ^{temperature of the heat (e.g. 48 0} C) and the cold (e.g. 12 ° C), it is necessary:

- balance the two thermal outputs that are emitted by the exchange circuit to their minimum values,

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- the electrical power and the delivery rates of the heat pumps, of the various circulation pumps of circuits C, D, E and F and the feed and return pumps of circuit B to be optimally used.

This optimal sequence is controlled by a process computer, not shown, in which, for example, the following main ones Enter parameters:

- outside temperature,

- return temperature before the exchangers 7,9,14,35,

- flow temperature of condenser 2 and evaporator 4,

- inlet temperature of the thermal water to exchangers 8 and 9,

- inlet temperature of the industrial waste heat upstream of the exchangers 14, 8 and 35,

- Inlet temperature of the non-freezing medium to the solar collectors 28,

- Flow rates of circuits C, D, E and F.

The computer sends control commands to servomechanisms (not shown here) that regulate the following settings:

- Three-way cocks 19 and 37 around the thermal equilibrium of the To maintain heat balance in circuit A,

- Flow rate of the compressor 1 adapted to that through the circuit A thermal power to be transmitted,

- Three-way cocks 4o, 41 and 42 for the exchange between the To regulate circuit F and circuits C, B and D,

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- Circulation pumps, like 1o for regulating the flow

in circuit C and like 2o and 24 for that of circuit D,

- Three-way cocks 15 and 36 for the storage and delivery of thermal power peaks,

- Circulation pumps such as 26 and 31 and three-way taps such as 27 and for the transfer of the energy obtained by the solar panels Energy,

- Sliders, like 12 and 22, which the heat 11 and cold consumers control by changing the flow rate as a function of the power requirement.

The economic importance of a system according to the invention is extremely great, because:

1. The transmissions of circuit A take place with a very high coefficient of performance. You can, for example, at a maximum temperature of the heat source of 49 ⁰ C and a minimum temperature of the cold source of 11 ⁰ C and a geothermal layer from which water of 30 ° C is taken, by optimizing the flow rates of the geothermal circuit and the two distribution circuits for heat and cold Achieve return temperatures to the condenser and evaporator systems in the order of 30 ° C. One could, for example, with a group of 4Wärmepumpenstufen, the 4 parallel elementary circuits between the circuits C and D feed, these pumps operate with temperature differences between the heat and the cold source, which are approximately 14,23,31 and 38 ⁰ C. The coefficient of performance for the whole

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Circuit would be about 1o for the heat transfer and for the Cold displacement is about 9, while the coefficient of performance with balanced mixed operation (heat-cold pump) could even increase to 19.

2. The total electrical power consumed by the heat pumps Performance is minimal because of:

the high coefficient of performance,

the absorption of thermal power peaks by the buffers.

3. The area of the solar panels is minimal because of:

- their operation at a low average temperature (e.g. 18 ° C),

- the maximum annual utilization of solar energy.

The areas required for a given total amount of energy are about 1o χ smaller than those required when the Areas after the winter sun exposure and for operation at the usual average temperature (of e.g. 40 ° C) would interpret.

4. The well systems for the utilization of the lukewarm thermal water, as used advantageously according to the invention with the same usable amount of heat given off cost about half of those for hot thermal water, which is usually used with heat pumps.

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5. Lukewarm layers abound in sedimentary layers and their intensive and extensive exploitation is possible thanks to the heat recovery. By preserving her thermal energy potential, its use on a large scale for urban heating and cooling is conceivable.

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Claims (11)

Beireff: Applicant: Jacques Louis Marie Henri LENOIR, 1o, rue Mansart, 78ooo Versailles / France Patent claims 1.] Cyclical, thermal exchange process between one Heat distribution circuit and a heat recovery circuit, characterized in that a thermal Exchange circuit with the heat distribution and recovery circuits and cooperates with a naturally lukewarm geothermal layer that in the course of a part of the annual cycle, the heat distribution circuit draws an amount of heat from the shift that reduces the shift temperature caused by only a few degrees compared to the natural temperature equilibrium and that by the heat recovery circuit in In the course of the same annual cycle, approximately the same amount of heat is returned to the shift, so that at the end of the cycle the Layer temperature essentially back to the initial value Telephone: Lindau (08382) 6917 Telegraph: Office hours: Bank accounts: 05 4374 by arrangement Bayer. Vereinsbank Lindau (B) No. 120 8578 (BLZ 735 200 74) Postal checking account: Munich 295 25-809 291653Ü -2- the start of the cycle comes back. 2. The method according to claim 1, characterized characterized in that the heat distribution circuit and the heat recovery circuit via an exchange circuit are connected to each other, which is suitable to extract available energy from the recovery cycle and they to be transferred to the distribution circuit. 3. The method according to claims 1 and 2, characterized characterized in that the geothermal layer has a natural temperature equilibrium at about 30 ° C. 4. The method according to any one of claims 1-3, characterized in that the heat recovery circuit and / or has an industrial waste heat recovery circuit. 5. The method according to any one of claims 1-4, characterized characterized in that the circulation of the medium of the heat exchange circuit is influenced to an optimum Distribution of the thermal power to be supplied to the distribution circuit and to be withdrawn from the recovery circuit to ensure. 6. Plant for heat generation and distribution, which has a heat distribution - and comprises a heat recovery circuit, characterized in that it comprises a thermal Contains exchange circuit, which with heat distribution and 9098U / 0 <UÖ -3- - recovery cycles, as well as with a natural lukewarm geothermal layer and that the heat recovery cycle is suitable, via an exchange cycle, in the course of an annual cycle, the shift is about the same To re-supply the amount of heat that was withdrawn in the course of the cycle in order to feed the heat distribution circuit. 7. Plant according to claim 7, characterized marked is that it contains an exchange circuit through which the heat distribution and heat recovery circuit are connected to each other and which is suitable for extracting available energy from the recovery cycle and feed them into the distribution circuit » 8. Plant according to claims 6 and 7, characterized characterized in that the heat recovery circuit and / or a recovery circuit for industrial Has waste heat. 9. System according to claims 6-8, thereby characterized in that the thermal exchange cycle Branches with three-way taps (slide) and / or pumps with variable flow rate possesses to the control the thermal exchange between the distribution circuit, the recovery circuit and the naturally lukewarm Layer to ensure. 291653Ü 10. Plant according to one of claims 6-9, characterized characterized in that it has buffer tanks interposed in the heat distribution and recovery circuit, to absorb the peaks of thermal power distributed or recovered. 11. Plant according to one of claims 6-1o, characterized in that the heat recovery circuit comprises a cooling system. -5- fi098U / 09A9