RU2362946C2 - Method and device for energy regeneration - Google Patents

Abstract

FIELD: technological processes. ^ SUBSTANCE: method and device are intended for energy regeneration. Method of energy regeneration in air conditioning and ventilation equipment sets, comprising device for direction of volume flow of plenum air, device for direction of exhaust air volume flow and system of heat regeneration, includes the following stages: exchange of heat energy in volume flow of exhaust air coming out of heat regeneration system by means of the first heat exchanger connected to heat pump; transfer of exchanged heat energy by means of heat pump and the second heat exchanger connected to heat pump to accumulation circuit, which is connected to heat exchanger for heat energy transfer and comprises energy accumulator; transfer of heat energy sent to accumulation circuit by means of the third heat exchanger to volume flow of plenum air coming out of heat regeneration system with the purpose to cool or heat volume flow of plenum air; control of portion of transferred heat energy in heat exchanger, given to volume flow of plenum air, by control of circulating fluid amount contained in accumulation circuit, passing through energy accumulator and heat exchanger. ^ EFFECT: higher coefficient of heat return. ^ 25 cl, 4 dwg

Description

The invention relates to a method for energy recovery in installations of air conditioning and ventilation and to a device for energy recovery in installations of air conditioning and ventilation.

Heat recovery systems, installations with recuperative and regenerative heat transmitters, as well as installations with an intermediate medium or heat pumps are used in air conditioning and ventilation techniques to recover energy from exhaust or exhaust air.

Heat recovery systems are repeatedly described in the literature. Such systems are known in the art of ventilation and are widely used. With their help, according to the literature, the so-called heat recovery factors of up to 0.8 are achieved.

In the publication „Recknagel, Sprenger, Schramek; Taschenbuch für Heizung + Klimatechnik 01/02, Ausgabe 2001, Oldenbourg Industrieverlag München "on page 1367 and further describes various methods of heat recovery. This also includes a heat pump system.

Other indications of heat recovery systems in ventilation installations can be found in Handbuch der Klimatechnik, 3. Auflage, Verlag C.F. Müller GmbH, Karlsruhe, Band 2; Berechnung und Regelung "on p. 115 ff.

In traditional heat recovery systems that use different designs of heat exchangers, the heat output decreases linearly with the temperature difference between the exhaust air supplied by the ventilation unit and the outside air supplied by the ventilation unit. If, therefore, in the case of heating, the outdoor temperature rises, then the temperature difference between the outdoor air and the exhaust ventilation unit discharged by the exhaust air volume decreases. Less energy is taken from the volumetric flow of exhaust air and less energy is given to the outside air supplied as a volumetric flow of the supply air. Outside air must therefore be preheated with a heater.

In the case of cooling of the exhaust air volume flow from the extract air for the same reason, i.e. due to a drop in outdoor temperature, only a fraction of the energy can be taken.

Outside air must therefore be preheated by a heater in case of heating or further cooled by a cooler in case of cooling.

It is also known to cool by a built-in cooling device after a heat exchanger or by heating with a heat pump located after the heat pipe. Both of these systems can only be regulated conditionally, for example, by means of stepwise switching on, connecting and disconnecting, or by means of compressors with variable speed. Cooling is sometimes adapted with the help of bypass regulation of hot gas. This method, due to the associated energy consumption, is used less and less.

Sliding control over the entire range of different outdoor temperatures is not possible with any of the systems without reducing the so-called power factor. The variable volume flows, which are increasingly used in modern air conditioning systems, cannot be cooled or heated by the above systems.

With the help of previously known systems, switching from the cooling mode to the heating mode and vice versa is regulated inefficiently or only with worse efficiency. through mixing air.

From DE 9218937 U1, an indoor air conditioning device is known. This device contains a regenerative heat transfer between the volume flows of the supply and exhaust air. Behind the heat transmitter is the heat pump evaporator. An additional regenerative heat transfer unit and a heat pump condenser are located in the volume flow of exhaust air. In order to increase the energy output, a second external air stream is provided in parallel with the outdoor air flow supplying the building premises. The evaporator and condenser of the heat pump are located in a correspondingly different external air stream, so that energy can be transferred from the first external air stream to the second external air stream through the heat pump.

Further, air conditioning is known from DE 19500527 A1. This air conditioner has a volumetric flow of supply and exhaust air, both directed through a heat exchanger. An evaporator is located behind the heat exchanger in the supply air volume flow, and the heat pump condenser in the exhaust air volume flow. A heat pump provides optimal energy recovery in only one specific application. It depends on the calculation of the power of the heat pump.

Finally, from DE 1985 1889 A1, a heat pump air conditioning unit with energy recovery is known. In the air conditioning unit, the supply and exhaust air is routed through a common heat exchanger. In the supply air behind the heat exchanger there is an additional heat exchanger connected in the first coupling circuit to the hot water accumulator. The hot water accumulator is connected in the second coupling circuit to the heat pump condenser. The heat pump evaporator can be loaded with a partial stream of exhaust air. Another part of the exhaust air is sent through a heat exchanger, and another smaller part of the exhaust air is mixed with the supply air. The air conditioning installation is complex, poorly regulated and requires an additional cooling unit for cooling, which must be included in the supply air circuit through an additional heat exchanger.

From the described prior art, a conventional ventilation installation requires significant additional equipment for heating or additional cooling of the resulting volumetric flow of supply air.

The technical result of this invention is a significant increase in heat recovery with good adjustability.

The technical result of the present invention is achieved in a method of energy recovery in air conditioning and ventilation equipment comprising a device for directing a volumetric flow of supply air and a device for directing a volumetric flow of exhaust air, optionally a heat recovery system connecting volumetric flows of supply and exhaust air for heat transfer between volumetric flows supply exhaust air and consisting of one or more heat exchangers, and / or heat pump, to which for additional energy transfer is located between the volumetric flow of the supply air and the volumetric flow of exhaust air and / or is attached to the heat recovery system between the volumetric flow of the supply air and the volumetric flow of exhaust air and is connected to the volumetric flow of the supply air and / or the volumetric flow of exhaust air through heat exchangers, in that it includes the following steps:

- exchange of thermal energy in the volume flow of exhaust air leaving the heat recovery system by means of a first heat exchanger connected to the heat pump;

- transfer of the exchanged heat energy by means of a heat pump and a second heat exchanger connected to the heat pump to a storage circuit, which is connected to the heat exchanger to transmit heat energy and contains an energy accumulator;

- transfer of heat energy transferred to the storage circuit by means of a third heat exchanger to the supply air volume flow leaving the heat recovery system for cooling or heating the supply air volume flow;

- regulation of the fraction of transferred thermal energy in the heat exchanger attached to the volumetric flow of the supply air by controlling the amount of circulating liquid contained in the storage circuit flowing through the energy accumulator and the heat exchanger.

Preferred in the method is that it includes the following steps:

- selection of thermal energy from the volume flow of exhaust air leaving the heat recovery system through a heat exchanger connected to the heat pump;

- transferring at least a portion of the selected energy by means of a heat pump and a heat exchanger included in the storage circuit to the storage circuit or energy accumulator;

- transfer of energy transferred from the volumetric flow of exhaust air to the storage circuit by means of a heat exchanger in order to heat the volumetric flow of supply air leaving the heat recovery system.

Also preferred in the method is that it includes the following steps:

- selection of heat energy from the heat recovery volume stream of the supply air leaving the heat recovery system (10) in order to cool the volume flow of the supply air through a heat exchanger (1) connected to the storage circuit (9);

- selection of at least a portion of the selected heat energy by means of a heat pump (3) and a heat exchanger (4) included in the storage circuit (9) from the storage circuit (9);

- transfer of heat energy taken from the storage circuit (9) by means of a heat pump (3) and a heat exchanger (2) to the volume flow of exhaust air leaving the heat recovery system (10).

It is advisable that it includes the following steps:

- selection of thermal energy from the volume flow of exhaust air leaving the heat recovery system for adiabatic cooling of the volume flow of exhaust air;

- supply of a cooled volume flow of exhaust air to the heat exchanger in order to transfer the heat energy taken from the storage circuit to the cooled volume flow of exhaust air.

It is also advisable that it includes the following steps:

- supply of thermal energy to the supply air volume flow connected to the heat exchanger circuit with the aim of additional heating to control the humidity of the cooled supply air volume flow by means of an additional heat exchanger mainly associated with the hot gas circuit of the heat pump;

- supply of a heated volume stream of supply air to an air-conditioned room.

The advantage is that the regulation of the variable volumetric flow of exhaust air and / or the volumetric flow of supply air is carried out in the following steps:

- exchange of thermal energy in the volume flow of exhaust air leaving the heat recovery system by means of a heat exchanger with an additional storage circuit containing an additional energy accumulator;

- transferring at least a portion of the exchanged thermal energy by means of a fourth heat exchanger connected to the heat pump and a heat pump from the additional storage circuit through a heat exchanger connected to the first storage circuit containing the energy storage battery to the first storage circuit;

- transferring at least a portion of the heat energy transferred to the first storage circuit by means of a heat exchanger to the volume flow of the supply air leaving the heat recovery system.

It is also an advantage that the fraction of the transferred heat energy in the heat exchanger attached to the volume flow of exhaust air is controlled by controlling the amount of circulating liquid contained in the storage circuit flowing through the energy accumulator and the heat exchanger.

In addition, the advantage is that the energy is transferred by means of a heat pump between the volumetric flow of the supply air and the volumetric flow of exhaust air without using a heat recovery system.

The technical result of this invention is achieved in an energy recovery device in an air conditioning and ventilation installation with a supply air volumetric flow and an exhaust air volume flow, which optionally contains a heat recovery system connecting the supply air volume flow and the exhaust air volume flow for heat transfer between the supply air volume flow and a volume flow of exhaust air that contains a regenerative heat exchanger, or regenerative heat exchange a heat exchanger, or heat accumulator, or heat pipe, and a heat pump, which is attached to a heat recovery system to transfer energy to a volumetric supply air stream or a volumetric exhaust stream, and is connected to a volumetric supply air flow and / or a volumetric exhaust air flow through heat exchangers, or a heat pump, which, without an additional heat recovery system through heat exchangers, is connected to the supply air volume flow and / or the exhaust air volume flow xa, and a storage circuit with an energy accumulator, a heat exchanger located in the volumetric flow of exhaust air and a heat pump, and the heat pump through the second heat exchanger connected to the storage circuit, in that the storage circuit is located between the heat pump and the heat exchanger located in the supply air volumetric flow after the heat recovery system, and a device is provided for controlling the transfer of thermal energy in the storage circuit between the heat pump and the heat exchange Energy storage device and / or heat exchanger.

Preferred in the device is that it contains a heat exchanger located in the volume flow of exhaust air and connected to the heat pump, a storage circuit connected to the heat pump through a second heat exchanger, an energy accumulator included in the storage circuit, a heat exchanger connected to the storage circuit and located in the volume flow of the supply air, and a device for controlling the temperature of the volume flow of the supply air, which controls the flow of circulating liquid spine in the storage circuit through the heat exchanger and the energy accumulator.

It is also preferable in the device that the first heat exchanger is made in the form of an evaporator or condenser of a heat pump.

It is advisable that the second heat exchanger is made in the form of an evaporator or condenser of a heat pump.

It is also advisable that the device contains an additional storage circuit connected through an additional heat exchanger to the heat pump, an additional energy accumulator included in the additional storage circuit and a device for controlling the transfer of thermal energy to the volume flow of exhaust air, which controls the flow of circulating fluid in the additional storage circuit through a heat exchanger and an additional energy accumulator, while regulating the variable volumetric outflow of supply air and / or volumetric flow of exhaust air.

The advantage is that the heat exchanger is designed as an evaporator or condenser of a heat pump.

It is also an advantage that the heat pump is switchable.

The preferred option is that a device is provided for adiabatically cooling the volumetric flow of exhaust air before entering the heat pump condenser to increase the power factor in case of cooling the volumetric flow of the supply air.

A suitable option is that a device is provided for heating the supply air volumetric flow leaving the heat exchanger in order to control the humidity of the supply air volumetric flow by means of the heat pump heat exchanger located in the supply air volume flow, mainly from the heat pump hot gas.

It is also advisable that a heating device is provided, and an additional heating installation is included in the storage circuit through a separate heat exchanger.

A variant of the invention is that it is provided as an additional heating installation device in accordance with heating equipment.

Another embodiment of the invention is that the heat pump is used in combination with a volumetric flow of supply air and a volumetric flow of exhaust air without using a heat recovery system.

A further embodiment of the invention is that several supply and exhaust devices are combined into a single energy recovery system, and only one heat pump and only one storage circuit with an energy storage device are provided.

A suitable option is that several supply and exhaust devices are combined into a single energy recovery system, and only one heat pump is provided, which is connected to two or more storage circuits with one energy accumulator for heat and one energy accumulator for cold.

The preferred option is that several supply and exhaust devices are combined into a single energy recovery system, and only one heat pump is provided, connected to two or more storage circuits in which an energy accumulator is provided for accumulating heat or cold.

It is also preferable that one or more places independent of the heat pump or devices for transferring thermal energy in the storage circuit, and / or in the energy storage device, and / or in the storage circuit, and / or in the energy storage device.

An embodiment of the invention is that the heat pump is provided with an external condenser / evaporator.

The invention consists in the combination of one of the known heat recovery systems with a system of a heat pump, a storage circuit and a heat exchanger connected to the storage circuit, which is located behind the heat recovery system in the volumetric flow of the supply air. Another heat exchanger is located behind the heat recovery system in the volumetric flow of exhaust air. Both heat exchangers are connected by means of a heat pump, moreover, on the supply air processing side, the heat pump is connected via another heat exchanger to a storage circuit, which is equipped with an energy accumulator and a mixing valve.

Due to the interaction of these structural elements, it is possible to regulate heat transfer. This is necessary, in particular, to limit the supply air temperature.

The temperature of the circulating liquid in the storage circuit is set so high that a sufficiently high condensation temperature is reached for the heat pump to operate. This is calculated according to the compressor manufacturer, taking into account the temperature of the volumetric flow of exhaust air, the design of the heat exchanger located in it, and the evaporation temperature. If in order to achieve an average temperature difference in the heat exchanger, a higher temperature of the circulating liquid is required in the supply air volume flow, then the temperature is chosen to achieve the required average temperature difference. Thus, the optimum power factor of the heat pump is always achieved, however, it is possible to heat exchange in the heat exchanger in the volumetric flow of the supply air.

The supply air temperature is controlled by means of a mixing valve, which can be made, for example, in the form of a 3-way valve with a regulator and an electric motor. In the case of heating with a decrease in the required supply air temperature below a predetermined value, the volumetric flow of circulating liquid to the heat exchanger in the volumetric flow of the supply air is increased. When the required supply air temperature is exceeded, on the contrary, the volumetric flow of the circulating liquid to the heat exchanger in the volumetric flow of the supply air is reduced.

If, for some reason, the volume flow of exhaust air decreases, the evaporation temperature will drop because less heat is supplied. The drop in evaporation temperature is detected by a pressure sensor in front of the compressor, and alternatively by a temperature sensor. If the evaporation temperature drops below a preset value, the controller will turn off the compressor. The volumetric flow of the supply air is then heated by thermal energy from the energy accumulator. After the idle time necessary for the compressor to stop, the compressor switches on again.

When the heat pump is switched off due to reaching the maximum temperature of the circulating liquid, the mixing valve maintains a constant temperature of the volume flow of the supply air, controlled by the energy from the energy accumulator. When the circulating liquid is re-cooled, the heat pump is switched back on to re-transfer energy from the volume flow of exhaust air to the circulating liquid and the energy accumulator.

Continuous shutdown and inclusion occurs in heat pumps with one compressor. More powerful heat pumps are equipped with several compressors. If several compressors are built into the heat pump, the compressors are switched on and off in sequence. As compressors can also be used models with speed control. In this case, the energy accumulator can be made slightly smaller, which, however, under certain circumstances reduces the power factor.

The energy accumulator is calculated from the point of view of volume so that the time period for the complete pumping of the liquid volume lasts longer than is necessary for the stop time of the smallest heat pump compressor. In order to avoid turbulent flows in the energy accumulator, the incoming volumetric flow of circulating liquid can be introduced into the energy accumulator mainly using a nozzle pipe. This causes a favorable laminar flow in the energy accumulator.

The volumetric flow of exhaust air is cooled to obtain as much energy as possible as necessary for heat transfer. If icing of the heat exchanger in the volume flow of exhaust air does not interfere or icing does not occur due to conditioning of the exhaust air, then using the correspondingly powerful temperature pump, the desired supply air temperature after the heat exchanger in the volume flow of exhaust air can be achieved without an additional heater.

Due to the use of a heat pump and the required electrical power for the operation of the heat pump, more energy can be transferred to the outside air than can be taken from the exhaust air.

Thanks to the described invention, in the case of cooling, it is possible to cool the outside air to prepare a volumetric flow of supply air. This is due to the reversal of the cooling circuit of the heat pump. It is also possible to establish a constant supply air temperature.

The advantages achieved by the invention are, inter alia, in the preferred effects described below.

1. Extremely high heat recovery is achieved. The transmitted power achieved by the heat recovery system is supplemented by the heat pump system made in the described combination. More energy can be taken from the volume flow of exhaust air than is necessary to heat the volume flow of the supply air. Excess energy can also be optionally used to heat process water, for example, also to heat the volumetric flow of supply air after adiabatic humidification.

Compared to other heat recovery systems based on an adjustable heat recovery system, the heat recovery coefficient 1 can be exceeded, while other known heat recovery systems achieve a maximum heat recovery coefficient of 0.8.

The volume flow of exhaust air with a combined circulation system with a heat recovery coefficient of 0.47 is cooled in combination with a heat pump system from 24 ° C at a relative humidity of 50% to 6.8 ° C.

Outside air enters with a temperature of 10 ° C at a relative humidity of 70%. The volumetric flow of supply air is transferred through processing to a state with a temperature of 31 ° C at a relative humidity of 19%.

The value of the coefficient of heat recovery: 1.23.

2. In most cases, there is no need for additional heating of the supply air volumetric flow with an additional heater for heating.

3. In most cases, outside air can be cooled so much for cooling that further cooling is not required with an additional cooler. You can save on the cooler in the ventilation unit.

4. The power consumed by the supply fan decreases on the shaft, since the dynamic pressure difference necessary for this is eliminated due to the absence of an air cooler.

5. Supply devices due to the lack of an air heater become smaller and lighter.

6. For most of the supply air cooling and decentralized building cooling, in most cases no additional refrigeration machine is needed.

7. The invention can be used decentrally or centrally integrated in an air treatment unit.

8. The invention can be used centrally for parallel operation, for example, several ventilation units.

The invention is depicted as an example using schematic images of installations and methods and is described in more detail below.

The drawings show:

figure 1 is a diagram of a first embodiment of the invention with one battery of energy;

figure 2 is a diagram of a second embodiment of the invention with two energy accumulators;

3 is a diagram of a first embodiment of the invention for use in parallel ventilation installations;

4 is a diagram of a second embodiment of the invention for use in parallel ventilation installations.

According to a first embodiment of the invention, in FIG. 1, a heat exchanger 2 is placed in a volumetric flow of exhaust air, which becomes exhaust air due to ventilation-technical treatment, after the heat recovery system 10, the heat recovery system 10, on the other hand, is connected to the volumetric flow of the supply air obtained due to ventilation and technical processing from outside air. The heat recovery system 10 can be made of one of the known constructions, for example, in the form of a combined circulation system, a rotational or plate heat exchanger, a smooth-tube heat transmitter, a mass storage heat exchanger, or a heat pipe. The heat exchanger 2 is connected to the heat pump 3 and acts in the case of heating as an evaporator, and in the optional case of cooling, as a condenser of the heat pump 3. In the cooling circuit of the heat pump 3 there is an additional heat exchanger 4, used in the case of heating as a condenser, and in in case of cooling - as an evaporator. Further, also in the volumetric flow of the supply air after the heat recovery system 10, heat exchanger 1 is located. The heat exchanger 1 is integrated in the storage circuit 9. A heat exchanger 4 is also connected to the heat pump 3 in this storage circuit 9. Further, an energy accumulator 9.1 is provided in the storage circuit 9. The storage circuit 9 and the energy accumulator 9.1 are filled with heat accumulating circulating fluid pumped by the pump. The circulating fluid for heat transfer between the heat exchangers 1 and 4 may be water, a water-glycol mixture, or another liquid used in refrigeration and air conditioning.

In the case of heating, the temperature of the circulating liquid in the storage circuit 9 is chosen so high as to provide the minimum required condensation temperature for the heat pump 3, however, the average temperature difference in the heat exchanger 1 is so great that the heat energy can be transferred to the outside air, which after the described ventilation-technical treatment forms a volumetric flow of supply air. In the optional cooling case, the temperature of the circulating liquid in the storage circuit 9 is chosen so low that the outside air in the volumetric flow of the supply air is cooled to the desired supply air temperature.

The temperature level of the circulating liquid and, thus, the regulation of the temperature of the supply air volumetric flow is set using the mixing valve 6 or, alternatively, using the hydraulic arrow. The mixing valve 6 can be made in the form of a 3-way valve with a regulator and an electric motor.

To regulate the temperature level of the circulating liquid, the mixing valve 6 is located in the branch of the accumulating circuit 9, in which its two branches A and B are brought together. The branch A of the branch as a return line is connected directly to the heat exchanger 1. The branch B is connected to the supply line coming from the battery 9.1 for heat exchanger 1. Due to regulation, the mixing valve 6 passes different amounts of circulating liquid through both branches A and B and thereby creates a mixed flow AB. Thus, the passage of heat through the heat exchanger 1 can be controlled from a maximum level to a minimum. In the maximum case, the circulating liquid is completely passed through the heat exchanger 1, and in the minimum case, the circulating liquid is not supplied to the heat exchanger 1. The energy accumulator 9.1, located immediately after the heat exchanger 4, is always washed by the entire amount of liquid and absorbs the heat supplied by the heat pump 3, but not converted by the heat exchanger 1. Similarly, when the heat pump 3 is turned off, thermal energy from the energy accumulator 9.1 can be transferred through the heat exchanger 1 to the volumetric flow of the supply air.

If a disturbing ice build-up occurs in the heat exchanger 2, the temperature of the circulating liquid is increased. With an unacceptable thickness of the ice build-up, the refrigeration cycle is interrupted for a short time, so that the heat exchanger 2 is not cooled by the heat pump, and the volume flow of exhaust air again melts the ice build-up. Alternatively, you can also use separately defrosting heating for heat exchanger 2. The presence of ice build-up can be determined, for example, using a differential pressure gauge 5 in the volume flow of exhaust air before and after heat exchanger 2. Alternatively, the presence of ice build-up can also be determined by increasing pressure of the exhaust air in the volumetric flow in front of the heat exchanger 2.

The heat pump 3 is turned on and off by a temperature sensor commonly used in refrigeration. If the temperature in the cooling circuit of the heat pump 3 is too high, the compressors are turned off or, for large, for example, multi-stage heat pumps, the compressors are connected or disconnected depending on the temperatures. Likewise, compressors are shut off if the temperature in the cooling circuit drops below an acceptable value.

An additional heating source, if necessary, can transfer its energy through an optional heat exchanger 16, which is integrated in the supply line to the heat exchanger 1 into the storage circuit 9. The transmission of this thermal energy is regulated in a simple way by means of a mixing valve 6.

In cases of the circulation mode in which heat recovery does not occur, as well as in the additional heating mode of the ventilation unit, the storage circuit 9 can be used in an additional way. In this case, the hot water of the heating system pump heating the storage circuit 9 through the heat exchanger 16 can have low temperatures in the forward and reverse lines. This ensures the use of heating equipment as a heating system in ventilation equipment. To this end, a predominantly heating boiler can be connected to a heat exchanger 16, for example plate-type, operating very efficiently even at low temperatures.

The optional outdoor cooling function for the cooled supply air volumetric flow is achieved by switching the cooling circuit due to known devices on the heat pump 3.

To optionally control the humidity of the supply air volumetric flow in the case of cooling after heat exchanger 1, an additional heat exchanger 7 is built into the supply air volumetric flow 7. The heat exchanger 7 transfers heat to the supply air volume flow, which was previously further cooled to remove moisture, through almost free energy received from the refrigerant. In this case, the temperature of the supply air volume flow is regulated by a mixing valve 8. The optional regulation of the humidity of the supply air volume flow in the case of heating, on the contrary, is associated with the energy accumulator 9.1 and is described below in the second embodiment.

To improve heat dissipation in the case of cooling, a device for adiabatic cooling can be provided between the heat recovery system 10 and heat exchanger 2 of the heat pump 3 in the volume flow of exhaust air. Thus, the heat transfer in this place is improved in a simple manner.

In order to influence the air treatment in the channels between the supply air volumetric flow and the exhaust air volume flow, air shutters can be provided in a known manner for supplying mixed air from the exhaust air volume flow to the supply air volume flow or for circulating operation, as described above. When using mixed air, it is possible to transfer more heat energy at low air temperature from the condenser by increasing the volumetric air flow through the air damper. In this way, cold water can also be obtained for possible decentralized cooling. Cold water can be taken from the battery 9.1 energy.

The temperature of evaporation and condensation can also be controlled alternatively by means of pressure sensors.

An additional heater can be integrated in the cooling circuit for heating household water with a high temperature level.

The second embodiment of the invention serves to improve the transfer of thermal energy at variable volumetric flows of the supply and / or exhaust air. A similar setup for creating variable volumetric flows is depicted in figure 2.

This improvement according to the invention contains on the supply air side of the heat pump 3 a storage circuit 9 with heat exchangers 1, 4 and an energy accumulator 9.1, as well as a mixing valve 6 between the branches A and B of the storage circuit 9, as described above with reference to FIG. .

In the device of FIG. 2, the heat exchanger 2 is not washed, however, with the refrigerant from the heat pump 3. Here, the heat exchanger 2 is used as a liquid-air heat exchanger. The heat pump 3 on the exhaust side of the system is given an additional storage circuit 12 with an energy accumulator 12.1. The storage circuit 12 is connected to the heat pump by means of a fourth heat exchanger 13. In this case, the heat exchanger 13 acts selectively as an evaporator or condenser for the heat pump 3. Thus, the power of the compressor / compressors of the heat pump 3 can be fully used in cases of cooling and heating. The storage circuit 12 and the energy accumulator 12.1 are also filled with a heat storage circulating fluid pumped by the pump. The flow of liquid in the accumulation circuit 12 is regulated by means of a mixing valve 14. The mixing valve 14 is assigned branches A and B of the accumulation circuit 12. Branch A is connected directly to the heat exchanger 2 as a return line. The branch B is connected to the supply line coming from the battery 12.1 to the heat exchanger 2. By adjusting the mixing valve 14, it is possible to control the flow of the circulating liquid in the accumulation circuit 12 from extreme conditions with full flow through the heat exchanger 2 to turn off the heat exchanger 2. The energy accumulator 12.1 is located immediately after the heat exchanger 13 and is washed with the entire amount of liquid.

Thermal energy is transferred through the circulating liquid to the exhaust air FO through the heat exchanger 2. If the pressure difference due to the ice build-up on the heat exchanger 2 exceeds a predetermined value, the mixing valve 14 is opened for the liquid to flow from branch B to AB and the amount of energy introduced by the heat pump 3 is temporarily stored in the storage circuit 12. In this case, the heat exchanger 2 is turned off. After the ice build-up in the heat exchanger 2 is thawed and, thereby, the pressure difference is reduced, the mixing valve 14 in the accumulation circuit 12 opens the branch A to A-B, and the heat energy is transferred further through the heat exchanger 2 to the exhaust air flow and, thus, to the exhaust air FO.

In addition to controlling the humidity for the case of cooling (summer), as described in the first embodiment of FIG. 1, humidity control can also be provided for the case of heating (winter). For this, an additional heat exchanger 11 is located in the supply air volume flow. It is connected to the energy accumulator 12.1 of the additional storage circuit 12 and is located after the humidifier in the supply air volume flow. The mixing valve 15 controls the flow rate and, thus, the final temperature of the volumetric flow of the supply air.

The transferred energy is accumulated in the energy accumulators 9.1, 12.1 and continuously, even when the compressors are stopped, is transferred to the external air or to the volumetric flow of supply air and the volumetric flow of exhaust air or exhaust air

In particular, the energy accumulator 9.1 can be directly or indirectly connected to additional devices for heat supply and heat removal through the storage circuit 9 in order to better use its energy intensity.

The additional heating source necessary for the case transfers energy through the optional heat exchanger 16 to the storage circuit 9. The transmission of this thermal energy is regulated by the mixing valve 6.

As already described in the first embodiment, the installation can be supplemented here with a heating device in accordance with heating technology. This is possible when the ventilation unit is operating in a circulating mode or in an auxiliary heating mode at low water temperatures. In this case, the hot water of the heating system pump heating the storage circuit 9 through the heat exchanger 16 can have low temperatures in the forward and reverse lines.

The invention can also be used in a very preferred way when using a heat pump, without giving it an additional traditional first heat recovery system in the first stage of regeneration.

The described device can be used with both single and multi-stage heat pumps.

In addition to the described necessary elements, other elements for air treatment, such as filters, silencers or humidifiers, can be habitually installed in the ventilation ducts. In order to increase the productivity of the heat pump 3 and for complete heat transfer at variable volume flows, air conditioning can also be mixed with air mixed with exhaust air through an air mixing valve. In the same way, the setup described above is suitable for circulation mode.

As shown in FIGS. 3 and 4, the invention can also be used to operate combined plants. In this case, the heat pump 3 in a very rational manner is connected through a storage circuit or circuits 19, 20 with several ventilation systems 17,18.

Figure 3 shows a device with two storage circuits 19, 20 for two ventilation units 17,18. These ventilation units 17, 18 can operate independently of each other in cooling and heating modes. To do this, respectively, use one battery 19.1 or 20.1 energy for cooling mode and one battery 19.1 or 20.1 energy for heating mode.

4, the storage circuit 19 is reduced to a single energy accumulator 19.1. This embodiment is used when the ventilation units 17, 18 should only be used in heating mode.

Further, the invention can also be used when the heat pump is operated with an external condenser or evaporator. This particularly advantageously supports the action of the heat pump.

The invention can be used in combination with air conditioning and ventilation systems of any order, i.e., for example, also for air conditioning or heating systems.

The invention is also suitable for retrofitting existing installations, since a heat pump with a storage circuit or circuits can be connected in block form to existing ventilation installations.

The invention is not limited to the described embodiment, but may also be performed differently within the framework of specialized knowledge.

List of Reference Items

1 - heat exchanger

2 - heat exchanger

3 - heat pump

4 - heat exchanger

5 - differential pressure gauge

6 - mixing valve

7 - heat exchanger

8 - control valve

9 - storage loop 9.1 - energy storage

10 - heat recovery system

11 - heat exchanger

12 - storage circuit 12.1 - energy storage

13 - heat exchanger

14 - mixing valve

15 - control valve

16 - heat exchanger

17 - ventilation device

18 - ventilation device

19 - cumulative circuit

19.1 - energy accumulator

20 - cumulative circuit

20.1 - energy storage

Claims (26)

1. The method of energy recovery in installations of air conditioning
and ventilation, comprising a device for directing a volumetric flow of supply air and a device for directing a volumetric flow of exhaust air, optionally a heat recovery system (10) connecting the volumetric flow of supply and exhaust air for heat transfer between the volumetric flow of supply and exhaust air and consisting of one or more heat exchangers, and / or heat pump (3), which is located between the supply air volume flow and the volume flow from driver running air and / or between the volume flow of the supply air and the volume flow of exhaust air given system (10) heat recovery means of heat exchangers associated with a volume flow of supply air and / or the volume flow of the exhaust air, characterized in that it comprises the following steps:
exchange of thermal energy in the volume flow of exhaust air leaving the heat recovery system (10) by means of a first heat exchanger (2) connected to the heat pump (3);
transferring the exchanged heat energy by means of the heat pump (3) and the second heat exchanger (4) connected to the heat pump (3) to the storage circuit (9), which is connected to the heat exchanger (4) to transfer heat energy and contains an energy accumulator (9.1);
transferring heat energy transferred to the storage circuit (9) by means of a third heat exchanger (1) to the volume flow of the supply air leaving the heat recovery system (10) to cool or heat the volume flow of the supply air;
controlling the fraction of transferred heat energy in the heat exchanger (1) attached to the supply air volume flow by controlling the amount of circulating liquid contained in the storage circuit (9) flowing through the energy accumulator (9.1) and the heat exchanger (1). 2. The method according to claim 1, characterized in that it includes the following steps:
selection of thermal energy from the volume of exhaust air flow leaving the heat recovery system (10) by means of a heat exchanger (2) connected to the heat pump (3);
transferring at least a portion of the selected energy by means of a heat pump (3) and a heat exchanger (4) included in the storage circuit (9) to the storage circuit (9) or energy accumulator (9.1);
transfer of energy transferred from the volume stream of the exhaust air to the storage circuit (9) by means of a heat exchanger (1) in order to heat the volume flow of the supply air leaving the heat recovery system (10). 3. The method according to claim 1, characterized in that it includes the following steps:
selection of thermal energy from the heat supply volumetric flow of the supply air leaving the heat recovery system (10) in order to cool the supply air volume flow by means of a heat exchanger (1) connected to the storage circuit (9);
the selection of at least part of the selected heat energy by means of a heat pump (3) and a heat exchanger (4) included in the storage circuit (9) from the storage circuit (9);
transfer of heat energy taken from the storage circuit (9) by means of the heat pump (3) and heat exchanger (2) to the volume flow of exhaust air leaving the heat recovery system (10). 4. The method according to claim 3, characterized in that it includes the following steps:
selection of thermal energy from the volume of exhaust air flow leaving the heat recovery system (10) for adiabatic cooling of the volume flow of exhaust air;
supply of a cooled volume flow of exhaust air to the heat exchanger (2) in order to transfer the heat energy taken from the storage circuit (9) to the cooled volume flow of exhaust air. 5. The method according to claim 3 or 4, characterized in that it includes the following steps:
supply of heat energy to the supply air volume flow exiting from the heat exchanger (1) connected to the storage circuit (9) for additional heating to control the humidity of the cooled volume supply air flow through an additional heat exchanger (7), mainly associated with the hot gas circuit of the heat pump (3) );
supply of a heated volume stream of supply air to an air-conditioned room. 6. The method according to claim 1, characterized in that the regulation of the variable volumetric flow of exhaust air and / or the volumetric flow of supply air is carried out in the following steps:
exchange of thermal energy in the volume flow of exhaust air leaving the heat recovery system (10) by means of a heat exchanger (2) with an additional storage circuit (12) containing an additional energy accumulator (12.1);
transferring at least a portion of the exchanged heat energy by means of a fourth heat exchanger (13) connected to the heat pump (3) and the heat pump (3) from the additional storage circuit (12) through the heat exchanger (4) connected to the energy containing the battery (9.1) the first storage loop (9), to the first storage loop (9);
transferring at least a portion of the heat energy transferred to the first storage circuit (9) by means of a heat exchanger (1) to a volume flow of supply air leaving the heat recovery system (10). 7. The method according to claim 6, characterized in that the fraction of the transferred heat energy in the heat exchanger (2) attached to the volumetric exhaust air stream is controlled by controlling the amount of circulating liquid contained in the storage circuit (12) flowing through the battery (12.1) and heat exchanger (2). 8. The method according to one of claims 1, 2, 3, 4, 6, 7, characterized in that the energy is transferred by means of a heat pump (3) between the volumetric flow of the supply air and the volumetric flow of exhaust air without using the regeneration system (10) heat. 9. A device for energy recovery in the installation of air conditioning and ventilation technology, with a volumetric flow of supply air and a volumetric flow of exhaust air, comprising selectively a heat recovery system (10) connecting a volumetric flow of supply air and a volumetric flow of exhaust air for the purpose of heat transfer between the volumetric flow of supply air and a volumetric flow of exhaust air that contains a regenerative heat exchanger, or a regenerative heat exchanger, or a mass storage heat exchanger, and whether a heat pipe, and a heat pump (3), which, in order to transfer energy to the supply air volume flow or the exhaust air volume flow, is attached to the heat recovery system (10) and is connected to the supply air volume flow and / or the exhaust air volume flow through heat exchangers, or a heat pump (3), which, without an additional system (10) for heat recovery through heat exchangers, is connected to a volumetric flow of supply air and / or a volumetric flow of exhaust air, and a storage circuit (9) with battery an energy emitter (9.1), moreover, a heat exchanger (2) located in the volumetric flow of exhaust air with a heat pump (3), and the heat pump (3) is connected to a storage circuit (9) by means of a second heat exchanger (4), characterized in that the storage circuit (9) is located between the heat pump (3) and the heat exchanger (1) located in the supply air volume stream after the heat recovery system (10), and a device is provided for controlling the transfer of heat energy in the storage circuit (9) between the heat pump (3) and tep oobmennikom (1) energy accumulator (9.1) and / or the heat exchanger (1). 10. The device according to claim 9, characterized in that it comprises a heat exchanger (2) located in the volume flow of exhaust air and connected to the heat pump (3), a storage circuit (9) connected to the heat pump (3) by means of a second heat exchanger (4) an energy accumulator (9.1) included in the storage circuit (9), a heat exchanger (1) connected to the storage circuit (9) and located in the supply air volume flow, and a device (6) for controlling the supply air volume flow temperature, which controls the flow of c rkuliruyuschey liquid in the storage circuit (9) through heat exchanger (1) and battery (9.1) energy. 11. The device according to claim 10, characterized in that the first heat exchanger (2) is made in the form of an evaporator or condenser of a heat pump (3). 12. The device according to claim 10, characterized in that the second heat exchanger (2) is made in the form of an evaporator or condenser of a heat pump (3). 13. The device according to claim 10, characterized in that it contains an additional storage circuit (12) connected through an additional heat exchanger (13) with a heat pump (3), an additional energy accumulator (12.1) included in the additional storage circuit (12), and a device (14) for controlling the transfer of thermal energy to a volume flow of exhaust air, which controls the flow of circulating liquid in an additional storage circuit (12) through a heat exchanger (13) and an additional battery (12.1) of energy, belt supply air volume flow and / or volumetric flow of exhaust air. 14. The device according to item 13, wherein the heat exchanger (13) is made in the form of an evaporator or condenser of a heat pump (3). 15. The device according to one of paragraphs.9-14, characterized in that the heat pump (3) is configured to switch. 16. The device according to one of claims 9-14, characterized in that it comprises a device for adiabatic cooling of the volume flow of exhaust air before entering the heat pump condenser (3) to increase the power factor in the case of cooling the volume flow of the supply air. 17. The device according to one of claims 9-14, characterized in that it comprises a device for heating the supply air volume flow leaving the heat exchanger in order to control the humidity of the supply air volume flow by means of a heat exchanger (7) located in the supply air volume flow of the supply air energy of the heat pump (3), mainly from the hot gas of the heat pump (3). 18. The device according to one of claims 9 to 14, characterized in that it comprises a device for preheating, the additional heating installation being included in the storage circuit (9) through a separate heat exchanger (16). 19. The device according to p. 18, characterized in that it contains, as an additional heating installation, a device in accordance with heating equipment. 20. The device according to one of claims 9 to 14, characterized in that the heat pump (3) is used in combination with a volumetric flow of supply air and a volumetric flow of exhaust air without using a heat recovery system (10). 21. The device according to one of paragraphs.9-14, characterized in that several supply and exhaust devices (17, 18) are combined into a single energy recovery system, and only one heat pump (3) and only one storage circuit (19) are provided with battery (19.1) of energy. 22. The device according to item 13, characterized in that several supply and exhaust devices (17, 18) are combined into a single energy recovery system, and only one heat pump (3) is provided, which is connected to two or more storage circuits (19, 20) with one battery (19.1, 20.1) of energy for heat and one battery (19.1, 20.1) of energy for cold. 23. The device according to item 13, characterized in that several supply and exhaust devices (17, 18) are combined into a single energy recovery system, and only one heat pump (3) is provided, connected to two or more storage circuits (19, 20 ), in which an accumulator (19.1, 20.1) of energy is provided for the accumulation of heat or cold. 24. The device according to p. 22 or 23, characterized in that it contains one or more places or devices that transfer heat energy independent of the heat pump (3) in the storage circuit (19) and / or in the energy accumulator (19.1), and / or in the storage circuit (20), and / or in the battery (20.1) of energy. 25. The device according to one of paragraphs. 9-24, characterized in that the heat pump
(3) equipped with an external condenser / evaporator.
Priority on points: 05/21/2003 according to claims 1-25.

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