DE202020101707U1 - Air-water heat pump with heat recovery - Google Patents

Abstract

Air-water heat pump with heat recovery, comprising a compressor, a refrigerant / water heat exchanger, a refrigerant / air heat exchanger, a heat exchanger for hot water for household purposes, a suction accumulator, a four-way valve, solenoid and control valves, characterized in that they have one Monoblock and that it comprises a compressor with a frequency control (1), which on the one hand by a solenoid valve (2), a four-way valve with reversing function (3), an electronic control valve (4) and a liquid-absorbing heat exchanger (5) with a refrigerant / Water-finned heat exchanger (internal circuit 6), on the other hand through a solenoid valve (7) with a refrigerant / water-finned heat exchanger (8) for hot water for household purposes, from the third side through a solenoid valve (2) and the four-way valve with reversing function (3 ) is connected to the refrigerant / air finned tube heat exchanger (external circuit 9), the K Medium / water finned heat exchanger (internal circuit 6) is connected to the refrigerant / air heat exchanger (external circuit 9) by an electronic expansion valve (10), a liquid-absorbing heat exchanger (11) and an electronic control valve (12), the refrigerant / Water-fin heat exchanger (8) for hot water for household purposes through an electronic expansion valve (13), through the two successive liquid-absorbing heat exchangers (5, 11) and through the electronic control valve (12) with the refrigerant / air fin Pipe heat exchanger (external circuit 9) is connected, and in turn the refrigerant / air finned tube heat exchanger (external circuit 9) through the four-way valve with reversing function (3) with the suction accumulator (14) and the liquid-absorbing heat exchanger (11) with the Compressor is connected to a frequency control (1).

Description

The utility model relates to an air-water heat pump with heat recovery that uses renewable energy to produce thermal energy that is in one piece (monoblock heat pump) or split (split heat pump) and is used for heating and / or cooling buildings, hot water heating for household and industrial purposes, for cooling production processes, u. a. finds.

Different types of heat pumps are known, which work with different refrigerants. The current environmental requirements set by Regulation (EU) No. 517/2014 of the European Parliament and of the Council of April 16, 2014 on fluorinated greenhouse gases and repealing Regulation (EC) No. 842/2006 - Text of relevance to the EEA, are determined, require the use of refrigerants with a low global warming potential (GWP). Unfortunately, the refrigerants known today that meet this characteristic are in most cases flammable, explosive or toxic (R32, R290, R717, R1234yf etc.). Due to the requirement for a lower GWP, the newly developed refrigerants are chemically unstable and form acids. It is advisable not to let such types of gases into buildings.

The embodiments of two types of heat pumps - split heat pump and monoblock - are possible. The divided system consists of an indoor unit (hydro module), which is located in the building, and an outdoor unit, which is located on the outside of the building. Most of the components (the compressor, the valves, the tanks) and the refrigerant are in the outdoor unit, i.e. H. outside the building. The indoor unit is a hydraulic module with a main component of the refrigeration system - a finned heat exchanger. The defects associated with the leakage from the environment in this type of device are minimal. The arrangement of the hydraulic module inside the building (with the split system) reduces the likelihood of malfunctions due to icing of the heat transfer medium in winter conditions and when the heat pump system is set or has failed.

The monoblock system in turn consists of only one outdoor unit, i.e. H. the entire refrigeration system and, accordingly, the refrigerant is located outside the building. The connection to the heating system within the building is made via an intermediate heat transfer medium (water or the solution of an anti-freeze fluid). The use of such a system type is reliable because the entire amount of the refrigerant is brought out of the building. Another advantage of the monoblock systems is their smaller volume, i. H. the smaller amount of refrigerant in it. /1/

The utility model is based on the task of creating a monoblock or split heat pump, that is to say a two-unit air-water heat pump with heat recovery, which enables simultaneous water production with two heat flows - high-temperature zone 2nd and low temperature zone 1 - enables, and can work with refrigerants with low GWP (global warming potential).

The task is offered by the air-water heat pump with heat recovery, which includes a compressor, a refrigerant / water heat exchanger, a refrigerant / air heat exchanger, a heat exchanger for hot water for household purposes, a suction accumulator, a four-way valve and solenoid and control valves. According to the utility model, the air-to-water heat pump with heat recovery is a monoblock and comprises a compressor with frequency control, which on the one hand has a solenoid valve, a four-way valve with reversing function, an electronic control valve and a liquid-absorbing heat exchanger with a refrigerant / water lamella Heat exchanger (internal circuit) is connected. On the other hand, the compressor is connected to a frequency control by a solenoid valve with a refrigerant / water finned heat exchanger for hot water for household purposes. From the third side, the compressor is connected to a frequency control by means of a solenoid valve and by a four-way valve with a reversing function to a refrigerant / air lamella tube heat exchanger (external circuit). For its part, the refrigerant / water finned heat exchanger (internal circuit) is connected to the refrigerant / air heat exchanger (external circuit) by an electronic expansion valve, a liquid-absorbing heat exchanger and an electronic control valve. The refrigerant / water finned heat exchanger for hot water for household purposes is connected to the refrigerant / air finned tube heat exchanger (external circuit) by an electronic expansion valve, the two successive liquid-absorbing heat exchangers and the electronic control valve. The refrigerant / air finned tube heat exchanger (external circuit) is in turn connected to a frequency control by the four-way valve with reversing function with the suction accumulator and with the liquid-absorbing heat exchanger with the compressor.

In accordance with the same utility model, the air-to-water heat pump with heat recovery has a compressor, a refrigerant / water heat exchanger, a refrigerant / air heat exchanger, a heat exchanger for hot water for household purposes, a suction accumulator, a four-way valve and solenoid and control valves. The compressor with a frequency control with the solenoid valve, with the four-way valve with reversing function, with the refrigerant / air finned tube heat exchanger, (external circuit), with the liquid-absorbing heat exchanger, with the electronic control valve and with the suction accumulator, the in the outdoor unit A are arranged, connected. The refrigerant / water finned heat exchanger (internal circuit) is equipped with the refrigerant / water finned heat exchanger for hot water for household purposes, with the electronic expansion valve, with the second electronic expansion valve, with the liquid-absorbing heat exchanger and with a solenoid valve, which in the Indoor unit (hydro module) B are arranged, connected, the two units A and B are interconnected by copper piping and soldered connections. The advantages of the offered air-water heat pump with heat recovery, which uses renewable energy for the production of thermal energy, and which is a monoblock or split heat pump, are the possibility to work with refrigerants with low GWP (global warming potential) , whereby water with two heat flows is produced at the same time as the chiller is operating optimally, thus increasing its performance and reducing operating costs.

The use of a monoblock heat pump favors the use of explosive refrigerants, such as R290 (propane), or toxic agents, such as R717 (ammonia), since all of the refrigerant is removed from the building.

Another advantage of the monoblock systems is their smaller volume, i. H. the smaller amount of refrigerant in it.

The use of a split heat pump allows the larger part of the system and therefore the refrigerant to be located outside the building. This feature favors the use of refrigerants, such as R32, that are flammable, i.e. H. they burn if there is a source of fire, extinguish if there is no source of fire, and are not explosive regardless of concentration. The two units are connected by copper piping and soldered connections.

In addition, the sound level in the building is reduced for both types of heat pumps, with the compressor in the split system being brought out into the outer module. The monoblock system achieves an even lower sound level due to the fact that all components are located outside the building. The systems with a similar structure are a prerequisite for reducing the leakage of refrigerants into the building.
The use of modern refrigerants complies with the ecological requirements of Regulation (EC) No. 517/2014 and contributes to improving the heat and energy parameters of the system.

An embodiment of an air-water heat pump with heat recovery as the subject of the present utility model is shown in the accompanying figures.

• 1 - die Zeichnung einer Luft-Wasser-Wärmepumpe mit Wärmerückgewinnung, die als Monoblock ausgebildet ist und
• 2 - die Zeichnung einer Luft-Wasser-Wärmepumpe mit Wärmerückgewinnung, die als Split-System ausgebildet ist und zwei miteinander verbundene Einheiten - innere und äußere Einheit - umfasst.

The utility model is explained on the basis of these figures, but is not restricted. Show it:

• 1 - The drawing of an air-water heat pump with heat recovery, which is designed as a monoblock and
• 2nd - The drawing of an air-water heat pump with heat recovery, which is designed as a split system and comprises two interconnected units - inner and outer unit.

According to the enclosed 1 the air / water heat pump with heat recovery is a monoblock and includes a compressor with frequency control 1 on the one hand by a solenoid valve 2nd , a four-way valve with reversing function 3rd , an electronic control valve 4th and a liquid-absorbing heat exchanger 5 with a refrigerant / water finned heat exchanger (internal circuit 6 ) connected is. On the other hand is the compressor 1 through a solenoid valve 7 with a refrigerant / water finned heat exchanger 8th connected for hot water for household purposes. The third is the compressor 1 through a solenoid valve 2nd and the four-way valve with reversing function 3rd with the refrigerant / air finned tube heat exchanger (external circuit 9 ) connected. The refrigerant / water finned heat exchanger (internal circuit 6 ) by an electronic expansion valve 10th , through a liquid-absorbing heat exchanger 11 and an electronic control valve 12th with the refrigerant / air heat exchanger (external circuit 9 ) connected. The refrigerant / water finned heat exchanger 8th for hot water for household purposes is through an electronic expansion valve 13 , the two successive liquid-absorbing heat exchangers 5 and 11 and the electronic control valve 12th with the refrigerant / air finned tube heat exchanger (external circuit 9 ) connected. The refrigerant / air finned tube heat exchanger (external circuit 9 ) is in turn due to the four-way valve with reversing function 3rd with the suction accumulator 14 and with that Liquid-absorbing heat exchanger 11 with the compressor with a frequency control 1 connected.

According to the enclosed 2nd the air / water heat pump with heat recovery includes a compressor with frequency control 1 . This is with a solenoid valve 2nd , a four-way valve with reversing function 3rd , a refrigerant / air finned tube heat exchanger (external circuit 9 ), a liquid-absorbing heat exchanger 11 , with the electronic control valve 12th and with the suction accumulator 14 connected that in the outdoor unit A are arranged. The compressor is also equipped with a refrigerant / water finned heat exchanger (internal circuit 6 ) connected to a refrigerant / water finned heat exchanger 8th for hot water for household purposes, an electronic expansion valve 10th , an electronic expansion valve 13 , a liquid-absorbing heat exchanger 5 and a solenoid valve 15 connected in the indoor unit (in the hydro module) B are arranged, the units A and B are interconnected.

• Kühlung In dieser Betriebsart wird die vom Innenkreislauf (eine Gebäudeklimaanlage) entnommene Wärme in die Umgebung durch die Kältemaschine geführt und dann in die Atmosphäre abgegeben.

The heat pump thus offered can work in five main operating modes:

• Cooling In this operating mode, the heat extracted from the indoor circuit (a building air conditioning system) is conducted into the environment by the chiller and then released into the atmosphere.

Working principle in cooling mode

The hot vapors from the compressor 1 flow through the solenoid valve 2nd , the four-way valve with a reversing function 3rd and flow into the refrigerant / air finned tube heat exchanger 9 in which the refrigerant condenses. The liquefied refrigerant flows through the electronic control valve one after the other 12th , the liquid-absorbing heat exchanger 11 and the electronic expansion valve 10th and evaporates in the refrigerant / water finned heat exchanger (internal circuit 6 ). The low pressure vapors flow through a liquid-absorbing heat exchanger 5 , the electronic control valve 4th , the four-way valve 3rd , the suction accumulator 14 and the second liquid-absorbing heat exchanger 11 and are from the compressor 1 sucked in.

Heating In this operating mode, the heat taken from the environment is generated by the outer finned tube heat exchanger 9 through the chiller and the low temperature circuit zone 1 - led to the building.

Working principle in the heating mode

The hot vapors from the compressor 1 flow through the solenoid valve 2nd , the four-way valve 3rd , an electronic control valve 4th , a liquid-absorbing heat exchanger 5 and flow into the refrigerant / water finned heat exchanger (internal circuit 6 ) a. The liquefied refrigerant flows through the electronic expansion valve one after the other 10th , the liquid-absorbing heat exchanger 11 and the electronic control valve 12th and evaporates in the refrigerant / air finned tube heat exchanger 9 . The low pressure vapors flow through the four-way valve 3rd , the suction accumulator 14 and the liquid-absorbing heat exchanger 11 , and are from the compressor 1 sucked in.

High temperature heating (hot water for household purposes)

In this operating mode, the heat taken from the environment is generated by the outer finned tube heat exchanger 9 through the chiller to the building and to the high temperature circuit zone 2nd - delivered.

Working principle in the high temperature heating mode

The hot vapors from the compressor 1 flow through a solenoid valve 7 and flow into the refrigerant / water finned heat exchanger 8th for hot water for household purposes. The liquefied refrigerant flows through the electronic expansion valve one after the other 13 , the two successive liquid-absorbing heat exchangers 5 and 11 , as well as the electronic control valve 12th and evaporates in the refrigerant / air finned tube heat exchanger 9 . The low pressure vapors flow through the four-way valve 3rd , the suction accumulator 14 and the liquid-absorbing heat exchanger 11 and are from the compressor 1 sucked in.

Combi mode - heating and hot water for household purposes

In this operating mode, the heat taken from the surroundings is conducted from the outer finned tube heat exchanger through the chiller to the building and successively first to the high-temperature circuit zone 2nd - and then to the internal circuit / low temperature circuit zone 1 - delivered.

Working principle in the two-zone mode - high temperature zone 2 and low temperature zone 1

The hot vapors from the compressor 1 flow through a solenoid valve 7 and flow into the Refrigerant / water finned heat exchanger 8th for hot water for household purposes (high temperature zone 2nd ) where they are cooled to dry saturated vapors. Then they flow through the solenoid valve 15 and flow into the refrigerant / water finned heat exchanger (internal circuit 6 ) (Low temperature zone 1 ) in which they completely condense. The liquefied refrigerant flows through the electronic expansion valve one after the other 10th , the liquid-absorbing heat exchanger 11 and the electronic control valve and evaporates in the refrigerant / air finned tube heat exchanger 9 . The low pressure vapors flow through the four-way valve 3rd , the suction accumulator 14 and the liquid-absorbing heat exchanger 11 and are from the compressor 1 sucked in.

Operating mode with heat recovery

The recycling of waste heat in the building and its conversion into useful heat for the production of hot water for household purposes or heat for technological purposes is the top priority in this operating mode. In the case of excess heat, the heat is dissipated into the environment through the external heat exchanger, and in the case of a lack of heat the reverse process takes place, the heat is absorbed from the environment.

Working principle in the waste heat recovery operating mode

The hot vapors from the compressor 1 flow through a solenoid valve 5 and flow into the refrigerant / water finned heat exchanger 8th for hot water for household purposes (high temperature zone 1 ) in which they condense. The liquefied refrigerant flows through the electronic expansion valve 13 , the liquid-absorbing heat exchanger 5 and the electronic expansion valve 10th and flows into the refrigerant / water finned heat exchanger (internal circuit 6 ) in which it evaporates. The low-pressure vapors flow through the liquid-absorbing heat exchanger 5 , the electronic control valve 4th , the four-way valve 3rd , the suction accumulator 14 and the liquid-absorbing heat exchanger 11 and are from the compressor 1 sucked in.

Submode recovery of waste heat with excess thermal energy

Operation in this operating mode is analogous to the main operating mode with heat recovery. The difference is that the excess amount of thermal energy is dissipated into the environment, with some of the hot vapors coming from the compressor 1 the solenoid valve 2nd and the four-way valve 3rd flow through and into the refrigerant / air finned tube heat exchanger 9 flow in, in which they condense. The liquefied refrigerant flows through the electronic control valve one after the other 12th and the liquid-absorbing heat exchanger 11 and mixes with the main flow of liquid refrigerant, which is from the refrigerant / water fin heat exchanger 8th for hot water for household purposes (high temperature zone 1 ) comes. The mixed liquid flows through the electronic expansion valve 10th and evaporates in the refrigerant / water finned heat exchanger (internal circuit 6 ). The low-pressure vapors then flow through the liquid-absorbing heat exchanger 5 , the electronic control valve 4th , the four-way valve 3rd , the suction accumulator 14 and the liquid-absorbing heat exchanger 11 and are from the compressor 1 sucked in.

Submode recovery of waste heat with lack of thermal energy

Analogous to the above submode, operation in this submode is analogous to the main mode with heat recovery. The difference is that the required (insufficient) amount of thermal energy is absorbed from the environment, with part of the heat exchanger in the refrigerant / water fins 8th for hot water for household purposes (high temperature zone 1 ) condensed the electronic expansion valve one after the other 13 , the two successive liquid-absorbing heat exchangers 5 and 11 and the electronic control valve 12th flows through and in the refrigerant / air finned tube heat exchanger 9 evaporates. The low pressure vapors flow through the solenoid valve 16 , the suction accumulator 14 and the liquid-absorbing heat exchanger 11 and are from the compressor 1 sucked in.

1 -

Kühlung

2 -

Heizung

3 -

Heißwasser zu Haushaltszwecken

4 -

Heißwasser zu Haushaltszwecken und Heizung

5 -

Wärmerückgewinnung

6 -

Wärmerückgewinnung mit Wärmeüberschuss

7 -

Wärmerückgewinnung mit Wärmemangel

The operating modes described are shown in the accompanying figures as follows:

1 -

cooling

2 -

heater

3 -

Hot water for household purposes

4 -

Hot water for household purposes and heating

5 -

Heat recovery

6 -

Heat recovery with excess heat

7 -

Heat recovery with lack of heat

The reversible air-water heat pump with heat recovery offered in this way represents a concept solution that combines the working principle of a water cooling unit, a heat pump and a system for year-round production of hot water at high temperature for household and / or technological purposes. The waste heat is used in cooling mode. The freezing of the liquid coolant and the overheating of the low-pressure vapors in the liquid-absorbing heat exchanger in connection with the two-stage throttling of the refrigerant increase the efficiency of the chiller and ensure the safe operation of the compressor, which increases the reliability of the system. The intended frequency control of the compressor ensures the adaptable operation of the system and high seasonal performance.

The technical solution offered for one of two units A and B The existing split system enables the construction of a compact system, which is closed in a sound-insulating housing located in the building, and an outdoor unit, which are not subject to such high demands in terms of noise pollution. In addition, maintenance of the main part of the heat pump system is made easier since it is located outside the building. The use of flame-retardant refrigerants of the R32 type is favored by the reduced possibility of seepage within the building and in the rooms.

The solution offered by a monoblock system requires the construction of only a single outdoor unit, which will be soundproofed, regardless of the fact that it is not located in the building. Placing the whole system outside the building will favor maintenance.

literature

1. 2599U1

Claims (2)

Air-water heat pump with heat recovery, comprising a compressor, a refrigerant / water heat exchanger, a refrigerant / air heat exchanger, a heat exchanger for hot water for household purposes, a suction accumulator, a four-way valve, solenoid and control valves, characterized in that they have one Monoblock and that it comprises a compressor with a frequency control (1), which on the one hand by a solenoid valve (2), a four-way valve with reversing function (3), an electronic control valve (4) and a liquid-absorbing heat exchanger (5) with a refrigerant / Water-finned heat exchanger (internal circuit 6), on the other hand through a solenoid valve (7) with a refrigerant / water-finned heat exchanger (8) for hot water for household purposes, from the third side through a solenoid valve (2) and the four-way valve with reversing function (3 ) is connected to the refrigerant / air finned tube heat exchanger (external circuit 9), the K The medium / water lamella heat exchanger (internal circuit 6) is connected to the refrigerant / air heat exchanger (external circuit 9) by an electronic expansion valve (10), a liquid-absorbing heat exchanger (11) and an electronic control valve (12), the refrigerant / Water-fin heat exchanger (8) for hot water for household purposes through an electronic expansion valve (13), through the two successive liquid-absorbing heat exchangers (5, 11) and through the electronic control valve (12) with the refrigerant / air fin Pipe heat exchanger (external circuit 9) is connected, and in turn the refrigerant / air finned tube heat exchanger (external circuit 9) through the four-way valve with reversing function (3) with the suction accumulator (14) and the liquid-absorbing heat exchanger (11) with the Compressor is connected to a frequency control (1). Air / water heat pump with heat recovery, comprising a compressor, a refrigerant / water heat exchanger, a refrigerant / air heat exchanger, a heat exchanger for hot water for household purposes, a suction accumulator, a four-way valve and solenoid and control valves, characterized in that they are a compressor with a frequency control (1), connected to a solenoid valve (2), a four-way valve with reversing function (3), a refrigerant / air lamella tube heat exchanger (external circuit 9), an electronic control valve (12), a liquid-absorbing heat exchanger ( 11) and a suction accumulator (14) arranged in the outdoor unit A and a refrigerant / water-fin heat exchanger (internal circuit 6) connected to a refrigerant / water-fin heat exchanger for hot water for household purposes (8), an electronic expansion valve (10 ), an electronic expansion valve (13), a liquid-absorbing heat exchanger (5th ) and a solenoid valve (15), arranged in the indoor unit (in the hydro module) B, the units A and B being connected to one another by pipelines made of copper and soldered connections.

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