WO2016192977A1 - Air heat pump for obtaining environmental heat from air - Google Patents

Abstract

The invention relates to an air heat pump (3) for obtaining environmental heat from air and for controlling the temperature of a useful fluid using a coolant evaporator (4), wherein air that is being moved by the wind impinges on the air heat pump, and the air heat pump has an air inlet device (5) and an air outlet device (6). An air heat pump (3) according to the invention is characterized in that the air inlet device (5) and/or the air outlet device (6) is mounted in a movable manner by means of a movable bearing (8), and at least one wind tracking device (9) is provided for orienting the air inlet device (5) and/or the air outlet device (6) towards the wind. A method according to the invention for controlling a wind tracking process in an air heat pump (3) is characterized by the steps of detecting a wind direction and/or a wind speed, detecting a possible better angular position of the air inlet device (5) and/or the air outlet device (6), and moving and aligning the air inlet device (5) and/or the air outlet device (6) according to the detected wind direction.

Description

 Description title

 Air heat pump for recovering environmental heat from air

The invention relates to an air heat pump for recovering environmental heat from air and temperature control of a Nutzfluids with a refrigerant evaporator, which is flowed by wind-blown air, comprising an air inlet device and an air outlet device.

State of the art

Heat pumps serve to heat a service fluid by utilizing a low-temperature heat potential (for example, environmental heat or waste heat). A refrigerant circuit connects an evaporator, a compressor, a condenser and an expansion device and optionally other components by means of a piping system for circulation of a

Refrigerant. In the evaporator, liquid refrigerant is vaporized by transferring low-temperature environmental heat. In the compressor, the

Condenses refrigerant vapor, whereby he erhh heated. In the condenser, the previously recorded environmental heat and the recorded

Compressing energy at a now elevated temperature from the refrigerant to a Nutzfluid transferred while liquefying the refrigerant. In the

Expansion device, the refrigerant is released. Subsequently, the refrigerant is returned to the evaporator. A control device can for

Monitoring and control of said heat pump components serve.

Heat pumps can, for example, the space heating or

Serve drinking water heating, thereby come as Nutzfluide water or air used. Air heat pumps use the heat contained in air (eg Outside air or exhaust air). In this case, the amount of air flowing through the evaporator causes the amount of heat transferable to the useful fluid. Outdoor air heat pumps for DHW heating suck in outdoor air by means of a blower via an air inlet device, promote this in a

Heat pump housing through the evaporator, and blow the cooled air through an air outlet device again. If these outdoor air heat pumps are exposed to the wind, the wind conditions can influence the amount of air impinging the evaporator and thus the heat yield.

Evaporator and condenser are heat exchangers and can vary depending on

Heat pump type, for example, be designed as an air-liquid heat exchanger or liquid-liquid heat exchanger. exemplary

Evaporator designs are finned heat exchangers and

Finned tube heat exchangers with air-flowed sheet metal laminations or sheet metal ribs that border thermally conductive to refrigerant pipelines.

DISCLOSURE OF THE INVENTION An air heat pump according to the invention for the production of environmental heat

Air and temperature control of a Nutzfluids with a refrigerant evaporator, which is flowed by wind-blown air, has an air inlet device and an air outlet device. It is provided that the air inlet device and / or the air outlet device are movably mounted by means of a movable mounting and at least one wind tracking device for

Tracking of air inlet device and / or air outlet device is included according to the wind direction. This is achieved that the

Air inlet device or the air outlet device or both

Air inlet device and air outlet device to move and can align according to an atmospheric wind movement of the air, and that this wind movement causes an admission or flow through the evaporator with air or at least supported and amplified. Depending on the atmospheric conditions, the wind can blow from different directions (from different angles, measured as an angle to a north direction, for example). By means of the mobile Storage and the wind tracking device can be the

Move air inlet device and / or air outlet device and

align according to the wind direction. Thus, air flows under wind pressure particularly easily and largely unhindered by an open

Air inlet cross section in the air inlet device and thus in the

 Heat pump into it, flows through the refrigerant evaporator where it transfers its environmental heat to the refrigerant, and flows very easily and largely unhindered by an open air outlet cross-section of the air outlet device and thus out of the heat pump out again. The tracking thus includes a movement and an orientation according to the wind direction. Aligning means a targeted movement of

Air inlet device and / or air outlet device in an angular position corresponding to the wind direction. Tracking according to the wind direction or alignment according to the wind direction may mean that

Air inlet device and / or air outlet device to move or rotate or adjust so that they occupy a predetermined angular position with respect to the wind direction. An angular position can be measured, for example, as an angle to a north direction. Thus, an air flow of the heat pump and the evaporator can be maximized and an efficiency of the

Heat pump can be optimized.

In a further optional embodiment, the

Wind tracking device a wind direction sensor for detecting a wind direction and / or a wind speed sensor for detecting a wind speed. This can be a single sensor for capturing the

Wind direction or two separate sensors that detect the wind direction and the wind speed separately, or it may be a

Combination sensor acting, the wind direction and wind speed recorded together. Wind direction sensors and / or wind speed sensors generate on the basis of detected wind direction and / or recognized

 Wind speed control signals, which is a tracking of the

Air intake device and / or air outlet device cause. In this case, the generation of the actuating signals can be based directly on a wind pressure associated with the wind, or indirectly with a translation of the detected

Wind direction and / or wind speed in a different way Signal energy form associated (for example, by implementing a directly associated with wind direction and / or wind speed physical value in an electrical signal). Thus, air inlet device and / or air outlet device are aligned according to the wind direction.

For example, the heat pump may include a control device, which

Signals of the wind direction sensor and / or the wind speed sensor receives and further processed, whereby finally a tracking of the air inlet device and / or air outlet device is made possible. This controller may be the same as one used to monitor and control the heat pump components. The controller causes by means of

 Tracking a maximized air flow of the heat pump and the evaporator and an optimized efficiency of the heat pump.

In an optional embodiment, the wind tracking device comprises an adjusting device, while the adjusting device causes in dependence of the

Actuator signal movement of the air inlet device and / or the

Air dispensing device. The adjusting device may include a drive unit such as a motor for generating the movement and / or a transmission unit such as a transmission for transmitting the movement to the air inlet device and / or the air outlet device.

In further possible embodiments, the adjusting device causes a movement to mechanical, electrical, magnetic,

electromotive and / or hydraulic principle. The tracking is then effected by mechanical, electrical, magnetic, electromotive and / or hydraulic forces, such as leverage forces generated by wind pressure, electrical or magnetic attraction forces, or of

Electric motors or hydraulic devices transmitted torques.

An advantageous wind tracking device is designed such that an air inlet cross section of the air inlet device is aligned in or to the wind direction of the wind, and / or that an air outlet cross section of the

Aligns the air outlet device in or to empty the wind. This is done, for example, with a wind direction sensor for detecting a Wind direction and / or empty direction, whose actuating signals cause a movement of an adjusting device and thus an orientation of the air inlet cross section and / or the air outlet cross section. This ensures that the largest possible dynamic pressure or overpressure relative to atmospheric pressure is formed at the air inlet cross section and the wind-swept air can flow directly without avoidable flow losses through the air inlet cross-section in the air inlet device to the evaporator. Furthermore, this ensures that at the air outlet cross-section of a magnitude as large suction pressure or negative pressure against atmospheric pressure is formed and the air leaving the evaporator directly without avoidable

Flow losses through the air outlet cross section from the

Air outlet device can flow out. So that will be between

Air inlet device and air outlet device integrated evaporator flows through wind-blown air.

In one possible embodiment, the movable storage of

Air inlet device and air outlet device formed as a rotatable mounting, preferably as a rotatable mounting with a vertical axis of rotation. This is particularly advantageous in the tracking according to the

usually horizontal wind movements.

In one possible embodiment, the air inlet device and the air outlet device are designed as two separate structural units. They can be separated, ie independent from each other

Movements or be designed for coupled movements. This is often structurally smaller dimensions of the movable bearing possible.

In an optional embodiment of the air heat pump, the

Air inlet device and / or the air outlet device formed by attached to an upper portion of the air heat pump intake manifold and / or Ausblaskrümmer, for example in the form of 90-degree pipe bends. This is a simple component design with simple connection options for air flow within a heat pump housing by the Evaporator reached. In this case, each manifold can be moved individually, or both manifolds can be moved together connected by a translation.

In an alternative embodiment, the air inlet device and the air outlet device are formed as a one-piece structural unit and mounted as a unit movable together. This can be achieved that

Air inlet cross-section and air outlet cross-section are always opposite each other and an orientation according to the wind direction, for example, a windward / leeward orientation, is particularly simple.

In an optional embodiment, the wind direction sensor and / or the wind speed sensor are selected from a group comprising

Wind vane, wind direction sensor, anemoscope, pitot tube, pitot tube, pitot tube, Prandtl tube, anemometer. Also combinations of these probes are conceivable. This is a simple, robust and secure detection of

Wind direction and / or wind speed achievable.

In an optional embodiment, the air heat pump comprises a blower for conveying air through the refrigerant evaporator, wherein the

Blower speed depending on the wind speed and / or a

Air flow through the evaporator and / or a

Heat pump heating and / or a Nutzfluidtemperatur is controllable. Wind speed and / or air flow rate and / or heat pump heat output and / or useful fluid temperature are preferably currently determined or measured or assumed values. The blower causes the required for a current Temperierungsbedarf a Nutzfluides air flow through the evaporator, if the atmospheric motion, for example, in the case of calm or low wind speed or hardly existing air movement can not cause a required air flow. Or the fan supports and increases a wind-induced air flow through the

Evaporator. For example, the wind speed or the air flow rate through the evaporator or a heat pump heating power or a

Nutzfluidtemperatur measured or determined and compared with a required value. If the required value is not reached, the fan is switched on or the fan speed is increased. Then more air reaches the Evaporator, a refrigerant evaporation performance is increased, and more environmental heat from air can be recovered and used. For example, a control device monitors or measures or determines the wind speed, the air flow rate through the evaporator, the heat pump heat output and / or the Nutzfluidtemperatur and controls the fan speed as a function thereof. As a result, the control device ensures a wind-independent

Minimum air flow through the evaporator. The air flow through the evaporator can also be maximized by means of the regulator and blower with the aim of maximizing the heat pump heat output.

An inventive method for controlling a wind tracking of an air inlet device and / or an air outlet device in an air heat pump according to the invention, which is flowed by wind-blown air is characterized by the steps detecting a wind direction and / or a wind speed, detecting a possible better angular position of the air inlet device and / or Air outlet device, and moving and aligning the air inlet device and / or the air outlet device according to the detected better angular position. This ensures that the wind - swept air with minimal flow losses through the

Air inlet cross section flows into the air inlet device, the

Flows through the refrigerant evaporator, and flows through the air outlet cross section from the air outlet device. A better angular position in this context means an angular position of the air inlet device and / or air outlet device, in which the wind-blown air is easier and

less flow loss flows into the air inlet device and / or flows out of the air outlet device and the evaporator is flowed through by more wind-blown air.

An optional method is characterized in that the detection of a wind direction takes place by means of a wind vane which can be moved about a vertical axis, wherein the wind vane automatically aligns under the influence of the wind in an empty direction of the wind.

In an optional method, the detection of a wind direction and / or a wind speed takes place by determining a maximum back pressure by means of a ram pressure sensor rotatable about a vertical axis. In this case, a first dynamic pressure in a first angular position, a second dynamic pressure in a second angular position deviating by 45 degrees clockwise from the first angular position, and a third dynamic pressure in a counterclockwise by 45 degrees from the first angular position deviating third angular position of the dynamic pressure sensor measured, wherein the first angular position of the dynamic pressure sensor is identical to the current angular position of the air inlet cross section, and wherein a maximum back pressure is determined with information on angular position and size by interpolation from the measured back pressures. The movement of the dynamic pressure sensor takes place on the same or the same principle as the movement of air inlet device and / or air outlet device. Optionally, the movements of dynamic pressure sensor, air inlet device and / or air outlet device are coupled together. Thus, a simple method is provided, with the help of a maximum back pressure, a current wind direction and a current wind speed can be determined.

An optional method is characterized in that the recognition of a possible better angular position of the air inlet device and / or

Air outlet device in response to an angular deviation between a current angular position of the air inlet device and / or

Air outlet device and a detected wind direction and in dependence of the wind speed takes place. Angular position of the air inlet device and / or air outlet device is understood to mean, for example, the angular position of a windward / leeward orientation of the air inlet device and / or air outlet device with respect to a north direction. At angular deviations greater than or equal to a deviation limit (for example, 5 degrees) and / or at wind speeds greater than or equal to a velocity limit (eg, 2 meters per second), a possible better angular position of air inlet and / or air outlet is detected. The better one

Angular position is identical to the detected wind direction. This is

Ensures that larger wind direction changes and larger

Wind speeds cause a tracking of air inlet device and / or air outlet device, these wind changes have the potential to affect a wind-driven air flow rate of the evaporator. Small wind direction changes and small wind speeds can be disregarded, so no moving and aligning

Air intake device and / or air outlet device entrain because they have little or no effect on the wind-driven air flow rate of the evaporator.

Moving and aligning the air inlet device and / or

Air outlet device according to the wind direction, advantageously the air inlet device in the windward direction of the wind and / or the

Air outlet device in the empty direction, takes place according to mechanical, electrical, magnetic, electric motor and / or hydraulic principle in

Dependence of actuating signals on the part of the wind direction sensor and / or the wind speed sensor. An optional method is characterized in that the moving and

Aligning an air inlet device and / or air outlet device by means of a movable about a vertical axis wind vane, wherein the wind vane automatically aligns the air inlet device and / or air outlet device under the influence of the wind in windward or empty direction of the wind.

In this case, a direct coupling of wind vane and air inlet device and / or air outlet device may be advantageous.

In an optional method, a speed of an impeller becomes a

Blower for conveying air through the refrigerant evaporator depending on the wind speed and / or an air flow through the

Refrigerant evaporator and / or a Wärmepumpenheizleistung and / or a Nutzfluidtemperatur regulated. The air heat pump includes a fan with switchable and / or variable impeller speed, which at least then supports and partially or completely takes over an air delivery through the evaporator when the wind is insufficient to supply the evaporator with an adequate amount of air for an applied heating demand. That a wind-driven air flow is not sufficient, is detected by optionally available sensors for wind speed measurement, air flow rate measurement, heating power measurement or Nutzfluidtemperaturmessung. For example, the fan speed is increased when the wind speed and / or the Air flow rate and / or the heat pump heating capacity and / or the

Useful temperature below a target value.

Figures la and lb show a heat pump heater according to the prior art,

 FIGS. 2a and 2b show an air heat pump according to the invention,

Figure 4 shows an upper portion of an air heat pump according to the invention, Figure 5 shows an upper portion of an air heat pump according to the invention, Figure 6 shows an upper portion of an air heat pump according to the invention, Figure 7 shows an upper portion of an air heat pump according to the invention, FIG. 8 shows a flow diagram of a method according to the invention,

FIG. 9 shows a flow diagram of a method according to the invention.

Figure la shows a heat pump heater 1 according to the prior art in a longitudinal section, Figure lb shows this heat pump heater 1 in plan view. In the lower portion of the heat pump heater 1 is a

Hot water tank 2 for storing a Nutzfluides. In the upper section is the actual air heat pump 3 with a refrigerant evaporator 4, an air inlet device 5, an air outlet device 6 and a blower 7. The fan 7 sucks low-temperature air from the

Aufstellumgebung the heat pump heater 1 through the

Air inlet device 5, it promotes through the evaporator 4, and blows the cooled air through the air outlet device 6 again. An unillustrated compressor heats circulating refrigerant and delivers it to a condenser (not shown) where the heat is transferred to the working fluid. For this purpose, Nutzfluid is by means of a (not shown)

Circulating pump sucked from the memory 2, flows through the condenser, and is conveyed back into the memory. The heated working fluid (for example, domestic hot water, heating water, etc.) can be removed from the memory 2 for use purposes. Figure 2a shows a heat pump heater 1 with an embodiment of an air heat pump 3 according to the invention in the upper section, Figure 2b shows the corresponding plan view. The air heat pump 3 gains environmental heat from air and tempered a Nutzfluid. The air heat pump 3 is of

wind-entrained air, it comprises an air inlet device 5 and an air outlet device 6, wherein the air inlet device 5 and / or the air outlet device 6 are movably mounted. In the example shown, they each have a movement bearing 8, for example, a ball bearing (8) or sliding bearing (8), and are rotatably mounted about a vertical axis of rotation. Furthermore, the air heat pump 3 comprises a wind tracking device 9, the one

Tracking of air inlet device 5 and / or air outlet device 6 according to the wind direction allows. Air inlet device 5 and

Air outlet device 6 are formed as two separate units in the manner of 90-degree pipe bends as intake manifold 5 and 6 Ausblaskrümmer. Directly on the intake manifold 5 sets a rigidly connected wind vane

9, on the exhaust manifold 6 set two rigidly connected wind vanes 9 at. The wind vanes are wind direction sensors 11.1 and detect a wind direction. Depending on the wind speed presses a wind pressure on the wind vanes 9 and turns the wind vanes 9 itself and with them the intake manifold 5 and the

Ausblaskrümmer 6 and aligns them according to the wind direction. Thus, the wind pressure with a force on the surface of the wind vane 9 generates a torque about the vertical axis of rotation, this corresponds to a control signal. The wind vane 9 is at the same time adjusting device, the self as well

Intake manifold 5 and exhaust manifold 6 according to the torque

moved and aligned according to the wind direction. Aligned so, the wind-swept air flows through the without further flow losses

Air inlet device 5 to the evaporator 4, transfers its low-temperature heat to the refrigerant, continues to flow to the air outlet device 6 and leaves the heat pump cooled 3. The tracking of

Air inlet device 5 and air outlet device 6 according to the

Wind direction is used to maximize a wind-swept air flow through the evaporator 4. An impeller speed of a fan 7, which serves to promote air through the evaporator 4, can be reduced if enough wind-driven air flows through the evaporator 4. Thus, electrical energy can be saved to drive the blower 7. In the illustrated embodiment, the wind vanes 9 are aligned with the

Suction or the discharge direction of the two manifolds 5, 6. This takes place at sufficient wind pressure alignment of the

Intake manifold 5 in the windward direction and the Ausblaskrümmers 6 in Leerichtung the wind.

The heat pump heater 1 may comprise, for example, a cylindrical or cuboidal housing in which the components of the heat pump 3 in an upper portion and a storage container 2 (for example

 Hot water tank or heating buffer) are arranged in a lower portion. The air inlet device 5 and / or the

Air outlet means 6 may be arranged on an upwardly oriented housing part or on a circumference of the housing. In an optional embodiment of the invention, the entire air heat pump 3 may be rotatably mounted.

The air inlet device 5 comprises an air inlet cross section as an open cross section or opening for the incoming air. The

Air outlet device 6 comprises an air outlet cross-section as open

Cross section or opening for the outflowing air. At least one of these openings may be protected by grids, filters or covers against the unwanted ingress of dust, leaves, other objects, animals or the inadvertent intervention of hands. Tracking and alignment of air inlet device 5 and / or air outlet device 6 may in particular mean the air inlet cross section and / or the

Align the air outlet cross section perpendicular to the wind direction and / or empty direction of the wind, whereby an inflow and outflow of

wind-driven air is particularly low-flow loss.

Figure 3 shows a further embodiment of the air heat pump 3 with

Air inlet device 5 and air outlet device 6, again as 90-degree elbows 5, 6 formed. These are designed as a one-piece structural unit 5, 6 and mounted as a unit movable together (pivot bearing 8). Directly to the assembly 5, 6 sets a rigidly connected wind vane 9, which the Air inlet device 5 and air outlet device 6 under wind pressure of the wind direction nachzuführen accordingly.

FIG. 4 discloses an alternative embodiment of the air heat pump 3, in which the air inlet device 5 and the air outlet device 6 are arranged in the jacket surface of the cover 10 of the upper section of the heat pump heater 1. A wind vane 9 on the upper surface created under

Wind pressure is a torque about the vertical axis of rotation and rotates the entire cover 10 and / or the entire upper portion of the

Heat pump heater 1 to the pivot bearing. 8

FIG. 5 shows a further embodiment of the air heat pump 3, in which the air inlet device 5 is arranged in the jacket surface of the cover 10 of the upper section of the heat pump heater 1. The

Air outlet device 6 and the wind vane 9 are arranged on the upper surface. The wind vane 9 generates a torque about the vertical axis of rotation under wind pressure and rotates the entire cover 10 with

Air inlet device 5 and air outlet device 6 to the pivot bearing. 8

FIG. 6 discloses a further embodiment of the air heat pump 3 with air inlet device 5, air outlet device 6 and two rotary bearings 8. A wind direction sensor 11.1 for detecting a wind direction and / or a wind speed sensor 11.2 for detecting a wind speed is provided on the air inlet device 5, these sensors generate corresponding control signals. Air inlet device 5 and air outlet device 6 are moved and aligned according to a detected wind direction. Provided for this purpose is an adjusting device 12 which is controlled by a control device 13

is controlled and both the air inlet device 5 and the

Air outlet device 6 moves and aligns. The control device 13 receives actuating signals of the wind direction sensor 11.1 and / or the

Wind speed sensor 11.2, processes these and gives control commands to the adjusting device 12 for moving and aligning the air inlet device 5 and the air outlet device. 6 FIG. 7 shows a further embodiment of the air heat pump 3

Air inlet device 5, air outlet device 6 and two pivot bearings 8. At the air heat pump 3 is a wind direction sensor 11.1 for detecting a

Wind direction and / or a wind speed sensor 11.2 provided for detecting a wind speed. The wind sensor 11.1, 11.2 generates a

 Actuating signal. Air inlet device 5 and air outlet device 6 are moved and aligned according to a detected wind direction. Provided for this are two adjusting devices 12, which are controlled by a control device 13 and the air inlet device 5 and the

Move air outlet device 6 and align. The wind sensor 11.1, 11.2 has a rotary bearing 14 and an adjusting device 15. It detects a wind direction and / or a wind speed by a maximum

Back pressure and an associated angular position can be determined. The

Angular position of the maximum dynamic pressure is identical to the angle of the wind direction.

FIG. 8 shows a flow chart of the method according to the invention for regulating a wind tracking of an air inlet device 5 and / or an air outlet device 6 in an air heat pump 3, which can be flowed by wind-induced air. The method comprises the steps 16: detecting a

 Wind direction and / or a wind speed, 17: Recognizing a possible better angular position of the air inlet device and / or

Air outlet device, as well as 18: moving and aligning the

Air inlet device and / or the air outlet device according to the detected wind direction. These steps 16, 17, 18 are repeatedly executed in a predefinable temporal periodicity.

Figure 9 shows a flow chart of a detailed embodiment of the method. The wind sensor 11.1, 11.2 detects a wind direction and / or a wind speed by a maximum back pressure and an associated

Angle position can be determined. For this purpose, in step 16.1, a first dynamic pressure in an angular position of the wind sensor 11.1, 11.2 corresponding to the current angular position of the air inlet device 5 is measured. In steps 16.2 and 16.3, a second and a third dynamic pressure are measured in, for example, 45 degrees clockwise and counterclockwise deviating second and third third angular positions. In step 17, the maximum back pressure and the associated angular position of the measured back pressures and

Angle positions determined and evaluated whether this is a possible better angular position to be approached. The angular position of the maximum dynamic pressure is identical to the angle of the wind direction. In step 18, air inlet device 5 and air outlet device 6 on the

Wind direction aligned. In step 19.1, a timer responsible for the periodicity of the method is set to zero, in step 19.2 this timer determines a pause and a subsequent repeated execution of steps 16 to 18.

The inventive method allows a continuous realignment of the air inlet device 5 and air outlet device 6 a

according to the wind direction, when it is detected that a better angular position is possible. Then, the evaporator 4 of the air heat pump 3 is lighter and therefore increasingly flowed through by wind-blown air, so that the fan power for air delivery can be reduced accordingly.

Is inventively provided that the air heat pump 3 a

Wind direction sensor 11.1 and / or has a wind speed sensor 11.2, the following additional advantages can be achieved.

From experience it is known that humidity at low temperatures can lead to frost formation or icing of the evaporator, which causes the

Reduce the efficiency of the heat pump, and that higher air velocities associated with a lower frost formation. Now, for example, based on the measured or detected wind speed, optionally in conjunction with a temperature sensor and / or a humidity sensor, a frost formation rate for the air side of the evaporator 4 can be predicted. Based on the forecast of the frost formation rate and, for example, a

Operating time can predict an absolute frost formation. Derived from this, a signal can then be output to an operator of the heat pump 3, with which he is informed of such icing and a

Necessity for defrosting the evaporator 4 is made aware. On the other hand, it is known that an evaporator 4 is polluted by air particles and therefore has to be cleaned at certain intervals. On the basis of the measured or detected wind speed is now a conclusion on the air flow rate, which flows through the evaporator 4, possible. On the basis of the air volume flow determined in this way and, for example, an operating time, it is possible to predict an air quantity and thus correlatively an expected soiling of the evaporator 4. Derived from this, a signal can then be output to an operator of the heat pump 3, with which he is alerted to such contamination and a need for cleaning.

Claims

claims

Air heat pump (3) with a refrigerant evaporator (4) for obtaining

Environmental heat from air and temperature control of a Nutzfluids, wherein the

Air heat pump (3) of wind-blown air can be flown, comprising a

Air inlet device (5) and a Luitaustrittseinrichtung (6),

characterized in that the air inlet device (5) and / or the

Air outlet device (6) by means of a movable bearing (8) are movably mounted and at least one wind tracking device (9) for tracking air inlet device (5) and / or air outlet device (6) is included.

Air heat pump (3) according to claim 1,

characterized in that the wind tracking device (9) has a

Wind direction sensor (11.1) for detecting a wind direction and / or a

Wind speed sensor (11.2) for detecting a wind speed, wherein the wind direction sensor (11.1) and / or the wind speed sensor (11.2) are adapted to generate control signals, which is a tracking of

Air inlet device (5) and / or air outlet device (6) effect.

Air heat pump (3) according to claim 1 or 2,

characterized in that the wind tracking device (9) a

Adjusting device (12), wherein the adjusting device (12) is designed to carry out a movement of the air inlet device (5) and / or air outlet device (6) as a function of the actuating signal.

Air heat pump (3) according to claim 3,

characterized in that the adjusting device (12) is formed, according to a movement of the air inlet device (5) and / or air outlet device (6)

mechanical, electrical, magnetic, electromotive and / or hydraulic principle to effect.

5. Air heat pump (3) according to one of the preceding claims,

 characterized in that the Windnachführungseinrichtung (9) is adapted to align an air inlet cross-section of the air inlet device (5) in the windward direction of the wind, and / or align an air outlet cross section of the air outlet device (6) in the direction of vacancy of the wind.

6. Air heat pump (3) according to one of the preceding claims,

 characterized in that the movable bearing (8) of air inlet device (5) and air outlet device (6) is a rotatable bearing (8), preferably a rotatable bearing (8) with a vertical axis of rotation.

7. Air heat pump (3) according to one of the preceding claims,

 characterized in that the air inlet means (5) and the

 Air outlet device (6) formed as two separate units and designed for separate movements or coupled movements.

8. Air heat pump (3) according to one of claims 1 to 6,

 characterized in that the air inlet means (5) and the

 Air outlet device (6) formed as a one-piece unit and are mounted as a unit movable together.

9. Air heat pump (3) according to one of the preceding claims,

 characterized in that the air inlet device (5) and / or the

 Air outlet device (6) are formed by attached to an upper portion of the air heat pump (3) intake manifold (5) and / or Ausblaskrümmer (6).

10. Air heat pump (3) according to one of claims 2 to 9,

 characterized in that the wind direction sensor (11.1) and / or the

Wind speed sensors (11.2) are selected from a group comprising wind vane, wind direction sensor, anemoscope, pitot tube, pitot tube, pitot tube, Prandtl tube, anemometer. Air heat pump (3) according to one of the preceding claims, characterized in that the air heat pump (3) comprises a fan (7) for conveying air through the refrigerant evaporator (4), wherein the fan speed depending on the wind speed and / or an air flow through the Refrigerant evaporator (4) and / or a Wärmepumpenheizleistung and / or a Nutzfluidtemperatur is controllable.

Method for regulating a wind tracking of an air inlet device (5) and / or an air outlet device (6) in an air heat pump (3) according to one of the preceding claims, which can be inflowed by wind-blown air,

characterized by the steps

 Detecting (16) a wind direction and / or a wind speed,

• Recognize (17) a possible better angular position of

 Air inlet device (5) and / or air outlet device (6), and

Moving and aligning (18) the air inlet device (5) and / or the air outlet device (6) corresponding to the better ones detected

 Angular position.

Method according to claim 12,

characterized in that the detection of a wind direction by means of a movable about a vertical axis wind vane (9), wherein the wind vane automatically aligns under the influence of the wind in the empty direction of the wind.

14. The method according to claim 12,

 characterized in that the detection of a wind direction and / or a wind speed by determining a maximum dynamic pressure and the associated angular position by means of a movable about a vertical axis dynamic pressure sensor (11.3), wherein

 • a first dynamic pressure in a first angular position of the dynamic pressure sensor

 (11.3) is measured

 • a second back pressure in an angle A clockwise from the

 first angular position horizontally deviating, second angular position of the dynamic pressure sensor (11.3) is measured, and

 A third dynamic pressure is measured in a third angular position of the dynamic pressure sensor (11.3) which deviates horizontally by an angle A in a counterclockwise direction from the first angular position,

 wherein the first angular position of the dynamic pressure sensor (11.3) with the current

 Angle position of the air inlet cross-section is identical, wherein the angle A is a predetermined or predeterminable angle and in the range between 10 degrees and 180 degrees, preferably in the range between 25 degrees and 65 degrees, more preferably in the range between 40 degrees and 50 degrees, and wherein of the

 maximum back pressure and the associated angular position by measurement

 and / or interpolation from the measured back pressures and angular positions are determined.

15. The method according to any one of claims 12 to 14,

 characterized in that the detection of a possible better angular position of the air inlet device (5) and / or air outlet device (6) in dependence on an angular deviation between a current angular position of

Air entrainment device (5) and / or air outlet device (6) and a detected wind direction and depending on the wind speed, wherein at angular deviations greater than or equal to a deviation limit and / or wind speeds greater than or equal to a speed limit, a possible better angular position is detected, and wherein the better angular position with the detected wind direction is identical.

16. The method according to any one of claims 12 to 15,

 characterized in that a speed of a blower (7) for conveying air through the refrigerant evaporator (4) in dependence on the wind speed and / or an air flow rate through the refrigerant evaporator (4) and / or a

 Heat pump heat output and / or a Nutzfluidtemperatur is regulated.

17. The method according to claim 16,

 characterized in that the fan speed is increased when the

 Wind speed and / or the air flow and / or the

 Heat pump heat and / or the Nutzfluidtemperatur below a target value.