Patent Description:
In particular Air Source Heat Pumps (ASHP) take heat from the air and use it to vapourise refrigerants. The component that collects this heat is the evaporator. In cold and damp conditions frost can develop on the evaporator surface that will ultimately block the air passages between the fins and tubes of the evaporators and leave them unable to effectively absorb any useful heat. This has the result that the ASHP cannot function properly and requires the frost to be melted before normal operation can resume.

This means that for example in Air To Water (ATW) ASHP systems a water loop, which can be the heat transport means into a building, will not deliver heating and hot water.

Thus, efficient performance requires the removal of frosting and icing on the evaporator's surface. This operation method is called defrosting and it requires energy input to keep it running such as electric heater-based defrosting, hot-gas-bypass-based defrosting and/or reverse cycle-based defrosting and also by a sub-cooling heat transport process.

<CIT> describes a refrigerator in which a freezing chamber can be defrosted while cooling a refrigerating chamber. The freezing chamber can be defrosted without using a heater.

<CIT> describes an apparatus for heating or cooling a space. The system has a first bypass line extending between an outlet of an outside heat exchanger and an inlet of an inside heat exchanger. A thermal storage device is positioned in the first bypass line. Furthermore, a second bypass line is provided which extends between an inlet of the inside heat exchanger and an outlet of the inside heat exchanger. The second bypass line communicates with the first bypass line to bypass the inside heat exchanger.

A problem in prior art defrosting systems is that heat which is required for defrosting is obtained from the entity which in normal mode is to be heated. If this entity is for example the inside of a building, the temperature inside the building will drop.

It is therefore the object of the present invention to provide a system which allows defrosting without temperature drop at the entity which is to be heated in normal mode.

The object is solved by the heat pump system according to claim <NUM> and the method for defrosting the evaporator of a heat pump system according to claim <NUM>. The respective dependent claims describe advantageous embodiments of the heat pump system according to claim <NUM> and the method for defrosting according to claim <NUM>.

The present invention relates to a heat pump as defined in claim <NUM>.

In the present invention the refrigerant circuit comprises a bypass line which bypasses the heat exchanger. The bypass line can therefore connect a pipe that connects one port of the evaporator with one port of the heat exchanger with a pipe connecting the other port of the evaporator with the other port of the heat exchanger.

According to the present invention, the refrigerant circuit further comprises a heat source which is adapted to heat refrigerant which is routed through the bypass line. This heater according to the invention is in addition to the heat exchanger and the evaporator, thus it is not identical to the heat exchanger, if present, not identical to the condenser and not identical to the evaporator.

In a method for defrosting the evaporator of the heat pump system the refrigerant can be routed through the bypass line and heated by the heater. In this case, the heater can provide the heat which is required for defrosting the evaporator to the refrigerant. As the refrigerant does preferably not pass through the heat exchanger during this defrosting operation, a cooling of the entity to be heated can be avoided.

According to the invention, the heater is located within the bypass line, that is between the pipes connecting the ports of the evaporator and the heat exchanger.

The refrigerant circuit of the present invention comprises an expansion valve located in a line connecting a first port of the heat exchanger with a first port of the evaporator.

The refrigerant circuit comprises a compressor located in the line connecting the second port of the evaporator with a second port of the heat exchanger, wherein each first port is different from each second port. Thus, the expansion valve and the compressor may be located on opposite sides of to the heat exchanger and the evaporator.

In a preferred embodiment of the present invention the bypass line may branch off a line connecting a first port of the evaporator with the first port of the heat exchanger in a first three-way valve and an opposite end of the bypass line may branch off a line connecting the second port, different from the first port, of the evaporator with a second port, different from the first port of the heat exchanger, in a second three-way valve. Thus, the bypass line may be connected to the main refrigerant circuit via a three-way valve. The three-way valves are preferably designed such that they allow to build up a fluid conduit between the evaporator and the bypass line while at the same time shutting off a conduit for the refrigerant from the evaporator to the heat exchanger and from the heat exchanger to the evaporator, respectively.

Above mentioned expansion valve may be preferably located between the bypass line and the evaporator, that is, if the bypass line is connected to the line connecting the evaporator and the heat exchanger via three-way valves, the expansion valve may be located between the evaporator and one of these three-way valves.

Above mentioned compressor may preferably be located between the evaporator and the bypass line. If the bypass line is connected to the other line connecting the heat exchanger and the evaporator via a three-way valve, the compressor may preferably be located between the evaporator and the three-way valve.

The expansion valve and the compressor are preferably located on opposite sides of the evaporator. The expansion valve and the compressor are preferably located on opposite sides of the bypass line.

It is also possible and advantageous if the expansion valve is located between the bypass line and the heat exchanger and/or the compressor is located between the heat exchanger and the bypass line.

In this case, the bypass line may in an advantageous embodiment comprise in series the heater as well as an auxiliary expansion valve, being adapted to expand refrigerant flowing in the bypass line before entering the heater, and/or an auxiliary compressor, being adapted to compress refrigerant flowing through the bypass line after leaving the heater and before entering the evaporator. The auxiliary expansion valve, the heater and the auxiliary compressor may be connected in series, which means that refrigerant flowing into the bypass line in defrost mode first flows through the expansion valve, after flowing out of the expansion valve flows into the heater and after flowing out of the heater flows into the auxiliary compressor.

In the embodiment comprising the auxiliary expansion valve and the auxiliary compressor, the bypass line would be the line comprising the auxiliary expansion valve, the heater and the auxiliary compressor.

Preferably the auxiliary compressor is arranged such that it compresses refrigerant flowing out of the heater and outputs compressed refrigerant in the direction of the evaporator.

In a preferred embodiment of the invention the bypass line may comprise a liquid pump, which is adapted to pump refrigerant flowing in the bypass line. Preferably the liquid pump is connected in series with the heater and it is particularly preferred if the liquid pump is located between a point where the bypass line branches off the line connecting the evaporator with the heat exchanger or the main expansion valve on the one-hand side and the heater on the other hand side. Preferably the liquid pump is located upstream of the heater in defrost mode. Thus, preferably the liquid pump is arranged such that it pumps refrigerant in the direction of the heater.

The invention also relates to above mentioned method for defrosting the evaporator of a heat pump system wherein the heat pump system is constituted as described before. In the defrosting method the refrigerant is routed through the bypass line and heated by the heater.

According to a non-claimed embodiment, the refrigerant is routed from the evaporator to the main expansion valve, from the main expansion valve to the bypass line, from the bypass line to the main compressor and from the main compressor back to the evaporator for defrosting.

If the bypass line branches off between the evaporator and the main expansion valve on one hand side and between the main compressor and the evaporator on the other hand side, the refrigerant in defrost mode may be conducted from the evaporator through the bypass line and back to the evaporator. If in this case the bypass line comprises above mentioned auxiliary expansion valve and above mentioned auxiliary compressor, the refrigerant may be conducted from the evaporator to the auxiliary expansion valve, from the auxiliary expansion valve to the heater, from the heater to the auxiliary compressor and from the auxiliary compressor back to the evaporator.

Preferably the direction in which the compressor compresses refrigerant is reversed in defrost mode compared to normal mode. That is, while in normal mode the compressor preferably compresses the refrigerant flowing out of the evaporator in the direction of the heat exchanger it may in defrost mode compress refrigerant flowing in direction of the evaporator. In the present invention this refrigerant may flow into the compressor out of the bypass line.

In a preferred operation mode of the defrosting method according to the invention it will be decided in a first step whether frosting has occurred at the evaporator. If frosting is present at a evaporator, above mentioned valves are operated such that the heat exchanger is closed off and refrigerant is guided through the bypass line, for example via above mentioned three-way valves. Furthermore, the heater is activated and the compressor is reversed. This operation state is maintained until it is determined that frosting has ended. The method can then proceed with normal operation and can continuously or at specific times monitor whether frosting occurs at the evaporator.

Advantageously, the heat exchanger may comprise a condenser between the first port and the second port by which ports the heat exchanger is connected to the refrigerant circuit.

Advantageously, the heater may for example be an electrical resistance heater. Such a heater may for example wrap around the refrigerant pipe, so that if the heater is power off it does not change the pipe configuration.

In the following the invention shall be described by way of examples with reference to figures. Same reference signs denote same or corresponding features. The features in the examples can be combined among the examples and can be realized independently from this specific example.

The present invention may be realized as an air source heat pump (ASHP) as an example.

<FIG> shows an air source heat pump system according to the prior art. The system in <FIG> comprises on the left hand side a refrigerant circuit comprising an evaporator <NUM>, a compressor <NUM>, a heat exchanger <NUM>, which may comprise a condenser, and an expansion valve <NUM>. On the right hand side the system of <FIG> comprises a heat transport medium circuit, comprising a pump <NUM>, a water tank <NUM> and the heat exchanger <NUM>. Heat can be transferred between the refrigerant circuit and the heat transport medium circuit in the heat exchanger <NUM>. The heat exchanger <NUM> is port of both, the refrigerant circuit and the heat transport medium circuit.

In the heat transport medium circuit the pump <NUM> is connected with the secondary side port of the heat exchanger <NUM> via a pipe <NUM>. The pump <NUM> is connected to the water tank <NUM> via a pipe <NUM>. The water tank on an upper side is connected with an opposite port of the secondary side of the heat exchanger <NUM> via pipe <NUM>. The water tank <NUM> can be used to store water which is conducted into the water tank <NUM> via an inlet pipe <NUM> and out of the water tank via an outlet pipe <NUM>. The water in the water tank <NUM> can be heated by the heat transport medium flowing in the heat transport medium circuit.

In the refrigerant circuit on the left hand side of <FIG>, left of the heat exchanger <NUM>, a refrigerant is pumped by compressor <NUM>. Compressor <NUM> is connected with a first port of a primary side of the heat exchanger <NUM> via a pipe <NUM>. A second port of the primary side of the exchanger <NUM> is connected to the expansion valve <NUM> via a further pipe <NUM>. Expansion valve <NUM> is connected with a first port of evaporator <NUM> via pipe <NUM>. Furthermore, a second port of evaporator <NUM> is connected to the compressor <NUM> via a pipe <NUM>. In the normal mode where heat is pumped towards the water tank <NUM>, the refrigerant flows in the refrigerant circuit as indicated by the arrows on the pipes <NUM>, <NUM>, <NUM> and <NUM>. The heat transport medium and the heat transport medium cycle flows in the direction indicated by the arrows on the pipes <NUM>, <NUM> and <NUM>.

In normal mode, the compressor <NUM> receives refrigerant from the evaporator <NUM> and outputs compressed refrigerant to pipe <NUM> towards the heat exchanger <NUM>.

According to an embodiment useful for understanding the present invention, in a defrost mode the compressor <NUM> reverses its operation direction. Refrigerant therefore flows in the refrigerant cycle as indicated by the dashed arrows. The compressor in defrost mode receives refrigerant through pipe <NUM> from heat exchanger <NUM> and outputs compressed refrigerant to pipe <NUM> towards the evaporator <NUM>. By this, heat is received in the heat exchanger <NUM> from the heat transport medium cycle and pumped to the evaporator <NUM> which is heated and therefore defrosted. However, the heat is obtained from water tank <NUM> which is therefore cooled in defrost mode.

<FIG> shows a first example of a refrigerant circuit. The refrigerant circuit corresponds to the left side of <FIG>. On the right hand side an element <NUM> is shown which could for example be a heat exchanger and which could for example comprise a condenser. If element <NUM> is a heat exchanger, heat can for example be exchanged with an optional heat transport medium circuit as shown on the right hand side in <FIG>. Alternatively the element <NUM> as a condenser could exchange heat with outside air or could provide heat to any other entity to be heated. In the following only the refrigerant cycle will be regarded while the entity to be heated can for example be a heat transport medium cycle as shown in <FIG> or a different entity to be heated.

The refrigerant cycle in <FIG> comprises the heat exchanger or condenser <NUM>. A first port of the condenser or heat exchanger <NUM> is connected via a pipe <NUM> to a three-way valve <NUM>. Three-way valve <NUM> is connected to a main expansion valve <NUM> via a pipe <NUM>. Main expansion valve <NUM> is connected to a first port of an evaporator <NUM> via a pipe <NUM>. A second port, different from the first port, of the evaporator <NUM> is connected to a compressor <NUM> via a pipe <NUM>. Compressor <NUM> is connected with a second three-way valve <NUM> via a pipe <NUM>. One port of the second three-way valve <NUM> is connected to the heat exchanger <NUM> or condenser <NUM> via a pipe <NUM>. Another port of the second three-way valve <NUM> is connected to a heater <NUM> via a pipe <NUM>. The heater <NUM> is connected with another port of the first three-way valve <NUM> via a pipe <NUM>.

The pipes <NUM> and <NUM> together with the heater <NUM> constitute a bypass line which bypasses the heat exchanger <NUM> or condenser <NUM>. The heater <NUM> may advantageously be an electrical heater <NUM> in all embodiments of the present invention.

In <FIG> arrows on the pipes indicate a flow direction of refrigerant in normal mode where heat is transported from the evaporator <NUM> to the condenser <NUM> or heat exchanger <NUM>. In normal mode the first three-way valve <NUM> is set such that line <NUM> is connected to line <NUM> in refrigerant conducting manner and the second three-way valve <NUM> is set such that line <NUM> is connected with pipe <NUM> in a refrigerant conducting manner. On the other hand, the three-way valves <NUM> and <NUM> are set such that refrigerant is not guided into the bypass line.

In normal mode, the compressor <NUM> is operated such that it receives refrigerant coming from the evaporator <NUM> through pipe <NUM> and outputs compressed refrigerant into pipe <NUM> towards the second three-way valve <NUM>.

<FIG> shows the refrigerant circuit shown in <FIG> in defrost mode, in which evaporator <NUM> is defrosted. The ports and the relative connection of the ports is the same as in <FIG>. Reference is made to above description of <FIG>.

Differently from <FIG> the refrigerant in the defrost mode shown in <FIG> flows as indicated by the arrows on the lines. In defrost mode the first three-way valve <NUM> is set such that refrigerant coming from the main expansion valve <NUM> through line <NUM> is guided into pipe <NUM> of the bypass circuit. Pipe <NUM> connected with the heat exchanger <NUM> or condenser <NUM> is shut off. Furthermore, the second three-way valve <NUM> is set such that refrigerant flowing into the three-way valve <NUM> from line <NUM>, the refrigerant coming from the heater <NUM>, is guided towards the compressor <NUM> via pipe <NUM>. Compressor <NUM> operates in reverse direction as compared to normal mode shown in <FIG>. That is, the compressor <NUM> receives refrigerant from pipe <NUM> and outputs compressed refrigerant into line <NUM> towards the evaporator <NUM>. In defrost mode the heater <NUM> is operated so that refrigerant flowing through the heater <NUM> is heated. The heated refrigerant is conducted to the evaporator <NUM> and defrosts evaporator <NUM>.

<FIG> shows a flow diagram of an operation of the system shown in <FIG> and <FIG>. The system monitors S1 whether frosting occurs at the evaporator. The monitoring can happen continuously or at predetermined or regular times. If it is determined in S1 that frosting has occurred the three-way valves <NUM> and <NUM> are actuated in S2 to close off the condenser <NUM>. Refrigerant is allowed to flow through bypass line <NUM>, <NUM> and <NUM> via the three-way valves <NUM> and <NUM> in S3. In S4 the heater <NUM> is activated and in S5 the compressor <NUM> is reverted. The system is run in this state for a period of time in S6 and is monitored in S7 whether frosting has ended. If frosting has not ended, the system is further run in defrost mode in S6. On the other hand, if frosting has ended, the system returns to normal mode, which is not explicitly shown in <FIG>. The return to normal mode reverses the actions S2, S3, S4 and S5. It should be noted that the actions S2, S3, S4 and S5 can happen at the same time or in any other order than shown in <FIG>.

<FIG> shows a further example of a refrigerant circuit and a heat pump system according to the present invention.

A heat exchanger <NUM> or condenser <NUM> is connected with a main expansion valve <NUM> via pipe <NUM>. Main expansion valve <NUM> is connected to a first three-way valve <NUM> via pipe <NUM>. First three-way valve <NUM> is connected to an evaporator <NUM> via a pipe <NUM>. The evaporator <NUM> is connected to a second three-way valve <NUM> via a pipe <NUM>. The second three-way valve <NUM> is connected to a compressor <NUM> via a pipe <NUM>. The compressor <NUM> is connected to the opposite port of the heat exchanger <NUM> or condenser <NUM> via pipe <NUM>. A third port of the three-way valve <NUM>, which is not connected to the pipes <NUM> and <NUM> is connected with an auxiliary expansion valve <NUM> via a pipe <NUM>. The auxiliary expansion valve <NUM> is connected to a heater <NUM> via pipe <NUM>.

A third port of the second three-way valve <NUM>, which is not connected with pipes <NUM> and <NUM>, is connected with an auxiliary compressor <NUM> via a pipe <NUM>. The auxiliary compressor <NUM> is connected to the heater <NUM> via a pipe <NUM>.

In this example the line comprising pipe <NUM>, auxiliary expansion valve <NUM>, pipe <NUM>, heater <NUM>, pipe <NUM>, auxiliary compressor <NUM> and pipe <NUM> can be regarded as the bypass line.

<FIG> shows the system in normal mode. The flow of the refrigerant is indicated by arrows on the lines. It is indicated that the refrigerant only flows in the main refrigerant circuit through main expansion valve <NUM>, three-way valve <NUM>, evaporator <NUM>, three-way valve <NUM>, compressor <NUM>, condenser <NUM> or heat exchanger <NUM> and back to the main expansion valve <NUM>. As in the other figures compressor <NUM> receives refrigerant from the evaporator <NUM> and outputs compressed refrigerant to the condenser or heat exchanger <NUM>. The bypass line is shut off by the three-way valves <NUM> and <NUM> in normal mode.

<FIG> shows the same setup as <FIG>, however, being switched to defrost mode. Again the arrows on the lines indicate the flow of the refrigerant. It can be seen that the three-way valves <NUM> and <NUM> are set such that refrigerant flows in the bypass line. The refrigerant flows out of the evaporator <NUM> through the first three-way valve <NUM> into the auxiliary expansion valve <NUM> and from the auxiliary expansion valve <NUM> through the heater <NUM> into the auxiliary compressor <NUM>. The refrigerant is received by the auxiliary compressor <NUM> from the heater <NUM> and is compressed and the compressed refrigerant is output to the evaporator <NUM> via the second three-way valve <NUM>. The main refrigerant circuit comprising the main expansion valve <NUM>, the condenser <NUM> and the main compressor <NUM> is shut off in defrost mode by the three-way valves <NUM> and <NUM>.

Via the bypass circuit heat is transported to the evaporator <NUM> and heat <NUM> is set free at the evaporator <NUM> to defrost the evaporator <NUM>.

<FIG> shows an operation of the system shown in <FIG> and <FIG>. The operation is very similar to the operation shown in <FIG>. Reference is therefore made to the description of <FIG>. However, different from <FIG> it is not necessary in S5 to reverse the compressor. Instead, the auxiliary compressor <NUM> is activated in S5. It should also be noted that differently from <FIG> and <FIG> the refrigerant does not flow through the main expansion valve <NUM> in defrost mode but rather through the auxiliary expansion valve <NUM>.

<FIG> shows another advantageous embodiment of the present invention.

The main refrigerant circuit in <FIG> is of the same structure as in <FIG> and <FIG>. That is, the main expansion valve <NUM> is connected to the first three-way valve <NUM> via pipe <NUM> and the first three-way valve <NUM> is connected to the evaporator <NUM> via pipe <NUM>. The evaporator <NUM> is connected to a second three-way valve <NUM> via pipe <NUM> and the second three-way valve <NUM> is connected to the compressor <NUM> via pipe <NUM>. The compressor <NUM> is connected to the condenser <NUM> via pipe <NUM> and the condenser <NUM> is connected to the main expansion valve <NUM> via pipe <NUM>.

Differently from <FIG> and <FIG> a third port of the first three-way valve <NUM>, which port is not connected to lines <NUM> or <NUM>, is connected to a liquid pump <NUM> via a pipe <NUM>. Liquid pump <NUM> is connected to a heater <NUM> via a pipe <NUM>. The heater <NUM> is connected to a third port of the second three-way valve <NUM>, which third port is not connected to pipe <NUM> or <NUM> via pipe <NUM>. In this example the circuit comprising the liquid pump <NUM>, the heater <NUM> and the pipe <NUM> can be regarded as the bypass circuit.

<FIG> shows the system in normal mode. The normal mode of this circuit is identical to the normal mode shown in <FIG> as the bypass circuit is shut off equally in <FIG> and <FIG>. Reference to the description above is therefore made here.

<FIG> shows the system of <FIG> operating in defrost mode. Again, the black arrows indicate the flow of the refrigerant. It can be seen that the first three-way valve <NUM> and the second three-way valve <NUM> are set such that refrigerant flowing out of the evaporator <NUM> is conducted to the liquid pump <NUM>. The liquid pump <NUM> pumps the refrigerant into the heater <NUM> and out of the heater <NUM> through pipe <NUM> and the second three-way valve <NUM> back into the evaporator <NUM>. The main refrigerant circuit comprising the main expansion valve <NUM>, the condenser <NUM> and the compressor <NUM> is shut off in defrost mode in this embodiment.

Claim 1:
Heat pump system comprising
a refrigerant circuit,
the refrigerant circuit comprising an evaporator (<NUM>) and
a heat exchanger (<NUM>) which is adapted to exchange heat between the refrigerant circuit and an entity to be heated,
wherein
the refrigerant circuit further comprises a bypass line bypassing the heat exchanger(<NUM>)
and the refrigerant circuit in addition to the heat exchanger (<NUM>) and the evaporator (<NUM>) comprises a heater (<NUM>) which is adapted to heat refrigerant which is routed through the bypass line,
characterised in one of the following:
- the refrigerant circuit comprising a main expansion valve (<NUM>) located between a first port of the heat exchanger (<NUM>) and the evaporator (<NUM>) and the refrigerant circuit further comprising a main compressor (<NUM>) located between the evaporator (<NUM>) and a second port, different from the first port, of the heat exchanger (<NUM>), the main expansion valve (<NUM>) is located between the bypass line and the heat exchanger (<NUM>) and/or the main compressor (<NUM>) is located between the heat exchanger (<NUM>) and the bypass line , and the bypass line comprising in series the heater (<NUM>) as well as an auxiliary expansion valve (<NUM>), being adapted to expand refrigerant flowing in the bypass line before entering the heater (<NUM>), and/or an auxiliary compressor (<NUM>), being adapted to compress refrigerant flowing through the bypass line after leaving the heater (<NUM>) and before entering the evaporator (<NUM>);
- the refrigerant circuit comprising a main expansion valve (<NUM>) located between a first port of the heat exchanger (<NUM>) and the evaporator (<NUM>) and the refrigerant circuit further comprising a main compressor (<NUM>) located between the evaporator (<NUM>) and a second port, different from the first port, of the heat exchanger (<NUM>), the main expansion valve (<NUM>) is located between the bypass line and the heat exchanger (<NUM>) and/or
the main compressor (<NUM>) is located between the heat exchanger (<NUM>) and the bypass line , and the refrigerant circuit comprising a liquid pump (<NUM>), being adapted to pump refrigerant flowing in the bypass line, the liquid pump (<NUM>) being preferably connected in series with the heater (<NUM>) between a point where the bypass line branches off the line connecting the evaporator (<NUM>) with the main expansion valve (<NUM>) and the heater (<NUM>).