DE102007056461A1 - Heat pump type-hot water supply device, has heat pump controller with current sensor for recording current value of electrical power, where frequency is increased, when current value is smaller than specific regenerative current value - Google Patents

Abstract

The device has a heat pump controller with a current sensor (23) for recording a current value of electrical power, where the value is supplied to a heat pump. The controller has a regular operation mode with which a frequency of the power is lowered, when the current value exceeds a preset upper limit value. The frequency is increased, an opening of an expansion valve is enlarged and a target discharge temperature of a cooling medium is lowered, when the current value is smaller than a specific regenerative current value, which is smaller than the upper limit value.

Description

The The present invention relates to hot water supply devices and in particular, a heat pump type hot water supply device using a refrigerant.

In recent years, hot water supply devices using a heat pump have been widely used in view of the energy saving possibility. General points, as in 7 shown, this type of hot water delivery devices, a sink 1 , a heat pump 2 for heating externally supplied water, a hot water storage tank 3 for storing by the heat pump 2 heated hot water, and a conduit 4 in the storage tank 3 stored hot water to the tub 1 to lead up.

Specifically, as in 8th shown the heat pump 2 provided with: a compressor 6 for compressing a refrigerant by its compression force, which is controlled by the frequency of the electrical drive power supplied thereto; a refrigerant-water heat exchanger 8th that with the outlet of the compressor 6 through a first conduit 7a for transferring the thermal energy stored in the refrigerant to that in the storage tank 3 stored water is connected; an expansion valve 9 connected to the outlet of the refrigerant-water heat exchanger 8th through a second conduit 7b for expanding the refrigerant, wherein the heat exchange in the refrigerant-water heat exchanger 8th is done, is connected; an air-refrigerant heat exchanger 10 , with the outlet of the expansion valve 9 through a third pipe 7c for transferring the thermal energy stored in the air to the refrigerant; a fourth conduit 7d to the refrigerant, in which the heat exchange in the air-refrigerant heat exchanger 10 is done, to the compressor 6 to lead; an ejection temperature sensor 11 for determining the temperature of the compressor 6 discharged refrigerant; and a heat pump controller 12 for comparing that by the ejection temperature sensor 11 determined refrigerant temperature with a predetermined target discharge temperature and for regulating the operation of the compressor 6 so that the deviation between the temperatures can be reduced.

Also is a pressure collector 13 in the fourth pipe 7d between the air-refrigerant heat exchanger 10 and the compressor 6 connecting them, inserted to the compressor 6 to protect from a compression of liquid, in the event that a complete evaporation of the refrigerant in the air-refrigerant heat exchanger 10 fails. Further, an internal heat exchanger 14 over the second and fourth pipe 7b and 7d inserted to that through the second conduit 7b Cooling refrigerant cooling through the heat exchange with that through the fourth conduit 7d to allow flowing refrigerant (low-temperature refrigerant).

The heat pump controller 12 has a current sensor (not shown in FIG 8th ) for determining the to the heat pump 2 supplied power value of the drive power. The heat pump controller 12 monitors the current value detected by the current sensor and carries out a control operation such that an overload operation of the compressor 6 can not expire. A heat pump regulator apparatus adapted to perform this type of heat pump control is known in the art (see, eg, Examined Japanese Patent Publication No. H05-54022 ).

In the for this type of heat pump controller device typical heat pump control will be overloaded when the compressor is on, the heat pump on the basis of the current value determined by the current sensor. Specifically, if the power supplied to the compressor is a exceeds the predetermined upper limit current value applied to the compressor Drive power frequency lowered, i. the operating mode becomes switched to a regulated operating mode. If after that Decrease of the current value below a predetermined regulation value, which is less than the upper limit current value is detected, raises the heat pump controller the Antriebsleistungsfrequentz to the operating mode to a to switch to normal operating mode.

With this heat pump control technology However, sometimes the case arises that the operating mode soon after switching from the regulated operating mode to the normal operating mode switch back to the regulated operating mode, which is the control process makes it unstable. Especially in cases, at where the compressor is controlled alone, as mentioned above the heat pump control unable to with the increase of the current supplied to the heat pump to cope, which makes it difficult to achieve stable operation.

The The object of the present invention is therefore to provide a hot water supply device, in the case of a suspension or an unstable operation due to an overcurrent even under overload conditions is avoided, and therefore the device is allowed to secure To get operation.

These The object is solved by the features of claim 1. advantageous Embodiments of the invention are characterized in the subclaims.

The present invention provides a hot water supply device, comprising: a heat pump; and a storage tank for storing the heat pump heated be called Water.

The heat pump includes a compressor for compressing a refrigerant with a compaction force that has a frequency applied to it electrical drive power is controlled, and a refrigerant-water heat exchanger, at an outlet of the Compressor through a first conduit for transferring the refrigerant stored thermal energy stored in the storage tank Water is connected. Furthermore, the heat pump includes an expansion valve with a variable opening and is with an outlet of the refrigerant-water heat exchanger through a second connecting line for expanding the refrigerant, in which the heat exchange in the refrigerant-water heat exchanger is done, connected. Furthermore, the heat pump includes an air-refrigerant heat exchanger, which with a Outlet of the Expansion valve through a third conduit for transfer the thermal energy stored in the air to the refrigerant connected, and a fourth conduit to the refrigerant, in which the heat exchange in the air-refrigerant heat exchanger is done, to conduct to the compressor. Also includes the heat pump an ejection temperature sensor for determining the refrigerant temperature discharged from the compressor, and a Heat Pump controller for comparing the determined by the ejection temperature sensor Refrigerant temperature with a predetermined target ejection temperature, and for controlling the compression force of the compressor by such a Adjust the frequency of the electric drive power so that a deviation between the determined refrigerant temperature and the predetermined target discharge temperature zero becomes. The heat pump controller includes a current sensor for detecting a to the heat pump supplied current value of the electric drive power and has a regulated mode of operation in which, if by the current sensor determined current value exceeds a predetermined upper limit current value, the frequency of the electrical power supplied to the compressor is lowered, and if then determined by the current sensor Current value becomes smaller than a predetermined recovery current value, is smaller than the upper limit current value, the frequency of the raised electrical drive power, the opening of the Expansion valve is enlarged, and the target discharge temperature for the ejected from the compressor refrigerant is lowered.

Therefore In the regulated operating mode, it is the one in the heat pump lowered compressor supplied drive power frequency, when passing through the current sensor, which is used to detect the heat pump supplied current of the drive power, determined current value exceeds the predetermined upper limit current value, and if the thereafter, the current value determined by the current sensor becomes smaller than the preset recovery current value is raised the frequency of the drive power, with the opening of the Expansion valve enlarged, and the target discharge temperature of the ejected from the compressor refrigerant is lowered. Consequently, even in cases where the heat pump is overloaded is a stable operation of the heat pump continued become.

Preferably the heat pump controller switches the power supply to the compressor when the frequency of the electrical drive power to drive the compressor equal a predetermined minimum frequency, and also by the current sensor determined current value is greater as a predetermined current value.

Therefore when the frequency of the supply voltage for driving the compressor is equal to the minimum frequency, and at the same time by the current sensor determined current value is greater as the preset current value, the power supply to the compressor switched off, whereby a high level of security is ensured.

At the compressor will be one of the predetermined different Applied frequencies of the electric drive power, and the heat pump controller lowers the present applied frequency of the electric drive power, if for a given Duration continuously a current value is determined, the predetermined upper limit current value associated with the currently applied frequency is, exceeds.

Preferably the heat pump controller raises the currently applied frequency of the electrical drive power, if continuous a current value less than one of the currently applied frequency assigned predetermined recovery current value determined becomes.

Also breaks the heat pump controller the regulated operating mode when the frequency of the electric Drive power to one before switching to the regulated Operating mode applied frequency returns.

Preferably breaks the heat pump controller the regulated operating mode when the frequency of the electric Drive power after switching to the regulated operating mode when starting the compressor to a predetermined target drive frequency returns.

Preferably breaks over it addition, the heat pump controller the regulated operating mode, if after switching to the regulated operating mode during defrost control operation ends defrost control operation.

Also if the regulated operating mode is aborted, the heat pump for one predetermined period of time the application of the then-adjacent frequency of electrical drive power to the compressor continues.

In this way will be when the regulated operating mode is canceled is the compressor with the frequency of the electric drive power, on the then-adjacent frequency for a given period of time is maintained, the operating mode on a renewed Switch to the regulated operating mode shortly after the return from the regulated mode of operation, is hindered, and therefore practical Advantages, such as Control stability, result.

With the above hot water supply device can exposure or unstable operation of the heat pump due to the flow of an overcurrent while an overload operation be prevented, and the operation can be safely continued.

One Another field of application of the present invention will be apparent from the the following detailed description. However, should be clear that the detailed description and the specific example that the preferred embodiments of the invention, for illustrative purposes only, because different changes and modifications within the spirit and scope of the invention for the expert will be apparent from the detailed description.

The Type of invention as well as other objects and advantages thereof in the following with reference to the accompanying drawings, wherein in the figures, the same reference numerals designate the same or similar Name parts, and where:

1 Fig. 10 is a schematic block diagram of a power supply section for driving a compressor in a hot water supply device according to a first embodiment of the present invention;

2 Fig. 10 is a flowchart illustrating an operation of the hot water supplying device of the embodiment;

3 indicate preset upper limit current values and recovery current values for respective drive power frequencies;

4 a flow chart is a startup run of the in 2 illustrates occurring control process;

5 a flow chart is a flow for a in 2 occurring normal control process illustrated;

6 a flow chart is a flow for a in 2 occurring defrost control process illustrated;

7 shows a schematic arrangement of a hot water supply device using a heat pump; and

8th is a schematic block diagram of a main part of the heat pump.

A preferred embodiment of the present invention will be described below with reference to the attached drawings. 1 to 6 illustrate the operation of a hot water supply device with a heat pump according to the embodiment. The hot water supply device and the heat pump have basic designs, each with those in 7 and 8th are shown identical and therefore no further explanation is given below about the arrangements here (hereinafter also a reference to the in the 7 and 8th made shown parts).

The in 1 shown compressor 6 Eg by an induction motor, in turn, by an inverter 20 is driven and is able to vary the supplied to the electric motor frequency of the electric drive power in such a way to rotate it. The inverter 20 is with the DC power of a converter 22 an input for a direct current, the converter 22 is adapted to an alternating current with a commercial frequency coming from a commercial power supply 21 is delivered to convert to DC. A current sensor 23 gets into the primary side of the converter 22 inserted to that of the commercial power supply 21 supplied electrical current, which is determined by the current sensor 23 determined current value to the heat pump controller 12 is delivered.

The heat pump controller 12 operates the heat pump according to one in the flow chart of 2 2, and includes a start-up control operation described later in detail, a normal control operation, and a defrost control operation.

When the power is turned on, the heat pump controller starts 12 a standby process (step S1), in which the heat pump controller 12 waiting for an input of an operation instruction from a control panel, not shown. Upon receipt of a warming operation command (step S2) during the standby operation, the heat pump controller proceeds to an operation (step S3). In the operation, the heat pump controller calculates 12 a required hot water supply capacity and the like based on the outside air temperature detected by an outside air temperature sensor, not shown, and the temperature of the heat pump 2 introduced water, etc. and determines operating conditions (step S4), such as a to be applied to the compressor target drive frequency.

After determining the operating conditions, the heat pump controller exercises 12 a starting control process for the heat pump 2 (Step S5). In the starting control process is the the compressor 6 applied driving power frequency is gradually increased at predetermined time intervals T, and at the same time, the opening of the expansion valve 9 gradually increased so that the operating conditions determined in step S4 can be met. The startup control process is continued until the operating conditions determined in step S4 are satisfied, and when the startup of the heat pump 2 is judged completed (step S6), the heat pump controller passes 12 a normal control process (step S7).

After the normal control process, the heat pump controller compares 12 the temperature of the heat pump 2 returned water having a pre-specified water-end temperature (step S8), and if the earlier value is judged to be greater than the latter value, the heating operation is ended (step S9), and the process returns to the stand-by process (step S1).

Also if during of the normal control operation (step S7), it is judged that defrosting is being performed If necessary, the process proceeds to a defrost control operation (step S10), and then step S5 and subsequent steps run again.

The above is an overview of the operation of the hot water supply device according to the present invention, and in the following, the control features characterizing the present invention will be explained in more detail. The through the heat pump controller 12 to the compressor 6 applied driving power frequency can be varied to a plurality of different frequencies by successively adding a predetermined frequency step .DELTA.f to a minimum frequency f. The drive power frequency, namely the output frequency of the inverter 20 , is incrementally increased from the minimum frequency f until a predetermined drive capacity is reached. Also, as in 3 shown, an upper limit (upper limit current value) for the compressor 6 supplied current, and a recovery current value with respect to the respective drive frequencies set in advance. The recovery current value is used as a reference when the drive frequency, and therefore the drive capacity, is due to overcurrent flow through the compressor 6 , which is caused by an overload or the like, is increased again, and is avoided by a temporary lowering of the drive frequency and therefore the drive capacity. The current values associated with the respective drive frequencies are related to each other: I _r <I ₀ <I ₁ <I ₂ <... <I ₅ <I ₆ <I ₇ , and are set, for example, such that the one associated with a particular drive frequency upper limit current value is equal to the recovery current value, which is the drive frequency, which is greater by a step .DELTA.f greater than the predetermined drive frequency assigned.

In the start-up control operation performed by the aforementioned step S5, the heat pump controller performs 12 in the 4 shown steps. First, the heat pump controller determines 12 whether by the current sensor 23 detected current indicates a value which is greater than or equal to the upper limit current value, that of the compressor 6 (Step S20) is assigned to currently applied drive power frequency or not.

If it is judged in step S20 that the detected current value is greater than or equal to the upper limit current value associated with the currently applied drive power frequency, the heat pump controller determines 12 whether or not the overcurrent supply has continued for a predetermined period of time ta (eg, about 5 seconds) (step S21).

If in step S21, it is judged that the time period during which the determined current value is greater than or equal to is equal to the upper limit current value, shorter than the predetermined one Time ta, the heat pump controller returns back to step S20 and leads the surveillance of the detected current.

On the other hand, if it is judged in step S21 that the detected current value is greater than or equal to the upper limit current value for a predetermined period of time ta, the heat pump controller determines 12 whether the current on the compressor 6 applied driving power frequency is the minimum frequency or not (step S22). If it is judged in step S22 that the present at the compressor 6 applied drive power frequency is not the minimum fre the heat pump controller lowers 12 the at the compressor 6 to be applied drive power frequency by one step. For example, if the current drive power frequency is f + 4Δf, the drive power frequency f + 3Δf, which is one step (Δf) smaller than the current frequency, is applied to the compressor 6 created (step S23). The heat pump controller 12 then ends the startup control process (step S24) and switches the operation mode to the regulated operation mode (step S25).

Then the heat pump controller beats 12 in the 3 according to the values shown, to determine whether the current sensor 23 detected current indicates a value that is less than or equal to the recovery current value, that of the compressor 6 or not currently applied, lowered drive frequency is assigned (step S26). Then the heat pump controller determines 12 whether or not the detected current value is smaller than or equal to the restoration current value over a predetermined time tb (eg, about 20 seconds), and if it is judged that the predetermined time tb has been exceeded, it is determined whether the current one at the compressor 6 applied drive power frequency has reached the target drive frequency or not (step S28). If it is judged in step S28 that the drive power frequency has reached the target drive frequency, the heat pump controller breaks 12 the regulated operating mode and starts the normal control process (step S29).

If it is judged in step S27 that the period in which the detected current value is less than or equal to the recovery current value is shorter than the predetermined time tb, the heat pump controller returns 12 back to step S26 and continues to monitor the detected current. Even if it is judged in step S28 that the target drive frequency is not reached, the heat pump controller performs 12 repeat step S25 and subsequent steps to continue the regulated mode of operation.

Furthermore, the heat pump controller stops 12 the operation of the compressor 6 (Step S30) on the assumption that any abnormality (error) has occurred if it is judged in Step S22 that the currently applied drive power frequency is the minimum frequency. Even if it is judged in step S26 that by the current sensor 23 detected current value is greater than the recovery current value, that of the compressor 6 currently applied, lowered drive frequency is assigned determines the heat pump controller 12 whether or not the detected current indicates a value greater than or equal to the upper limit current value associated with the lowered drive frequency (step S31).

If it is judged in step S31 that the detected current value is smaller than the upper limit current value associated with the lowered drive frequency, the heat pump controller performs 12 again step S25 and the subsequent steps. On the other hand, if it is judged that the detected current value is greater than or equal to the upper limit current value, it is determined whether the detected current value over the predetermined time ta is greater than or equal to the upper limit current value (step S32). If it is judged in step S32 that the predetermined period of time ta has not yet been exceeded, the heat pump controller performs 12 again step S25 and the subsequent steps; if it is judged that the predetermined time ta has elapsed, step S22 and subsequent steps are executed.

Therefore, the heat pump controller lowers 12 if that through the current sensor 23 detected current value is greater than the regeneration current value and at the same time greater than or equal to the same drive frequency associated upper limit current value, the compressor to be applied drive power frequency by one step, unless the drive power frequency is equal to the minimum frequency, and performs the operation using the upper limit current value and the regeneration current value associated with the lowered drive frequency continues as criteria.

The through the heat pump controller 12 Normalsteuervor applied in the hot water supply device of the present invention will now be with reference to the flow chart of 5 described in more detail. First, the heat pump controller determines 12 whether by the current sensor 23 detected current indicates a value that is greater than or equal to the upper limit current value, that of the compressor 6 or not currently applied drive power frequency (step S40). If it is judged in step S40 that the detected current value is greater than or equal to the upper limit current value, the heat pump controller determines whether the overcurrent supply has continued for the predetermined time period ta (eg, about 5 seconds) (step S41). Then, if it is judged in step S41 that the period in which the detected current value is greater than or equal to the upper limit current value is shorter than a predetermined time period ta, the heat pump controller returns 12 back to step S40 and continues to monitor the detected current.

On the other hand, if it is judged in step S41 that the detected current value over the predetermined time ta is greater than or equal to the upper limit current value, the heat pump controller determines 12 whether the to the compressor 6 to be applied drive power frequency of the minimum frequency or not (step S42). If in step S42 It is judged that the compressor 6 currently applied drive power frequency does not correspond to the minimum frequency, the heat pump controller lowers 12 the drive power frequency by one step (step S43).

Then the heat pump controller switches 12 the operation mode to the regulated operation mode (step S44). The heat pump controller 12 then beats the in 3 according to the values shown, to determine whether the current sensor 23 detected current indicates a value which is less than or equal to the recovery current value, that of the compressor 6 or not currently applied, lowered drive frequency is assigned (step S45). Then the heat pump controller determines 12 Whether or not the detected current value is less than or equal to the restoration current value for a predetermined time tb (eg, about 20 seconds) (step S46). If it is judged that the predetermined time tb has been exceeded, the heat pump controller raises the compressor 6 applied drive power frequency by one stage, which also increases the opening of the expansion valve, and the target temperature value (target discharge temperature) of the compressor 6 discharged refrigerant is lowered (step S47). In step S47, the heat pump controller lowers 12 namely the compressor 6 applied load to the flow of current to the compressor 6 to reduce. Then the heat pump controller returns 12 to step S44 and performs step S44 and subsequent steps.

If it is judged in step S42 that the drive power frequency corresponds to the minium frequency, the heat pump controller stops 12 the operation of the compressor 6 (Step S48) on the assumption that some abnormality (error) has occurred. If it is judged in step S45 that the signal passing through the current sensor 23 detected current value is greater than the recovery current value, that of the compressor 6 currently applied, lowered drive frequency is assigned determines the heat pump controller 12 whether or not the current detected by the current sensor indicates a value that is greater than or equal to the upper limit current value associated with the lowered drive frequency (step S49).

If it is judged in step S49 that the detected current value is not greater than or equal to that of the lowered drive frequency associated upper limit current value, the heat pump controller performs 12 again step S44 and the subsequent steps. On the other hand, if it is judged that the detected current value is greater than or equal to the upper limit current value, it is determined whether the detected current value over the predetermined period ta is greater than or equal to the upper limit current value (step S50). If it is judged in step S50 that the predetermined period ta has not yet been exceeded, the heat pump controller performs 12 again step 544 and the subsequent steps; if it is judged that the predetermined time ta has elapsed, step S42 and subsequent steps are executed.

The through the heat pump controller 12 The defrosting operation performed in the hot water supply device of the present invention will now be described with reference to the flowchart of FIG 6 described in more detail. First, the heat pump controller determines 12 whether that's through the current sensor 23 detected current indicates a value which is greater than or equal to the current drive frequency associated with the associated upper limit current value or not (step S60). If it is judged in step S60 that the detected current value is greater than or equal to the upper limit current value associated with the current drive frequency, the heat pump controller determines 12 whether the overcurrent delivery has continued over the predetermined time period ta (eg, about 5 seconds) (step S61).

If it is judged in step S61 that the period in which the detected current value is greater than or equal to the upper limit current value is shorter than the predetermined period ta, the heat pump controller returns to step S60 and continues to monitor the detected current. On the other hand, if it is judged in step S61 that the detected current value over the predetermined period of time ta is greater than or equal to the upper limit current value, the heat pump controller determines 12 whether the on the compressor 6 currently applied drive power frequency of the minimum frequency or not (step S62).

If it is judged in step S62 that the compressor 6 currently applied drive power frequency does not correspond to the minimum frequency, the heat pump controller lowers 12 the to the compressor 6 to be applied drive power frequency by one step (step S63).

Then the heat pump controller switches 12 the operation mode to the regulated operation mode (step S64). The heat pump controller 12 then determines whether the defrost control is being executed (step S65) or not, and if it is judged that the defrost control is being executed, the heat pump controller determines 12 whether by the current sensor 23 detected current shows a value that is less than or equal to the recovery current value, that of the compressor 6 or not currently applied, lowered drive frequency is assigned (step S66). The heat pump controller then determines 12 whether the detected current value over the predetermined time tb (eg, about 20 seconds) is less than or equal to the recovery current value (step S67). If beur it is informed that the predetermined time tb has not yet been exceeded, the heat pump controller returns to step S66 and repeats the comparison; if it is judged that the predetermined time tb has elapsed, the heat pump controller returns to step S60 and continues the control. If it is decided in step S65 that the defrosting control is not executed and ended, the heat pump controller aborts the regulated operation mode and starts the normal control operation (step S69).

Further, if it is judged in step S62 that the present drive power frequency corresponds to the minimum frequency, the heat pump controller stops 12 the operation of the compressor 6 (Step S68) on the assumption that some abnormality (error) has occurred. The heat pump controller also determines 12 if it is judged in step S66 that the current value detected by the current sensor is greater than the regeneration current value associated with the lowered drive frequency, if the current detected by the current sensor indicates a value greater than or equal to the upper limit current value associated with the lowered drive power frequency, or not (step S70).

If it is judged in step S70 that the detected current value is smaller than the upper limit current value associated with the lowered drive frequency, the heat pump controller performs 12 again step S64 and the subsequent steps. On the other hand, if it is judged that the detected current value is greater than or equal to the upper limit current value, it is determined whether the detected current value is greater than or equal to the upper limit current value over a predetermined period ta (step S71). If it is judged in step S71 that the predetermined period ta has not yet been exceeded, the heat pump controller performs 12 again step S64 and subsequent steps; if it is judged that the predetermined time ta has elapsed, step S62 and subsequent steps are executed.

As explained above, in the hot water supply device according to the present invention, the to the compressor 6 in the heat pump 2 applied drive power frequency lowered, if that to the heat pump 2 supplied current value of the drive power generated by the current sensor 23 is greater than or equal to the corresponding upper limit current value over a first predetermined period of time. Then, the operation mode is switched to the regulated operation mode in which the drive power frequency is raised, with the opening of the expansion valve 9 is increased, and the target discharge temperature for the compressor 6 discharged refrigerant is lowered, if by the current sensor 23 detected current value over a second predetermined period of time is less than or equal to the corresponding recovery current value. Consequently, even the safe operation of the heat pump 2 be preserved if the heat pump 2 overloaded.

Also, with the hot water supply device of the present invention, the power supply to the compressor 6 shut off, thereby ensuring a high level of safety when passing through the current sensor 23 detected current value is greater than or equal to the corresponding upper limit current value and at the same time corresponds to the frequency of the voltage applied to the compressor supply voltage of the minimum frequency.

In cases where the operating mode during the starting control process or the normal control process or the Defrost operation is switched to the regulated operation mode and the drive power frequency thereafter to the before switching returns to the regulated operating mode, the regulated operating mode can be aborted, and the compressor can also operate with the then-adjacent frequency be that for monitored for a predetermined period of time becomes. This avoids the situation where the regulated operating mode resumed immediately after canceling the regulated operating mode is, or the so-called Nachpendeln, resulting in practical advantages leads, such as a rule stability.

Claims (8)

A hot water supply device comprising: a heat pump; and a storage tank ( 3 ) for storing hot water heated by the heat pump, the heat pump comprising: a compressor ( 6 ) for compressing a refrigerant having a compression force regulated by a frequency of electric drive power supplied thereto, a refrigerant-water heat exchanger ( 8th ) connected to an outlet of the compressor by a first conduit ( 7a ) for transferring stored in the refrigerant thermal energy to the stored water in the storage tank, an expansion valve ( 9 ), which has a variable orifice and with an outlet of the refrigerant-water heat exchanger through a second conduit ( 7b ) for expanding the refrigerant in which the heat exchange has occurred in the refrigerant-water heat exchanger is connected, an air-refrigerant heat exchanger ( 10 ), which at an outlet of the expansion valve through a third conduit ( 7c ) is connected to transfer refrigerant stored in the air thermal energy to the refrigerant, a fourth conduit ( 7d ) to guide the cold by means of which the heat exchange has taken place in the air-refrigerant heat exchanger, to the compressor, an ejection temperature sensor ( 11 ) for detecting the temperature of the refrigerant discharged from the compressor, and a heat pump controller ( 12 ) for comparing the refrigerant temperature detected by the discharge temperature sensor with a predetermined discharge temperature and for controlling the compression force of the compressor ( 6 ) by thus adjusting the frequency of the electric drive power so that a deviation between the detected refrigerant temperature and the predetermined target discharge temperature becomes zero, characterized in that the heat pump controller ( 12 ) a current sensor ( 23 ) for detecting a current value of the electric drive power supplied to the heat pump, the heat pump controller having a regulated operation mode in which, when the current value detected by the current sensor exceeds a predetermined upper limit current value applied to the compressor ( 6 4), and when thereafter the current value detected by the current sensor is smaller than a predetermined recovery current value smaller than the upper limit current value, the frequency of the electric drive power is increased, the opening of the expansion valve is increased, and the target discharge temperature of the refrigerant discharged from the compressor is lowered. Hot water supply device according to claim 1, characterized in that the heat pump controller ( 12 ) the power supply to the compressor ( 6 ) turns off when the frequency of the electric drive power for driving the compressor is equal to a predetermined minimum frequency, and also the current value detected by the current sensor is larger than a predetermined current value. Hot water supply device according to claim 1 or 2, characterized in that to the compressor ( 6 ) one of the predetermined different frequencies of the electrical drive power is applied, and the heat pump controller ( 12 ) lowers the currently applied frequency of the electric drive power if, over a predetermined period of time, a current value exceeding the upper limit current value associated with the currently applied frequency is continuously detected. Hot water supply device according to any one of claims 1 to 3, characterized in that the compressor ( 6 ) one of predetermined different frequencies of the electric drive power is applied, and the heat pump controller ( 12 ) raises the currently applied frequency of the electric drive power if a current value smaller than a predetermined regeneration current value associated with the currently applied frequency is continuously detected over a predetermined period of time. Hot water supply device according to any one of claims 1 to 4, characterized in that, when the frequency of the electric drive power returns to a frequency applied before switching to the regulated operating mode, the heat pump controller ( 12 ) aborts the regulated operating mode. Hot water supply device according to any one of claims 1 to 5, characterized in that, when the frequency of the electric drive power returns to a predetermined target drive frequency after switching to the regulated operating mode when starting the compressor, the heat pump controller ( 12 ) breaks off the regulated operating mode. Hot water supply device according to any one of claims 1 to 6, characterized in that, when after the switching to the regulated operating mode, a defrost control operation ends during the defrost control operation, the heat pump controller ( 12 ) aborts the regulated operating mode. Hot water supply device according to any one of claims 1 to 7, characterized in that, when the regulated operating mode is interrupted, the heat pump controller ( 12 ) continues to apply a then-applied frequency of the electrical drive power to the compressor for a predetermined period of time.