KR100408468B1 - Heat pump unit for air conditioning - Google Patents

Abstract

Provided is a heat pump apparatus for air conditioning capable of suitably performing overload reduction of a compression section.

The air conditioning heat pump apparatus 100 compresses the heat-operating fluid in the compression section 2 and performs heat exchange with the outside air in the heat exchanger 5 and then the indoor air and the indoor air in the heat exchanger 81 via the storage tank 4A. And the indoor air is cooled by heat exchange. The drive source 1 of the compression section 2 is overloaded when the temperature of the outside air flowing through the heat exchanger 5 is high. The flow rate reduction of the heat-operated fluid to the heat exchanger 81 by the flow rate adjusting valve V1 and the air volume reduction by the blower F1 are performed in parallel to reduce the overload. In the case of a configuration in which a plurality of indoor units 80 are arranged, the overload reduction is performed in order of preference from the low temperature of the indoor air detected by the temperature detector D6. Although only the flow rate reduction of the heat-operated fluid causes condensation to occur in the downstream portion of the flow path in the heat exchanger 81, when the flow rate reduction and the flow rate reduction are performed in parallel, the refrigerant is similarly cooled from the inlet to the outlet of the flow passage, none.

Description

Heat pump unit for air conditioning

The present invention relates to a heat pump apparatus for air conditioning that performs indoor air conditioning such as cooling and heating by a heat pump action of a heat operating fluid.

For example, as shown in Fig. 7, as the air conditioning heat pump device 100, a cooling heat source such as a cooling heat source or the like for warming by a heat operating fluid pressurized by a compression section 2, For example, the heat source from the heat source 10, which obtains a heat source such as a heating source for heating, is applied to a cooling load or a warming load, for example, an indoor air conditioning indoor unit 80 arranged in the room to perform a cooling operation or a warming operation One configuration is well known.

However, the heat pump apparatus for air conditioning according to the present invention includes a heat pump apparatus that performs only the cooling operation, for example, a cooling load is only a cooling apparatus, or a cooling display case of food or the like. In the present invention, the term " interior " includes a case such as the cooling display case.

7, a circuit portion indicated by a thick line is a heat-operating fluid for obtaining a heat source, for example, a refrigerant line, and a circuit portion indicated by a thin line is an electric circuit for an electric detection signal, Since the heat source unit 10 is generally disposed outdoors, it may be called an outdoor unit, but may be disposed indoors. In general, a heat source is provided from one heat source 10 to one indoor unit or a plurality of indoor units.

The compressor of the compressor 2, for example, a rotary type compressor is driven by a drive source 1 such as an engine to pressurize a heat operating fluid such as Freon R22 or Freon R137 for obtaining a heat source, (Not shown) for separating the oil subjected to the mixing operation with the heat operating fluid in the heat exchanging unit 5 and the heat exchanging unit 81 to be described later, (Not shown) to the compression section 2, and the drive source 1 uses an engine, that is, an internal combustion engine or an electric motor.

When the indoor unit 80 is to perform a cooling operation, for example, a cooling operation, the flow path switching unit 3 connects the heat exchanger 81 on the side of the indoor unit 80 so as to operate as a heat absorbing heat exchanger, When the heat exchanger 5 on the side of the heat source 10 is connected to each duct so as to operate as the heat radiating heat exchanger and the indoor unit 80 is heated, And the heat exchanger 81 on the side of the indoor unit 80 is connected to each duct so as to function as a heat exchanger for heat radiation. For example, the four- And the like.

The heat exchanger 5 is provided with a plurality of fins on a serpentine pipe for circulating a heat-operating fluid and is provided with air blowing of the outside air by the blower F2 to ventilate in the direction of the arrow to heat the outside air or to absorb heat from the outside air And is generally called an outdoor heat exchanger since it performs heat exchange with outdoor air outside the room.

The heat exchanger 81 is constructed in the same manner as the heat exchanger 5. The air is circulated in the direction of the arrow by the blower F1 so as to return the room air to the heat exchanger 81. The heat exchanger 81 absorbs heat from the room air during the cooling operation, Is a heat exchanger that radiates heat to indoor air and is generally called an indoor heat exchanger because it performs heat exchange with indoor air.

During the cooling operation, the heat exchanger 5 functions as a condenser, and the heat exchanger 81 functions as an evaporator. In the heating operation, the heat exchanger 81 functions as a condenser and the heat exchanger 5 functions as an evaporator .

On the side of the heat source 10, the respective detected values of the temperature and the pressure of the required portions of the heat-operating fluid on the side of the heat source 10, for example, the temperature of the heat operating fluid on the discharge side of the heat- A pressure detector D7 for detecting the pressure and a temperature detector D8 for detecting the temperature, that is, a pressure detector D9 for detecting the pressure on the re-introduction side of the heat-operating fluid of the compression section 2, A temperature detector D10 for detecting the temperature of the heat-operating fluid, a temperature detector D2 for detecting the temperature of the inlet and outlet sides of the heat-operating fluid in the heat exchanger 5, a temperature detector D3, The detected value by the temperature detector D1 for detecting the rotational speed of the drive shaft 1 of the compression unit 2 and the rotational speed detector D11 for detecting the rotational speed of the drive shaft 1 of the compression unit 2 and the respective set values set from the setting operation unit 6, (7).

On the side of the indoor unit 80, various detected values such as the temperature of the heat-operated fluid on the side of the indoor unit 80 and the temperature of the object, for example, the angles of the inlet side and the outlet side of the heat- The temperature detector D4 for detecting the temperature and the temperature detector D5 for detecting the temperature and the temperature detector D6 for detecting the temperature of the intake side of the room air in the heat exchanger 5, And the set temperature of the set temperature which is the control target of the heating operation.

The control unit 7 and the control unit 82 exchange the detected values and the required values among the set values and operate the compression unit 2 by the control processing function of the control unit 7 based on these values The control unit 7 controls the operation of the drive source 1 and controls the flow rate adjusting unit 4 to adjust the flow rate of the heat operating fluid to be sent to the indoor unit 80 And controls the flow rate adjusting valve V1 and the blower F1 based on a command from the control unit 82 or the control unit 7 by the control processing function of the control unit 82. [

8, a commercially available CPU board (CPU / B) is connected to the control unit 7 and the control unit 82. [ And inputs each detection signal obtained by detecting the state of each part and each operation signal input by operating the setting operation unit 6 or the setting operation unit 83 as input data from the input / output port 71 And stores them in the working memory 73. In addition, based on these input data and the programs and the control data of the processing flow stored in advance in the processing memory 72, necessary control processing is carried out and the respective control signals Output port 71 as shown in Fig.

In addition to the time required for the control processing by the clock circuit 74, the operation state and the control state of each part, the respective setting states, and the like are displayed on the display unit 75, and the control unit 7 And a communication connection terminal 76 for communicating control data or the like by an extension line of a bus line or a communication cable are provided on the communication line 77 between the control unit 82 and the control unit 82, And a communication connection terminal using a communication integrated circuit such as the RS485 standard as necessary.

In the configuration shown in Fig. 7, one indoor unit 80 is connected to one heat source unit 10 (hereinafter referred to as "one indoor unit configuration"), but one heat source unit 10 (Hereinafter referred to as " a plurality of indoor unit configurations ") connected to the indoor units 80 of the condenser is connected to the control unit 7 of the heat source unit 10. In the latter case, And a configuration in which a configuration is performed by a separately provided general controller.

In the cooling operation of the air-conditioning heat pump apparatus 100, when the temperature of the outside air becomes equal to or greater than a predetermined value, the abnormal temperature rise of the discharge side heat operating fluid of the compression section (2) When the respective detected values of the temperature detector D1 for ambient temperature and the temperature detector D3 for condensation temperature are equal to or more than respective predetermined values in order to solve the problem of the flow rate control valve V1 of the indoor heat exchanger 81 (Hereinafter, referred to as a first prior art) in which the flow rate is reduced and adjusted and the number of rotations of the drive source 1 of the compression section 2, for example, the number of revolutions of the engine or the motor, Japanese Patent Laid-Open No. 3-177758 based on the crew of the applicant.

Even when the heat operating capacity of the heat source 10 and the heat operating capacity of the indoor unit 80 are the same, the temperature of the outside air is high during the cooling operation, or when the temperature of the heat exchanger 5 The heat radiation of the heat exchanger 5 becomes insufficient when the part of the heat radiation ventilation by the blower F2 is returned to the heat exchanger 5 so that it becomes an overload state, There is a drawback that the pressure of the heat operating fluid becomes too high and the safety valve operates or the driving source 1 of the compression section 2, that is, the engine or the motor, is overloaded and stopped, and the whole apparatus is stopped.

In the case of the "multiple indoor unit configuration", since the total heat operating capacity of each indoor unit is set to a large capacity, for example, a maximum capacity of about 130%, in comparison with the heat operating capacity of the heat source 10, Even when the outside air temperature is relatively low, there is a drawback that the overloaded state is the same as described above, and the entire apparatus is stopped.

The flow rate of the flow rate adjusting valve V1 of the heat exchanger 81 is reduced and the driving speed of the driving source 1 of the compression section 2 is adjusted to It is effective to reduce the flow rate of the flow rate adjusting valve V1 of the heat exchanger 81 that operates as an evaporator, the following drawbacks arise.

That is, when the flow rate of the flow control valve V1 is set to the steady state, the condensed heat operating fluid evaporates gradually from the inlet side to the outlet side of the heat exchanger 81 and completely evaporates at the outlet side, The indoor air that is blown into the heat exchanger 81 by the blower F1 is cooled on average over the entire fin in the heat exchanger 81. [

Therefore, since the dehumidification of the room air ventilated in the heat exchanger 81 is similarly performed on an average, no condensation will occur. However, if the flow rate of the flow control valve V1 is adjusted to be reduced, The dehumidification becomes insufficient at a portion close to the outlet side, so that dew condensation occurs, and as a result, condensation is generated, and as a result, The water may fall into the room, or the condensation may be decayed to cause mold and the like.

Therefore, there is a problem that it is desired to provide a heat pump apparatus for air conditioning which does not have such drawbacks.

1 is an overall block diagram of an embodiment of the present invention.

Fig. 2 is a flow chart showing a lumber control process according to an embodiment of the present invention; Fig.

Fig. 3 is a characteristic diagram of the lumbar part of the embodiment of the present invention. Fig.

4 is an overall block diagram of an embodiment of the present invention;

5 is a diagram showing a flow of control process in the embodiment of the present invention;

6 is a view showing a control processing selection method in an embodiment of the present invention.

7 is an overall block diagram of the prior art.

Fig. 8 is a block diagram of the prior art; Fig.

Description of the Related Art

1: driving source 2: compression section

2A: compressor 2B: accumulator

3: flow path switching part 4: flow rate adjusting part

4A: Storage tank 5: Heat exchanger

5C: Blocking plate 6: Setting control unit

7: control unit 10: heat source

70: CPU / B 71: I / O port

72: processing memory 73: working memory

74: Clock circuit 75: Display

76: Communication connection terminal 77: Communication path

80: indoor unit 81: heat exchanger

82: control section 83: setting operation section

100: Heat pump unit for air conditioning D1: Temperature detector

D2: Temperature detector D3: Temperature detector

D4: Temperature detector D5: Temperature detector

D6: Temperature detector D7: Pressure detector

D8: Temperature detector D9: Pressure detector

D10: Temperature detector F1: Blower

F2: blower V1: flow regulating valve

V2: Flow control valve V3: Check valve

According to the present invention,

Such

The condensing heat operating fluid obtained by condensing the desired heat operating fluid pressurized by the compression section by heat exchange with the outside air is given to a heat exchanger for performing heat exchange with the room air and evaporated to perform a cooling operation for cooling the room air And an overload reduction operation for reducing the overload when the compression section is overloaded, the apparatus comprising:

An overload reduction means for performing the overload reduction operation in parallel with the reduction of the flow rate of the condensed heat operating fluid flowing through the heat exchanger and the reduction of the flow rate of the indoor air flowing through the heat exchanger

And a second structure in which the first structure is provided,

In the same air-conditioning heat pump apparatus as the first configuration,

Within a range from a temperature difference between the inlet side and the outlet side of the heat exchanger exceeding a first predetermined value and reaching a second predetermined value, the flow rate of the condensation heat operating fluid flowing through the heat exchanger A first overload reduction means for performing the overload reduction operation in parallel with the reduction of the flow rate of the indoor air flowing through the heat exchanger,

And a second overload reduction means for performing the overload reduction operation only by reducing the flow rate of the room air circulated in the heat exchanger when the temperature difference reaches the second predetermined value,

A second structure for installing the second substrate,

A condensing heat operating fluid obtained by condensing the desired heat operating fluid pressurized by the compression section by heat exchange with the outside air is given to a condenser of a heat exchanger for performing heat exchange with the room air and evaporated to thereby perform a cooling operation for cooling the room air And an overload reduction operation for reducing the overload when the compression section is overloaded, the heat pump apparatus comprising:

Low-temperature priority overload reduction means for preferentially selecting the heat exchanger having the lowest indoor air temperature among the heat exchangers of the condensers, and sequentially performing the overload reduction operation;

And the temperature of the heat-operated fluid at the inlet side and the outlet side of the heat exchanger selected by the selection is within the range from the first predetermined value to the second predetermined value, A first overload reduction means for performing a first overload reduction operation in parallel with the reduction of the flow rate of the indoor air and the flow rate of the indoor air flowing through the heat exchanger;

When the temperature difference of the heat exchanger selected by the selection reaches the second predetermined value, performs a second overload reduction operation only by reducing the flow rate of the indoor air flowing through the heat exchanger

And a third configuration in which the first,

In this third configuration,

The second reducing operation is canceled by sequentially selecting the heat exchanger which is performing the second reduction operation with the highest indoor air temperature among the condensers when releasing the reduction, And the load reduction canceling means for releasing the first reduction operation in order of priority to the heat exchanger performing the first reduction operation

The above-described problems are solved by the fourth structure.

As an embodiment of the present invention, an embodiment in which the present invention is applied to the air conditioning heat pump apparatus 100 of Fig. 7 will be described.

Hereinafter, an embodiment will be described with reference to Figs. 1 to 6. Fig. In Figs. 1 to 6, the same reference numerals as those in Figs. 7 and 8 denote parts having the same functions as the parts denoted by the same reference numerals in Figs. 7 and 8. 1 to 6 are portions having the same functions as those of the same reference numerals as those described in any of Figs. 1 to 6. Fig.

≪ Embodiment 1 >

First, the first embodiment will be described with reference to Figs. 1 to 3. Fig. The configuration of FIG. 1 is different from the configuration of FIG. 7 in that the compressor 2, the flow path switching portion 3, the flow rate adjusting portion 4, the heat exchanger 5, the blower F2, the heat exchanger 81, The control section 82, the setting operation section 6, the setting operation section 83, and the like are omitted from the drawings.

1, the heat exchanger 5 and the blower F2 are arranged such that the two sets of heat exchangers 5 are opposed to each other with the blower F2 interposed therebetween, one side is surrounded by the blocking plate 5C, So that heat exchange between the heat exchanger 5 and the outside air can be performed more effectively.

The flow rate regulating section 4 is constituted by a flow rate regulating valve V2, a check valve V3 and a reservoir 4A. In the case of the warming operation, (Not shown) so as to pass through the flow path shown by the solid line in the case of the cooling operation.

Accordingly, when the heating operation is performed, the heat-operating fluid is circulated through the compressor 2A, the flow path switching portion 3, the heat exchanger 81, the flow rate adjusting valve V1, the storage tank 4A, the flow rate adjusting valve V2, The refrigerant flows from the compressor 2A to the flow path switching portion 3 when the refrigerant is in the cooling operation, and the refrigerant is circulated through the passage switching portion 3, the flow path switching portion 3, the accumulator 2B, → the heat exchanger 5 → the check valve V3 → the reservoir 4A → the flow control valve V1 → the heat exchanger 81 → the flow path switching part 3 → the accumulator 2B → the compressor 2A It is circulating on the route.

The flow rate adjusting valve V1 and the flow rate adjusting valve V2 are both opened and closed in steps of, for example, about 500 stages from the closed state to the fully opened state, In the normal cooling operation, the flow rate adjusting valve V1 is switched between a temperature value T1 of the temperature detector D4 and a temperature difference T2 of the temperature value T2 of the temperature detector D5 -T1) is controlled to be kept within a range of 0 to 1 DEG C, and when the temperature difference exceeds the predetermined value, the opening degree of the flow rate adjusting valve V1 is increased by a predetermined step amount, for example, +1 step, , The opening degree of the flow rate adjusting valve V1 is controlled to be reduced by a predetermined step amount, for example, -1 step. In the control operation in the following description, since the control operation of the flow rate adjusting valve V2 is not included, the flow rate adjusting valve V2 can perform the operation required during the warming operation, that is, the operation as the expansion valve Valves of other types can be used as long as they are present.

Both of the blower F1 and blower F2 are configured to adjust the air flow rate between, for example, about 50 steps from the blowing stop state to the highest wind force state. For example, And is a blower having a variable configuration of driving voltage by malfunction control.

Although not shown in Fig. 1, the outdoor unit 10 and each indoor unit 80 are provided with the control unit 7, 82 and the setting operation unit 6, 83 described with reference to Figs. 7 and 8, The control process flow for performing the cooling operation and the warming operation and the detection values of the temperature detector D1 for ambient temperature and the temperature detector D3 for condensation temperature in the same manner as the configuration described in the first related art, The control processing flow for reducing and adjusting the flow rate of the flow rate adjusting valve Vl of the indoor heat exchanger 81 and reducing and adjusting the driving rotational speed of the driving source 1 of the compression section 2, The control processing stores the ambient temperature detected by the temperature detector D1 and the temperature of the heat operating fluid from the compression section 2 detected by the pressure detector D7 When the discharge pressure is higher than the [outside temperature / compression discharge pressure The pressure limit point PL immediately before reaching a high pressure value, for example, 2.6 MPa, for example, from 2.3 to 2.4 MPa. ≪ / RTI >

In order to achieve the object of the present invention, the control processing flow program and the predetermined value data for performing the cooling operation described later with reference to Figs. 2 and 3 are stored in the respective processing memories 72, When the compression section 2 is in an overloaded state, control is performed so as to reduce the overload by adjusting the air volume of the blower F1 and the flow rate of the flow rate adjusting valve V1.

<Determination of Overload State>

The &quot; determination of the overload state &quot; in the control processing flow of Fig. 2 is performed using, for example, one of the following two determination methods.

When the detected value of the pressure detector D7 reaches the pressure limit point PL of the &quot; outside air temperature / compression discharge pressure characteristic &quot; in Fig. 3, the first overloaded state determination method determines that the compression section 2 is in an overload state Method.

The second overloaded state determination method is a method of determining the overload state of the compressor 2A based on the rotational speed rpm of the drive shaft 1 of the drive source 1, for example, the engine or the electric motor, and the drive output PS The data of the drive output change 2 that has been obtained in advance is output to the processing memory 72 of the control unit 7 and the current drive output PSA is obtained from the current rotation number rpm detected by the rotation number detector D11 For example, an empirical formula that obtains the required driving force PSA from each detected value detected by the pressure detector D7, the pressure detector D9, the temperature detector D8, and the temperature detector D10, And the required driving force PSA obtained from this calculation formula reaches the limit value (PSL) of 90% of the safety value of the driving output PS, for example, the driving output PS It is assumed that the compression section 2 is in an overload state It is a way to stop.

<Order of Overload Reduction>

The overload reduction in the control processing flow of FIG. 2 is configured to perform the two-stage reduction processing of the first reduction and the second reduction.

In the normal cooling operation, the temperature difference between the inlet side and the outlet side of the condensed heat-operating fluid flowing through the heat exchanger 81, that is, the detected value Tl of the temperature detector D4 and the detected value Tl of the temperature detector D5 The temperature difference T2-T1 of the compressor T2 is controlled to be in the range of, for example, 0 to 1 占 폚. However, when the compression section 2 becomes overloaded, first the first reduction is performed, When necessary, control processing is performed so as to perform the second reduction.

In the first reduction, until the value of the temperature difference (T2-T1) exceeds the first predetermined value TA, for example, exceeding 1 deg. C and reaches the second predetermined value TB, for example, 10 deg. The amount and the temperature of the heat operating fluid returning to the compression section 2 are controlled so that the opening degree of the flow rate adjusting valve V1 is reduced and the air flow rate of the blower F1 is reduced in the range (2) is reduced.

In other words, in the first reduction, the flow rate of the heat-operating fluid flowing through the heat exchanger 81 is excessively narrowed, but the flow rate of the indoor air flowing through the cooling fins of the heat exchanger 81 is reduced in parallel, The operation fluid is not completely evaporated in the middle of the flow path of the heat exchanger 81 and the evaporation is terminated near the outlet of the flow path so that condensation does not occur in the cooling fin in the second half portion of the flow path.

When the value of the temperature difference (T2-T1) reaches a second predetermined value (TB), for example, 10 DEG C, the first reduction is shifted to the second reduction. In the second reduction, So that the flow rate of the indoor air flowing through the cooling fins of the heat exchanger 81 is reduced to return to the compression section 2 so that the heat operating fluid does not completely evaporate in the flow path of the heat exchanger 81 And the overload of the compression section 2 is reduced by normally controlling the amount and temperature of the heat-operating fluid.

<Description of Control Processing Flow>

Hereinafter, the second control processing flow will be described.

This processing flow is constituted as a subroutine attached to the main control processing flow for performing the normal cooling operation and the control processing in the heating operation on the whole of the heat source unit 10 and the indoor unit 80, And the control processing flow is shifted to this control processing flow every predetermined time interval, for example, every 5 seconds.

◆ In step SP1, data of each required detection value is entered and the process proceeds to the next step SP2.

At step SP2, it is determined whether the overload state is established by the above-described &quot; determination of overload state &quot;. If it is in the overloaded state, the process proceeds to the next step SP3, and if not, the process proceeds to the step SP10.

At step SP3, a value obtained by obtaining the temperature difference (T2-T1) between the detection value T1 of the temperature detector D4 and the detection value T2 of the temperature detector D5 is set in the control section 82 of each indoor unit 80 It is determined whether or not it is within the range of the first reduction by discriminating whether it is less than the second predetermined value (TB), that is, less than 10 ° C. When it is less than the second predetermined value TB, the process proceeds to the next step SP4. If not, that is, when the second predetermined value TB is reached, the process proceeds to the step SP6.

At step SP4, the opening degree of the flow control valve V1 is reduced by one step, that is, by -1 step, and at the same time, the air volume of the blower F1 is reduced by one step, that is, -1 step , The data of the fact that the first reduction has been performed is stored in the work memory 73 of the control unit 7 and the process returns to the predetermined step of the main control processing flow.

At step SP5, it is determined whether the value of the temperature difference (T2-T1) reaches the second predetermined value (TB), that is, whether or not the temperature difference is within the range of the second reduction. If it is the second predetermined value (TB), the process proceeds to the next step SP4. If not, that is, the value is lower than the second predetermined value (TB), the process proceeds to the step SP7.

At step SP6, as the second reduction, the data of the content of the second reduction after the air volume of the blower F1 is reduced by one step, that is, at -1 step, is stored in the working memory 73 And returns to the predetermined step of the main control processing flow.

At step SP7, an alarm of "overload failure" is displayed on each display unit 75 attached to the control unit 7 and the control unit 82, and the procedure goes to a step for performing an abnormal stop of the main control process flow.

In step SP10, the "load margin", that is, the load state of the current compressor 2A is below the pressure limit point PL in the "outside air temperature / compression discharge pressure characteristic" in FIG. 3, Quot; number / compression drive output characteristic &quot;. If there is a "load margin", the routine proceeds to the next step SP11. If not, that is, if it coincides with the pressure limit point PL or the limit value PSL, the routine returns to the predetermined step of the main control processing flow.

At step SP11, it is determined at step SP6 whether or not the second reduction is being performed. When the second reduction is being made, the process proceeds to the next step SP12. If not, the process proceeds to the step SP14. This discrimination is discriminated by the data stored in the working memory 73 of the control section 7 in step SP6.

At step SP12, it is determined whether or not the first predetermined time t1, for example, three minutes has elapsed from the cancellation of the second reduction of the previous time, that is, the release by step SP13 described later. This determination is made based on the fact that there is stored the data of the second reduction reduction canceled by the step SP13 stored in the working memory 73 of the control unit 7 and the elapsed time from the time of the second reduction reduction is stored in the clock circuit 74) determines that the time data has elapsed from the first predetermined time t1.

At step SP13, as the second reduction cancellation, data indicating that the second reduction cancellation has been performed after increasing the air flow rate of the blower F1 by one step, that is, after +1 step, Stored in the working memory 73, and returned to the predetermined step of the main control processing flow.

At step SP14, it is determined at step SP4 whether or not the first reduction is made. When the first reduction is being made, the process proceeds to the next step SP15, and if not, the process returns to the predetermined step of the main control process flow. This determination is made based on the data stored in the work memory 73 of the control unit 7 in step SP4.

At step SP12, it is determined whether the second predetermined time t2, for example, 10 minutes has elapsed since the last reduction of the second reduction, that is, the release at step SP13 described later. This determination is made based on the fact that there is data storage of the first reduction reduction canceling at step SP16 which is stored in the working memory 73 of the control section 7 and that the time elapsed from the time of the first reduction reduction resetting is stored in the clock circuit 74 ) Is determined to have passed the second predetermined time t2.

At step SP16, the opening degree of the flow rate adjusting valve V1 is increased by one step, that is, by +1 step, and at the same time, the air amount of the blower F1 is increased by one step, , The data of the fact that the first reduction cancellation has been performed is stored in the work memory 73 of the control unit 7 and the process returns to the predetermined step of the main control process flow.

<Summary of Configuration of First Embodiment>

To summarize the configuration of the first embodiment,

A heat exchanger for exchanging heat with the room air by condensing the required heat operating fluid pressurized by the compression section 2 by heat exchange with the outside air, for example, by heat exchange by the heat exchanger 5, For example, a cooling operation for cooling the room air by evaporating it by applying it to the heat exchanger 81, and at the same time, when the compression section 2 is overloaded, for example, the overload is discriminated at step SP2, In an air conditioning heat pump apparatus (100) for performing an overload reduction operation for reducing an overload,

The flow rate of the condensing heat operating fluid flowing through the heat exchanger 81 by reducing the flow rate of the flow rate adjusting valve V1 is reduced and the air flow rate of the blower F1 is reduced and adjusted by the step SP4, The overload reducing means for performing the overload reduction operation by reducing the flow rate of the indoor air flowing through the heat exchanger (81)

A first structure for installing the first substrate,

In the air-conditioning heat pump apparatus 100 similar to the first configuration,

The temperature difference between the heat-operating fluid on the inlet side and the outlet side of the heat exchanger, that is, the heat exchanger 81, for example, the temperature detector D4 and the temperature detector D5 are detected by steps SP3 and SP4 The flow rate of the flow rate adjusting valve V1 is reduced and adjusted within the range until the temperature difference T1-T2 due to the temperature exceeds the first predetermined value TA and reaches the second predetermined value 7B. The flow rate of the condensing heat operating fluid flowing through the heat exchanger 81 is reduced and the flow rate of the indoor air flowing through the heat exchanger 81 by reducing the air volume of the blower F1 is reduced, First overload reduction means for performing an operation,

For example, when the temperature difference (T1-T2) reaches the second predetermined value (TB) by the step SP5 and the step SP6, the flow rate of the blower F1 is reduced and adjusted to the heat exchanger 81 And second overload reduction means for performing the overload reduction operation only by reducing the flow rate of the indoor air

As shown in Fig.

&Lt; Embodiment 2 >

Next, a second embodiment will be described with reference to Figs. 4 to 6. Fig. This second embodiment is different from the first embodiment in that the air conditioner heat pump apparatus 100 according to the "multiple indoor unit configuration" in which the indoor unit 80 in the first embodiment is constituted by a plurality of units, for example, units 1, 2 and 3 And a portion different from the first embodiment is an example in which the overload reduction of the compression section 2 is preferentially selected among the heat exchangers 81 of the indoor units 80 with the lowest indoor temperature, And the second overload reduction is canceled. When the overload reduction is canceled, the second highest overload reduction canceling is sequentially performed by sequentially selecting the highest indoor air temperature in the heat exchanger 81 of each indoor unit 80, And the data of the program and the predetermined value by the control processing flow as shown in Fig. 5 are stored in the processing memory 72 of the control section 7 Have .

<Description of Control Processing Flow>

Hereinafter, the control processing flow of FIG. 5 will be described.

5 is different from the control processing flow in Fig. 2, in the control processing flow for performing the overload reduction on the left side in Fig. 5, the heat exchanger 81 of each indoor unit 80 is preferentially selected to have the lowest indoor air temperature And a step SP3A and a step SP5A for discriminating whether the selected heat exchanger 81 is to be firstly reduced or secondarily reduced.

In the control processing flow for canceling the right overload reduction of Fig. 5, it is a part of steps SP12A and SP15A for preferentially selecting the indoor air temperature of the heat exchanger 81 of each indoor unit 80 that has the highest indoor air temperature.

Therefore, only the parts of these steps SP2A, step SP3A, step SP5A, step SP12A, and step SP15A will be described, and description of other steps will be omitted.

The control processing according to steps SP2A, SP3A, and SP6A is performed by, for example, selecting and controlling the same as the &quot; lowest temperature indoor unit selection control method &quot; shown in Fig.

In Step SP2A, the lowest temperature value TC of the indoor air detected by the temperature detector D6 in each heat exchanger 81 is selected, and the process proceeds to Step SP3A. Here, when a plurality of temperature values (TC) are the same, the one having a smaller temperature difference (T2-T1) is selected.

6, for example, the first unit having the lowest temperature value (TC) is selected in the reduction step 1, and the second unit is selected in the second step, the second unit is selected in the second step, , the second unit is selected in the (n + 1) th stage, and the second unit is selected in the (n + 2) th stage.

At step SP3A, it is determined whether or not the heat exchanger 81 selected at step SP2A2 is to be firstly reduced. If the first reduction is to be performed, the process proceeds to the next step SP4, and if not, the process proceeds to the step SP5A. Here, the first reduction is performed for a temperature difference (T2-T1) exceeding a first predetermined value (TA), for example, exceeding 1 deg. C and lower than a predetermined value (TB), for example, lower than 10 deg. .

6, for example, in the first unit of the first stage of the reduction step, since the difference (T2-T1) is 1.5 占 폚 and less than the second predetermined value (TB) It corresponds to the object of the first reduction and similarly, the second unit of the second stage, the second unit of the third stage, and the second unit of the n + 1 stage correspond to the first reduction target.

In step SP5A, it is determined whether or not the second reduction is to be performed on the heat exchanger 81 selected in step SP2A2. If the second reduction is to be performed, the process proceeds to the next step SP6, and if not, the process proceeds to the step SP7. Here, the second reduction is performed on the fact that the temperature difference (T2-T1) has reached the second predetermined value (TB), for example, 10 占 폚, so it is determined whether or not this is the case.

6, the temperature difference (T2-T1) is 10 占 폚 and reaches the second predetermined value (TB), for example, 10 占 폚, in the nth- And the second unit of the (n + 2) -th stage corresponds to the second reduction target.

At step SP12A, the heat exchanger 81 having the highest temperature difference (T2-T1) is selected and the process proceeds to the next step SP13.

In step SP15A, the heat exchanger 81 having the highest temperature difference (T2-T1) is selected and the process proceeds to the next step SP16.

<Summary of Configuration of Second Embodiment>

To summarize the configuration of the second embodiment,

A heat exchanger for exchanging heat with the room air by condensing the required heat operating fluid pressurized by the compression section 2 by heat exchange with the outside air, for example, by heat exchange by the heat exchanger 5, For example, a condenser of the heat exchanger 81 and evaporates, thereby performing a cooling operation for cooling the indoor air. When the compression section 2 is overloaded, for example, the overload is discriminated in step SP2 And an overload reduction operation for reducing the overload is performed,

For example, the temperature value TC detected by the temperature detector D6 is the lowest in the indoor heat exchanger 81 of the condenser by the step SP2A and the heat exchanger 81 is preferentially Low-temperature priority overload reduction means for selectively performing the overload reduction operation,

For example, in step SP3A, the temperature of the heat-operating fluid on the inlet side and the outlet side of the heat exchanger 81 selected by the above selection, for example, the detection values of the temperature detector D4 and the temperature detector D5 The flow rate of the flow rate adjusting valve V1 is adjusted within the range until the temperature difference (T1-T2) by the flow rate adjusting valve (V1) exceeds the first predetermined value (TA) until reaching the second predetermined value (TB) 81 and the flow rate of the indoor air flowing through the heat exchanger 81 by reducing and adjusting the air flow rate of the air blower F1 in parallel with the first overload First overload reduction means for performing a reduction operation, that is, a first reduction operation,

For example, when the temperature difference (T2-T1) of the heat exchanger (81) selected by the selection at step SP5A reaches the second predetermined value (TB), the air amount of the blower (F1) And a second overload reduction means for performing a second overload reduction operation, that is, a second reduction operation, only by reducing the flow rate of the indoor air flowing through the heat exchanger (81)

In the third configuration,

When releasing the reduction, for example, the heat exchanger 81 having the highest indoor air temperature among the condensers and performing the second reduction operation is preferentially selected by steps SP11, SP12A, and SP13 After the second reduction operation is sequentially released, the heat exchanger 81 having the highest indoor air temperature among the condensers and performing the first reduction operation is preferentially performed at step SP14, step SP15A, and step SP16 And a load reduction releasing means for releasing the first reduction operation in order.

<Modification Implementation>

The present invention includes the following modifications.

(1) The present invention is applied to a heat pump apparatus for air conditioning that performs only a cooling operation.

According to the present invention, even when the temperature of the outside air flowing through the heat exchanger on the heat source side is high and the compressing section is liable to be overloaded during the cooling operation, the temperature difference of the heat fluid flowing through the heat exchanger on the indoor unit side The flow rate of the heat-operating fluid flowing through the heat exchanger is reduced and the flow rate of the indoor air is reduced. In addition, after reaching the predetermined value, only the flow rate of the indoor air flowing into the heat exchanger And the overload of the compression section is reduced. Therefore, it is possible to appropriately reduce the overload with respect to the overload state over a wide range.

In addition, since the flow rate of the heat-operating fluid flowing through the heat exchanger is reduced and the flow rate of the indoor air is reduced, evaporation of the heat-operating fluid is averaged constantly from the inlet to the outlet of the heat exchanger. It is possible to provide a heat pump apparatus for air conditioning which eliminates condensation in the rear half portion near the outlet side of the heat exchanger.

Claims (4)

The condensing heat operating fluid obtained by condensing the desired heat operating fluid pressurized by the compression section by heat exchange with the outside air is given to a heat exchanger for performing heat exchange with the room air and evaporated to perform the cooling operation for cooling the room air, And an overload reduction operation for reducing the overload when the compression section is overloaded, the apparatus comprising: An overload reduction means for performing the overload reduction operation in parallel with the reduction of the flow rate of the condensed heat operating fluid flowing through the heat exchanger and the reduction of the flow rate of the indoor air flowing through the heat exchanger And a heat pump for heating the air. The condensing heat operating fluid obtained by condensing the desired heat operating fluid pressurized by the compression section by heat exchange with the outside air is given to a heat exchanger for performing heat exchange with the room air and evaporated to perform the cooling operation for cooling the room air, And an overload reduction operation for reducing the overload when the compression section is overloaded, the apparatus comprising: Within a range from a temperature difference between the inlet side and the outlet side of the heat exchanger exceeding a first predetermined value and reaching a second predetermined value, the flow rate of the condensation heat operating fluid flowing through the heat exchanger A first overload reduction means for performing the overload reduction operation in parallel with the reduction of the flow rate of the indoor air flowing through the heat exchanger, And a second overload reduction means for performing the overload reduction operation only by reducing the flow rate of the room air circulated in the heat exchanger when the temperature difference reaches the second predetermined value. Device. A condensing heat operating fluid obtained by condensing the desired heat operating fluid pressurized by the compression section by heat exchange with the outside air is given to a condenser of a heat exchanger for performing heat exchange with the room air and evaporated to thereby perform a cooling operation for cooling the room air And an overload reduction operation for reducing the overload when the compression section is overloaded, the apparatus comprising: Low-temperature priority overload reduction means for preferentially selecting the heat exchanger having the lowest indoor air temperature among the heat exchangers of the condensers, and sequentially performing the overload reduction operation; And the temperature of the heat-operated fluid at the inlet side and the outlet side of the heat exchanger selected by the selection is within the range from the first predetermined value to the second predetermined value, A first overload reduction means for performing a first overload reduction operation in parallel with the reduction of the flow rate of the indoor air and the flow rate of the indoor air flowing through the heat exchanger; When the temperature difference of the heat exchanger selected by the selection reaches the second predetermined value, performs a second overload reduction operation only by reducing the flow rate of the indoor air flowing through the heat exchanger And a heat pump for heating the air. A condensing heat operating fluid obtained by condensing the desired heat operating fluid pressurized by the compressing section by heat exchange with the outside air is given to the condenser of the heat exchanger performing the heat exchange with the room air, And an overload reduction operation for reducing the overload when the compression section is overloaded, the apparatus comprising: Low-temperature priority overload reduction means for preferentially selecting the heat exchanger having the lowest indoor air temperature among the heat exchangers of the condensers, and sequentially performing the overload reduction operation; And the temperature of the heat-operated fluid at the inlet side and the outlet side of the heat exchanger selected by the selection is within the range from the first predetermined value to the second predetermined value, (Hereinafter, referred to as &quot; first overload reduction operation &quot;) in parallel with the reduction of the flow rate of the indoor air flowing through the heat exchanger and the reduction of the flow rate of the indoor air flowing through the heat exchanger, When the temperature difference of the heat exchanger selected by the selection reaches the second predetermined value, the second overload reduction operation (hereinafter referred to as the second reduction operation) is performed only by reducing the flow rate of the room air flowing through the heat exchanger Second overload reduction means for performing the second overload reduction, The second reducing operation is canceled by sequentially selecting the heat exchanger which is performing the second reduction operation with the highest indoor air temperature among the condensers when releasing the reduction, And the load reduction canceling means for releasing the first reduction operation in order of priority to the heat exchanger performing the first reduction operation And a heat pump for heating the air.

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