DE60221748T2 - Method for ending the defrosting process of an air conditioning and air conditioning system using the method - Google Patents

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

These The invention relates to a method for properly ending a defrosting operation and an air conditioner using the method.

2. Description of the state of the technique

air conditioning with compressors of constant speed, the air conditioners for overseas use included, take over in general, one of the following methods for ending a defrosting operation. According to one First method is a timer for counting a set time provided as a defrosting time on an air conditioner, and the defrosting process is terminated (paused) when the timer reaches the specified defrosting time counted Has. According to one second method is an indoor unit with an indoor temperature sensor, an indoor heat exchanger temperature sensor and an indoor control while an outdoor unit with an outdoor heat exchanger and an outside control equipped, and the defrosting process is based on the temperature, each from the indoor temperature sensor, the indoor heat exchanger temperature sensor and the outdoor heat exchanger temperature sensor is detected. Next is in accordance with a third method of defrosting based on the internal temperature, detected by an indoor temperature sensor, the indoor heat exchanger temperature, that of an indoor heat exchanger temperature sensor is detected, and a fixed drive current value to terminate defrosting is finished.

In the second method of ending the defrost on the basis the temperature of each sensor, the defrosting can be performed with certainty, however, it is necessary to use the outdoor heat exchanger temperature sensor on the outdoor unit and also the outside control for processing the temperature information from the outdoor heat exchanger temperature sensor so that the manufacturing costs increase.

Further, in the third method of controlling the defrosting operation on the basis of the preset current value, the outdoor control and the outdoor temperature sensor in the outdoor unit may be omitted, and thus this method is advantageous in terms of cost. However, when the power source voltage applied to the compressor is changed (or switched to another voltage), the current value (drive current value) of the compressor also changes during the defrosting operation. However, the drive current value preset for terminating the defrosting operation is fixed (invariably) irrespective of the change of the power source voltage, the type of the compressor, etc., so that there is a problem that frost partly remains or an excessive defrosting operation is unintentionally performed. FR-A-2 379 037 discloses an air conditioner with a defrost function.

SUMMARY OF THE INVENTION

Therefore It is an object of the present invention to provide a method for End of a defrosting provide that the defrosting process more precisely according to the capacity of the used compressor, the type of compressor used or the like can end, so that the occurrence of lagged Frost can be prevented and also prevents excessive defrosting can be.

Around to solve this task will according to one First aspect of this invention, an air conditioner according to the features provided by claim 1.

In This control system stops the defrosting process when the drive current of the compressor after calculating the reference current value is not less than the reference current value.

In In the air conditioner described above, the controller includes a memory for storing parameters in advance, and the controller calculates the reference current value based on the drive current value of the compressor, during the Defrosting is detected, and stored in the memory Parameter by using a given calculation equation.

In The air conditioner described above will be several sets of Parameters used in the calculation equation for the termination of defrosting are usable, prepared and stored in the memory, and a set of parameters used to determine the reference current value for the used compressor is most appropriate, is made properly from the several sentences selected.

In the air conditioner described above, the reference current value is calculated according to the following equation: Id = Ik + (F - Ik) × K where Id represents the reference current value, F and K represent the sets of parameters, and Ik represents the mini compressor drive current rating under compressor drive current readings for a given period of time.

According to one second aspect of this invention is a method for terminating a Defrosting process for An air conditioning system provided by the features of claim 6 is marked.

These The method further comprises a termination step of termination the defrosting process, when judged in the judging step, that the drive current of the compressor, according to the calculation of the reference current value is not smaller than the reference current value is.

In the method described above, the reference current value is calculated by the following equation: Id = Ik + (F - Ik) × K where Id represents the reference current value, F and K represent the sets of parameters, and Ik represents the minimum drive current value of the compressor among drive current values of the compressor detected for a predetermined period of time.

According to the present Invention is the drive current value I of the compressor during the defrosting process for one monitored for a specified period of time, and the calculation current value Ik, which is the minimum current value for the given period corresponds, is determined. At the time when the given period of time expires becomes a reference current value Id, which is a threshold for termination defrosting operation, by the given calculation under Use of the calculation current value Ik and in advance in the controller determined parameter, and the thus determined reference current value Id is stored in the controller. Thereafter, the drive current value continues to increase I detected the compressor, and it is judged whether the drive current value I is not smaller than the reference current value Id. When judged is that the drive current value I is not smaller than the reference current value Id, the defrosting operation (i.e., the cooling operation) is performed by the controller stopped (stopped), and the heating operation resumed. In accordance with a change (increase / decrease) a power source voltage becomes the drive current I of the compressor also varies (increases / decreases), and thus the reference current value Id becomes the termination of the defrosting process also changed (Increased / reduced), so the time control for stopping the defrosting operation of the change of the power source voltage can follow exactly. Therefore, the occurrence of lagged To prevent frost, and excessive defrosting can also be prevented. Therefore, the procedure for termination defrosting and the air conditioning system according to the present invention in a wider power source voltage range and under one greater energy source variation be applied.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is a diagram showing a cooling circuit and a control circuit of an air conditioner according to the invention;

2 Fig. 10 is a flowchart showing an embodiment of a method of stopping the defrosting operation of the air conditioner;

3 Fig. 10 is a conceptual diagram showing the change of the drive current of the compressor with the passage of time during the defrosting operation; and

4 FIG. 15 is a diagram showing the changes of a reference current value for terminating the defrosting operation and a drive current value of a compressor with a change of a power source voltage in the flowchart of FIG 2 shows.

DETAILED DESCRIPTION OF THE PREFERRED Embodiment

A preferred embodiment of the invention will be described below with reference to 1 to 4 described.

1 schematically shows an air conditioner, which performs an air conditioning operation without Außenwärmeaustauschertemperatursensor and without external control in an outdoor unit.

First is an outdoor unit 1 with a compressor 10 for compressing refrigerant, an outdoor heat exchanger 11 for performing heat exchange with the outside air by radiating heat to the outside air when the cooling operation is performed, and taking in heat from the outside air when the heating operation is performed, a four-way valve 13 for reversing the direction of circulation of the refrigerant, an expansion valve 14 , a store 15 and maintenance valves 16a and 16b equipped with inter-unit piping extending from the indoor unit. These parts are connected to each other by a refrigerant pipe. Next contains the outdoor unit 1 an outside air blower 12 for blowing air on the outdoor heat exchanger 11 , and a connection plate 17 which is connected to inter-unit lines extending from the indoor unit.

The indoor unit 2 is with an indoor heat exchanger 20 for performing the heat exchange with the inside air, an inside air blower 21 for blowing the inside air to the indoor heat exchanger 20 , a temperature sensor 22 for detecting the internal temperature and an internal control 23 equipped to control the entire operation of the air conditioning. The interior control 23 contains a power relay 24 for controlling the drive of the compressor 10 (Pressing / stopping the compressor 10 ) and a current sensor 25 for detecting the drive current value of the compressor 10 , Next is the interior control 23 the indoor unit 2 with a receiver 26 for receiving drive information (signals) from a wireless remote controller (hereinafter referred to as "remote controller") 28 for issuing different commands for driving the air conditioner (setting parameters, operating / stopping the air conditioner, etc.), and a plug 27 , through which the air conditioner power is supplied, equipped.

In the outdoor unit 1 are the two inter-unit pipelines 3 that differ from the indoor unit 2 extend, with the maintenance valves 16a and 16b connected, and the five inter-unit lines 4 that differ from the indoor unit 2 extend are with the connection plate 17 connected. In this case, it is needless to say that the number of inter-unit piping 3 and the number of inter-unit lines 4 are not limited to these values.

In the following, the flow of the refrigerant in the in 1 described refrigerant circuit described.

During the heating operation of the air conditioning is initially the four-way valve 13 switched to a heating operation side. At this time, as shown by arrows with dashed lines, the refrigerant flowing in the compressor is running 10 was compressed by the four-way valve 13 and flows through the service valve 16a and the inter-unit piping 3a in the indoor heat exchanger 20 the indoor unit 2 , The refrigerant in the indoor heat exchanger 20 exchanges the heat with air coming from the inside air blower 21 is blown off, so that the heat of the refrigerant is radiated to the air. The heat exchanged refrigerant thereby passes through the inter-unit piping 3b and the maintenance valve 16b and returns to the indoor unit 1 back. Thereafter, the refrigerant passes through the expansion valve 14 and flows into the outdoor heat exchanger 11 , In the outdoor heat exchanger 11 The refrigerant exchanges heat with air coming from the outside air blower 12 is blown out, so that the heat is absorbed by the outside air, and then flows through the four-way valve 13 and the memory 15 in the compressor 10 so that the heating operation is performed based on the heating cycle.

On the other hand, during the cooling operation, the air conditioner becomes the four-way valve 13 initially switched to a cooling operation side. At this time, as shown by solid line arrows, the refrigerant passes through the four-way valve 13 and then flows into the outdoor heat exchanger 11 , In the outdoor heat exchanger 11 The refrigerant exchanges heat with the outside air from the outside air blower 12 is blown off, so that its heat is radiated to the outside air. Thereafter, the so heat exchanged refrigerant passes through the expansion valve 14 and flows through the service valve 16b and the inter-unit piping 36 in the indoor heat exchanger 20 the indoor unit 2 , In the indoor heat exchanger 20 The refrigerant exchanges heat with the inside air coming from the inside air blower 21 is blown out, so that it absorbs the heat of the indoor air. Thereafter, the thus heat-exchanged refrigerant flows through the inter-unit piping 3a and the maintenance valve 16a and returns to the outdoor unit 1 back. In the outdoor unit 1 The refrigerant flows through the four-way valve 13 and the memory 15 in the compressor 10 so that the cooling operation is performed based on the cooling cycle.

During the defrosting operation, the same cooling cycle as in the above-described cooling operation is performed, the outside air blower 12 and the indoor air blower 10 however, they are operated at rest (non-blistering condition) or at a low air blast condition.

When next In general, the control operation of the air conditioner will be as follows carried out.

First, the plug 27 connected to an outlet of a power source to keep the air conditioner in such a condition that power can be applied to the air conditioner at all times. Further, an arbitrary drive mode of the cooling operation mode and the heating operation mode becomes by using the remote control 28 selected, the desired indoor temperature is set as the target temperature by using the remote control 28 is set, and a drive start command is by operation of a drive switch of the remote control 28 transferred to the air conditioner.

When the drive start command by the receiver 26 is received, the indoor controller turns off 23 the four-way valve 13 the outdoor unit 1 on the cooling side, if by the receiver 26 received drive mode indicates the cooling mode of operation, or switches the four-way valve 13 the outdoor unit 1 on the heating side, when the drive mode indicates the heating operation mode, and also turns the inside air blower 21 one. Further calculates the interior control 23 the temperature difference between the temperature passing through the internal temperature sensor 22 is detected, and the target temperature by the remote control 28 transmitted and by the recipient 26 is received, and turns on the outside air blower 12 and the power relay 24 based on the thus calculated temperature difference, so that the air conditioning operation is performed.

If the defrosting operation is required, when the heating operation in the air conditioner is selected and performed, the indoor control switches 23 the four-way valve 13 to the cooling operation side to reverse the cycle of the refrigerant, so that the defrosting operation is performed as a cooling cycle. According to this embodiment, when it is judged based on the following procedure that the defrosting should be terminated, the defrosting operation and the four-way valve are ended 13 switched to the heating operation side to resume heating operation.

The detecting method and the defrosting termination judgment method will be described with reference to the flowchart of FIG 2 described.

When defrosting begins, the four-way valve becomes 13 switched to the cooling operation side (S1), and the compressor 10 the outdoor unit 1 is operated while the refrigerant circuit is set to the refrigeration cycle (S2). Further, a timer a is operated (S3). The timer a is installed in the indoor controller to count the time during defrosting.

With regard to some types of compressors, such a case occurs that the drive current value for each compressor becomes unstable at the time when the defrosting operation is started. Therefore, in order for the controller to neglect the unstable drive current, a masking time is detected for detecting the drive current value of the compressor 10 is set, and in step S4, it is judged whether the timer a counts the 3 second offense. If the timer a does not count the procedure of 3 seconds, the time-course check described above is repeated, and when it is judged that 3 seconds have passed, the current value I of the compressor becomes 10 detected as initial current value Is and stored in a first memory M1 of the internal control (S5).

Subsequently, the current value I of the compressor 10 detected (S6), and the initial current value Is, which is stored in the first memory M1, and the current I of the compressor 10 that is detected are compared with each other (S7). When it is judged that the current value I is smaller than the initial current value Is, the current value I is set as the calculation current value Ik and in a second memory M2 of the indoor controller 23 stored (S8). On the other hand, when the current value I is greater than or equal to the initial current value Is, the initial current value Is is set as the calculation current value Ik and stored in the second memory M2 (S9).

It is checked whether the timer a counts one minute (60 seconds), that is, it is checked whether 60 seconds have passed or not (S10). If one minute has not passed, the process proceeds to step S130 to control the drive current I of the compressor 10 and then the current value I thus detected is compared with the calculation current value Ik stored in the second memory (S140). When the current value I is less than the calculation current value Ik, the current value I thus detected is stored as the new calculation current value Ik in the second memory (step S150). On the other hand, if the current value I is not smaller than the calculation current value Ik, the calculation current value Ik is kept unchanged (step S160). Thereafter, the processing returns to step S10 to judge whether the timer counts one minute. These steps from S10 to S160 are repeated until the timer counts one minute in step S10.

If the timer counts one minute in step S10, the processing proceeds to step S11 to obtain a reference current value Id by the following equation based on the current value Ik finally stored in the second memory M2 in step S150 or S160 and the parameter F and K in the interior control 23 the indoor unit 2 have been stored in advance, to calculate: Id = Ik + (F - Ik) × K

The calculation result is set as the reference current value Id and in a third memory M3 of the indoor controller 23 is stored (S12) to judge whether the defrost drive operation should be terminated or not.

Here, the parameters F and K are set in accordance with the capacity of the compressor used, the manufacturer of the compressor used, and so on. In this embodiment, a plurality of pairs of parameters F and K are prepared in advance and in a memory other than the first to third memories in the indoor controller 23 the indoor unit 2 saved. For example, in the method of manufacturing an air conditioner from a manufacturer, a pair of parameters F and K will be the most appropriate net, to set the reference current value of the air conditioning compressor, is selected from the predetermined pairs of parameters.

After 60 seconds have elapsed, the current value (drive current value) I of the compressor becomes 10 during the defrosting operation (S13), and it is judged whether the current value I is equal to or greater than the reference current value Id calculated in step S11 (S14). When the current value I of the compressor 10 is smaller than the reference current value Id, the defrosting operation is continued, and the processing returns to step S13 to repeat the current value I of the compressor 10 and compare it again with the reference current value Id. When the current value I of the compressor 10 is equal to or greater than the reference current value Id, the initial current value Is, the calculation current value Ik and the reference current value Id stored in the first to third memories are cleared (S15 to S17), and the timer a is reset (S18), whereby the defrosting operation is terminated and the process returns to the normal heating operation.

Hereinafter, the calculation of the reference current value Id for the termination of the defrosting operation based on the calculation equation of the step S11 in the flowchart of FIG 2 described by the use of some examples.

In these examples, it is assumed that the parameters F and K (F = 4.78, K = 0.591) are selected from the number of numerical values that are in advance in the indoor control 23 are prepared. At this time, for example, when the power source voltage is equal to a rated voltage Va [Volt], the calculation current value Ik that is finally stored in the second memory M2 by the flowchart of FIG 2 is equal to 3.0 [Ampere] = Ia, Id becomes by the following equation from step S11 of the flowchart of FIG 2 shown: Id = Ia + (F - Ia) × K = 3.0 + (4.78-3.0) × 0.591 ≒ 4.05 (1)

As described above, the defrost end current reference value Id is 4.05 [Ampere] = Ida. The defrosting operation is terminated at the time ta when the current value I of the compressor 10 exceeds the reference current value Ida.

For example, if the power source voltage is equal to Vb [volts] lower than the rated voltage, that to the compressor 10 voltage to be applied is also reduced, and thus the calculation current value Ik, which is finally stored in the second memory M2 by the flowchart of FIG 2 is stored, also reduced. Therefore, if Ik is 2.5 [Ampere] = Ib, Id = Ib + (F-Ib) × K = 2.5 + (4.78-2.5) × 0.591 × 3.85 (2)

At this time, the defrost end current reference value Id is 3.85 [Ampere] = Idb. As a result, the defrosting operation is terminated at the time tb. if the current value I of the compressor 10 exceeds the reference current value Idb.

On the other hand, if the power source voltage is Vc [volts] higher than the rated voltage V, the voltage applied to the compressor increases 10 is applied, and therefore the calculation current value Ik, which finally rises in the second memory M2 through the flowchart of FIG 2 is stored. Therefore, the calculation current value is 4.0 [Ampere] = Ic, Id = Ic + (F - Ic) × K = 4.0 + (4.78 - 4.0) × 0.591 ≒ 4.46 (3)

This time is the reference current value Id for the termination of defrosting is 4.46 [ampere] = Idc. consequently the defrost operation is terminated at the time tc when the current value I of the compressor exceeds the reference current value Idc.

3 is a conceptual diagram showing the change of the drive current I of the compressor 10 with the progress of time during defrosting.

To start the defrost process, the air conditioner is controlled to switch the heating mode to the cooling mode. Therefore, at the start time of the defrosting operation, the drive current I of the compressor becomes 10 considered equal to zero or a small value, as in 3 shown because the air conditioning load is equal to zero at this instantaneous time. As the cooling operation proceeds, the drive current I of the compressor increases 10 , As the cooling operation progresses, the drive current I of the compressor approaches 10 based on the air conditioning load a substantially fixed value.

As in 3 3, the drive current I corresponds to the drive current value Is at the time of 3 seconds and is stored in the first memory M1. After 30 seconds has elapsed, the drive current I, which fluctuates up and down, is compared with the initial current value Is stored in the first memory. When the drive current I is less than the initial current value Is, the Drive current I stored at this time as calculation current value Ik in the second memory M2. This comparison process is continued until 60 seconds (1 minute).

The calculation current value Ik, which is finally stored in the second memory at the time of 60 seconds, corresponds to the minimum value of the function of the drive current I in the period of 30 seconds to 60 seconds. At the time of 60 seconds, the reference current value Id is calculated on the basis of the calculation current value Ik, which is finally stored in the second memory, and the parameters F and K. After 60 seconds have elapsed, at the time when the drive current I exceeds the reference current value Id (at ts in 3 ) the defrosting process ended.

In the conventional one Air conditioner becomes the reference current value Id regardless of the compressor type etc. set. In this embodiment however, the reference current value Id becomes according to the calculation equation Id = Ik + (F - Ik) × K varies. As described above, the parameters F and K for each performance (Power) of a compressor being used or each manufacturer of the compressor, and therefore becomes the reference current value Id better than parameter to stop the defrost compared to the conventional one Air conditioning used.

4 FIG. 14 is a diagram showing the variation of the calculation current value Ik (Ia, Ib, Ic) finally stored in the second memory M2 and the change of the defrosting time t (ta, b, tc) of the compressor with respect to the change of the power source voltage V (FIG. Va to Vc) shows, and 4 also shows the reference current value (Ida to Idc) for the calculation of the defrosting operation based on the calculation current value Ik (Ia, Ib, Ic) and the power source voltage V (Va, Vb, Vc) by the calculation equation of the flowchart (S11) of FIG 2 is calculated.

The change of the power source value V contains not only a case where the power source value V, which of the Air conditioning supplied is changed, for some reason but also a case in which the energy source (commercial Energy source) in countries, in which the same types of air conditioners are used, different is.

As in 4 For example, when the power source voltage V is changed in the ascending direction, the reference current value Id is increased so that the defrosting operation can be prevented from being terminated at an excessively early time, and thus the defrosting operation can be performed without leaving frost , On the other hand, when the power source voltage V is changed in the decreasing direction, the reference current value is lowered so that the defrosting operation can be prevented from being terminated at an excessively late time, and thus excessive defrosting can be prevented.

In the embodiment described above It prefers that the compressor used in the air conditioner is a constant speed compressor. Continue to be in this embodiment Two types of parameters F and K are used to determine the timing of the Defining the end of defrosting. The number of parameters however, it is not restricted to two, and it can be three or more to the accuracy of the time of termination the defrosting process continues to improve. In this case, the Calculation equation by an improved calculation equation replaced.

In the embodiment described above the inventive method applied to an air conditioner to complete defrosting. However, the present invention is not limited to the air conditioner and Can be applied to any device that has a compressor and a defrosting function, such as a refrigerator, a refrigerator or similar.

As has been described above, according to the invention, the current value of the compressor while of the defrosting operation, and the reference current value for the termination the defrosting operation is based on the thus detected current value certainly. After the reference current value has been determined, the Drive current of the compressor detected, and the drive current is compared with the reference current value. If the drive current value is greater than is the reference current value, the defrosting operation is terminated. consequently the defrosting process can be ended properly while the Occurrence of lagging Ripe and excessive defrosting be prevented.

Further can according to the invention the termination of defrosting, which has a wide power source voltage range support can, without indoor temperature sensor, without indoor heat exchanger temperature sensor and without outdoor heat exchanger temperature sensor and performed without measuring the power source voltage.

Claims (7)

An air conditioner having a compressor and defrosting function, comprising: a detector for detecting a drive current value applied to the compressor during the defrosting operation; and a control unit ( 23 a reference current value calculating means for calculating a reference current value for terminating the defrosting operation on the basis of a variable value of the drive current of the compressor measured by the detector within a predetermined period during the defrosting operation; a judging means for comparing the reference current value with the drive current value of the compressor to judge whether or not the defrosting should be terminated; and a defrost termination means for terminating the defrost operation when the drive current value of the compressor is not less than the reference current value. Air conditioning according to claim 1, wherein the control unit has a memory for storing parameters includes in advance, and the control unit sets the reference current value based on the drive current value of the compressor while of the defrosting operation and that stored in the memory Parameter by using a predetermined calculation equation calculated. Air conditioning according to claim 2, with several sentences of parameters that can be used in the calculation equation for the termination of the defrosting process where memory is prepared and stored, and either Set of parameters selected from the multiple sets to the reference current value to get that for the compressor used is the most suitable. The air conditioner according to claim 2, wherein the reference current value is calculated by the following equation: Id = Ik + (F - Ik) × K, where Id represents the reference current value, F and K represent the set of parameters, and Ik represents the minimum drive current value of the compressor in drive current values of the compressor detected for a given period of time. Air conditioning according to claim 1, wherein the variable value of the drive current value is the minimum value the drive current of the compressor within the given time period is. Method for ending the defrosting process for an air conditioning system with the steps: Detecting a drive current value of the compressor within a given period during the defrosting; Calculating a reference current value for termination the defrosting operation based on the drive current value of the compressor, which was detected in the detection step; Judge whether the defrosting process should be ended or not based on the Comparison between the reference current value and the drive current value of the Kom pressors, which detects after the calculation of the reference current value was, and a set of parameters, which in a calculation equation of the Reference current value for the termination of defrosting are usable; and Termination of the defrost process, if in the judgment step is judged that the drive current value of the compressor after calculating the reference current value is not less than the reference current value. The method of claim 6, wherein the reference current value is calculated using the following equation: Id = Ik + (F - Ik) × K, where Id represents the reference current value, F and K represent the set of parameters, and Ik represents the minimum drive current value of the compressor in drive current values of the compressor detected for a given period of time.