ITRM990698A1 - METHOD OF CONTROL OF HEAT OF OVERLOAD IN AN AIR CONDITIONER. - Google Patents

Description

Description of the industrial invention entitled: "METHOD OF CONTROL OF THE OVERLOAD HEAT IN AN AIR CONDITIONER"

DESCRIPTION

FOUNDATION OF THE INVENTION

Field of the invention

The present invention relates to an inverter-type air conditioner which changes the operating frequencies of a compressor in a variable manner according to the cooling or heating capacity, and more particularly to a method of controlling the heat overload of the air conditioner. air by limiting the operating frequencies of the compressor, when a heat overload condition is detected, thereby preventing noise from being generated when the operating frequencies of the compressor change.

DESCRIPTION OF THE PRIOR ART

In general, in a heating operation performed by a compressor in an inverter type air conditioner, if the temperature (Tp) of the indoor heat exchanger drops below the release temperature, as shown in fig. 1, the compressor operating frequency is maintained with increasing heat. However, as soon as the temperature (Tp) of the indoor heat exchanger bypasses the trip temperature, the operating frequency of the compressor is kept at its operating level, limiting any further temperature rise. On the other hand, if the temperature (Tp) continuously increases above the dropping temperature, triggering an overload heat condition, the operating frequency of the compressor decreases so as to protect itself from being damaged.

At this point, when the operating frequency of the compressor decreases to a predetermined level where the temperature (Tp) of the internal heat exchanger begins to drop, the compressor stops the descent and maintains its operating frequency in its proper operating range. On the other hand, when the temperature (Tp) of the indoor heat exchanger drops below the release temperature, the compressor increases its operating frequency in response to changes in the temperature (Tp) of the indoor heat exchanger so that the compressor variably controls its operating frequencies.

However, there are problems with the conventional inverter-type air conditioner overload heat control method in that when a heating overload condition occurs (indoor and outdoor temperature varying above 25 ° C and 20 °, respectively C), the compressor internal pressure increases above a maximum reliability guarantee pressure of 27 kg / cm <2> due to the increase in temperature (Tp) of the internal heat exchanger, thereby reducing the compressor reliability, and when the compressor variably and repetitively controls its operating frequencies in the heat overload condition, the compressor operating frequencies increase and decrease repetitively, causing noises and variations in the heating capacity of the air conditioner.

Summary of the invention

Therefore, the present invention is envisaged to solve the aforementioned problems and it is an object of the present invention to provide a method for controlling the heating overload of the air conditioner by limiting the operating frequency of the compressor to its maximum level, i.e., 2Hz less than the frequency. operating the compressor when the heating overload condition occurs, which takes the minimum number of increases and decreases in the operating frequencies of the compressor, thereby preventing the generation of noise and minimizing the variation in the heating capacity of the air conditioner .

To achieve the aforementioned object, the present invention provides a method for controlling the heating overload of the air conditioner performing the heating operation by variably controlling the operating frequency of the compressor in response to changes in the temperature of a heat exchanger. internal, the method including the operations of:

discriminate if the indoor heat exchanger temperature exceeds the drop temperature due to the heat overload condition;

limiting the maximum operating frequency of the compressor, when the indoor heat exchanger temperature is maintained above the dropping temperature, by setting a predetermined number lower than the one just before the indoor heat exchanger temperature reaches the dropping temperature;

discriminate if the temperature of the internal heat exchanger falls below the release temperature;

discriminating whether a predetermined period of time has elapsed with the internal heat exchanger temperature being maintained below the release temperature before the internal heat exchanger temperature drops from the drop temperature below the release temperature; And

restoring the maximum operating frequency of the compressor to a predetermined number greater than the maximum operating frequency limited in the previous operation after a predetermined period of time has elapsed.

Brief description of the drawings

Fig. 1 is a diagram for illustrating the operating frequency of a variable controlled compressor in relation to the temperature variations of a conventional indoor heat exchanger;

fig. 2 is a block diagram of an inverter of an air conditioner according to an embodiment of the present invention;

fig. 3 is a circuit diagram for driving the compressor according to the present invention;

fig. 4 is a flow chart for illustrating the heating overload control operating sequence of an air conditioner according to the present invention; And

fig. 5 is a diagram for illustrating the operating frequency of the variable controlled compressor in relation to the temperature variations of the internal heat exchanger according to the present invention.

Detailed description of the invention

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. As shown in figs.

2 and 3, a converter 3 rectifies and levels an AC alternating current input from an energy input terminal 1 to convert it into direct current DC. Power supply means 5 change the DC converted in the converter 3 to predetermined DC voltages (DC of 5V for a microcomputer drive energy, a DC of 12V for a load drive energy).

Control means 7 consist of a microcomputer which initializes the air conditioner by receiving a DC voltage output from the power supply means 5 and determines the operating frequency of a compressor 13 according to an instruction of an indoor unit and the condition of the outdoor for emit an inverter driving signal. The inverter driving means 9 amplifies the PWM pulse width modulation signal sent by the control means 7 into an inverter driving signal to rotate the compressor at its operating frequency determined by the control means 7.

Furthermore, an inverter 11 alternately activates and deactivates six power transistors TRI -TR6 in response to the driving signal sent by the inverter driving means 9 to transform the DC output from the converter 3 into 3 phases (phase u, phase v and phase w) of AC to be supplied to the compressor 13. The temperature detection means 15 consist of a thermistor which controls the variations in the temperature outside, inside and in the internal heat exchanger.

Now, the method of controlling the overload heat of the air conditioner thus structured will be described. When AC is supplied from the power input terminal 1, converter 3 converts the AC to DC. Then, the DC is input into the power supply means 5 in which the DC is transformed respectively into DC microcomputer driving energy of 5V required to drive the air conditioner and into DC load driving energy of 12V to reach subsequently fed to the control means 7 and to the inverter driving means 9. The control means 7 receive the DC voltage (microcomputer driving energy) emitted by the power supply means 5 to initialize the air conditioner.

At this point, if a user presses an operation button on a remote control device or operates a button on the control panel of the indoor unit to set a desired operating mode and temperature Ts, the control means 7 determine a frequency operation of the compressor 13 in relation to the external condition and to an instruction of the indoor unit to output a PWM signal for driving the inverter.

Consequently, the inverter driving means 9 amplifies the PWM signal sent by the control means 7 so as to alternately activate and deactivate six power transistors TRI - TR6 of the inverter 11, so that the DC output from the converter 3 is transformed into 3 AC phases to be used to rotate the compressor 13.

In other words, the inverter 11 supplies an operating frequency of the compressor 13 and a voltage relevant to the compressor 13 according to the cooling or heating capacity necessary to operate the air conditioner, so that the compressor 13 is operated at a desired operating frequency. .

At this point, the operating frequencies of the compressor 13 are controlled in a variable manner in relation to the variations in the temperature of the internal heat exchanger. When a heat overload condition occurs (internal temperature of 25 ° C and external temperature of more than 20 ° C), the temperature of the internal heat exchanger increases due to the increase in the internal pressure of the compressor 13. Hence, the frequencies operating times of the compressor 13 increase and decrease in a repetitive manner within a short period of time. In other words, a so-called heat overload control state occurs.

Therefore, when the heat overload condition is detected, the operating frequencies of the compressor 13 are limited so as to prevent the heat overload control state from occurring as shown in FIG. 4.

Fig. 4 is a flow chart for illustrating the heating overload control operating sequence of the air conditioner according to the present invention. The reference symbol S in fig. 4 indicates a step.

Firstly, in the heating operation carried out by the compressor 13, the temperature Tp of the internal heat exchanger is controlled by temperature detection means 15 to determine if it is lower than the release temperature (about 53 ° C, the temperature preset in the control means), as in fig. 5. If so, the operating frequency of compressor 13 increases until the temperature (Tp) of the indoor heat exchanger reaches the release temperature. When it exceeds the release temperature, the increase in the operating frequency of the compressor 13 is stopped and maintains the current operating level.

At this point, in step 1, the control means 7 discriminate if the temperature (Tp) of the internal heat exchanger continues to increase due to the overload heat and exceeds the drop temperature (about 60 ° C the preset temperature in the means control) shown in FIG. 5.

As a result of the discrimination in the YES step, if the temperature (Tp) of the indoor heat exchanger is kept below the dropping temperature (in the case of NO), the compressor 13 maintains its current operating frequency and repeats the subsequent operations to YES as long as the temperature (Tp) of the indoor heat exchanger exceeds the drop temperature.

On the other hand, as a result of the discrimination in step SI, if the temperature (Tp) of the internal heat exchanger exceeds the drop temperature (in case of SI), the flow proceeds to S2, in which the control means 7 determine if the heating overload has occurred. Thus, the operating frequency of the compressor 13 is reduced by 2Hz (the initial operating frequency of the compressor shown in FIG.

5), just before the temperature (Tp) of the internal heat exchanger exceeds the dropping temperature, for a maximum operating frequency of compressor 13 (the first maximum operating frequency of the compressor shown in fig. 5). At this point, a predetermined period of time begins to be counted, 10 minutes.

Then, in step S3, the operating frequency of the compressor, as shown in fig. 5, is reduced to protect the compressor 13 until the temperature (Tp) of the internal heat exchanger drops below the drop temperature. In step S4, the control means 7 discriminates whether the temperature of the internal heat exchanger continues to drop below the drop temperature according to the reduced maximum operating frequency of the compressor 13.

As a result of discrimination in step S4, if the temperature (Tp) of the indoor heat exchanger is still higher than the falling temperature (in the case of NO), the flow returns to step S3 and repeats the operations before step S3 while the frequencies operating conditions of the compressor 13 continue to decrease until the temperature (Tp) of the internal heat exchanger falls below the drop temperature.

On the other hand, as a result of the discrimination in step S4, if the temperature (Tp) of the indoor heat exchanger drops below the dropping temperature (in case of SI), the flow proceeds to step S5 where the compressor 13 stops the decrease in its operating frequencies and maintain its current operating level.

Consequently, in step S6 the control means 7 discriminate whether the temperature (Tp) of the internal heat exchanger continues to drop below the release temperature as shown in fig. 5.

As a result of the discrimination in step S6, if the temperature (Tp) of the internal heat exchanger exceeds the release temperature (in case of NO), the flow advances to step S61 in which the control means 7 continue to count the time and , then, they return to step S5 to repeat the operations before S5.

As a result of the discrimination in step 56, if the temperature (Tp) of the internal heat exchanger falls below the release temperature (in case of SI), the flow proceeds to step S7 in which the control means 7 determine whether 10 have elapsed. minutes between when the temperature (Tp) of the internal heat exchanger has exceeded the drop temperature and when it falls below the release temperature, if 10 minutes have not elapsed (in the case of NO), the flow proceeds to step S7 in which the control means 7 increase the period of time that must pass.

As a result of the discrimination in step 57, if 10 minutes have elapsed (in case of SI), the flow proceeds to step S8 wherein the control means 7 determines whether the overload heat control state caused by the overload condition is abandoned and resets the compressor operating frequency to that (compressor initial operating frequency) 2Hz higher than the maximum operating frequency (the first compressor maximum operating frequency) limited by the heating overload condition in S2.

Subsequently, in step S9, the frequency of the compressor 13 is increased until the temperature (Tp) of the internal heat exchanger is supplied above the release temperature, as illustrated in fig. 5, and in step S10, the control means 7 discriminates whether the temperature (Tp) of the internal heat exchanger has increased according to the ascending frequency of the compressor 13 so as to become higher than the release temperature.

As a result of discrimination in step SIO, if the temperature (Tp) of the indoor heat exchanger is below the release temperature (in case of NO), the flow returns to step S9 to continuously increase the frequency of compressor 13 until point at which the temperature (Tp) of the internal heat exchanger begins to become higher than the release temperature, and carry out the repeated operations following step S9.

Meanwhile, as a result of discrimination in step SIO, if the temperature (Tp) of the indoor heat exchanger is greater than the release temperature (in case of SI), the flow advances to step SII for the similar frequency release in compressor 13 and as illustrated in fig. 5, maintain the current operating frequency of the compressor, after which the flow returns to step SI to carry out the operations following step SI in a repetitive manner.

Furthermore, as a result of the discrimination in step S7, if 10 minutes have not passed (in case of NO), the control means 7 discriminates that the overload control according to the heating overload condition is not abandoned, and advances to step S9 to increase the frequency of the compressor 13, as illustrated in fig. 5, until the temperature (Tp) of the internal heat exchanger increases above the release temperature, and carry out the operations following step S9 in a repetitive manner.

As described above, whenever the heating overload condition occurs, that is, the temperature (Tp) of the internal heat exchanger exceeds the drop temperature, the maximum operating frequencies are limited (first, second, third ....) of the compressor by setting them 2Hz lower than those before the temperature (Tp) reaches the dropping temperature as shown in Fig. 5. Therefore, the number by which the compressor increases and decreases its operating frequencies has been reduced.

Also, the predetermined 10 minute time period to elapse at the first, second, third ... maximum compressor frequency limited by the overload heat control becomes variable and the compressor operating frequencies return to their initial level, so that it can the operating efficiency of the compressor 13 is improved.

Therefore, there are advantages in the method of controlling the overload heat of the air conditioner according to the present invention in that, when the overload heat condition is detected, the maximum operating frequency of the compressor is limited by setting it to 2Hz less than the frequency. operating current just before the overload heat condition occurs, so that the number by which the compressor increases and decreases its operating frequencies is minimized to prevent compressor noise generation and reduce variation in heating capacity of the air conditioner.

Claims (5)

CLAIMS 1. Overload heat control method of an air conditioner which performs a heating operation by variably controlling the operating frequencies of a compressor in response to changes in the temperature of an indoor heat exchanger, the method comprising the operations of : discriminate if the indoor heat exchanger temperature exceeds the drop temperature due to the overload heat condition; limiting the maximum operating frequency of the compressor, when the internal heat exchanger temperature is kept higher than the dropping temperature, by setting a predetermined number lower than the one just before the internal heat exchanger temperature reaches the dropping temperature; discriminate if the internal heat exchanger temperature drops below, the release temperature; discriminating whether a predetermined period of time has elapsed with the internal heat exchanger temperature and is maintained below the release temperature before the internal heat exchanger temperature drops from the drop temperature below the release temperature; And restoring the maximum operating frequency of the compressor to a predetermined number higher than the maximum operating frequency limited in the previous operation after a predetermined period of time has elapsed. The method as defined in claim 1, the method comprising the operation in which the operating frequency of the compressor is changed in a variable manner by decreasing the temperature Tp of the internal heat exchanger so as to drop below the dropping temperature, if it exceeds the dropping temperature, and stopping the decrease to maintain its current operating level, if the indoor heat exchanger temperature drops below the dropping temperature. The method as defined in claim 1 or 2, the method comprising the step of resetting the counted time period if the indoor heat exchanger temperature does not drop below the release temperature in the release temperature discrimination operation. The method as defined in claim 1, the method comprising a range of predetermined operating frequencies of the compressor to be controlled set between 1 - 3 Hz. The method as defined in claim 1 or 4, the method comprising a predetermined period of time in the range of 5 to 15 minutes.