KR20000033583A - Method for deciding control mode of refrigerator adopting linear compressor - Google Patents

Abstract

PURPOSE: A method for deciding a control mode of a refrigerator is provided to positively correspond to environmental change by easily changing cooling force of a linear compressor. CONSTITUTION: A control mode of a refrigerator is decided by the steps of: minimizing power consumption by running a refrigerator in a low power consumption mode; detecting temperature of the refrigerator when running it; checking an incline of the temperature; performing rapid cooling by running the refrigerator in a cooling mode if the incline is higher than a certain value during a specific time; and quietly running the refrigerator in a sleep mode if the time to open a door has expired.

Description

How to determine the control mode of a refrigerator using a linear compressor

The present invention relates to a method of determining a control mode of a refrigerator employing a linear compressor that enables optimal operation control in a refrigerator employing a linear compressor. Particularly, the present invention relates to a method of determining optimal operation by varying power consumption, noise, and cold power in a refrigerator. The present invention relates to a method of determining a control mode of a refrigerator employing a linear compressor, which maintains the freshness of food and uses a minimum power consumption with a pleasant environment for the customer.

The conventional method of controlling the temperature of a refrigerator employing a Recipro compressor includes a first step of sensing a temperature inside a refrigerator, a second step of comparing the detected temperature with a set temperature, and detecting the above. If the temperature is lower than the set temperature, the compressor is turned off. If the detected temperature is higher than the set temperature, the compressor is turned on to adjust the internal temperature of the compressor.

Looking at the prior art made of each step as follows.

The temperature inside the refrigerator is read from the temperature sensor attached to the inside of the refrigerator.

Then, the temperature inside the refrigerator read from the temperature sensor is compared with the set temperature.

As a result, when the temperature inside the refrigerator is lower than the set temperature, the compressor is turned off. On the contrary, when the temperature inside the refrigerator is higher than the set temperature, the compressor is turned on to cool the refrigerator to be below the set temperature.

This will adjust the temperature inside the refrigerator.

However, in the prior art as described above, when the hot food enters the refrigerator or the refrigerator door is opened frequently, the temperature in the refrigerator rapidly increases, so the compressor always operates with a constant cooling power. Since it is maintained for a long time, there is a problem that the freshness of food can be lowered, and also the compressor operates the same at all times in the middle of the night, which requires a quiet state such as a comfortable sleep of the customer, so that it feels relatively loud in the middle of the night and disturbs the comfortable sleep. There is such a problem.

Accordingly, an object of the present invention for solving the conventional problems as described above is to provide a method of determining a control mode of a refrigerator employing a linear compressor to facilitate the variable cooling power of the linear compressor to actively respond to environmental changes. .

Another object of the present invention is to provide a method for determining a control mode of a refrigerator employing a linear compressor to maintain food freshness due to optimal cooling power control.

Still another object of the present invention is to provide a method of determining a control mode of a refrigerator employing a linear compressor to help the customer to create a pleasant environment by driving in the quietest mode when a quiet state such as a late night is required.

Another object of the present invention is to provide a method for determining a control mode of a refrigerator employing a linear compressor using a minimum power consumption.

1 is a control circuit diagram of a refrigerator employing a linear compressor.

Fig. 2 is a signal waveform diagram of each part in Fig. 1.

3 is a size characteristic diagram for power consumption, noise, and cooling power in accordance with FIG. 1.

4 is a flowchart illustrating a method for determining a control mode of a refrigerator employing the linear compressor of the present invention.

*** Explanation of symbols for main parts of drawing ***

10: linear compressor 20: electric circuit

30: control unit 31: cooling mode determiner

32: stroke controller 33: stroke estimator

In order to achieve the above object, the present invention provides a first step of minimizing power consumption by operating in a low power consumption mode with low power consumption when driving a refrigerator, and a second step of sensing a temperature inside the refrigerator when operating in a low power consumption mode. And a third step of obtaining a temperature rise for a predetermined time by checking a temperature rise gradient of the refrigerator internal temperature detected above, and operating in a cold power mode if the temperature rise for a predetermined time is greater than or equal to a predetermined value. And a fourth step of checking the door opening interval time at the time of requesting a quiet state such as a late night, and driving in a late night mode to operate quietly when the door opening time is longer than a predetermined time.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 4 is a flowchart illustrating a method for determining a control mode of a refrigerator employing a linear compressor according to an embodiment of the present invention. As shown in FIG. 4, a first step of minimizing power consumption by operating in a low power consumption mode with low power consumption when driving a refrigerator ( S1), the second step (S2) of detecting the temperature inside the refrigerator in the operation mode in the operation mode, the third step (S3) of checking the temperature rising slope of the refrigerator inside temperature detected in the above, and for a predetermined time If the temperature rise is greater than or equal to the predetermined value, the fourth step of operating in a cold power mode and performing rapid cooling (S4), and checking the door opening interval time at the time of requesting a quiet state such as the late night, if the door opening time is more than a predetermined time A fifth step S5 is performed to operate in a late night mode and operate quietly.

Thus, as shown in FIG. 1, the control circuit of the refrigerator employing the linear compressor for performing the method comprising the steps includes a linear compressor 10 for adjusting the cooling force by varying the stroke by the vertical movement of the piston. A control unit 30 for controlling the phase of the power supply voltage so that the stroke command value according to the temperature information set by the user and the stroke by the stroke voltage of the linear compressor 10 are matched, and the stroke controlled by the control unit 30 in phase control. It is composed of an electric circuit unit 20 for varying the stroke by controlling the magnitude of the current flowing into the linear compressor 10 according to the size of.

Referring to the operation and effect of the present invention configured as described in detail as follows.

When a 220V power supply voltage as shown in FIG. 2 (a) is supplied from the power supply voltage terminal to the linear compressor 10, a zero-cross signal as shown in FIG. To the stroke controller 32.

The stroke controller 32 then uses the zero-cross signal to determine how long after the zero-cross point to generate the gate signal G, and calculates the determined time, that is, the gate generation time t1. .

Therefore, when the gate signal generation time t1 is small as shown in FIG. 2 (c), the gate signal is set shortly from the zero-cross time point, so that a large amount of current flows as shown in FIG. As in e), when the gate signal generation time t1 is large, the gate signal is set to be large from the zero-cross time point, so that a small current flows as shown in FIG.

When a current flows into the linear compressor 10 by this process, the piston 11 reciprocates up and down.

Here, the reciprocating stroke of the piston 11 is a stroke, and the stroke is varied to vary the cooling force.

At this time, when the user sets the temperature inside the refrigerator, the set temperature is inputted by the cooling mode determiner 31 of the controller 30 to determine the cooling mode for the set temperature, and the stroke command value according to the determined cooling mode is controlled by the stroke controller. Transfer to 32.

In addition, the sensorless stroke estimator 33 of the controller 30 includes a voltage Vo between the power voltage terminal and the current sensing resistor R from the electric circuit unit 20 for supplying current to the linear compressor 10. The voltage V ₁ between the current sensing resistor R and the triac Tr, the voltage V ₃ supplied from the triac Tr to the linear compressor 10, and a capacitor from the power supply voltage terminal. The voltage V ₄ supplied to the linear compressor 10 is input via (C), the stroke is estimated using the stroke voltages Vo, V ₁ , V ₂ , and V ₃ , and the estimated stroke is estimated. Is transmitted to the stroke controller 32.

The stroke controller 32 then receives the stroke command value from the cooling mode determiner 31 and the current stroke information from the stroke estimator 33.

The stroke controller 32 which receives the stroke in this way controls the phase of the power supply voltage so that the current stroke matches the current stroke.

After the phase is controlled in this manner, a gate signal is applied to the triac Tr of the electric circuit unit 20 to supply current to the linear compressor 10.

In this way, the linear compressor 10 is driven to adjust the cooling power of the refrigerator.

In the present invention, as shown in Fig. 3, the operation is usually performed in the stroke S2 of Mode 2 (low power consumption mode) with the lowest power consumption, and the stroke S3 of Mode 3 (cold power mode) when much cold power is required. If you need a quiet state, such as late night, drive in the mode (midnight mode) (S1) to maintain the freshness of food, create a comfortable indoor environment, using a minimum power consumption to provide a better refrigerator for consumers The process is as follows.

The stroke controller 32 of the control unit 30 operates in the stroke S2 of the low power consumption mode shown in Fig. 3 to minimize the power consumption.

When operating in the low power consumption mode, the stroke controller 32 reads the temperature from the temperature sensor installed in the refrigerator in order to cope with a case where the temperature in the refrigerator rises rapidly due to hot food or door opening, and the temperature rises in a constant cycle. (S2)

The temperature rise for a predetermined time is obtained by using the temperature rise gradient thus obtained. (S3)

If the temperature rise obtained above is higher than the set temperature rise THD1, it is determined that this is the time when the temperature in the refrigerator is high and the greatest cooling force is required.

Therefore, the gate signal is output to the triac Tr of the electric circuit unit 20 to operate in the cold force mode S3 shown in FIG.

Then, a lot of current flows into the linear compressor 10, and accordingly, the piston 11 of the linear compressor 10 performs rapid cooling while rapidly reciprocating up and down.

Accordingly, the internal temperature of the refrigerator decreases the temperature within a short time to maintain the freshness of the internal food. (S4)

At the same time, he notices that he doesn't open the refrigerator door well at night.

As a result of the detection, if the time interval in which the door opening is detected is long enough between the previously detected time and the currently detected time, that is, the dT time or more, it is determined that this is a time point requiring a late night or a quiet state.

Therefore, the stroke controller 32 outputs the gate signal for driving in the stroke S1 of the late night mode, which is the quietest mode, to the triac Tr of the electric circuit unit 20.

Then, the triac Tr is turned on so that a small amount of current flows into the linear compressor 10.

Accordingly, the piston 11 of the linear compressor 10 is to reciprocate slowly up and down to operate quietly.

In the end, it provides a more comfortable indoor environment for customers.

As described above, the refrigerator operates in different modes (low power consumption mode, midnight mode, and cold power mode) according to the state of the refrigerator and the surrounding environment, thereby minimizing power consumption and maintaining the freshness of the food in the refrigerator. In order to realize customer-oriented refrigerator control.

Accordingly, the present invention is to enable the intelligent response to the intelligent detection of the rapid rise of the temperature in the refrigerator and the late night, such as a quiet indoor environment using the variable cooling power of the linear compressor.

Claims (1)

A first step of minimizing power consumption by operating in a low power consumption mode in which the refrigerator consumes less power; and a second step of sensing a temperature inside the refrigerator when operating in a low power consumption mode; and detecting the high temperature inside the refrigerator A third step of obtaining a temperature rise for a predetermined time by checking a temperature rising slope of the step; and a fourth step of performing rapid cooling by operating in a cold power mode if the temperature rise for a predetermined time is above a predetermined value; Method of determining a control mode of a refrigerator employing a linear compressor, characterized in that the fifth step of checking the door opening interval time at the time of requesting the state, when the door opening time is more than a predetermined time to operate in a midnight mode to operate quietly. .