KR20110034950A - System and method for driving compressor by detecting of water temperature - Google Patents

Abstract

PURPOSE: A system and method for driving a compressor are provided to reduce power consumption when a user does not frequently use a purification function. CONSTITUTION: A system and method for driving a compressor comprises a temperature detector(300), a programmable logic controller(400), and a motor drive controller(500). The temperature detector detects the temperature of the water stored in a cool water tank. The programmable logic controller determines whether the water temperature difference of the detected water temperature and preset water temperature is bigger than a preset valve. The motor drive controller controls the RPM of the motor installed in the compressor. The compressor cools the water of a purified water tank according to the result of the detection.

Description

System and method for driving compressor by detecting of water temperature

The present invention relates to a compressor driving system and a driving method according to the temperature detection of water, and more particularly to a system and method for driving a compressor for cooling the water stored in the cold water tank according to the temperature detection of the water stored in the cold water tank.

Recently, as various environmental pollutions increase, there are almost no homes or businesses using raw water, and more and more people buy and drink bottled water for drinking water at home. When drinking water is required in large quantities, such as restaurants, it is often used due to the economic burden.

Such a water purifier is configured such that water supplied from a water pipe passes through a filter composed of several pieces, and filters various foreign substances or heavy metals. The filtered water is stored in the reservoir, and the user drinks or uses the water by pushing the cup into an externally installed dispenser.

Briefly, the operation principle of the purified water is supplied to the purified water tank through the filter, the water supplied to the purified water tank is supplied to the hot water tank and the cold water tank is heated and cooled, respectively. Then, the water supplied to the purified water tank, the hot water tank and the cold water tank is extracted through the valve through the respective paths.

As described above, the conventional water purifier drives the compressor provided therein at a fixed speed, and when the water purifier is frequently used, such as daytime, it is not only able to rapidly cool the water stored in the cold water tank, but also the water purifier such as night or dawn. There is a problem of unnecessarily generating a power consumption when the use of is not frequent.

An aspect of the present invention is to provide a compressor driving system and a driving method capable of fluidly driving a compressor for cooling water stored in a cold water tank according to the temperature of water.

An aspect of the present invention provides a compressor driving system for a water purifier including a cold water tank and a purified water tank for supplying water to the cold water tank, the compressor comprising: a temperature detector configured to detect a temperature of water stored in the cold water tank; An operation control unit which determines whether a difference between the detected water temperature and a preset water temperature is greater than a preset value; And controlling the speed of the motor provided in the compressor for cooling the water stored in the cold water tank to the first predetermined speed, respectively, depending on whether the difference between the detected water temperature and the preset water temperature is greater than a preset value. It provides a compressor driving system according to the temperature detection of the water comprising a; motor drive control unit for controlling at a second set speed slower than the set speed.

In one embodiment of the present invention, the water level sensing unit for detecting whether the water level of the water stored in the purified water tank is more than a predetermined level, and if the water level of the water stored in the purified water tank is greater than a predetermined level, the motor drive control unit is If the speed of the motor is controlled at the first set speed, and the water level of the water stored in the purified water tank is not equal to or greater than a preset level, the motor driving controller determines a difference between the temperature of the water detected in the cold water tank and the preset water temperature. According to the present invention, a compressor driving system according to temperature detection of water is provided, wherein the speed of the motor is controlled at the first set speed or at a second set speed slower than the first set speed.

In another embodiment of the present invention, the first set speed is more than 3000 RPM, the second set speed provides a compressor drive system according to the temperature detection of water, characterized in that less than 3000 RPM.

According to another aspect of the present invention, in a compressor driving method of a water purifier including a cold water tank and a purified water tank for supplying water to the cold water tank, a difference between a temperature of water detected in the cold water tank and a preset water temperature is greater than a preset value. Determining whether large; If the difference between the detected water temperature and the preset water temperature is greater than the preset value, the speed of the motor provided in the compressor for cooling the water stored in the cold water tank is controlled at the first set speed, and the detected water temperature and And a drive motor speed control step of controlling the speed of the motor to a second set speed slower than the first set speed if the difference in temperature is not greater than a preset value. To provide.

In an embodiment of the present disclosure, the method may further include detecting whether a water level of the water stored in the purified water tank is greater than or equal to a predetermined level, and when the water level of the water stored in the purified water tank is greater than or equal to a preset level, the speed of the motor When the water level of the water stored in the purified water tank is controlled at a first set speed and is not equal to or greater than a preset water level, the motor is set according to whether the difference between the temperature of the water detected in the cold water tank and the preset water temperature is greater than a preset value. It provides a compressor driving method according to the temperature detection of the water, characterized in that for performing the drive motor speed control step of controlling the speed at the first set speed or at a second set speed slower than the first set speed.

According to the present invention, it is possible to fluidly drive a compressor that cools the water stored in the cold water tank according to the temperature detection of the water, so that the water stored in the cold water tank can be rapidly cooled when the water purifier is frequently used, such as during the day. When the use of water purifiers is not frequent such as dawn, power consumption can be significantly reduced.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention may be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shape and the size of the elements in the drawings may be exaggerated for clarity and the same elements are denoted by the same reference numerals in the drawings.

1 is a view showing the interior of a water purifier equipped with a compressor according to the present invention. Referring to FIG. 1, the water purifier 100 includes a main body 110, a water supply unit 120, a filtration unit 130, and a water purification tank. 140, the cold water tank 150, the hot water tank 160, the purified water outlet pipe 170, the drain pipe 180, and the over heating pipe 190.

The main body 110 is formed at one side of the casing 111 and the casing 111 to form an exterior, and an air inlet 112 through which outside air is introduced, and an air inlet to discharge the air in the casing 111 to the outside. The air outlet 113 formed in the casing 111 to correspond to the 112, the interior of the plurality of support portion 114, the casing 111 provided on the lower outer surface of the casing 111 so that the main body 110 is easily installed. The compressor 115 is provided at one side to change the refrigerant gas of low temperature and low pressure into a refrigerant gas of high temperature and high pressure, and is installed at one side of the compressor 115 to change the refrigerant gas of high temperature and high pressure flowing from the compressor 115 into the refrigerant liquid. A condenser 116 connected to the compressor 115 by a refrigerant pipe (not shown) is provided on one side of the condenser 116 to cool the compressor 115 while liquefying the refrigerant flowing in the condenser 116. 116 and fan 117, fan for blowing air around the compressor 115 And a motor 118 that is coupled to 117 and generates power to rotate the fan 117.

The water supply unit 120 is connected to the tap water 121 for supplying raw water, such as tap water, and a water supply pipe guiding the raw water supplied from the tap water 121 to be introduced into the filtration unit 130 ( 122).

Filtration unit 130, at least one filter 131 connected to the water supply pipe 122, the filter 131 is connected to the filter 131 to filter the raw water flowing from the water supply unit 120 purified water purified by the filter 131 It includes a purified water inlet pipe 132 to supply to the purified water tank 140.

The filter 131 is a sedimentation filter for removing suspended solids and debris from raw water, and a sun carbon filter and a sun carbon for removing chlorine components and foreign substances (comparatively large particles) contained in water passing through the sedimentation filter. Membrane filter to remove various heavy metals contained in the water passing through the filter, as well as carcinogens, Carbon filter after removing odor and toxic gas components that have penetrated the water through the membrane filter, and sterilizing water passing through the carbon filter It is preferable to include an ultraviolet filter.

The purified water tank 140 is disposed above the main body 110 and connected to the filter 131 on the upper surface of the purified water tank 140 so that purified water flows into the purified water tank 140 through the filtration unit 130. One end of the purified water inlet pipe 132 is connected, and stores the purified water.

On the other hand, the purified water tank 140 and the cold water tank 150 are installed to distinguish each. One side of the cold water tank 150 is connected to one end of the discharge pipe (not shown) to take out the cold water stored in the cold water tank 150 through a discharge valve (not shown), the lower portion of the cold water tank 150 Cold drain pipe 151 is connected to discharge the cold water stored for a long time. The cold water tank 150 is provided with a cooling coil 153, such as an evaporation tube, on one side of the lower portion, and the purified water stored in the purified water tank 140 is cooled by the cooling coil 153 to be made of cold water to the cold water tank 150. Stored.

In addition, the cold water tank 150 preferably further includes a cold drain valve 155 provided to open and close the flow of the cold drain pipe 151.

The hot water tank 160 is connected to the purified water tank 140 to heat and store the purified water introduced from the purified water tank 140, and one side of the hot water tank 160 to take out the hot water stored in the hot water tank 160 valve One end of the extraction pipe is connected to be withdrawn through, the hot water pipe 161 connected to the lower portion to discharge hot water stored for a long time, is provided on one side of the lower portion to heat the purified water flowing into the hot water tank 160 to the hot water Heating coil 163 to make, including the on and off valve 165 provided to open and close the flow of the hot water pipe (161).

The purified water outlet pipe 170 is connected between the purified water tank 140 and the hot water tank 160 to guide the purified water introduced from the purified water tank 140 to the hot water tank 160.

The drainage pipe 180 is a cold drainage pipe 151 and the hot water drainage pipe 161 are combined, the cold water flowing through the cold drainage pipe 151 and the hot water introduced through the hot water drainage pipe 161 to the outside of the main body 110. Discharge it.

The overheating tube 190 is connected to the hot water tank 160 and the other side is extended toward the purified water tank 140 so that the hot water overflowed from the hot water tank 160 is overflowed into the purified water tank 140.

Cold water tank 150 is connected to the purified water tank 140 by the purified water outlet pipe 170 to cool and store the purified water introduced from the purified water tank 140.

The overflow pipe 191 is connected to the cold water tank 150 on one side and extends toward the water purification tank 140 on the other side. Cold water flowing into the purified water tank 140 through the overflow pipe 191, because the temperature is low, if the cold water stored in the cold water tank 150 is full and the pressure is not enough cold water is overflow pipe 191 Since it is difficult to flow into the purified water tank 140 through the pump may be provided on the overflow pipe 191.

2 is a block diagram of a compressor drive system according to the present invention. Referring to FIG. 2 together with FIG. 1, the compressor driving system includes a water level detector 200, a temperature detector 300, an operation controller 400, and a motor drive controller 500.

The water level detecting unit 200 detects whether the water level stored in the purified water tank 140 is greater than or equal to the preset water level. The water level detection unit 200 may be implemented as a capacitive sensor, and generates a detection signal when water fills a predetermined level inside or outside the purified water tank 140.

The temperature detector 300 detects the temperature of the water stored in the cold water tank 150 when the water level of the water stored in the purified water tank 140 is not equal to or higher than the preset water level. The temperature detector 300 may be implemented as a temperature detection sensor and is provided inside or outside the cold water tank 150 to generate a corresponding temperature detection signal.

The operation control unit 400 receives a detection signal from the water level detection unit 200 when the water level of the water stored in the purified water tank 140 is greater than or equal to a preset level to generate a corresponding motor speed control signal. The operation controller 400 receives the temperature signal detected by the temperature detector 300 to determine whether the difference between the detected water temperature and the preset water temperature (eg, 5 to 7 ° C.) is greater than the preset value. do.

The motor driving control unit 500 receives the motor speed control signal from the operation control unit 400 when the difference between the detected water temperature and the preset water temperature is greater than the preset value, thereby cooling the water stored in the cold water tank 150. The speed of the motor 118 provided in the compressor 115 is controlled to the first set speed. However, the motor driving control unit 500 receives the corresponding motor speed control signal from the operation control unit 400 when the difference between the detected water temperature and the preset water temperature is not greater than the preset value, thereby reducing the speed of the motor 118. Control at a second set speed slower than the first set speed.

In the present invention, a brushless direct current (BLDC) motor was used, and the first set speed and the second set speed were set to 3000 RPM or more and less than 3000 RPM, respectively. The reason why the first set speed and the second set speed are set in such a range is that the amount of power consumption is remarkably lower than 3000 RPM.

For this reason, when the water purifier is used frequently, such as during the day, the speed of the motor can be controlled to 3000 RPM or more to quickly cool the water stored in the cold water tank. By controlling below 3000 RPM, power consumption can be significantly reduced.

3 is a flowchart of a compressor driving method according to the present invention. 3 will be described together with FIGS. 1 and 2.

First, the water level detecting unit 200 detects whether the water level of the water stored in the purified water tank 140 is greater than or equal to the predetermined level (S100).

After the step S100, if the water level of the water stored in the purified water tank 140 is more than the predetermined level, the operation control unit 400 receives the detection signal from the water level detection unit 200 generates a corresponding motor speed control signal and then the motor drive control unit The 500 receives the motor speed control signal from the operation control unit 400 and controls the speed RPM of the motor 118 to the first set speed (S410). However, if the water level of the water stored in the purified water tank 140 is not more than the predetermined level, the temperature detector 300 detects the temperature of the water stored in the cold water tank 150 (S200).

After operation S200, the operation controller 400 determines whether a difference between the temperature of the water detected by the temperature detector 300 and the temperature of the preset water is greater than the preset value (S300).

After the step S300, if the difference between the water temperature detected by the temperature control unit 300 and the preset water temperature is greater than the preset value, the motor drive control unit 500 receives the motor speed control signal from the operation control unit 400 to the cold water tank The speed of the motor provided in the compressor 115 for cooling the water stored in the 150 is controlled to the first set speed (S410). However, if the difference between the water temperature detected by the temperature detector 300 and the preset water temperature is not greater than the preset value, the motor driving control unit 500 receives the motor speed control signal from the operation control unit 400 and the motor 118. ) Is controlled to a second set speed slower than the first set speed (S420).

4 is a table showing the results obtained by fluidly driving the compressor according to the present invention. Referring to Figure 4, it can be seen that the difference in the power consumption measured by varying the speed of the motor provided in the compressor.

Compressor model used in the present invention is VEMY6H, the power consumption was measured by varying the speed (RPM) of the motor to 2920 RPM, 3246 RPM, 3654 RPM until the temperature of the cold water tank was lowered from 30 ° C to 5 ° C, which is a proper temperature. . At this time, the used amount of the refrigerant (R134a) was 59.5g.

When controlling the motor at speeds of 2920 RPM, 3246 RPM, and 3654 RPM, the power consumptions were 359 Wh, 395 Wh, and 403 Wh, respectively.

When the amount of power consumed when controlling the motor at the speed of 3654 RPM was 100%, the amount of power consumed when the motor was controlled at the speed of 2920 RPM and 3246 RPM was 89% and 98%, respectively.

Taken together, it can be seen that the speed (RPM) of the motor is proportional to the amount of power consumption when considering the amount of power consumption. In particular, when the motor speed is 3246 RPM and 3654 RPM, it can be seen that the power consumption is similar, but when the motor speed is 2920 RPM, the motor speed is significantly smaller than when the motor speed is 3246 RPM and 3654 RPM. have.

From this fact, it is possible to flexibly drive the compressor to cool the water stored in the cold water tank, so that when the water purifier is frequently used, such as during the day, the speed of the motor is set to the first set speed (the reference value set in the present invention is 3000 RPM or more). .) Can quickly cool the water stored in the cold water tank. That is, when the water purifier is frequently used, such as during the day, since the water in the purified water tank is generally supplied to the cold water tank, the difference between the water temperature detected in the cold water tank and the preset water temperature becomes larger than the preset value. The speed of control is controlled to the first set speed.

In addition, when the use of the water purifier is not frequent, such as at night or dawn, the speed of the motor may be controlled to a second set speed (the reference value set in the present invention is less than 3000 RPM), thereby significantly reducing the power consumption. That is, when the water purifier is not used frequently, such as at night or at dawn, the amount of water supplied to the cold water tank is generally less than that of the cold water tank. Therefore, the difference between the water temperature detected in the cold water tank and the preset water temperature is smaller than the preset value. Since it becomes small, the speed of a motor is controlled by a 2nd set speed.

The compressor driving system and the driving method according to the present invention can be equally applicable to a device using a refrigerator and other compressors as well as a water purifier.

The present invention is not limited by the above-described embodiment and the accompanying drawings. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims, .

1 is a view showing the interior of the water purifier equipped with a compressor according to the present invention.

2 is a block diagram of a compressor drive system according to the present invention.

3 is a flowchart of a compressor driving method according to the present invention.

4 is a table showing the results obtained by fluidly driving the compressor according to the present invention.

                 <Explanation of symbols for the main parts of the drawings>

110: main body 120: water supply unit

130: filtration unit 140: water purification tank

150: cold water tank 160: hot water tank

190: overheating pipe 191: overflow pipe

200: water level detection unit 300: temperature detection unit

400: operation control unit 500: motor drive control unit

Claims (5)

In the compressor drive system of the water purifier comprising a cold water tank and a water purification tank for supplying water to the cold water tank, A temperature detector detecting a temperature of water stored in the cold water tank; An operation control unit which determines whether a difference between the detected water temperature and a preset water temperature is greater than a preset value; And Depending on whether the difference between the detected water temperature and the preset water temperature is larger than a preset value, the speed of the motor provided in the compressor for cooling the water stored in the purified water tank, respectively, is controlled at the first set speed or the first set speed. A motor driving control unit controlling the second set speed lower than the speed; Compressor drive system according to the temperature detection of water, comprising a. The method of claim 1, And a water level detecting unit for detecting whether the water level of the water stored in the purified water tank is greater than or equal to a predetermined level. If the water level of the water stored in the purified water tank is greater than or equal to a predetermined level, the motor driving controller sets the speed of the motor to the first setting. If the water level of the water stored in the purified water tank is not equal to or greater than a predetermined level, the motor driving controller determines whether the motor is different depending on whether the difference between the temperature of the water detected in the cold water tank and the preset water temperature is greater than a preset value. Compressor drive system according to the temperature detection of the water, characterized in that for controlling the speed of the control to the first set speed or a second set speed slower than the first set speed. The method of claim 1, The first set speed is more than 3000 RPM, the second set speed is a compressor drive system according to the temperature detection of water, characterized in that less than 3000 RPM. In the compressor driving method of the water purifier comprising a cold water tank and a water purification tank for supplying water to the cold water tank, Determining whether a difference between a temperature of water detected in the cold water tank and a preset temperature of water is greater than a preset value; If the difference between the detected water temperature and the preset water temperature is greater than the preset value, the speed of the motor provided in the compressor for cooling the water stored in the cold water tank is controlled at the first set speed, and the detected water temperature and A driving motor speed control step of controlling the speed of the motor to a second set speed slower than the first set speed if the difference in temperature is not greater than a preset value; Compressor driving method according to the temperature detection of water, comprising a. The method of claim 4, wherein Detecting whether the water level of the water stored in the purified water tank is above a predetermined level, If the water level of the water stored in the purified water tank is greater than or equal to a predetermined level, the speed of the motor is controlled to the first set speed, and if the water level of the water stored in the purified water tank is not greater than or equal to a predetermined level, the water of the water detected in the cold water tank A driving motor speed control step of controlling the speed of the motor at the first set speed or at a second set speed slower than the first set speed according to whether a difference between a temperature and a preset water temperature is greater than a preset value; Compressor driving method according to the temperature detection of the water, characterized in that performed.

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