KR100571311B1 - Defrost method of dual water-generating device - Google Patents

Abstract

The present invention; The present invention relates to a defrosting method of a dual drinking water generating device that naturally defrosts ice frozen on the surface of an evaporator by controlling the fan to be driven for a certain time even after the compressor is stopped.

The present invention as such; A first step S1 in which the microcomputer 100 drives the compressor 71 and the fan 77; A second step S2 of stopping only the compressor 71 when the set compressor driving time t1 elapses; A third step S3 of stopping the operation of the fan 77 when a predetermined time t2 elapses from the time when the compressor 71 is stopped; If the water level of the collecting tank 50 does not rise above a certain level (S4), it is determined whether the predetermined period (T) has elapsed, the fifth step (S5) to return to the first step (S1); And a sixth step S6 of stopping the driving of the compressor 71 and the fan 77 when the water level of the collection tank 50 rises above a predetermined level in the fourth step S4.

According to the invention; By defrosting the ice frozen on the surface of the evaporator naturally, it is possible to ensure the normal operation of the water purifier to stabilize the water purifier system.

Dual drinking water generator, defrosting method, compressor, condenser, evaporator, fan, microcomputer,

Description

Defrosting method of dual drinking water generator {DEFROST METHOD OF DUAL WATER-GENERATING DEVICE}             

1 is an external perspective view showing the appearance of a conventional drinking water generating device of the prior art,

Figure 2 is a front sectional view of the dual drinking water generating device according to Figure 1,

3 is a side cross-sectional view of the dual drinking water generating device according to FIG.

4 is a control circuit diagram including a microcomputer for controlling the dual drinking water generating device of FIG.

5 is a block diagram showing a drinking water generation process of the dual drinking water generating device of FIG.

6 is an operation flowchart illustrating a defrosting method of the dual drinking water generating apparatus according to an embodiment of the present invention.

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

10 casing 11: first chamber

12: 2nd room 13: 3rd room

14: 4th room 20: drinking water tank

21, 53: water level sensor 30: hot water device

35: cold water device 40: water purification system

50: collecting tank 60: sterilization means (UV lamp)

70: drinking water condensation system 71: compressor

73 condenser 75 evaporator

77: fan 100: micom

The present invention relates to a defrosting method of a dual drinking water generating device, and more particularly, in the control of the operation of the compressor and the fan, the microcomputer controls the fan to be driven for a certain time even after the compressor is stopped, thereby providing external warm air. The present invention relates to a defrosting method of a dual drinking water generating device which naturally defrosts ice frozen on the surface of the evaporator by introducing the evaporator into the evaporator for a predetermined time.

1 and 2, the conventional dual drinking water generating apparatus forms an exterior with a rectangular common casing 10, and the side of the casing 10 is introduced from the rear of the casing 10. A discharge network 18b for discharging air is mounted, and a filter 18a for filtering primary air pollutants introduced into the casing 10 is mounted at the rear of the casing 10. The front of the casing 10 is equipped with a hot water supply knob 17 and a cold water supply knob 19 for supplying hot water and cold water, the lower portion of the hot water supply knob 17 and the cold water supply knob 19 The drain tank 15 for collecting and discharging the dropped water is formed, and a drain plate 16 for mounting the cup is mounted on the drain tank 15.

As shown in FIGS. 2 and 3, the inside of the casing 10 is partitioned into four stages from the top to the bottom, and the first chamber 11 is moved from the top to the bottom, respectively. The 2nd chamber 12, the 3rd chamber 13, and the 4th chamber 14 are called.

At this time, the fan 77 for introducing the humidity air into the casing 10 and the air introduced by the fan 77 pass through the third chamber 13 and the fourth chamber 14. And a condensation evaporator 75, a compressor 71 connected to the evaporator 75, and a condenser 73 condensing the refrigerant compressed from the compressor 71 is installed. The fourth chamber 14 is provided with an ordinary collecting tank 50 for collecting drinking water that condenses on the surface of the evaporator 75 and falls.

In addition, the upper part of the water collecting tank 50 is provided with sterilization means 60 for sterilizing drinking water collected into the water collecting tank 50 through the water collecting plate 66 and the water collecting tube 67. The third chamber 13 is provided with a water purification system 40 for purifying drinking water collected in the collection tank 50. At this time, the water purification system 40 is composed of a first filtration filter 41, a first carbon filter 42, a second filtration filter 43, and a second carbon filter 44.

In addition, a drinking water tank 20 in which the purified water is stored while passing through the water purification system 40 and the water level sensor 21 is installed therein is installed in the first chamber 11. The chamber 14 is equipped with a water supply pump 65 for pumping the drinking water collected in the collection tank 50 to pass through the water purification system 40 to reach the drinking water tank 20.

In addition, the second chamber 12 is provided with a hot water device 30 and a cold water device 35 for heating or cooling the water from the drinking water tank 20 to the outside.

Then, a connector 59 is installed on the water supply pipe 58 so as to connect or disconnect the water supply pipe 58 between the water purification system 40 and the drinking water tank 20.

In addition, the water supply pipe 58 includes a drinking water supply pipe 57 for supplying drinking water from the external drinking water supply source to the water supply pipe 58, a drinking water supply valve 56 for opening and closing the drinking water supply pipe 57, and an auxiliary pipe ( An auxiliary drinking water supply means having 55) is provided.

On the other hand, Figure 4 is a control circuit diagram including a microcomputer for controlling the conventional dual drinking water generating apparatus, the microcomputer 100 is a double drinking water by controlling the display panel 110 according to the user's selection when the power is supplied from the outside The operation status of the generator is displayed. For example, when the user selects the hot water selection button and / or the cold water selection button, the hot water device 30 and / or the cold water device 35 are controlled to be displayed. At the same time, the microcomputer 100 controls a pair of bimetal, which is a hot water temperature sensor 32 for controlling the operation of the heater 31 of the hot water device 30, and the operation of the compressor 71 of the cold water device 35. In order to sense the operation of the thermostat, cold water temperature sensor 37 to be displayed to the outside. Similarly, when the user selects the dual selection button, the microcomputer 100 displays that drinking water supplied from the outside is purified instead of moisture in the air.

In addition, the microcomputer 100 is provided with the detection results from the water level sensor 53 of the water collecting tank 50 and the water level sensor 21 of the drinking water tank 20, and the drinking water condensation system 70 according to the detection result. The operation of the compressor 71 and the fan 77 and the feed water pump 65 is controlled. In detail, when the water level of the collecting tank 50 is detected by the water level detection sensor 53 of the collecting tank 50 or more, the microcomputer 100 operates the water supply pump 65 to collect the collecting tank 50. By allowing the drinking water from the water supply system 40 to be provided to the drinking water tank 20, the water in the collection tank 50 is prevented from overflowing. And when the water level of the drinking water tank 20 is detected by the water level detection sensor 21 of the drinking water tank 20 is a predetermined level or more, the microcomputer 100 is the water level detected from the water level detection sensor 53 of the collecting tank 50. If it is determined that the water level of the collecting tank 50 is more than a certain level, it is determined that the collection of drinking water should be stopped to stop the driving of the compressor 71 and the fan 77. Reference numeral 36 is a compressor of the cold water device.

Hereinafter, the control method of the microcomputer 100 according to the water level of the collecting tank 50 drops below a predetermined level during the operation of the conventional double drinking water generator described above will be described with reference to FIGS. 4 and 5. do.

First, when the microcomputer 100 drives the compressor 71 and the fan 77 at the same time, the evaporator 75 is cooled. Then, moisture in the air introduced into the casing 10 by passing through the filter 18a by the fan 77 condenses on the surface of the evaporator 75, and the moisture is deprived while passing through the evaporator 75. As the air passes through the condenser 73, the temperature is increased and discharged to the outside through the discharge network 18b. When the temperature difference between the outside and the evaporator 75 is more than 10 ° C., when the compressor 71 and the fan 77 are operated for a predetermined time, a sufficient amount of moisture condenses on the surface of the evaporator 75.

Then, the microcomputer 100 simultaneously stops the operation of the compressor 71 and the fan 77 for a predetermined time to raise the temperature of the evaporator 75, so that the moisture condensed on the surface of the evaporator 75 melts and falls. Do it. Subsequently, the drinking water collected in the collecting plate 66 at the bottom of the evaporator 75 and flowed through the collecting pipe 67 is sterilized while passing through the UV lamp 60 installed at the upper portion of the collecting tank 50. 50 is accommodated.

Thus, the compressor 71 and the filter 77 periodically repeat driving and stopping under the control of the microcomputer 100, and thus drinking water is increased in the collecting tank 50, and the collection tank 50 is When the water level detected by the water level sensor 53 is above a certain level, the microcomputer 100 stops driving the drinking water condensation system 70.

However, in the above-described conventional double drinking water generating device, when the external temperature is rapidly lowered during the operation, ice is formed on the surface of the evaporator when the surface temperature of the evaporator drops below the freezing point, and the ice becomes larger so that the water efficiency significantly decreases the water purifier. It was a factor that prevented the catching operation of.

Nevertheless, the above-described conventional dual drinking water generator is unable to melt ice attached to the evaporator because the compressor for cooling the evaporator and the fan for introducing external air are always stopped after being driven at the same time interval. There was a problem that the water purifier system is unstable and the cause of the failure always exists.

Accordingly, the present invention has been made to solve the conventional problems as described above, the object of the present invention in controlling the operation of the compressor and the fan by controlling the fan to be further driven for a certain time even after the compressor is stopped, the external It is to provide a defrosting method of the dual drinking water generator to allow the warm air of the water to flow into the evaporator for a certain time to naturally defrost the ice frozen on the surface of the evaporator, thereby ensuring the normal operation of the water purifier. have.

In order to achieve the above object, the defrosting method of the present double drinking water generating apparatus, the casing; A drinking water condensation system comprising a fan, an evaporator, a condenser and a compressor; A collecting tank having a level sensor; Sterilization means; Water purification system; A drinking water tank having a level sensor; A water supply pump installed on the water supply pipe extending to the drinking water tank; In the defrosting method of the dual drinking water generating device having a microcomputer for controlling the operation of the means,

A first step of controlling the condensation of moisture on the surface of the evaporator when the microcomputer senses that the water level of the collecting tank is below a predetermined level through the water level sensor;                         

A second step of determining whether the microcomputer has set a predetermined compressor driving time (t1), and if so, stops only the compressor to raise the temperature of the evaporator;

A third step in which the microcomputer determines whether a predetermined time t2 has elapsed from when the compressor is stopped, and stops the operation of the fan when the set time t2 elapses;

A fourth step of determining, by the microcomputer, whether the water level of the water collecting tank has risen above a predetermined level through the water level sensor;

If the water level of the collecting tank does not rise above a predetermined level in the fourth step, the microcomputer determines whether a predetermined period T has elapsed since the set stop time t3 has elapsed since the fan was stopped. Determining, the fifth step of proceeding to the first step again after a predetermined period (T); And

In the fourth step, when the water level of the collection tank is raised to a predetermined level or more, the microcomputer is configured to have a sixth step of terminating the compressor and fan driving operations.

Hereinafter, the defrosting method of the dual drinking water generating apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings, but the general description of the dual drinking water generating apparatus shown in FIGS. As already mentioned in the description of the description will be omitted.

In FIG. 4, the microcomputer 100 applied to the present invention drives the compressor 71 and the fan 77 when the water level of the collection tank 50 is detected to be below a predetermined level through the water level sensor 53. After the compressor driving time t1 has elapsed, only the compressor 71 is stopped first, and then the fan 77 is stopped after a predetermined time t2 has elapsed. Both the 71 and the fan 77 are driven to repeat the operation periodically.

Then, the defrosting method of the dual drinking water generating device according to an embodiment of the present invention will be described in more detail with reference to FIG.

First, in order to help the understanding of the following description, the compressor 71 and the fan 77 drive cycle T is "1 hour", the compressor drive time t1 is "50 minutes", and the compressor ( It is assumed that the elapsed time t2 from the time when 71 is stopped is set to "5 minutes", and the elapsed time t3 from the time when the fan 77 is stopped is set to "5 minutes".

When the microcomputer 100 detects that the water level of the collection tank 50 is lower than or equal to a predetermined level through the water level sensor 53, the microcomputer 100 drives the compressor 71 and the fan 77 of the evaporator 75. Control to condense moisture on the surface (S1).

Thereafter, the microcomputer 100 determines whether "50 minutes", which is the set compressor driving time t1, has passed (S2), and when it passes (YES), stops only the compressor 71 so that the evaporator 75 Raise the temperature of (S2).

Subsequently, the microcomputer 100 determines whether a predetermined time (t2 = 5 minutes) has elapsed from the time when the compressor 71 is stopped (S3), and when the "5 minutes" elapses (YES), the fan Operation of 77 is stopped (S3).

On the other hand, the microcomputer 100 determines whether the water level of the collection tank 50 has risen above a predetermined level through the water level sensor 53 (S4).

At this time, if the water level of the collecting tank 50 does not rise above a predetermined level in the fourth step S4 (NO), the microcomputer 100 stops the set time from the time when the fan 77 is stopped. It is determined whether or not a predetermined period (T = 1 hour) has elapsed as (t3 = 5 minutes) (S5), and when the predetermined period T has elapsed (YES), the process returns to the first step S1. Return (S5).

On the other hand, when the water level of the collecting tank 50 rises above a predetermined level in the fourth step S4 (YES), the microcomputer 100 ends the driving operation of the compressor 71 and the fan 77. (S6).

Here, the compressor driving time t1 described above, the elapsed time t2 from the time when the compressor 71 is stopped, the elapsed time t3 from the time when the fan 77 is stopped, and the constant period T Equation 1 is established as shown in Equation 1 below, wherein a predetermined period T can be arbitrarily set within a range of "30 minutes ≤ T ≤ 6 hours", and t2 is set to 5 to 30% of t1. It can be set arbitrarily within the range of corresponding time, and t3 can be arbitrarily set within the range of 5-10 minutes.

T = t1 + t2 + t3, (t1> t2)

Although the present invention has been described in more detail with reference to some embodiments, the present invention is not necessarily limited to these embodiments, and various modifications can be made without departing from the spirit of the present invention.

As described above, according to the defrosting method of the dual drinking water generating device according to the present invention, in the control of the operation of the compressor and the fan, the microcomputer for a certain time even after the compressor is stopped to introduce external warm air to the evaporator for a certain time. By controlling the fan to be driven further, the ice frozen on the surface of the evaporator naturally defrosting, thereby allowing the water purifier to operate normally to stabilize the water purifier system.

Claims (2)

Casing; A drinking water condensation system comprising a fan, an evaporator, a condenser and a compressor; A collecting tank having a level sensor; Sterilization means; Water purification system; A drinking water tank having a level sensor; A water supply pump installed on the water supply pipe extending to the drinking water tank; In the defrosting method of the dual drinking water generating device having a microcomputer for controlling the operation of the means, A first step of controlling the condensation of moisture on the surface of the evaporator when the microcomputer senses that the water level of the collecting tank is below a predetermined level through the water level sensor; A second step of determining whether the microcomputer has set a predetermined compressor driving time (t1), and if so, stops only the compressor to raise the temperature of the evaporator; A third step in which the microcomputer determines whether a predetermined time t2 has elapsed from when the compressor is stopped, and stops the operation of the fan when the set time t2 elapses; A fourth step of determining, by the microcomputer, whether the water level of the water collecting tank has risen above a predetermined level through the water level sensor; If the water level of the collecting tank does not rise above a predetermined level in the fourth step, the microcomputer determines whether a predetermined period T has elapsed since the set stop time t3 has elapsed since the fan was stopped. Determining, the fifth step of proceeding to the first step again after a predetermined period (T); And And a sixth step of terminating the compressor and fan driving operations when the water level of the collection tank is raised to a predetermined level or more in the fourth step. The method of claim 1, The compressor driving time t1, the elapsed time t2 from the point at which the compressor is stopped, the elapsed time t3 from the point at which the fan is stopped, and the constant period T are expressed as shown in Equation 1 below. Defrost method of the dual drinking water generating apparatus, characterized in that established. [Equation 1] T = t1 + t2 + t3, (t1> t2) The predetermined period T may be arbitrarily set within a range of "30 minutes ≤ T ≤ 6 hours", t2 may be arbitrarily set within a range of time corresponding to 5 to 30% of t1, and t3 is 5 to It can be set arbitrarily within the range of 10 minutes.

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