KR101063982B1 - Power-saving drink - Google Patents

Abstract

The present invention relates to a power-saving drinking machine, and more particularly, to a drinking machine capable of saving power by controlling the operation of a heater for heating water in order to sterilize the water flowing into the cold water tank in conjunction with the water level.

The present invention is a drinking machine having a hot water and a cold water supply, comprising a heat sterilization means for heating and sterilizing the water supplied to the cold water supply, the heat sterilization means is an inner passage in which water is heated by a heater; An outer cylinder into which the coolant for receiving the inner cylinder is introduced and cooling the inner cylinder, a level sensor unit installed in the inner tube, and a control unit controlling the operation of the heater by a signal from the level sensor unit; Equipped.

According to the present invention, the heater can be protected by not applying power to the heater in a state in which the water is not filled in the heater accommodating part, and the heater is repeatedly operated by preventing the power from being applied to the heater while the drinking water is not used. This can prevent unnecessary power waste.

Drinking water, power saving, water level detection

Description

Device drinking water with function saving power

The present invention relates to a power-saving drinking machine, and more particularly, to a drinking machine capable of saving power by controlling the operation of a heater for heating water in order to sterilize the water flowing into the cold water tank in conjunction with the water level.

Recently, the water purifier is widely used to supply purified water by passing tap water through various filters such as sediment filter, sun carbon filter, membrane filter, fu carbon filter, ultraviolet filter.

Such water purifiers are installed and used not only in places where users are restricted to certain people such as homes or offices, but also in places where many people can use such as school cafeterias, school corridors, libraries, highway rest areas, train waiting rooms, government offices, and other public buildings. .

The water purified by the filter may be supplied as it is, but it is stored in a cold water tank and cooled by a cooling device (a gas refrigerant circulation cycle consisting of a compressor, a condenser, and an evaporator, or a thermoelectric element is mainly used), or stored in a hot water tank, such as an electric coil. Heated by a heating device. And the cold water and hot water stored in the cold water tank and hot water tank is discharged to the outside through the intake tap.

According to such a conventional water purifier, even if it is filtered by a filter, even microorganisms are not completely filtered out, which is a problem. In the case of hot water, there is no risk of germ propagation because the water is heated and maintained by more than 90 degrees by the heating device.

Therefore, there is known a structure of a water purifier for introducing water into a cold water tank after sterilization by heating water in a separate container before entering the cold water tank.

However, since the conventional water purifier heats water by operating a heater every predetermined time by a timer, there is a problem in that electricity is wasted when the water purifier is not used. In particular, when the water purifier is not used on a weekend, such as a school or public office, the heater is continuously operated every predetermined time, so unnecessary electricity is wasted.

In addition, the conventional water purifier mainly uses a wet heater to heat the water within a short time. When the heater is powered without the water being filled, the heater is damaged due to high heat generation and the trouble of replacement. And the addition of cost is a problem.

The present invention has been made to improve the above-mentioned problems, and in order to control the operation of a heater that heats water in storing and heating a predetermined amount of water in a separate bucket before flowing into the cold water tank, according to the level of water stored in the bucket. The purpose is to provide a drinking machine.

Another object of the present invention is to provide a drinking machine that can protect the heater by preventing power from being applied to the heater when the water is not filled.

Energy-saving drinking machine of the present invention for achieving the above object in the drinking water having a hot water and cold water supply, comprising a heat sterilization means for heating and sterilizing the water supplied to the cold water supply, the heat sterilization means The inner cylinder is heated by the heater, the outer cylinder into which the coolant for receiving the inner cylinder and cooling the inner cylinder flows, the level sensor unit installed in the inner cylinder to sense the water level, and the signal of the water level sensor unit It characterized in that it comprises a control unit for controlling the operation of the heater.

The water level sensor unit is a support tube installed vertically to a predetermined height inside the inner cylinder, respectively installed on the upper and lower portions of the support tube flows up and down along the support tube by a change in the water level of the inner cylinder and the magnetic material First and second floats having a built-in; first and second lead switches embedded in the support pipe to provide an on / off signal to the controller by the flow of the first and second floats; And first and second stoppers for limiting the upper and lower flow ranges of the first and second floats, respectively.

The support tube is installed through the bottom of the inner cylinder, the water level sensor unit is supported on the bottom of the inner cylinder to move the support tube up and down so as to adjust the level of sensing by changing the height of the support tube It characterized in that it further comprises a fastening unit to.

It is formed to be drawn downward from the bottom of the inner cylinder is provided with a heater receiving portion is installed the heater, the support tube is installed to penetrate the heater receiving portion, the water level sensor unit is of a height corresponding to the bottom of the inner cylinder A third float installed on the support pipe, a third lead switch embedded in the support pipe to provide an on / off signal to the controller by the flow of the third float, and a vertical flow range of the third float. A third stopper for limiting is further provided.

As described above, according to the power-saving drinking machine of the present invention, the heater may be protected by preventing power from being applied to the heater in a state where water is not filled in the heater accommodating portion.

In addition, it is possible to prevent the power is applied to the heater while not using the drinking machine to prevent unnecessary power waste due to the repeated operation of the heater.

In addition, by moving the support tube of the water level sensor unit up and down, the user can arbitrarily adjust the high and low water levels sensed by the sensor, so that the amount of heating of the inner cylinder can be properly adjusted according to the amount of the drinking machine, thereby saving electricity.

Hereinafter, with reference to the accompanying drawings will be described in detail a power-saving drinking machine according to a preferred embodiment of the present invention.

1 is a perspective view showing a drinking machine according to an embodiment of the present invention, Figure 2 is a schematic view showing the configuration of the drinking machine of Figure 1, Figure 3 is the inside of the heat sterilization means applied to the drinking machine of Figure 1 4 is an exploded cross-sectional view showing the main portion extracted, Fig. 4 is an exploded perspective view showing a state in which the water level sensor unit is applied to the fastening unit, Figure 5 is a state in which the water level sensor unit of Figure 4 is fastened to the fastening unit 6 is a partial perspective view illustrating a level sensor unit applied to a drinking machine according to another embodiment of the present invention.

1 to 5, the drinking machine 10 according to an embodiment of the present invention is a large-capacity drinking machine for the group water supply, and supplies a drinking water that can be safely sterilized. In addition, although not shown, the drinking machine 10 of the present invention may be implemented as a small drinking machine for home use.

Drinking water 10 according to an embodiment of the present invention is largely connected to the housing 15, the raw water supply pipe 17, the filter unit 19 for filtering the raw water, and the filtration treatment by the filter unit 19 A heat sterilization means 30 for heating and sterilizing the prepared water, a cold water supply unit 70 for cooling the water by receiving the heated water from the heat sterilization means 30, and supplying cold water for drinking water, and filtered water It is provided with a hot water supply unit 80 for supplying hot water for drinking water by receiving the water, and the intake faucet unit 90 for discharging the cold water and hot water to the outside.

The drinking machine 10 according to the present invention configured as described above will be described in more detail by component.

The cylindrical housing 15 incorporating the above components uses a metal material having high corrosion resistance such as stainless steel. In the front of the housing 15, the intake faucet 91 of the intake faucet unit 90 is formed to protrude. In this case, a plurality of intake faucets 91 are installed so that many people can use at the same time. The intake faucet 90 is divided into a cold water intake faucet for discharging cold water and a hot water drain faucet for discharging hot water.

And below the intake faucet 91 protrudes from the front surface of the housing 15, the drain basin 13 is formed. The drain 13 has a drain hole for naturally collecting water discharged from the intake faucet 91 and flowing out to the bottom of the housing 15.

A cup holder (not shown) for storing a cup may be formed at an upper portion of the housing 15, and a plurality of cup collecting portions (not shown) may be used at a lower portion of the drain 13 of the housing 15 to collect the used cups. Can be formed.

The illustrated shape of the housing 15 is just an example, and various changes are possible, of course.

The raw water supply pipe 17 drawn in from the outside of the housing 15 and extending therein is connected to the water supply pipe to supply raw water to the inside of the housing 15. The raw water supplied through the raw water supply pipe 17 is purified by the filter unit 19.

The filter unit 19 is for filtering raw water and supplying it to the heat sterilization means 30 and the hot water supply means 80. The filter unit 19 includes a pre-filter for filtering contaminants, chlorine, organic chemicals, and other bacteria. Pre-carbon filter and membrane filter and after-carbon filter to remove heavy metals, siloxane mea filter to remove heavy metals such as lead and cadmium, toxic compounds It may be made of a TAL filter or the like to remove. The filtered water in the filter unit 19 is supplied to the heat sterilization means 30 through the first supply line 20.

The heat sterilization means 30 is installed in the inner cylinder 31 in which the water is heated, the outer cylinder 33 which accommodates the inner cylinder 31 and the cooling water for cooling the inner cylinder 31, and the inner cylinder 31. It is provided with a water level sensor unit 50 for detecting a, and a control unit 65 for controlling the operation of the heater by the signal of the water level sensor unit (50).

The inner cylinder 31 is introduced into the filtered water in the filter unit 19 through the first supply pipe (20). In this case, the first valve 21 is installed on the first supply pipe 20 to open and close the flow path of the first supply pipe 20 under the control of the controller 65. The inner cylinder 31 has an inner space so that a certain amount of water can be stored therein. The bottom of the inner cylinder 31 is provided with a heater 35 for heating the water stored in the inner cylinder.

In this case, as shown in the bottom of the inner cylinder 31 is provided with a heater accommodating portion 34 is formed recessed downwardly to form a space of a predetermined size, the heater 35 is connected to the power supply to the heater accommodating portion 34 Is installed. As the heater 35, a dry heater or a wet heater may be used, but it is preferable to use a wet heater having the advantage of heating a large amount of water in a short time.

The first water temperature sensor 37, which senses the temperature of the water stored in the inner cylinder and sends a signal to the controller 65, is installed inside the inner cylinder 31.

When a user operates a heater power button (not shown) installed at the rear of the housing 15, the first power is applied to heat the water stored in the inner cylinder 31, and when heated to 90 to 95 ° C., the first water temperature sensor 37. The control unit 65 cuts the power by the signal output from the) to stop the operation of the heater 35.

In addition, a timer (not shown) is installed at one side of the housing 15 to repeat the heating by activating the heater 35 periodically after a predetermined time in order to prevent the breeding of microorganisms.

The outer cylinder 33 has a space surrounding the inner cylinder 31 and has a space for storing a predetermined amount of coolant, and the coolant at room temperature flows in through the coolant supply pipe 23 and flows along the side of the inner cylinder to be heated in the inner cylinder 31. Cool the water to room temperature. Water introduced into the outer cylinder 33 may have a circulating flow continuously discharged through the coolant discharge pipe 25 or may be stored for a predetermined time and then discharged through the coolant discharge pipe 25. The water naturally cooled in the inner cylinder 31 is supplied to the cold water supply water part 70 through the third supply pipe 27.

And the cooling water supply pipe 23 and the cooling water discharge pipe 25 are provided with the 2nd and 3rd valves 24 and 26 operated by the control of the control part 65, respectively.

The water level sensor unit 50 for detecting the water level of the inner cylinder 31 is installed in the upper and lower portions of the support tube 51 and the support tube 51 that is installed vertically in the inner cylinder 31 and the high water level and The first and second floats 53 and 55 in which the magnetic body 54 is built and which flows up and down along the support tube 51 to sense the low water level are embedded in the support tube 51 and the first and the second First and second lead switches 57 and 59 for detecting the flow of the second floats 53 and 55, and first and second restricting the upper and lower flow ranges of the first and second floats 53 and 55. Second stoppers 60 and 61 are provided.

The support tube 51 is formed to extend perpendicularly to the inside of the inner cylinder 31 through the bottom of the inner cylinder 31 from the outside of the inner cylinder 31. In this case, the support tube 51 is installed to penetrate the heater accommodating part. The support tube 51 is formed in the tubular body which is hollow inside. The first stopper 60 is installed on the upper and lower portions of the first float 53, and the second stopper 61 is installed on the support pipe 51 positioned on the upper and lower portions of the second float 55, respectively. do. Therefore, each float 53, 55 is limited in the flow range within the separation distance of the pair of stoppers. The first and second stoppers 60 and 61 may use a snap ring mounted in the mounting groove 52 formed in the support tube 51.

The first float 53 may be located at a height of about 8/10 to 9/10 of the height of the inner cylinder 31, and the second float 55 may be located at a height of about 3/10 to 5/10 of the height of the inner cylinder 31. It is preferable to be installed on each of the support pipes 51 so that.

The first lead switch 93 is built in the support tube 51 and is installed at a position corresponding to the first float 53. The first lead switch 93 is made of a magnetic material, and the two leads 94 connected to the wire 96 are installed in the glass tube 95 filled with the inert gas, and the first float 53 floating on the water surface. ) Moves along the water level onto the support tube 51 in which the first lead switch 93 is located, the magnetic force lines generated from the magnetic body 54 embedded in the first float 53 are larger in the lid 94. The two leads 94 are separated from each other by passing through them. The electrical on / off signal generated by the contact or disconnection of the lead 94 is provided to the controller 100. The first lead switch 93 has the advantage that the operation and return of the contact is fast and the reliability is high.

The second lead switch 97 is built in the support tube 51 and is installed at a position corresponding to the second float 55. Configuration and operation are the same as the first lead switch 93, so detailed description thereof will be omitted.

The first float 53 and the first reed switch 93 positioned on the upper part of the support tube 51 are for detecting the high water level of the inner cylinder 31. The first float when the water rises to the upper portion of the inner cylinder 31 53 flows upward, whereby the first lead switch 57 outputs an electrical signal to the controller 65. The controller 65 detects the high water level to close the flow path of the first valve 21 to block the inflow of water.

The second float 55 and the second lead switch 97 positioned below the support tube 51 are for controlling the operation of the heater 35 by sensing the low water level of the inner cylinder 31, and the second float 55. When the second float 55 is positioned upward because the water level is higher than the position of the control unit 65, the controller 65 controls not to apply power to the heater 35.

In the drinking machine 10 of the present invention, when the cold water cooled by the cold water supply unit 70 is not used, the water heated from the inner cylinder 31 is not introduced into the cold water supply unit 70. Therefore, the water stored up to the high water level of the inner cylinder 31 has almost no change in the water level, and if there is no change in the water level, the water level of the water stored in the inner cylinder 31 is higher than the position of the second float 55, even if the timer is operated. 65 does not apply power to the heater 35.

Since the water stored in the inner cylinder 31 is not reheated while the drinking machine 10 is not used as described above, power consumption due to unnecessary heater 35 can be greatly reduced.

On the other hand, the support tube 51 is preferably installed by the fastening unit 100 to be movable up and down with respect to the inner cylinder (31). When the support pipe 51 is raised or lowered to a certain height, the heights of the first and second floats 51 and 55 are changed so that the user can set the high water level and the low water level arbitrarily. This is to easily control the amount of water heated according to the daily usage of drinking water.

Fastening unit 100 according to an embodiment of the present invention is mounted so as to penetrate the mounting hole 32 formed in the bottom of the inner cylinder 31, the nipple 105 and the nipple 105 through which the support tube 51 is vertically penetrated, A nut 109 that is screwed into the lower portion of the 105 to fix the nipple 105 to the bottom of the inner cylinder 31, and a sealing member 107 that is installed between the inner cylinder bottom 31 and the nut 109 to maintain watertightness. ), A tightening nut 101 which is screwed to the upper portion of the nipple 105 to fix the support tube at a predetermined position, and an O-ring 103 installed between the tightening nut 101 and the nipple 105 to maintain watertightness. It is provided.

Therefore, when the tightening nut 101 is released to raise and lower the support tube 51, the support tube 51 can be moved up and down, and the nipple of the tightening nut 101 is fixed to fix the support tube 51 after the position adjustment. When the fastening nut 105 is fastened, the O-ring 103 is pressed during the fastening nut 105 is fastened, and the O-ring 103 is in close contact with the outer circumferential surface of the support pipe 51 to prevent the support pipe 51 from moving. At the same time watertight action so that the water in the inner cylinder 31 is not leaked to the outside.

The control unit 65 is composed of a conventional controller, and receives the signals output from the first water temperature sensor 37 and the water level sensor unit 50 to the first to fourth valves 21, 24, 26, and 28. Open / close and control the power applied to the heater 35.

The cold water supply unit 70 is installed in the cold water tank 71 to cool the water stored in the cold water tank 71 and the cold water tank 71 connected to the inner cylinder 31 by the third supply pipe 27. An evaporator 73, a compressor 77 for absorbing the latent heat of evaporation from the evaporator 73 and compressing the evaporated heat exchange medium, and a condenser 75 for condensing the heat exchange medium in the vapor phase compressed by the compressor 77. And a throttling valve 79 provided between the condenser 75 and the evaporator 73 to throttle the heat exchange medium condensed by the condenser 75. In addition, the inside of the cold water cooler 71 may be provided with a conventional level sensor 72 for detecting the water level. In addition, a second water temperature sensor (not shown) may be installed inside the cold water tank 71 to detect a temperature of water.

The hot water supply unit 80 further includes a hot water tank 81 for storing filtered water and a hot water heater 85 for heating water in the hot water tank 81. The hot water tank 81 flows directly into the heated state before cooling the water heated in the inner cylinder 31 through the fourth supply pipe 85. Unlike this, raw water may flow into the hot water tank 81 from the first supply pipe 20.

The hot water supply unit 80 is not limited to the above-described embodiment and may be used as long as the hot water supply unit is applied to a normal drinking water as long as the structure can heat the water. The cold water tank 71 and the hot water tank 81 are connected to a plurality of intake faucet units 90 to discharge cold water or hot water through the intake faucet 91.

Hereinafter, the operation of the heat sterilization means of the drinking water which is a feature of the present invention will be described.

First, when the manager operates a heater power button (not shown) in a state where water is filled in the inner cylinder 31, power is applied to the heater. When the water is heated to a predetermined temperature, the control unit 65 cuts off the power of the heater 35 by the signal of the first water temperature sensor 37 and opens the second valve 24 to allow the coolant to flow therein. The coolant flowing into the outer cylinder 33 is continuously introduced until the water heated in the inner cylinder 31 is naturally cooled to about 25 to 30 ° C. and discharged through the cooling water discharge pipe 25 to perform a continuous natural cooling process. .

When the water stored in the inner cylinder 31 is cooled by the coolant, the controller 65 controls the second valve 24 to block the inflow of the coolant by the signal of the first water temperature sensor 37. The control unit 65 opens the fourth valve 28 to supply the water cooled to room temperature to the cold water tank 71. In this case, when a predetermined amount of water is supplied to the cold water tank 71, the control unit 65 operates the fourth valve 28 by the signal of the water level sensor 72 installed in the cold water tank 71 to supply the third supply pipe 27. ) Will block the flow path.

The water stored in the cold water tank 71 is cooled until it becomes 4-5 degreeC. Cold water stored in the cold water tank is supplied to the outside through the intake tap (91). If the user continues to use cold water, the water level of the cold water tank 71 is lowered, and when the water level is lowered, the control unit 65 opens the fourth valve 28 to the inner cylinder 31 by the signal of the water level sensor 72. The process of supplying the stored room temperature water to the cold water tank 71 is repeatedly performed.

When the water is supplied to the cold water tank 71, the water level of the water stored in the inner cylinder 31 is lowered, and when the water level continues to decrease, the second float 55 of the water level sensor unit 50 that detects the low water level is downward. The control unit 65 detects the low water level. Therefore, the control unit 65 operates the first valve 21 to allow water to flow into the inner cylinder 31 through the first supply pipe 20, and simultaneously applies power to the heater 35 to operate the heater 35. To heat the water.

And the water level of the cold water tank 71 is maintained at a certain amount during the period when the drinking water is not used, such as the weekend, so that the water supply from the inner cylinder 31 to the cold water tank 71 is also stopped, so the water level of the inner cylinder 31 continues to a high water level. maintain. Therefore, the second float 55 of the water level sensor unit is positioned upward, so that the heater 35 is not powered by the control of the controller 65 even if the timer is operated.

As described above, when the drinking water of the present invention is not supplied to the outside, the heater 35 for heating the water stored in the inner cylinder 31 is not operated, thereby preventing unnecessary waste of electricity.

On the other hand, referring to Figure 6, the water level sensor unit is applied to another embodiment of the present invention is installed in the inner cylinder 31 so that the support tube 51 penetrates the heater housing 34, the heater housing 34 The third float 64 and the third reed switch (not shown) installed in the interior of the support tube 51 to detect the flow of the third float 64 is located in the lower portion of the support tube 51 is located, A third stopper 63 is further provided to limit the up and down flow range of the third float 64. In this case, the installation height of the third float 64 is installed at a position capable of detecting a level of water corresponding to a height corresponding to the bottom of the inner cylinder 31.

Therefore, in the water level sensor unit, the third float 64 is installed at the lower portion of the support pipe 51, and although not shown, the second float and the first float are spaced apart a predetermined distance above the third float 64. Is installed.

In the state where the water is not filled in the heater accommodating part 34 by the water level sensor unit 50 as described above, even if the manager operates the heater power button, the control unit does not apply power to the heater 35 so that the heater 35 Protect. Unlike this, although not shown, a magnetic switch installed between the heater 35 and the power source may be connected to the third lead switch so that the power may be applied to the heater 35 only when the heater accommodating part 34 is filled with water. have.

Therefore, the drinking machine of the present invention may protect the heater by preventing the heater 35 from being operated in a state in which the heater accommodating part 34 is not filled with water.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments thereof are possible.

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

1 is a perspective view showing a drinking machine according to an embodiment of the present invention,

2 is a configuration diagram schematically showing the configuration of the drinking machine of FIG.

Figure 3 is a sectional view excerpts for showing the inside of the heat sterilization means applied to the drinking machine of Figure 1,

4 is an exploded perspective view showing a state in which the water level sensor unit applied to FIG. 1 is fastened to a fastening unit;

5 is a cross-sectional view illustrating a state in which the water level sensor unit of FIG. 4 is fastened to a fastening unit.

6 is a partial perspective view showing the water level sensor unit applied to the drinking machine according to another embodiment of the present invention.

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

15: housing 31: inner cylinder

33: outer cylinder 35: heater

50: water level sensor unit 65: control unit

70: cold water supply unit 80: hot water supply unit

Claims (4)

delete In a drinking machine having hot and cold water supply, It is provided with heat sterilization means for heating and sterilizing the water supplied to the cold water supply, The heat sterilization means includes an inner cylinder through which water is heated by a heater, an outer cylinder through which the coolant for receiving the inner cylinder and cooling the inner cylinder flows, a level sensor unit installed in the inner cylinder to detect a water level, and the level detection It is provided with a control unit for controlling the operation of the heater by the signal of the sensor unit, The water level sensor unit is a support tube installed vertically to a predetermined height inside the inner cylinder, respectively installed on the upper and lower portions of the support tube flows up and down along the support tube by a change in the water level of the inner cylinder and the magnetic material First and second floats having a built-in; first and second lead switches embedded in the support pipe to provide an on / off signal to the controller by the flow of the first and second floats; and the first And first and second stoppers respectively limiting the up and down flow range of the second float, It is formed to be drawn downward from the bottom of the inner cylinder is provided with a heater receiving portion is installed the heater, the support tube is installed to penetrate the heater receiving portion, The water level sensor unit is provided with a third float installed on the support tube having a height corresponding to the bottom of the inner cylinder, and built in the support tube to provide an on / off signal to the controller by the flow of the third float. And a third stopper for limiting the vertical flow range of the third float switch and the third float. According to claim 2, The support tube is installed through the bottom of the inner cylinder, The water level sensor unit further comprises a fastening unit for supporting the bottom of the inner cylinder to move the support tube up and down to adjust the level of the sensing by changing the height of the support tube. delete

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