KR20120059927A - Ice discharging apparatus and water purifier having ice-maker - Google Patents

Abstract

PURPOSE: An ice discharging device and an ice water purifier having the same are provided to control the discharging speed of ice through controlling a screw according to the quantity of the ice stored in an ice storage. CONSTITUTION: An ice discharging device comprises a screw(11), a DC motor(13), a measuring unit(17), and a control unit(15). The screw discharges the ice stored in an ice storage. The DC motor rotates the screw through being connected with the shaft of the screw. The measuring unit measures the quantity of the ice stored in the ice storage. The control unit controls the speed of the DC motor through controlling the voltage level supplied from the DC motor according to the measured ice quantity.

Description

Ice discharging apparatus and water purifier having same {Ice discharging apparatus and water purifier having ice-maker}

The present invention relates to an ice discharge device capable of discharging ice while controlling the discharge speed and an ice water purifier including the same.

In general, an ice water purifier is a device for supplying ice by purifying raw water such as tap water to freeze purified water (or cold water) as well as purified water and cold water and / or hot water. Ice water purifiers typically include a filter unit for purifying raw water, a purified water tank for storing purified water, a cold water tank for cooling purified water, and an ice making unit for making ice, and a hot water tank for heating and storing purified water. You may.

Such ice water purifiers are typically provided with ice trays for receiving raw water for ice removal from water tanks or cold water tanks to produce ice by cooling the ice water received in the trays with an ice making unit that performs a refrigeration cycle. As such, the generated ice is stored in the ice reservoir through a defrosting process, and discharged from the ice reservoir when the extraction instruction of the user is given.

An ice discharge device applied to a conventional ice water purifier discharges ice by driving a screw at a constant speed. Thus, the ice discharge rate is different depending on the amount of ice loaded in the ice storage. Therefore, when the amount of ice is high, the ice is excessively discharged, and when the amount of ice is low, the ice discharge rate is low, which inconveniences the user.

An object of the present invention is to propose an ice discharge device having an ice discharge rate insensitive to the amount of ice loaded in an ice reservoir.

Ice discharging device according to an embodiment of the present invention for solving the above problems is disposed in the lower end of the ice reservoir screw for discharging the ice loaded in the ice reservoir, connected to the rotating shaft of the screw direct current to rotate the screw A motor, a measuring unit for measuring the amount of ice loaded in the ice reservoir and a control unit for controlling the speed of the DC motor by controlling the voltage level supplied to the DC motor in accordance with the measured amount of ice.

The measuring unit is implemented using at least one optical sensor, the optical sensor is disposed at a predetermined height of the inner wall of the ice reservoir.

The measuring unit is implemented using a pressure sensor or a weight sensor.

The controller controls the speed of the DC motor to be the minimum speed when the measured amount of ice is full and when the measured amount of ice is the lowest, the speed of the DC motor becomes the maximum speed.

The controller controls the speed of the DC motor so that the speed of the DC motor is inversely proportional to the measured amount of ice.

The controller adjusts a voltage level supplied to the DC motor by using a pulse width modulation (PWM) scheme.

The ice ejecting apparatus further includes a second measuring unit capable of measuring the speed of the DC motor, and the controller is a preset range of the speed of the DC motor whose speed of the measured DC motor corresponds to the amount of ice loaded. The voltage level supplied to the direct current motor is controlled to remain in.

The second measuring unit measures the rotational speed of the DC motor using a magnetic sensor.

Ice purifier according to an embodiment of the present invention for solving the above problems is to produce an ice making unit for generating ice, an ice storage for storing the ice generated in the ice making unit and the ice stored in the ice storage using a DC motor And an ice discharge device for varying the speed of the DC motor according to the amount of ice stored in the ice making unit.

The ice discharge device is a screw disposed at the bottom of the ice reservoir to discharge the ice loaded in the ice reservoir, the DC motor connected to the rotating shaft of the screw to drive the screw rotation, the amount of ice loaded in the ice reservoir And a control unit for controlling the speed of the DC motor by controlling a voltage level supplied to the DC motor according to the measured ice measuring unit and the measured amount of ice.

According to the ice ejection apparatus of the present invention by the above solution, it is possible to maintain the ice ejection rate is relatively constant by varying the rotational speed of the screw in accordance with the amount of ice stored in the ice reservoir.

1 is a partial cutaway perspective view showing an example of an ice water purifier.
Figure 2 is a schematic diagram showing the internal structure of the ice water purifier shown in FIG.
3 is a schematic view of a state in which ice is supplied to an ice reservoir at a defrosting position of the drip member.
4 is a functional block diagram showing a functional block of the ice ejecting apparatus of the present invention.
5 is a schematic view showing the structure when the ice discharge device of the present invention is applied to an ice water purifier.
6 is a waveform diagram illustrating waveforms of signals output from the control unit of the ice ejecting apparatus of the present invention and waveforms of driving voltages of the DC motor.
7 is a circuit diagram of a pulse signal quadruple circuit used in the second measurement unit of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing in detail the operating principle of the preferred embodiment of the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and like parts are denoted by similar reference numerals throughout the specification.

In addition, when a part is said to "include" a certain component, this means that it may further include other components, except to exclude other components unless otherwise stated.

1 is a partial cutaway perspective view showing an example of an ice water purifier, and FIG. 2 is a schematic diagram showing an internal structure of the ice water purifier shown in FIG. 1.

1 and 2, the ice water purifier 100 includes a drip member 200 for receiving raw water for ice making, an ice storage 140 for storing ice generated through the ice making unit, and an ice making unit. Cold water tank 130 for cooling the water contained therein using the ice generated through the guide member for guiding the ice generated in the ice making unit selectively supplied to the ice reservoir 140 or the cold water tank 130 And 150.

The drip member 200 is an ice making drip tray 210 for receiving raw water for making ice through ice making unit (not shown), and after cooling the raw water for ice making by the ice making unit, the drip tray for ice making ( In the process of emptying the 210 is provided with an auxiliary drip tray 220 for receiving raw water for ice remaining in the drip tray 210 for deicing. In addition, the guide grill 230 may be installed on the auxiliary drip tray 220.

3 is a schematic view of a state in which ice is supplied to an ice reservoir at a defrosting position of the drip member.

As shown in FIG. 3, the ice generated by the ice making unit moves to the ice reservoir after the drip member 200 moves to the defrosting position. At this time, when the drip member 200 moves to the defrosting position, when the hot gas is supplied to the immersion tube 121 of the evaporator 120, the ice I generated by heat is defrosted. At this time, the defrosted ice falls along the surface of the inclined guide grill 230 and is moved to the ice storage 140 according to the position when the guide member 150 is open.

4 is a functional block diagram showing a functional block of the ice ejecting apparatus of the present invention.

Referring to FIG. 4, the ice ejecting apparatus 10 of the present invention may include a screw 11, a DC motor 13, a measuring unit 17, and a control unit 15, and a power supply unit 20. It may be configured to include more.

The screw 11 may be disposed at the lower end of the ice reservoir 140 to rotate the ice loaded in the ice reservoir 140 through rotation.

The DC motor 13 may be connected to the rotating shaft of the screw 11 to drive the screw 11 in rotation. The DC motor 13 can change the rotational speed according to the average level of the supply voltage, and is a component which can control the rotational speed.

The measuring unit 17 may measure the amount of ice loaded in the ice storage 140. The measuring unit 17 may include a plurality of light sensors 17a to 17c, and the plurality of light sensors 17a to 17c may be disposed at predetermined positions on the inner wall of the ice storage 140. By using a plurality of optical sensors 17a to 17c, the loading height of the ice may be recognized to estimate the loading amount. The pressure sensor 17 may be disposed on the lower surface of the ice reservoir 140, and the load may be estimated by measuring the weight of the ice loaded in the ice reservoir 140 using the pressure sensor 17.

The controller 15 may control the speed of the DC motor by controlling the voltage level supplied to the DC motor 13 according to the measured amount of ice. The controller 15 may control the speed of the DC motor 13 to be the minimum speed when the measured amount of ice is at full ice and the maximum speed of the DC motor 13 when the measured amount of ice is the minimum. In particular, the speed of the DC motor 13 can be controlled such that the speed of the DC motor 13 is inversely proportional to the measured amount of ice.

For example, when the ice load is high, the rotational speed of the DC motor 13 is 10 rpm. When the ice load is heavy, the rotation speed of the DC motor 13 is 20 rpm, and the ice load is low. In this case, the rotation speed of the DC motor 13 is set to 30 rpm.

In addition, the average level of the voltage supplied from the controller 15 to the DC motor 13 may be controlled using a pulse width modulation (PWM) scheme.

Referring to FIG. 6, even when the voltage supplied to the DC motor 13 is in the form of a pulse, the driving voltage waveform of the DC motor 13 may be delayed due to the electrical characteristics of the motor. Therefore, when the width of the pulse of the supply voltage is changed, the average level of the driving voltage waveform is increased to control the rotation speed of the DC motor 13.

Furthermore, although not shown, the apparatus further includes a second measuring unit which detects the rotational speed of the DC motor 13, and the controller 15 includes a DC motor corresponding to the amount of ice loaded with the measured rotational speed of the DC motor 13. The voltage level supplied to the DC motor 13 can be controlled so as to remain within the preset range of the rotational speed of (13). That is, the speed of the DC motor 13 can be controlled through feedback control. In addition, feedback control may use a PID control scheme.

The second measuring unit (not shown) may measure the rotational speed of the DC motor 13 by using an encoder including a magnetic sensor, and output a pulse signal received from the encoder in order to perform precise speed control in the circuit shown in FIG. 7. By multiplying by 4 may be delivered to the control unit 15.

5 is a schematic view showing the structure when the ice discharge device of the present invention is applied to an ice water purifier.

Referring to FIG. 5, the ice reservoir 140 may have ice discharge means such as a screw 141 for extracting the ice into the housing 142. When the screw 141 rotates in a forward direction about the rotation shaft 141a by the driving of the DC motor 148, the ice loaded in the ice reservoir 140 is discharged through the ice discharge port 143.

In the ice discharge port 143 side of the ice reservoir 140, a discharge inclined portion 142a inclined downward is formed to facilitate the discharge of the ice pushed out by the screw 141, and behind the ice reservoir 140, The inclined portion 142b is formed to discharge the water generated while the ice melts in the ice reservoir 140 through the drain 144.

In addition, an optical sensor 145 may be installed at one side of the housing 142 of the ice reservoir 140 to detect a loading state of the ice accommodated in the ice reservoir 140.

The photosensors 145a, 145b, and 145c may be arranged at a predetermined height of the inner wall of the ice reservoir so as to check the loading height of the ice.

The DC motor 148 may be driven at different rotational speeds according to the average level of the voltage signal of the controller (not shown).

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those skilled in the art.

Claims (10)

A screw disposed at the bottom of the ice reservoir for discharging the ice loaded in the ice reservoir;
A DC motor connected to the rotating shaft of the screw to drive the screw in rotation;
A measuring unit measuring an amount of ice loaded in the ice storage unit; And
And a control unit controlling the speed of the DC motor by controlling the voltage level supplied to the DC motor according to the measured amount of ice.
The method of claim 1, wherein the measuring unit is implemented using one or more optical sensors,
And the optical sensor is disposed at a predetermined height of an inner wall of the ice reservoir.
The ice ejection apparatus of claim 1, wherein the measurement unit is implemented using a pressure sensor or a weight sensor.
The ice ejection apparatus of claim 1, wherein the controller is configured to discharge the ice to control the speed of the DC motor to be the maximum speed when the measured amount of ice is at maximum and when the measured amount of ice is the minimum. Device.
The ice ejection apparatus of claim 4, wherein the controller controls the speed of the DC motor so that the speed of the DC motor is inversely proportional to the measured amount of ice.
The ice ejection apparatus of claim 4, wherein the control unit adjusts a voltage level supplied to the DC motor by using a pulse width modulation (PWM) scheme.
The method of claim 1,
The ice discharge device further includes a second measuring unit capable of measuring the speed of the DC motor,
And the control unit controls the voltage level supplied to the DC motor so that the measured speed of the DC motor is maintained within a predetermined range of the speed of the DC motor corresponding to the loaded ice amount.
The method of claim 7, wherein the second measuring unit
Ice ejection device that measures the rotational speed of a DC motor using a magnetic sensor.
An ice making unit for generating ice;
An ice reservoir for storing the ice generated by the ice making unit; And
And an ice discharge device for discharging the ice stored in the ice reservoir using a direct current motor and varying the speed of the direct current motor according to the amount of ice stored in the ice making unit.
The method of claim 9, wherein the ice discharge device
A screw disposed at a lower end of the ice reservoir for discharging ice loaded in the ice reservoir;
The direct-current motor connected to the rotating shaft of the screw to drive the screw in rotation;
A measuring unit measuring an amount of ice loaded in the ice storage unit; And
And a controller for controlling the speed of the DC motor by controlling the voltage level supplied to the DC motor according to the measured amount of ice.

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