KR102225176B1 - Ice storage and water purifier having the same - Google Patents

Abstract

The ice storage according to the present invention comprises: a main body having an inner space for storing ice and an outlet for discharging the ice; A transfer unit provided in the main body to transfer ice in the inner space to the discharge port; A measuring unit provided in the main body to measure the amount of ice in the inner space; And a control unit for controlling the transport unit based on the amount of ice measured by the measurement unit, wherein the inner space includes a first inner surface where the discharge port is located, a second inner surface facing the first inner surface, and , Has a bottom surface inclined downward from the first inner surface toward the second inner surface, and the conveying part moves the ice toward the discharge port or in the opposite direction according to the forward rotation or reverse rotation of the conveying blade having a screw shape. And the control unit transfers the ice to the inner space according to the amount of ice measured by the measurement unit before or after the forward rotation of the transfer blade for extracting the ice. In order to flatten, the transfer blade can be rotated in reverse.

Description

Ice storage and water purifier having the same {ICE STORAGE AND WATER PURIFIER HAVING THE SAME}

The present invention relates to an ice reservoir and a water purifier having the same, and more particularly, to an ice reservoir that is more advantageous for quantitative extraction of ice and a water purifier having the same.

Water purifiers on the market in recent years are generally capable of providing ice to users. In order to provide ice as described above, the water purifier includes an ice generating unit for generating ice and an ice storage unit for storing ice. That is, recently marketed water purifiers have a structure in which ice is made by an ice generating unit and then stored in an ice storage unit, and when a user requests ice, ice from the ice storage unit is provided to the user. In many cases, refrigerators have such a structure. However, even if ice is provided, it is very difficult to provide a quantity of ice unlike providing a quantity of purified water. Accordingly, although it is very convenient for a user to provide a quantity of ice, a water purifier or a refrigerator that provides a quantity of ice is hardly available on the market until now. Therefore, the development of an ice reservoir that can provide quantitative ice is urgently needed.

Accordingly, the present invention has been conceived to solve the above problems, and an object of the present invention is to provide an ice reservoir that is more advantageous for quantitative extraction of ice.

The ice storage according to the present invention comprises: a main body having an inner space for storing ice and an outlet for discharging the ice; A transfer unit provided in the main body to transfer ice in the inner space to the discharge port; A measuring unit provided in the main body to measure the amount of ice in the inner space; And a control unit for controlling the transport unit based on the amount of ice measured by the measurement unit, wherein the inner space includes a first inner surface where the discharge port is located, a second inner surface facing the first inner surface, and , Has a bottom surface inclined downward from the first inner surface toward the second inner surface, and the conveying part moves the ice toward the discharge port or in the opposite direction according to the forward rotation or reverse rotation of the conveying blade having a screw shape. And the control unit transfers the ice to the inner space according to the amount of ice measured by the measurement unit before or after the forward rotation of the transfer blade for extracting the ice. In order to flatten, the transfer blade can be rotated in reverse.

Since the ice storage according to the present invention measures the amount of ice stored and then controls the transport unit based on this, the ice can be actively discharged through the transport unit according to the amount of ice stored, which is very advantageous for quantitative extraction of ice. .

1 is a side cross-sectional view showing an ice storage according to an embodiment of the present invention
FIG. 2 is a side cross-sectional view showing a case in which the amount of ice is intermediate as the ice storage of FIG. 1
3 is a side cross-sectional view showing a case in which the amount of ice is minimum as the ice storage of FIG. 1
FIG. 4 is a side cross-sectional view showing a case where ice is biased toward a second inner side as the ice storage of FIG. 1

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited or limited by the following examples.

1 is a side cross-sectional view showing an ice storage according to an embodiment of the present invention. As shown in FIG. 1, the ice storage according to an embodiment of the present invention includes a body unit 110, a transfer unit 130, a measurement unit 150, and a control unit (not shown). For reference, the ice storage according to an embodiment of the present invention may be applied to a water purifier or a refrigerator.

First, a look at the main body 110. The main body 110 serves to temporarily store ice. That is, the main body 110 serves to store ice until the user requests ice. To this end, the main body 110 has an inner space 111 for storing ice. That is, ice generated by a water purifier or refrigerator is stored in the inner space 111 of the main body 110 until a user requests ice. If a user requests ice during such storage, ice in the inner space 111 may be discharged from the inner space 111 of the main body 110 through the outlet 112 of the main body 110 and supplied to the user. . (The outlet may include a door that opens and closes according to the discharge of ice.)

Next, it looks at the transfer unit 130. The transfer unit 130 is provided in the body unit 110 and serves to transfer ice in the inner space 111 to the discharge port 112. That is, when a user requests ice, the transfer unit 130 serves to transfer the ice from the inner space 111 to the discharge port 112 under the control of a controller to be described later. To this end, the transfer unit 130 may include a transfer blade 131 having a screw shape as shown in FIG. 1. That is, the transfer unit 130 may forward or reverse the transfer blade 131 through the transfer motor 132 to transfer the ice toward the discharge port 112 or in the opposite direction thereof. Hereinafter, a rotation for transferring ice toward the outlet 112 is referred to as a forward rotation, and a rotation for transferring ice toward the opposite direction thereof is referred to as a reverse rotation.

Next, it looks at the measurement unit 150. The measurement unit 150 is provided in the body unit 110 and serves to measure the amount of ice in the inner space 111. To this end, the measurement unit 150 may include an infrared transmitter 151 and receivers 152 and 153. In this case, the infrared transmitter 151 may be installed on the first inner surface 115 of the inner space 111, and the infrared receivers 152 and 153 may be installed on the second inner surface 116 of the inner space 111. Here, the first inner surface 115 is an inner surface of the inner space 111 in which the outlet 112 is located, and the second inner surface 116 is the inner space 111 facing the first inner surface 115. It is the inner side.

In order to efficiently store ice, the inner space 111 preferably has a bottom surface 117 inclined downward from the first inner surface 115 to the second inner surface 116 as shown in FIG. 1. . In this case, there is a high possibility that the ice is stored in a biased direction from the inner space 111 to the second inner surface 116. Accordingly, it is preferable that the infrared transmitter 151 is installed on the first inner surface 115 and the infrared receivers 152 and 153 are installed on the second inner surface 116. This is because the amount of ice in the inner space 111 is measured according to whether the infrared receivers 152 and 153 are received as described later.

For reference, the outlet 112 need not be directly formed on the first inner surface 115. That is, if the outlet 112 is located on the first inner surface 115, even if it is not directly formed on the first inner surface 115, the outlet 112 is considered to be located on the first inner surface 115 hereinafter. In addition, it is not necessary that the bottom surface 117 is integrally formed with the body portion 110. For example, in order to filter ice of a certain size or less, as shown in FIG. 1, a partition plate 118 may be further installed under the inner space 111, in this way, the partition plate 118 is further provided. When installed, the partition plate 118 can be viewed as the bottom surface 117. The partition plate 118 may have a through hole 119 having a predetermined size to filter ice smaller than the through hole 119.

Finally, we look at the control unit. The control unit serves to control the transfer unit 130 based on the amount of ice measured by the measurement unit 150. More specifically, in order to extract the amount of ice, the control unit reduces the operating time of the transfer unit 130 when the amount of ice in the inner space 111 increases, and when the amount of ice in the inner space 111 decreases, the transfer unit 130 Control to increase the operating time of the device. (In this case, the quantity is generally a constant amount.) That is, the control unit increases or decreases the operating time of the transport unit 130 according to the amount of ice in the inner space 111, so that a certain amount of ice is (usually) by the transport unit 130. It is to be discharged through the outlet 112. For reference, the control unit may be a control unit independently installed in the ice storage unit, or may be a control unit installed in a water purifier or refrigerator to which the ice storage unit is applied.

The control of the control unit will be described in more detail. First, when a user requests ice, the infrared transmitter 151 transmits infrared rays, and then the infrared receivers 152 and 153 receive infrared rays to measure the amount of ice in the inner space 111. In order to measure the amount of ice through such an operation, a plurality of infrared receivers 152 and 153 may be installed along the height direction of the second inner surface 116.

1 to 3, if both the first infrared receiver 152 and the second infrared receiver 153 do not receive infrared rays, it is determined that the amount of ice is maximum (see FIG. 1), and the first infrared receiver If only 152 does not receive infrared rays, it is determined that the amount of ice is intermediate (see FIG. 2), and when both the first infrared ray receiver 152 and the second infrared ray receiver 153 receive infrared rays, the amount of ice is determined to be the minimum. Judgment is made (see Fig. 3). Here, the maximum or minimum may be determined according to the height of the infrared receivers 152 and 153.

However, even if the infrared receiver partially receives infrared rays, the amount of ice may be determined in the same manner as when the infrared ray is not received. Ice is transparent. Therefore, even if ice is located between the infrared transmitter and the infrared receiver, it is difficult to block 100% of the infrared rays. For example, infrared rays transmitted from an infrared transmitter may be refracted by ice and then received by an infrared receiver. However, in this case, there is a difference in the degree to which the infrared receiver receives infrared rays compared to when ice is not located between the infrared transmitter and the infrared receiver. Therefore, when such a difference occurs, it can be determined that the ice is located.

Alternatively, instead of the infrared transmitter 151 or the receivers 152 and 153, a plurality of temperature sensors (not shown) may be installed along the height direction of the second inner surface 116. If the temperature value measured by the temperature sensor at a specific height is below the reference value, it can be considered that ice is located at that height. Through this, the amount of ice in the inner space 111 can be measured. The measurement unit 150 may be implemented in various ways.

Next, based on the amount of ice measured in this way, the operating time of the transfer unit 130 is controlled through the control unit. For example, if the amount of ice is measured at the maximum, the transfer wing 131 is rotated forward for 5 seconds, and if the amount of ice is measured in the middle, the transfer wing 131 is rotated forward for 7 seconds, and the amount of ice is minimum. If it is measured as, the transfer blade 131 is rotated forward for 10 seconds.

As the amount of ice increases in this way, it is preferable to reduce the operating time of the transfer unit 130. If there is a lot of ice in the inner space 111, the required amount of ice will be discharged even if the transport unit 130 is operated shortly, and if there is little ice in the inner space 111, the required amount of ice must be operated for a long time. Because the ice will be discharged. (Or, depending on the slope of the bottom surface, the more ice can be located closer to the outlet, so if there is a lot of ice in the inner space, even if the transfer unit is shortly operated, the required amount of ice will be discharged.) Such a transfer unit ( 130) can be determined experimentally. That is, the operating time of the transfer unit 130 may be optimally determined through repeated experiments according to the size or shape of the inner space 111.

As described above, quantitative extraction of ice may be achieved by controlling the operation time of the transport unit 130, that is, the rotation time of the transport blade 131, but quantitative extraction of ice is performed by controlling the number of rotations of the transport blade 131. You can also plan. That is, since a substantially constant amount of ice will be transferred every time the transfer wing 131 rotates, the transfer unit 130 may be controlled based on the number of rotations of the transfer wing 131. (If the rotational speed of the transfer blade is not constant, it will be more accurate to control the number of rotations rather than the rotation time.) At this time, if the transfer blade 131 is rotated by a synchronous motor, the synchronous motor rotates the transfer blade 131 at a substantially constant speed. Since it can be rotated, it is also possible to control the number of rotations of the transfer wing 131 by controlling the rotation time of the transfer wing 131.

Meanwhile, the control unit may reversely rotate the transfer wing 131 for the purpose of flattening ice before or after rotating the transfer wing 131 forward for the purpose of extracting ice. When the transfer blade 131 is rotated in a reverse direction to transfer the ice in the opposite direction of the discharge port 112, the ice may be more flat in the inner space 111. When the ice is flat like this, it is very advantageous for quantitative extraction of ice. Here, if the transfer wing 131 is rotated in reverse before the forward rotation of the transfer wing 131, it will be more advantageous for quantitative extraction of ice, and if the transfer wing 131 is reversely rotated after the forward rotation of the transfer wing 131, the rapid supply of ice Will be more advantageous to

In addition, even when it is determined that the ice is maximally filled in the inner space 111 according to the amount of ice measured by the measuring unit 150, the control unit may rotate the transfer blade 131 to flatten the ice. Since the bottom surface 117 of the inner space 111 is inclined downward from the first inner surface 115 to the second inner surface 116, the ice is biased toward the second inner surface 116 as shown in FIG. There is a possibility. Therefore, in the case of FIG. 4, if the amount of ice is determined to be maximum and the transport unit 130 is operated short, it is difficult to extract the amount of ice. In order to prevent this, as a result of measuring the amount of ice in the inner space 111 by periodically transmitting infrared rays from the infrared transmitter 151, when the amount of ice in the inner space 111 is determined to be maximum, the transfer wing 131 is reversed. It is desirable to flatten the ice in the inner space 111 by rotating.

However, there may be a case where ice is not discharged despite the operation of the transport unit 130. To solve this, the ice storage according to the present embodiment may further include a sensing unit (not shown) that detects whether ice is discharged to the outlet 112 according to the operation of the transport unit 130. In the case of further including a sensing unit as described above, the controller may operate the transport unit 130 to extract ice and then determine whether to further operate the transport unit 130 according to a detection result of the sensing unit.

For example, when it is determined that the amount of ice is intermediate and the transfer wing 131 is rotated forward for 7 seconds, but the detection unit does not detect the discharge of ice, the control unit can rotate the transfer wing 131 again for 7 seconds. . In this case, when the detection unit does not detect the discharge of ice, the control unit may repeat the previous operation as it is. Alternatively, the control unit may rotate the transfer blade 131 in the same manner (for example, for 2 seconds) regardless of the operation immediately before.

Meanwhile, the ice storage according to the present embodiment may further include a display unit (not shown) that displays the amount of ice in the inner space 111 to the outside according to the amount of ice measured by the measurement unit 150. For example, when the amount of ice is determined to be the maximum, the maximum amount of ice may be displayed on the display unit, and when the amount of ice is determined to be the minimum, the minimum amount of ice may be displayed on the display unit. When displayed in this way, the user can easily grasp the amount of ice stored according to the display on the display unit. Accordingly, the user can predict the extraction time of ice, thereby providing convenience to the user. For reference, the display unit may be installed outside the water purifier or refrigerator to which the main body 110 is applied, rather than being directly installed on the main body 110.

110: main body 111: internal space
112: outlet 115: first inner surface
116: second inner surface 117: bottom surface
130: conveying unit 131: conveying blade
132: feed motor 150: measuring unit
151: infrared transmitter 152: first infrared receiver
153: second infrared receiver

Claims (15)

A main body having an inner space for storing ice and an outlet for discharging the ice;
A transfer unit provided in the main body to transfer ice in the inner space to the discharge port;
A measuring unit provided in the main body to measure the amount of ice in the inner space; And
And a control unit for controlling the transfer unit based on the amount of ice measured by the measurement unit,
The inner space has a first inner surface on which the outlet is located, a second inner surface facing the first inner surface, and a bottom surface inclined downward from the first inner surface toward the second inner surface,
The conveying unit conveys the ice toward the outlet or in the opposite direction according to the forward or reverse rotation of the conveying blade having a screw shape,
The control unit transfers the ice to flatten the ice when it is determined that the ice is maximally filled in the inner space according to the amount of ice measured by the measurement unit before or after the forward rotation of the transfer blade for extracting the ice. Ice storage, characterized in that the wing is rotated in reverse. The method according to claim 1,
Wherein the control unit decreases the operating time of the transfer unit according to an increase in the amount of ice for quantitative extraction of the ice. delete The method according to claim 1,
Wherein the control unit controls the number of rotations of the transfer blade based on the amount of ice measured by the measurement unit. The method according to claim 1,
The control unit controls the rotation time of the transfer blade based on the amount of ice measured by the measuring unit. delete delete The method according to claim 1,
And a sensing unit configured to detect whether the ice is discharged to the discharge port according to the operation of the transfer unit. The method of claim 8,
And the control unit operates the transfer unit to extract the ice, and then determines whether to further operate the transfer unit according to a detection result of the detection unit. delete delete The method according to claim 1,
The measuring unit is installed on the first inner surface, an infrared transmitter that transmits infrared rays toward the second inner surface, and is installed on the second inner surface to receive the infrared rays, and a plurality of the infrared rays are transmitted along the height direction of the second inner surface An ice storage unit comprising an infrared receiver in which a dog is installed. The method according to claim 1,
And a temperature sensor installed on the second inner surface to measure a temperature, and a plurality of temperature sensors installed along the height direction of the second inner surface. The method according to claim 1,
And a display unit configured to display the amount of ice in the inner space to the outside according to the amount of ice measured by the measuring unit. A water purifier having an ice storage according to any one of claims 1, 2, 4, 5, 8, 9, 12 to 14.

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