KR20170023277A - Ice maker - Google Patents

Abstract

An ice maker is disclosed. According to one embodiment of the present invention, the ice maker comprises: a cooling unit having an immersion member immersed in water to generate ice; and a rotation means rotating the cooling unit between an ice making position above a first tank storing the water where the immersion member is immersed and an ice separation position above a second tank storing the ice generated in the immersion member.

Description

Ice-maker {ICE MAKER}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an ice maker for making ice, and more particularly, to an ice maker capable of making ice with a simple configuration without a tray containing water immersed in an immersion member for generating ice.

An ice maker is an ice maker.

Such an ice maker is provided in an apparatus for providing ice, for example, an ice water purifier or a refrigerator, to produce ice and supply it to the user.

Such an ice-maker includes an immersion member immersed in water contained in a tray, and the immersion member is cooled down to the freezing point by a cooling unit, and water is sprayed onto the ice-making frame cooled down below the freezing point by the immersion- Or a water-based type in which water is made to flow into an ice-making frame cooled down to the freezing point by a cooling unit to make ice.

Of these, in the case of immersion, a tray is required in which the immersion member is immersed in water as described above.

In addition, during ice making to make ice, the tray had to be rotated so that water was contained in the tray and ice was separated from the immersion member to move the ice, so that the ice did not hit the tray. That is, the tray had to be rotated between the freezing position and the freezing position.

In this way, since the tray must be rotated, space and equipment are required for the tray, and space and equipment for supplying water to the tray and discharging the residual water contained in the tray are required.

Therefore, the conventional submerged ice maker is relatively complicated in structure, and thus it is difficult to miniaturize the ice maker.

The present invention is realized by recognizing at least any one of the above-mentioned conventional needs or problems.

One aspect of the object of the present invention is to provide an immersion member which is capable of making ice even without a tray that contains immersed water and rotates between the ice-making position and the ice-making position.

Another aspect of the object of the present invention is to simplify the structure of the ice maker and make it possible to miniaturize the ice maker.

Another aspect of the object of the present invention is that the cooling unit including the immersion member is rotated between the freezing position on the first tank containing the water to which the immersion member is immersed and the driving position on the second tank where the ice is stored.

An ice maker relating to an embodiment for realizing at least one of the above problems may include the following features.

An ice maker according to an embodiment of the present invention includes: a cooling unit including an immersion member in which water is immersed in water; And rotation driving means for rotating the cooling unit between a freezing position on the first tank containing the water immersed in the immersion member and a driving position on the second tank where the ice produced in the immersion member is stored; . ≪ / RTI >

In this case, the cooling unit may further include an evaporator to which the immersion member is connected and in which the refrigerant flows.

In addition, one end of the evaporator may be connected to an expansion valve or capillary included in the refrigeration cycle together with the evaporator by a flexible tube, and the other end of the evaporator may be connected to a compressor included in the refrigeration cycle by a flexible tube.

The rotation driving means may include a rotating link member connected to the cooling unit and rotating.

In addition, the rotating link member may be rotatably provided in the second tank.

The rotation driving means may further include a driving motor connected to the rotating link member to rotate the rotating link member.

In addition, the first tank and the second tank may be open at the top.

The first tank may be connected to an inlet pipe through which water is introduced and a discharge pipe through which water is discharged.

Further, the first tank may be a cold water tank and the second tank may be an ice storage tank.

In the state that the immersion member is immersed in the water contained in the first tank, cold refrigerant below the freezing point is allowed to flow to the evaporator to cool the water contained in the first tank and to make cold water.

As described above, according to the embodiment of the present invention, the cooling unit including the immersion member is rotated between the freezing position on the first tank containing the water to which the immersion member is immersed and the driving position on the second tank where the ice is stored .

In addition, according to the embodiment of the present invention, water immersed in the immersion member is contained and ice can be made without a tray rotating between the ice-making position and the ice-removing position.

Further, according to the embodiment of the present invention, the structure of the ice maker can be simplified and the size of the ice maker can be reduced.

1 is a view showing an embodiment of an ice maker according to the present invention.
2 is a cross-sectional view taken along line A-A 'in Fig.
FIGS. 3 to 7 are sectional views showing the operation of an embodiment of the ice maker according to the present invention, and FIG. 3 shows the inflow of water into the first tank in a state where the cooling unit is in the ice making position.
Fig. 4 shows that ice is initially produced in the immersion member of the submerged cooling unit in the first tank.
5 shows that ice of predetermined required size is generated in the immersion member.
Fig. 6 shows that the cooling unit is rotated to the de-icing position.
Fig. 7 shows that the ice produced in the immersion member is moved to the second tank.

In order to facilitate understanding of the features of the present invention as described above, an ice maker relating to an embodiment of the present invention will be described in detail.

The embodiments described below will be described on the basis of embodiments best suited to understand the technical characteristics of the present invention, and the technical features of the present invention are not limited by the embodiments described, And that the present invention may be implemented with other embodiments. Therefore, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. In order to facilitate understanding of the embodiments to be described below, in the reference numerals shown in the accompanying drawings, among the constituent elements which perform the same function in each embodiment, the related constituent elements are indicated by the same or an extension line number.

Hereinafter, an embodiment of the ice maker according to the present invention will be described with reference to FIGS. 1 to 7. FIG.

FIG. 1 is a view showing an embodiment of an ice maker according to the present invention, and FIG. 2 is a sectional view taken along the line A-A 'in FIG.

3 to 7 are sectional views showing the operation of one embodiment of the icemaker according to the present invention, and Fig. 3 shows the inflow of water into the first tank in a state where the cooling unit is in the ice making position.

4 shows that ice is initially generated in the immersion member of the water-immersed cooling unit contained in the first tank, Fig. 5 shows that ice of a predetermined required size is generated in the immersion member, Fig. 6 FIG. 7 shows that the ice generated in the immersion member is moved to the second tank by being skimmed.

One embodiment of the ice maker 100 according to the present invention may include a cooling unit 200 and a rotation driving unit 300 as shown in FIGS.

The cooling unit 200 may include an immersion member 210. The immersion member 210 may be immersed in water to generate ice (I) as shown in FIG. 3 to FIG. The shape and configuration of the immersion member 210 are not particularly limited, and any shape and configuration can be used as long as the immersion member 210 is shaped so that ice (I) can be generated in the water.

The immersion member 210 may be a plurality of immersion members. However, the number of the immersion members 210 is not particularly limited, and any number can be used.

The cooling unit 200 may further include an evaporator 220. The above-described immersion member 210 may be connected to the evaporator 220. The immersion member 210 can be connected to the evaporator 220, for example, by welding.

However, the structure in which the immersion member 210 is connected to the evaporator 220 is not particularly limited, and may be any known construction such as being connected by bolts, rivets, or the like.

The evaporator 220 may be included in a refrigeration cycle with a compressor (not shown), a condenser (not shown) and an expansion valve or capillary (not shown) to allow the refrigerant to flow.

One end of the evaporator 220 may be connected to the expansion valve or capillary tube by a flexible tube. The other end of the evaporator 220 may be connected to the compressor by a flexible tube. As a result, the rotation of the cooling unit 200 by the rotation driving means 300 is smooth and the refrigerant can flow into the evaporator 220.

When the cold refrigerant under the freezing point flows into the evaporator 220, the above-described immersion member 210 connected to the evaporator 220 can be cooled below the freezing point. As a result, as shown in FIGS. 4 and 5, ice (I) may be generated in the immersion member 210.

In addition, when the hot refrigerant on the freezing point flows into the evaporator 220, the immersion member 210 connected to the evaporator 220 can be heated above the freezing point. 7, ice (I) generated in a size required for the immersion member 210 can be separated from the immersion member 210. As shown in FIG.

However, the structure in which the immersion member 210 is heated so that the ice I is separated from the immersion member 210 is not limited to allowing the hot refrigerant on the freezing point to flow to the evaporator 220 as described above, A heater (not shown) may be provided in the evaporator 210 or the evaporator 220 to heat the immersion member 210 to a temperature higher than the freezing point.

As described above, when the immersion member 210 is connected to the evaporator 220 through which the refrigerant flows, the refrigerant flowing through the evaporator 220 may also flow into the immersion member 210.

For example, a refrigerant channel (not shown) connected to the evaporator 220 may be formed in the immersion member 210 to allow the refrigerant to flow into the immersion member 210.

In addition, the cooling unit 200 may include a thermoelectric module (not shown) in which heat is transferred from one side to the other side when power is applied, in addition to the evaporator 220 described above. The immersion member 210 may be connected to the thermoelectric module and may be heated so that the ice (I) cooled or generated is separated to generate ice (I).

The rotation driving means 300 is configured to move the cooling unit 200 to a freezing position on the first tank T1 containing the water immersed in the immersion member 210 as shown in Figures 3 to 5, Between the ice-making position on the second tank T2 where the ice (I) produced in the immersion member 210 as shown in FIG.

When the cold refrigerant under the freezing point flows in the evaporator 220 connected to the immersion member 210, the immersion member 210 is immersed in the water contained in the first tank T1, Ice (I) can be generated.

Since the immersion member 210 is located on the second tank T2 where the ice I is stored in the ice making position, when the hot refrigerant on the freezing point flows to the evaporator 220 to which the immersion member 210 is connected , Ice (I) of a predetermined required size generated in the immersion member 210 can be separated from the immersion member 210 and moved to the second tank T2.

Accordingly, water immersed in the immersion member such as a conventional submerged ice-making machine is contained, and ice can be produced without a tray rotating between the ice-making position and the ice-making position. Since the structure of the ice maker is simplified, the size of the ice maker can be reduced.

The rotation driving means 300 may include a rotating link member 310. The rotating link member 310 may be connected to the cooling unit 200, e.g., the evaporator 220 of the cooling unit 200. In addition, if the cooling unit 200 includes a thermoelectric module as described above, the rotating link member 310 may be connected to the thermoelectric module.

As shown in FIG. 1, an annular connecting portion 311 may be formed on one side of the rotating link member 310. The rotating link member 310 can be connected to the evaporator 220 by, for example, inserting the evaporator 220 into the annular connecting portion 311 of the rotating link member 310.

However, the configuration in which the rotating link member 310 is connected to the cooling unit 200, for example, the evaporator 220 of the cooling unit 200, etc. is not particularly limited, and any well-known configuration is possible.

1, two rotating link members 310 may be connected to one side and the other side of the evaporator 220 of the cooling unit 200, respectively. However, the number of the rotating link members 310 is not particularly limited, and any number can be used.

The rotating link member 310 can rotate. Accordingly, the cooling unit 200 can be rotated between the freezing position as shown in Figs. 3 to 5 and the freezing position as shown in Figs. 6 and 7.

The annular connecting portion 311 of the rotating link member 310 may be provided with a bearing (not shown). Accordingly, even when the rotating link member 310 is rotated, the immersion member 210 can always be oriented in the gravity direction.

The rotating link member 310 may be rotatably provided in the second tank T2. For example, a rotation protrusion (not shown) is formed in the second tank T2 and an insertion hole (not shown) in which a rotation protrusion is inserted is formed on the other side of the rotation link member 310, May be rotatably provided around the rotation protrusion of the second tank T2.

However, a configuration in which the rotating link member 310 is rotatably provided in the second tank T2 is not particularly limited. The rotating link member 310 is formed with a rotation protrusion, and the second tank T2 is provided with an insertion hole And is rotatably provided.

The rotation driving means 300 may further include a driving motor 320. The driving motor 320 may be connected to the rotating link member 310 to rotate the rotating link member 310.

When the two rotating link members 310 are connected to the evaporator 220 of the cooling unit 200 as shown in Figure 1, the driving motor 320 is connected to one of the two rotating link members 310 . However, two driving motors 320 may be connected to the two rotating link members 310, respectively.

1, the gear 322 is connected to the rotation shaft 321 of the drive motor 320 and the gear 322 is engaged with the internal gear 311 formed on the other side of the rotation link member 310 The driving motor 320 can be connected to the rotating link member 310. [

However, the structure in which the drive motor 320 is connected to the rotary link member 310 is not particularly limited, and the gear 322 of the drive motor 320 may be connected to the external gear (not shown) formed on the other side of the rotary link member 310 (Not shown), and the like.

The first and second tanks T1 and T2, in which the cooling unit 200 is located at the ice-making position or the ice-making position, can be opened at the top.

Thereby, the immersion member 210 of the cooling unit 200 can be easily immersed in the water contained in the first tank T 1 by the rotation driving means 300, and the ice I (I Is separated from the immersion member 210 and drops by its own weight and can easily move to the second tank T2.

The first tank T1 may be connected to an inflow pipe PI through which water flows and a discharge pipe PO through which water is discharged. The inlet pipe (PI) and the outlet pipe (PO) may be provided with opening / closing valves (V), respectively. The inlet pipe PI is connected to a water supply source (not shown) such as a water supply pipe, and the outlet pipe PO can be connected to a water discharge member (not shown) such as a cock or a faucet.

Accordingly, when the opening / closing valve V of the inlet pipe PI is opened, the water of the water supply source can be supplied to the first tank Tl through the inlet pipe PI as shown in Fig. When the opening and closing valve V of the discharge pipe PO is opened, the water contained in the first tank T1 cooled by the cool refrigerant below the freezing point flowing through the evaporator 220 through the immersion member 210 The cold water may be discharged through the discharge pipe PO and supplied to the user by the water discharge member as shown in FIG.

On the other hand, when the cold refrigerant below the freezing point is allowed to flow in the evaporator 220 in the ice making position of the cooling unit 200, that is, in the state where the immersion member 210 is immersed in the water contained in the first tank T1, The water contained in the tank T1 is cooled and ice (I) is generated in the immersion member 210. However, as described above, the cold water is generated in the first tank T1 and the cold water can be stored. As described above, the cold water stored in the first tank T1 is discharged to the outside through the discharge pipe PO and the on-off valve V, and can be supplied to the user.

The first tank T1 may be a cold water tank. Further, the second tank T2 may be an ice storage tank. However, the first tank T1 and the second tank T2 are not particularly limited, and any known one can be used as long as the immersion member 210 is capable of storing immersed water or storing ice (I).

As described above, when the ice maker according to the present invention is used, the cooling unit including the immersion member rotates between the ice-making position on the first tank containing the water to which the immersion member is immersed and the ice- The water immersed in the immersion member is contained, ice can be made without a tray rotating between the ice making position and the ice making position, the structure of the ice maker can be simplified, and the size of the ice maker can be reduced.

The above-described ice maker can be applied to a limited range of the above-described embodiments, but the embodiments may be constructed by selectively combining all or some of the embodiments so that various modifications may be made.

100: Ice maker 200: Cooling unit
210: immersion member 220: evaporator
300: rotation driving means 310: rotating link member
311: connecting portion 312: internal gear
320: drive motor 321:
322: Gear I: Ice
PI: inlet pipe PO: outlet pipe
V: opening / closing valve

Claims (10)

A cooling unit including an immersion member in which water is submerged and ice is generated; And
Rotation driving means for rotating the cooling unit between a freezing position on the first tank containing the water to which the immersion member is immersed and a driving position on the second tank where the ice produced in the immersion member is stored;
. The ice maker of claim 1, wherein the cooling unit further comprises an evaporator to which the immersion member is connected and in which the refrigerant flows. The refrigeration system of claim 2, wherein one end of the evaporator is connected to the expansion valve or the capillary tube included in the refrigeration cycle by the flexible tube together with the evaporator,
And the other end of the evaporator is connected to a compressor included in a refrigeration cycle by a flexible tube. 2. The ice maker according to claim 1, wherein the rotation driving means includes a rotating link member connected to the cooling unit and rotating. The ice-maker according to claim 4, wherein the rotating link member is rotatably provided in the second tank. 5. The ice maker according to claim 4, wherein the rotation driving means further comprises a driving motor connected to the rotating link member to rotate the rotating link member. The ice maker according to claim 1, wherein the first tank and the second tank are open at the top. The ice maker of claim 1, wherein the first tank is connected to an inlet pipe through which water flows and a discharge pipe through which water is discharged. The ice maker according to claim 1, wherein the first tank is a cold water tank and the second tank is an ice storage tank. The ice-maker as claimed in claim 2, wherein a cold coolant below the freezing point flows in the evaporator while the immersion member is immersed in the water contained in the first tank, thereby cooling water contained in the first tank and making cold water.

Images