Pulse electrothermal mold release icemaker with safety baffles for refrigerator

Abstract

An icemaker and a refrigerator having an icemaker are discussed. The icemaker has pulse-electrothermal ice release and includes an ice-making tray having several ice forming portions in which water is stored and ice is formed; and a housing surrounding the ice-making tray provided with at least one cold air inlet and/or ice ejection port through which cold air is supplied and ice released along a bent channel. The cold air inlet and/or ice ejection ports are baffled to prevent contact with a user's fingers and thereby reduce the possibility of electric shock.

Description

FIELD OF THE INVENTION

The present invention relates to an icemaker and a refrigerator having an icemaker. More specifically, the present invention relates to a pulse electrothermal icemaker and a refrigerator having the icemaker, wherein the icemaker has a baffled passage for admitting cold air and releasing ice while preventing users from accessing interior components of the icemaker.

BACKGROUND

Generally, an ice-making tray is an apparatus in which ice is made from water by exposure to cold air in a freezing device. In particular, an ice making tray, which stores water in a specific container and makes the stored water into ice by freezing the stored water below the freezing point, is generally used in a refrigerator, a water purifier or vending machine, and an icemaker (hereinafter, referred to as a “refrigerator and so forth”).

In the past, a simply configured ice making process, in which an ice-making container filled with water is placed in a freezing chamber below the freezing point and ice is inconveniently taken out of the ice-making container by a user after ice is made, was generally used. However, as living standards rise and technologies develop, more and more refrigerators have automatic icemakers.

Ice making trays are largely classified into thermal icemaking trays and twist icemaking trays according to the type of ice release. The thermal type generally has a heater installed adjacent to the tray to melt and separate ice therefrom, and the twist type is a type in which ice is released by twisting the ice-making tray without using a heater.

A pulse-electrothermal icemaking tray releases ice by applying a brief pulse of electric current through the tray to melt an interface layer and release the ice.

Application of electric current to an icemaking tray can, however, pose risk to users if users are permitted easy access to the icemaking trays.

However, as the ice making tray installed in the icemaker chills water not by itself but by cold air supplied, the ice making tray installed in the icemaker must have a cold air inlet port for sufficiently supplying cold air because cold air must be sufficiently supplied into the ice making tray installed in the icemaker.

Also, an ice outlet must be provided so that ice can be discharged from the icemaker.

SUMMARY

To achieve these objects and other advantages and in accordance with the purpose of the invention, as embodied and broadly described herein, an icemaker having pulse-electrothermal ice release includes an ice making tray having several of ice forming portions in which water is stored and ice is formed; and a housing surrounding the ice making tray provided with at least one cold air inlet and/or ice ejection port through which cold air is supplied and ice released along a bent channel.

In an embodiment, a cold air inlet port is a gap between spaced plates disposed at an upper part of the ice-making tray. In an embodiment, the plates are positioned at different heights and parallel to each other. In another embodiment, a cold air inlet ports may be formed by several slanted block members.

Further, the housing is provided with a slanted inner surface that faces toward the inner side of the housing at a specific angle, and the ice outlet may be a gap between two slanted inner surfaces of the housing. In a particular embodiment, the pair of slanted inner surfaces have a vertically overlapped portion at the lower part of the ice-making tray. Also, the gap that constitutes the ice outlet is preferably less than the maximum width of ice that is formed in the ice-making tray.

In an embodiment, a refrigerator having an icemaker includes: a cabinet provided with a freezing chamber for freezing foods; a door which is hinged to the cabinet in order to selectively open/close the freezing chamber; an ice making tray within the icemaker; and a housing surrounding the ice making tray and provided with a cold air inlet port through which cold air supplied from an upper part of the ice making tray flows to the ice making tray along a bent channel and an ice outlet through which ice moved from the ice making tray is discharged along a bent passage at the lower side.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an icemaker provided with an ice making tray according to the present invention;

FIG. 2 is a perspective view of an ice making tray according to the present invention;

FIG. 3A and FIG. 3B show an icemaker according to a preferred embodiment of the present invention;

FIG. 4A and FIG. 4B illustrate an icemaker according to another embodiment of the present invention; and

FIG. 5A and FIG. 5B show an icemaker according to further another embodiment of the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. However, the present invention is not restricted to the illustrated embodiments, but may be embodied in different ways within in the scope of the invention. The embodiments are described so that the concept of the present invention is sufficiently appreciated by a person skilled in the art. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.

FIG. 1 is a perspective view showing an icemaking tray provided in an icemaker according to the present invention, and FIG. 2 is a perspective view showing only the icemaking tray.

The icemaker 100 according to the present invention has an ice making tray 110 with apparatus for dispensing water therein, and an icemaking tray cover (not shown) at the upper part of the ice making tray 110 to prevent water from overflowing or splashing.

The ice making tray 110 includes at least one receiving portions 112 receiving water for making ice cubes and provided with an opening through which water is supplied and ice cubes are separated. The icemaking tray 110 may be an assembly of several receiving portions 112.

In variations of this embodiment, the ice-making tray 110 may be configured that receiving portions 112 are arranged in a row as shown, or the receiving portions 112 may be arranged in several rows.

Receiving portions 112 may be formed in various shapes. Specifically, the receiving portions 112 may be formed in a hemisphere shape or in a cube shape. Multiple interchangeable ice making trays 110 having receiving portions 112 of various shapes may be provided such that ice cubes having shape satisfying a particular user's taste and need can be made. It is understood that the receiving portions 112 having complicated shapes such as a star shape and a heart shape can be provided.

Icemaker 100 has a moving portion that moves the ice-making tray 110 to an ice release position so that the after water freezes in icemaking tray 110 the ice can be separated from the ice-making tray 110.

In an embodiment, the moving portion may be configured that it translates the ice-making tray 110. In another embodiment, however the moving portion rotates the ice-making tray 110 about a longitudinal axis so the open upper part of the receiving portions 112 of the ice making tray 110 faces downwards toward the lower part.

The moving portion may further include a pivot 122 that is axially connected to both longitudinal ends of the ice-making tray 110, and a motor (not shown) for rotating the ice-making tray 110.

After completing the ice making process the motor starts and rotates the ice-making tray 110 through an angle of 90°˜180°. On one side of the moving portion, a water supply device for supplying water into the ice-making tray 110 is provided. The water supply may include a storage container 132 in which water is stored, and a water supply pipe 134 that supplies water from the storage container 132 to the ice-making tray 110.

The storage container 132 is configured that it can be supplied with water from a water supply hose 136. Also, since a valve (not shown) is provided in a region where the water supply pipe 134 and the storage container 132 are connected, water flows into the ice-making tray 110 only when needed.

The ice making tray 110 is made of an electrical conductor, and the ice making tray 110 generates heat as current is passed through tray 110. This heat melts an interfacial layer of ice thereby separating the ice from the tray 110.

A power supply 142 capable of supplying electric current through the ice-making tray 110 is provided. The power supply device 142 has a power supply 143 and an input control device 144.

The electrical conductor of which the ice making tray 110 may be made of a material including, but not limited to, Copper, Silver, Aluminum, Titanium, stainless steel alloy or aluminum alloy having high electric conductivity, as well as an injection molded electrically conductive plastic.

It is possible to uniformly heat the ice-making tray 110 rapidly by applying electric current through electrode 114.

The ice making tray 110 is configured that electric current flows lengthwise through the ice making tray 110 An electric circuit (not shown) is connected to an electrode 114 (illustrated only at one end) at each end of the tray 110.

As heat is generated by applying an electric current to the ice making tray 110 ice is melted at the contact surface between the receiving portions 112 of the ice making tray 110 and the ice formed therein. While icemaking tray 110 is rotated to face the icemaker bottom, ice attached to the receiving portion 112 separates from the receiving portion 112, and drops from the ice-making tray 110.

The heating of the ice-making tray 110 is produced by a pulse of current controlled by the input control device 144. Here, the input control device 144 may include a resistive circuit, a triac circuit or a coil circuit.

FIG. 3 a is a perspective view of an icemaker having a housing 150, wherein a side surface of the housing is incised, and FIG. 3b is a cross-sectional view schematically showing an icemaker according to the present invention.

The housing 150 of the icemaker 100 surrounds the ice-making tray, and the housing is configured to discharge ice and to receive cold air.

A cold air inlet port 151a through which cold air enters is provided at the upper part of the housing. Cold air inlet port 151a allows cold air introduced from the upper part of the housing 150 to reach the ice-making tray 110 along a bent channel. The bent or baffled channel prevents users from contacting the tray and being electrically shocked as well as supplying cold air for making ice.

The cold air circulates into the ice-making tray 110 by convection. Therefore, the cold air supplied into the ice-making tray 110 is supplied from the upper part and ice is made by freezing water in the ice-making tray 110.

As shown in FIG. 3b, the cold air introduced from the upper part of housing 150 reaches the ice-making tray 110 along the bent channel X.

In the embodiment of FIG. 3b, the cold air inlet port 151a, through which cold air is supplied, is a gap between spaced plates 154a, 155a. Plates 154a, 155a may have a bent and extended portion, and they may be installed at both sides 154, 155 of the housing 150. In an embodiment, plates 154a, 155a have an overlapped portion at the upper part of the ice-making tray 110.

Plates 154a, 155a are overlapped at the upper part of the icemaking tray 110 to prevent users from contacting with the ice-making tray 110 and protect users from electrical shock from contacting the icemaking tray 110.

The channel for cold air supplied to the ice-making tray 110 is formed as a bent channel to prevent the user from contact with the icemaking tray 110.

The extended length of the plates 154a, 155a is preferably set such that the icemaking tray 110 cannot be seen from outside housing 155.

Since the ice making tray 110 cannot be seen from the outside housing 155, then straight metal objects (for example, kitchen utensils such as a knife) inserted by a user into the cold air inlet port 151a will not contact tray 110.

Also, the housing is provided with an ice outlet 153 from which ice released from the ice making tray 110 is discharged via a bent passage to prevent the user from contacting the ice making tray 110 though the ice outlet.

The ice-making tray 110 is heated by an electric current to release ice into the ice storage cabinet after the icemaking tray rotates so that the receiving portions face down.

In the embodiment of FIG. 3b, the dotted lines indicate the rotated state of the ice-making tray 110. Released ice drops by its own weight, and is discharged to the ice outlet 153 via bent passage Y.

Ice discharged drops through the ice outlet 153, a gap between the slanted inner surfaces 154b, 155b provided at the lower part of a pair of opposing inner surfaces 154, 155 of housing 150.

The slanted inner surfaces 154b, 155b may be integrally formed in the inner surfaces 154, 155 as illustrated in FIG. 3b, or may be formed separately from the inner surfaces 154, 155. The inner surfaces are bent toward the inner side of the housing at an angle and extended, and the ice outlet 153 is a gap between the slanted inner surfaces 154b, 155b that are bent and extended.

The ice-making tray may be installed in a refrigerator with the ice-making tray at the door of the freezing chamber. In this case, it is necessary to prevent the hands of users from approaching the ice-making tray 110 of the icemaker from the bottom.

In particular, users of low stature, specifically children, should be prevented from being electrically shocked by inserting their hands into the housing at the lower part of the ice-making tray 110.

Therefore, according to the embodiment shown in FIG. 3b, the bent channel Y, from which ice is discharged, is configured that the ice is not vertically dropped, but is collides with the higher inner side surface of the pair of inner side surfaces 154, 155 of the housing and again with the lower inner side surface before discharge.

In this embodiment, the angle of the inner side surface of the housing which is bent and extended at an angle, and the length of the slanted inner surface 154b, 155b are preferably determined as follows.

That is, the angle θ1, θ2 of the bent and extended inner side surface is preferably within the range that can downwardly slide ice without remaining on the bent inner side surface 154b, 155b even when the ice collides with the inner side surface.

Also, since ice is not downwardly slid where the angle of the bent and extended inner side surface is a steep angle, the angle should be the range that allows ice to be downwardly slide after colliding thereto.

Also, as well as the above described cold air inlet port 151a, the respective length α, β of the slanted inner surface 154b, 155b has an overlapped portion at the lower part of the ice making tray 110, as the plate constituting the cold air inlet port has an overlapped portion.

The housing 150 is preferably designed such that the ice-making tray cannot be seen from below by extending the respective slanted inner surface 154b, 155b.

The respective lengths α, β of the slanted inner surface 154b, 155b and the angle θ1, θ2 of the bent and extended inner side surface are determined according to the size of ice capable of being discharged.

The width of the ice outlet 153 should be greater than the minimum size capable of discharging the ice.

The least distance between the slanted inner surface 155b disposed at the lower side and the slanted inner surface 154b disposed at the upper side is defined as δ. This δ is a vertical distance from the slanted inner surface 155b disposed at the lower side to the lower end of the slanted inner surface 154b disposed at the upper side.

In an embodiment, the least distance δ is greater than the maximum depth c of the unit receiving portion 112 of the ice making tray 110 and is less than the maximum diameter d of one receiving portion 112.

The least distance δ is greater than the maximum depth of the receiving portion 112 of the ice-making tray 110, because the least distance δ must be greater than the depth of the receiving portion 112, i.e. the thickness of ice, in order to discharge released ice through the ice outlet 153.

The receiving portion 112 can be shaped in various ways.

As described in the above, the ice-making tray according to the present invention may be installed at the door of the freezing chamber when it is installed in the refrigerator. In this embodiment, the door of the freezing chamber is a door that is hinged to the cabinet, in which the freezing chamber is provided, to selectively open or close the freezing chamber.

Since the inner side surface, which is installed in a direction of the inner side surface of the door, is configured with the higher slanted inner surface 154b surrounding the lower slanted inner surface 155b, it is difficult for users to approach the ice-making tray than otherwise, even when user's arm is bent.

FIG. 4 a is a perspective view of an icemaker having a housing 150, wherein a side surface of the housing is incised, and FIG. 4b is a cross-sectional view schematically showing an icemaker according to the present invention.

The overlapped explanation with the embodiment in FIG. 3 will be omitted from the embodiment in FIG. 4.

According to the embodiment in FIG. 4, the housing 150 surrounding the ice making tray 110, in which ice is made, is provided with a plurality of slot-like cold air inlet ports 151b that are formed by a plurality of slanted block members 152.

FIG. 4 b illustrates the cold air inlet ports 151b with reference to the schematic cross-sectional view of the icemaker according to the present invention.

Cold air supplied into the upper part of the ice making tray 110 is supplied to the ice making tray provided in the housing via the cold air inlet ports 151b formed by the plurality of slanted block members 152.

The block members 152 at the upper part of the housing 152 are inclined at a specific angle. Block members 152 may be integrally formed with the housing 150, or may be separately made and installed at the upper part of the housing.

By adjusting the spacing between of the block members 152, it is possible to block user's fingers from the ice-making tray 110. For example, if the diameter of an object capable of passing through the cold air inlet port 151a is less than 10 mm, it is possible to prevent parts of the body, for example the finger of children, from touching tray 110.

To prevent straight conductive slender objects inserted into the cold air inlet port 151b from contacting tray 110, the angle θ3 of the block member 152 can be increased.

If the angle θ3 of the block member 152 is increased, the ice-making tray 110 cannot be seen from the upper part of the housing.

FIG. 5 a is a perspective view of an icemaker having a housing 150, wherein a side surface of the housing is incised, and FIG. 5b is a cross-sectional view schematically showing an icemaker according to the present invention.

In the embodiment of FIGS. 5A and 5B, the block member constituting the cold air inlet port are arranged in double layers and the slot constituting the cold air inlet port is arranged in double layers.

The cold air inlet ports 151c, 151d in the shape of a slot will be explained with reference to FIG. 5b.

As shown in FIG. 5b, block members 152a, 152b are slantedly arranged in double layers with cold air inlet ports 151c, 151d formed by the block members overlapping each other. The cold air supplied from the upper part of the housing through the overlapped cold air inlet ports can be supplied into the ice-making tray 110 along the cold air passage X.

As shown in FIG. 5a and 5b, the angle θ3 of the block member 152 is high enough so that the ice-making tray cannot be seen from above the upper part of the housing.

With the horizontal position of the respective block member 152a, 152b is appropriately adjusted, the possibility of metallic objects touching the ice-making tray is minimized because the ice-making tray 110 cannot be seen from the upper part of the housing.

It is therefore possible to prevent electric shock from the conductive ice-making tray while sufficient cold air flows into the ice-making tray and the discharge of ice is unimpeded.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. Thus, 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.

Claims

1. An icemaker, comprising: an icemaking tray having a plurality of ice receiving portions in which water is stored to make ice, the icemaking tray comprising a material that generates heat when an electric current flows through the icemaking tray;a controller for providing an electric current through the icemaking tray to perform an ice body separation; anda housing surrounding the ice making tray and provided with a cold air inlet port through which cold air supplied from an upper part of the ice making tray flows to the ice making tray along a bent channel, and an ice outlet through which ice moved from the ice making tray is discharged along a bent passage at a lower side of the housing;wherein the cold air inlet port is a gap between spaced plates disposed at an upper part of the ice-making tray; andwherein the plates are positioned at different height and are parallel to each other.

2. The icemaker according to claim 1, wherein the plates overlap each other such that they are spaced apart at the upper part of the ice making tray.

3. An icemaker, comprising: an icemaking tray having a plurality of ice receiving portions in which water is stored to make ice, the icemaking tray comprising a material that generates heat when an electric current flows through the icemaking tray;a controller for providing an electric current through the icemaking tray to perform an ice body separation; anda housing surrounding the ice making tray and provided with a cold air inlet port through which cold air supplied from an upper part of the ice making tray flows to the ice making tray along a bent channel, and an ice outlet through which ice moved from the ice making tray is discharged along a bent passage at a lower side of the housing; andwherein the cold air inlet port is a plurality of slots formed by a plurality of slanted block members;wherein the slots formed by the block members are formed as double layers at different heights.