KR102152384B1 - ice maker assembly for refrigerator - Google Patents

Abstract

The present invention relates to an ice maker assembly for a refrigerator for extracting ice by operating a protruding piece disposed at a position eccentric from a rotation axis of an ice tray with a lever.

Description

Ice maker assembly for refrigerator}

The present invention relates to an ice maker assembly for a refrigerator for extracting ice by manipulating a protruding piece of an ice tray interlocked therewith through a lever.

Conventionally, as an apparatus related to an ice maker assembly for refrigerators, those described in patent documents are known.

As shown in FIG. 15, the conventional ice maker 1000 includes a frame body 100, a pair of ice trays 200 that are rotatably supported by the frame body 100 and form ice in a certain shape. , A power transmission means 300 disposed on one side of the frame body 100 and rotatably connecting the ice tray 200 and an operation lever 400 for transmitting power to operate the power transmission means 300 Consists of including.

The frame body 100 includes a first frame 110 and a second frame 120. The first frame 110 serves to support the ice tray 200, and the second frame 120 includes a power transmission means 300 for twisting rotation of the ice tray 200 and an operation lever 400. It is a structure that allows operation to take place. In addition, rotation shafts 210a and 210b are formed at the centers of both sides of the ice tray 200 so as to be rotatable by the power transmission means 300. In addition, a spring 220 for providing an elastic restoring force is coupled to the outer circumferential surface of the rotation shaft 210a in a wound state. When the ice tray 200 rotates while one end of the spring 220 is fixed to the ice tray 200 and the other end is fixed to the first frame 110, the spring 220 moves the ice tray 200 It provides resilience to restore it to its original position.

The power transmission means 300 is disposed on one side of the first frame 110, and receives power from the operation lever 400 to rotate the ice tray 200, and thus the rotation shaft 210b of the ice tray 200 It consists of a first pinion 310 and a second pinion 320 respectively connected to one end. The power transmission means 300 and the operation lever 400 rotate the ice tray 200 by gear engagement therebetween. The operating lever 400 transmits power to the power transmission means 300, and is disposed under the power transmission means 300 to rotate the power transmission means 300 in the process of sliding forward and backward. This is the configuration of the size word 410.

Since the direction of the elastic restoring force by the spring 220 and the direction of the rotational force by the power transmission means 300 are opposite to each other, the first pinion 310 and the second pinion 320 of the power transmission means 300 have an operating member The ice tray 200 rotates at the same time in the process of moving the slide, so that the torsional rotation of the ice tray 200 is quickly performed. In addition, the lower portion of the ice tray 200 may include a storage container (not shown) in which ice extracted by twisting rotation is dropped and stored.

However, in order to rotate the ice tray 200, since a separate rack gear 410 and a pinion for interlocking the operation lever 400 and the ice tray 200 are required, the structure and manufacturing process are complicated.

In addition, since the operating lever 400 on which the rack gear 410 is formed protrudes to the outside, there is a risk of injury and is not good aesthetically.

In addition, the spring 220 must be wound on the outer circumferential surface of the rotating shaft 210a for restoring the original position of the operation lever 400 and the torsional rotation of the ice tray 200.

Korean Patent Publication No. 10-2012-0072777

The present invention was conceived to solve the above-described problem, for a refrigerator that can reduce the cost of parts by simplifying the structure linking the lever and the ice tray, and improve the safety and convenience of the user in extracting and storing ice. It is an object to provide an ice maker assembly.

In order to achieve the above object, the ice maker assembly for a refrigerator according to claim 1 of the present invention includes: an ice tray having a rotating shaft; A tray frame supporting the rotation axis of the ice tray; A protruding piece protruding from one side of the ice tray, and a lever for pulling the protruding piece over the ice tray, wherein the protruding piece is disposed at an eccentric position with respect to the center of the rotation axis.

In the ice maker assembly for a refrigerator according to claim 2 of the present invention, the lever includes a body, a handle formed on a front surface of the body, and a rail formed on the body to guide the protruding piece.

In the ice maker assembly for a refrigerator according to claim 3 of the present invention, the rail includes a lower horizontal section for starting rotation of the ice tray, and a vertical section extending upward from the lower horizontal section to gradually advance the rotation of the ice tray. It consists of a section and an upper horizontal section formed by bending and extending sideways in the vertical section.

The ice maker assembly for a refrigerator according to claim 4 of the present invention further includes a support rail extending laterally in the lower horizontal section so as to support and guide the protruding piece when the tray frame is opened or closed.

In the ice maker assembly for a refrigerator according to claim 5 of the present invention, stoppers are formed on both sides of the tray frame to twist the ice tray in a state in which rotation of the ice tray is stopped.

According to the present invention, there are the following effects.

Since the ice tray is rotated by simply manipulating the protruding piece formed on the ice tray through the lever, the structure is simple, reducing parts and reducing the cost of the manufacturing process. In addition, the process of extracting and storing ice is easy and convenient.

And since the lever has a square shape and is inserted inside without a protruding part outside, there is no risk of injury and an aesthetic effect is obtained.

In addition, since a storage device is formed on the upper side of the ice maker that generates and stores ice, it is possible to receive more cold air of ice when storing ice cream or frozen food that needs to be frozen, thereby obtaining a reliable freezing effect.

And because the ice is extracted by implementing a torsional motion on the ice tray through a stopper and a protruding piece, a torsional rotational motion without a spring can be implemented.

1 is a perspective view of an ice maker assembly for a refrigerator according to a preferred embodiment of the present invention.
Figure 2 is an exploded perspective view of Figure 1;
Fig. 3 is a perspective view of Fig. 2 viewed from the R direction.
Figure 4 is a perspective view showing the ice-making tray separated from Figure 1;
5 is a cross-sectional view taken along line AA of FIG. 1.
Figure 6 is a cross-sectional view showing the separation of the lever and the ice tray in Figure 5;
7A to 7C are cross-sectional views showing a rotational operation state of the ice tray.
Figure 8 is a perspective view showing an ice tray.
9 is a perspective view showing a tray frame.
10 is a perspective view showing a lever.
11 is a perspective view showing a state in which the storage case is opened and closed in FIG. 1.
12 is a perspective view showing a storage case.
13 is a perspective view showing a storage frame.
14 is a perspective view of FIG. 1 coupled to a refrigerator door.
15 is a perspective view showing a conventional ice maker assembly for a refrigerator.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view of an ice maker assembly for a refrigerator according to a preferred embodiment of the present invention, FIG. 2 is an exploded perspective view of FIG. 1, FIG. 3 is a perspective view of FIG. 2 viewed from the R direction, and FIG. 4 is A perspective view showing the ice tray separated, FIG. 5 is a cross-sectional view taken along line AA of FIG. 1, FIG. 6 is a cross-sectional view showing the lever and the ice tray separated in FIG. 5, and FIGS. 7A to 7C are Fig. 8 is a cross-sectional view showing an ice tray, Fig. 9 is a perspective view showing a tray frame, Fig. 10 is a perspective view showing a lever, and Fig. 11 is a state in which the storage case is opened and closed in Fig. 1 Fig. 12 is a perspective view, Fig. 12 is a perspective view showing a storage case, Fig. 13 is a perspective view showing a storage frame, and Fig. 14 is a perspective view of Fig. 1 coupled to a refrigerator door.

The ice maker assembly 1 for a refrigerator according to a preferred embodiment of the present invention includes an ice maker 10 that generates and stores ice, as shown in FIGS. 1 to 6. Further, the ice maker assembly 1 for a refrigerator is further provided with a storage device 70 disposed above the ice maker 10 to store food.

As shown in FIGS. 1 to 6, the ice maker 10 includes an ice making unit 11 for generating ice, and a storage unit disposed below the ice making unit 11 to store ice generated in the ice making unit 11 It consists of 60.

The ice making unit 11 includes an ice making tray 20 for generating ice, an ice extracting member 30 for extracting ice generated from the ice making tray 20, and an ice making tray 20 and an ice extracting member 30 therein. ) Is combined and composed of an ice making frame 50 installed on the refrigerator door 99.

In addition, the ice making tray 20 includes an ice tray 21 on which an ice generating cell 24 and a rotation shaft 23 are formed, and a tray frame 25 on which the rotation shaft 23 of the ice tray 21 is supported. In addition, the ice extracting member 30 includes a protruding piece 31 protruding from one side of the ice tray 21 and a lever 40 that pulls the protruding piece 31 and turns the ice tray 21 over. The ice making frame 50 includes a lever housing 51 in which the lever 40 is accommodated.

The storage unit 60 includes a basket 61 for storing ice generated by the ice making unit 11 and a storage frame 66 to which the basket 61 is coupled.

The storage device 70 is disposed above the ice maker 10 and includes a storage case 71 in which food is stored, a storage frame 80 to which the storage case 71 is hinged, and a storage case 71 and a storage frame It consists of a lid (90) covering the top of (80).

Hereinafter, the ice making tray 20 will be described in detail.

The ice making tray 20 includes an ice tray 21 having an ice generating cell 24 and a rotating shaft 23 formed thereon, and a tray frame 25 supporting the rotating shaft 23 of the ice tray 21. 1 and 4, it is coupled to the ice making frame 50 and disposed in the center of the ice maker assembly 1 for a refrigerator.

As shown in FIG. 4, the ice tray 21 is disposed inside and coupled to the ice making tray 20. As shown in Figure 8, the ice tray 21 has a rectangular ice body 22, a plurality of cells 24 formed inside the ice body 22, and protruding from both sides of the ice body 22. It consists of a rotating shaft (23). The ice body 22 is supported by the tray frame 25 and has a size and shape to be rotatable. Inside the ice body 22, a plurality of cells 24 for generating ice in a certain shape are formed. A plurality of cells 24 are formed inside the ice body 22, such as an egg plate. Each cell 24 has a shape of a mountain peak that is convex downward. The upper side of the cell 24 has a square circumference, and the circumference becomes narrower and concave as it goes down. Therefore, since the lower circumference is narrower than the upper side, it is easy to extract ice generated in the cell 24. The rotation shaft 23 is formed protruding in a cylindrical shape on both sides of the ice body 22. The rotation shaft 23 is disposed at the center of both sides of the ice body 22 to support the ice tray 21 on the tray frame 25, and also serves as a central axis on which the ice tray 21 rotates.

As shown in FIG. 4, the tray frame 25 has a rectangular box shape and an ice tray 21 is supported at the top. As shown in FIG. 9, the tray frame 25 includes a support groove 27 in which the rotation shaft 23 of the ice tray 21 is inserted and supported, and a stopper for stopping and twisting the rotation of the ice tray 21. (26) And, the opening and closing handles 28 formed on the front bottom of the tray frame 25, and formed on the outer sides of both sides of the tray frame 25, the tray frame 25 is attached to the ice-making frame 50 in a drawer method. It consists of a coupling bar a (25-1) to be coupled.

The support grooves 27 are disposed on upper ends of the inner side surfaces of both sides of the tray frame 25, respectively. The support groove 27 is disposed in consideration of the rotational motion of the ice tray 21 because the rotation shaft 23 is inserted and positioned on the same line with the central axis on which the ice tray 21 is rotated. The support groove 27 has a cylindrical shape and is formed to protrude from the inside to the outside so that the rotation shaft 23 of the ice tray 21 is inserted, respectively. Therefore, the ice tray 21 is supported on the tray frame 25, and the ice tray 21 can rotate until it stops at the stopper 26.

The stopper 26 is formed in a rectangular plate shape on both upper ends of the front end of the tray frame 25. At the top of the end of the stopper 26 in the direction of the support groove 27, a peak-shaped stop protrusion 26-1 is formed to collide with one side of both sides of the rotating ice tray 21. In addition, the stopper 26 is disposed in front of the upper side of the support groove (27). So, after the ice tray 21 rotating around the rotation shaft 23 inserted in the support groove 27 rotates more than 90 degrees and less than 180 degrees, one side of the edge of the ice tray 21 hits the stopper 26 The rotation is stopped. The ice tray 21 whose rotation is stopped is twisted according to the operation of the lever 40 to extract the ice inside the cell 24. And the extracted ice falls into the lower basket (61). The torsional rotation of the ice tray 21 and the ice extraction process will be described in detail below. The stoppers 26 on both sides are connected to the front surface of the tray frame 25, respectively. As shown in FIG. 4, the front surface of the tray frame 25 is formed in a plate shape and enclosed like a castle wall, and is rounded and extended at one end of the left side.

The opening and closing handle 28 is formed at the bottom of the front surface of the tray frame 25, as shown in FIGS. 4 to 6. The opening/closing handle 28 has a width greater than enough to accommodate a person's hand and is formed to be long sideways. A groove a (29) is formed on the inner upper side of the opening/closing handle 28 so that a hand inserted through the opening/closing handle 28 can grip the front surface of the tray frame 25. So, by gripping the front surface of the tray frame 25, the ice making tray 20 can be opened and closed.

As shown in Figs. 4 and 9, the coupling bar a (25-1) is formed long in a bar shape on both outer surfaces of the tray frame 25. The coupling bar a (25-1) is coupled to the coupling lane a (53) to push the tray frame 25 to the ice-making frame 50 in a drawer manner to be coupled. The rear end of the coupling bar a (25-1) is formed so that the width becomes narrower and the end is sharp. So it can be easily coupled to the coupling lane a (53).

Hereinafter, the ice extracting member 30 will be described in detail.

As shown in FIGS. 2 to 10, the ice extracting member 30 pulls the protruding piece 31 protruding from one side of the ice tray 21 and the protruding piece 31 to turn the ice tray 21 over. It consists of a lever 40.

As shown in FIG. 8, the protruding piece 31 is disposed at a position eccentric to the center of the rotation shaft 23, and manipulates the protruding piece 31 to operate the ice tray 21 around the rotation shaft 23. ) Can be reversed. It consists of a protrusion piece 35 protruding upward from one edge of the ice tray 21 and a rail groove piece 32 protruding from the upper end of the protrusion piece 35 to the side.

The protrusion piece 35 is formed to protrude convexly in a finger shape from one edge of the ice edge. Therefore, the upper left and right sides of the protrusion piece 35 are smoothly rounded like a finger shape. In addition, the protrusion piece 35 is formed at an eccentric position from the center of the rotation shaft 23 of the ice tray 21. The protrusion piece 35 supports the rail groove piece 32 formed on the upper outer side.

The rail groove piece 32 is formed protruding from the upper end of the protrusion piece 35 to the outer side, that is, the opposite side corresponding to the ice tray 21, as shown in FIG. 8. The rail groove piece 32 is composed of a rail groove 33 protruding from the protrusion piece 35 and a guide 34 protruding from the rail groove 33 and extending its circumference.

The rail groove 33 protrudes in a cylindrical shape from the center of the outer side of the upper end of the protrusion piece 35. The rail groove 33 has a diameter smaller than the upper horizontal length of the protrusion piece 35. The rail groove 33 is disposed between the upper end of the protruding piece 35 and the guide 34, and contacts the rail 42 when the protruding piece 31 is fitted into the rail 42. Accordingly, the length of the rail groove 33 protruding outward is determined at a level at which the rail 42 of the lever 40 can be inserted and moved. If the length of the rail groove 33 is excessively longer than the width of the rail 42, since the interlocking of the ice tray 21 according to the operation of the lever 40 is not properly implemented, the length of the rail groove 33 is considered. Decide.

Guide 34 is formed protruding outward from the end of the rail groove (33). The guide 34 is formed in a cylindrical shape having a diameter larger than that of the rail groove 33. So, the protruding piece 31 is properly fitted to the rail 42 so that it can be moved.

The protruding piece 31 rises and moves on the rail 42 according to the operation of the lever 40, while rotating the ice tray 21 to turn it over, and while moving in the opposite direction, the protruding piece 31 descends on the rail 42 and descends the ice tray 21. To the original position.

Hereinafter, a process of implementing a torsional rotational motion of the ice tray 21 by manipulating the protruding piece 31 with the lever 40 and the lever 40, and extracting ice will be described in detail.

The lever 40 is accommodated in the ice making tray 20 and disposed on the side of the tray frame 25 as shown in FIGS. 1 to 7C and 10. When ice is generated in the ice tray 21, the lever 40 is interlocked with the ice tray 21 through the protruding piece 31, and the ice tray 21 is rotated and turned over.

As shown in Figure 10, the lever 40 is formed on the body 41, the body 41, the rail 42 for guiding the protruding piece 31, and the rail 42 further extends laterally. It consists of a supporting rail 46, a sliding piece 47 that forms a lower portion of the body 41 and makes sliding contact with the ice-making frame 50, and a handle 48 formed on the front surface of the body 41.

The body 41 has a square shape, and is slidably accommodated in the lever receiving portion 51 of the ice making frame.

The rail 42 is formed protruding laterally from the upper end of the rear end of the body 41. The rail 42 forms a gently rounded shape. The protruding piece 31 is fitted in the rail 42 to rotate the ice tray 21 while moving along the rail 42. The rail 42 includes a lower horizontal section 43 that starts rotation of the ice tray 21 and a vertical section 44 that is bent upward from the lower horizontal section 43 to gradually advance the rotation of the ice tray 21. ), and an upper horizontal section 45 formed by bending and extending laterally in the vertical section 44.

The lower horizontal section 43 forms the lower end of the rail 42, forms a short horizontal plane, and protrudes laterally from the upper end of the rear end of the body 41. At the lateral end of the lower horizontal section 43, an upwardly convex rail 1 (43-1) is formed, and is fitted into the rail groove piece 32 of the protruding piece 31. In the rail 1 (43-1) of the lower horizontal section 43, as shown in FIGS. 5 and 7A, the lever 40 is completely inserted into the ice-making frame 50 so that the ice tray 21 is attached to the tray frame 25. ) In a horizontally supported state, the protruding piece 31 is fitted and placed. So, when the lever 40 is pulled forward, the protruding piece 31 starts rotation of the ice tray 21 as it rises along the lower horizontal section 43. Subsequently, as the lever 40 is further pulled forward, the protruding piece 31 is moved to the vertical section 44.

The vertical section 44 is gently bent upward in the lower horizontal section 43 to form a vertical surface and protrude laterally. At the lateral end of the vertical section 44, a rail 2 (44-2) is formed by gently bending and extending from the rail 1 (43-1). The rotation of the ice tray 21 started in the lower horizontal section 43, as the lever 40 is further pulled forward, the protruding piece 31 rises on the rail 2 (44-2) of the vertical section 44. While going, the rotation of the ice tray 21 is gradually performed. Subsequently, as shown in FIG. 7B, as the lever 40 is further pulled forward, the protruding piece 31 is moved to the upper horizontal section 45.

The upper horizontal section 45 is formed by gently bending and extending laterally in the vertical section 44. The upper horizontal section 45 forms a short horizontal plane and protrudes laterally and is formed parallel to the lower horizontal section 43. At the lateral end of the upper horizontal section 45, a rail 3 (45-3) is formed by gently bending and extending from the rail 2 (44-2). The rotation of the ice tray 21 proceeded in the vertical section 44, as the lever 40 is further pulled, the protruding piece 31 passes the rail 2 (44-2) of the vertical section 44, and the upper horizontal section ( It is moved along rail 3 (45-3) of 45). When the protruding piece 31 is positioned at the end point of the rail 3 (45-3) of the upper horizontal section 45, the ice tray 21 is rotated 90 degrees and positioned vertically.

When the protruding piece 31 located at the end of the upper horizontal section 45 is pulled further, the protruding piece 31 is reversely lowered from the upper horizontal section 45 to the vertical section 44 and lowers the ice tray 21 to 90 Rotate more than degrees.

As the protruding piece 31 passes through the upper horizontal section 45 and descends back to the vertical section 44, the rotation of the ice tray 21 proceeds as shown in FIG. 7C, and one side of the edge of both sides of the ice tray 21 is It is stopped by hitting the stop protrusion 26-1 of the stopper 26.

When the rotation is stopped, the ice tray 21 is twisted while the protruding piece 31 is pulled, one side on which the protruding piece 31 is formed with respect to the rotation shaft 23 is pulled forward. Thus, ice generated in the cell 24 of the ice tray 21 is extracted and falls into the basket 61 at the bottom.

After the ice is extracted from the ice tray 21, the lever 40 pulled forward is inserted back into the ice making frame 50 to place it in its original position. Unlike the linkage with the ice tray 21 when the lever 40 is pulled forward, only the lever 40 is moved when the lever 40 is put back into the ice making frame 50 and the ice tray 21 is a stopper ( 26). Subsequently, the tray frame 25, that is, the ice tray 20 including the ice tray 21 is pulled forward and opened as if opening a drawer. After that, the ice tray 21 supported by the stopper 26 in a rotated state is manually placed back horizontally. Then, after filling the empty cells 24 of the ice tray 21 with water appropriately, the ice making tray 20 is pushed back into the ice making frame 50 so that ice can be generated.

As shown in FIG. 10, the support rail 46 is formed to extend laterally toward the front of the lever 40 in the lower horizontal section 43 of the rail 42. The support rail 46 protrudes laterally from one side of the body 41 to form a horizontal surface. The support rail 46 is formed to support and guide the protruding piece 31 when the tray frame 25, that is, the ice making tray 20, is opened and closed in a drawer manner in the state of FIGS. 5 and 7A.

The sliding piece 47 forms a lower portion of the body 41 as shown in FIGS. 6 and 10. The sliding piece 47 is formed in a rectangular plate shape with a narrow width. Therefore, the lever housing 51 of the ice making frame 50 is in linear contact and slides to minimize friction.

As shown in FIG. 10, the handle 48 is formed in front of the upper surface and the upper front surface of the body 41. The handle 48 is formed with a groove so that a finger can be inserted, so that the lever 40 can be pulled.

As described above, the present invention rotates the ice tray 21 by simply manipulating the protruding piece 31 formed on the ice tray 21 through the lever 40, thereby simplifying parts and reducing the cost of the manufacturing process. And the process of extracting and storing ice is easy and convenient. In addition, the lever 40 has a rectangular shape unlike the conventional operation lever 400 having a long rod shape, and when not operated, the lever 40 is completely inserted into the ice making frame 50 and does not have a part protruding to the outside. So there is no risk of injury, and aesthetic effects are also obtained.

Hereinafter, the ice making frame 50 will be described in detail.

As shown in FIGS. 1 and 5, the ice making frame 50 has a shape of U and is disposed behind the tray frame 25. Inside the ice-making frame 50, a tray frame 25, that is, an ice-making tray 20 including an ice tray 21, is inserted and coupled in a drawer manner. The ice-making frame 50 includes a lever receiving portion 51 in which the lever 40 is slidably accommodated, and a coupling lane a 53 formed on both inner sides of the ice-making frame 50 to which the tray frame 25 is coupled. , Protrusions a 54 are formed on both outer surfaces of the ice-making frame 50 to install the ice-making frame 50 on the refrigerator door 99.

The lever storage unit 51 is formed between the lever storage guide 52 inside the right side of the ice making frame 50 and the right side of the ice making frame 50 as shown in FIGS. 3 to 4. 4 shows a state in which the lever 40 is accommodated in the lever housing 51 of the ice making frame 50. The lever housing 51 is formed so that the lever 40 can be inserted to the rear surface of the ice-making frame 50, so that the lever 40 is slidably accommodated.

As shown in FIG. 4, one coupling lane a 53 is formed inside the left side of the ice making frame 50 corresponding to the left side of the lever storage guide 52. Therefore, the coupling bar a (25-1) is coupled to the coupling lane a (53) to couple the ice-making tray 20 to the ice-making frame (50). The coupling lane a (53) is formed of two horizontal bars, and the coupling bar a (25-1) is inserted into the space between the two horizontal bars to be coupled. At the front end of the coupling lane a (53), the upper horizontal bar is bent upward, and the lower horizontal bar is bent downward, thereby facilitating the coupling of the coupling bar a (25-1).

Protrusions a 54 are formed on the outer surfaces of both sides of the ice making frame 50 as shown in FIGS. 1 to 4. The protrusion a (54) is formed by protruding a narrow vertical surface from the outer surface of the ice making frame (50), and protruding from the upper end of the vertical surface to the rear side. The protrusion a 54 allows the ice-making frame 50 to be installed on the refrigerator door 99.

Hereinafter, the storage unit 60 disposed under the ice making unit 11 will be described in detail.

As shown in FIGS. 1 to 5, the storage unit 60 is disposed below the ice making unit 11 and installed on the refrigerator door 99. The storage unit 60 includes a basket 61 that receives and stores ice generated and extracted from the ice tray 21, and a storage frame 66 that is coupled to the basket 61 and installed on the refrigerator door 99. Done.

The basket 61 is disposed under the tray frame 25 and is formed to receive and store ice that is extracted from the ice tray 21 and dropped, as shown in FIGS. 1 to 6. The basket 61 is formed to include a wide storage space so that ice extracted from the ice tray 21 and falling does not escape outside the basket 61 and is contained in the basket 61. The middle-rear ends of the basket 61 are formed in a rectangular box shape so that they can be fitted into the storage frame 66 and ice is stored. The front end of the basket 61 is formed by extending to both sides longer than the horizontal length of the rear end of the basket 61, and both edges of the front end of the basket 61 are rounded gently. Further, a groove b 62 is formed under the front end of the basket 61 so that a hand can be inserted to grip the front surface of the basket 61. Put a hand in the groove b (62) to open and close the basket (61). And the basket 61 includes a coupling bar b (61-1) on the outer surface.

The coupling bar b (61-1) is formed long in a bar shape on both outer surfaces of the middle-rear end of the basket (61). The coupling bar b (61-1) is coupled to the coupling lane b (67) to push the basket (61) to the storage frame (66) in a drawer manner to be coupled. The rear end of the coupling bar b (61-1) is formed so that the width becomes narrower and the end is sharp. So it can be easily coupled to the coupling lane b (67).

The storage frame 66 is disposed behind the basket 61, as shown in FIGS. 1 to 5. And it has a shape of c and the front and top surfaces are open. A flat bottom surface is formed in the lower part. A basket 61 is inserted into the storage frame 66 in a drawer manner and coupled. The storage frame 66 is formed on both inner surfaces of the combination lane b 67 to which the basket 61 is coupled, and the ice-making frame 50 is formed on the outer surfaces of both sides of the ice-making frame 50 to provide the refrigerator door 99 It comprises a protrusion b (68) to be installed on.

As shown in FIG. 2, one coupling lane b 67 is formed on the inner side of both sides of the storage frame 66, respectively. Therefore, the coupling bar b (61-1) is coupled to the coupling lane b (67) to couple the basket (61) to the storage frame (66). The coupling lane b 67 is formed of two horizontal bars, and the coupling bar b 61-1 is inserted into the space between the two horizontal bars to be coupled. At the front end of the coupling lane b (67), the upper horizontal bar is bent upward, and the lower horizontal bar is bent downward, thereby facilitating the coupling of the coupling bar b (61-1).

Protrusions b 68 are formed on both outer surfaces of the storage frame 66 as shown in FIGS. 1 to 4. The protrusion b 68 is formed such that a narrow vertical surface protrudes from the outer surface of the storage frame 66, and the shape of a hook protrudes from the upper end of the vertical surface toward the rear side. The protrusion b 68 allows the storage frame 66 to be installed on the refrigerator door 99.

Hereinafter, the storage device 70 will be described in detail.

As shown in FIG. 1, the storage device 70 is disposed above the ice maker 10, that is, above the tray frame 25, so that food can be stored. The storage device 70 includes a storage case 71 for storing food, a storage frame 80 that is hingedly coupled to the storage case 71 to be installed on the refrigerator door 99, a storage case 71 and a storage frame ( It consists of a lid (90) covering the top of the 80). In addition, it further includes an opening and closing angle limiting member for limiting the opening and closing angle of the storage case 71 with respect to the storage frame 80.

The storage case 71 is disposed above the tray frame 25 and is hinged to the storage frame 80 as shown in FIGS. 11 and 12. The storage case has a case body 72 in which food is accommodated in a rectangular box shape as a whole, and a hinge 73 protruding from the lower outer surface of the front end of the case body 72 and coupled to the hinge groove 82, As an opening/closing angle limiting member, it consists of a bar 74 formed on the middle outer surface of the case body 72.

As shown in FIG. 12, the case body 72 is formed so that the front and rear and left and right sides are perpendicular to the bottom surface of a rectangular plate shape to form a rectangular box shape as a whole. The front surface of the case body 72 is formed at a height such that the front surface of the storage frame 80 can be covered when it is coupled to the storage frame 80. The rear surface of the case body 72 is formed to be about half the height of the front surface. The upper ends of the left and right sides of the case body 72 are formed horizontally from the rear end to the front end as shown in FIG. 5, and then gradually increase in height while drawing a rounded curve. Then, it is formed horizontally again and reaches the front end and is formed in a curved shape to the upper side of the front surface. A storage space is formed inside the case body 72, which is useful for storing frozen food.

As shown in FIG. 12, the hinge 73 is formed to protrude in a cylindrical shape under the left and right outer surfaces of the front end of the case body 72. The hinge 73 is inserted into the hinge groove 82 to hinge the storage case 71 to the storage frame 80. Thus, the storage case 71 is opened and closed by rotating the hinge 73 about the central axis, as shown in FIG. 11. The storage case 71 can be opened and closed by holding the upper end of the front surface by hand.

As shown in Fig. 12, the bar 74 is formed on the left and right outer surfaces of the case body 72 as an opening and closing angle limiting member. The bar 74 has a narrow bar shape, and is formed to be inclined toward the rear. The bar 74 is disposed inside the groove 81 of the storage frame 80 and pivots in accordance with the opening and closing of the storage case 71. Therefore, the bar 74 is caught on the front and rear sides of the groove 81, thereby limiting the opening and closing angle of the storage case 71.

As shown in FIG. 11, a handle groove 91 is formed at the front end of the lid 90 on the upper side of the storage case 71 so that the upper end of the front surface of the storage case 71 can be easily gripped. When the front surface is pulled to open the storage case 71, the storage case 71 rotates about the hinge 73 inserted in the hinge groove 82 about the central axis. At the same time, the bottom surface of the storage space is lifted upward and forms an inclined shape. Thus, the storage case 71 is opened and closed to accommodate food. Since the ice maker 10 for generating ice is located under the storage case 71, food that needs to be stored at a low temperature can be easily stored.

The storage frame 80 is disposed behind the storage case 71 as shown in FIGS. 11 and 13. In addition, it has a c shape and the front and top-bottom sides are open. The storage case 71 is hinged to the storage frame 80. The storage frame 80 is formed on the lower left and right inner surfaces of the hinge groove 82 to which the hinge 73 is coupled, and the bar 74 is formed on the left and right inner surfaces of the storage frame 80 as an opening and closing angle limiting member. The revolving groove 81, the holder 83 formed along the lower rim of the storage frame 80 to mount the storage case 71, and the storage frame 80 formed on the left and right outer surfaces of the storage frame 80 ) Is formed to include a protrusion c (84) for installing the refrigerator door (99).

The hinge groove 82 is formed under the left and right inner surfaces of the front end of the storage frame 80. The hinge groove 82 has a cylindrical shape, and the hinge 73 of the storage case 71 is inserted and coupled. So, as described above, the storage case 71 is opened and closed around the hinge 73.

The groove 81 is an opening/closing angle limiting member and is located above the left and right inner surfaces of the storage frame 80. The groove 81 is formed in a fan shape, and a bar 74 is disposed therein to rotate. The upper and lower surfaces of the groove 81 are formed in parallel in a curved arc shape. The front and rear sides are formed to have a length that can be rotated by the bar 74 is disposed. When the storage case 71 is opened, the bar 74 is caught on the front side of the groove 81 and the opening angle is limited. When the storage case 71 is closed, the bar 74 is placed on the rear side of the groove 81. The opening angle is limited.

As described above, the groove 81 and the bar 74 form a pair as an opening/closing angle limiting member, thereby limiting the opening/closing angle of the storage case 71. Therefore, it allows the storage case 71 to be properly opened and closed to store food.

The cradle 83 is formed along the lower edge of the storage frame 80. Therefore, it is formed to extend into the interior of the storage frame 80 from the left and right sides and the lower side of the rear surface, and has a U shape. Since food is stored in the storage case 71, it is not appropriate to support the weight of the storage case 71 only with the bar 74, which is an opening and closing angle limiting member. Even if a lot of food is stored in the storage case 71 through the cradle 83, it can be properly supported.

The protrusions c 84 are formed on the left and right outer surfaces of the storage frame 80. The protrusion c 84 is formed by protruding a narrow vertical surface from the outer surface of the storage frame 80, and the shape of a hook protruding from the upper end of the vertical surface toward the rear side. The protrusion c 84 allows the storage frame 80 to be installed on the refrigerator door 99.

As shown in FIGS. 1 and 11, the lid 90 is installed above the storage frame 80 to cover the storage frame 80 and the storage case 71. The lid is formed to be installed on the storage frame 80, and comprises a handle groove 91 at the tip of the lid 90. The handle groove 91 makes it possible to open and close the storage case 71 by easily gripping the upper end of the front surface of the storage case 71.

The present invention is not limited to the specific preferred embodiments described above, and any person of ordinary skill in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims can implement various modifications. Of course, it is added that such changes will fall within the scope of the claims description.

1: ice maker assembly for refrigerator 10: ice maker
11: ice making unit 20: ice making tray
21: ice tray 22: ice body
23: rotary shaft 24: cell
25: tray frame 25-1: coupling bar a
26: stopper 26-1: stop protrusion
27: support groove 28: opening and closing handle
29: groove a 30: ice extracting member
31: protruding piece 32: rail groove piece
33: rail groove 34: guide
35: projection piece 40: lever
41: body 42: rail
43: lower horizontal section 43-1: rail 1
44: vertical section 44-2: rail 2
45: upper horizontal section 45-3: rail 3
46: support rail 47: sliding piece
48: handle 50: ice making frame
51: lever storage unit 52: lever storage guide
53: coupling lane a 54: projection a
60: storage unit 61: basket
61-1: coupling bar b 62: groove b
66: storage frame 67: combined lane b
68: protrusion b 70: storage device
71: storage case 72: case body
73: hinge 74: bar
80: storage frame 81: groove
82: hinge groove 83: cradle
84: protrusion c 91: handle groove
99: refrigerator door

Claims (5)

An ice tray including an ice tray on which a rotation axis is formed and a tray frame on which the rotation axis of the ice tray is supported;
A protruding piece protruding from one side of the ice tray, and a lever for pulling the protruding piece over the ice tray,
The protruding piece is disposed at a position eccentric with respect to the center of the rotation axis,
And an ice making frame to which the ice making tray is inserted and coupled in a drawer manner,
The lever is slidably received in a lever receiving portion formed in the ice-making frame and can be inserted without a portion protruding to the outside,
As the lever is pulled forward and slid, the protruding piece is pulled by the lever to rotate the ice tray.
The method according to claim 1,
The lever is an ice maker assembly for a refrigerator comprising a body, a handle formed on a front surface of the body, and a rail formed on the body to guide the protruding piece.
The method according to claim 2,
The rail includes a lower horizontal section for starting rotation of the ice tray, a vertical section extending upward in the lower horizontal section to gradually advance the rotation of the ice tray, and an upper side formed by bending and extending laterally in the vertical section Ice maker assembly for a refrigerator consisting of a horizontal section.
The method of claim 3,
An ice maker assembly for a refrigerator further comprising a support rail extending laterally in the lower horizontal section to support and guide the protruding piece when the tray frame is opened or closed.
The method according to any one of claims 1 to 4,
Ice maker assemblies for refrigerators having stoppers formed on both sides of the tray frame to twist the ice tray while stopping rotation.

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