KR20070096552A - An ice maker for refrigerator - Google Patents

Abstract

An ice maker for refrigerator is provided to prevent damage of product by rotating a lever holder by a predetermined angle to a gear unit. An ice maker for refrigerator comprises an ice maker body(51), ice bank(B), a holder assembly(60), a ice detection lever(90). The ice maker makes ice and an ejector for withdrawing out the ice is rotatably installed in a predetermined angle. The ice bank is installed under the ice maker body so as to be withdrawn out and accepted and stores ice with drawn by the ejector. The holder assembly is formed at the one side of the ice maker body, and includes a gear part rotating in a predetermined angle with rotation of the ejector, a lever holder reversely rotating in a predetermined angle to the gear part and an elastic member applying an elastic force in a predetermined direction to the gear part in the lever holder. The ice detection lever is fixed to the lever holder, and rotated at predetermined angle in the inside/outside of the ice bank according to rotation of the holder assembly, and detects an ice amount stored in ice bank. When an external force of the ice detection lever is applied at a position for detecting the ice amount stored in the ice bank, the lever holder and ice detection lever overcome the elastic force of the elastic member and is rotated within a predetermined angle range to the gear part.

Description

Ice maker for refrigerator {An ice maker for refrigerator}

1 is a perspective view showing an ice maker for a refrigerator according to the prior art.

2 is a perspective view showing the lever holder shown in FIG.

Figure 3 is a perspective view showing a preferred embodiment of the icemaker for a refrigerator according to the present invention.

4 is an exploded perspective view showing the holder assembly constituting the embodiment shown in FIG.

FIG. 5 is a cross-sectional view showing a holder assembly constituting the embodiment shown in FIG. 3. FIG.

6A to 6F are operation state diagrams showing a process of detecting the amount of ice according to the embodiment shown in FIG.

Explanation of symbols on the main parts of the drawings

50: ice maker 51: ice maker

51a: mounting flange 53: ejector

53a: ejector shaft 55: stripper

57: water supply hopper 59: housing

59a: mounting plate 59h: through hole

60: holder assembly 61: gear unit

71: seating opening 73: guide opening

75,77: engaging jaw 79: spring insertion hole

80: lever holder 81: guide rib

83: fixing hole 85: fastening hook

87: stopper 89: spring insertion hole

90: detection lever 91: fixed part

91: ice detection unit S: torsion spring

The present invention relates to a refrigerator, and more particularly, to a refrigerator ice maker provided in the refrigerator to manufacture ice.

Recently, a refrigerator equipped with an ice maker for manufacturing ice and supplying it to a user is commercially available. 1 shows an ice maker for a refrigerator according to the prior art.

As shown therein, the ice making body 11 of the ice maker 10 is formed long in the longitudinal direction. An ice making tray (not shown) is provided inside the ice making body 11. The ice making tray is a place where the ice is substantially produced by receiving water from the water supply hopper 17 to be described below. In addition, a pair of mounting flanges 11a for installing the ice maker 10 in the refrigerator are provided on one longitudinal direction of the ice making body 11.

On the other hand, the ejector 13 is provided on the upper portion of the ice making body 11 corresponding to the upper side of the ice making tray. The ejector 13 is provided with a plurality in the longitudinal direction of the ice making body (11). The ejector 13 serves to draw the ice produced in the ice making tray to the outside of the ice making body 11. To this end, the ejector 13 is rotated up and down in a predetermined angle range around the ejector shaft 13a provided in the longitudinal direction of the ice making body 11.

The stripper 15 is provided on an upper surface of the longitudinal direction of the ice making body 11. The stripper 15 is provided in plural number alternately with the ejector 13 in the longitudinal direction of the ice making body (11). The stripper 15 guides the ice drawn out to the outside by the ejector 13 and prevents the extracted ice from being re-introduced into the ice making body 11 again.

In addition, although not shown, the ice bank is installed to be retractable under the ice-making body (11). Ice is stored in the ice bank. The ice bank is withdrawn in parallel in a direction perpendicular to the longitudinal direction of the ice making body (11).

The ice-making main body 11 has a water supply hopper 17 at one end thereof. The water supply hopper 17 is for transferring water supplied from an external water supply source to the ice making tray, and is located above the ice making tray. One end of the water supply hopper 17 is fixed to one end of the water supply tube (not shown) connected to the water supply source.

The housing 19 is provided at the other end of the ice making body 11 corresponding to the opposite side of the feed hopper 17. One side of the housing 19 is provided with a switch (sw) for turning on / off the power of the ice maker (10). Inside the housing 19, a printed circuit board p, on which various electrical components including a sensor hole are installed, is installed. In addition, the inside of the housing 19 is provided with a mounting plate (19a) for installing various components for the operation of the ice maker (10). For example, the mounting plate 19a may include a controller (not shown) for controlling the operation of the ice maker 10, a driving motor m for providing a driving force, and the lever holder 20 to be described below. A lever l, a gear g, and the like for transmitting the driving force of the motor m are provided. And a magnet is provided on one side of the lever (1).

The lever holder 20 is provided inside the housing 19. The lever holder 20 is formed long in the longitudinal direction. The lever holder 20 has support holes formed in the through hole 19h and the mounting plate 19a, both ends of which are formed at one surface of the housing 19 adjacent to one end of the ice making body 11. (Not shown) to be rotatably supported.

As shown in detail in FIG. 2, a gear part 21 is provided at one side of the outer circumferential surface of the lever holder 20. The gear part 21 is meshed with the gear g provided in the housing 19. Therefore, the lever holder 20 is rotated by the drive motor.

In addition, a fixing hole 23 is formed at one end of the lever holder 20 penetrating the through hole. Therefore, the fixing hole 23 is opened to the outside in a state where one end of the lever holder 20 passes through the through hole. The fixing hole 23 is where the detection lever 30 is inserted.

The ice detection lever 30 is for detecting the amount of ice stored in the ice bank. The sensing lever 30 includes a fixing part 31 inserted into and fixed to the fixing hole 23, and an sensing part 33 extending from one end of the fixing part 31 to have an L shape. . Accordingly, the detection part 30 is positioned horizontally parallel to the length direction of the ice making body 11 while the fixing part 31 is inserted into and fixed to the fixing hole 23. do.

When the lever holder 20 rotates, the detection lever 30 rotates the detection unit 33 around the fixing unit 31 in a predetermined angle range to the inside and outside of the ice bank. That is, before the ejector 13 withdraws the ice, the inspection lever 30 is located outside the ice bank. When the ejector 13 rotates upwardly with respect to the ejector shaft 13a to extract ice, the detection lever 30 and substantially the detection unit 33 are centered on the fixed part 31. Rotate downwards to the inside of the ice bank.

Hereinafter, according to the ice maker for a refrigerator according to the prior art, the ejector 13 is rotated by the control unit to extract the ice produced from the ice tray. At the same time as the ejector 13 rotates, the lever 1 rotates to rotate the gear g. Therefore, the gear part 21 geared to the gear g is rotated so that the inspection lever 30 rotates downward toward the inside of the ice bank.

By the way, in a state where more than a predetermined amount of ice is stored in the ice bank, the rotation of the ice detection lever 30 is prevented by the ice so that the lever 1 cannot rotate to a predetermined position. In this state, the driving of the driving motor m is stopped because the sensor hole provided in the printed circuit board p does not detect the magnetic force of the magnet provided in the lever 1. Therefore, the rotation of the ejector 13 is also stopped so that the ice produced by the ice tray is no longer drawn out.

However, the refrigerator ice maker according to the related art has the following problems.

As described above, the detection lever 30 is rotated in and out of the ice bank by receiving the driving force of the driving motor to detect the amount of ice. Therefore, when the ice bank is accommodated in the state in which the inspection lever 30 is rotated downward, an external force acts on the inspection lever 30 by the ice bank. In this way, the gear or the gear 21 may be removed or an overload acts on the driving motor by an external force acting on the detection lever 30, thereby causing damage to the product.

The present invention is to solve such a conventional problem, it is an object of the present invention to provide an ice making apparatus for a refrigerator configured to prevent the phenomenon that the product is damaged.

According to a feature of the present invention for achieving the above object, the present invention is an ice making body, the ejector for ejecting the produced ice is installed in a predetermined angle range rotatably; An ice bank installed at a lower side of the ice making body and storing ice drawn out by the ejector; It is provided on one side of the ice making body, the gear unit to rotate in a predetermined angle range in conjunction with the rotation of the ejector, and the lever holder to rotate relative to the gear unit in a predetermined angle range in relation to the gear portion and the lever holder A holder assembly composed of an elastic member for imparting an elastic force in a predetermined direction to the gear portion; And a detection lever fixed to the lever holder and rotating the holder assembly in and out of the ice bank at a predetermined angle to detect an amount of ice stored in the ice bank. And an external force acting on the sensing lever at a position for detecting the amount of ice stored in the ice bank, the lever holder and the sensing lever overcome the elastic force of the elastic member and are predetermined with respect to the gear part. Rotate in the angle range of.

A circular seating opening is formed to penetrate the inside of the gear unit in a rotational axis direction, and the lever holder is formed in a cylindrical shape having a diameter corresponding to the seating opening, and is installed through the seating opening.

A portion of the outer peripheral surface of the seating opening is provided with a guide opening formed radially extending in a fan shape having a predetermined central angle, and one side of the outer peripheral surface of the lever holder penetrates the guide opening in a state of the guide opening. A guide rib moving in an arc shape is provided, and the lever holder is rotated with respect to the gear part in a range in which the guide rib moves in an arc shape along the guide opening.

One end of the lever holder is formed with a fixing hole into which one end of the sensing lever is inserted, and the other end of the lever holder corresponding to the opposite side of the fixing hole prevents the lever holder from being removed while passing through the seating opening. A fastening hook is provided, and a stopper is provided at one side of the outer circumferential surface of the lever holder adjacent to the fixing hole to prevent the lever holder from completely penetrating the seating opening while the lever holder penetrates the seating opening. do.

The elastic member is installed on an outer circumferential surface of the lever holder corresponding to one surface of the gear portion and the stopper, and both ends of the elastic member are fixed to one side of the gear portion and one side of the lever holder, respectively. The lever is characterized in that the torsion spring to give an elastic force in the direction opposite to the rotating direction to detect the amount of ice stored in the ice bank.

According to the present invention as described above there is an advantage that it is possible to prevent the product from being damaged by the external force acting on the ice detection lever by the withdrawal of the ice bank.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the refrigerator ice maker according to the present invention will be described in more detail.

3 illustrates a preferred embodiment of the icemaker for a refrigerator according to the present invention, and FIGS. 4 and 5 show a holder assembly constituting the embodiment shown in FIG. 3.

As shown therein, the ice making body 51 of the ice maker 50 is installed in the refrigerator to manufacture ice. The ice making body 51 is formed long in the longitudinal direction. An ice making tray (not shown) in which ice is substantially manufactured is provided inside the ice making body 51. In addition, a mounting flange 51a is provided on one longitudinal surface of the ice making body 51. The mounting flange 51a is for fixing the ice maker 50 to a refrigerator.

An ejector 53 is provided on an upper portion of the ice making body 51. The ejector 53 is provided with a plurality of ejector shafts (53a) are provided long in the longitudinal direction of the ice making body (51). The ejector 53 rotates about a predetermined angle range around the ejector shaft 53a to take out ice produced in the ice making tray.

In addition, a plurality of strippers 55 are provided on an upper surface of the longitudinal direction of the ice making body 51. The stripper 55 is provided in the longitudinal direction of the ice making body 51 alternately with the ejector 53. The stripper 55 serves to guide the ice drawn out by the ejector 53 to an ice bank (not shown). At the same time, the stripper 55 also serves to prevent the ice drawn out by the ejector 53 from being introduced into the ice making body 51.

On the other hand, the ice bank is installed in the lower side of the ice making body 51 to be withdrawn. The ice bank is withdrawn in parallel in the direction orthogonal to the longitudinal direction of the ice making body (51). And the ice drawn by the ejector 53 is stored in the ice bank.

In addition, a water supply hopper 57 is provided at one end of the ice making body 51. The water hopper 57 stores water supplied from an external water supply source. And the water stored in the feed hopper 57 is delivered to the ice tray is made of ice. To this end, the water supply hopper 57 is located above the ice tray, and one side of the water supply hopper 57 is connected to one end of a water supply tube (not shown) connected to the water supply source.

A housing 59 is provided at the other end of the ice making body 51 corresponding to the opposite side of the feed hopper 57. A switch SW is installed at one side of the housing 59. The switch SW is for turning on / off the power of the ice maker 50. In addition, the housing 59 is provided with a printed circuit board P on which various electrical components including a sensor hole are installed. The housing 59 includes a driving motor M, a lever L provided with a magnet, and a mounting plate 59a provided with a plurality of gears G and the like. Since the internal structure of the housing 59 is the same as in the related art, a detailed description thereof will be omitted.

Further, through-holes 59h and support holes (not shown) are formed on one surface of the housing 59 adjacent to the ice making body 51 and one side of the mounting plate 59a corresponding to each other. The through hole 59h and the support hole are for supporting the lever holder 70 to be described below.

Meanwhile, the holder assembly 60 is installed inside the housing 59. The holder assembly 60 serves to rotate the inspection lever 90 to be described below to the inside and outside of the ice tray in a predetermined angle range. The holder assembly 60 is composed of a gear unit 70, a lever holder 80, and a torsion spring (S).

The gear unit 70 is geared with the gear G to rotate in a predetermined angle range by the drive motor. At this time, the gear unit 70 is configured to rotate in a direction opposite to the rotation direction of the ejector shaft 53a about the lever holder 80. The gear unit 70 rotates in a range such that the ice detection lever 90 is positioned inside or outside the ice tray.

As shown in detail in FIGS. 4 and 5, a circular seating opening 71 is provided in the gear unit 70. The seating opening 71 is opened in the rotational axis direction of the gear unit 70, that is, in the longitudinal direction of the lever holder 80. The lever holder 80 is installed at the seating opening 71.

In addition, the guide opening 73 is provided inside the gear unit 70 corresponding to the outer circumferential surface of the seating opening 71. The guide opening 73 is formed by extending a radial portion of the outer peripheral surface of the seating opening 71 in a fan shape having a predetermined center angle. The guide opening 73 serves to guide the guide rib 81 to be described below.

On the other hand, the guide opening 73 is formed in a fan shape having a relatively large diameter compared to the upper seating opening 71. Therefore, both side boundary portions of the seating opening 71 and the guide opening 73 having different diameters are formed stepped with each other in a direction toward the center thereof. In the following, the stepped gap is referred to as a locking jaw at both sides of the seating opening 71 and the inner opening 73. In this case, the upper one in the drawing in FIG. 4 is referred to as the first locking jaw 75 and the lower one in the drawing is referred to as the second locking jaw 77.

And a spring insertion hole 79 is formed on one side of the gear portion 70. The spring insertion hole 79 of the gear part 70 is a place where one end of the torsion spring S passes. The spring insertion hole 79 of the gear portion 70 is a part of the gear portion 70 adjacent to the seating opening 71 and the guide opening 73 and the seating opening 71 and the guide opening 73 and It is formed through the same direction, that is, the longitudinal direction of the lever holder 80.

The lever holder 80 is installed through the seating opening 71 of the gear unit 70. The lever holder 80 is formed in a cylindrical shape having a diameter corresponding to the seating opening 71. Both ends of the lever holder 80 are rotatably supported by the through hole 59h and the support hole while penetrating through the seating opening 71. The lever holder 80 is rotated relative to the rotation of the gear unit 70 or relative to the gear unit 70 in a predetermined angle range.

Guide ribs 81 are provided on one side of the outer circumferential surface of the lever holder 80. The guide rib 81 protrudes radially from the outer peripheral surface of the lever holder 80 by a predetermined length. The guide rib 81 is positioned inside the guide opening 73 in a state where the lever holder 80 passes through the seating opening 71. When the lever holder 80 is rotated relative to the gear part 70, the guide rib 81 is disposed between the first locking jaw 75 and the second locking jaw 77. 73 serves to limit the rotational range of the lever holder 80 by moving in an arc.

A fixing hole 83 is formed at one end of the lever holder 80 penetrating the through hole 59h. The fixing hole 83 is formed long in the longitudinal direction of the lever holder (80). The fixing hole 83 penetrates the through hole 59h and is exposed to the outside. The fixing part 91 of the detection lever 90 is inserted into and fixed to the through hole 59h.

A fastening hook 85 is provided at the other end of the lever holder 80 corresponding to the opposite side of the fixing hole 83, that is, the other end of the lever holder 80 penetrating the support hole. The fastening hook 85 is configured in pairs and has a predetermined elasticity in a direction orthogonal to the longitudinal direction of the lever holder 80. The fastening hook 85 is caught on the rear surface of the mounting plate 59a in a state where it penetrates the support hole, so that one end of the lever holder 80 may not be arbitrarily removed in a state where it is supported through the support hole. It plays a role.

In addition, a stopper 87 is provided at one side of the outer circumferential surface of the lever holder 80 adjacent to one end of the lever holder 80 in which the fixing hole 83 is formed. That is, the stopper 87 is substantially positioned between one end of the lever holder 80 and one surface of the gear unit 70. The stopper 87 extends radially from one side of the outer circumferential surface of the lever holder 80. The stopper 87 serves to prevent the lever holder 80 from completely penetrating the seating opening 71 while the lever holder 80 is installed to penetrate the seating opening 71.

A spring insertion hole 89 is formed at one side of the stopper 87. The spring insertion hole 89 of the lever holder 80 is a portion through which the other end of the torsion spring S penetrates the spring insertion hole 79 of the gear part 70. The spring insertion hole 89 of the lever holder 80 penetrates in the longitudinal direction of the lever holder 80 in the same manner as the spring insertion hole 79 of the gear part 70.

Meanwhile, the torsion spring S is installed on the outer circumferential surface of the lever holder 80. The torsion spring S imparts an elastic force to the lever holder 80 in a predetermined direction with respect to the gear unit 70 and in a clockwise direction in FIG. 3. To this end, both ends of the torsion spring S are bent at a predetermined angle in the state of penetrating the spring insertion hole 79 of the gear part 70 and the spring insertion hole 89 of the lever holder 80, respectively. It is supported on one surface of the gear portion 70 or one surface of the stopper 87 of the lever holder (80).

In addition, the lever holder 80 is fixed to the ice detection lever 90. The detection lever 90 is for detecting the amount of ice stored in the ice bank. To this end, the detection lever 90 rotates inside and outside the ice bank when the lever holder 80 rotates.

The sensing lever 90 is composed of a fixing part 91 and the sensing part 93. The fixing part 91 is inserted into the fixing hole 83. In this case, the fixing unit 91 is bent in a predetermined shape to have elasticity so that the fixing unit 91 is not detached in the state inserted into the fixing hole 83. In addition, the detection part 93 is formed in an L-shape as a whole by being bent two times orthogonally at the tip of the fixing part 91. The ice detector 93 is a portion that substantially detects the amount of ice by rotating the ice bank B around the fixing unit 91.

Hereinafter, a process of detecting the amount of ice stored in the ice bank by the preferred embodiment of the refrigerator ice maker according to the present invention will be described in more detail with reference to the accompanying drawings.

6A to 6F illustrate a process of detecting the amount of ice according to a preferred embodiment of the refrigerator ice maker according to the present invention.

As shown in FIG. 6A, in the state in which the ejector 53 does not extract the ice produced from the ice tray, the guide rib 81 of the lever holder 80 is engaged with the first locking jaw 75 of the gear unit 70. ) Is in close contact. At this time, the lever holder 80 is subjected to the elastic force in the clockwise direction on the drawing by the torsion spring (S). In addition, the detection lever 90 fixed to the lever holder 80 is located outside the ice bank (B).

In this state, when the ejector 53 rotates to extract ice, the gear unit 70 rotates counterclockwise in the drawing as shown in FIG. 6B in conjunction with this. Therefore, the first locking jaw 75 pushes the guide rib 81, so that the lever holder 80 also rotates counterclockwise in the drawing in conjunction with the rotation of the gear unit 70. Since the gear unit 70 and the lever holder 80 rotate at the same time, no external force is applied to the torsion spring S. In addition, by the rotation of the lever holder 80, the detection lever 90 is rotated counterclockwise in the drawing is positioned inside the ice bank (B).

In the state where the ejector 53 is continuously rotated and the ice is completely drawn out, the gear part 70 and the lever holder 80 are positioned as shown in FIG. 6C. That is, the gear unit 70 and the lever holder 80 are rotated by a predetermined angle in the counterclockwise direction in the state shown in FIG. 6A.

On the other hand, as shown in Figure 6d, the ejector 53 may be rotated to withdraw the ice in the state in which the ice bank (B) is drawn out. Accordingly, the gear unit 70, the lever holder 80, and the detection lever 90 are rotated or rotated counterclockwise in the drawing as illustrated in FIG. 6B. That is, the inspection lever 90 is placed at a position corresponding to the inside of the ice bank B in a state where the ice bank B is accommodated.

In this state, as shown in FIG. 6E, when the ice bank B is moved to the right in the drawing and stored, the sensing lever 90 is moved to the right in the drawing by the ice bank B. It is pushed. Therefore, the detection lever 90 is rotated counterclockwise in the drawing. In addition, the lever holder 80 to which the detection lever 90 is fixed also rotates counterclockwise on the drawing.

At this time, the gear unit 70 does not rotate in a fixed state. That is, the lever holder 80 is rotated relative to the gear unit 70 in the counter-direction in the drawing. The guide rib 81 moves circumferentially in the counterclockwise direction along the guide opening 73. In addition, the torsion spring S begins to be compressed by the rotation of the lever holder 80.

In this case, the lever holder 80 has the guide rib 81 on the second locking jaw 77 of the gear unit 70 according to the size of the ice bank B and the relative angle of the detection lever 90. It can be rotated to a close range. And the torsion spring (S) will be in the maximum compressed state by the relative rotation of the lever holder 80 with respect to the gear unit 70.

Next, as shown in FIG. 6F, when the ice bank B moves to the right in the drawing and reaches a predetermined position, for example, a position at which the side and the inspection lever 90 are separated from each other, The lever holder 80 is rotated in the clockwise direction on the drawing by the elastic force of the torsion spring (S). At this time, the guide rib 81 moves circumferentially in the clockwise direction along the guide opening 73 in a state of being in close contact with the first locking jaw 75 and is in close contact with the second locking jaw 77. . In addition, the detection lever 90 also rotates clockwise in the drawing by the rotation of the lever holder 80. As a result, the detection lever 90 is located outside the ice bank B, i.e., as shown in FIG. 6A, which does not interfere with the withdrawal of the ice bank B.

Within the scope of the basic technical spirit of the present invention as well as many other modifications are possible to those skilled in the art, the scope of the present invention should be interpreted based on the appended claims. .

In the ice making device for a refrigerator according to the present invention configured as described above, the ice detection lever for rotating the inside and outside of the ice bank to detect the amount of ice is interlocked with the gear part receiving the driving force of the driving motor or in a predetermined angle range with respect to the gear part. It is fixed to the rotating lever holder. Therefore, according to the present invention, even if an external force acts on the detection lever, the lever holder rotates in a predetermined angle range with respect to the gear part, thereby preventing damage to the product and also ensuring operational reliability of the product. Will be.

Claims (5)

An ice making body, on which ice is manufactured and an ejector for extracting the manufactured ice is rotatably installed in a predetermined angle range; An ice bank installed at a lower side of the ice making body and storing ice drawn out by the ejector; It is provided on one side of the ice making body, the gear unit to rotate in a predetermined angle range in conjunction with the rotation of the ejector, and the lever holder to rotate relative to the gear unit in a predetermined angle range in relation to the gear portion and the lever holder A holder assembly composed of an elastic member for imparting an elastic force in a predetermined direction to the gear portion; And An ice detection lever fixed to the lever holder and configured to detect an amount of ice stored in the ice bank by rotating the holder assembly in a predetermined angle range in and out of the ice bank; It is configured to include, When an external force acts on the detection lever at a position for detecting the amount of ice stored in the ice bank, the lever holder and the detection lever rotate in a predetermined angle range with respect to the gear part while overcoming the elastic force of the elastic member. Refrigerator ice maker, characterized in that. The method of claim 1, A circular seating opening penetrating the inside of the gear portion in the direction of the rotation axis is formed, The lever holder is formed in a cylindrical shape having a diameter corresponding to the seating opening is provided for penetrating through the seating opening. The method of claim 2, Inside the gear portion is provided with a guide opening which is formed to extend radially in a fan shape having a portion of the outer peripheral surface of the seating opening having a predetermined center angle, One side of the outer circumferential surface of the lever holder is provided with a guide rib moving through the guide opening in an arc shape of the guide opening in a state, And the lever holder rotates with respect to the gear part in a range in which the guide rib moves in an arc shape along the guide opening. The method of claim 2 or 3, One end of the lever holder is formed with a fixing hole into which one end of the sensing lever is inserted, The other end of the lever holder corresponding to the opposite side of the fixing hole is provided with a fastening hook for preventing the lever holder from being removed in the state passing through the seating opening, And a stopper provided at one side of the outer circumferential surface of the lever holder adjacent to the fixing hole to prevent the lever holder from completely penetrating the seating opening while the lever holder penetrates the seating opening. The method of claim 4, wherein The elastic member is installed on an outer circumferential surface of the lever holder corresponding to one surface of the gear portion and the stopper, and both ends thereof are fixed to one side of the gear portion and one side of the lever holder, respectively, and the sensing part with respect to the gear portion in the lever holder. And a torsion spring for which a lever imparts an elastic force in a direction opposite to the direction of rotation to detect the amount of ice stored in the ice bank.

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