KR100518807B1 - apparatus for ice making machine - Google Patents

Abstract

A support frame rotatably installed at an upper portion of the ice storage tank provided inside the ice maker body; A base frame supported by the support frame and pivoted together with the support frame, the upper frame having a plurality of ice-water grooves filled with ice-making water in which cooling projections of the cooling plate are locked; And an ice level detecting unit installed in the base frame or the support frame to detect the fullness of the ice in the ice storage tank when the support frame and the base frame are rotated to drop the ice frozen in the cooling protrusion into the ice storage tank. An ice maker of an ice maker is disclosed.

Description

Ice making machine of ice maker {apparatus for ice making machine}

The present invention relates to an ice making level sensing device of an ice maker.

An ice maker is an apparatus for making ice by cooling supplied ice making water, and FIG. 1 shows a conventional ice maker disclosed in Korean Patent No. 1002152894.

Referring to FIG. 1, a conventional ice maker includes a case 10 and an ice making unit 20.

Inside the case 10 is provided with an ice reservoir 11 for storing the ice made in the ice making unit 20. A refrigeration system 30 including a compressor 31 and a condenser 32 is installed below the ice reservoir 11. In addition, the case 10 is connected to a water supply pipe 12 for supplying water to the ice making unit 20 and a drain pipe 13 for discharging water not frozen in the ice making unit 20 to the outside of the ice maker body 10. do. The water supply pipe 12 is installed to extend from the water supply equipment (not shown) to the ice making unit 20, and the drain pipe 13 is installed to extend from the water collecting portion 14 installed in the ice reservoir 11 to the drainage equipment not shown. .

As shown in FIG. 2, the ice making unit 20 includes a water plate 21 filled with water, a cooling plate 22, and an evaporation tube 23. The water plate 21 is connected to the support member 25 rotatably supported by the pivot shaft 24, and the oscillation plate 26 is installed therein. The support member 25 is rotated about the pivot shaft 24 by the swing motor AM to incline the water dish 21 in one direction to discharge the water remaining in the water dish 21. The swinging plate 26 swings up and down by the swinging motor RM to swing the water in the water plate 21 to remove bubbles in the water. One side of the water plate 21 is provided with a drain guide plate 27 for guiding the water discharged from the water plate 21 to the water collecting unit 14.

The lower portion of the cooling plate 22 is provided with a plurality of cooling projections 28 that are immersed in the water to grow ice around it.

The evaporation tube 23 is installed on the upper surface of the cooling plate 2 and connected to the refrigeration system 30. A refrigerant flows into the evaporation tube 23, and the cooling plate 22 and the cooling protrusion 28 are cooled by heat exchange of the refrigerant.

According to the above structure, water freezes around the cooling projection 28 cooled below the freezing point by heat exchange of the refrigerant. After the ice having a predetermined size is formed around the cooling protrusion 28, the high-temperature refrigerant discharged from the compressor 31 is directly supplied into the evaporation tube 23 without passing through the condenser 32. Remove from (28). The water plate 21 is inclined about the pivot shaft 24 together with the support member 25 by the swing motor AM. Thus, the generated ice falls into the ice reservoir 11 and the water remaining without freezing in the water dish 21 is discharged to the drainage facility through the drain pipe 13.

By repeating this ice making operation, the ice maker 11 is operated so that a predetermined amount of ice is always stored in the ice reservoir 11. Therefore, an ice level detection device is required to detect whether the ice is full in the ice reservoir 11 and to stop the ice making operation.

The present invention has been made to solve the above problems, and an object thereof is to provide an ice level sensor of an ice maker that can detect the ice level in the ice storage.

Ice maker according to the present invention for achieving the above object, the ice maker body is provided with an ice storage tank therein; A support frame installed on the ice storage tank so as to be rotated at a predetermined angle; A base frame supported by the support frame and pivoted together with the support frame, the upper frame having a plurality of ice-water grooves filled with ice-making water in which cooling projections of the cooling plate are locked; An ice level detecting unit installed in the base frame or the support frame to detect the ice in the ice storage tank when the support frame and the base frame are rotated to drop the ice frozen in the cooling protrusion into the ice storage tank; Characterized in that it comprises a.

Here, the ice level detecting unit, the contact deformation detecting member is installed on the side of the support frame facing the ice in the ice tank when rotated downward, and deformed when contacting the ice in the ice tank; And a sensor installed at the support frame so as to face the contact deformation detecting member at a predetermined interval and detecting the deformed state by contact with the ice.

In addition, the contact deformation detection member is preferably a silicon molding that can be deformed and restored by an external force.

In addition, the contact deformation detecting member, the both ends are fixed to the side of the support frame, the body having a space in the center; A contact portion extending from the tip of the body to a thinner thickness and bent and deformed upon contact with the ice; And a sensing protrusion extending from the contact portion facing the sensor and positioned in the space portion.

In addition, the sensing protrusion may be formed with a receiving groove for accommodating the magnet member detected by the sensor.

In addition, a magnet member is supported by the contact deformation detecting member, and the sensor detects a magnetic force generated between the magnet member and determines whether the contact deformation detecting member is deformed.

In addition, the ice level detection unit, it is preferable to be installed on the opposite side corresponding to one side provided with the rotation shaft of the support frame.

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

3 and 4, the ice maker of the ice maker according to the embodiment of the present invention includes a support frame 60 rotatably installed on an upper portion of the ice storage tank 51 provided in the ice maker body 50. The base frame 70 is installed on the support frame 60, and the ice level detecting unit 80 is installed on the support frame 60.

The support frame 60 is installed to rotate and return downward at an angle of about 90 degrees from the upper portion of the ice storage tank 51. The support frame 60 has a plate-shaped body 61 and a pair of shaft support portions 63 provided on one side of the body 61. Support shafts (not shown) are provided on each of the shaft support parts 63, and one of the shaft support parts 63 is connected to a rotation shaft 92 which is rotated by the power of the rotation driving motor 91. The support shaft is rotatably connected to the support part 110 provided below the cover member 100. The cover member 100 is coupled to and supported by an upper end of the ice storage tank 51.

The base frame 70 is installed on the support frame 60 to be elevated. To this end, a spring 65 is installed between the support frame 60 and the base frame 70. The upper surface of the base frame 70 is formed with a plurality of ice-water groove 71 is filled with ice. In addition, a drain passage 73 for draining the remaining water without ice making is formed on one side of the upper surface of the base frame 70. When the base frame 70 is rotated downward by 90 degrees, water is discharged through the drain passage (73). A drain container (not shown) for receiving the drained water is installed in the ice storage tank 51. The base frame 70 is guided up and down by the guide member 75, and is rotated together with the support frame 60. As a means for elevating the base frame 70, a cam 93, a cam driving motor 95 and a cam shaft 97 are provided. The cam drive motor 95 is supported by the cover member 100, and a pair of cams 93 are provided and connected to the camshaft 97. The cam 93 pushes down the upper surfaces of both ends of the base frame 70 when it is rotated, and allows the cam 93 to descend. Lifting force is provided by the spring 65

Here, an upper portion of the base frame 70 is provided with a cooling plate 110 having a cooling protrusion 111 and an evaporation tube 120 connected to a refrigeration system (not shown). Since the cooling plate 110 and the evaporation tube 120 is a known technique, detailed description thereof will be omitted.

The ice level detecting unit 80 includes a contact deformation detecting member 81 installed on the support frame 60 and a sensor 85 installed on the support frame 60 so as to face the contact deformation detecting member 81. Equipped.

The contact deformation detecting member 81 is a silicon molding, and is fixed to the other side of the support frame 60, that is, the other side of the support frame 60 opposite to the shaft portion 63. Therefore, the contact deformation detecting member 81 is elastically deformable by the contact force when it comes into contact with the ice in the ice storage tank 51 when the support frame 60 is rotated. The contact deformation detecting member 81 has a body 82 having both ends 82a fixed to the side of the support frame 60 and having a space portion 82b at the center thereof, and the body (from the tip of the body 82). A contact portion 83 thinner than the contact portion 82 and a sensing protrusion 84 protruding from the contact portion 83 into the space portion 82b are spaced apart from each other at a predetermined interval. The sensing protrusion 84 is provided with a receiving groove 84a into which the magnet or the metal member 86 is fitted. When the contact portion 83 is deformed, ie bent, by the ice, the sensing protrusion 84 is bent to one side together with the contact portion 83 and further away from the sensor 85.

The sensor 85 is a kind of hall sensor, and measures magnetic force generated between the metal member 86 and detects whether the metal member 86 is at a certain distance or out of a certain distance. . That is, the sensor 85 measures the strength of the magnetic force between the metal members 86 and detects that the contact portion 83 touches the ice in the ice storage tank 51 when the variation range exceeds a predetermined error range. You can do it. Accordingly, the control unit receiving the signal from the sensor 85 determines that the ice storage tank 51 is full of ice, and stops the ice making operation.

Looking at the operation of the ice level sensor of the ice maker according to an embodiment of the present invention having the above configuration as follows.

First, as shown in FIG. 3, the ice water is filled in the ice water groove 71 of the base frame 70, and the cooling protrusion 111 of the cooling plate 110 is cooled. At this time, as the cooling plate 110 is elevated by the driving of the cam 93, ice is gradually frozen in the cooling protrusion 111, and the ice fragments are increased.

The ice cubes become larger to some extent, and the lifting operation of the cooling plate 110 is no longer difficult, and this is detected by a sensor not shown to stop the lifting operation. Thereafter, the support frame 60 is rotated 90 degrees downward by rotating the rotation shaft 92 using a driving motor (not shown) as shown in FIG. 5. Then, the water remaining in the ice-water groove 71 is discharged through the drainage path (73). In this state, when the hot gas is supplied to the evaporation tube 120, the ice chips stuck to the cooling protrusion 111 are melted and fall into the ice storage tank 51.

On the other hand, if the ice is filled in the ice storage tank 51 in the above process, when the support frame 60 is rotated downward by 90 degrees, the contact deformation detecting member 81 is in contact with the ice Is deformed. That is, as shown in Fig. 7, the contact portion 83 is in contact with the ice cubes and bent, and then, the sensing projection 84 connected to the contact portion 83 is also bent together to be in the position as shown. In this case, a distance between the metal member 84 supported by the sensing protrusion 84 and the sensor 85 is further increased. Therefore, the magnetic force sensed by the sensor 85 is reduced, and the control unit receiving such a signal determines that the storage tank 51 is filled with ice. Therefore, after that, the ice making operation can be stopped and maintained in the standby state.

Meanwhile, in the exemplary embodiment of the present invention, the ice level detecting unit has been described as an example in which the support frame 60 is installed, but this is merely exemplary and may be installed in the base frame 70.

According to the icemaker of the icemaker of the present invention as described above, by installing the ice level detection unit in the support frame rotated at an angle of 90 degrees, it is possible to detect whether the ice is full during the ice making operation. In particular, the sensing unit has a configuration that is configured to detect the signal while deforming in contact with the ice is simple in configuration, there is an advantage that the cost can be reduced to a simple volume.

1 is a schematic cross-sectional view showing a conventional ice maker.

Figure 2 is a schematic cross-sectional view showing an extract of the ice making unit shown in FIG.

3 is a cross-sectional view showing an ice making unit of an ice maker according to an embodiment of the present invention.

Figure 4 is an exploded perspective view showing an ice making unit of the ice maker according to an embodiment of the present invention.

5 is a perspective view of the combination of the ice making unit shown in FIG.

Figure 6 is a perspective view showing the extract showing the ice level detection unit shown in FIG.

7 is a view for explaining the operation of the ice level detection unit shown in FIG.

<Description of Symbols for Major Parts of Drawings>

50. Ice machine body 51. Ice storage tank

60 .. support frame 70. base frame

93. Cam 80. Ice level detection unit

81. Contact deformation sensor 85. Sensor

100. Cover member 110. Cooling plate

111..cooling projection 120..evaporator

Claims (7)

A support frame rotatably installed at an upper portion of the ice storage tank provided inside the ice maker body; A base frame supported by the support frame and pivoted together with the support frame, the upper frame having a plurality of ice-water grooves filled with ice-making water in which cooling projections of the cooling plate are locked; An ice level detecting unit installed in the base frame or the support frame to detect the ice in the ice storage tank when the support frame and the base frame are rotated to drop the ice frozen in the cooling protrusion into the ice storage tank; Ice maker of the icemaker comprising a. The method of claim 1, wherein the ice level detection unit, A contact deformation sensing member installed at a side surface of the support frame facing the ice in the ice tank when rotated downward, and deformed upon contact with the ice in the ice tank; And a sensor installed on the support frame so as to face the contact deformation detecting member at a predetermined interval, and detecting the deformed state by contact with the ice. The ice making apparatus of claim 2, wherein the contact deformation detecting member is a silicon molding that can be deformed and restored by an external force. The method of claim 2 or 3, wherein the contact deformation detecting member, Both ends are fixed to the side of the support frame, the body having a space in the center; A contact portion extending from the tip of the body to a thinner thickness and bent and deformed upon contact with the ice; And And a sensing protrusion extending in a direction facing the sensor from the contact portion and positioned in the space portion. The icemaker of claim 4, wherein the sensing protrusion is provided with a receiving groove in which the magnet member sensed by the sensor is accommodated. According to claim 2 or 3, wherein the magnetism is supported by the contact deformation detection member, the sensor detects the magnetic force generated between the magnet member to determine whether the deformation deformation of the contact deformation detection member. An ice maker of an ice maker. According to claim 1, wherein the ice level detection unit, Ice making apparatus of the ice maker, characterized in that installed on the opposite side corresponding to one side provided with the rotating shaft of the support frame.