KR101139899B1 - Device auto-making ice - Google Patents

Abstract

PURPOSE: An automatic ice maker is provided to smoothly control a horizontal angel and ice separation angle so that the ice generation efficiency is enhanced. CONSTITUTION: An automatic ice maker comprises a body(110), a driving motor, a driving gear, a first gear(130), a second gear(140), a third gear(150), a rotary gear(160), an ice sensing lever(170), and full detecting sensor(190). A driving shaft is formed in the middle front side of the rotary gear to a longitudinal direction. A projection unit having a constant height to a longitudinal direction is formed in the middle front side of the driving shaft. The projection unit has a predetermined angle. Parts connected to the driving shaft in both sides of the projection unit are inclined. A rotary quantity sensor(180) is installed in a side of the inner part of the body. A hinge shaft is formed in a side of the middle part of the ice sensing lever and a detecting unit is formed to a vertical direction in the rear part of the ice sensing lever. A support unit having a constant length to a horizontal direction is formed in a side of the rear part of the ice sensing lever.

Description

Device Ice-making Device

The present invention relates to an automatic ice making device, and more particularly, automatic ice making to control the rotation angle of the ice making container, as well as the filling and ice position of the ice to improve the reliability of the ice making operation as well as the operating efficiency. Relates to a device.

In general, the automatic ice growth value is installed in the freezer of the refrigerator and serves to generate ice.

The automatic ice growing value is automatically supplied with water to create an ice of a certain size of ice, an ice storage container for storing the ice formed by forming the lower portion of the ice production container, and the ice of the container It is connected to the rear is made of a drive means for rotating the ice producing container by measuring the amount of ice storage in the ice storage container.

Background art of the present invention as described above is disclosed in Republic of Korea Patent Publication No. 10-1999-0049551 (1999.07.05).

However, the conventional automatic ice growing value for refrigerators can discharge the ice generated by measuring the filling (full ice) state of the ice storage container, but the ice detection lever rotating in the vertical direction to check the filling state of the ice is different from the ice. If it does not move anymore, it will not be able to rotate the ice making container has a functional limit that can not perform smooth ice production.

In particular, since it is not possible to control the exact rotation position of the ice producing container has a problem that can not supply the generated ice accurately into the inside of the ice storage container.

In addition, the conventional automatic ice growth for the refrigerator has a problem that provides a major cause of frequent malfunctions as well as malfunction due to the complex operation method and components.

Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art,

It is an object of the present invention to smoothly control the horizontal angle and the ice angle of the ice making container, as well as to provide an automatic ice making device capable of measuring the fullness of the ice stored in the ice storage container.

Automatic ice raw growth value of the present invention for achieving the above object,

Body 110 is installed on one side of the freezer compartment in front of the cover 111 is removable; A driving motor 120 installed on one side of the body 110; A drive gear 121 coupled to the rotation shaft of the drive motor 120; A first gear 130 installed at one side of the body 110 to rotate in engagement with the drive gear 121; A second gear 140 installed at an inner side of the body 110 to rotate in engagement with the first gear 130; A third gear 150 installed at one side of the body 110 to rotate in engagement with the second gear 140; It is installed on the inner side of the body 110 so as to rotate in engagement with the third gear 150, the coupling hole 161 is formed at the rear is coupled with the ice-making container 200 and the cam 163 on the central one side Rotating gear 160 is provided; An ice detection lever 170 installed on the inner side of the body 110 to rotate in an up and down direction for measuring an amount of ice in the ice storage container; In the automatic ice making device is installed on one side of the body 110 and made of a fullness detection sensor 190 for measuring the fullness of the ice in contact with one side of the sensing lever 170,

A drive shaft 162a protruding in the longitudinal direction is formed at the center front of the rotary gear 160, and a protrusion 162 is provided at the center front of the drive shaft 162a to have a predetermined height in the longitudinal direction, and the protrusion ( 162 is formed to have an angle of 135 ° to 145 ° when viewed in the side state, the portion connected to the drive shaft 162a at both ends of the protrusion 162 is formed to be inclined, the interior of the body 110 One side includes a rotation amount detection sensor 180 for rotating the ice making container 200 by operating the driving motor 120 by contacting the surfaces of the protrusion 162 and the drive shaft 162a, the detection The lever 170 is a hinge shaft 172 is formed on one side of the middle and the sensing unit 173 is provided in the vertical direction at the rear, the rear side is composed of a support portion 171 formed to have a predetermined length in the horizontal direction It is done.

Here, the front end of the inspection lever 170 is mounted with an inspection plate (170a), the front side of the detection plate 170a is formed with a locking jaw (170b) is formed so that the inspection lever 170 is fitted and fixed to the inspection A locking protrusion 170c is formed at one rear side of the ice plate 170a so that the inspection lever 170 is fitted and supported.

The present invention has the effect of improving the production efficiency by smoothly controlling the horizontal angle and the ice angle of the ice making container.

In addition, the present invention has the effect of accurately supplying the ice into the interior of the ice storage container along the ice and filling position of the ice produced.

In particular, the present invention has the effect that the structure is simple and to prevent the main cause of the malfunction in advance to ensure the efficiency of the production work.

Figure 1 is an exploded perspective view showing the structure of the present invention automatic ice making device.
Figure 2 is a perspective view for showing the structure of the automatic ice making apparatus of the present invention.
Figure 3 is a perspective view of the structure of the present invention automatic ice making apparatus viewed from the rear.
Figure 4 is a plan view for showing the structure of the automatic ice making apparatus of the present invention.
5 is a cross-sectional view taken along the line AA of FIG.
Figure 6 is a perspective view for showing the structure of the rotary gear in the present invention.
Figure 7 is a side view for showing the structure of the rotary gear in the present invention.
Figure 8 is a front view for showing the structure of the rotary gear in the present invention.
9 to 11 is a flow chart for showing the operating state of the automatic ice making apparatus of the present invention.

When described in more detail by the accompanying drawings the technical configuration for achieving the object of the present invention as described above are as follows.

1 is an exploded perspective view for showing the structure of the automatic ice making device of the present invention, Figure 2 is a combined perspective view for showing the structure of the automatic ice making device of the present invention, Figure 3 is a structure of the automatic ice making device of the present invention 4 is a plan view showing the structure of the automatic ice making apparatus of the present invention, FIG. 5 is a cross-sectional view taken along line AA of FIG. 2, and FIG. 6 is a view showing the structure of the rotating gear of the present invention. 7 is a side view for showing the structure of the rotary gear in the present invention, Figure 8 is a front view for showing the structure of the rotary gear in the present invention.

The present invention is installed on one side of the inside of the freezer compartment body 110, the cover 111 is removable in front; A driving motor 120 installed on one side of the body 110; A drive gear 121 coupled to the rotation shaft of the drive motor 120; A first gear 130 installed at one side of the body 110 to rotate in engagement with the drive gear 121; A second gear 140 installed at an inner side of the body 110 to rotate in engagement with the first gear 130; A third gear 150 installed at one side of the body 110 to rotate in engagement with the second gear 140; It is installed on the inner side of the body 110 so as to rotate in engagement with the third gear 150, the coupling hole 161 is formed at the rear is coupled with the ice-making container 200 and the cam 163 on the central one side Rotating gear 160 is provided; An ice detection lever 170 installed on the inner side of the body 110 to rotate in an up and down direction for measuring an amount of ice in the ice storage container; In the automatic ice making device is installed on one side of the body 110 and made of a fullness detection sensor 190 for measuring the fullness of the ice in contact with one side of the sensing lever 170,

A drive shaft 162a protruding in the longitudinal direction is formed at the center front of the rotary gear 160, and a protrusion 162 is provided at the center front of the drive shaft 162a to have a predetermined height in the longitudinal direction, and the protrusion ( 162 is formed to have an angle of 135 ° to 145 ° when viewed in the side state, the portion connected to the drive shaft 162a at both ends of the protrusion 162 is formed to be inclined, the interior of the body 110 One side includes a rotation amount detection sensor 180 for rotating the ice making container 200 by operating the driving motor 120 by contacting the surfaces of the protrusion 162 and the drive shaft 162a, the detection The lever 170 is formed of a support shaft 171 formed to have a hinge shaft 172 on one side of the middle and a sensing unit 173 in the vertical direction at the rear side and a predetermined length in the horizontal direction on one rear side.

The body 110 is installed on one side of the freezer compartment, and as shown in Figure 1 in the form of the interior is empty to guide each component of the present invention can be inserted and fixed in the interior and assembly or maintenance in the front In order to remove the cover 111.

In this case, as shown in FIG. 3, the lower side of the body 110 may have a long hole 112 formed in a vertical direction to prevent interference during the rotation of the detection lever 170 in the vertical direction.

On the other hand, the drive motor 120 receives the ON or OFF signal of the rotation amount sensor 180 and the fullness detection sensor 190 to rotate the ice making container 200 forward or reverse depending on whether the ice is filled. Generates a driving force to rotate.

In addition, the driving gear 121, the first gear 130, the second gear 140, the third gear 150, the rotary gear 160 are sequentially engaged with each other to maintain the rotational force of the drive motor 120. It is possible to smoothly rotate the ice production vessel 200 through the increase or decrease.

At this time, the drive gear 121, the first gear 130, the second gear 140, the third gear 150, the rotary gear 160 is a gear having a variety of shapes and teeth such as spur gear or worm gear is applied Of course it can.

Meanwhile, as shown in FIG. 6, the rotary gear 160 protrudes a coupling hole 161 for coupling the ice making container 200 in a horizontal direction and a cam 163 is provided at a central side thereof.

In addition, as shown in FIG. 8, a driving shaft 162a protruding in the longitudinal direction is formed at the center front of the rotary gear 160, and a protrusion part having a predetermined height in the longitudinal direction at the center front of the driving shaft 162a. 162 is provided, which is ON when the actuating projection 181 of the rotation amount sensor 180 is in contact with the surface of the driving shaft 162a or the protruding portion 162 which is not only different in height, but also rotates. While OFF, the driving motor 120 is operated to set a reference point for forward rotation or reverse rotation of the ice production vessel 200.

At this time, the protrusion 162 is formed to have an angle (a) of 135 ° to 145 ° when viewed from the side as shown in Figure 7, which is the designated angle that the ice making vessel 200 rotates in the ice process This is to easily discharge the generated ice into the ice storage container.

Particularly, as shown in FIG. 8, portions connected to the driving shaft 162a at both ends of the protrusion 162 are formed to be inclined, which rotates the operation protrusion 181 of the rotation amount sensor 180. When the protrusion 162 and the driving shaft 162a is in contact with each other, it is to perform an ON or OFF function while naturally moving without collision and interference.

In addition, the cam 163 is in contact with the support portion 171 of the sensing lever 170 in accordance with the rotation angle rotates in the vertical direction to move the operation projection 191 of the fullness detection sensor 190 to the sensing lever 170 ), The sensing unit 173 abuts or falls to determine whether it is full.

Here, the detection lever 170 is formed of a support shaft 171 formed to have a hinge shaft 172 on one side of the middle, the sensing unit 173 is provided in the vertical direction at the rear and has a predetermined length in the horizontal direction on the rear side. do.

At this time, the hinge shaft 172 is mounted on one side of the lower portion of the body 110 serves as a central axis to rotate in the vertical direction.

In particular, the support part 171 may contact the surface of the cam 163 and rotate about the hinge axis 172, so that the sensing part 173 may contact the actuating protrusion 191 to determine whether it is full. .

On the other hand, as shown in Figure 4 the front end of the detection lever 170, the detection plate (170a) is mounted, the locking jaw (170b) is formed on one front side of the detection plate (170a) is the detection lever ( 170 is inserted and fixed, and a locking protrusion 170c is formed at one rear side of the detection plate 170a to allow the detection lever 170 to be inserted and supported.

At this time, the detection plate (170a) is in the shape of a wide plate protruding in the lower direction can be in contact with the ice generated inside the ice production vessel 200 can perform a smooth detection function.

In addition, the blacking jaw (170a) and the locking projection (170c) is guided so that the inspection lever 170 is fitted and fixed as well as removable during maintenance.

In addition, when described in more detail by the accompanying drawings the operating state of the present invention as described above are as follows.

9 to 11 show a flow chart for showing the operating state of the automatic ice making apparatus of the present invention.

First, as shown in FIG. 9, in the state where the ice making container 200 is positioned in the horizontal direction, the operation protrusion 181 of the rotation amount sensor 180 is in contact with the surface of the driving shaft 162a. You will see the initial state of preparation.

At this time, when the amount of ice is insufficient, the tip portion of the ice detection lever 170 is rotated downwardly around the hinge axis 172 by its own weight, and at the same time the detection unit 173 is raised to the fullness detection sensor 190 In contact with the operation protrusion 191 of the) to operate the drive motor 120 may rotate the ice production vessel (200).

Next, as shown in FIG. 10, the operation protrusion 181 of the rotation amount sensor 180 contacts the protrusion 162 to continuously operate the driving motor 120 in an ON state. As the rotary gear 160 and the ice making container 200 rotate, the operation protrusion 181 of the rotation amount detecting sensor 180 may rotate to the surface of the driving shaft 162a by deviating from the surface of the protrusion 162. In this case, the operation protrusion 181 is turned off and the driving motor 120 is stopped to finish the ice work.

In addition, by pressing the support 171 while the cam 163 rotates to induce the detection unit 173 does not come into contact with the operation protrusion 191 of the fullness detection sensor 190 to finish the ice work.

Lastly, as shown in FIG. 11, when both the rotation amount detecting sensor 180 and the fullness detecting sensor 190 are turned off, the driving motor 120 reversely rotates and the ice making container 200 and the ice detection lever ( 170 is located in the horizontal direction to return to the initial state.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

100: the present invention automatic ice making device
110: body 111: cover
112: longman
120: drive motor 121: drive gear
130: first gear 140: second gear
150: third gear 160: rotary gear
161: coupler 162: protrusion
162a: drive shaft 163: cam
170: ice detection lever 170a: ice plate
170b: Jamming 170c: Jamming
171: support portion 172: hinge axis
173: detector
180: rotation amount detection sensor 181: detection projection
190: fullness detection sensor 191: detection projection
200: ice making container

Claims (2)

Body 110 is installed on one side of the freezer compartment in front of the cover 111 is removable; A driving motor 120 installed on one side of the body 110; A drive gear 121 coupled to the rotation shaft of the drive motor 120; A first gear 130 installed at one side of the body 110 to rotate in engagement with the drive gear 121; A second gear 140 installed at an inner side of the body 110 to rotate in engagement with the first gear 130; A third gear 150 installed at one side of the body 110 to rotate in engagement with the second gear 140; It is installed on the inner side of the body 110 so as to rotate in engagement with the third gear 150, the coupling hole 161 is formed at the rear is coupled with the ice-making container 200 and the cam 163 on the central one side Rotating gear 160 is provided; An ice detection lever 170 installed on the inner side of the body 110 to rotate in an up and down direction for measuring an amount of ice in the ice storage container; In the automatic ice making device is installed on one side of the body 110 and made of a fullness detection sensor 190 for measuring the fullness of the ice in contact with one side of the sensing lever 170,
A drive shaft 162a protruding in the longitudinal direction is formed at the center front of the rotary gear 160, and a protrusion 162 is provided at the center front of the drive shaft 162a to have a predetermined height in the longitudinal direction, and the protrusion ( 162 is formed to have an angle of 135 ° to 145 ° when viewed in the side state, the portion connected to the drive shaft 162a at both ends of the protrusion 162 is formed to be inclined, the interior of the body 110 One side includes a rotation amount detection sensor 180 for rotating the ice making container 200 by operating the driving motor 120 by contacting the surfaces of the protrusion 162 and the drive shaft 162a, the detection The lever 170 is a hinge shaft 172 is formed on one side of the middle and the sensing unit 173 is provided in the vertical direction at the rear, the rear side is composed of a support portion 171 formed to have a predetermined length in the horizontal direction Auto ice made Generating device. According to claim 1, wherein the detection plate (170a) is mounted to the front end of the detection lever 170, the locking jaw (170b) is formed on one front side of the detection plate (170a) the detection lever 170 is The automatic ice-making apparatus, characterized in that the locking projection is formed on the one side of the rear side of the ice detection plate (170a) is supported by the detection lever 170 is fitted.

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