KR20110058636A - Ice maker - Google Patents

Abstract

PURPOSE: An ice maker is provided to directly detect the size of ice blocks and automatically determine the timing of separating completed ice blocks. CONSTITUTION: An ice maker comprises a plurality of ice making elements(200), an ice making tray(300), a pivot element(400), and a detecting unit(500). The ice making elements are connected to an evaporator(E) included in a freezer system. The ice making tray stores water in which the ice making elements are dipped to make ice blocks. The pivot element rotates inside the ice making tray. The detecting unit senses the contact of ice blocks when one side of the pivot element contacts the ice blocks that have grown to a fixed size.

Description

Ice maker {ICE MAKER}

The present invention relates to an ice maker that directly detects the size of the ice and determines the defrosting point of the ice.

An ice maker is a device for making ice in a refrigerator or an ice purifier.

These ice makers are equipped with a refrigeration system to make ice. The refrigeration system includes an evaporator and a plurality of ice making members are connected to the evaporator. The refrigerant flowing through the refrigeration system may flow inside the plurality of ice making members. In addition, the ice maker is provided with an ice tray containing water in which the plurality of ice-making members described above are immersed.

On the other hand, cold refrigerant flows inside the plurality of ice making members during ice making. Accordingly, ice is generated in the ice producing member by heat exchange between the cool refrigerant flowing in the ice producing member and the water in which the ice producing member is submerged. Then, during defrosting, hot refrigerant flows inside the plurality of ice producing members. Thus, the surface of the ice in contact with the ice-making member is melted, thereby separating the ice from the ice-making member and stored in the ice storage.

In the conventional ice maker, the temperature of the refrigerant at the outlet of the evaporator is measured to determine the timing of defrosting of ice generated in the ice making member. That is, during ice making, heat is transferred from the water to the refrigerant to generate ice, so that the temperature of the refrigerant at the evaporator outlet is significantly higher than the temperature of the refrigerant flowing into the evaporator. However, if ice of a certain size is produced, the heat transfer from the water to the refrigerant is not good, so the temperature of the refrigerant at the outlet of the evaporator is not much higher than the temperature of the refrigerant flowing into the evaporator. Therefore, when the temperature of the refrigerant at the evaporator outlet is below a certain temperature, it is determined as the ice-breaking time to de-ice the ice.

However, there is a problem that the temperature of the refrigerant at the evaporator outlet is influenced by factors other than ice size, such as the performance of the temperature sensor measuring the temperature and the amount of refrigerant or the external temperature. Accordingly, there is a problem in that it is not possible to accurately determine a defrosting time for deicing ice that has reached a certain size. In addition, since the defrosting point of the ice is determined in an indirect manner that can be changed by factors other than the size of the ice, there is a problem in that ice of a certain size cannot be made.

The present invention is made by recognizing at least one of the needs or problems occurring in the conventional ice maker.

One object of the present invention is to directly detect the size of the ice to determine the ice break time.

Another object of the present invention is to prevent the ice-breaking time is changed by factors other than ice size.

Yet another object of the present invention is to be able to produce ice of a certain size.

An ice maker according to an embodiment for realizing at least one of the above problems may include the following features.

The present invention is basically based on measuring the size of the ice directly so that the ice can be defrosted if it is a certain size.

Ice maker according to an embodiment of the present invention a plurality of ice producing member connected to the evaporator included in the refrigeration system; An ice making tray containing water so that a plurality of ice making members are locked to generate ice; A pivot member provided in the ice tray so as to be pivotable inside the ice tray; And a sensing unit configured to detect ice when the ice generated in the ice making member has a predetermined size so that one side of the turning member contacts the ice. It may be configured to include.

In this case, the sensing unit includes a support member having a space in which the other side of the pivot member can enter and exit according to the pivot of the pivot member; An electromagnetic wave transmitting member which is provided at one side of the supporting member and is blocked by entering and exiting the other side of the turning member when the ice generated in the ice making member is not a predetermined size, and transmits electromagnetic waves which are not blocked when the ice is a predetermined size; And an electromagnetic wave receiving member provided at a position of the support member capable of receiving electromagnetic waves transmitted from the electromagnetic wave transmitting member. It may include.

The sensing unit includes an electromagnetic wave transmitting member provided in the ice making tray and transmitting electromagnetic waves; An electromagnetic wave receiving member provided in the ice making tray adjacent to the electromagnetic wave transmitting member and receiving the electromagnetic wave; And when the ice generated in the ice-making member is not a certain size, the electromagnetic wave is reflected so that the electromagnetic wave transmitted from the electromagnetic wave transmitting member is received by the turning member according to the turning of the turning member and the electromagnetic wave is not reflected when the ice is a certain size A reflection member provided at a position of the pivot member; It may include.

In addition, one side of the pivot member may be provided with a contact member to contact when the ice is a predetermined size.

In addition, the pivot member may pivot periodically.

On the other hand, the pivot member can be pivoted by a drive unit including a drive motor.

In addition, the pivot member can be pivoted by a drive unit using magnetic force.

In this case, the drive unit includes a magnetic body provided in the pivot member; And a magnetic force generating member generating magnetic force so as to periodically generate attractive force or repulsive force between the magnetic body and the magnetic force generating member provided at a position where the generated magnetic force may affect the magnetic body. It may include.

The magnetic body may be a permanent magnet, and the magnetic force generating member may be a solenoid.

As described above, according to an embodiment of the present invention, the ice break time can be determined by directly detecting the size of the ice.

In addition, according to an embodiment of the present invention, the defrosting time may not be changed by other factors than the ice size.

And also, according to an embodiment of the present invention, it is possible to produce ice of a certain size.

1 is a view showing an embodiment of an ice maker according to the present invention.
2 is a view showing another embodiment of an ice maker according to the present invention.
3 is a view showing another embodiment of an ice maker according to the present invention.
4 to 7 show the operation of one embodiment of an ice maker according to the present invention.

In order to help the understanding of the features of the present invention as described above, it will be described in more detail with respect to the ice maker associated with an embodiment of the present invention.

Hereinafter, the described embodiments will be described on the basis of the most suitable embodiments for understanding the technical features of the present invention, and the technical features of the present invention are not limited by the described embodiments. It is to be exemplified that the present invention can be implemented as in the following embodiments. Accordingly, the present invention may be modified in various ways within the technical scope of the present invention through the embodiments described below, and such modified embodiments fall within the technical scope of the present invention. And, in order to help the understanding of the embodiments described below, in the reference numerals described in the accompanying drawings, among the components that will have the same function in each embodiment, the related components are denoted by the same or extension numbers.

Embodiments related to the present invention are basically based on directly measuring the size of the ice so that the ice can be defrosted when it reaches a certain size.

As illustrated in FIGS. 1 to 3, the ice maker 100 according to the present invention includes a plurality of ice making members 200, an ice making tray 300, a turning member 400, and a sensing unit 500. It may be configured to include.

The plurality of ice making members 200 may be connected to an evaporator E included in a refrigeration system (not shown). Accordingly, a cool refrigerant or a hot refrigerant may flow in the evaporator E and the plurality of ice making members 200. That is, a cool refrigerant may flow through the evaporator E and the ice making member 200 during ice making in which ice I is formed in each of the ice making members 200. In addition, a hot refrigerant may flow through the evaporator E and the ice making member 200 during the defrosting to separate the ice I generated in each of the ice making members 200 from the ice making member 200. .

The ice making tray 300 may be located under the plurality of ice making members 200 as shown in FIGS. 1 to 3. In addition, the ice tray 300 may contain water. Accordingly, the ice I may be generated in each of the ice making members 200 by immersing the ice making members 200 in the water contained in the ice making tray 300.

The pivot member 400 may be provided in the ice tray 300 as in the embodiment shown in FIGS. The pivot member 400 may be pivotable inside the ice tray 300. The pivot member 400 may pivot about the pivot axis A provided in the ice tray 300 as shown in the illustrated embodiment. 1 and 2, the turning member 400 may be pivoted at the same position as the ice making tray 300, that is, the short side of the ice making tray 300 having a long side and a short side. In addition, the pivot member 400 may be pivoted at the same position as the ice tray 300 as shown in FIG. 3, that is, at the long side of the ice tray 300. However, the position in the ice making tray 300 of the revolving member 400 is not particularly limited. In addition, one side of the pivot member 400 may be provided with a contact member 410 as shown in the illustrated embodiment. The contact member 410 is in contact with the ice (I) generated in the ice making member 200 by turning the turning member 400 when the ice (I) generated in the ice making member 200 is a predetermined size. Can be.

Meanwhile, the pivot member 400 may pivot periodically. As such, when the pivot member 400 pivots periodically inside the ice tray 300, waves may be generated in the water contained in the ice tray 300. As a result, when the ice I is generated in the ice making member 200, the bubble layer that may occur in the ice I may not grow. Accordingly, transparent ice I may be generated in the ice making member 200.

The pivot member 400 may be pivoted by the driving unit 600 including the driving motor M as shown in FIG. 1. That is, the pivot member 400 may pivot about the pivot axis A by the driving motor M and the gear (not shown) connected thereto.

In addition, the pivot member 400 may pivot about the pivot axis A by the driving unit 600 using magnetic force, as shown in FIGS. 2 and 3. To this end, the driving unit 600 may include a magnetic body 610 and a magnetic force generating member 620 as shown in the illustrated embodiment.

The magnetic body 610 may be provided in the pivot member 400 as shown in FIGS. 2 and 3. The magnetic force of a predetermined direction is generated by the magnetic body 610. The magnetic body 610 may be a permanent magnet. However, the magnetic body 610 is not limited to the permanent magnet, and any one can be used as long as it generates a magnetic force in a predetermined direction.

The magnetic force generating member 620 may also generate magnetic force. In addition, the magnetic force generating member 620 may be provided at a position where the generated magnetic force may be applied to the magnetic body 610 provided in the turning member 400. For example, as in the embodiment shown in Figures 2 and 3, the magnetic force generating member 620 may be provided in the ice maker body (B). However, the position of the magnetic force generating member 620 is not limited to the illustrated embodiment, as long as the magnetic force generated by the magnetic force generating member 620 can be applied to the magnetic body 610 provided in the pivot member 400. It is possible to position. In addition, the magnetic force generating member 620 may be provided with a magnetic force transmission member 621 so that the magnetic force of the magnetic force generating member 620 to the magnetic body 610 provided in the turning member 400 as shown in the embodiment have. The direction of the magnetic force generated by the magnetic force generating member 620 may be a direction in which attraction or repulsive force may periodically occur between the magnetic member 610 provided in the turning member 400 so that the turning member 400 may turn. Can be. For example, the magnetic force generating member 620 may periodically generate a magnetic force in a direction in which an attractive force may occur between the magnetic body 610 and the magnetic body 610. In addition, the magnetic force in a direction in which repulsive force may occur between the magnetic body 610 may be periodically generated. In addition, the magnetic force in the direction in which the attraction force and the repulsive force may be generated between the magnetic body 610 may be periodically generated. To this end, the magnetic force generating member 620 may be a solenoid. However, the magnetic force generating member 620 is not limited to the solenoid, and any magnetic material can be used as long as it can generate magnetic force in a direction in which attraction or repulsive force can periodically occur between the magnetic body 610.

The detection unit 500 may be configured to detect when the ice I generated in the ice making member 200 reaches a predetermined size in association with the pivot member 400. That is, the sensing unit 500 is the ice (I) generated in the ice making member 200 is a predetermined size so that the contact member 410 provided on one side of the pivot member 400 or one side of the pivot member 400 It may be configured to detect the contact with the ice (I).

To this end, the sensing unit 500 may include a support member 510, an electromagnetic wave transmitting member 520, and an electromagnetic wave receiving member 530, as shown in FIGS. 1 and 2.

The support member 510 may be formed with a space S as in the embodiment shown in FIGS. 1 and 2. Therefore, when the pivot member 400 pivots about the pivot axis A, the other side of the pivot member 400, that is, the opposite side provided with the contact member 410 of the pivot member 400 is supported by the support member 510. Can enter and exit the formed space (S).

The electromagnetic wave transmitting member 520 may be provided at one side of the supporting member 510 as shown in FIGS. 1 and 2. The electromagnetic wave transmitting member 520 may transmit electromagnetic waves. In addition, the electromagnetic wave receiving member 530 may be provided at a position of the support member 510 capable of receiving the electromagnetic wave transmitted from the electromagnetic wave transmitting member 520. Therefore, the electromagnetic wave transmitted from the electromagnetic wave transmitting member 520 may be received by the electromagnetic wave receiving member 530. That is, the path of the electromagnetic wave is formed in the space S of the support member 510. The other side of the pivot member 400 may enter and exit the space S in which the path of the electromagnetic wave is formed as described above. Therefore, when the turning member 400 turns without being influenced by the outside, that is, when the ice I generated in the ice making member 200 does not become a predetermined size, one side of the turning member 400 The contact member 410 provided on one side of the pivot member 400 does not contact the ice I by the pivot of the pivot member 400. Accordingly, the other side of the turning member 400 may enter the space S of the supporting member 510 by turning the turning member 400, and may block the path of the electromagnetic wave formed in the space S. However, when the turning member 400 turns while being affected by the outside, that is, when the ice I generated in the ice making member 200 has a predetermined size, one side of the turning member 400 or the turning member The contact member 410 provided at one side of the 400 is in contact with the ice (I). Accordingly, the other side of the turning member 400 cannot enter the space S of the support member 510 and cannot block the path of the electromagnetic wave formed in the space S. Therefore, it is possible to detect that the ice I has become a certain size, thereby determining the icebreaking time of the ice I.

In addition, the sensing unit 500 may include an electromagnetic wave transmitting member 520, an electromagnetic wave receiving member 530, and a reflective member 540 as shown in FIG. 3.

3, the electromagnetic wave transmitting member 520 may be provided in the ice making tray 300. In addition, electromagnetic waves may be transmitted from the electromagnetic wave transmitting member 520. In addition, the electromagnetic wave receiving member 530 may be provided in the ice making tray 300 as shown in the illustrated embodiment. The electromagnetic wave receiving member 530 may be provided in the ice making tray 300 adjacent to the electromagnetic wave transmitting member 520. The electromagnetic wave receiving member 530 receives electromagnetic waves. As will be described later, electromagnetic waves transmitted from the electromagnetic wave transmitting member 520 may be reflected by the reflecting member 540 and received by the electromagnetic wave receiving member 530.

The reflective member 540 may be provided in the pivot member 400 as shown in FIG. 3. Therefore, the reflection member 540 may also be turned by turning the turning member 400. When the turning member 400 turns without being influenced by the outside, that is, when the ice I generated in the ice making member 200 does not become a predetermined size, one side of the turning member 400 or the turning member The contact member 410 provided at one side of the 400 does not contact the ice I by the pivot of the pivot member 400. Accordingly, the turning member 400 also turns in response to the turning of the turning member 400 so that the electromagnetic wave is reflected so that the electromagnetic wave transmitted from the electromagnetic wave transmitting member 520 is received by the electromagnetic wave receiving member 530. However, when the turning member 400 turns while being affected by the outside, that is, when the ice I generated in the ice making member 200 has a predetermined size, one side of the turning member 400 or the turning member The contact member 410 provided at one side of the 400 is in contact with the ice (I). Accordingly, the electromagnetic wave transmitted from the electromagnetic wave transmitting member 520 is not reflected by the reflective member 540. Therefore, the electromagnetic wave receiving member 530 does not receive the electromagnetic wave. As a result, it is possible to detect that the ice I has become a certain size, and determine the icebreaking time of the ice I.

As described above, since the size of ice I is determined by directly detecting the size of ice I generated in the ice making member 200, the time of defrosting may not be changed by other factors than the size of ice I. Can be. Thus, ice I of a certain size can be produced.

Hereinafter, the operation of one embodiment of the ice maker 100 according to the present invention will be described in detail with reference to FIGS. 4 to 7.

First, in the state in which the ice making tray 300 is in the ice making position as shown in FIG. 4, water is supplied as shown in the ice making tray 300 through the water supply member P. FIG. Accordingly, the ice making tray 300 contains water W so that the plurality of ice making members 200 can be locked.

Water is supplied to the ice making tray 300 through the water supply member P to a level at which the plurality of ice producing members 200 can be locked so that ice I may be generated in the plurality of ice producing members 200. In one state, as shown in FIG. 5, the driving motor M of the driving unit 600 is operated to periodically rotate the pivot member 400 about the pivot axis A.

As such, when the pivot member 400 pivots about the pivot axis A periodically, waves are generated in the water W contained in the ice making tray 300, as shown in FIG. In this state, a refrigeration system (not shown) connected to the evaporator E is operated. Accordingly, a cool refrigerant flows inside the plurality of ice making members 200 connected to the evaporator E and the evaporator E. As a result, heat exchange is performed between the cold refrigerant flowing in the plurality of ice making members 200 and the water W contained in the ice making tray 300 in which the plurality of ice making members 200 are locked. That is, heat transfer is performed from the water W contained in the ice making tray 300 in which the ice making member 200 is locked to a cool refrigerant flowing through the inside of the ice making member 200. Accordingly, as shown in FIG. 5, ice I is generated in each of the plurality of ice producing members 200.

On the other hand, since the wave generated in the water contained in the ice making tray 300 by the turning of the turning member 400 as described above, when the ice (I) is generated in the ice making member 200, the ice (I) The bubble layer that may occur within it will not grow. Accordingly, transparent ice I may be generated in the ice making member 200.

As shown in FIG. 5, when the ice I generated in the ice making member 200 does not reach a predetermined size, the turning of the turning member 400 is made without being influenced by the outside. Therefore, in the case of the embodiment shown in Figures 1 and 2, the other side of the turning member 400 can enter the space (S) of the support member 510. Accordingly, the path of the electromagnetic wave formed in the space S by the electromagnetic wave transmitting member 520 and the electromagnetic wave receiving member 530 is blocked by the other side of the turning member 400 entering the space S by the turning. . In addition, in the embodiment shown in FIG. 3, the electromagnetic wave transmitted from the electromagnetic wave transmitting member 520 is reflected by the reflective member 540 provided in the turning member 400 and received by the electromagnetic wave receiving member 530. Since the turning of the revolving member 400 is performed periodically, the blocking of the path of electromagnetic waves formed in the space S by the other side of the revolving member 400 is also periodically performed. In addition, the electromagnetic wave transmitted from the electromagnetic wave transmitting member 520 by the reflective member 540 is also reflected periodically received by the electromagnetic wave receiving member 530. By detecting this, it can be seen that the ice I generated in the ice making member 200 does not reach a predetermined size.

On the other hand, as shown in Figure 6, when the ice (I) generated in the ice making member 200 reaches a predetermined size, the contact member provided on the pivot member 400 or one side of the pivot member 400 ( 410 comes into contact with ice (I). Therefore, the turning of the turning member 400 is hindered by external influences, that is, the ice I generated in the ice making member 200. Accordingly, the turning angle of the turning member 400 is reduced, and as shown, the other side of the turning member 400 does not enter the space S of the supporting member 510. Therefore, the other side of the turning member 400 does not block the path of the electromagnetic wave formed in the space S of the supporting member 510. 3, the electromagnetic wave transmitted from the electromagnetic wave transmitting member 520 by the reflective member 540 is not reflected and received by the electromagnetic wave receiving member 530. If this is detected, it can be seen that the size of the ice I generated in the ice making member 200 has reached a certain size. At this time, the ice is defrosted.

When it is detected that the size of the ice I generated in the ice making member 200 reaches a predetermined size, that is, when the ice-breaking time is determined, the ice tray 300 is moved to the ice-breaking position as shown in FIG. Rotate When the ice tray 300 is rotated to the ice-free position, the water W contained in the ice tray 300 is sent to a cold water tank (not shown) or transferred to a drip tray (not shown) connected to the ice tray 300. .

Thereafter, the refrigeration system is operated to allow the hot refrigerant to flow through the evaporator E and the ice making member 200. Accordingly, the surface of the ice I in contact with the ice making member 200 is melted. Thus, as shown in FIG. 7, the ice I is separated from the ice making member 200. Then, the ice I separated from the ice making member 200 falls by its own weight and is sent to a cold water tank (not shown) to cool the water stored in the cold water tank, or by a guide member (not shown). Guided to an ice reservoir (not shown) and stored in the ice reservoir.

Using the ice maker 100 according to the present invention as described above, it is possible to directly determine the size of the ice (I) to determine the de-icing time of the ice (I).

In addition, the ice-breaking point may not be changed by factors other than the size of ice (I).

Thus, ice I of a certain size can be produced.

The ice maker described above may not be limitedly applied to the configuration of the above-described embodiment, but the embodiments may be configured by selectively combining all or some of the embodiments so that various modifications can be made.

100: ice maker 200: ice making member
300: ice tray 400: pivot member
410: contact member 500: detection unit
510: support member 520: electromagnetic wave transmitting member
530: electromagnetic wave receiving member 540: reflective member
600: drive unit 610: magnetic material
620: magnetic force generating member 621: magnetic force transmitting member
E: Evaporator I: Ice
W: water S: space
M: Drive motor B: Ice maker main body
P: Water supply member A: Swivel shaft

Claims (9)

A plurality of ice producing members 200 connected to the evaporator E included in the refrigeration system;
An ice making tray (300) containing water so that the plurality of ice making members (200) are locked to produce ice (I);
A pivot member 400 provided in the ice tray 300 so as to be pivotable inside the ice tray 300; And
A sensing unit 500 configured to detect ice when the ice I generated in the ice making member 200 becomes a predetermined size so that one side of the pivot member 400 contacts the ice I;
Ice machine configured to include. The method of claim 1, wherein the detection unit 500
A support member 510 having a space S through which the other side of the pivot member 400 enters and exits according to the pivot of the pivot member 400;
When the ice (I) generated in the ice producing member 200 is provided on one side of the support member 510 and is not a predetermined size, the ice (I) is blocked by entering and exiting the other side of the pivot member 400. The electromagnetic wave transmitting member 520 which transmits electromagnetic waves that are not blocked when the predetermined size); And
An electromagnetic wave receiving member 530 provided at a position of the support member 510 capable of receiving electromagnetic waves transmitted from the electromagnetic wave transmitting member 520;
Ice maker comprising a. The method of claim 1, wherein the detection unit 500
An electromagnetic wave transmitting member 520 provided in the ice making tray 300 and transmitting electromagnetic waves;
An electromagnetic wave receiving member 530 provided in the ice making tray 300 adjacent to the electromagnetic wave transmitting member 520 and receiving the electromagnetic wave; And
When the ice I generated in the ice making member 200 does not have a predetermined size, electromagnetic waves transmitted from the electromagnetic wave transmitting member 520 according to the turning of the turning member 400 are the electromagnetic wave receiving member 530. A reflection member 540 provided at a position of the pivot member 400 in which electromagnetic waves are reflected to be received by the beam and the electromagnetic wave is not reflected when the ice (I) reaches a predetermined size;
Ice maker comprising a. The ice maker according to claim 1, wherein a contact member (410) is provided at one side of the pivot member (400) to contact when the ice (I) has a predetermined size. The ice maker according to any one of claims 1 to 4, wherein the pivot member (400) pivots periodically. The ice maker according to claim 5, wherein the pivot member (400) is pivoted by a driving unit (600) including a driving motor (M). The ice maker according to claim 5, wherein the pivot member (400) is pivoted by a drive unit (600) using magnetic force. The method of claim 7, wherein the driving unit 600
A magnetic body 610 provided in the pivot member 400; And
A magnetic force generating member 620 which generates magnetic force so as to periodically generate attraction force or repulsive force between the magnetic body 610 and the generated magnetic force on the magnetic body 610;
Ice maker comprising a. The ice maker of claim 8, wherein the magnetic material (610) is a permanent magnet, and the magnetic force generating member (620) is a solenoid.

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