KR102345488B1 - An ice maker - Google Patents

Abstract

The ice maker according to an embodiment includes a chamber, a water supply unit that receives and provides water from the outside, a heat exchange unit disposed in the chamber to cool water provided by the water supply unit to form ice, and the water supply unit and the heat exchange unit The control unit may include a control unit for controlling an operation, and the control unit may control a water supply time of the water supply unit to adjust the thickness of the ice and control the number of stages of the thickness of the ice.

Description

Ice Maker {AN ICE MAKER}

The following embodiments relate to an ice maker.

Commonly known ice makers are domestic patent registration No. 10-0178693 (November 24, 1998), Patent Registration No. 10-0691027 (February 27, 2007), and Patent Registration No. 10-1268911 (May 2013) 23) have been known as ice makers for producing snow ice (powdered ice) used as an ice cream material.

The ice maker includes a cylindrical ice-making drum that rotates with a part of its outer peripheral surface submerged in an ice-making water tank in which raw material water is supplied from a raw material water supply tank installed on the upper surface of the ice-making machine and the raw material water is temporarily stored; A refrigerant pipe for spraying a refrigerant, a recovery pipe for recovering the refrigerant sprayed in the ice-making drum, a cutting member for cutting frozen ice on the outer circumferential surface of the ice-making drum, a driving motor for rotating and driving the ice-making drum; It consists of an outer casing.

Known Patent No. 10-1609794 discloses that the first shaft installed on one side of the ice-making drum of the rotating device is configured as a refrigerant coupler to circulate the refrigerant in the ice-making drum, and at the same time, the surface of the ice-making drum is immersed in water and frozen while cutting the ice layer. The refrigerant coupler is assembled on one side of the ice-making drum and rotates together with the ice-making drum, which is a housing, which is inserted into the central passage of the housing to accommodate the refrigerant pipe block. An ice maker provided with a central passage and supported in the center of a housing at the same time having a mandrel as a fixing device, a rotating chamber and a fixing chamber installed between the mandrel and the housing, and a spring installed to apply a pressure to the rotation chamber and the fixing chamber In this case, it is possible to pass a refrigerant blocking performance test in the form of a unit part in the form of a unit part in a state separated from the refrigerant pipe block before being assembled in the ice-making drum, so that the unit part satisfying the refrigerant blocking performance is provided to the assembly of the ice-making drum, and at the same time, the refrigerant In order to match the gas expansion pressure direction and the close contact pressure direction between the two chambers, the housing is a device that is assembled on one side of the ice-making drum and rotates together with the ice-making drum, and is inserted into the central passage of the housing and the refrigerant pipe block A central passage for accommodating is provided and at the same time supported in the center of the housing, the mandrel being a fixing device, a spring 55 inserted into the spring hole of the housing to pressurize the fixing chamber to the rotating chamber with tight elasticity, and the fixing device mandrel The unit part of the ice-making drum is constituted by the mandrel cap fixed to the rear of the mandrel to support the rear of the shaft to the rear of the rotating device housing and at the same time press the spring to push the mandrel in the direction of generating tight elasticity between the two seals. In the step, the refrigerant pipe block is first assembled in the central passage of the mandrel of the unit part, and then the unit part can be assembled on one side of the ice-making drum. In such an ice maker, the area of the fixed shaft portion for fixing the refrigerant supply pipe and the refrigerant return tube of the central shaft portion increases, and as the structure of the shaft portion for fixing the refrigerant supply tube and the recovery tube of the drum ice maker increases, the size of the drum ice maker becomes unnecessary. In addition to the disadvantage of increasing, there was a problem that the high-pressure refrigerant sprayed inside the drum leaked from the rotating contact portion.

In addition, the ice maker of Patent No. 10-1482250 generates ice on the surface of the ice-making drum by immersing the ice-making drum supplied with the refrigerant into the water storage tank, and grinds the ice generated on the surface of the ice-making drum with a grinding blade. An ice powder manufacturing apparatus for manufacturing ice powder, the ice making drum comprising: a drum body having a rotating shaft connected to one side and a through hole at the other side; a refrigerant supply shaft inserted into the through hole and having a plurality of injection nozzles; a refrigerant return pipe inserted into the refrigerant supply shaft and bent toward the bottom surface of the drum body; a filter provided at the suction port of the refrigerant return pipe to filter out foreign substances mixed in the recovered refrigerant; and a hollow shaft that surrounds the coolant supply shaft and is coupled to the through hole of the drum body to rotate with respect to the coolant supply shaft together with the drum body, wherein the coolant supply shaft rotatably coupled to the hollow shaft has an outer diameter It has an increased thickness, and after the ball bearings and thrust bearings are sequentially coupled to both sides of the thick portion, a closing cap is attached to the outside of the thrust bearing so that the refrigerant leaks between the refrigerant supply shaft and the hollow shaft However, the closing cap is provided with an O-ring groove on the outer peripheral surface and an inclined surface on the inner surface, and the O-ring is inserted into the O-ring groove and the inclined surface to prevent refrigerant leakage.

An object of the present exemplary embodiment is to provide an ice maker capable of performing an ice making process by adjusting a thickness of ice according to a user's taste.

It is an object of one embodiment to provide an ice maker having a structure capable of reducing vibration generated by a compressor in the ice maker.

The ice maker according to an embodiment includes a chamber, a water supply unit that receives and provides water from the outside, a heat exchange unit disposed in the chamber to cool water provided by the water supply unit to form ice, and the water supply unit and the heat exchange unit The control unit may include a control unit for controlling an operation, and the control unit may control a water supply time of the water supply unit to adjust the thickness of the ice and control the number of stages of the thickness of the ice.

The controller is configured to extend the water supply time of the water supply unit to a preset time when the ice is to be formed thicker than the predetermined thickness based on the predetermined thickness of the ice according to the predetermined water supply time of the water supply unit, and , when it is desired to form ice thinner than the predetermined thickness, the water supply time of the water supply unit may be shortened from a preset time.

The water supply unit may include a drain case for accommodating water introduced from the outside, a pump for moving the water accommodated in the drain case, a hose for guiding the water moved by the pump, and the water transferred by the hose to the heat exchange unit It may include a water spray pipe for spraying to the side.

The heat exchange unit may include an evaporator disposed above the chamber to cool the water sprayed from the water spray pipe, and a compressor connected to the evaporator in the chamber to compress the refrigerant exchanging heat with the water in the evaporator. .

The ice maker may further include a vibration transmitting member transmitting vibration generated from the compressor to the evaporator and a vibration absorbing member transmitting vibration generated by the compressor to the evaporator.

The vibration transmitting member includes a housing disposed in the heat exchange unit, the evaporator and the compressor are accommodated in the housing, the housing and the compressor are connected to each other, and vibration generated by the compressor is transmitted to the housing By being delivered to the evaporator through the evaporator, moisture may be removed from the surface of the evaporator by vibration of the compressor.

In addition, the vibration absorbing member may include a damper connected between the lower surface of the housing and the bottom surface of the heat exchange unit, a grommet spaced apart from the damper with the lower surface of the housing interposed therebetween, and a fixing element for fixing the compressor in the housing. and the vibration may be absorbed by the damper and the grommet.

In addition, the control unit may be operated by a PCB program, and the control unit and the water supply unit may be connected by a control line.

In this case, the vibration absorbing member may be disposed on a lower side of the ice maker, and the damper may extend from a bottom surface of the heat exchange unit in a vertical direction toward a lower surface of the housing. The heat exchange units may be fixed to be spaced apart from each other.

The grommet may be disposed coaxially with the damper, and the compressor may be spaced apart from the lower surface of the housing by the grommet, and the compressor may not be directly fixed to the housing.

In addition, the vibration transmission member may further include a refrigerant line connecting both between the evaporator and the compressor, one end of the refrigerant line is connected to the compressor, and the other end of the refrigerant line is connected to the evaporator, , the vibration generated in the compressor may be transmitted to the evaporator.

Accordingly, the vibration generated in the compressor is transmitted directly to the evaporator through the refrigerant line, so that moisture can be removed from the surface of the evaporator.

The ice maker may further include a first sensor unit for measuring the thickness of the ice and a second sensor unit for measuring the strength of the ice.

In this case, when the thickness of the ice measured by the first sensor unit is smaller than a preset thickness, the amount of water supplied by the water supply unit may be increased.

Also, when the strength of the ice measured by the second sensor unit is lower than a preset strength, the cooling time by the heat exchange unit may be increased.

The ice maker according to an exemplary embodiment may perform an ice making process by adjusting a thickness of ice according to a user's taste.

The ice maker according to an exemplary embodiment may reduce vibration generated by a compressor in the ice maker.

1 shows an ice maker according to an embodiment.
2 illustrates a state of ice according to the use of an ice maker according to an exemplary embodiment.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. The following description is one of several aspects of the embodiments, and the following description forms part of the detailed description of the embodiments.

However, in describing an embodiment, a detailed description of a well-known function or configuration will be omitted in order to clarify the gist of the present invention.

In addition, the terms or words used in the present specification and claims should not be construed in a conventional or dictionary meaning, and the inventor may properly define the concept of the term in order to best describe his invention. Based on the principle that there is, it should be interpreted as meaning and concept consistent with the technical idea of the ice maker according to an embodiment.

Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiment of the ice maker according to the embodiment, and do not represent all the technical ideas of the ice maker according to the embodiment, so the present application It should be understood that there may be various equivalents and variations that may be substituted for them at any point in time.

1 shows an ice maker according to an embodiment, and FIG. 2 shows a state of ice according to the use of the ice maker according to an embodiment.

Referring to FIG. 1 , an ice maker according to an exemplary embodiment includes a chamber 100 , a water supply unit 200 that receives and provides water from the outside, and is disposed in the chamber to cool water provided by the water supply unit to form ice. and a control unit 400 for controlling the operation of the water supply unit and the heat exchange unit to can be controlled

At this time, the water supply unit 200 includes a drain case 210 for accommodating water introduced from the outside, a pump 220 for moving water accommodated in the drain case, and a hose 230 for guiding the water moved by the pump. And it may include a water spray pipe 240 for spraying the water delivered by the hose to the side of the heat exchange unit.

The heat exchange unit may include an evaporator, a condenser, and a compressor. Specifically, it may include an evaporator 310 disposed on the upper side of the chamber to cool the water sprayed from the water spray pipe, and a compressor 320 connected to the evaporator in the chamber to compress the refrigerant exchanging heat with water in the evaporator. .

The compressor is a device for compressing the refrigerant, and may be disposed on a refrigerant flow path for flowing the refrigerant from the evaporator to the condenser. For example, the compressor may receive refrigerant from the evaporator and compress it at high temperature and high pressure, and may deliver the refrigerant compressed at high temperature and high pressure to the condenser. In this case, moisture generated on the surface of the evaporator by the vibration of the compressor by the vibration transmitting member, which will be described later, can be easily removed from the surface of the evaporator.

Also, the ice maker may further include a vibration transmitting member (not shown) that transmits vibrations generated from the compressor to the evaporator, and a vibration absorbing member (not shown) that absorbs vibrations generated by the compressor.

The vibration transmitting member includes a housing disposed in the heat exchange unit, the evaporator and the compressor are accommodated in the housing, the housing and the compressor are connected to each other, and vibration generated by the compressor is transmitted to the evaporator through the housing, Moisture can be removed from the surface of the evaporator by vibration.

Specifically, an evaporator and a condenser may be disposed at an upper portion in the housing, and a compressor may be disposed at a lower portion in the housing. In this case, the housing and the compressor may be connected to each other. Thereby, the vibration generated in the compressor is transmitted to the housing and transmitted to the evaporator disposed in the housing, so that moisture generated on the surface of the evaporator can move downward from the surface of the evaporator. As a result, by naturally removing moisture existing on the surface of the evaporator from the evaporator, it is possible to effectively prevent the formation of frost on the evaporator.

In addition, the vibration absorbing member may include a damper connected between the lower surface of the housing and the bottom surface of the heat exchange unit, a grommet spaced apart from the damper with the lower surface of the housing interposed therebetween, and a fixing element for fixing the compressor in the housing. At this time, vibration may be absorbed by the damper and the grommet.

In addition, the control unit 400 is operated by a PCB program, and the control unit 400 and the water supply unit 200 may be connected by a control line 500 .

In this case, the vibration absorbing member may be disposed on the lower side of the ice maker, and the damper may extend from the bottom surface of the heat exchange unit toward the lower surface of the housing in a vertical direction, and the housing and the heat exchange unit may be fixed to be spaced apart from each other by the damper. can

The grommet may be disposed coaxially with the damper, and the compressor may be spaced apart from the lower surface of the housing by the grommet, and the compressor may not be directly fixed to the housing.

In addition, the vibration transmitting member may further include a refrigerant line connecting both between the evaporator and the compressor, one end of the refrigerant line is connected to the compressor, and the other end of the refrigerant line is connected to the evaporator, so that the vibration generated in the compressor is transmitted to the evaporator. can be transferred to the phase.

Accordingly, the vibration generated in the compressor is transmitted directly to the evaporator through the refrigerant line, so that moisture can be removed from the surface of the evaporator.

Also, the ice maker may further include a first sensor unit for measuring the thickness of the ice and a second sensor unit for measuring the strength of the ice.

In this case, when the thickness of the ice measured by the first sensor unit is thinner than the preset thickness, the amount of water supplied by the water supply unit may be increased.

Also, when the ice strength measured by the second sensor unit is lower than the preset strength, the cooling time by the heat exchange unit may be increased.

Referring to FIG. 2 , the control unit sets the water supply time of the water supply unit to a preset thickness when the ice is to be formed thicker than the predetermined thickness based on the predetermined thickness of the ice according to the predetermined water supply time of the water supply unit. In the case of extending the time and forming ice thinner than the predetermined thickness, the water supply time of the water supply unit may be shortened than the preset time.

That is, if the ice quality problem occurs when the use environment changes in the PCB PROGRAM in the simple fixing device for ice making, the default value for each product is entered into the PROGRAM as shown in FIG. The user can select the desired quality, and if the step-by-step ice quality becomes a problem, the user can derive the desired quality by manually changing the program.

The ice maker according to an embodiment including the above configuration may perform an ice making process by adjusting the thickness of ice according to a user's taste, reduce vibration generated by a compressor in the ice maker, and form on the surface of the evaporator Efficiency can be increased by efficiently removing the used moisture.

As described above, the embodiment has been described with reference to specific matters such as specific components and limited embodiments and drawings, but these are provided to help the overall understanding. In addition, the present invention is not limited to the above-described embodiments, and various modifications and variations are possible from these descriptions by those skilled in the art to which the present invention pertains. Therefore, the spirit of the present invention should not be limited to the above-described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims shall fall within the scope of the spirit of the present invention.

100: chamber
200: water supply unit
300: heat exchange unit
400: control unit
500: control line

Claims (5)

chamber;
a water supply unit that receives and provides water from the outside;
a heat exchange unit disposed in the chamber to cool the water provided by the water supply unit to form ice; and
a control unit for controlling operations of the water supply unit and the heat exchange unit;
including,
The control unit controls a water supply time of the water supply unit to adjust the thickness of the ice, and controls the number of stages of the thickness of the ice;
The control unit is
Based on a predetermined thickness of the ice according to a preset water supply time of the water supply unit,
When it is desired to form ice thicker than the predetermined thickness, the water supply time of the water supply unit is extended beyond a preset time,
When it is desired to form ice thinner than the predetermined thickness, the water supply time of the water supply unit is shortened from a preset time,
a first sensor unit for measuring the thickness of the ice; and
a second sensor unit for measuring the strength of the ice;
including,
When the thickness of the ice measured by the first sensor unit is thinner than a preset thickness, increasing the amount of water supplied by the water supply unit;
When the strength of the ice measured by the second sensor unit is lower than a preset strength, the cooling time is increased by the heat exchange unit,
The water supply unit,
a drain case for accommodating water introduced from the outside;
a pump for moving the water contained in the drain case;
a hose for guiding the water moved by the pump; and
a water spray pipe for spraying the water delivered by the hose toward the heat exchange unit;
including,
The heat exchange unit,
an evaporator disposed above the chamber to cool the water sprayed from the water spray pipe; and
a compressor connected to the evaporator in the chamber to compress a refrigerant that exchanges heat with the water in the evaporator;
including,
The user can select the quality of ice by changing the water supply time according to the pre-entered program to control the thickness of the ice.
ice machine.
delete According to claim 1,
a vibration transmitting member transmitting vibration generated from the compressor to the evaporator; and
a vibration absorbing member for absorbing vibration generated by the compressor;
further comprising,
The vibration transmitting member includes a housing disposed in the heat exchange unit,
The evaporator and the compressor are accommodated in the housing, and the housing and the compressor are connected to each other so that vibration generated by the compressor is transmitted to the evaporator through the housing, so that moisture is absorbed by the vibration of the compressor removed from the surface of the evaporator,
The vibration absorbing member,
a damper connected between the lower surface of the housing and the heat exchange unit;
a grommet spaced apart from the damper with the lower surface of the housing interposed therebetween and disposed inside the housing; and
a fixing element for fixing the compressor in the housing;
including,
and the vibration is absorbed by the damper and the grommet.
4. The method of claim 3,
The control unit is operated by a PCB program,
The control unit and the water supply unit are connected by a control line,
The vibration absorbing member may be disposed below the ice maker,
The damper may extend in a vertical direction from a bottom surface of the heat exchange unit toward a lower surface of the housing, and the housing and the heat exchange unit may be fixed to be spaced apart from each other by the damper,
The grommet may be disposed coaxially with the damper, and the compressor may be disposed to be spaced apart from the lower surface of the housing by the grommet, and the compressor may not be directly fixed to the housing;
The vibration transmitting member may further include a refrigerant line connecting both between the evaporator and the compressor,
One end of the refrigerant line is connected to the compressor, and the other end of the refrigerant line is connected to the evaporator, so that vibration generated in the compressor can be transmitted to the evaporator,
The vibration generated in the compressor is directly transmitted to the evaporator through the refrigerant line, so that moisture is removed from the surface of the evaporator.
delete

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