KR20160052021A - Ice maker - Google Patents

Abstract

The present invention relates to a combination-type ice maker having an air cooling type freezer on an upper portion. The ice maker comprises: a machine room (10) having a compressor (11) and a condenser (12); an ice-making room (30) integrated with the machine room (10); a freezer (20) located on an upper portion of the ice-making room (30); a refrigerant line (40) extending from the machine room (10) to the ice-making room (30) and to the freezer (20); and a control unit (50) to control supply of the refrigerant to the ice-making room (30) and the freezer (20). The refrigerant line (40) comprises: an ice-making room capillary tube (41) connected from the condenser (12) to an ice-making module (31) of the ice making chamber (30); a first cutoff valve (411) connected to the ice-making room capillary tube (41); a freezer capillary tube (42) connected from the condenser (12) to an unit cooler (21) of the freezer (20); a second cutoff valve (421) connected to the freezer capillary tube (42); an ice-making room low pressure pipe (43) connected from the ice-making module (31) to the compressor (11) of the machine room (10); a freezer low pressure pipe (44) connected from the unit cooler (21) to the compressor (11) of the machine room (10); a third cutoff valve (441) connected to the freezer low pressure pipe (44); a hotline (46) integrated with a connection pipe (45) between the compressor (11) and the condenser (12), and connected to the ice-making module (31); and a hotline valve (461) integrated with the hotline (46).

Description

 Ice maker with an air-cooled freezer at the top {

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ice maker, and more particularly, to a combi-ice maker having an air-cooled freezer at an upper portion thereof.

An ice maker is a device that continuously mass-produces ice blocks with a uniform shape. These ice machines are widely used in shipyards and cafes. The ice maker consists largely of an ice making room for ice generation and ice storage, and a machine room in which a cooling system for circulation and cooling of the refrigerant is installed.

On the other hand, a refrigerator was separately provided in a shop, and the food was frozen and stored. Therefore, the employer had to purchase the refrigerator and the ice maker separately.

However, in the case of a narrow space, there was not enough room to place the freezer and ice maker. Also, it was an economic burden if they were to be separately provided.

Therefore, it has become necessary to develop an ice-maker having both an ice-making function and a freezing function.

Technical documents related to the ice maker include Korean Patent Laid-Open Nos. 10-2001-0051251 and Korean Patent Laid-Open No. 10-2006-0036986.

The present invention provides an ice maker having a freezing chamber and a freezing chamber together.

The present invention also provides an ice maker for driving both the ice making chamber and the freezing chamber by using one compressor and a condenser.

The present invention also provides an ice-maker having an upper portion of a freezer that operates in air-cooling mode.

According to an aspect of the present invention,

A machine room (10) having a compressor (11) and a condenser (12);

An ice making chamber 30 coupled with the machine room 10;

A freezing chamber 20 located above the ice making chamber 30;

A refrigerant line (40) starting from the machine room (10) and connected to the ice making chamber (30) and the freezing chamber (20);

And a controller (50) for controlling the refrigerant supplied to the ice making chamber (30) and the freezing chamber (20)

The refrigerant line (40)

An ice-making chamber capillary (41) connected to the ice-making module (31) of the ice-making chamber (30) in the condenser (12);

A first shut-off valve 411 coupled to the ice-making chamber capillary 41;

A freezer compartment capillary 42 connected to the unit cooler 21 of the freezer compartment 20 in the condenser 12;

A second shutoff valve (421) coupled to the freezer compartment capillary (42);

An ice making chamber low pressure pipe (43) connected from the ice making module (31) to the compressor (11) of the machine room (10);

A freezing chamber low pressure pipe (44) connected to the compressor (11) of the machine room (10) in the unit cooler (21);

A third shut-off valve (441) coupled to the freezing compartment low pressure pipe (44);

A hot line (46) coupled to the connection pipe (45) located between the compressor (11) and the condenser (12) and connected to the ice making module (31);

There is provided a combi-ice maker having an air-cooled freezer at the top including a hot-line valve 461 coupled to the hot line 46.

Also,

The control unit (50)

The first shut-off valve 411, the second shut-off valve 421 and the third shut-off valve 441 are opened and the hot-line valve 461 is shut off so that the freezing chamber 20 and the The refrigerant circulated through the freezing chamber 20 and the ice making chamber 30 is recovered by the compressor 11,

The second shutoff valve 421 and the third shutoff valve 441 are shut off and the hot line valve 461 is opened so that hot gas does not flow into the freezing chamber 20, And the hot gas flows to the outdoor unit (31).

The present invention provides an ice maker having a freezing chamber and a freezing chamber together.

The present invention also provides an ice maker for driving both the ice making chamber and the freezing chamber by using one compressor and a condenser.

In addition, the present invention provides an ice-maker equipped with a freezer operating in air-cooling mode.

In addition, the present invention provides an ice maker in which a freezing chamber is located at the top.

1 is a cross-sectional view (icing and freezing process) of a combi-type ice maker having an air-cooled freezer at the top according to an embodiment of the present invention;
FIG. 2 is a cross-sectional view of a combi-type ice maker having an air-cooled freezer at an upper part according to an embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. , Thereby not limiting the spirit and scope of the present invention.

The freezing chamber of the present embodiment may have only a refrigerating function or a refrigerating function.

FIG. 1 is a cross-sectional view (icing and freezing process) of a combi-type ice maker having an air-cooled freezer at an upper portion thereof according to an embodiment of the present invention. FIG. 2 is a cross- (The process of evacuation).

In the combi-type ice maker 100 having the air-cooled freezer on the upper part of this embodiment,

A machine room (10) having a compressor (11) and a condenser (12);

An ice making chamber 30 coupled with the machine room 10;

A freezing chamber 20 located above the ice making chamber 30;

A refrigerant line (40) starting from the machine room (10) and connected to the ice making chamber (30) and the freezing chamber (20);

And a controller (50) for controlling the refrigerant supplied to the ice making chamber (30) and the freezing chamber (20)

The refrigerant line (40)

An ice-making chamber capillary (41) connected to the ice-making module (31) of the ice-making chamber (30) in the condenser (12);

A first shut-off valve 411 coupled to the ice-making chamber capillary 41;

A freezer compartment capillary 42 connected to the unit cooler 21 of the freezer compartment 20 in the condenser 12;

A second shutoff valve (421) coupled to the freezer compartment capillary (42);

An ice making chamber low pressure pipe (43) connected from the ice making module (31) to the compressor (11) of the machine room (10);

A freezing chamber low pressure pipe (44) connected to the compressor (11) of the machine room (10) in the unit cooler (21);

A third shut-off valve (441) coupled to the freezing compartment low pressure pipe (44);

A hot line (46) coupled to the connection pipe (45) located between the compressor (11) and the condenser (12) and connected to the ice making module (31);

And a hotline valve (461) coupled to the hotline (46).

The ice maker 100 of the present embodiment has both a freezing function and an ice-making function. In order for these functions to operate in combination, the controller 50 must control the flow of the refrigerant effectively. The freezing chamber 20 is coupled to the unit cooler 21.

The unit cooler 21 may include a fan and a temperature controller.

The machine room 10 is generally located below the ice maker 100. The machine room 10 includes a compressor 11, a condenser 12, a blower 13, and the like, which are similar to the machine room of a general ice maker. Therefore, detailed description of the specific configuration of the machine room 10 is omitted.

The freezing chamber 20 receives refrigerant from the machine room 10. The refrigerant compressed in the machine room (10) is transferred to the freezer compartment (20). The freezing chamber 20 of the present embodiment operates in an air-cooling manner, and the unit cooler 21 is located inside. Heat exchange takes place immediately in the unit cooler 21.

The ice making chamber 30 is located below the freezing chamber 20. An ice making module (31) is located inside the ice making chamber (30) to form ice pieces. The ice-making module 31 can use all known techniques.

The ice making module 31 generates ice through an ice-making process and a de-ice process. In the ice-making process, the low-temperature refrigerant is supplied to the ice-making module 31, and the water sprayed from the lower portion is frozen on the surface of the ice-making module 31 to grow ice. Thereafter, when the ice is sufficiently grown, the hot gas is supplied to the ice-making module 31 in the course of the ice-making process. This removes the ice combined with the ice frame.

The core technology of the present embodiment is such that low temperature refrigerant is supplied to the ice-making module 31 of the ice-making chamber 30 and the unit cooler 21 of the freezer 20 in the ice-making process, And the valves are controlled so that the hot gas is not supplied to the unit cooler 21.

The refrigerant line 40 is connected to the freezing chamber 20 and the ice making chamber 30 starting from the machine room 10. In this refrigerant line 40, valves are coupled, and the control unit 50 controls these valves to control the refrigerant supplied to the ice making chamber 30 and the freezing chamber 20.

The ice-making chamber capillary tube 41 is connected from the condenser 12 to the ice-making module 31 of the ice-making chamber 30. The ice-making chamber capillary tube 41 absorbs heat while the liquid-state refrigerant in the ice-making chamber 31 is converted into a gas by the ice-making module 31 in the ice-making chamber 30. The first shutoff valve 411 is coupled to the ice-making chamber capillary tube 41, and the first shutoff valve 411 is automatically opened and closed under the control of the controller 50.

The freezer capillary tube 42 is connected from the condenser 12 to the unit cooler 21 of the freezer compartment 20. The refrigerant supplied to the freezer compartment capillary tube 42 is converted into gas from the unit cooler 21 of the freezer compartment 20 and takes heat. A second shutoff valve 421 is coupled to the freezing compartment capillary tube 42. The second shutoff valve 421 is automatically opened and closed under the control of the controller 50.

The ice making room low pressure pipe 43 is connected from the ice making module 31 to the compressor 11 of the machine room 10. The refrigerant expanded by the ice-making module 31 to absorb heat and gasified is recovered to the compressor 11 along the ice-making chamber low-pressure pipe 43.

The freezing compartment low pressure pipe 44 is connected from the unit cooler 21 to the compressor 11 of the machine room 10. The refrigerant expanded in the unit cooler 21 and converted into gas is recovered to the compressor 11 again along the freezer compartment low pressure pipe 44. And the third shutoff valve 441 is coupled to the freezing room low pressure pipe 44).

Meanwhile, a coupling pipe 45 is coupled between the compressor 11 and the condenser 12. The high-temperature and high-pressure refrigerant which has passed through the compressor 11 is moved to the condenser 12. [ A hot line (46) is branched to the connector (45). The hot line 46 is connected to the ice making module 31 of the ice making chamber 30 to supply hot gas to the ice making module 31. Hot gas is needed in the process of evacuation. A hot line valve 461 is coupled to the hot line 46, and the hot line valve 461 is controlled by the control unit 50.

A method in which the control unit 50 controls the valves during the deicing process and the deicing process is as follows.

The controller 50 opens the first shut-off valve 411, the second shut-off valve 421, and the third shut-off valve 441 during the de-icing process. Further, the controller 50 cuts off the hot-line valve 461 in the ice-making process. As a result, the refrigerant is supplied to the freezing chamber 20 and the ice making chamber 30 in the ice-making process. In the ice-making process, the refrigerant circulating through the freezing compartment 20 and the ice-making compartment 30 is recovered by the compressor 11.

The control unit 50 cuts off the second shut-off valve 421 and the third shut-off valve 441 during the descaling process. Further, the control unit 50 opens the hot-line valve 461. [ As a result, the hot gas moves to the ice-making module 31 through the hot line 46. Ice attached to the ice-making frame of the ice-making module 31 is scooped down by gravity and falls downward. In addition, the second shutoff valve 421 and the third shutoff valve 441 are shut off so that hot gas does not flow into the freezing chamber 20. Therefore, the foods in the freezing compartment 20 are not dissolved.

The controller 50 effectively controls the valves during the ice-making process and the de-icing process so that both the ice-making chamber 30 and the freezing chamber 20 are operated by the single compressor 11 and the condenser 12.

When the ice maker 100 of the present embodiment is used, the ice making chamber 30 and the freezing chamber 20 can be completed as a single product.

The icemaker 100 of the present embodiment may have all or some of the functions of the existing icemaker in the icemaker 30. For example, a device such as a water jetting device for supplying water from the outside and jetting to an ice-making module, a circulating pump for circulating water, a drain for discharging overflowed water to the outside can be installed in the ice- In addition, a door for taking out ice and an ice reservoir for storing ice can be installed in the ice making chamber 30.

In addition, the air-cooled freezer compartment 20 of the present embodiment can have all or selectively the functions of the conventional air-cooled freezer compartment.

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 exemplary embodiments. Modifications and additions by those skilled in the art to an equivalent range based on the embodiment will also fall within the scope of the present invention.

A combi-type ice maker 100 having an air-
Compressors (11) Condensers (12)
Machine room (10) Freezer room (20)
In the ice making chamber 30, the refrigerant line 40,
The ice-making chamber capillary (41)
The first shutoff valve 411, the freezer compartment capillary 42,
The second shut-off valve 421, the ice-making chamber low-pressure pipe 43,
Freezer Low Pressure Tube (44) Third Isolation Valve (441)
Hotline (46) Hotline Valves (461)

Claims (2)

A machine room (10) having a compressor (11) and a condenser (12);
An ice making chamber 30 coupled with the machine room 10;
A freezing chamber 20 located above the ice making chamber 30;
A refrigerant line (40) starting from the machine room (10) and connected to the ice making chamber (30) and the freezing chamber (20);
And a controller (50) for controlling the refrigerant supplied to the ice making chamber (30) and the freezing chamber (20)

The refrigerant line (40)
An ice-making chamber capillary (41) connected to the ice-making module (31) of the ice-making chamber (30) in the condenser (12);
A first shut-off valve 411 coupled to the ice-making chamber capillary 41;
A freezer compartment capillary 42 connected to the unit cooler 21 of the freezer compartment 20 in the condenser 12;
A second shutoff valve (421) coupled to the freezer compartment capillary (42);
An ice making chamber low pressure pipe (43) connected from the ice making module (31) to the compressor (11) of the machine room (10);
A freezing chamber low pressure pipe (44) connected to the compressor (11) of the machine room (10) in the unit cooler (21);
A third shut-off valve (441) coupled to the freezing compartment low pressure pipe (44);
A hot line (46) coupled to the connection pipe (45) between the compressor (11) and the condenser (12) and connected to the ice making module (31);
(461) coupled to the hot line (46).

The method according to claim 1,
The control unit (50)
The first shut-off valve 411, the second shut-off valve 421 and the third shut-off valve 441 are opened and the hot-line valve 461 is shut off so that the freezing chamber 20 and the The refrigerant circulated through the freezing chamber 20 and the ice making chamber 30 is recovered by the compressor 11,
The second shutoff valve 421 and the third shutoff valve 441 are closed and the hot line valve 461 is opened to control the flow of hot gas into the freezing chamber 20 And an air-cooled freezer at the upper part.

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