KR20220018181A - refrigerator - Google Patents

Abstract

The present invention can improve a structure of a portion of a fluid outlet of a frost detection duct, can design depth of a flow passage inside a guide flow passage where water can be easily drained, and can prevent frost of an inlet portion or the inside of the flow passage of a frost detection device due to defrost water or other condensate generated during defrosting operation by application of at least one structure among slope structures of an inlet of the flow passage.

Description

refrigerator {refrigerator}

The present invention relates to a new type of refrigerator capable of preventing an implantation of an implantation detection device into a flow path due to defrost water or other condensed water generated during a defrosting operation.

BACKGROUND ART In general, a refrigerator is a device that allows storage objects stored in a storage space to be stored for a long time or while maintaining a constant temperature by using cold air.

The refrigerator is provided with a refrigeration system including one or two or more evaporators and is configured to generate and circulate the cold air.

Here, the evaporator functions to heat-exchange the low-temperature and low-pressure refrigerant with the air inside the refrigerator (cold air circulating in the refrigerator) to maintain the air in the refrigerator within a set temperature range.

During heat exchange with the air in the refrigerator, frost is generated on the surface of the evaporator due to moisture or moisture contained in the air in the refrigerator or moisture existing around the evaporator.

Conventionally, when a predetermined time elapses after the operation of the refrigerator is started, a defrosting operation for removing the frost generated on the surface of the evaporator is performed.

That is, conventionally, the defrosting operation is performed through indirect estimation based on the operation time, rather than directly detecting the amount of frost (implantation amount) generated on the surface of the evaporator.

Accordingly, conventionally, there is a problem in that consumption efficiency is lowered due to the defrosting operation being performed even though the frosting is not performed, or the defrosting operation is not performed despite the excessive implantation.

In particular, the above-described defrosting operation is operated to perform defrosting by heating the heater to raise the ambient temperature of the evaporator. had no choice but to

Accordingly, in the prior art, various studies have been made to shorten the time for the defrost operation or the period for the defrost operation.

Recently, in order to accurately check the amount of implantation on the surface of the evaporator, a method using the temperature difference or pressure difference between the inlet side and the outlet side of the evaporator has been proposed. Patent No. 10-2019-0106201, Patent Publication No. 10-2019-0106242, Patent Publication No. 10-2019-0112482, Patent Publication No. 10-2019-0112464, etc. as presented.

That is, in the above-described technique, an implantation detection duct is formed in the cold air duct to have a flow separate from the air flow through the evaporator, and the temperature difference that changes according to the difference in the amount of air passing through the implantation detection duct is measured and defrosted. It is designed to accurately determine the starting point of driving.

On the other hand, in the case of the prior art described above, there is a case in which the defrost water generated by melting ice deposited on the evaporator while the defrosting operation is being performed is introduced into the implantation detection duct.

At this time, the defrost water introduced into the implantation detection duct was not completely discharged from the implantation detection duct due to a sensor located in the corresponding implantation detection duct, and some remained.

That is, in the case of the implantation detection duct, since the flow path is narrow and long, it may cause a case where the temperature stays below zero even while the defrost operation is being performed, which causes a phenomenon in which the defrost water freezes while flowing down the implantation detection duct. it has become

However, conventionally, a structure for preventing the closure of the implantation detection duct or freezing of the sensor by the defrost water introduced into the implantation detection duct is not provided. There was a problem that the duct was closed or the sensor was frozen.

Of course, there is always a risk of closure of the implantation detection duct or freezing of the sensor even by condensed water caused by a temperature difference inside and outside the landing detection duct, not the defrost water.

In addition, the above-mentioned implantation detection duct according to the prior art has a problem in that the moisture flowing along the outer wall surface of the fluid inlet side is gradually frozen at the fluid inlet to close the corresponding fluid inlet.

That is, in the conventional implantation detection duct, a phenomenon in which moisture existing on the outer wall surface of the fluid inlet does not fall from the fluid inlet and remains, and the remaining moisture freezes and closes the fluid inlet.

In addition, in the conventional technology for implantation detection, the heating element and the sensing element of the sensor for implantation detection are installed to face the inside of the flow path through which the fluid flows.

However, there were cases in which the sensor was installed in an upside-down state (the back side of the PCB faces the inside of the flow path) due to the carelessness of the operator. No, there was a problem in that control failure was generated.

Patent Publication No. 10-2019-0101669 Patent Publication No. 10-2019-0106201 Patent Publication No. 10-2019-0106242 Patent Publication No. 10-2019-0112482 Patent Publication No. 10-2019-0112464

The present invention has been devised to solve the various problems according to the prior art described above, and an object of the present invention is to allow the defrosting water or moisture introduced into the implantation detection duct to be smoothly discharged, so that the defrosting water or moisture can cause an implantation detection duct An object of the present invention is to provide a new type of refrigerator that can prevent internal closure or sensor freezing.

Another object of the present invention is to provide a refrigerator of a new type capable of preventing the phenomenon of moisture flowing along the outer wall surface of the fluid inlet side of the implantation detection duct from freezing at the fluid inlet.

In addition, the present invention allows the operator to accurately recognize when the implantation confirmation sensor for implantation detection is installed in an inverted state, thereby preventing control failure caused by inaccurate measurement values due to incorrect mounting of the implantation confirmation sensor. The goal is to provide a new type of refrigerator that is designed to help.

In order to achieve the above object, in the refrigerator of the present invention, an inclined surface may be included on the outer surface of the flow path cover dividing the implantation detection duct. Accordingly, it is possible to prevent moisture from condensing on the outer surface of the flow path cover and freezing.

In addition, in the refrigerator of the present invention, an inclined surface may be formed on a circumferential wall surface of the fluid inlet provided at the lower end of the flow path cover. Accordingly, it is possible to prevent moisture from condensing on the outer surface of the fluid inlet and freezing.

In addition, in the refrigerator of the present invention, inclined surfaces formed in the fluid inlet may be respectively formed on both side walls of the fluid inlet. Accordingly, it is possible to prevent the moisture present on the wall surfaces of both sides of the fluid inlet from flowing down the inclined surface and freezing in the corresponding area.

In addition, in the refrigerator of the present invention, a contact protrusion may be formed to protrude from the flow path cover. Accordingly, when the implantation confirmation sensor is incorrectly mounted on the implantation detection duct, the flow path cover is not completely coupled to the installation detection duct by the contact protrusion, and the operator can accurately recognize this.

In addition, in the refrigerator of the present invention, the concave depth (D) of the implantation detection duct may be made to satisfy the condition of (1.5mm*2)+T≤D with respect to the thickness (T) of the implantation confirmation sensor. Accordingly, even if the defrost water flows down into the implantation detection duct, it is possible to prevent the defrost water from icing on the implantation confirmation sensor.

In addition, in the refrigerator of the present invention, an open portion of the implantation detection duct to allow the fluid to flow out may be disposed to be exposed to a flow path formed between the cold air heat source and the second duct. Accordingly, the fluid passing through the implantation detection duct is not affected by the cold air heat source.

In addition, in the refrigerator of the present invention, a portion of the implantation detection duct that is opened to allow fluid to flow therein may be disposed to be exposed to a flow path formed between the first duct and the cold air heat source. Accordingly, the fluid flowing into the first duct and flowing to the cold air heat source may be partially introduced into the implantation detection duct.

In addition, the refrigerator of the present invention may include at least one of temperature, pressure, and flow rate as a physical property value measured by an implantation detection device.

In addition, in the refrigerator of the present invention, the conception confirmation sensor may be configured to include a sensing element and a sensing derivative.

In addition, in the refrigerator of the present invention, the sensing derivative constituting the implantation sensing device may include a heating element generating heat, and the sensing element constituting the implantation sensing device may include a sensor measuring the temperature of heat. Accordingly, the implantation detection device can measure the temperature difference value (logic temperature) (ΔHt) according to the flow amount of the fluid.

In addition, the refrigerator of the present invention may include a fluid outlet in which the implantation detection duct is located in the shroud. Accordingly, the fluid passing through the implantation detection duct may flow out through the portion where the fluid outlet of the shroud is located.

In addition, the refrigerator of the present invention may include a guide passage through which the implantation detection duct is located on the rear surface of the grill pan.

Also, in the refrigerator of the present invention, a portion of the fluid outlet formed in the shroud may be concave into the guide passage formed in the grill pan. Accordingly, even if the defrost water is introduced through the fluid outlet, it can smoothly flow down into the guide flow path of the grill pan.

In addition, the refrigerator of the present invention may be configured such that any one portion of the flow path cover constituting the implantation detection device is in contact with the implantation confirmation sensor installed in the implantation detection duct. As a result, when the implantation confirmation sensor is not correctly coupled, the flow path cover is also not coupled correctly, so that the operator can accurately recognize it.

In addition, in the refrigerator of the present invention, a contact protrusion may be formed on the flow path cover. Accordingly, when the flow path cover is installed, the contact protrusion may come into contact with the implantation confirmation sensor.

In addition, the refrigerator of the present invention may be configured such that installation grooves are respectively formed on both side walls of the implantation detection duct, and both ends of the implantation confirmation sensor are respectively inserted into the installation grooves. Thereby, the implantation confirmation sensor can be installed in the correct position.

In addition, the refrigerator of the present invention may be formed so that the contact protrusion of the flow path cover is recessed into the installation groove. Accordingly, the contact protrusion may be in contact with the end of the implantation confirmation sensor located in the installation groove.

In addition, in the refrigerator of the present invention, a protruding end may be protruded from the conception confirmation sensor, and a concave groove may be formed in the installation groove. In this way, it is possible to recognize whether the implantation confirmation sensor is correctly installed.

In addition, in the refrigerator of the present invention, the signal line connected to the implantation confirmation sensor is horizontally drawn out from the implantation detection duct to the back surface of the guide duct forming the shroud, and then bent in the vertical direction while in contact with the outer surface of the guide duct, and then bent upward. It may be configured to be withdrawn. Accordingly, it is possible to prevent a problem that the signal line is damaged due to contact with or stamped on the cold air heat source.

In addition, the refrigerator of the present invention may be provided with a coupling portion to the flow path cover. Thereby, the flow path cover can be accurately coupled to the implantation detection duct.

In addition, the refrigerator of the present invention may be provided with a first coupling portion at the upper end of the flow path cover. Accordingly, the upper end of the flow path cover can be accurately coupled to the implantation detection duct.

In addition, the refrigerator of the present invention may be provided with a second coupling portion at the lower end of the flow path cover. Accordingly, the lower end of the flow path cover can be accurately coupled to the implantation detection duct.

As described above, in the refrigerator of the present invention, since moisture such as condensed water generated on the side wall of the fluid inlet can be discharged while flowing down without condensing on the corresponding part, the phenomenon of condensing and freezing at the fluid inlet can be prevented. have the effect of being

In addition, in the refrigerator of the present invention, since the concave depth (D) of the implantation detection duct satisfies the condition of (1.5mm*2)+T≤D with respect to the thickness (T) of the implantation confirmation sensor, each It has the effect that moisture can pass smoothly through the gap between the wall surface and the implantation confirmation sensor, and freezing of the implantation confirmation sensor can be prevented.

In addition, in the refrigerator of the present invention, since the mounting protrusion formed on the fluid inlet side of the fluid outlet is formed to be concave in the guide passage, even if moisture such as defrost water or condensed water flows into the fluid outlet, it does not accumulate at the connection portion between the fluid outlet and the guide passage. It has the effect of being able to flow smoothly without

In addition, since the refrigerator of the present invention is configured such that at least one portion of the flow path cover is in contact with the implantation confirmation sensor, it is possible to recognize whether the implantation confirmation sensor is installed incorrectly through the correct coupling of the flow path cover.

In addition, since the refrigerator of the present invention is provided with a coupling portion for coupling with the implantation detection duct on the flow path cover, the flow path cover can be accurately mounted and maintained.

In addition, since the refrigerator of the present invention is installed without interfering with the fluid flow while the signal line drawn out from the conception confirmation sensor has the shortest possible path, damage to the signal line can be prevented.

1 is a front view schematically showing the internal configuration of a refrigerator according to an embodiment of the present invention;
2 is a longitudinal cross-sectional view schematically showing the configuration of a refrigerator according to an embodiment of the present invention;
3 is a view schematically illustrating an operation state performed according to an operation reference value based on a user-set reference temperature for each storage compartment of the refrigerator according to an embodiment of the present invention;
4 is a block diagram schematically illustrating a control structure of a refrigerator according to an embodiment of the present invention;
5 is a state diagram schematically showing the structure of a thermoelectric module according to an embodiment of the present invention;
6 is a block diagram schematically illustrating a refrigeration cycle of a refrigerator according to an embodiment of the present invention;
7 is a cross-sectional view showing a main part of a space on the rear side of a second storage compartment in a case to explain an installation state of an implantation detection device and an evaporator constituting a refrigerator according to an embodiment of the present invention;
8 is an enlarged view of part “A” of FIG. 7
9 is an exploded perspective view of the front side of the fan duct assembly shown to explain the installation state of the implantation detection device constituting the refrigerator according to the embodiment of the present invention;
10 is an exploded perspective view of the rear side of the fan duct assembly shown to explain the installation state of the implantation detection device constituting the refrigerator according to the embodiment of the present invention;
11 is a rear perspective view of the fan duct assembly shown to explain the installation state of the implantation detection device constituting the refrigerator according to the embodiment of the present invention;
12 is an exploded perspective view illustrating a state in which a flow path cover and a sensor are separated from a fan duct assembly of a refrigerator according to an embodiment of the present invention;
13 is an enlarged view of part “B” of FIG. 12
14 is a state diagram of the fan duct assembly viewed from the rear in order to explain the relationship between the installation positions of the implantation detection device and the cold air heat source constituting the refrigerator according to the embodiment of the present invention;
15 is a rear view of the fan duct assembly from the rear to explain the installation state of the implantation detection device constituting the refrigerator according to the embodiment of the present invention;
16 is a front view illustrating a front state of a shroud constituting a fan duct assembly of a refrigerator according to an embodiment of the present invention;
17 is an enlarged view of part “C” of FIG. 7
18 is a state diagram of main parts showing the internal structure of an implantation detection duct constituting an implantation detection device of a refrigerator according to an embodiment of the present invention;
19 is a perspective view showing the structure of a guide passage and a fluid outlet of an implantation detection duct constituting an implantation detection device of a refrigerator according to an embodiment of the present invention;
20 is a perspective view of main parts showing a coupling relationship between a guide passage and a fluid outlet forming an implantation detection duct of a refrigerator according to an embodiment of the present invention;
21 is a perspective view of a main part illustrating a state in which a flow path cover is installed in an implantation detection duct of a refrigerator according to an embodiment of the present invention;
22 is a rear view illustrating a state in which a flow path cover is installed in an implantation detection duct of a refrigerator according to an embodiment of the present invention;
23 is a rear perspective view illustrating a flow path cover constituting an implantation detection device of a refrigerator according to an embodiment of the present invention;
24 is a rear view illustrating a flow path cover constituting an implantation detection device of a refrigerator according to an embodiment of the present invention;
25 is a front perspective view illustrating a flow path cover constituting an implantation detection device of a refrigerator according to an embodiment of the present invention;
26 is an enlarged view of part “D” of FIG. 25
27 is a side view of the main part shown to explain the first coupling part of the flow path cover constituting the implantation detection device of the refrigerator according to the embodiment of the present invention;
28 is an enlarged view of part “E” of FIG. 25
29 is a main part state diagram showing a state in which a contact protrusion formed on a flow path cover of a refrigerator presses an implantation confirmation sensor according to an embodiment of the present invention;
30 is a main part state diagram showing the state of the flow path cover when the implantation confirmation sensor of the refrigerator according to the embodiment of the present invention is incorrectly installed;
31 is an enlarged view of the “F” part of FIG.
32 is an enlarged view of the “G” part of FIG. 22
33 is an enlarged view of the “H” part of FIG. 25
34 is a state diagram showing the main part to explain a portion where the second coupling part of the flow path cover is coupled according to an embodiment of the present invention;
35 and 36 are enlarged views of main parts shown to explain the flow of fluid depending on whether the implantation detection device according to an embodiment of the present invention is implanted;
37 is a state diagram schematically illustrating a state in which an implantation confirmation sensor is installed in an implantation detection duct constituting an implantation detection device of a refrigerator according to an embodiment of the present invention;
38 is a schematic diagram illustrating an implantation confirmation sensor of an implantation detection device according to an embodiment of the present invention;
39 is a perspective view of a main part showing a structure in which an implantation confirmation sensor is installed in an implantation detection duct of a refrigerator according to an embodiment of the present invention;
40 is a flowchart illustrating a control process by a controller during an implantation detection operation of a refrigerator according to an embodiment of the present invention;
41 and 42 are diagrams illustrating the temperature change in the implantation detection duct according to the on/off of the heating element and the on/off of each cooling fan in a state in which the evaporator of the refrigerator according to the embodiment of the present invention is implanted. state diagram

The present invention provides a new type of refrigerator capable of preventing implantation in the flow path or inlet side of an implantation detection device due to defrost water or other condensed water generated during a defrosting operation.

In addition, the present invention provides a new type of refrigerator so that an operator can accurately recognize when an implantation confirmation sensor is incorrectly coupled.

An embodiment of a preferred structure of the refrigerator according to the present invention and an embodiment of an operation control process will be described with reference to FIGS. 1 to 42 attached thereto.

1 is a front view schematically showing the internal configuration of a refrigerator according to an embodiment of the present invention, and FIG. 2 is a longitudinal cross-sectional view schematically showing the configuration of a refrigerator according to an embodiment of the present invention.

As shown in these drawings, the refrigerator 1 according to the embodiment of the present invention may include a case 11 .

The case 11 includes an inner-case 11a forming an inner wall surface of the refrigerator 1 and an outer case 11b forming an exterior surface of the refrigerator 1, and in this case 11, A storage room in which the stored material is stored may be provided.

Only one storage compartment may be provided, or a plurality of two or more storage compartments may be provided. In an embodiment of the present invention, it is assumed that the storage chamber includes two storage chambers for storing stored materials in different temperature regions.

The storage chamber may include a first storage chamber 12 maintained at a first set reference temperature.

The first set reference temperature may be a temperature at which the stored object is not frozen, but may be in a temperature range lower than the external temperature (indoor temperature) of the refrigerator 1 .

For example, the first set reference temperature may be made of a freezer temperature of 32°C or less and greater than 0°C. Of course, the first set reference temperature may be set higher than 32°C, or equal to or lower than 0°C, if necessary (eg, according to the indoor temperature or the type of storage).

In particular, the first set reference temperature may be the internal temperature of the first storage compartment 12 set by the user, and if the user does not set the first set reference temperature, an arbitrarily designated temperature is the first It can be used as a set reference temperature.

In addition, the first storage compartment 12 may be configured to operate at a first operating reference value for maintaining the first set reference temperature.

The first operation reference value is a temperature range value including the first lower limit temperature (NT-DIFF1) and the first upper limit temperature (NT+DIFF1).

That is, when the internal temperature of the refrigerator in the first storage chamber 12 reaches the first lower limit temperature NT-DIFF1 based on the first set reference temperature, the operation for supplying cold air is stopped. On the other hand, when the internal temperature of the refrigerator is increased based on the first set reference temperature, the operation for supplying cold air may be resumed before the first upper limit temperature (NT+DIFF1) is reached.

As such, cold air is supplied or stopped in the first storage compartment 12 in consideration of the first operation reference value for the first storage compartment based on the first set reference temperature.

The set reference temperature NT and the operating reference value DIFF are as shown in FIG. 3 .

In addition, the storage chamber may include a second storage chamber 13 maintained at a second set reference temperature.

The second set reference temperature may be a temperature lower than the first set reference temperature. In this case, the second set reference temperature may be set by the user, and when the user does not set the temperature, an arbitrarily prescribed temperature is used.

The second set reference temperature may be a temperature sufficient to freeze the stored object. For example, the second set reference temperature may include a temperature of 0 ℃ or less -24 ℃ or more.

Of course, the second set reference temperature may be set higher than 0°C, or equal to or lower than -24°C, if necessary (eg, depending on the room temperature or the type of storage).

In particular, the second set reference temperature may be the internal temperature of the second storage chamber 13 set by the user, and if the user does not set the second set reference temperature, the arbitrarily designated temperature is the second It can be used as a set reference temperature.

In addition, the second storage chamber 13 may be operated at a second operation reference value for maintaining the second set reference temperature.

The second operation reference value may include a second lower limit temperature (NT-DIFF2) and a second upper limit temperature (NT+DIFF2).

That is, when the internal temperature of the refrigerator in the second storage chamber 13 reaches the second lower limit temperature NT-DIFF2 based on the second set reference temperature, the operation for supplying cold air may be stopped. On the other hand, when the internal temperature of the refrigerator is increased based on the second set reference temperature, the operation for supplying cold air may be resumed before the second upper limit temperature (NT+DIFF2) is reached.

As such, cold air is supplied or stopped in the second storage chamber 13 in consideration of the first operation reference value for the second storage chamber 13 based on the second set reference temperature.

In particular, the first operation reference value may be set to have a smaller range between the upper limit temperature and the lower limit temperature than the second operation reference value.

For example, the first lower limit temperature (NT-DIFF1) and the first upper limit temperature (NT+DIFF1) of the first operation reference value may be set to ±2.0 °C, and the second lower limit temperature (NT-DIFF2) of the second operation reference value ) and the second upper limit temperature (NT+DIFF2) may be set to ±1.5°C.

On the other hand, the above-described storage chamber is made to maintain the internal temperature of the storage chamber while the fluid is circulated.

The fluid may be air. In the following description, the fluid circulating in the storage chamber is air as an example. Of course, the fluid may be a gas other than air.

The temperature outside the storage chamber (internal temperature) may be measured by the first temperature sensor 1a as shown in FIG. 9, and the internal temperature (temperature in the storage chamber) is measured by the second temperature sensor 1b. can be measured.

The first temperature sensor 1a and the second temperature sensor 1b may be formed separately. Of course, the indoor temperature and the internal temperature of the refrigerator may be measured by the same single temperature sensor, or two or more temperature sensors may be configured to measure cooperatively.

The second temperature sensor 1b may be provided in a second duct (eg, a second fan duct assembly) to be described later, as shown in FIG. 10 .

1 and 2, the storage compartments 12 and 13 may be provided with doors 12b and 13b.

The doors 12b and 13b serve to open and close the storage compartments 12 and 13, and may have a rotational opening/closing structure or a drawer type opening/closing structure.

One or more of the doors 12b and 13b may be provided.

Next, the refrigerator 1 according to the embodiment of the present invention may include a cold air heat source.

The cold air heat source is configured to generate cold air and supply it to the storage room.

A structure for generating cold air of such a cold air heat source may be made in various ways.

For example, the cold air heat source may include a thermoelectric module 23 .

At this time, the thermoelectric module 23 includes a thermoelectric element 23a including a heat absorbing surface 231 and a heat generating surface 232 as shown in FIG. 5 , and at least one of the heat absorbing surface 231 and the heat generating surface 232 . It can be a module comprising a sink 23b connected to one.

In the embodiment of the present invention, the structure for generating cold air from the cold air heat source is made of a refrigeration system including evaporators 21 and 22 and a compressor as an example.

The evaporators 21 and 22 form a refrigeration system together with a compressor 60 (see attached FIG. 6 ), a condenser (not shown), and an expander (not shown), and exchange heat with air passing through the evaporator. It functions to lower the temperature of the air.

When the storage chamber includes a first storage chamber 12 and a second storage chamber 13 , the evaporator includes a first evaporator 21 for supplying cold air to the first storage chamber 12 and the second storage chamber 13 . A second evaporator 22 for supplying cold air to the furnace may be included.

At this time, the first evaporator 21 is located on the rear side of the first storage chamber 12 in the inner case 11a, and the second evaporator 22 is located on the rear side of the second storage chamber 13 . can be located on the side.

Of course, although not shown, the evaporator may be provided only in at least one of the first storage chamber 12 and the second storage chamber 13 .

In addition, even if two evaporators are provided, only one compressor 60 constituting a corresponding refrigeration cycle may be provided.

In this case, as shown in FIG. 6 , the compressor 60 is connected to supply refrigerant to the first evaporator 21 through the first refrigerant passage 61 and the second refrigerant passage 62 through the second refrigerant passage 62 . It may be connected to supply a refrigerant to the evaporator 22 . At this time, each of the refrigerant passages (61, 62) can be selectively opened and closed using the refrigerant valve (63).

In addition, a cooling fan may be included in the structure for supplying the cold air of the cold air heat source.

Such a cooling fan may be configured to supply cold air generated while passing through a cold air heat source to the storage chambers 12 and 13 .

The cooling fan may include a first cooling fan 31 that supplies cool air generated while passing through the first evaporator 21 to the first storage chamber 12 .

The cooling fan may include a second cooling fan 41 that supplies cool air generated while passing through the second evaporator 22 to the second storage chamber 13 .

Next, the refrigerator 1 according to the embodiment of the present invention may include a first duct.

The first duct is a duct for guiding the fluid inside the storage chamber to move to the cold air heat source. The first duct may include a suction duct 42a provided in a second duct to be described later.

That is, the fluid flowing through the second storage chamber 13 can flow to the second evaporator 22 by the guidance of the suction duct 42a.

In addition, the first duct may include a portion of the bottom surface of the inner case 11a.

At this time, a portion of the bottom surface of the inner case 11a is a portion from a portion facing the bottom surface of the suction duct 42a to a position where the second evaporator 22 is mounted.

Accordingly, the first duct provides a flow path through which the fluid flows from the suction duct 42a toward the second evaporator 22 .

Next, the refrigerator 1 according to the embodiment of the present invention may include a second duct.

The second duct is a duct that guides the fluid around the evaporators 21 and 22 constituting the cold air heat source to move to the storage chamber.

The second duct may be the fan duct assemblies 30 and 40 positioned in front of the evaporators 21 and 22 .

At this time, the fan duct assemblies 30 and 40 form a rear wall in each storage chamber 12 and 13, and the cooling fans 31 and 41 are installed respectively while passing through each of the cold air heat sources 21 and 22. It is configured to guide the cold air to flow into each storage chamber (12, 13).

1 and 2, the fan duct assemblies 30 and 40 are a first fan duct assembly 30 and a second storage chamber 13 for guiding cold air to flow in the first storage chamber 12. A second fan duct assembly 40 for guiding cold air to flow therein may be included.

At this time, the space between the fan duct assemblies 30 and 40 in which the evaporators 21 and 22 are located and the rear wall surface of the inner case 11a is defined as a heat exchange passage through which air exchanges heat with the evaporators 21 and 22 . can

Of course, although not shown, even if the evaporators 21 and 22 are provided in only one storage compartment, the fan duct assemblies 30 and 40 may be provided in both storage compartments 12 and 13, respectively, and the evaporator 21, Although 22) is provided in both storage chambers 12 and 13, only one fan duct assembly 30, 40 may be provided.

On the other hand, in the embodiment described below, the structure for generating cold air from the cold air heat source is the second evaporator 22 , the structure for supplying cold air from the cold air heat source is the second cooling fan 41 , and the first duct is It is assumed that the suction duct 42a is formed in the two fan duct assembly 40 , and the second duct is the second fan duct assembly 40 .

7 to 12 , the second duct, that is, the second fan duct assembly 40 may include a grill pan 42 .

In this case, a suction duct 42a through which air is sucked from the second storage chamber 13 may be formed in the grill pan 42 .

The suction duct 42a may be formed at both ends of the lower side of the grill pan 42, respectively, and sucks the air flowing through the inclined corner between the bottom and rear wall of the inner case 11a due to the machine room. made to guide the flow.

In this case, the suction duct 42a may be used as a partial structure of the first duct. That is, the fluid inside the second storage chamber 13 is guided to move to the second evaporator 22 by the suction duct 42a.

The suction duct 42a may be formed to protrude forward (inside the second storage chamber) and gradually inclined downward toward the front.

The inclination of the suction duct 42a may be the same as or similar to the inclination formed by the machine room among the bottom rear side portions of the inner case 11a used as the first duct.

In addition, a fluid discharge part 42b for discharging cold air into the second storage chamber 13 may be formed in the grill pan 42 .

In particular, two or more fluid discharge parts 42b may be formed. For example, as shown in FIG. 9 , the upper portion, the middle portion, and the lower portion of the grill pan 42 may be formed on both sides of the grill pan 42 .

7 to 12 , the second fan duct assembly 40 may include a shroud 43 .

The shroud 43 is coupled to the rear surface of the grill pan 42, and a flow path for guiding the flow of cold air to the second storage chamber 13 is provided between the shroud 43 and the grill pan 42. can

In addition, the fluid inlet (43a) may be formed in the shroud (43). The fluid inlet (43a) is configured to be located above the second evaporator (22).

That is, the cold air that has passed through the second evaporator 22 is introduced into the flow path for the cold air flow between the grill fan 42 and the shroud 43 through the fluid inlet 43a, and then is guided by the flow path. It is made to be discharged into the second storage chamber 22 through each fluid discharge portion 42b of the grill pan 42 .

In addition, guide ducts 43b may be formed to extend downward, respectively, on both sides of the shroud 43 .

Each of these guide ducts 43b extends the cold air blown by the second cooling fan 41 to the fluid discharge portion 42b located at the lower portion of the grill fan 42 among the fluid discharge portions 42b. guide it to move.

Meanwhile, the second cooling fan 41 may be installed in the flow path between the grill fan 42 and the shroud 43 .

Preferably, the second cooling fan 41 may be installed in the fluid inlet 43a formed in the shroud 43 . That is, by the operation of the second cooling fan 41, the air in the second storage chamber 22 sequentially passes through the suction duct 42a and the second evaporator 22, and then through the fluid inlet 43a. can flow into the euro.

Next, the refrigerator 1 according to the embodiment of the present invention may include a defrosting device 50 .

The defrosting device 50 is configured to provide a heat source for the removal of frost implanted in the cold air heat source (eg, the second evaporator).

Of course, the defrosting device 50 may be configured to also perform a function of defrosting or preventing freezing of the implantation detecting device 70 to be described later.

As shown in FIGS. 4 and 7 and 14 , the defrosting device 50 may include a first heater 51 .

That is, the frost formed on the second evaporator (cold air heat source) 22 by the heat of the first heater 51 can be removed.

The first heater 51 may be located at the bottom (air inlet side) of the second evaporator 22 . That is, heat can be provided in the air flow direction from the lower end to the upper end of the second evaporator 22 through the heat generated by the first heater 51 .

Of course, although not shown, the first heater 51 may be located on the side of the second evaporator 22, may be located in front or behind the second evaporator 22, and the second evaporator 22 It may be located on the top of the, it may be located in contact with the second evaporator (22).

The first heater 51 may be formed of a sheath heater. That is, the frost formed on the second evaporator 22 is removed by using radiant heat and convection heat of the sheath heater.

A second heater 52 may be included in the defrosting device 50 as shown in FIGS. 4 and 7 and 14 .

The second heater 52 may be a heater that provides heat to the second evaporator 22 while generating heat at a lower output than that of the first heater 51 .

The second heater 52 may be positioned in contact with the heat exchange fin of the second evaporator 22 . That is, the second heater 52 is capable of removing the frost formed on the second evaporator 22 through heat conduction while in direct contact with the second evaporator 22 .

This second heater 52 may be formed of an L-cord heater. That is, the frost formed on the second evaporator 22 is removed by the conduction heat of the L cord heater.

In this case, the second heater 52 may be installed so as to be in contact with a heat exchange fin located at an upper portion (air outlet side) of the second evaporator 22 .

Meanwhile, the defrosting device 50 may include both the first heater 51 and the second heater 52 , or only one of the first heater 51 and the second heater 52 . have.

In addition, the defrosting device 50 may include a temperature sensor for an evaporator (not shown).

The temperature sensor for the evaporator senses the ambient temperature of the defrosting device 50, and the detected temperature value may be used as a factor for determining on/off of each of the heaters 51 and 52.

For example, after each of the heaters 51 and 52 is turned on, when the temperature value sensed by the temperature sensor for the evaporator reaches a specific temperature (defrost end temperature), each of the heaters 51 and 52 is turned off It can be (OFF).

The defrost end temperature may be set to an initial temperature, and if residual ice is detected in the defrosting end second evaporator 22, the defrost end temperature may be increased by a predetermined temperature.

Next, the refrigerator 1 according to the embodiment of the present invention may include an implantation detection device 70 .

The implantation detection device 70 is a device for detecting the amount of frost or ice generated in the cold air heat source.

In particular, the implantation detection device 70 recognizes the degree of implantation of the second evaporator 22 using a sensor that outputs different values according to the physical properties of the fluid, and the execution time of the defrost operation based on the recognized degree of implantation. is configured so that it can be accurately known.

In this case, the physical property may include at least one of temperature, pressure, and flow rate.

7 is a cross-sectional view showing a main part to explain the installation state of the implantation detection device and the evaporator according to an embodiment of the present invention, and FIG. 8 is an enlarged view of part “A” of FIG. 7 .

In addition, the accompanying FIGS. 9 to 12 and 15 are the state in which the implantation detection device is installed in the second fan duct assembly, and FIGS. 16 to 34 show the detailed structure of each component constituting the implantation detection device.

The structure of the implantation detection device will be described in more detail with reference to these drawings.

Prior to the description, the implantation detection device is located on the flow path of the fluid guided to the suction duct (first duct) 42a and the second fan duct assembly (second duct) 40 while the second evaporator (cold air heat source) The device for detecting the conception of (22) will be described as an example.

First, the implantation detection device 70 may include an implantation detection duct 710 .

The implantation detection duct 710 is a flow path through which air flows while the implantation confirmation sensor 740 for confirming the implantation of the second evaporator 22 is provided.

In particular, the implantation detection duct 710 may be configured to guide an air flow that passes through the second evaporator 22 and a separate air flow that is partitioned from the air flow that flows through the nat of the second fan duct assembly 40 .

To this end, the implantation detection duct 710 may include a guide passage 713 (refer to FIGS. 13 and 18 and 20 attached).

The guide passage 713 is a portion formed to guide the flow of the fluid introduced into the implantation detection duct 710 through the fluid inlet 711 .

The guide flow path 713 is formed as a recessed portion with both side wall surfaces and a bottom surface and an open upper surface, a bottom surface and a rear surface as well as a concave indentation formed on the rear surface (opposite surface of the second evaporator) of the grill pan 42. can The fluid inlet 711 may be an open bottom surface of the guide passage 713 .

At this time, the portion where the guide passage 713 is formed may protrude forward of the grill pan 42 as shown in FIG. 9 . That is, the thickness of the grill pan 42 can be maintained constant by protruding forward of the grill pan 42 by the depth of the depression of the guide passage 713 .

In particular, installation grooves 714 in which both ends of the implantation confirmation sensor 740 are installed may be concavely formed on both sidewalls in the guide passage 713 .

The installation groove 714 may be formed such that both ends of the implantation confirmation sensor 740 are inserted from the rear (open rear) of the guide passage 713 toward the bottom surface in the guide passage 713 .

Preferably, the installation groove 714 is a point at which the flow of the fluid introduced through the fluid inlet 711 and flowing to the fluid outlet 712 is stabilized (about 2/3 of the distance from the fluid inlet to the fluid outlet) ) can be located.

The installation groove 714 may be formed to a depth sufficient to place the implantation confirmation sensor 740 in its original position. That is, when the implantation confirmation sensor 740 is inserted up to the end of the installation groove 714, the implantation confirmation sensor 740 is placed in the correct position.

At this time, the position refers to a position where the front of the implantation confirmation sensor 740 is spaced apart from the bottom surface of the guide passage 713 by at least 1.5 mm and at least 1.5 mm from the open rear surface of the guide passage 713. .

That is, considering that moisture cannot smoothly escape through a gap of less than 1.5 mm and can stay, between the implantation confirmation sensor 740 and the bottom surface in the guide passage 713 and the implantation confirmation sensor 740 and the flow path cover 720 to be described later ), it is preferable that a minimum gap (1.5 mm) through which the moisture can pass is provided.

To this end, the concave depth D of the guide passage 713 constituting the implantation detection duct 710 is (1.5mm*2)+T≤D with respect to the thickness T of the implantation confirmation sensor 740 . can be configured to satisfy At this time, the concave depth (D) and the thickness (T) are as shown in the accompanying FIG.

Accordingly, the freezing of the implantation confirmation sensor 740 caused by the moisture does not pass through the gap and stays can be prevented.

In addition, when the implantation confirmation sensor 740 is positioned at the correct position in the installation groove 714 , a separation prevention protrusion 715 blocking a portion of the rear surface of the implantation confirmation sensor 740 may be formed to protrude.

That is, as can be seen from the accompanying Figures 29 and 39, the implantation confirmation sensor 740 in the installation groove 714 by the separation prevention protrusion 715 does not undesirably deviate from its original position.

At this time, the separation prevention protrusion 715 may be formed to protrude by a distance sufficient to smoothly install the implantation confirmation sensor 740 in the installation groove 714 . That is, it is preferable not to make it difficult to forcibly press the implantation confirmation sensor 740 into the installation groove 714 due to the excessive protrusion distance of the separation prevention protrusion 715 .

In addition, a withdrawal guide groove 716 may be additionally formed in any one of the two installation grooves 714 formed on both side wall surfaces of the guide passage 713 .

The withdrawal guide groove 716 may be formed from any one installation groove 714 of the guide passage 713 toward the side thereof.

In particular, the extraction guide groove 716 may be formed to be gradually inclined toward the surface of the grill pan 42 from the inside of the installation groove 714 . In this case, the inner side of the installation groove 714 may be a portion from which the signal line 745 of the implantation confirmation sensor 740 is drawn out when the implantation confirmation sensor 740 is completely inserted into the installation groove 714 .

In addition, the implantation detection duct 710 may include a fluid outlet 717 as shown in FIGS. 16 and 18 and 20 attached thereto.

The fluid outlet 717 is a portion formed to guide the fluid flowing along the guide passage 713 to be discharged to the fluid outlet 712 .

The fluid outlet portion 717 may be formed in an inclined portion of the shroud 43 and may be formed as a recessed portion having both side wall surfaces, a bottom surface, and an upper surface, and an open bottom surface and a rear surface thereof.

In this case, the fluid outlet 712 may be a part of the open rear surface of the fluid outlet 717 .

In particular, a mounting protrusion 717a may be formed on the fluid outlet portion 717 .

The mounting protrusion 717a may be formed to protrude downward from a portion where the fluid flows into the fluid outlet 717 and to be concave into the guide passage 713 formed in the grill pan 42 .

That is, as the mounting protrusion 717a of the fluid outlet 717 is formed to be concave in the guide passage 713 , when moisture such as defrost water or condensed water flows into the fluid outlet 712 , the moisture is transferred to the fluid outlet It is possible to flow down smoothly without accumulating in the connection portion between the 717 and the guide passage 713 .

In addition, a blocking protrusion 717b may be formed on the upper side of the fluid outlet 717 on the rear surface of the shroud 43 .

Specifically, the blocking protrusion 717b may be formed to block the upper portion of the fluid outlet 712 .

That is, the provision of the blocking protrusion 717b prevents moisture flowing along the rear surface of the shroud 43 from flowing into the fluid outlet 712 .

The blocking protrusion 717b may be formed in an upwardly convex round structure (refer to the attached drawings), may be formed in an upwardly convex inclined structure, or may be formed in a simple straight structure.

On the other hand, the implantation detection duct 710 may be located on the flow path of the cold air circulating in the second storage chamber 22 , the suction duct 42a , the second evaporator 22 , and the second fan duct assembly 40 . have.

At least a portion of the implantation detection duct 710 may be disposed on a flow path through which the fluid flows toward the cold air heat source while passing through the first duct.

Specifically, the fluid inlet 711 of the implantation detection flow path 710 may be located openly on the flow path through which the fluid flows toward the air inlet side of the second evaporator 22 while passing the suction duct 42a. .

That is, part of the air flowing toward the air inlet side of the second evaporator 41 while passing through the suction duct 42a can be introduced into the implantation detection duct 710 .

At least a portion of the implantation detection duct 710 may be disposed on a flow path through which the fluid flows toward the second duct while passing through the cold air heat source.

Specifically, the fluid outlet 712 formed in the fluid outlet 717 constituting the implantation detection duct 710 is the air outlet side of the second evaporator 22 and cold air is supplied to the second storage chamber 13 . It may be positioned to be exposed to the flow path.

More specifically, as shown in FIG. 14 , the fluid outlet 712 of the implantation detection flow path 710 passes through the second evaporator 22 to the fluid inlet 43a of the shroud 43 . It can be positioned openly on the flow path through which the fluid flows.

That is, the air passing through the implantation detection duct 710 through the fluid outlet 712 can flow directly between the air outlet side of the second evaporator 22 and the fluid inlet port 43a of the shroud 43. will be.

In addition, the implantation detection device 70 may include a flow path cover 720 .

The flow path cover 720 is installed to cover the open rear surface (the side opposite to the second evaporator) of the implantation detection duct 710 and divides the flow path inside the implantation detection duct 710 from the external environment. .

In this case, the upper end of the flow path cover 720 may be formed to cover up to the remaining portions except for the fluid outlet 712 of the fluid outlet 717 constituting the implantation detection duct 710 .

Accordingly, the fluid outlet 712 may be opened to the outside, and the fluid provided to the fluid outlet 717 through the guide passage 713 may flow out through the fluid outlet 712 . This is as shown in the accompanying Figures 21 and 22.

33 to 37, at least a portion of the flow path cover 720 may be inclined (or rounded).

That is, considering that the fluid outlet part 717 is formed on the inclined surface of the shroud 43, a part of the flow path cover 720 for covering a part of the fluid outlet part 717 is also the inclined surface of the shroud 43 and It can be formed to be bent while having the same slope (or round).

A first coupling part 721 may be formed at an upper end of the bent portion of the flow path cover 720 .

At this time, the first coupling portion 721 is a portion for coupling the upper end portion of the flow path cover 720 to the implantation detection duct (710).

The first coupling part 721 is formed to be rounded while protruding upward from both sides of the upper end of the flow path cover 720 as shown in the accompanying FIGS. 25 and 26, and is formed on both sides of the fluid outlet part 717. It is installed through the coupling hole (717c) (refer to FIGS. 18 to 20) formed in the.

A rear surface (a surface opposite to the second evaporator) of the flow path cover 720 may be configured to be positioned on the same plane as a rear surface (a surface opposite to the second evaporator) of the grill pan 42 .

To this end, in the portion where the guide flow path 713 of the grill pan 42 is recessed, a mounting jaw 42c on which the flow path cover 720 can be accommodated and mounted may be recessed.

13 and 20 , the mounting jaw 42c may be recessed from the rear surface of the grill pan 42 by the thickness of the flow path cover 720 .

At least one portion of the flow path cover 720 may be formed to contact the implantation confirmation sensor 740 installed in the guide flow path 713 .

Specifically, the flow path cover 720 may have a contact protrusion 722 that is partially recessed into the installation groove 714 of the guide flow path 713 .

That is, when the flow path cover 720 is covered with the implantation detection duct 710 , the contact protrusion 722 can come into contact with the implantation confirmation sensor 740 installed at the correct position in the installation groove 714 .

If the implantation confirmation sensor 740 is not installed in the proper position in the installation groove 714, the flow path cover 720 is not accurately coupled to the implantation detection duct 710 due to the contact protrusion 722. will not

Accordingly, the operator can recognize whether the implantation confirmation sensor 740 is correctly installed by confirming whether the flow path cover 720 is correctly coupled to the implantation detection duct 710 .

The contact protrusion 722 may be formed to protrude forward from both sides of the front surface of the flow path cover 720 as shown in FIG. 28 .

In addition, the flow path cover 720 may be provided with a fluid inlet 730 .

The fluid inlet 730 is a configuration that provides flow resistance to the fluid flowing into the implantation detection duct 710, and as shown in FIGS. 8 and 14, the fluid passes through the first duct and toward the cold air heat source. may be disposed to be exposed on the flow path.

That is, the flow rate of the fluid flowing into the implantation detection duct 710 due to the flow resistance of the fluid inlet 730 may be smaller than when there is no flow resistance, and the flow rate may be further slowed.

In this way, as the flow velocity in the implantation detection duct 710 becomes slower, the difference between the maximum temperature and the minimum temperature confirmed by the on-off control of the heating element 741 of the implantation confirmation sensor 740 to be described later may increase. It can increase the discriminatory power in the confirmation of implantation.

Of course, although not shown, the structure for providing the flow resistance is made separately from the fluid inlet part 730 and the cold air heat source passes through the fluid inlet part 730 of the implantation detection duct 710 or the first duct. It may be additionally provided on a flow path through which the fluid flows.

This fluid inlet 730 extends downward from the lower end of the flow path cover 720 as shown in the accompanying FIGS. 21 to 25, and has a peripheral wall as shown in FIGS. 31 to 33. It may be formed into a tubular body.

The fluid inlet 730 may be disposed at a lower position than the lower end (air inlet side) of the cold air heat source (second evaporator). Accordingly, the fluid flowing from the second storage chamber 13 to the second evaporator 22 may be partially introduced into the implantation detection duct 710 .

31 and 33, the upper and lower surfaces of the fluid inlet 730 may be formed to be open.

At this time, the upper surface of the open fluid inlet 730 may coincide with the fluid inlet 711 of the guide passage forming the implantation detection duct 710 .

In addition, the lower surface of the open fluid inlet 730 may be positioned on a flow path through which the fluid flows to the cold air heat source while passing through the first duct. Accordingly, a portion of the fluid passing through the flow path may be introduced into the fluid inlet 730 through the open bottom surface of the fluid inlet 730 .

Meanwhile, the fluid inlet 730 may be formed to have a front wall 731 and a rear wall 732 .

The front wall 731 of the fluid inlet 730 may be a side wall facing the bottom surface in the guide passage 713 , and the rear wall 732 may be a side wall facing the cold air heat source.

A second coupling part 731a may be formed on the front wall 731 of the fluid inlet part 730 .

The second coupling portion 731a is a portion for coupling the lower end portion of the flow path cover 720 to the implantation detection duct 710 .

The second coupling part 731a may have at least one hook structure that protrudes forward from the front surface of the front wall 731 constituting the fluid inlet part 730 . This is as shown in the attached Figure 33.

In this case, a fitting groove 713a into which the second coupling part 731a of the hook structure is fitted may be formed on the bottom surface of the guide passage 713 . This is as shown in the attached Figure 34.

The front surface of the second coupling part 731a is formed to be rounded while being bent so that it can be smoothly inserted into the fitting groove 713a, and unwanted separation can be prevented while being inserted into the fitting groove 713a. let it be

An inlet slot 734 may be formed in the rear wall 732 of the fluid inlet 730 .

The inlet slot 734 is an open portion to guide the cold air flowing backward from the cold air heat source into the implantation detection duct 710 .

That is, as frost or ice is implanted on the cold air heat source, a portion of the fluid passing through the cold air heat source is reversely flowed while receiving flow resistance by the implanted frost or ice. It is made to pass through the implantation detection duct 710 while smoothly flowing into the implantation detection duct 710 through the . This is as shown in the attached Figure 35.

Of course, the inlet slot 734 is guided by the suction duct 42a to the rear wall 732 of the fluid inlet 730 while the fluid flowing to the cold air heat source passes through the fluid inlet 730. It also performs the function of allowing it to flow directly to the cold air heat source without colliding with it. This is as shown in the attached Figure 36.

That is, if the inlet slot 734 does not exist in the rear wall 732 , the fluid collides with the rear wall 732 while passing the fluid inlet 730 and flows into the implantation detection duct 710 . As a result, if the inflow slot 734 does not exist, the amount of fluid inflow before implantation is excessively large, which causes a disadvantage in that the discrimination force is lowered upon detection of implantation.

In addition, the fluid inlet 730 may include a side wall 733 connecting the front wall 731 and the rear wall 732 .

An inclined surface 733a may be formed on the side wall 733 of the fluid inlet 730 .

The inclined surface 733a is a portion that is inclined inward toward the bottom, and moisture such as condensed water generated from the side wall 733 of the corresponding fluid inlet 730 by providing the inclined surface 733a does not condense on the portion. It can flow without

That is, as the moisture does not form on the fluid inlet 730, the phenomenon of freezing of the moisture is prevented, and the open bottom of the fluid inlet 730 or the inlet slot 734 is blocked by the freezing of the moisture. phenomenon is prevented.

In addition, the implantation detection device 70 may include an implantation confirmation sensor 740 .

The implantation confirmation sensor 740 is a sensor that measures the physical properties of the fluid passing in the implantation detection duct 710 . In this case, the physical property may include at least one of temperature, pressure, and flow rate.

In particular, the implantation confirmation sensor 740 may be configured to calculate the amount of implantation of the second evaporator 22 based on the difference in the output value that is changed according to the physical properties of the air (fluid) passing through the implantation detection duct 710. have.

That is, it is used to determine whether or not a defrosting operation is necessary by calculating the amount of implantation of the second evaporator 22 with the difference of the output value confirmed by the implantation confirmation sensor 740 .

In the embodiment of the present invention, it is assumed that the implantation confirmation sensor 740 is a sensor provided to confirm the amount of implantation of the second evaporator 22 by using a temperature difference according to the amount of air passing through the implantation detection duct 710 .

That is, as shown in the accompanying FIGS. 17, 22 and 37, the implantation confirmation sensor 740 is provided at the portion where the fluid flows in the implantation detection duct 710, and the amount of fluid flow in the implantation detection duct 710 is Based on the output value changed accordingly, the amount of implantation of the second evaporator 22 can be confirmed.

Of course, the output value may be variously determined, such as a pressure difference or other characteristic difference as well as the temperature difference.

The attached FIG. 38 shows the structure of the implantation confirmation sensor 740 .

According to the drawing, the conception confirmation sensor 740 may be configured to include a sensing derivative.

The sensing inductor may be a means for inducing the sensing element to improve the measurement precision so that the physical property (or output value) can be measured more accurately.

In the embodiment of the present invention, it is assumed that the sensing derivative includes a heating element 741 .

The heating element 741 is a heating element that generates heat by receiving power.

In addition, the implantation confirmation sensor 740 may be configured to include a sensing element 742 .

The sensing element 742 is an element that measures the temperature around the heating element 741 .

That is, considering that the temperature around the heating element 741 changes according to the amount of air passing through the heating element 741 while passing through the implantation detection duct 710, the detection element 742 measures this temperature change and then based on this temperature change The degree of implantation of the second evaporator 22 can be calculated.

In addition, the conception confirmation sensor 740 may be configured to include a sensor PCB (743).

The sensor PCB 743 determines the difference between the temperature sensed by the sensing element 742 in the off state of the heating element and the temperature detected by the sensing element 742 in the ON state of the heating element 741 done so that

Of course, the sensor PCB 743 may be configured to determine whether the logic temperature ΔHt is equal to or less than a reference difference value.

For example, when the amount of implantation of the second evaporator 22 is small, the flow rate of air flowing through the implantation detection duct 710 is small. relatively small cooling.

Accordingly, the temperature sensed by the sensing element 742 increases, and the logic temperature ΔHt also increases.

On the other hand, when the amount of implantation of the second evaporator 22 is large, the flow rate of air flowing in the implantation detection duct 710 is increased, and in this case, the heat generated according to the ON of the heating element 741 is the flow air is cooled relatively much by

Accordingly, the temperature sensed by the sensing element 742 is lowered, and the logic temperature ΔHt is also lowered.

As a result, the amount of implantation of the second evaporator 22 can be accurately determined according to the high and low of the logic temperature ΔHt, and the defrosting operation is performed at the correct time based on the determined amount of implantation of the second evaporator 22 . be able to do

That is, when the logic temperature ΔHt is high, it is determined that the amount of implantation of the second evaporator 22 is small, and when the logic temperature ΔHt is low, it is determined that the amount of implantation of the second evaporator 22 is large.

Accordingly, when a reference temperature difference value is designated and the logic temperature ΔHt is lower than the designated reference temperature difference value, it can be determined that the defrost operation of the second evaporator 22 is necessary.

In addition, the implantation confirmation sensor 740 may be configured to include a sensor housing 744 .

The sensor housing 744 serves to prevent water flowing down through the implantation detection duct 710 from coming into contact with the heating element, the sensing element 742 or the sensor PCB 743 .

The sensor housing 744 may be formed so that at least one side of both ends is open. As a result, the signal line (or power line) 745 can be drawn out from the sensor PCB 743 .

A protruding end 744a may be formed to protrude from the front surface of the sensor housing 744 (the surface facing the bottom in the guide passage) (the surface facing the upper side when referring to FIG. 34 ).

The protruding end 744a may be formed to protrude toward the inside of the guide passage 713 while having a smaller width than the front surface of the sensor housing 744 .

The protruding end 744a has a structure provided so that the operator can recognize the front and rear directions of the sensor housing 744 . That is, the operator can refer to the protruding direction of the protruding end 744a in the process of installing the implantation confirmation sensor 740 in the guide passage 713 .

In particular, as shown in FIGS. 13 and 29, and 30 and 39, in the installation grooves 714 formed on both side wall surfaces of the guide passage 713, there is a yaw having the same shape as the protruding end 744a. An indentation groove 718 may be additionally formed, and the protruding end 744a may be configured to be concave in the indentation groove 718 .

That is, the protrusion end 744a can be engaged with each other through the formation of the concave groove 718 to prevent shaking of the implantation confirmation sensor 740, and the front and rear surfaces of the implantation confirmation sensor 740 are inverted. In the case of being installed as a , the implantation confirmation sensor 740 is separated from its original position in the installation groove 714 by the depth (or the protrusion height of the protruding end) of the concave groove 718 .

At this time, the front and rear surfaces of the implantation confirmation sensor 740 are installed in an inverted state, and the implantation confirmation sensor 740 is installed in the installation groove 714 by the depth (or the protrusion height of the protruding end) of the concave groove 718 . When separated from the position, due to the contact protrusion 722 concave into the installation groove 714 , the flow path cover 720 cannot be accurately engaged with the mounting jaw 42c of the grill pan 42 . This is as shown in the attached FIG. 30 .

In this case, the operator can recognize that the implantation confirmation sensor 740 is installed incorrectly.

Next, the refrigerator 1 according to the embodiment of the present invention may include a control unit 80 .

The controller 80 may be a device for controlling the operation of the refrigerator 1 .

As shown in the attached FIG. 4 , the control unit 80 can check the indoor temperature and the inside temperature based on each temperature sensor 1a and 1b, and control the implantation confirmation sensor 740 or the implantation confirmation sensor 740 ) may be provided with sensed information, and the defrosting device 50 may be controlled.

For example, the control unit 80 may control the temperature in each storage compartment 12 and 13 to determine if the internal temperature in the storage compartment is in the dissatisfaction temperature region divided based on the set reference temperature NT set by the user for the storage compartment. It can be configured to control so that the amount of cold air supplied can be increased so that it can descend, and to control so that the amount of cold air supplied can be reduced when the internal temperature of the refrigerator in the storage room is in a satisfactory temperature range divided based on the set reference temperature (NT). .

Also, the control unit 80 may be configured to control the implantation detection device 70 to perform an implantation detection operation.

To this end, the control unit 80 may be configured to perform the implantation detection operation for a preset implantation detection time.

The implantation detection time may be variably controlled according to a temperature value of the room temperature measured by the first temperature sensor 1a or a temperature set by a user.

For example, the higher the indoor temperature or the lower the set temperature, the shorter the implantation detection time is performed due to more frequent cold operation. Since it is performed in a small amount, the implantation detection time can be controlled to be performed long enough.

In addition, the control unit 80 controls the implantation confirmation sensor 740 to operate at a predetermined period.

That is, under the control of the control unit 80, the heating element 741 of the implantation confirmation sensor 740 is heated for a predetermined time, and the sensing element 742 of the implantation confirmation sensor 740 is turned on. In addition to sensing the temperature immediately after being turned off, the temperature immediately after the heating element 741 is OFF is sensed.

Through this, the minimum temperature and the maximum temperature can be confirmed after the heating element 741 is turned on, and the temperature difference between the minimum temperature and the maximum temperature can be maximized, so that the discrimination power for implantation detection can be further improved. there will be

In addition, the control unit 80 checks the temperature difference value (logic temperature) ΔHt when the heating element 741 is turned on/off, and whether the maximum value of the logic temperature ΔHt is less than or equal to the first reference difference value may be configured to determine

In this case, the first reference difference value may be a value set to the extent that it is not necessary to perform a defrosting operation.

Of course, the above-described logic temperature (ΔHt) confirmation and comparison with the first reference difference value may be configured to be performed by the sensor PCB 743 constituting the implantation confirmation sensor 740 .

In this case, the control unit 80 receives the result of checking and comparing the logic temperature ΔHt with the first reference difference value performed from the sensor PCB 743 to control the on/off of the heating element 741 . can be

Next, a process of installing the implantation detection device of the refrigerator 1 according to an embodiment of the present invention will be described in detail.

First, a second duct in which the grill pan 42 and the shroud 43 are coupled is prepared.

At this time, the mounting protrusion 717a of the fluid outlet 717 formed in the shroud 43 is configured to be mounted in the upper end of the guide passage 713 formed in the grill pan 42 .

Then, the implantation confirmation sensor 740 is mounted on the implantation detection duct 710 of the second duct thus prepared.

Specifically, both ends of the implantation confirmation sensor 740 are inserted into the installation groove 714 of the guide passage 713 constituting the implantation detection duct 710 .

At this time, the implantation confirmation sensor 740 is installed with its protruding end 744a facing the bottom surface in the guide passage 713 .

Accordingly, the protruding end 744a of the implantation confirmation sensor 740 coincides with the concave groove 718 formed in the installation groove 714 .

While the end of the implantation confirmation sensor 740 is inserted into the installation groove 714, it is disturbed by the separation prevention protrusion 715 formed in the installation groove 714.

However, considering that the departure prevention protrusion 715 protrudes only enough to prevent the departure of the implantation confirmation sensor 740, and its end surface is rounded, the tip of the implantation confirmation sensor 740 is pressed. By this operation, the implantation confirmation sensor 740 can be installed at the end of the installation groove 714 past the separation prevention protrusion 715 .

And, in the state in which the implantation confirmation sensor 740 is installed in this way, it is possible to prevent the implantation confirmation sensor 740 from being unintentionally deviated from the end in the installation groove 714 due to the departure prevention protrusion 715 .

In addition, in the state in which the implantation confirmation sensor 740 is installed in the installation groove 714 as described above, the signal line 745 connected to the corresponding implantation confirmation sensor 740 is provided with a withdrawal guide groove 716 formed in the installation groove 714 . to be withdrawn to the outside.

At this time, considering that the withdrawal guide groove 716 is formed to be inclined, it can be withdrawn from the implantation confirmation sensor 740 to the outside of the implantation detection duct 710 without abrupt bending of the signal line 745 .

In particular, the signal line 745 is drawn out horizontally from the implantation detection duct 710 to the rear surface of the guide duct 43b formed in the shroud 43 and then bent in the vertical direction along the guide duct 43b. installed so that it is drawn out from the top.

Preferably, the signal line 745 is partially adhesively fixed to the surface of the guide duct 43b using an adhesive tape. In this case, it is preferable that the bonding portion of the signal line 745 includes at least one of a bent portion of the corresponding signal line 745 or an end portion of the signal line 745 .

And, when the above operation is completed, the flow path (particularly the guide flow path) in the implantation detection duct 710 except for the fluid inlet 711 and the fluid outlet 712 is blocked from the external environment by coupling the flow path cover 720 .

At this time, the flow path cover 720 preferentially installs the first coupling part 721 formed on the upper end thereof through the coupling hole 717c formed on both sides of the fluid outlet part 717 and the lower end thereof. The second coupling part 731a formed in the fluid inlet part 730 of

Due to the coupling of the flow path cover 720, the fluid inlet 711 of the implantation detection duct 710 is positioned in communication with the inside of the fluid inlet 730 formed in the flow path cover 720, and the fluid inlet The open bottom of the 730 is located on the flow path through which the fluid flows to the cold air heat source while passing through the first duct.

At the same time, the fluid outlet 712 of the implantation detection duct 710 is not covered by the flow path cover 720 and is opened toward the fluid outlet side of the second evaporator 22 .

On the other hand, in the process of coupling the flow path cover 720 to the implantation detection duct 710, the contact protrusions 722 protruding from both sides of the flow path cover 720 are inserted into the installation groove 714 while the corresponding installation groove. It is pressed in contact with the tip of the implantation confirmation sensor 740 located in (714).

Accordingly, even if the implantation confirmation sensor 740 does not completely pass through the separation prevention protrusion 715 in the installation groove 714 and is in a partially insufficiently mounted state, by additional pressure by the contact protrusion 722, the installation groove It is possible to accurately position the tip in 714 .

At this time, the flow path cover 720 is indented while resting on the mounting jaws 42c formed along the circumference of the guide flow path 713_. It is possible to be positioned on the same plane as the rear surface (the surface opposite to the second evaporator) of the

If, even if the flow path cover 720 is coupled using the first coupling part 721 and the second coupling part 731a described above, a part of the flow path cover 720 floats from the guide flow path 713 or is not accurately coupled. There may be cases where it does not.

That is, in the process of inserting the implantation confirmation sensor 740 into the installation groove 714 of the guide flow path 713, by turning the implantation confirmation sensor 740 upside down and inserting it, the direction of the protruding end 744a is to be installed toward the rear. In this case, the corresponding implantation confirmation sensor 740 is insufficiently inserted into the insertion groove 714 by the height of the protruding end 744a, and the flow path cover 720 is not completely closed due to such insufficient insertion.

Accordingly, the operator can recognize whether the implantation confirmation sensor 740 is correctly coupled to the original position or installed upside down by re-checking the coupling state of the flow path cover 720 .

Then, by connecting the coupling of the flow path cover 720 and the drawn signal line 745 to a predetermined position (eg, a connector, etc.), the installation of the implantation detection device 70 is completed.

Next, an implantation detection operation for detecting the amount of implantation on the second evaporator 22 of the refrigerator 1 according to an embodiment of the present invention will be described.

Attached FIG. 40 is a flowchart of a method of performing a defrosting operation by determining a defrost required time of a refrigerator according to an embodiment of the present invention, and FIGS. It is a state diagram showing the temperature change measured by the implantation confirmation sensor.

41 shows the temperature change of the second storage chamber 13 and the temperature change of the heating element before the implantation of the second evaporator 22, and in FIG. Case) The temperature change of the second storage chamber and the temperature change of the heating element are shown.

As shown in these figures, after the previous defrost operation is completed (S1), the storage chambers 12 and 13 are controlled by the control unit 80 based on the first set reference temperature and the second set reference temperature. A cold operation is performed (S110).

In this case, the cold air operation is operated by controlling the operation of at least one of the first evaporator 21 and the first cooling fan 31 according to a first operation reference value designated based on the first set reference temperature, and It is operated through the operation control of at least one of the second evaporator 22 and the second cooling fan 41 according to a second operation reference value designated based on the second set reference temperature.

For example, the control unit 80 controls the first cooling fan 31 so that the first cooling fan 31 is driven when the internal temperature of the first storage compartment 12 is in the dissatisfaction temperature region divided based on the first set reference temperature set by the user. and control so that the first cooling fan 31 is stopped when the internal temperature of the refrigerator is within a satisfactory temperature range.

At this time, the control unit 80 controls the refrigerant valve 63 to selectively open and close each refrigerant passage 61 , 62 to perform a cold operation for the first storage chamber 12 and the second storage chamber 13 .

In addition, in the cold air operation for the second storage chamber 13, the air (cold air) that has passed through the second evaporator 22 is provided to the second storage chamber 13 by the operation of the second cooling fan 41, and the The cold air circulated in the second storage chamber 13 is guided by the suction duct 42a constituting the second fan duct assembly 40 and flows to the air inlet side of the second evaporator 22, and then flows to the second evaporator 22 again. ) repeats the flow through it.

At this time, most (eg, about 98%) of the air flowing to the air inlet side of the second evaporator 22 under the guidance of the suction duct 42a passes through the second evaporator 22, but some ( For example, about 2% of air is introduced into the implantation detection duct 710 through the fluid inlet 711 of the implantation detection duct 710 located on the air inlet side of the second evaporator 22 .

In particular, the fluid outlet 712 of the implantation detection duct 710 is disposed at a position in consideration of the pressure difference from the fluid inlet 711, and the effect of pressure generated by the operation of the second cooling fan 41 is also considered. It is arranged at a position (a position in consideration of the separation distance from the second cooling fan).

Accordingly, the air passing through the implantation detection duct 710 is less affected by the pressure by the second cooling fan 41, and even during non-implantation due to the pressure difference between the fluid outlet 712 and the fluid inlet 711 . In spite of this, some of them are forced to flow, so that it is possible to have the minimum discrimination power (temperature difference before and after implantation) for implantation detection.

And, it is continuously confirmed that the period for the conception detection operation is reached while the above-described general cold operation is performed ( S120 ).

In this case, the execution period of the conception detection operation may be a period of time, or may be a period in which the same operation, such as a specific component or a driving cycle, is repeatedly executed.

In an embodiment of the present invention, the cycle may be a cycle in which the second cooling fan 41 is operated.

That is, the implantation detection device 70 determines the amount of implantation of the second evaporator 22 based on the temperature difference (logic temperature) ΔHt according to the change in the flow rate of the air passing through the implantation detection duct 710 . is done

Also, the second cooling fan 41 of the second fan duct assembly 40 may be operated while the first cooling fan 31 of the first fan duct assembly 30 is stopped. Of course, if necessary, the second cooling fan 41 may be controlled to operate even when the first cooling fan 31 is not completely stopped.

In addition, the heating element 741 generates heat at the same time power is supplied to the second cooling fan 41 , or immediately after power is supplied to the second cooling fan 41 , or by the second cooling fan 41 . It can be controlled to generate heat when a certain condition is satisfied in a state in which power is supplied.

Preferably, the heating element 741 may be controlled so that heat is generated when a predetermined heating condition is satisfied in a state in which power is supplied to the second cooling fan 41 .

That is, when the cycle for the conception detection operation arrives, the heating condition of the heating element 741 is checked ( S130 ), and the heating element 741 can be controlled so that heat is generated only when the heating condition is satisfied.

These heating conditions are a condition in which the heating element is automatically heated when a set time has elapsed after driving the second cooling fan 41, and the temperature in the implantation detection duct 710 before the second cooling fan 41 is driven (sensing element) At least one of a condition in which the temperature confirmed in ) gradually decreases, a condition in which the second cooling fan 41 is operating, and a condition in which the door of the second storage chamber 13 is not opened may be included.

And, when it is confirmed that the heating conditions as described above are satisfied, the heating element 741 generates heat ( S140 ) under the control of the control unit 80 (or control of the sensor PCB).

In addition, when the heating element 741 generates heat, the sensing element 742 senses a physical property value in the implantation detection duct 710 , that is, the temperature Ht1 ( S150 ).

The sensing element 742 may sense the temperature Ht1 simultaneously with the heating of the heating element 741 or may sense the temperature Ht1 immediately after the heating of the heating element 741 is performed.

In particular, the temperature Ht1 sensed by the sensing element 742 may be the lowest temperature in the implantation detection duct 710 that is checked after the heating element 741 is turned on.

The sensed temperature Ht1 may be stored in the controller (or the sensor PCB) 80 .

And, the heating element 741 generates heat for a set heating time. In this case, the set heat generation time may be a time sufficient to have a discriminating force for a temperature change inside the implantation detection duct 710 .

For example, it is desirable that the logic temperature ΔHt when the heating element 741 heats up during the set heating time can have discrimination power even with the exception of the logic temperature ΔHt due to other factors that are predicted or not predicted in advance. .

The set heat generation time may be a specified time, or may be a time variable according to the surrounding environment.

For example, the set heat generation time is described above in the time required for the changed cycle when the operating cycle of the first cooling fan 31 for cold air operation of the first storage compartment 12 is changed shorter than the previous operating cycle. It can be a short time compared to the difference in time required for exothermic conditions.

In addition, the set heating time is required for the heating conditions described above in this changed time when the operating time of the second cooling fan 41 for the cold operation of the second storage chamber 13 is changed shorter than the previous operating time. It can be a short time compared to the difference in time.

In addition, the set heat generation time may be shorter than the operating time of the second cooling fan 41 when the second storage chamber 13 is operated at the maximum load.

In addition, the set heat generation time may be shorter than the difference between the time the second cooling fan 41 operates according to the temperature change in the second storage chamber 13 and the time required for the heat generation condition described above.

In addition, the set heating time is shorter than the difference between the time required for the heating conditions described above in the operation time of the second cooling fan 41 that is changed according to the specified temperature in the second storage chamber 13 designated by the user. this can be

And, when the set heating time has elapsed, the power supply to the heating element 741 may be cut off and the heating may be stopped (S160).

Of course, power supply to the heating element 741 may be controlled to be cut off even though the heating time has not elapsed.

For example, when the temperature sensed by the sensing element 742 exceeds a set temperature value (eg, 70° C.), it may be controlled such that the power supply to the heating element 741 is cut off, and the door of the second storage chamber 13 is closed. When opened, the power supply to the heating element 741 may be controlled to be cut off.

When an unexpected operation (operation of the first cooling fan) of the first storage chamber 12 occurs, it may be controlled such that the power supply to the heating element 741 is cut off.

When the second cooling fan 41 is turned off, the power supply to the heating element 741 may be controlled to be cut off.

When the heat generation of the heating element 741 is stopped in this way, the physical property, that is, the temperature Ht2, in the implantation detection duct 710 by the detection element 742 is sensed (S170).

In this case, the sensing of the temperature of the sensing element 742 may be performed simultaneously with the stopping of the heating of the heating element 741 , or may be performed immediately after the heating of the heating element 741 is stopped.

In particular, the temperature Ht2 sensed by the sensing element 742 may be the maximum temperature in the implantation detection duct 710 that is checked before and after the heating element 741 is turned off.

The sensed temperature Ht2 may be stored in the controller (or the sensor PCB) 80 .

Then, the control unit (or sensor PCB) 80 calculates each other's logic temperature (ΔHt) based on each sensed temperature (Ht1, Ht2), and based on the calculated logic temperature (ΔHt), the cold air heat source (second evaporator) ) It can be determined whether the defrost operation for (22) is performed.

That is, after calculating (S180) and storing the difference value (ΔHt) between the temperature (Ht1) when the heating element (741) generates heat and the temperature (Ht2) when the heating element (741) ends heating (S180), the logic temperature (ΔHt) of the defrost operation You can decide whether to do it or not.

For example, when the logic temperature ΔHt is higher than the first reference difference value set in advance, the flow rate of air in the implantation detection duct 710 is small, so that the amount of implantation of the second evaporator 22 performs a defrost operation. It can be judged as small compared to

That is, when the amount of implantation of the second evaporator 22 is small, the pressure difference between the air inlet side and the air outlet side of the second evaporator 22 is low, so that the flow rate of the air flowing in the implantation detection duct 710 is small. The logic temperature ΔHt is relatively high.

On the other hand, when the logic temperature (ΔHt) is lower than the second reference difference value set in advance, the air flow rate in the implantation detection duct 710 is large, so that the amount of implantation of the second evaporator 22 is enough to perform a defrost operation. can judge

That is, if the amount of implantation of the second evaporator 22 is large, the pressure difference between the air inlet side and the air outlet side of the second evaporator 22 is high. As ΔHt increases, the logic temperature ΔHt is relatively low.

In this case, the second reference difference value may be a value set to a degree to which a defrosting operation should be performed. Of course, the first reference difference value and the second reference difference value may be the same value, or the second reference difference value may be set to a lower value than the first reference difference value.

The first reference difference value and the second reference difference value may be any one specific value, or may be a value within a range.

For example, the second reference difference value may be 24°C, and the first reference difference value may be a temperature between 24°C and 30°C.

And, as a result of comparing the above-described logic temperature and each reference difference value, when the logic temperature ΔHt confirmed by the controller 80 is higher than a preset first reference difference value (eg, 24° C. to 30° C.) It can be determined that the implantation amount of the second evaporator 22 is insufficient compared to the set implantation amount.

In this case, after the second cooling fan 41 is stopped, the conception detection may be stopped until the next cycle of operation.

Thereafter, when the operation of the second cooling fan 41 of the next cycle is performed, the process of determining whether the heating condition for the above-described conception detection is satisfied may be repeatedly performed.

On the other hand, when the logic temperature ΔHt checked by the control unit 80 is lower than a preset second reference difference value (eg, 24° C.), it is determined that the second evaporator 22 exceeds the set implantation amount. Thus, the defrosting operation may be controlled to be performed (S2).

In this case, the stored logic temperature ΔHt for each implantation detection period may be reset when the defrosting operation is performed.

Next, a process ( S2 ) of performing a defrosting operation on the second evaporator 22 of the refrigerator according to an embodiment of the present invention will be described.

First, after the heating element 741 is turned off, a defrosting operation may be performed according to the determination of the controller 80 .

When the defrosting operation is performed, the first heater 51 constituting the defrosting device 50 may generate heat.

That is, it is possible to remove the frost formed on the second evaporator 22 with the heat generated by the heat of the first heater 51 .

At this time, when the first heater 51 is formed of a sheath heater, the heat generated by the first heater 51 removes the frost formed on the second evaporator 22 through radiation and convection.

In addition, when the defrosting operation is performed, the second heater 52 constituting the defrosting device 50 may generate heat.

That is, it is possible to remove the frost formed on the second evaporator 22 with the heat generated by the heat generated by the second heater 52 .

At this time, when the second heater 52 is formed of an L cord heater, the heat generated by the second heater 52 is conducted to the heat exchange fins to remove the frost on the second evaporator 22 .

The first heater 51 and the second heater 52 may be controlled to generate heat at the same time, or the first heater 51 may be controlled to generate heat after the first heater 51 is preferentially heated, and then the second heater 52 may be controlled to generate heat. After the second heater 52 is preferentially heated, it may be controlled so that the first heater 51 heats up.

And, after the first heater 51 or the second heater 52 generates heat for a set time, the heat of the first heater 51 or the second heater 52 is stopped.

At this time, even if the first heater 51 and the second heater 52 are provided together, the two heaters 51 and 52 may simultaneously stop heating, but one heater preferentially stops heating and then the other heater It may be controlled so that the heat generation is subsequently stopped.

In addition, the set time for the heating of each of the heaters 51 and 52 may be set to a specific time (eg, 1 hour, etc.) or may be set to a time variable according to the amount of frost implantation.

In addition, the first heater 51 or the second heater 52 may be operated with a maximum load or may be operated with a load varying according to the amount of defrost.

In addition, when the defrosting operation according to the operation of the above-described defrosting device 50 is performed, the heating element 741 constituting the implantation confirmation sensor 740 may be controlled to generate heat together.

That is, considering that water generated due to frost melting may flow down into the implantation detection duct 710 during the defrosting operation, the heating element 741 prevents the water flowing down in this way from freezing in the implantation detection duct 710. ) may also be desirable to generate heat together.

In addition, the defrosting operation may be performed based on time or may be performed based on temperature.

That is, when the defrosting operation is performed for an arbitrary time, the defrosting operation may be controlled to be terminated, or when the temperature of the second evaporator 22 reaches a set temperature, the defrosting operation may be controlled to be terminated.

And, when the operation of the defrosting device 50 is completed, the first cooling fan 31 is operated at the maximum load to bring the first storage compartment 12 to the set temperature range, and then the second cooling fan ( 41) may be operated to bring the second storage chamber 12 to a set temperature range.

At this time, when the first cooling fan 31 is operated, the refrigerant compressed from the compressor 60 may be controlled to be provided to the first evaporator 21 , and when the second cooling fan 41 is operated, the compressor The refrigerant compressed from 60 may be controlled to be provided to the second evaporator 22 .

In addition, when the temperature conditions of the first storage chamber 12 and the second storage chamber 13 are satisfied, the above-described control for the detection of an implantation of the second evaporator 22 by the implantation detection device 70 is sequentially performed again. .

Of course, it may be more preferable to detect residual ice immediately after the operation of the defrosting device 50 is completed and determine whether to perform an additional defrosting operation.

That is, when residual ice is confirmed, an additional defrosting operation is performed even though the defrosting operation timing is not reached, so that the residual ice can be controlled to be completely removed.

On the other hand, the defrosting operation may not be performed only based on the information acquired by the implantation detection device 70 .

For example, there may be a case in which the door of one storage chamber is in a state in which the door of one storage room is opened (micro-opened, etc.) for a long time due to the user's carelessness.

This can be recognized through a sensor that detects the opening of the door, and in this case, it may be set to perform a forced defrosting operation when a predetermined time elapses without operating the implantation detection device 70 .

In addition, if the implantation detection operation is not performed periodically due to excessively frequent opening and closing of the door, the forced defrost operation is performed at a set time in consideration of the frequent opening and closing of the door without using the information acquired by the implantation detection device 70 . It may be set to be

And, after the above-described defrosting operation is completed, the above-described cold operation is performed (S110), and the implantation detection operation for detection of implantation is continuously performed again.

In particular, after completion of the above-described defrost operation, at least one information of checking whether there is an afterimage by the logic temperature checked when the implantation detection operation is re-performed, checking whether the detection element 742 is faulty, or checking the blockage of the implantation detection duct 710 can be checked.

For example, if the logic temperature checked during the first implantation detection operation immediately after the defrost operation is 14° C. or less, it can be determined as freezing of the sensing element 742, and when the logic temperature is confirmed to be 37° C. or higher, the landing detection duct 710 can be determined as clogging, and when it is confirmed that the logic temperature is in the range of 28°C to 30°C, it can be determined that there is an afterimage in the cold heat source.

As a result, in the refrigerator of the present invention, since the circumferential wall (side wall) 733 of the fluid inlet part 730 extending from the lower end of the flow path cover 720 is formed to be inclined, the side wall of the fluid inlet part 730 is inclined. Moisture such as condensed water generated in 733 may be discharged while flowing down without condensing on the corresponding portion, thereby preventing the phenomenon of freezing due to condensing moisture at the fluid inlet 711 .

In addition, in the refrigerator of the present invention, the concave depth (D) of the implantation detection duct 710 is made to satisfy the condition of (1.5mm*2)+T≤D with respect to the thickness (T) of the implantation confirmation sensor 740 . Therefore, moisture can smoothly pass through the gap between each wall surface in the implantation detection duct 710 and the implantation confirmation sensor 740 , and freezing of the implantation confirmation sensor 740 is prevented.

In addition, in the refrigerator of the present invention, since the mounting protrusion 717a formed on the fluid inlet side of the fluid outlet 717 is formed to be concave in the guide passage 713 , moisture such as defrost water or condensed water enters the fluid outlet 712 . Even if it is introduced, it is possible to flow smoothly without being accumulated in the connection portion between the fluid outlet 717 and the guide passage 713 .

In addition, since the refrigerator of the present invention is configured such that at least one portion of the flow path cover 720 is in contact with the implantation confirmation sensor 740, the inaccuracy of the implantation confirmation sensor 740 is determined through the correct coupling of the flow path cover 720. You can recognize whether or not it has been installed.

In addition, in the refrigerator of the present invention, since coupling portions 721 and 731a for coupling with the implantation detection duct 710 are provided on the flow path cover 720 , the flow path cover 720 can be accurately mounted and maintained.

In addition, in the refrigerator of the present invention, since the signal line 745 drawn from the conception confirmation sensor 740 has the shortest possible path and is installed without interfering with the fluid flow, damage to the signal line 745 can be prevented.

1. Refrigerator 1a. first temperature sensor
1b. 2nd temperature sensor 11. Case
11a. inner case 11b. out case
12,13. storage rooms 12b, 13b. door
21,22. Evaporator 23. Thermoelectric module
23a. thermoelectric element 23b. sink
231. Heat absorbing side 232. Heating side
30. First fan duct assembly 31. First cooling fan
40. Second fan duct assembly 41. Second cooling fan
42. Grill Pan 42a. suction duct
42b. fluid outlet 42c. chin
43. Shroud 43a. fluid inlet
43b. Guide duct 50. Defrost device
51,52. Heater 60. Compressor
61. First refrigerant passage 62. Second refrigerant passage
63. Refrigerant valve 70. Implantation detection device
710. Implantation detection duct 711. Fluid inlet
712. Fluid outlet 713. Guide flow path
714. Installation groove 715. Detachment prevention projection
716. Draw-out guide groove 717. Fluid outlet
717a. Mounting protrusion 717b. cover
717c. Joiner 718. Concave groove
720. Euro cover 721. Second coupling part
722. Contact projection 730. Fluid inlet
731. Front wall 731a. second coupling part
732. Rear wall 733. Side wall
733a. Slope 734. Inlet Slot
740. Implantation confirmation sensor 741. Heating element
742. Sensing element 743. Sensor PCB
744. Sensor housing 745. Signal wire
80. Control

Claims (34)

case providing storage room;
a cold air heat source for generating cold air supplied to the storage chamber;
a first duct guiding the fluid inside the storage chamber to flow to the cold air heat source;
a second duct guiding the fluid around the cold air heat source to flow into the storage chamber;
Including; an implantation detection device for detecting the amount of frost or ice generated in the cold air heat source;
The implantation detection device,
An implantation detection duct providing a flow path through which a fluid passes, a flow path cover covering the implantation detection duct to separate it from a cold air heat source, and an implantation detection duct disposed in the implantation detection duct to measure physical properties of a fluid passing through the implantation detection duct includes a sensor,
The lower end of the flow path cover is provided with a fluid inlet portion having a peripheral wall while extending downward so as to be exposed to the flow path through which the fluid flows toward the cold air heat source while passing through the first duct,
The refrigerator, characterized in that the inward inclined surface toward the bottom is formed on the peripheral wall of the fluid inlet. The method of claim 1,
The inclined surfaces are respectively formed on both side walls of the fluid inlet part. The method of claim 1,
and an inflow slot for inflow of the fluid flowing backward from the cold air heat source is formed on a surface opposite to the cold air heat source among the peripheral wall surfaces of the fluid inlet. The method of claim 1,
The refrigerator, characterized in that the flow path cover is formed with contact protrusions protruding to contact both ends of the implantation confirmation sensor. The method of claim 1,
The implantation detection duct is formed with a concave indentation on the rear surface of the second duct facing the cold air heat source,
A refrigerator that the concave depth (D) of the implantation detection duct is made to satisfy the condition of (1.5mm*2)+T≤D with respect to the thickness (T) of the implantation confirmation sensor. The method of claim 1,
The refrigerator, characterized in that the physical property includes at least one of temperature, pressure, and flow rate. The method of claim 1,
The implantation confirmation sensor is a refrigerator, characterized in that it comprises a sensing element and a sensing derivative. 8. The method of claim 7,
Refrigerator, characterized in that the sensing derivative includes a heating element that generates heat. The method of claim 1,
The second duct is
A grill pan that forms a rear wall surface in the storage chamber and has a plurality of fluid discharge portions to discharge the fluid into the storage chamber;
The refrigerator, characterized in that it comprises a shroud installed to cover a part of the rear surface of the grill pan. 10. The method of claim 9,
The implantation detection duct is
A fluid outlet portion having an open portion so that the fluid flows out while being positioned in the shroud;
and a guide passage for guiding the flow of a fluid while concave in the rear surface of the grill pan is formed. 11. The method of claim 10,
A portion of the fluid outlet formed in the shroud is configured to be concave in the guide passage formed in the grill pan. 11. The method of claim 10,
An open portion through which the fluid flows out of the fluid outlet portion is disposed to be exposed to a flow path through which the fluid flows toward the second duct while passing through the cold air heat source. case providing storage room;
a cold air heat source for generating cold air supplied to the storage chamber;
a first duct guiding the fluid inside the storage chamber to flow to the cold air heat source;
a second duct guiding the fluid around the cold air heat source to flow into the storage chamber;
Including; an implantation detection device for detecting the amount of frost or ice generated in the cold air heat source;
The implantation detection device,
An implantation detection duct providing a flow path through which a fluid passes, a flow path cover covering the implantation detection duct to separate it from a cold air heat source, and an implantation detection duct disposed in the implantation detection duct to measure physical properties of a fluid passing through the implantation detection duct includes a sensor,
At least one portion of the flow path cover is configured to be in contact with the conception confirmation sensor. 14. The method of claim 13,
The refrigerator, characterized in that the flow path cover is formed with contact protrusions protruding to contact both ends of the implantation confirmation sensor. 14. The method of claim 13,
The implantation confirmation sensor is installed in a direction perpendicular to the direction in which the fluid in the implantation detection duct flows, and both ends are inserted and installed in installation grooves formed on both side walls of the implantation detection duct,
The refrigerator, characterized in that the flow path cover is formed with a contact protrusion partially recessed into the installation groove. 14. The method of claim 13,
A protruding end is formed protruding from any one of the depth direction outer surface of the implantation detection duct of the implantation confirmation sensor and the outer surface opposite to the cold air heat source,
Installation grooves for accommodating the ends of the implantation confirmation sensor are respectively formed on both side walls of the implantation detection duct, and an indentation groove having the same shape as the protruding end is additionally formed on the inner surface of the installation groove so that the protruding end is recessed. refrigerator to do. 14. The method of claim 13,
The implantation detection duct is formed with a concave indentation on the rear surface of the second duct facing the cold air heat source,
A refrigerator that the concave depth (D) of the implantation detection duct is made to satisfy the condition of (1.5mm*2)+T≤D with respect to the thickness (T) of the implantation confirmation sensor. 14. The method of claim 13,
The second duct is
A grill pan that forms a rear wall surface in the storage chamber and has a plurality of fluid discharge portions to discharge the fluid into the storage chamber;
The refrigerator, characterized in that it comprises a shroud installed to cover a part of the rear surface of the grill pan. 19. The method of claim 18,
The implantation detection duct is
A fluid outlet portion having an open portion so that the fluid flows out while being positioned in the shroud;
and a guide passage for guiding the flow of a fluid while concave in the rear surface of the grill pan is formed. 20. The method of claim 19,
A portion of the fluid outlet formed in the shroud is configured to be concave in the guide passage formed in the grill pan. 20. The method of claim 19,
An open portion through which the fluid flows out of the fluid outlet portion is disposed to be exposed to a flow path through which the fluid flows toward the second duct while passing through the cold air heat source. 20. The method of claim 19,
Guide ducts are formed on both sides of the shroud to guide the fluid flow up to the fluid discharge unit located at the lower portion of the grill pan,
The signal line connected to the implantation confirmation sensor in the implantation detection duct is drawn out from the implantation detection duct and horizontally drawn out to the rear surface of the guide duct in a state in contact with the rear surface of the grill pan, and then in contact with the rear surface of the guide duct A refrigerator, characterized in that it is bent in a vertical direction along the corresponding guide duct and is configured to be drawn out to the upper part. 14. The method of claim 13,
The flow path cover is provided with a fluid inlet,
and the fluid inlet portion is disposed to be exposed to a flow path through which the fluid flows toward the cold air heat source while passing through the first duct to resist the flow of the fluid flowing into the implantation detection duct. 14. The method of claim 13,
The flow path cover is provided with a fluid inlet,
The refrigerator, characterized in that the fluid inlet is disposed at a lower position than the lower end of the cold air heat source. 14. The method of claim 13,
The flow path cover is provided with a fluid inlet,
The refrigerator, characterized in that the fluid inlet portion is formed of a tube body extending downward from the lower end of the flow path cover and having a peripheral wall. 14. The method of claim 13,
The refrigerator, characterized in that the inward inclined surface toward the bottom is formed on the peripheral wall of the fluid inlet. case providing storage room;
a cold air heat source for generating cold air supplied to the storage chamber;
a first duct guiding the fluid inside the storage chamber to flow to the cold air heat source;
a second duct guiding the fluid around the cold air heat source to flow into the storage chamber;
Including; an implantation detection device for detecting the amount of frost or ice generated in the cold air heat source;
The implantation detection device,
An implantation detection duct providing a flow path through which a fluid passes, a flow path cover covering the implantation detection duct to separate it from a cold air heat source, and an implantation detection duct disposed in the implantation detection duct to measure physical properties of a fluid passing through the implantation detection duct includes a sensor,
The refrigerator, characterized in that at least one of the upper end portion or the lower end portion of the flow path cover is provided with a coupling portion for coupling with the implantation detection duct. 28. The method of claim 27,
and the coupling part includes a first coupling part formed at an upper end of the flow path cover. 29. The method of claim 28,
The first coupling part
Refrigerator, characterized in that it is made to protrude upward from the upper end of the flow path cover. 28. The method of claim 27,
and the coupling part includes a second coupling part formed at a lower end of the flow path cover. 31. The method of claim 30,
The second coupling portion is a refrigerator, characterized in that consisting of a hook fitted to the inner wall surface of the implantation detection duct. 28. The method of claim 27,
The flow path cover is provided with a fluid inlet,
The refrigerator, characterized in that the fluid inlet portion is formed of a tube body extending downward from the lower end of the flow path cover and having a peripheral wall. 33. The method of claim 32,
The refrigerator, characterized in that the inward inclined surface toward the bottom is formed on the peripheral wall of the fluid inlet. case providing storage room;
a cold air heat source for generating cold air supplied to the storage chamber;
a first duct guiding the fluid inside the storage chamber to flow to the cold air heat source;
a second duct guiding the fluid around the cold air heat source to flow into the storage chamber;
Including; an implantation detection device for detecting the amount of frost or ice generated in the cold air heat source;
The implantation detection device,
An implantation detection duct providing a flow path through which the fluid passes, and an implantation confirmation sensor disposed in the implantation detection duct to measure physical properties of the fluid passing through the implantation detection duct,
The second duct is
A grill pan that forms a rear wall surface in the storage chamber and has a plurality of fluid discharge portions to discharge the fluid into the storage chamber;
It is installed to cover a part of the rear surface of the grill pan and includes a shroud formed on both sides of which guide ducts are formed to guide the fluid flow up to the fluid discharge part located in the lower portion of the grill pan,
The signal line connected to the conception confirmation sensor is horizontally drawn out from the conception detection duct to the rear surface of the guide duct, and then is bent vertically along the guide duct to be drawn out upward.

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