KR20220018176A - refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator configured such that a fluid inlet part of a frosting detection duct is formed to protrude toward a flow path of a fluid to provide fluid resistance, and an inlet slot is formed in the fluid inlet part to be opened so that the fluid flowing backward from a cold air heat source can smoothly flow in when the cold air heat source is frosted, and the slot length of the inlet slot and the protrusion length of the fluid inlet part are made to satisfy the condition of 0.2 <= Ls/Li <= 1.0. Accordingly, the physical properties sensed by a frosting detection device can have sufficient discrimination power to not only check the frosting but also to additionally confirm various frosting-related information.

Description

refrigerator {refrigerator}

The present invention relates to a new type of refrigerator in which the structure of the fluid inlet side of the implantation detection duct is improved so as to improve the detection accuracy of the implantation detection device.

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 raising the ambient temperature of the evaporator by heating the heater. 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 a temperature difference or a pressure difference between the inlet side and the outlet side of the evaporator has been proposed. Technology 1), Patent Publication No. 10-2019-0106201 (Prior Art 2), Patent Publication No. 10-2019-0106242 (Prior Art 3), Patent Publication No. 10-2019-0112482 (Prior Art 4), Publication Patent No. 10-2019-0112464 No. (prior art 5) and the like are presented.

The above-described technique forms an implantation detection flow path (bypass flow path) configured to have a separate flow from the air flow passing through the evaporator in the cold air duct, and changes according to the difference in the amount of air passing through the implantation detection flow path due to implantation of the evaporator It is possible to check the implantation amount by measuring the temperature difference.

Accordingly, it is possible to confirm the actual amount of implantation, and the start time of the defrost operation can be accurately determined based on the confirmed amount of implantation.

On the other hand, in order to increase the detection reliability of the implantation amount of the evaporator, it is preferable that the amount of air passing through the implantation detection duct be significantly different from the cold air heat source before the implantation and at the time of implantation.

A method for increasing the difference in the amount of air may be made in various ways.

In the case of Prior Art 1, the position of the sensor, the control method of the control unit, the structure for protruding the fluid inlet (barrier) from the implantation detection flow path, and the inlet and outlet positions of the implantation detection duct are presented to increase the reliability of the implantation detection, respectively. have.

However, since the protruding structure of the fluid inlet (barrier) presented in the above-mentioned prior art 1 shows the protruding length of the fluid inlet and the length of the slot only as simple numerical values, when the duct is changed for each model of the refrigerator, the It is difficult to achieve the same effect.

Of course, in Prior Art 1, it is mentioned that the length of the slot may be designed within the range of 1/5 to 1/2 of the protruding length of the fluid inlet.

However, the above-described relationship between the slot and the protrusion length is only a relationship in consideration of the preferred length range of the slot and the preferred protrusion length range of the fluid inlet, respectively.

Accordingly, if the design (the length of the slot is designed within the range of 1/5 to 1/2 of the protrusion length of the fluid inlet part) is designed in the relationship between the two length ranges suggested in Prior Art 1, when an implantation occurs, the flow back into the implantation detection duct is As the inflow of air was insufficient, the temperature difference did not reach the level of having a high discrimination power.

In particular, due to the lack of air inflow at the time of implantation, the discrimination power for detecting implantation was low, making it difficult to accurately detect implantation.

In addition, the difference in temperature checked by the implantation detection device upon detection of an implantation must exceed at least 28°C to have a discriminatory power capable of recognizing various information related to implantation.

In this case, the various information related to the implantation may include not only the detection of an implantation, but also the clogging of the implantation detection duct, and whether there is residual ice after defrosting.

However, in the prior art, because only the protrusion length of the fluid inlet portion or only the length of the slot is considered, the implantation detection device can only confirm a temperature difference of about 26°C to 28°C during implantation detection, and with this temperature difference was disappointing that it did not have sufficient discrimination power to distinguish and judge each other information related to conception.

That is, the protrusion length of the fluid inlet portion affects the amount of fluid flowing into the corresponding implantation detection flow path when the amount of implantation in the evaporator is small, whereas the length of the slot formed in the fluid inlet portion determines the corresponding implantation detection flow path when there is an implantation in the evaporator. It functions to influence the amount of fluid flowing into the body.

Accordingly, the protrusion length of the fluid inlet and the length of the slot must always be considered together to provide the maximum temperature difference regardless of the implantation amount.

Nevertheless, in the prior art, since studies that consider both the protrusion length of the fluid inlet and the length of the slot have not been made, in fact, the length of the fluid inlet and the slot had to be designed separately. The physical properties did not have discriminatory power to confirm not only the conception but also other information.

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 problem according to the prior art described above, and an object of the present invention is to provide an optimal design condition for the relationship between the vertical opening distance of the inlet slot formed in the implantation detection duct and the protrusion length of the fluid inlet part. By providing it, the measurement precision for implantation detection can be improved.

In particular, the physical property values obtained under the optimal design conditions are intended to have sufficient discriminatory power to not only confirm the conception but also to additionally check various implantation-related information.

In addition, the present invention provides a flow resistance that gives resistance to the flow of the fluid at the site where the fluid flows in the implantation detection duct, so that the amount of fluid flowing into the implantation detection duct can be reduced as much as possible. The purpose is to allow the fluid to flow smoothly by using the pressure difference between the fluid inlet part and the fluid outlet part of the

In order to achieve the above object, the refrigerator of the present invention may be configured such that the fluid inlet formed in the implantation detection duct generates flow resistance against the flow of the fluid. Accordingly, it is possible to reduce the flow rate of the fluid introduced through the fluid inlet.

In addition, in the refrigerator of the present invention, an open fluid inlet may be formed on one wall of the fluid inlet so that a portion of the fluid flowing through the storage chamber to the cold air heat source flows. This allows fluid to enter through the fluid inlet.

In addition, in the refrigerator of the present invention, an inlet slot may be formed in the fluid inlet part. Accordingly, cold air flowing backward from the cold air heat source may be introduced.

In addition, in the refrigerator of the present invention, the protrusion length (Li) of the fluid inlet compared to the slot length (Ls) of the inlet slot may be configured to satisfy the condition of 0.2≤Ls/Li≤1.0. As a result, the temperature difference before and after the heating of the heating element is at least 5°C or more different from the slot length (Ls) of the inlet slot when the protrusion length (Li) of the fluid inlet is not taken into account, so that the conception can be accurately recognized It can have some degree of discrimination.

In addition, in the refrigerator of the present invention, at least a portion of the implantation detection duct may be disposed in a flow path formed between the second duct and the storage chamber. Accordingly, the fluid that has passed through the implantation detection duct may flow into the storage chamber through the second 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, the refrigerator of the present invention may be configured to include an implantation confirmation sensor and a sensing derivative.

In addition, the refrigerator of the present invention may be configured as a means for inducing the sensing derivative to improve precision when measuring physical properties.

In addition, in the refrigerator of the present invention, the sensing derivative constituting the implantation sensing device may include a heating element that generates heat, and the sensor 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 at least one of a thermoelectric module and an evaporator as a cold air heat source.

Also, in the refrigerator of the present invention, the thermoelectric module may include a thermoelectric element and a sink.

In addition, the refrigerator of the present invention may be configured to include a cold air heat source including an evaporator and a refrigerant valve.

In addition, the refrigerator of the present invention may be configured as a cold air heat source including a compressor.

In addition, the refrigerator of the present invention may be configured to include a cooling fan that blows the fluid from the cold air heat source.

In addition, the refrigerator of the present invention may be configured such that the slot length (Ls) of the inlet slot and the protrusion length (Li) of the fluid inlet part satisfy the condition of 0.2≤Ls/Li≤0.8. As a result, the temperature difference before and after heating of the heating element can be further different by at least 5°C or more compared to the slot length (Ls) of the inlet slot when the protrusion length (Li) of the fluid inlet is not taken into account, so that the conception can be recognized more accurately There may be some discriminatory power.

In addition, the refrigerator of the present invention may be configured such that the slot length (Ls) of the inlet slot and the protrusion length (Li) of the fluid inlet part satisfy the condition of 0.2≤Ls/Li≤0.6. As a result, the temperature difference before and after heating of the heating element can be further different by at least 5°C or more compared to the slot length (Ls) of the inlet slot when the protrusion length (Li) of the fluid inlet is not taken into account, so that the conception can be recognized more accurately There may be some discriminatory power.

In addition, the refrigerator of the present invention may be configured such that the slot length (Ls) of the inlet slot and the protrusion length (Li) of the fluid inlet part satisfy the condition of 0.4≤Ls/Li≤1.0. As a result, the temperature difference before and after heating of the heating element can be further different by at least 5°C or more compared to the slot length (Ls) of the inlet slot when the protrusion length (Li) of the fluid inlet is not taken into account, so that the conception can be recognized more accurately There may be some discriminatory power.

In addition, the refrigerator of the present invention may be configured such that the slot length (Ls) of the inlet slot and the protrusion length (Li) of the fluid inlet part satisfy the condition of 0.4≤Ls/Li≤0.8. As a result, the temperature difference before and after heating of the heating element can be further different by at least 5°C or more compared to the slot length (Ls) of the inflow slot when the protrusion length (Li) of the fluid inlet is not taken into account. Able to discriminate enough to recognize additional information

In addition, the refrigerator of the present invention may be configured such that the slot length (Ls) of the inlet slot and the protrusion length (Li) of the fluid inlet part satisfy the condition of 0.6≤Ls/Li≤1.0. As a result, the temperature difference before and after heating of the heating element can be further different by at least 5°C or more compared to the slot length (Ls) of the inlet slot when the protrusion length (Li) of the fluid inlet is not taken into account, so that the conception can be recognized more accurately There may be some discriminatory power.

In addition, the refrigerator of the present invention may be configured such that the slot length (Ls) of the inlet slot and the protrusion length (Li) of the fluid inlet part satisfy the condition of 0.6≤Ls/Li≤0.8. As a result, the temperature difference before and after heating of the heating element can be further different by at least 5°C or more compared to the slot length (Ls) of the inflow slot when the protrusion length (Li) of the fluid inlet is not taken into account. It may have discriminatory power enough to recognize additional information.

In addition, the refrigerator of the present invention may be configured such that the open cross-sectional area G1 of the fluid inlet satisfies the condition of 0.8*G2≤G1≤1.3*G2 when viewed based on the open cross-sectional area G2 of the inlet slot. Accordingly, it is possible to reduce a phenomenon in which the fluid inlet is designed to be excessively small or to be excessively large compared to the inlet slot, thereby reducing the discrimination force.

In addition, in the refrigerator of the present invention, after frost or ice is generated in the cold air heat source, an inlet slot for guiding the fluid to flow into the implantation detection duct may be formed between the fluid inlet of the implantation detection duct and the cold air heat source. Thereby, it is possible to increase the discrimination power before and after implantation of the cold air heat source.

In addition, the refrigerator of the present invention may include an evaporator in which the cold air heat source is located at the rear in the storage compartment, and the implantation detection duct may be disposed in front of the evaporator. Accordingly, the fluid flowing from the storage chamber to the evaporator may be partially introduced into the implantation detection duct.

In addition, in the refrigerator of the present invention, the fluid inlet portion of the implantation detection duct may be disposed at a lower place than the lower end of the evaporator. Accordingly, the fluid flowing from the storage chamber to the evaporator may be partially introduced into the implantation detection duct.

In addition, in the refrigerator of the present invention, a flow resistance body may be provided at the fluid inlet portion of the implantation detection duct. Accordingly, the flow rate of the fluid flowing into the cold air heat source can be greater than the flow rate of the fluid flowing into the implantation detection duct.

In addition, in the refrigerator of the present invention, the flow rate per unit time of the fluid flowing to the cold air heat source may be greater than the flow rate per unit time of the fluid flowing into the implantation detection duct. Accordingly, when the cold air heat source is implanted, some of the fluid passing through the cold air heat source may be additionally introduced into the implantation detection duct.

As described above, the refrigerator of the present invention has the effect that the flow rate resistance is provided at the portion where the fluid flows into the implantation detection duct, so that the amount of fluid flowing into the implantation detection duct can be minimized even when the implantation is insignificant.

In addition, the refrigerator of the present invention has the effect that, in the state in which the idea is made, the fluid can smoothly flow due to the pressure difference between the fluid inlet and the fluid outlet despite the flow resistance.

In addition, since the refrigerator of the present invention is designed so that the protrusion length (Li) of the fluid inlet part compared to the slot length (Ls) of the inlet slot of the implantation detection duct satisfies the condition of 0.2≤Ls/Li≤1.0, the upper and lower sides of the inlet slot It has the effect of being able to further increase the logic temperature for implantation detection compared to the case where only the opening distance is changed or only the vertical protrusion length of the fluid inlet is changed.

In addition, in the refrigerator of the present invention, since the logic temperature can obtain a value in a larger temperature range than the reference temperature difference value used for conventional implantation determination, not only the role of simple implantation detection, but also more diverse causes related to implantation are additionally distinguished It has the effect of being able to have a discriminatory power to do it.

In addition, in the refrigerator of the present invention, the open cross-sectional area (G1) of the fluid inlet is designed to satisfy the condition of 0.8*G2≤G1≤1.3*G2 based on the open cross-sectional area (G2) of the inlet slot. Compared to the inlet slot, the fluid inlet is designed to be excessively small or designed to be excessively large, so that it is possible to reduce the phenomenon of lowering the discrimination force.

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 partial cross-sectional view showing the space on the rear side of the second storage compartment in the case to explain the installation state of the implantation detection device and the evaporator constituting the refrigerator according to the embodiment of the present invention;
8 is an enlarged view of part “A” of FIG. 7
9 is a front 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;
10 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;
11 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;
12 is an enlarged view of part “B” of FIG. 11
13 is a rear view of the fan duct assembly shown 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;
14 is a rear view of the fan duct assembly to explain the installation state of the implantation detection device constituting the refrigerator according to the embodiment of the present invention;
15 is an enlarged view illustrating an installation state of an implantation detection device constituting a refrigerator according to an embodiment of the present invention;
16 is an enlarged view of part “C” of FIG. 15
17 is an enlarged view showing a state in which the flow path cover is removed to explain the internal state of the implantation detection duct of the implantation detection device constituting the refrigerator according to the embodiment of the present invention;
18 is an enlarged perspective view illustrating an installation state of an implantation detection device constituting a refrigerator according to an embodiment of the present invention;
19 is an enlarged view of part “C” of FIG. 18
20 is a comparison table illustrating the relationship between the flow rate and the flow rate with respect to the protruding length of the fluid inlet of the refrigerator according to the embodiment of the present invention;
21 is a comparison table illustrating the relationship between the flow rate and the flow rate with respect to the slot length of the inflow slot of the refrigerator according to the embodiment of the present invention;
22 is a graph showing the temperature change amount with respect to the ratio of the length of the inlet slot slot of the refrigerator and the protrusion length of the fluid inlet according to the embodiment of the present invention;
23 and 24 are enlarged views of main parts shown to explain the flow of fluid according to whether the implantation detection device according to an embodiment of the present invention is implanted;
25 is an enlarged view of the main part shown to explain the installation state of the implantation detection device according to the embodiment of the present invention;
26 is a schematic diagram illustrating an implantation confirmation sensor of an implantation detection device according to an embodiment of the present invention;
27 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;
28 and 29 are shown to explain 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 is to provide an optimal design condition for the relationship between the inlet slot slot length of the implantation detection duct and the protrusion length of the fluid inlet so that the measurement precision for implantation detection can be improved.

In particular, the present invention allows the physical property values sensed by the implantation detection device to have sufficient discriminating power to not only confirm implantation but also to additionally confirm various implantation-related information.

An embodiment of the preferred structure of the refrigerator according to the present invention and an embodiment of operation control will be described with reference to FIGS. 1 to 29 .

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 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 such that the internal temperature of the storage chamber is maintained 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 (indoor temperature) may be measured by the first temperature sensor 1a as shown in FIG. 4 , and the internal temperature of the storage chamber may be measured by the second temperature sensor 1b.

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 .

Also, as shown in FIGS. 1 and 2 , doors 12b and 13b may be provided in the storage compartments 12 and 13 .

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 from 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 the cold air of the cold air heat source is made of a refrigeration system including the evaporators 21 and 22 and the compressor 60 as an example.

The evaporators 21 and 22 form a refrigeration system together with a compressor 60 (refer to 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 serve to supply the cold air generated while passing through the 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 that guides 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 .

1 and 2, each of the fan duct assemblies 30 and 40 includes a first fan duct assembly 30 and a second storage chamber 13 for guiding cold air to flow in the first storage chamber 12. ) may include a second fan duct assembly 40 for guiding the flow of cold air therein.

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

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 9 , 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.

10 and 11 , 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).

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 cold air outlet 42b of the grill pan 42 .

In this case, two or more of the cold air outlets 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 .

The second evaporator 22 is configured to be positioned below the fluid inlet 43a.

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 13 , 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.

As shown in FIGS. 4 and 7 and 13 , the defrosting device 50 may include a second heater 52 .

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.

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, and FIGS. 10 to 16 shows a state in which the implantation detection device is installed in the second fan duct assembly.

As in the embodiment shown in these drawings, the implantation detection device according to an embodiment of the present invention is the flow of fluid guided to the suction duct (first duct) 42a and the second fan duct assembly (second duct) 40 It will be described as an example of a device that detects the implantation of the second evaporator (cold air heat source) 22 while being positioned on the path.

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 accurately determines the execution time of the defrost operation based on the recognized degree of implantation. It can be configured to be known.

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

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

The implantation detection duct 710 is provided with an implantation confirmation sensor 730 for confirming the implantation of the second evaporator 22, and provides a passage (channel) through which air flows.

The conception detection duct 710 may be configured as a flow path for guiding the air flow that passes through the second evaporator 22 and the air flow that flows through the nat of the second fan duct assembly 40 and separates the air flow. .

The implantation detection duct 710 may be provided with a fluid inlet 711 and a fluid outlet 712 .

The fluid inlet 711 is a portion open to allow fluid to flow into the implantation detection duct 710 , and the fluid outlet 712 is a portion open to allow the fluid passing through the implantation detection duct 710 to flow out. .

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

At least a portion of the implantation detection duct 710 may be disposed in a flow path formed between the suction duct (first duct) 42a and the second evaporator (cold air heat source) 22 .

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

That is, a portion of the air sucked into the air inlet side of the second evaporator 41 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 in a flow path formed between the second fan duct assembly (second duct) 40 and the second storage chamber 13 .

Specifically, the fluid outlet 712 of the implantation detection duct 710 may be located between the air outlet side of the second evaporator 22 and the flow path through which cold air is supplied to the second storage chamber 13 .

More specifically, as shown in FIG. 13, the fluid outlet 712 of the implantation detection duct 710 passes through the second evaporator 22 to the fluid inlet 43a of the shroud 43. It may be located openly on the flow path through which the fluid flows.

That is, the air that has passed through the implantation detection duct 710 can flow directly between the air outlet side of the second evaporator 22 and the fluid inlet 43a of the shroud 43 .

The implantation detection duct 710 may be recessed in a surface of the second fan duct assembly 40 opposite to the second evaporator 22 so that air flows into the second fan duct assembly 40 . At this time, the implantation detection duct 710 may protrude forward of the second fan duct assembly 40 as shown in FIG. 9 .

A part of the implantation detection duct 710 may be formed in the grill pan 42 , and the other part may be formed in the shroud 43 . For example, a lower end portion through which the fluid flows may be formed in the grill pan 42 , and an upper end portion through which the fluid flows may be formed in the shroud 43 .

Accordingly, the implantation detection duct 710 may be configured to cross the cold air heat source (second evaporator) up and down. In this case, the fluid outlet 712 may be provided at the upper end portion of the implantation detection duct 710 , and the fluid inlet 711 may be provided at the lower end portion of the implantation detection duct 710 .

Although not shown, the implantation detection duct 710 may be formed only on the grill pan 42 or only on the shroud 43 .

The implantation detection duct 710 may include an implantation detection passage 713 and a passage cover 714 .

At this time, the implantation detection flow path 713 is recessed in the rear surface of the second fan duct assembly 40 and configured so that a fluid can flow into the second fan duct assembly 40 , and the flow path cover 714 is the implantation detection flow path 713 . It is configured to block the open back side of the (a side opposite to the second evaporator).

Although not shown, the implantation detection duct 710 may be manufactured as a separate tube from the second fan duct assembly 40 and then be configured to be fixed (attached or coupled) to the second fan duct assembly 40. have.

The flow path cover 714 serves to partition the flow path inside the implantation detection duct 710 from the external environment while being installed to cover the open rear surface of the implantation detection flow path 713 .

In addition, the fluid outlet 712 provided to the implantation detection duct 710 may be formed by the flow path cover 714 .

That is, the flow path cover 714 is formed to cover the remaining portion of the implantation detection flow path 713 except for the side where the fluid flows out, so that the fluid outlet 712 is provided in an open state to the grill pan 42 . can

At least a portion of the flow path cover 714 may be inclined (or rounded). That is, considering that the portion of the shroud 43 where the implantation detection passage 713 is formed is inclined (or round) formed, the portion for covering the portion of the implantation detection passage 713 is the shroud. It can be formed with the same slope (or round) as the slope (or round surface) of (43).

The rear surface of the flow path cover 714 may be configured to be positioned on the same plane as the rear surface of the grill pan 42 .

11 and 17, the grill pan 42 in which the implantation detection flow path 713 is recessed is formed with a mounting jaw 42c on which the flow path cover 714 can be placed and restrained. , the mounting jaw 42c may be recessed from the rear surface of the grill pan 42 by the thickness of the flow path cover 714 .

12, 16 and 19, the flow path cover 714 may be provided with a fluid inlet part 715.

The fluid inlet part 715 is configured to provide flow resistance to the fluid flowing into the implantation detection flow path 713 .

That is, the flow rate of the fluid flowing to the cold air heat source guided by the first duct by the flow resistance of the fluid inlet 715 can be greater than the flow rate of the fluid flowing into the implantation detection flow path 713 . .

The fluid inlet 715 may be formed as a tubular body having a peripheral wall while extending downward from the flow path cover 714 .

The fluid inlet 715 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 passage 713 .

12, the upper and lower surfaces of the fluid inlet 715 may be formed to be open.

The lower surface of the open fluid inlet 715 may serve as the fluid inlet 711 , and the upper surface of the open fluid inlet 715 may be installed to match the open lower surface of the implantation detection flow path 713 . can

A part of the fluid inlet part 715 may be formed to protrude from the boundary 42d of the first duct toward the movement path of the fluid provided by the first duct.

The fluid inlet 715 may function as a flow resistor to prevent the flow of fluid flowing into the implantation detection duct 710 .

That is, the flow rate of the fluid flowing into the implantation detection duct 710 by the fluid inlet 715 provided as the flow resistor can be made smaller than the flow rate of the fluid flowing to the cold air heat source.

Of course, although not shown, the fluid flows through the fluid inlet 715 of the implantation detection duct 710 or the first duct to the cold air heat source while the flow resistance body has a separate configuration from the fluid inlet 715 . It may be further provided on the flow path to be used.

At this time, the boundary 42d of the first duct may be a bending portion in which the suction duct 42a protruding forward from the lower end of the grill pan 42 is bent obliquely from the grill pan 42, and the fluid inlet The part 715 may be configured to protrude downward directly from the bent portion.

The protruding portion of the fluid inlet 715 serves as a flow resistance to the fluid flowing from the storage chamber (second storage chamber) to the cold air heat source (second evaporator) by the guidance of the first duct (suction duct).

Considering this, as the protrusion length (height protruding downward from the boundary of the suction duct) (Li) of the fluid inlet part 715 is longer, the amount of fluid inflow into the pre-implantation detection flow path 713 of the cold air heat source (second evaporator) is may be reduced, and as the amount of fluid introduced into the pre-implantation detection flow path 713 before implantation is small, the flow rate in the implantation detection flow path 713 may become slower.

In addition, as the flow rate in the implantation detection flow path 713 becomes slower, the difference between the maximum temperature and the minimum temperature confirmed by the on-off control of the heating element 731 of the implantation confirmation sensor 730, which will be described later, may increase. It is possible to increase the discrimination power in the confirmation of implantation using.

The accompanying FIG. 20 shows the inflow amount and flow velocity of the fluid before and after implantation according to the protrusion length Li of the fluid inlet part 715 described above.

As can be seen from these drawings, as the protrusion length Li of the fluid inlet 715 is longer before the cold air heat source is implanted, the flow rate flowing into the implantation detection flow path 713 can be further reduced, and the flow rate can be further slowed down. can be known

At this time, it can be seen that the protrusion length Li of the fluid inlet part 715 has insignificant difference in the flow rate flowing into the implantation detection flow path 713 when the cold air heat source is implanted, and the flow rate also has insignificant difference.

Of course, as can be seen from the drawings, if the protrusion length Li of the fluid inlet part 715 is excessively long, the difference in the amount of fluid inflow into the implantation detection flow path 713 before and during implantation is rather reduced, and the flow rate difference It can also be seen that the decrease

Meanwhile, the fluid inlet part 715 may be formed to have a front side wall surface 715a and a rear side wall surface 715b.

The front wall surface 715a of the fluid inlet part 715 is a wall surface located on the flow inlet side of the fluid flowing to the cold air heat source under the guidance of the first duct, and the rear wall surface 715b is the first duct. It is a wall surface located on the flow outlet side of the fluid flowing to the cold air heat source by being guided.

In this case, the rear wall surface 715b may be a wall surface facing the cold air heat source.

The fluid inlet 715 may include a side wall 715c connecting the front wall 715a and the rear wall 715b.

An inlet slot 715d may be formed in the rear wall 715b of the fluid inlet 715 .

The inlet slot 715d is an open portion to guide cold air flowing backward from the cold air heat source into the implantation detection flow path 713 .

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 smoothly flow into the implantation detection passage 713 and pass through the implantation detection passage 713.

The accompanying FIG. 21 shows the inflow amount and flow velocity of the fluid before and after implantation according to the slot length Ls of the inflow slot 715d.

As can be seen from these figures, it can be seen that after the implantation of the cold air heat source starts, the longer the slot length (Ls), the greater the difference in flow rate from that before implantation.

In addition, the inlet slot 715d is guided by the suction duct 42a and the fluid flowing to the cold air heat source passes through the fluid inlet 715. The rear side wall 715b of the corresponding fluid inlet 715. It also performs the function of passing so that it flows directly to the cold heat source without colliding with it.

That is, if the inlet slot 715d does not exist in the rear wall 715b, the fluid collides with the rear wall 715b in the process of passing the fluid inlet 715 and flows into the implantation detection passage 713. do.

Accordingly, if the inflow slot 715d 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.

Of course, even when the inflow slot 715d formed in the rear wall 715b is excessively large, as the amount of fluid inflow before implantation is excessively increased, the discrimination force at the time of implantation detection may be lowered.

Although the inlet slot 715d is not formed in the fluid inlet 715 , it may be formed in any one portion between the fluid inlet 715 and the cold air heat source.

Preferably, the inflow slot 715d may be formed so that the flow rate per unit time of the fluid flowing to the cold air heat source is greater than the flow rate per unit time of the fluid flowing into the implantation detection flow path 713 .

The inlet slot 715d is formed to be open from the bottom of the rear wall 715b constituting the fluid inlet portion 715 to a predetermined height.

On the other hand, the slot length (up and down height) Ls of the inlet slot 715d may be made to satisfy the condition of 0.2*Li≤Ls≤1.0*Li with respect to the protrusion length Li of the fluid inlet part 715. have.

That is, as described based on the comparison table of FIGS. 20 and 21 , the protrusion length Li of the fluid inlet part 715 and the slot length Ls of the inflow slot 715d are the longer the length, the greater the flow velocity difference before and after implantation. can be seen to increase.

However, the protrusion length Li of the fluid inlet part 715 and the slot length Ls of the inflow slot 715d are not only limited in lengthening the length, but only one length is lengthened or both lengths are excessively long. If the length is longer, rather adverse effects may occur.

For example, as can be seen from the attached graph of FIG. 22 , the protrusion length Li of the fluid inlet part 715 and the slot length Ls of the inflow slot 715d depend on the length ratio of each other before and after implantation. (713) The difference in the flow rate or the flow rate difference of the fluid flowing into the interior can vary greatly.

Considering this, the protrusion length (Ls) of the slot length (Ls) is not limited to either the slot length (Ls) of the inlet slot (715d) or the upper and lower protrusion length (Li) of the fluid inlet part (715) ( By providing an optimal ratio of Li), an accurate design of the slot length Ls of the inlet slot 715d based on the protrusion length Li of the fluid inlet 715 can be achieved.

Accordingly, while the flow rate flowing into the implantation detection flow path 713 before the occurrence of an implantation can be minimized, the flow rate flowing into the implantation detection flow path 713 at the time of the occurrence of an implantation can be maximized. degree can be achieved.

At this time, the 0.2 and 1.0 are the minimum and maximum limits for the downward protrusion length Li of the fluid inlet 715 compared to the slot length Ls of the inflow slot 715d, and these minimum and maximum limits are In addition to confirmation, it may be a threshold value for obtaining other information related to the conception.

That is, if the downward protrusion length Li of the fluid inlet part 715 is designed as a ratio between the minimum limit value and the maximum limit value compared to the slot length Ls of the inflow slot 715d, whether or not a clogging occurs (whether a defrost operation is required or not) ) as well as whether the initial implantation (whether or not the implantation is early) can be confirmed.

In the initial stage of conception, since it is not necessary to perform the implantation detection operation every cycle, the power consumption according to the execution of the implantation detection operation is reduced as much, thereby improving the consumption efficiency.

Preferably, the slot length (up and down height) Ls of the inlet slot 715d is made to satisfy the condition of 0.2*Li≤Ls≤0.8*Ls with respect to the protrusion length Li of the fluid inlet part 715 . can

If the protrusion length Li of the fluid inlet 715 is designed to satisfy the above condition, the protrusion length Li of the fluid inlet 715 compared to the slot length Ls of the inflow slot 715d. ) may have discriminatory power enough to recognize the conception more accurately.

For example, the temperature difference before and after the heating of the heating element 731 constituting the implantation confirmation sensor 730, which will be described later, may additionally differ by ±5° C. or more, so that at least one of whether there is a clogged implantation, as well as whether initial implantation, or residual ice after a defrosting operation. Additional information can be checked.

Preferably, the slot length (up and down height) Ls of the inlet slot 715d is made to satisfy the condition of 0.2*Li≤Ls≤0.6*Li with respect to the protrusion length Li of the fluid inlet part 715 . can

If the protrusion length Li of the fluid inlet part 715 is designed to satisfy the above-described condition compared to the slot length Ls of the inflow slot 715d, the physical property value (eg, temperature difference) to be checked by the implantation confirmation sensor 730 ) may have discriminatory power enough to recognize the conception more accurately.

For example, the difference in temperature before and after heating of the heating element 731 constituting the conception confirmation sensor 730, which will be described later, is the slot length Ls of the inflow slot 715d compared to the protrusion length Li of the fluid inlet 715. Do not consider Since there may be an additional difference of ±5°C or more compared to when it is not, it is possible to additionally check at least one information of not only whether there is a clogged implantation, but also whether there is an initial implantation or whether there is residual ice after a defrost operation.

Preferably, the slot length (up and down height) Ls of the inlet slot 715d is made to satisfy the condition of 0.4*Li≤Ls≤1.0*Li with respect to the protrusion length Li of the fluid inlet part 715 . can

If the protrusion length Li of the fluid inlet 715 is designed to satisfy the above condition, the protrusion length Li of the fluid inlet 715 compared to the slot length Ls of the inflow slot 715d. It may have discriminatory power enough to recognize the conception more accurately.

For example, the temperature difference before and after the heating of the heating element 731 constituting the conception confirmation sensor 730, which will be described later, is compared to the slot length Ls of the inflow slot 715d. Do not consider the protrusion length Li of the fluid inlet 715. Since there may be an additional difference of ±5°C or more compared to when it is not, it is possible to additionally check at least one information of not only whether there is a clogged implantation, but also whether there is an initial implantation or whether there is residual ice after a defrost operation.

Preferably, the slot length (up and down height) Ls of the inlet slot 715d is made to satisfy the condition of 0.6*Li≤Ls≤1.0*Li with respect to the protrusion length Li of the fluid inlet part 715 . can

If the protrusion length Li of the fluid inlet 715 is designed to satisfy the above condition, the protrusion length Li of the fluid inlet 715 compared to the slot length Ls of the inflow slot 715d. ) may have discriminatory power enough to recognize the conception more accurately.

For example, the temperature difference before and after the heating of the heating element 731 constituting the conception confirmation sensor 730, which will be described later, is compared to the slot length Ls of the inflow slot 715d. Do not consider the protrusion length Li of the fluid inlet 715. Since there may be an additional difference of ±5°C or more compared to when it is not, it is possible to additionally check at least one information of not only whether there is a clogged implantation, but also whether there is an initial implantation or whether there is residual ice after a defrost operation.

Preferably, the slot length (up and down height) Ls of the inlet slot 715d is made to satisfy the condition of 0.6*Li≤Ls≤0.8*Li with respect to the protrusion length Li of the fluid inlet part 715 . can

If the protrusion length Li of the fluid inlet 715 is designed to satisfy the above condition, the protrusion length Li of the fluid inlet 715 compared to the slot length Ls of the inflow slot 715d. ) may have discriminatory power enough to recognize the conception more accurately.

For example, the temperature difference before and after the heating of the heating element 731 constituting the conception confirmation sensor 730, which will be described later, is compared to the slot length Ls of the inflow slot 715d. Do not consider the protrusion length Li of the fluid inlet 715. Since there may be an additional difference of ±5°C or more compared to when it is not, it is possible to additionally check at least one information of not only whether there is a clogged implantation, but also whether there is an initial implantation or whether there is residual ice after a defrost operation.

Most preferably, the slot length (up and down height) Ls of the inlet slot 715d satisfies the condition of 0.4*Li≤Ls≤0.8*Li with respect to the protrusion length Li of the fluid inlet part 715 . can be done

If the protrusion length Li of the fluid inlet 715 is designed to satisfy the above condition, the protrusion length Li of the fluid inlet 715 compared to the slot length Ls of the inflow slot 715d. ) may have discriminatory power enough to recognize the conception more accurately.

For example, the temperature difference before and after the heating of the heating element 731 constituting the conception confirmation sensor 730, which will be described later, is compared to the slot length Ls of the inflow slot 715d. Do not consider the protrusion length Li of the fluid inlet 715. Since there may be an additional difference of ±6°C or more compared to when it is not, it is possible to additionally check at least one information of not only whether there is a clogged implantation, but also whether there is an initial implantation, whether there is residual ice after a defrost operation, and whether the implantation detection passage 713 is clogged inside. .

Of course, the respective distance ratio can obtain a larger amount of temperature change under the condition of 0.6*Li≤Ls≤0.8*Li compared to the condition of 0.4*Li≤Ls≤0.8*Li.

However, considering that the 0.6*Li≤Ls≤0.8*Li condition may be difficult to design compared to the 0.4*Li≤Ls≤0.8*Li condition, each distance ratio is 0.4*Li≤Ls≤0.8*Li. It may be most desirable to set the condition.

The attached graph of FIG. 22 shows the amount of temperature change for each ratio of the protrusion length Li of the fluid inlet 715 to the slot length Ls of the inlet slot 715d (considering the relationship between the conventional slot length and the protrusion length). The amount of change compared to the temperature when not performed) is shown.

As can be seen from this graph, it can be seen that when each distance ratio satisfies the condition of 0.4*Li≤Ls≤0.8*Li, it can be seen that the temperature change amount of ±6°C or more can be additionally obtained.

On the other hand, the open cross-sectional area G1 of the fluid inlet 711 of the implantation detection duct 710 is 0.8*G2≤G1≤1.3*G2 based on the open cross-sectional area G2 of the inlet slot 715d described above. can be made to satisfy

The above condition is that the fluid inlet 711 is designed to be excessively small or excessively large compared to the inflow slot 715d. this can be

On the other hand, the amount of air (fluid) flowing in the implantation detection duct 710 may be changed according to the amount of implantation of the second evaporator 22 .

That is, as the amount of implantation of the second evaporator 22 is increased and the air flow passing through the second evaporator 22 is gradually blocked, the pressure difference between the air inlet side and the air outlet side of the second evaporator 22 gradually increases. , the amount of air sucked into the implantation detection duct 710 by this pressure difference gradually increases.

At the same time, as the amount of air sucked into the implantation detection duct 710 increases, the temperature of the heating element 731 constituting the implantation confirmation sensor 730, which will be described later, decreases, and the temperature difference value when the corresponding heating element 731 is turned on/off. (ΔHt) (hereinafter referred to as “logic temperature”) becomes small.

In consideration of this, it can be seen that the lower the logic temperature ΔHt inside the implantation detection duct 710 confirmed by the implantation confirmation sensor 730, the higher the amount of implantation of the second evaporator 22 is.

Referring to FIG. 23 , when there is no frost in the second evaporator 22 or the amount of implantation is remarkably small, most of the air passes through the second evaporator 22 in the heat exchange space. On the other hand, some of the air may flow into the implantation detection duct 710 .

For example, based on the state in which the second evaporator 22 is not implanted, approximately 98% of the air inhaled through the suction duct 42a passes through the second evaporator 22 and the remaining 2 % of air may be configured to pass through the implantation detection duct 710 .

At this time, the amount of air passing through the second evaporator 22 and the implantation detection duct 710 may be gradually changed according to the amount of implantation of the second evaporator 22 .

For example, when frost is formed on the second evaporator 22, the amount of air passing through the second evaporator 22 is reduced, while the amount of air passing through the implantation detection duct 710 is increased.

That is, the amount of air passing through the implantation detection duct 710 upon landing of the second evaporator 22 compared to the amount of air passing through the pre-implantation detection duct 710 of the second evaporator 22 is abruptly increased.

In particular, it may be preferable to configure the implantation detection duct 710 so that the change in the amount of air according to the amount of implantation of the second evaporator 22 can be at least twice or more. That is, in order to determine the amount of implantation using the amount of air, the amount of air must be generated at least twice or more to obtain a sensed value sufficient to have discriminating power.

Referring to FIG. 24 , when the amount of implantation of the second evaporator 22 is large enough to require a defrosting operation, since the frost of the second evaporator 22 acts as a flow resistance, the air flowing in the heat exchange space of the evaporator 22 is is decreased, and the amount of air flowing through the implantation detection duct 710 is increased.

As such, the flow rate of the air flowing through the implantation detection duct 710 varies according to the amount of implantation of the second evaporator 22 .

In addition, the implantation detection device 70 may include an implantation confirmation sensor 730 .

The implantation confirmation sensor 730 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 730 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 a defrost 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 730 .

In the embodiment of the present invention, it is assumed that the implantation confirmation sensor 730 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 FIG. 25 , while the implantation confirmation sensor 730 is provided at the portion where the fluid flows in the implantation detection duct 710 , the output value is changed according to the amount of fluid flow in the implantation detection duct 710 Based on the output value It is made so that 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.

26, the implantation confirmation sensor 730 may be configured to include a sensing derivative.

The sensing derivative may be a means for inducing the sensor (temperature sensor) 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, the sensing derivative includes a heating element 731 as an example.

The heating element 731 is a heating element that generates heat by receiving power.

26, the implantation confirmation sensor 730 may be configured to include a temperature sensor 732.

The temperature sensor 732 is a sensing element that measures the temperature around the heating element 731 .

That is, considering that the temperature around the heating element 731 changes according to the amount of air passing through the heating element 731 while passing through the implantation detection duct 710, the temperature sensor 732 measures this temperature change and then based on this temperature change The degree of implantation of the second evaporator 22 can be calculated.

26 , the implantation confirmation sensor 730 according to an embodiment of the present invention may be configured to include a sensor PCB 733 .

The sensor PCB 733 determines the difference between the temperature sensed by the temperature sensor 732 in the OFF state of the heating element and the temperature detected by the temperature sensor 732 in the ON state of the heating element 731 . done to be able to

Of course, the sensor PCB 733 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, and in this case, the heat generated according to the ON of the heating element 731 is generated by the flowing air. relatively small cooling.

Accordingly, the temperature sensed by the temperature sensor 732 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 increases, and in this case, the heat generated according to the ON of the heating element 731 is the flow air is cooled relatively much by

Accordingly, the temperature sensed by the temperature sensor 732 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.

On the other hand, the implantation confirmation sensor 730 is installed in a direction transverse to the direction in which air passes in the interior of the implantation detection duct 710 , and the surface of the implantation confirmation sensor 730 and the implantation detection duct 710 . The inner surfaces are spaced apart from each other.

That is, water can flow down through the spaced gap between the implantation confirmation sensor 730 and the implantation detection duct 710 .

In this case, it is preferable that the distance between the gaps is such that water does not accumulate between the surface of the implantation confirmation sensor 730 and the inner surface of the implantation detection duct 710 .

In addition, the heating element 731 and the temperature sensor 732 may be preferably made to be located together on any one surface of the implantation confirmation sensor (730).

That is, by locating the heating element 731 and the temperature sensor 732 on the same surface, the temperature sensor 732 can more accurately sense a temperature change according to the heat of the heating element 731 .

In addition, the implantation confirmation sensor 730 may be disposed between the fluid inlet 711 and the fluid outlet 712 of the implantation detection duct 710 in the interior of the implantation detection duct 710 .

Preferably, the fluid inlet 711 and the fluid outlet 712 may be disposed at a spaced apart position.

For example, the implantation confirmation sensor 730 may be disposed at an intermediate point in the implantation detection duct 710, and relatively close to the fluid inlet 711 compared to the fluid outlet 712 in the implantation detection duct 710. The implantation confirmation sensor 730 may be arranged, and the implantation confirmation sensor 730 may be arranged in a region relatively close to the fluid outlet 712 compared to the fluid inlet 711 in the implantation detection duct 710 .

In addition, the implantation confirmation sensor 730 may further include a sensor housing 734 .

The sensor housing 734 serves to prevent water flowing down through the implantation detection duct 710 from contacting the heating element, the temperature sensor 732 , or the sensor PCB 733 .

The sensor housing 734 may be formed so that at least one side of both ends is open. Accordingly, the power supply line (or signal line) can be drawn out from the sensor PCB 733 .

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 the respective temperature sensors 1a and 1b, and control the implantation confirmation sensor 730 or the implantation confirmation sensor 730 ) 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 supply 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 730 to operate at a predetermined period.

That is, under the control of the control unit 80, the heating element 731 of the implantation confirmation sensor 730 is heated for a predetermined time, and the temperature sensor 732 of the implantation confirmation sensor 730 is turned on. In addition to sensing the temperature immediately after being turned off, the temperature immediately after the heating element 731 is OFF is sensed.

Through this, the minimum temperature and the maximum temperature can be confirmed after the heating element 731 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 731 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 verification of the logic temperature ΔHt and the comparison with the first reference difference value may be configured to be performed by the sensor PCB 733 constituting the implantation confirmation sensor 730 .

In this case, the control unit 80 is configured to control the on/off of the heating element 731 by receiving the result of checking the logic temperature ΔHt and comparing it with the first reference difference value from the sensor PCB 733 . can be

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. 27 is a flowchart of a method of performing a defrosting operation by determining a defrost necessary 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.

28 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 passage 713 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 performing the implantation 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.

The implantation detection device 70 is configured to confirm the amount of implantation of the second evaporator 22 based on a temperature difference value (logic temperature) ΔHt according to a change in the flow rate of air passing through the implantation detection passage 713 .

In consideration of this, as the logic temperature ΔHt increases, the reliability of the detection result by the implantation detection device 70 can be secured, and the highest logic temperature ΔHt is only when the second cooling fan 41 is operated. can get

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.

The heating element 731 generates heat when power is supplied to the second cooling fan 41 , or immediately after power is supplied to the second cooling fan 41 , or power is supplied to the second cooling fan 41 . It can be controlled to generate heat when a certain condition is satisfied in the supplied state.

In the embodiment of the present invention, it is exemplified that the heating element 731 is controlled to generate heat when a predetermined heating condition is satisfied while 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 731 is checked ( S130 ), and the heating element 731 is 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 elapses after driving the second cooling fan 41, and the temperature (temperature sensor) in the implantation detection flow path 713 before driving the second cooling fan 41 At least one basic condition among 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 further included.

Then, when it is confirmed that the heating condition as described above is satisfied, the heating element 731 is heated by the control of the controller 80 (or the control of the sensor PCB) ( S140 ).

In addition, when the heating element 731 generates heat, the temperature sensor 732 detects a physical property value in the implantation detection passage 713 , that is, the temperature Ht1 ( S150 ).

The temperature sensor 732 may sense the temperature Ht1 simultaneously with the heating of the heating element 731 or may detect the temperature Ht1 immediately after the heating of the heating element 731 is performed.

In particular, the temperature Ht1 sensed by the temperature sensor 732 may be the lowest temperature in the implantation detection passage 713 that is checked after the heating element 731 is turned on.

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

And, the heating element 731 generates heat for a set heating time. In this case, the set heat generation time may be a time sufficient to have a discriminating power against a temperature change inside the implantation detection flow path 713 .

For example, it is desirable that the logic temperature ΔHt when the heating element 731 heats up during the set heating time can have discriminating power, even except for the logic temperature ΔHt caused by 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 731 is cut off and the heating may be stopped ( S160 ).

Of course, the power supply to the heating element 731 may be controlled to be cut off even though the heating time has not elapsed.

For example, when the temperature sensed by the temperature sensor 732 exceeds a set temperature value (eg, 70° C.), it may be controlled such that the power supply to the heating element 731 is cut off, and the door of the second storage chamber 13 is closed. When opened, the power supply to the heating element 731 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 731 is cut off.

When the second cooling fan 41 is turned off, the power supply to the heating element 731 may be controlled to be cut off.

When the heat generation of the heating element 731 is stopped in this way, a physical property value, that is, the temperature Ht2, in the implantation detection passage 713 by the temperature sensor 732 is sensed (S170).

In this case, the temperature sensing of the temperature sensor 732 may be performed at the same time as the heating of the heating element 731 is stopped, or may be performed immediately after the heating of the heating element 731 is stopped.

In particular, the temperature Ht2 sensed by the temperature sensor 732 may be the maximum temperature in the implantation detection flow path 713 checked before and after the heating element 731 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 (731) generates heat and the temperature (Ht2) at the end of heating of the heating element (731) (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 flow path 713 is small, so that the amount of implantation of the second evaporator 22 is such that the defrost operation is performed. 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 passage 713 is small. The logic temperature ΔHt is relatively high.

On the other hand, when the logic temperature (ΔHt) is lower than the preset second reference difference value, the air flow rate in the implantation detection flow path 713 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.

On the other hand, if the protrusion length (Li) of the fluid inlet compared to the slot length (Ls) of the inlet slot is configured to satisfy the condition of 0.4≤Ls/Li≤0.8, the temperature for the two distance ratio before and after the heating element constituting the implantation confirmation sensor heats up The amount of change can be obtained additionally by ±6°C or more, which makes it possible to obtain a logic temperature (ΔHt) up to approximately 36°C.

Accordingly, it is not only possible to more accurately determine whether the logic temperature reaches the first reference difference value and the second reference difference value, but it is difficult to confirm with the first reference difference value and the second reference difference value It is possible to classify more diverse information.

For example, each of the reference difference values can be distinguished not only from the above-described first reference difference value and the second reference difference value, but a reference difference value for recognizing whether a blockage implantation is present, and a reference difference value for recognizing whether an initial implantation is present At least one of a reference difference value, a reference difference value capable of recognizing whether there is residual ice after a defrost operation, a reference difference value capable of recognizing the internal blockage of the implantation detection flow path 713, and a reference difference value capable of recognizing sensor icing It is possible to classify by the reference difference value.

That is, through the design of the protrusion length (Li) of the fluid inlet part 715 compared to the slot length (Ls) of the optimal inflow slot (715d) in consideration of the reverse inflow of the fluid backflowing at the time of implantation, the amount of additional temperature change of 6°C or more can be obtained, so it becomes possible to judge more various information such as clogging the flow path or checking the initial temperature after defrosting.

In particular, the period for performing the implantation detection operation according to the classification of each reference difference value and the maximum amount of temperature change may be made variably.

For example, when the logic temperature is confirmed to be within 28°C to 30°C, the cycle may be set so that the implantation detection operation is omitted once or two or more times instead of every cycle.

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 731 is turned off, a defrosting operation may be performed according to the determination of the controller 80 .

When such a 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 731 constituting the implantation confirmation sensor 730 may be controlled to generate heat together.

That is, considering that water generated due to frost melting can also flow down into the implantation detection flow path 713 during the defrosting operation, the heating element 731 prevents the flowing water from freezing in the implantation detection flow path 713. ) 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 compartment is in a state in which the door of one storage chamber 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 defrosting 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 defrosting 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 temperature sensor 732 is faulty, or checking the blockage of the implantation detection flow path 713 can be checked.

For example, if the logic temperature confirmed during the first implantation detection operation immediately after the defrost operation is 14 ° C or less, it can be determined as freezing of the temperature sensor 732 , and when the logic temperature is confirmed to be 37 ° C or higher, the implantation detection flow path 713 . 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 flow resistance is provided at the portion where the fluid flows in the implantation detection duct 710, the amount of fluid flowing into the implantation detection duct 710 is minimized even when the implantation is insignificant, and in the state where the implantation is made, the Despite the flow resistance, the fluid can flow smoothly due to the pressure difference between the fluid inlet 715 and the fluid outlet 712 .

In particular, in the refrigerator 1 of the present invention, the protrusion length Li of the fluid inlet 715 compared to the slot length Ls of the inlet slot 715d of the implantation detection duct 710 is 0.2≤Ls/Li≤1.0. It is designed to be satisfactory. Accordingly, it is possible to further increase the logic temperature for implantation detection compared to a case where only the vertical opening distance of the inflow slot 715d is changed or only the vertical protrusion length of the fluid inlet part 715 is changed.

In addition, in the refrigerator of the present invention, since the logic temperature can obtain a value in a larger temperature range than the reference temperature difference value used for conventional implantation determination, not only the role of simple implantation detection, but also more diverse causes related to implantation are additionally distinguished have the ability to discriminate.

In addition, in the refrigerator of the present invention, the open cross-sectional area G1 of the fluid inlet 711 can satisfy the condition of 0.8*G2≤G1≤1.3*G2 based on the open cross-sectional area G2 of the inlet slot 715d. is designed to be Accordingly, it is possible to reduce the phenomenon that the fluid inlet is designed to be excessively small or excessively large compared to the inlet slot 715d, thereby reducing the discrimination force.

1. Refrigerator 1a. first temperature sensor
1b. 2nd temperature sensor 11. Case
11a. inner case 11b. out case
12, 13. First storage room 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
43. Shroud 43a. fluid inlet
50. Defrost 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. Implantation detection flow path 714. Euro cover
715. Fluid inlet 715a. front side wall
715b. rear wall 715c. side wall
715d. Inflow slot 730. Implantation confirmation sensor
731. Heating element 732. Temperature sensor
733. Sensor PCB 734. Sensor housing
80. Controls

Claims (28)

a case providing a storage room;
a cold air heat source for generating cold air supplied to the storage chamber;
a first duct disposed between the storage chamber and the cold air heat source while guiding the fluid inside the storage chamber to move to the cold air heat source;
a second duct disposed between the cold air heat source and the storage chamber while guiding the fluid around the cold air heat source to be moved to 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 through which the fluid is moved and an implantation confirmation sensor disposed in the implantation detection duct to measure the physical properties of the fluid passing through the implantation detection duct,
The implantation detection duct is provided with a fluid inlet into which the fluid flows,
The fluid inlet is configured to protrude from the boundary of the first duct toward the movement path of the fluid provided by the first duct to generate flow resistance,
An open fluid inlet is formed on one wall surface of the fluid inlet to allow a portion of the fluid flowing through the storage chamber to flow into the cold air heat source, and one of the wall surfaces of the fluid inlet portion facing the portion provided with the cold air heat source is from the cold air heat source. An open inlet slot is formed to receive the cold air flowing backward,
The slot length (Ls) of the inlet slot is proportional to the protrusion length (Li) of the fluid inlet part.
A refrigerator, characterized in that it satisfies the condition of 0.2*Li≤Ls≤1.0*Li. The method of claim 1,
The refrigerator, characterized in that at least a part of the implantation detection duct is disposed in a flow path formed between the first duct and the cold air heat source. The method of claim 1,
The refrigerator, characterized in that at least a part of the implantation detection duct is disposed in a flow path formed between the second duct and the storage compartment. 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 sensor and a detection derivative. 6. The method of claim 5,
The refrigerator according to claim 1, wherein the sensing derivative is a means for inducing the sensor to improve the accuracy of measuring physical properties. 6. The method of claim 5,
Refrigerator, characterized in that the sensing derivative includes a heating element that generates heat. The method of claim 1,
The cold air heat source comprises at least one of a thermoelectric module and an evaporator. 9. The method of claim 8,
wherein the thermoelectric module includes a thermoelectric element including a heat absorbing surface and a heat generating surface, and a sink connected to at least one of the heat absorbing surface and the heat generating surface. 9. The method of claim 8,
The cold air heat source comprises an evaporator and a refrigerant valve for controlling the amount of refrigerant supplied to the evaporator. 9. The method of claim 8,
The cold air heat source comprises a compressor for compressing the refrigerant supplied to the evaporator. 9. The method of claim 8,
The cold air heat source comprises a cooling fan operated to circulate the fluid around the evaporator to the storage chamber. The method of claim 1,
The slot length (Ls) of the inlet slot is proportional to the protrusion length (Li) of the fluid inlet part.
A refrigerator, characterized in that it satisfies the condition of 0.2*Li≤Ls≤0.8*Li. The method of claim 1,
The slot length (Ls) of the inlet slot is proportional to the protrusion length (Li) of the fluid inlet part.
A refrigerator, characterized in that it satisfies the condition of 0.2*Li≤Ls≤0.6*Li. The method of claim 1,
The slot length (Ls) of the inlet slot is proportional to the protrusion length (Li) of the fluid inlet part.
A refrigerator, characterized in that it satisfies the condition of 0.4*Li≤Ls≤1.0*Li. The method of claim 1,
The slot length (Ls) of the inlet slot is proportional to the protrusion length (Li) of the fluid inlet part.
A refrigerator, characterized in that it satisfies the condition of 0.4*Li≤Ls≤0.8*Li. The method of claim 1,
The slot length (Ls) of the inlet slot is proportional to the protrusion length (Li) of the fluid inlet part.
A refrigerator, characterized in that it satisfies the condition of 0.6*Li≤Ls≤1.0*Li. The method of claim 1,
The slot length (Ls) of the inlet slot is proportional to the protrusion length (Li) of the fluid inlet part.
A refrigerator, characterized in that it satisfies the condition of 0.6*Li≤Ls≤0.8*Li. The method of claim 1,
The open cross-sectional area (G1) of the fluid inlet is when viewed based on the open cross-sectional area (G2) of the inlet slot
A refrigerator, characterized in that it satisfies the condition of 0.8*G2≤G1≤1.3*G2. a case providing a storage room;
a cold air heat source for generating cold air supplied to the storage chamber;
a first duct disposed between the storage chamber and the cold air heat source while guiding the fluid inside the storage chamber to move to the cold air heat source;
a second duct disposed between the cold air heat source and the storage chamber while guiding the fluid around the cold air heat source to be moved to 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 through which the fluid is moved and an implantation confirmation sensor disposed in the implantation detection duct to measure the physical properties of the fluid passing through the implantation detection duct,
The implantation detection duct is provided with a fluid inlet into which the fluid flows,
An open fluid inlet is formed on one wall of the fluid inlet part so that a part of the fluid flowing through the storage chamber to the cold air heat source is introduced,
After frost or ice is formed in the cold air heat source, an inlet slot that is opened to guide the fluid around the cold air heat source to flow into the implantation detection duct is formed between the fluid inlet of the impaction detection duct and the cold air heat source Features a refrigerator. 21. The method of claim 20,
The inlet slot is a refrigerator, characterized in that formed in the fluid inlet portion of the implantation detection duct. 21. The method of claim 20,
The cold air heat source includes an evaporator located at the rear in the storage room,
The implantation detection duct is a refrigerator, characterized in that disposed in front of the evaporator. 23. The method of claim 22,
Refrigerator, characterized in that the fluid inlet portion of the implantation detection duct is disposed lower than the lower end of the evaporator. 23. The method of claim 22,
A flow resistance body is provided at the fluid inlet portion of the implantation detection duct so that the flow rate of the fluid flowing into the cold air heat source is greater than the flow rate of the fluid flowing into the implantation detection duct. a case providing a storage room;
a cold air heat source for generating cold air supplied to the storage chamber;
a first duct disposed between the storage chamber and the cold air heat source while guiding the fluid inside the storage chamber to move to the cold air heat source;
a second duct disposed between the cold air heat source and the storage chamber while guiding the fluid around the cold air heat source to be moved to 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 through which the fluid is moved and an implantation confirmation sensor disposed in the implantation detection duct to measure the physical properties of the fluid passing through the implantation detection duct,
The implantation detection duct is provided with a fluid inlet into which the fluid flows,
On the flow path through which the fluid moves from the storage chamber to the cold air heat source, the fluid inlet of the implantation detection duct is disposed in front of the cold air heat source,
An inflow slot is formed between the cold air heat source and the fluid inlet of the implantation detection duct so that the flow rate per unit time of the fluid flowing into the cold air heat source can be greater than the flow rate per unit time of the fluid flowing into the implantation detection duct refrigerator to do. 26. The method of claim 25,
The inlet slot is a refrigerator, characterized in that formed in the fluid inlet portion of the implantation detection duct. 26. The method of claim 25,
The cold air heat source includes an evaporator located at the rear in the storage room,
The implantation detection duct is a refrigerator, characterized in that disposed in front of the evaporator. 28. The method of claim 27,
Refrigerator, characterized in that the fluid inlet portion of the implantation detection duct is disposed lower than the lower end of the evaporator.

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