KR20230022631A - Refrigerator incorporated with air conditioner and a system for discharging air including the same - Google Patents

Abstract

The present invention relates to a refrigerator integrated with an air conditioner, and an exhaust system having the same. According to one aspect of the present invention, a refrigerator having a refrigerator evaporator for cooling a storage chamber and an air conditioner having an air conditioner evaporator and a discharge unit for cooling an indoor space can be integrally formed in the refrigerator integrated with an air conditioner. The refrigerator integrated with an air conditioner comprises: a refrigerator main body having the storage chamber; and a housing provided on one side of the refrigerator main body and having a suction unit sucking air and the discharge unit.

Description

Refrigerator incorporated with air conditioner and a system for discharging air including the same}

The present invention relates to an air conditioner-integrated refrigerator and an exhaust system including the same.

In general, a refrigerator is a home appliance that stores food at a low temperature in an internal storage space shielded by a door, and cools the inside of the storage space using cold air generated through heat exchange with a refrigerant circulating in a refrigerating cycle. It is configured so that food can be stored in an optimal condition.

An air conditioner is a home appliance for maintaining indoor air in the most suitable state according to use and purpose. For example, the indoor air is adjusted to a cool cooling state in summer, a warm heating state in winter, and also the indoor humidity is controlled and the indoor air is adjusted to a pleasant clean state.

The refrigerator and air conditioner are similar in that they cool or heat air by driving a refrigeration cycle. The refrigeration cycle may be configured to perform compression, condensation, expansion, and evaporation of the refrigerant.

An integral product that drives a refrigerator and an air conditioner by driving one refrigerating cycle can be proposed.

Prior literature information related to the prior art is as follows.

Patent Publication No. 1999-0054805 (July 15, 1999), Refrigerator with Air Conditioning Function

An object of the present invention is to provide an air conditioner-integrated refrigerator capable of driving a refrigerator and an air conditioner by driving one refrigerating cycle.

An object of the present invention is to provide an air conditioner integrated refrigerator capable of realizing a compact product by integrally configuring a refrigerator and an air conditioner into a single body.

An object of the present invention is to provide an air conditioner-integrated refrigerator capable of preventing a pressure drop of a refrigerant and improving efficiency by reducing a pipe length of a refrigerant circulating between a refrigerator and an air conditioner.

The present invention provides an air conditioner-integrated refrigerator having an evaporator for driving a refrigerator and an evaporator for driving an air conditioner, and using an expansion valve to distribute a necessary amount of refrigerant to each evaporator. The purpose.

The present invention is an air conditioner integrated refrigerator having one integrated condenser and a plurality of evaporators so that a refrigerator and an air conditioner having different cooling loads can be simultaneously driven, and can easily control the pressure of refrigerant flowing into each evaporator. It aims to provide

An object of the present invention is to provide an air conditioner-integrated refrigerator in which a cooling passage and a heat dissipation passage can be easily formed by compactly disposing cycle parts inside the housing of the air conditioner.

The present invention provides an air conditioner-integrated refrigerator that uses a condenser with a large heat dissipation capacity so that the refrigerator and the air conditioner can be driven together, so that heat generated in the integrated refrigerator can be easily discharged to the outside of the indoor space. aims to

An object of the present invention is to provide an air conditioner-integrated refrigerator equipped with an additional water-cooled condenser to drive an air conditioner with a larger load than a refrigerator and capable of easily discharging heat generated from the water-cooled condenser from an indoor space. to be

In an embodiment of the present invention, a refrigerator main body in which a storage compartment for storing goods is formed, and a housing forming a cooling passage and a heat dissipation passage are integrally configured to realize a compact product.

In an embodiment of the present invention, since a refrigerator and an air conditioner can be driven together by driving one refrigerating cycle, the number of refrigerating cycle parts can be reduced and the weight of the product can be reduced accordingly.

An embodiment of the present invention uses one condenser as a common condenser for the operation of a refrigerator and an air conditioner, and uses an expansion valve to transfer the refrigerant condensed in the condenser to a plurality of condensers corresponding to the load of the refrigerator and the air conditioner. Since it can be distributed and introduced into the evaporator, it is easy to respond to the load.

In the embodiment of the present invention, since the housing of the air conditioner is installed on the upper side of the refrigerator, and the heat dissipation flow path passing through the condenser and the cooling flow path passing through the evaporator can be partitioned from each other in the housing, the flow path for driving the product is easy to form.

In an embodiment of the present invention, the condensing fan and the evaporating fan for discharging air in combination are configured as one fan assembly, so that the space for component installation in the housing can be compacted.

In the embodiment of the present invention, since the expansion valves provided at the inlet side of the plurality of evaporators are composed of electronic expansion valves capable of adjusting the opening, the amount of refrigerant flowing into each evaporator can be easily adjusted according to the load of the refrigerator and the air conditioner. there is.

In the embodiment of the present invention, since the air conditioner is provided on the upper side of the refrigerator, the air discharged from the air conditioner can be easily discharged toward the lower part of the indoor space from a relatively high place.

In an embodiment of the present invention, heat generated inside the housing of the air conditioner can be easily discharged to the outside of the indoor space by extending the heat radiation duct from the integrated refrigerator.

According to an embodiment of the present invention, since an integrated refrigerator installed in a kitchen includes a heat radiation duct connecting the kitchen exhaust system and the integrated refrigerator, heat dissipation performance is improved and the temperature of the indoor space can be prevented from rising to an unpleasant level. there is.

An embodiment of the present invention has an advantage in that since the heat radiation duct extending from the integrated refrigerator is connected to a ventilation facility, heat generated by driving the integrated refrigerator can be directly discharged to the outside of the indoor space.

In an embodiment of the present invention, in response to the load that increases as a refrigerator and an air conditioner are driven together, an air-cooled condenser and a water-cooled condenser are used together and a pipe for directly discharging heat generated from the condensers to the outside of the indoor space is provided. may be provided.

In one aspect of the present invention, an air conditioner-integrated refrigerator may include a refrigerator having a refrigerator evaporator for cooling a storage compartment and an air conditioner having an air conditioner evaporator and a discharge unit for cooling an indoor space.

The integrated refrigerator includes a refrigerator body forming the storage compartment; It is provided on one side of the refrigerator body and may include a suction part for sucking in air and a housing forming the discharge part.

The all-in-one refrigerator includes an air-cooled condenser provided inside the housing and exchanging heat with some of the air sucked in through the suction part; and the air conditioning evaporator provided inside the housing and exchanging heat with the rest of the air sucked in through the suction part.

The discharge unit may include a heat discharge unit through which air exchanged with the air-cooled condenser is discharged, and a cooling discharge unit through which air exchanged with the air conditioning evaporator is discharged.

A heat dissipation duct extending to the outside of the heat dissipation unit may be further included to prevent air discharged from the heat dissipation unit from flowing into an indoor space.

The housing includes a partition wall dividing the inner space of the housing into a plurality of installation spaces, and the partition wall includes a first partition wall defining a first installation space for installing the compressor and a second partition wall for installing the air-cooled condenser. A second partition wall defining an installation space may be included.

The heat radiation outlet may be formed in the second installation space.

The housing may be disposed on an upper side of the refrigerator body, and the housing may include a rear portion forming the heat dissipating portion and a front portion forming the cooling discharge portion.

The partition wall may include a third partition wall defining a third installation space for installing the air conditioning evaporator, and the third partition wall may partition a fourth installation space in which a fan assembly is installed and the third installation space. .

The fan assembly may include a condensation fan for sending air to the air-cooled condenser; and an air conditioner fan for sending air to the air conditioner evaporator.

The condensing fan includes a first fan discharge unit for discharging air from the fourth installation space to the second installation space, and the air conditioner fan discharges air from the fourth installation space to the third installation space. A second fan discharge unit may be included.

The first fan discharge part may be coupled to the second partition wall, and the second fan discharge part may be coupled to the third partition wall.

The barrier rib may include a fourth barrier rib defining a fifth installation space for installation of electrical components, and the fifth installation space may be partitioned from the first and second installation spaces by the fourth barrier rib.

a water-cooled condenser provided inside the housing; an intake pipe connected to the water-cooled condenser and supplying water to the water-cooled condenser; and a water outlet pipe connected to the water-cooled condenser and discharging water heat-exchanged in the water-cooled condenser.

At least one of the intake pipe and the water outlet pipe may pass through the housing and extend to the outside of the housing.

In another aspect of the present invention, an exhaust system including an air conditioner integrated refrigerator includes a refrigerator having a refrigerator evaporator for cooling a storage compartment, an air conditioner having an air conditioner evaporator and a discharge unit for cooling an indoor space, and an air conditioner integrally can be formed

The exhaust system includes a housing provided on one side of the refrigerator body and forming a suction part for sucking in air and the discharge part; It is provided inside the housing and may include an air-cooled condenser that exchanges heat with some of the air sucked through the suction part.

The exhaust system includes a heat dissipation discharge unit through which air heat-exchanged with the air-cooled condenser is discharged; a heat radiation duct coupled to the heat radiation outlet; and an exhaust device connected to the heat radiation duct and discharging the air discharged from the heat discharge unit to the outside of the indoor space.

The exhaust device may include at least one of an exhaust hood for discharging contaminated air from the cooking appliance and a window for ventilation.

The exhaust system may further include a heat radiating fan provided in the heat radiating duct and forcing air to be discharged.

The exhaust system includes an intake pipe for supplying water into the housing; A water-cooled condenser connected to the water intake pipe; and a water outlet pipe connected to the water-cooled condenser and discharging water heat-exchanged in the water-cooled condenser to the outside of the housing.

The exhaust system includes an air conditioning evaporator provided inside the housing; and a cooling discharge unit formed in the housing and configured to discharge air heat-exchanged with the air conditioning evaporator into the indoor space.

The exhaust system may further include a fan assembly disposed between the air-cooled condenser and the air-conditioning evaporator.

In the exhaust system, the fan assembly may include a condensation fan having a first fan discharge part directed to the air-cooled condenser and an air conditioner fan having a second fan discharge part directed to the air conditioning evaporator.

According to the present invention, a refrigerator and an air conditioner can be efficiently operated by driving one refrigerating cycle.

According to the present invention, a compact product can be realized by integrally configuring a refrigerator and an air conditioner as one body.

According to the present invention, the pressure drop of the refrigerant can be prevented and efficiency can be improved by reducing the pipe length of the refrigerant circulating between the refrigerator and the air conditioner.

According to the present invention, an evaporator for driving a refrigerator and an evaporator for driving an air conditioner are provided, and a required amount of refrigerant can be easily distributed to each evaporator by using an expansion valve.

According to the present invention, one integrated condenser and a plurality of evaporators are provided so that a refrigerator and an air conditioner having different cooling loads can be simultaneously driven, and the pressure of the refrigerant flowing into each evaporator can be easily controlled.

According to the present invention, it is possible to easily form a cooling passage and a heat dissipation passage by compactly disposing cycle parts inside the housing of the air conditioner.

According to the present invention, by using a condenser having a large heat dissipation capacity so as to drive both the refrigerator and the air conditioner, heat generated in the integrated refrigerator can be easily discharged to the outside of the indoor space.

According to the present invention, an additional water-cooled condenser is provided to drive an air conditioner having a higher load than a refrigerator, and heat generated in the water-cooled condenser can be easily discharged from the indoor space.

1 is a view showing configurations of an air conditioner-integrated refrigerator and an exhaust system according to a first embodiment of the present invention.
2 is a perspective view showing the configuration of a refrigerator integrated with an air conditioner according to a first embodiment of the present invention.
3 is an exploded perspective view showing the configuration of a refrigerator integrated with an air conditioner according to a first embodiment of the present invention.
4 is a view showing the internal structure of the housing of the air conditioner according to the first embodiment of the present invention.
5 is a view showing the rear configuration of the air conditioner-integrated refrigerator according to the first embodiment of the present invention.
6 is a cross-sectional view taken along 6-6' of FIG. 1;
7 is a cycle diagram showing the configuration of a refrigerator integrated with an air conditioner according to a first embodiment of the present invention.
8 is a view showing configurations of an air conditioner-integrated refrigerator and an exhaust system according to a second embodiment of the present invention.
9 is a view showing configurations of an air conditioner-integrated refrigerator and an exhaust system according to a third embodiment of the present invention.
10 is a perspective view showing the configuration of a refrigerator integrated with an air conditioner according to a third embodiment of the present invention.
11 is an exploded perspective view showing the configuration of a refrigerator integrated with an air conditioner according to a third embodiment of the present invention.
12 is a view showing the configuration of a rear surface of a refrigerator integrated with an air conditioner according to a third embodiment of the present invention.
13 is a cycle diagram showing the configuration of a refrigerator integrated with an air conditioner according to a third embodiment of the present invention.
14 is a view showing the configuration of a water-cooled condenser according to a third embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to components in the drawings, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings.

In addition, in describing an embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function hinders understanding of the embodiment of the present invention, the detailed description will be omitted.

Also, terms such as first, second, A, B, (a), and (b) may be used to describe components of an embodiment of the present invention. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term.

When an element is described as being “connected,” “coupled to,” or “connected” to another element, that element may be directly connected or connected to the other element, but there may be another element between the elements. It should be understood that may be "connected", "coupled" or "connected".

1 is a view showing the configuration of an air conditioner integrated refrigerator and an exhaust system according to a first embodiment of the present invention, and FIG. 2 is a perspective view showing the configuration of an air conditioner integrated refrigerator according to a first embodiment of the present invention. 3 is an exploded perspective view showing the configuration of an air conditioner-integrated refrigerator according to the first embodiment of the present invention, and FIG. 4 is a view showing the internal configuration of the housing of the air conditioner according to the first embodiment of the present invention, FIG. 5 is a view showing the rear configuration of the air conditioner-integrated refrigerator according to the first embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along 6-6' of FIG. 1. Referring to FIG.

1 to 6, an air conditioner integrated refrigerator (10, hereinafter referred to as "integrated refrigerator") according to an embodiment of the present invention includes a refrigerator 100 forming a storage compartment for storing goods and the integrated refrigerator (10) may include an air conditioner 200 that discharges air for conditioning of an indoor space in which it is installed.

The integrated refrigerator 10 generally stores food and may be disposed adjacent to a kitchen where food is used.

For example, the integrated refrigerator 10 may be provided as a built-in type in kitchen furniture (apparatus) or general furniture.

The kitchen is provided adjacent to the sink (S) where the cooking device (C) is installed, and the cooking device (C), and an exhaust hood (H) for discharging smoke generated in the cooking process of food and storing food containers, etc. A cupboard (B) may be provided.

The exhaust hood H may be understood as a component of an exhaust device for discharging air from the indoor space to the outside of the indoor space.

The refrigerator 100 and the air conditioner 200 may be integrally configured. For example, the refrigerator 100 and the air conditioner 200 may be provided in one body.

As another example, the refrigerator 100 and the air conditioner 200 may be manufactured separately and coupled to each other.

The refrigerator 100 and the air conditioner 200 may be arranged in a vertical direction. For example, as shown in FIG. 1 , the air conditioner 200 may be provided above the refrigerator 100 . In this case, the cooling outlet 220 provided in the air conditioner 200 is formed at a relatively high position in the indoor space, and the air discharged from the cooling outlet 220 is directed toward the lower part of the indoor space. can be fluid.

Unlike what is shown in the drawings, the air conditioner 200 may be disposed above the refrigerator 100.

The refrigerator 100 may include a refrigerator body 110 forming storage chambers 101 and 105 for storing goods. The storage compartments 101 and 105 include first and second storage compartments, and the first and second storage compartments may constitute a refrigerating compartment 101 and a freezing compartment 105, respectively.

The refrigerating compartment 101 may be formed above the freezing compartment 105 . However, unlike this, the refrigerating compartment 101 may be formed below the freezing compartment 105, or the refrigerating compartment 101 and the freezing compartment 105 may be disposed left and right.

The refrigerator body 110 may include a barrier 106 partitioning the refrigerating compartment 101 and the freezing compartment 105 . The barrier 106 may include a heat insulating material for insulatingly separating the refrigerating compartment 101 and the freezing compartment 105 .

The refrigerator body 110 may include a shelf 141 for storing items. The shelves 141 may be provided in the refrigerating compartment 101 and the freezing compartment 105, respectively.

The refrigerator body 110 may include refrigerator evaporators 330 and 340 that generate cold air to be supplied to the storage compartments 101 and 105 . The refrigerator evaporators 330 and 340 may include a first evaporator 330 generating cold air to be supplied to the refrigerating compartment 101 and a second evaporator 340 generating cold air to be supplied to the freezing compartment 105.

The refrigerator evaporators 330 and 340 may be installed on the rear wall of the refrigerator body 110 . For example, the first evaporator 330 may be installed on the rear wall of the refrigerating compartment 101 and the second evaporator 340 may be installed on the rear wall of the freezing compartment 105 .

The refrigerator main body 110 may include evaporation fans 335 and 345 for supplying cold air generated by the refrigerator evaporators 330 and 340 to the storage compartments 101 and 105 . The evaporation fans 335 and 345 may be referred to as "refrigerator fans".

The evaporation fans 335 and 345 may include a first evaporation fan 335 provided at a downstream side of the first evaporator 330 to generate circulation of cold air to be supplied to the refrigerating compartment 101 . For example, the first evaporator fan 335 is provided on the rear wall of the refrigerating compartment 101 and may be installed above the first evaporator 330 .

The evaporation fans 335 and 345 may include a second evaporation fan 345 that is provided downstream of the second evaporator 340 and generates circulation of cold air to be supplied to the freezing compartment 105 . For example, the second evaporation fan 345 is provided on the rear wall of the freezing chamber 105 and may be installed above the second evaporator 340 .

The refrigerator 100 may include doors 121 and 125 for opening and closing the storage compartments 101 and 105 . For example, the doors 121 and 125 may be rotatably provided on the refrigerator body 110 .

However, unlike this, the doors 121 and 125 may be configured as a drawer type that slides and withdraws forward.

The doors 121 and 125 may include a refrigerating compartment door 121 for opening and closing the refrigerating compartment 101 and a freezing compartment door 125 for opening and closing the freezing compartment 105 .

The doors 121 and 125 may include a door basket 145 for storing articles. The door basket 145 may be provided to the refrigerating compartment door 121 and the freezing compartment door 125, respectively.

The air conditioner 200 may include a housing 210 . The housing 210 may form an inner space for installing parts of a refrigerating cycle, and may form a suction part and a discharge part for guiding suction and discharge of air.

For example, the housing 210 may have a polyhedral shape with an empty inside.

The housing 210 may be provided above the refrigerator 100, for example. For example, the housing 210 may be configured to be seated on the upper surface portion 115 of the refrigerator body 110 .

A depression 210a may be formed in the front portion of the lower surface of the housing 210 .

The recessed portion 210a may be configured to avoid interference between the housing 210 and the door hinge H protruding from the upper surface of the refrigerator 100 . The recessed portion 210a may be recessed upward from the lower surface of the housing 210 .

An installation space for installing parts of a refrigeration cycle may be formed inside the housing 210 . For example, parts of the refrigerating cycle may include a compressor 310, a condenser 320, a third expansion valve 363, and a third evaporator 350.

The third evaporator 350 may be understood as an "air conditioning evaporator" for cooling an indoor space.

The parts of the refrigerating cycle may further include a refrigerant pipe 300a connecting the compressor 310, the condenser 320, and the third evaporator 350 to allow flow of the refrigerant.

Components of the refrigerating cycle may further include a fan assembly 300b for forming an air flow path. The fan assembly 300b may be disposed between the third evaporator 350 and the condenser 320 .

For example, the third evaporator 350 may be disposed at the front of the housing 210 to discharge conditioned air toward the front of the integrated refrigerator.

The condenser 320 may be disposed on the opposite side of the third evaporator 350, that is, at the rear of the housing 210. Also, the fan assembly 300b may be installed at a point between the condenser 320 and the third evaporator 350, that is, approximately at the center of the housing 210.

The fan assembly 300b includes a condensation fan 325 for forming an air passage passing through the condenser 320 and a third evaporation fan 355 for forming an air passage passing through the third evaporator 350. can include

The condenser 320 may be referred to as an “air-cooled condenser” in that it exchanges heat with air.

The third evaporation fan 355 may be referred to as an "air conditioner fan".

The integrated refrigerator 10 may include a first motor 300d1 driving the condensation fan 325 and a second motor 300d2 driving the third evaporation fan 355 . For example, the first and second motors 300d1 and 300d2 may be provided between the condensation fan 325 and the third evaporation fan 355 .

A shaft of the first motor 300d1 may extend in one direction from the first motor 300d1 toward the condensation fan 325 and be connected to the condensation fan 325 .

A shaft of the second motor 300d2 may extend in another direction from the second motor 300d2 toward the third evaporation fan 355 and be connected to the third evaporation fan 355 .

The one direction and the other direction may be opposite to each other.

The condensing fan 325 may include a centrifugal fan that sucks in air in an axial direction and discharges it in a circumferential direction. For example, the condensation fan 325 may include a multi-blade fan (also referred to as a multiblade fan or a sirocco fan).

The condensation fan 325 may include a first fan discharge part 325a for discharging air in the circumferential direction of the plurality of blades. The first fan discharge part 325a may face the condenser 320 to send air to the condenser 320 .

For example, the first fan discharge part 325a may be connected to the second partition wall 216b.

The third evaporation fan 355 may include a centrifugal fan that sucks in air in an axial direction and discharges it in a circumferential direction. For example, the third evaporation fan 355 may include a multi-blade fan.

The third evaporation fan 355 may include a second fan discharge part 355a for discharging air in the circumferential direction of the plurality of blades. The second fan discharge part 355a may face the third evaporator 355 to send air to the third evaporator 355 .

For example, the second fan discharge part 355a may be connected to the third partition wall 216c.

Another embodiment is proposed.

In the above embodiment, it has been described that the condensation fan 325 and the third evaporation fan 355 are connected to the first and second motors, respectively, but unlike this, two shafts extend on both sides of one motor, and the two shafts may be connected to the condensation fan 325 and the third evaporation fan 355, respectively.

In this case, the condensation fan 325 and the third evaporation fan 355 may be driven together by driving one motor.

The housing 210 may form a suction part 231 for sucking air into the housing 210 . For example, the suction part 231 may be formed on an upper surface of the housing 210 .

A suction grill 232 may be provided in the suction part 231 to prevent foreign substances from being sucked in.

The housing 210 may form discharge parts 218 and 220 through which air heat-exchanged with the condenser 320 and the third evaporator 350 is discharged. The discharge units 218 and 220 may form a plurality of discharge units through which air having different temperatures is discharged.

In detail, the discharge parts 218 and 220 may include a heat discharge discharge part 218 through which air heat-exchanged with the condenser 320 is discharged.

For example, the heat dissipation outlet 218 may be formed on the rear side of the housing 210 so that air discharged through the heat dissipation outlet 218 does not directly reach a user.

The heat radiation outlet 218 may be connected to the heat radiation duct 90 . The heat dissipation duct 90 may be attached to or embedded in a wall surface of an indoor space, or may be attached to a wall surface of a cupboard or furniture provided in an indoor space.

For example, the heat dissipation duct 90 may be configured to be buried inside the cupboard B so as not to be exposed to the outside. In detail, the heat dissipation duct 90 extends laterally from the rear surface of the housing 210 and may pass through the inside of the cupboard B.

The heat dissipation duct 90 is finally connected to the exhaust hood H provided in the kitchen and can be flexibly connected to the outside of the indoor space.

The exhaust hood (H) may be configured such that a lower end thereof is opened so that contaminated gas generated from the cooking appliance (C) can be sucked in.

The heat dissipation duct 90 may be connected to a side surface of the exhaust hood H. The inner space of the heat dissipation duct 90 is fluidly connected to the inner space of the exhaust hood H, and exhaust can be performed by driving an exhaust fan provided in the exhaust hood H.

An additional heat dissipation fan 70 may be further provided inside the heat dissipation duct 90 . In particular, when the length of the heat radiation duct 90 is more than several meters, exhaust performance may be weakened.

Therefore, by installing the heat dissipation fan 70 in the heat dissipation duct 90, air can be easily discharged from the housing 210, and thus heat can be sufficiently dissipated.

As such, since the heat dissipation duct 90 is configured to connect the heat discharge outlet 218 and the exhaust hood H, the air discharged through the heat discharge outlet 218 is directed to the heat dissipation duct 90 and It can be discharged to the outside of the indoor space through the exhaust hood (H).

The discharge parts 218 and 220 may include a cooling discharge part 220 through which air heat-exchanged with the third evaporator 350 is discharged.

For example, the cooling outlet 220 may be formed on the front side of the housing 210 so that the air discharged through the cooling outlet 220 flows toward the front of the integrated refrigerator and is easily delivered to the user. there is.

The cooling discharge unit 220 may be provided with a discharge vane 221 capable of opening or closing the cooling discharge unit 220 . The discharge vane 221 may be movably provided. For example, the discharge vane 221 may rotate in a vertical direction.

When the discharge vane 221 moves while the cooling discharge part 220 is open, the flow direction of the air discharged from the cooling discharge part 220 may be changed.

When the third evaporation fan 355 is turned off, the discharge vane 221 may be closed. Of course, even if the third evaporation fan 355 is driven, air may not be discharged through the cooling discharge unit 220 when the discharge vane 221 is closed.

Inside the housing 210, partition walls 216a, 216b, 216c, and 216d partitioning a plurality of installation spaces for installing parts of a refrigeration cycle may be provided.

The plurality of installation spaces may include a first installation space 211 for installing the compressor 310 . The first installation space 211 may be partitioned from other installation spaces by the first partition wall 216a.

The first installation space 211 may be provided with a gas-liquid separator 312 provided at a suction side of the compressor 310 to separate gaseous refrigerant from refrigerant and transfer the gas to the compressor 310 . However, the gas-liquid separator 312 may be omitted.

At least a portion of the third expansion valve 363 and the refrigerant pipe 300a may be positioned in the first installation space 211 .

The plurality of installation spaces may include a second installation space 212 for installation of the condenser 320 . A heat dissipation outlet 218 for discharging air heat-exchanged with the condenser 320 may be formed at a rear end of the second installation space 212 .

The second installation space 212 may be partitioned from the fourth installation space 214 by the second partition wall 216b.

The plurality of installation spaces may include a third installation space 213 for installing the third evaporator 350 . The third installation space 213 may be partitioned from the fourth installation space 214 by the third partition wall 216c.

The plurality of installation spaces may include a fourth installation space 214 for installing the fan assembly 300b. The fourth installation space 214 may be understood as a space defined by a plurality of partition walls, for example, the first to fourth partition walls 216a, 216b, 216c, and 216d.

The fourth installation space 214 may be disposed between the second and third installation spaces 212 and 213 .

The plurality of installation spaces may include a fifth installation space 215 for installing the electronic unit 217 . The electrical unit 217 may include a control component for controlling the operation of the refrigerator 100 or the air conditioner 200 .

The fifth installation space 215 may be partitioned from the second to fourth installation spaces 212 , 213 , and 214 by the fourth partition wall 216d.

The second partition wall 216b and the third partition wall 216c may come into contact with the first partition wall 216a so that the first to fourth installation spaces 211 , 212 , 213 , and 214 are partitioned from each other.

The fifth installation space 215 may be formed opposite the first installation space 211 with the third and fourth installation spaces 213 and 214 as the center.

The first to fifth installation spaces 211 , 212 , 213 , 214 , and 215 may form different temperature environments. Accordingly, a heat insulating material may be provided on at least one of the first to fourth partition walls so that the first to fifth installation spaces 211 , 212 , 213 , 214 , and 215 may be thermally separated from each other.

The first fan discharge part 325a of the fan assembly 300b is coupled to the second partition wall 216b and can discharge air from the fourth installation space 214 to the second installation space 212. there is.

The second fan discharge part 355a of the fan assembly 300b is coupled to the third partition wall 216c and can discharge air from the fourth installation space 214 to the third installation space 213. there is.

Referring to FIG. 6 , air flow in the refrigerator 100 and the air conditioner 200 will be briefly described.

The compressor 310 and the condensing fan 325 are driven, and the refrigerant compressed in the compressor 310 is condensed in the condenser 320, reduced in pressure in the expansion valve, and then evaporated in the first and second evaporators 330 and 340. there is.

When the first evaporator fan 335 is driven, the cold air in the refrigerating compartment 101 flows from the lower space of the refrigerating compartment 101 to the rear wall of the refrigerating compartment 101, and passes through the return hole formed in the rear wall to the first evaporator 330. ) can flow to the suction side of

Cold air is cooled while passing through the first evaporator 330 and may be supplied to the refrigerating compartment 101 through the first evaporator fan 335 . A supply hole through which cold air that has passed through the first evaporation fan 335 is discharged into the refrigerating compartment 101 may be formed in a rear wall of the refrigerating compartment 101 .

When the second evaporator fan 345 is driven, the cold air of the freezing chamber 105 flows from the lower space of the freezing chamber 101 to the rear wall of the freezing chamber 105, and the second evaporator 340 passes through a return hole formed in the rear wall. ) can flow to the suction side of

Cold air is cooled while passing through the second evaporator 340 and may be supplied to the freezing compartment 105 through the second evaporator fan 345 . A supply hole through which cool air passed through the second evaporation fan 345 is discharged into the freezing chamber 105 may be formed in a rear wall of the freezing chamber 105 .

When the air conditioner 200 is operated, the third evaporation fan 355 is driven, and air in the indoor space may be introduced into the housing 210 through the suction part 231 .

The air introduced through the suction part 231 flows into the fourth installation space 214 and is sucked into the fan assembly 300b.

Some of the air sucked into the fan assembly 300b flows backward through the condensation fan 325 and flows into the second installation space where the condenser 320 is located.

Air is heated by heat exchange with the condenser 320 in the second installation space, and the heated air may be discharged to the outside of the housing 210 through the heat discharge unit 218 .

The compression capacity of the compressor 310 and the heat dissipation capacity of the condenser 320 may be designed to be sufficient to drive the integrated refrigerator 10 .

The refrigerator 100 may be a constantly driven product, and the air conditioner 200 may be understood as an intermittently driven product driven by a user's command.

When only the refrigerator 100 is driven, the heat dissipation amount of the condenser 320 may not be very large. However, when the air conditioner 200 is driven together with the refrigerator 100, the heat dissipation amount of the condenser 320 may greatly increase.

In particular, the amount of heat radiation required when driving the air conditioner 200 may be greater than the amount of heat radiation required when driving the refrigerator 100 .

When the refrigerator 100 and the air conditioner 200 are operated together and the heat generated in the condenser 320 is discharged to the indoor space or the kitchen, the temperature of the indoor space may rise to the extent that the user feels uncomfortable. can

Therefore, when the integrated refrigerator 10 is operated, the air heat-exchanged in the condenser 320 needs to be well discharged to the outside of the indoor space through the heat radiation duct 90 .

The rest of the air sucked into the fan assembly 300b flows forward through the third evaporation fan 355 and flows into the third installation space 213 where the third evaporator 350 is located.

Air is cooled by heat exchange with the third evaporator 350 in the third installation space, and the cooled air may be discharged to the outside of the housing 210 through the cooling outlet 220 .

When the cooled air is discharged through the cooling discharge unit 220, the discharge vane 221 is opened and the direction may be changed by the discharge vane 221. For example, the discharge vane 221 may be rotated downward or slidably moved in order to discharge air to the front lower portion of the integrated refrigerator.

7 is a cycle diagram showing the configuration of a refrigerator integrated with an air conditioner according to a first embodiment of the present invention.

Referring to FIG. 7 , the integrated refrigerator 10 according to the first embodiment of the present invention may drive a refrigerating cycle. The refrigerating cycle may be driven by a plurality of cycle parts.

The integrated refrigerator 10 may include a compressor 310 for compressing the refrigerant and a condenser 320 disposed at an outlet side of the compressor 310 and condensing the high-pressure gas refrigerant compressed by the compressor 310. can

The integrated refrigerator 10 may include expansion valves 361 , 362 , and 363 for depressurizing the refrigerant condensed in the condenser 320 and a plurality of evaporators 330 , 340 , and 350 evaporating the refrigerant depressurized in the expansion valves 361 , 362 , and 363 . .

The plurality of evaporators 330 , 340 , and 350 may include a first evaporator 330 , a second evaporator 340 , and a third evaporator 350 . For example, the first to third evaporators 330 , 340 , and 350 may constitute a "refrigerator compartment evaporator", a "freezer compartment evaporator", and an "air conditioner evaporator", respectively.

The expansion valves 361, 362, and 363 include a first expansion valve 361 provided at the inlet side of the first evaporator 330, a second expansion valve 362 provided at the inlet side of the second evaporator 340, and A third expansion valve 363 provided at an inlet side of the third evaporator 350 may be included.

The first and second expansion valves 361 and 362 may be called "refrigerator expansion valves", and the third expansion valve 363 may be called "air conditioner expansion valves".

The compressor 310, the condenser 320, the expansion valves 361, 362, and 363 and the plurality of evaporators 330, 340, and 350 are connected by a refrigerant pipe 300a to allow circulation of the refrigerant.

The refrigerant pipe 300a may include a discharge pipe 301 for guiding the refrigerant discharged from the compressor 310 to the condenser 320 . The discharge pipe 301 may be connected to the inlet side of the condenser 320 .

The refrigerant pipe 300a may include a condensation pipe 302 that is connected to the outlet of the condenser 320 and allows the refrigerant condensed in the condenser 320 to flow.

The condensation pipe 302 may be connected to the inlet side of the second evaporator 340 .

The refrigerant pipe 300a may include evaporator inlet pipes 303a, 303b, and 303c branched from the condensation pipe 302 or connected to the condensation pipe 320 and connected to the first to third evaporators 330, 340, and 350. there is.

The evaporator inlet pipes 303a, 303b, and 303c may include a first evaporator inlet pipe 303a branched from the first branch portion 302a of the condensation pipe 302 and connected to the first evaporator 330. there is.

The evaporator inlet pipes 303a, 303b, and 303c may include a second evaporator inlet pipe 303b that is connected to the condensation pipe 302 and introduces the refrigerant into the second evaporator 340. It can be understood that the second evaporator inlet pipe 303b constitutes a part of the condensation pipe 302.

The evaporator inlet pipes 303a, 303b, and 303c may include a third evaporator inlet pipe 303c branched from the second branch portion 302b of the condensation pipe 302 and connected to the third evaporator 350. there is.

The first expansion valve 361 may be installed in the first evaporator inlet pipe 303a.

The second expansion valve 362 may be installed in the second evaporator inlet pipe 303b.

The third expansion valve 363 may be installed in the third evaporator inlet pipe 303c.

At least one of the first to third expansion valves 361, 362, and 363 may be configured as an electronic expansion valve (EEV) capable of adjusting an opening degree. For example, the first to third expansion valves 361, 362, and 363 may be configured as electronic expansion valves (EEVs).

Refrigerating loads of the refrigerator 100 and the air conditioner 200 may be formed differently. For example, the refrigerating load of the air conditioner 200 may be larger than that of the refrigerator 100 .

The evaporation pressure of the third evaporator 350 provided in the air conditioner 200 may be higher than that of the first evaporator 330 provided in the refrigerating compartment 101 . Also, the evaporation pressure of the first evaporator 330 may be greater than that of the second evaporator 340 provided in the freezing compartment 105 .

The amount of refrigerant required to drive the air conditioner 200 may be larger than the amount of refrigerant required to drive the refrigerator 100 .

To this end, the opening size of the third expansion valve 363, which controls the amount of refrigerant flowing into the third evaporator 350, is the size of the opening of the first expansion valve 361, which controls the amount of refrigerant flowing into the first evaporator 330. It may be formed larger than the size of the opening.

That is, when the third expansion valve 363 is fully opened, the opening diameter of the third expansion valve 363 is equal to the first expansion valve 361 when the first expansion valve 361 is fully opened. 361) may be formed larger than the diameter.

The opening size of the third expansion valve 363 controlling the amount of refrigerant flowing into the third evaporator 350 is greater than the opening size of the second expansion valve 362 controlling the amount of refrigerant flowing into the second evaporator 340. can be made large.

That is, when the third expansion valve 363 is fully open, the opening diameter of the third expansion valve 363 is the second expansion valve (362) when the second expansion valve 362 is fully opened. 362) may be formed larger than the diameter.

For example, when the refrigerator 100 and the air conditioner 200 are driven together, the opening diameter of the third expansion valve 363 is the opening diameter of the first expansion valve 361 or the second expansion valve 363. The opening of the valve 362 may be larger than the diameter.

In this case, when the refrigerant passing through the condenser 320 is branched and introduced into the first to third evaporators 330, 340, and 350, the amount of refrigerant flowing into the third evaporator 350 is reduced to the first and second evaporators 330 and 340. may be greater than the amount of refrigerant flowing into the

However, when the user changes the set temperature of the storage compartments 101 and 105 of the refrigerator 100 or changes the set temperature of the indoor space through the air conditioner 200, the temperature of the refrigerator 100 and the air conditioner 200 Cooling load may vary.

Corresponding to the changing cooling load, opening degrees of the first to third expansion valves 361, 362, and 363 may be adjusted. At this time, the opening of the first to third expansion valves 361 , 362 , and 363 may be controlled so that the refrigerant at the outlet of the first to third evaporators 330 , 340 , and 350 may be in an overheated state.

When the refrigerator 100 is operated while the air conditioner 200 is not operated, the third expansion valve 363 is turned off (closed) and the first and second expansion valves 361 and 362 are opened. can

In this case, the refrigerant condensed in the condenser 320 may branch and flow into the first and second evaporators 330 and 340 . Further, the opening degrees of the first and second expansion valves 361 and 362 may be adjusted according to the loads of the refrigerating compartment 101 and the freezing compartment 105 .

The opening size of the first expansion valve 361 may be similar to, for example, the same as the opening size of the second expansion valve 362 .

That is, when the first expansion valve 361 is fully open, the flow path diameter of the first expansion valve 361 is the second expansion valve (362) when the second expansion valve 362 is fully opened. 362) may be formed similar to or equal to the flow path diameter.

The cooling load of the refrigerating compartment 101 and the cooling load of the freezing compartment 105 may vary according to the operating environment of the refrigerator.

For example, when the internal temperature of the refrigerating compartment 101 is maintained below a set temperature and the internal temperature of the freezing compartment 105 is higher than the set temperature, the cooling load of the refrigerating compartment 101 is small while cooling the freezing compartment 105. load may increase.

In this case, the opening of the second expansion valve 362 is controlled to be greater than the opening of the first expansion valve 361, so that the amount of refrigerant flowing into the second evaporator 340 flows into the first evaporator 330. It can be adjusted more than the amount of refrigerant.

Conversely, when the internal temperature of the freezing compartment 105 is maintained below the set temperature and the internal temperature of the refrigerating compartment 101 is higher than the set temperature, the cooling load of the freezing compartment 105 is small while the cooling load of the refrigerating compartment 101 is small. can increase.

In this case, the opening of the first expansion valve 361 is controlled to be greater than the opening of the second expansion valve 362, so that the amount of refrigerant flowing into the first evaporator 330 flows into the second evaporator 340. It can be adjusted more than the amount of refrigerant.

The refrigerant pipe 100a may include evaporator outlet pipes 304a, 304b, and 304c connected to outlets of the first to third evaporators 330, 340, and 350.

The evaporator outlet pipes 304a, 304b, and 304c include the first evaporator outlet pipe 304a connected to the outlet side of the first evaporator 330 and the second evaporator outlet pipe connected to the outlet side of the second evaporator 340. A third evaporator outlet pipe 304c connected to the outlet side of the pipe 304b and the third evaporator 350 may be included.

The first to third evaporator outlet pipes 304a, 304b, and 304c may be joined to the low pressure pipe 305. The low pressure pipe 305 is connected to the second evaporator outlet pipe 304b and may be connected to the suction side of the compressor 310 .

The low pressure pipe 305 may include a first lamination part 305a connected to the first evaporator outlet pipe 304a.

The low pressure pipe 305 may include a second lamination part 305b connected to the third evaporator outlet pipe 304c.

When the refrigerator 100 and the air conditioner 200 are driven together, the refrigerants evaporated in the first to third evaporators 330, 340, and 350 pass through the first to third evaporator outlet pipes 304a, 304b, and 304c. discharged and can be combined in the low pressure pipe 305. Also, the refrigerant of the low pressure pipe 305 may be sucked into the compressor 310 .

The evaporation pressure of the first evaporator 330 may be higher than that of the second evaporator 340 . In addition, the evaporation pressure of the third evaporator 350 may be higher than that of the first evaporator 330 .

When the refrigerants evaporated in the first to third evaporators 330, 340, and 350 are combined with the low-pressure pipe 305, the refrigerant flows through the first evaporator outlet pipe 304a or the second evaporator outlet pipe due to a difference in evaporation pressure. Check valves 381 and 382 may be provided to prevent reverse flow to 304b.

The check valves 381 and 382 may include a first check valve 381 installed in the first evaporator outlet pipe 304a.

The check valves 381 and 382 may include a second check valve 382 installed in the second evaporator outlet pipe 304b.

The low-pressure refrigerant combined in the low-pressure pipe 305 can be easily sucked into the compressor 310 by the check valves 381 and 382 .

The integrated refrigerator 10 may further include temperature sensors 371 , 372 , and 373 for detecting superheat levels of the first to third evaporators 330 , 340 , and 350 .

Based on the temperature values sensed by the temperature sensors 371, 372, and 373, the superheat of the first to third evaporators 330, 340, and 350 is detected, and the first to third expansion valves 361, 362, and 363 are controlled to adjust the superheat. can

The temperature sensors 371 , 372 , and 373 may include a first temperature sensor 371 for detecting a degree of overheating of the first evaporator 330 . The first temperature sensor 371 may include a first inlet temperature sensor installed at the inlet end of the first evaporator 330 and a first outlet temperature sensor installed at the outlet end of the first evaporator 330. .

The temperature sensors 371 , 372 , and 373 may include a second temperature sensor 372 for detecting the superheat of the second evaporator 340 . The second temperature sensor 372 may include a second inlet temperature sensor installed at the inlet end of the second evaporator 340 and a second outlet temperature sensor installed at the outlet end of the second evaporator 340. .

The temperature sensors 371 , 372 , and 373 may include a third temperature sensor 373 for detecting the superheat of the third evaporator 350 . The third temperature sensor 373 may include a third inlet temperature sensor installed at the inlet end of the third evaporator 350 and a third outlet temperature sensor installed at the outlet end of the third evaporator 350. .

The superheat of the evaporator can be calculated by subtracting the value detected by the inlet temperature sensor from the value detected by the outlet temperature sensor of each evaporator (330, 340, 350), and the calculated superheat can be formed within the set superheat. ~3 The opening of the expansion valves (361, 362, 363) can be adjusted.

In this way, a refrigeration cycle including one compressor 310 and one condenser 320 is driven to drive the refrigerator 100 and the air conditioner 200, and responds to the cooling load of the refrigerator and the air conditioner. Thus, cold air can be generated by selecting the first to third evaporators 330, 340, and 350 having appropriate cooling capacities.

Due to the characteristics of the refrigerator 100 that is always driven and the air conditioner 200 that is operated intermittently when a user gives an on command, the load of the refrigerating cycle may vary depending on the operation of the integrated refrigerator.

In response to the changing load of the refrigeration cycle, the pressure control of the refrigeration cycle can be easily performed by adjusting the opening degrees of the first to third expansion valves 361, 362, and 363 provided at the inlet ends of the evaporators 330, 340, and 350.

An evaporation fan for blowing cold air may be provided at one side of each of the evaporators 330, 340, and 350. The evaporation fan may include first to third evaporation fans 335 , 345 , and 355 provided on each side of the first to third evaporators 330 , 340 , and 350 .

8 is a view showing configurations of an air conditioner-integrated refrigerator and an exhaust system according to a second embodiment of the present invention.

Referring to FIG. 8 , the integrated refrigerator 10a according to the second embodiment of the present invention may include a heat radiation duct 90a for discharging heat generated in the integrated refrigerator 10a to the outside of the indoor space.

The description of the integrated refrigerator 10 of the first embodiment can be used for detailed configurations of the refrigerator 100 and the air conditioner 200 constituting the integrated refrigerator 10a.

The integrated refrigerator 10a according to the present embodiment may be installed at a location relatively far from the exhaust hood H located in the kitchen. In this case, when the heat radiating duct is connected to the exhaust hood H according to the structure described in the first embodiment, the length of the heat radiating duct is too long, and thus exhaust performance may deteriorate.

Therefore, in the present embodiment, it is characterized in that a window provided in the kitchen is used as an exhaust device without using an exhaust hood (H).

The heat dissipation duct 90a may extend from the integrated refrigerator 10a to the window W. As described above, the heat radiation duct 90a is connected to the heat radiation outlet 218 and may be embedded or attached to a wall surface or furniture to extend toward the window W.

The heat dissipation duct 90a may be disposed to pass through the window W, or may be attached to one side of the window W. At this time, the heat dissipation duct 90a may directly communicate with the outside of the indoor space.

An additional heat dissipation fan 70a may be installed inside the heat dissipation duct 90a or in the window W so that exhaust may be smoothly discharged through the heat dissipation duct 90a.

9 is a view showing the configuration of an air conditioner integrated refrigerator and an exhaust system according to a third embodiment of the present invention, and FIG. 10 is a perspective view showing the configuration of an air conditioner integrated refrigerator according to a third embodiment of the present invention. 11 is an exploded perspective view showing a configuration of an air conditioner integrated refrigerator according to a third embodiment of the present invention, and FIG. 12 is a view showing a rear configuration of an air conditioner integrated refrigerator according to a third embodiment of the present invention. .

9 to 12, the integrated refrigerator 10b according to the third embodiment of the present invention further includes a water-cooled condenser 400 that exchanges heat with fluid (water) in addition to the condenser 320 that exchanges heat with air. to be characterized

That is, the integrated refrigerator 10b according to the present embodiment may include the condenser 320 (hereinafter referred to as an air-cooled condenser) and the water-cooled condenser 400 described in the first embodiment.

As described in the first embodiment, when the refrigerator 100 and the air conditioner 200 are driven together, the water-cooled condenser 400 having a sufficient amount of heat dissipation may be used to achieve desired refrigerating performance.

The water-cooled condenser 400 has the advantage of being able to secure a large amount of heat dissipation and having a smaller size than an air-cooled condenser due to the nature of the condenser itself.

In addition, since the water-cooled condenser 400 performs heat dissipation using water, an effect of not increasing the temperature of the indoor space during the heat dissipation process may appear.

The description of the refrigerator 100 according to the present embodiment may refer to the description of the refrigerator according to the first embodiment.

The air conditioner 200 may include a housing 210 in which an installation space for installing parts of a refrigeration cycle is formed. For example, the parts of the refrigeration cycle may include a compressor 310, an air-cooled condenser 320, a water-cooled condenser 400, and a third evaporator 350.

Components of the refrigerating cycle may further include a fan assembly 300b for forming an air flow path. The fan assembly 300b may be disposed between the third evaporator 350 and the air-cooled condenser 320 . The description of the fan assembly 300b may refer to the description of the first embodiment.

The housing 210 includes a suction part 231 for sucking air into the housing 210 and a discharge part 218 and 220 for discharging air heat exchanged between the air-cooled condenser 320 and the third evaporator 350. ) can be formed.

In detail, the discharge units 218 and 220 include a heat discharge discharge unit 218 through which air exchanged with the air-cooled condenser 320 is discharged and a cooling discharge unit 220 through which air exchanged with the third evaporator 350 is discharged. can include Descriptions related to the heat dissipation discharge part 218 and the cooling discharge part 220 may refer to the description of the first embodiment.

The heat radiation outlet 218 may be connected to the heat radiation duct 90 . The heat dissipation duct 90 may be attached to or embedded in a wall surface of an indoor space, or may be attached to a wall surface of a cupboard B or furniture provided in the indoor space.

For example, as described in the first embodiment, the heat dissipation duct 90 is finally connected to the exhaust hood H provided in the kitchen and can be flexibly connected to the outside of the indoor space.

As another example, as described in the second embodiment, the heat dissipation duct 90 may be connected to the window (W).

Inside the housing 210, partition walls 216a, 216b, 216c, and 216d partitioning a plurality of installation spaces for installing parts of a refrigeration cycle may be provided. The description of the barrier rib may refer to the description of the first embodiment.

Water pipes 410 and 420 connected to the water-cooled condenser 400 may be provided in the housing 210 . The water pipes 410 and 420 may include an intake pipe 410 for supplying water to the water-cooled condenser 400 and a water outlet pipe 420 for discharging water heat exchanged in the water-cooled condenser 400 .

The water intake pipe 410 may pass through the housing 210, extend into the inner space of the housing 210, and be connected to the water-cooled condenser 400. The housing 210 may form an insertion hole into which the water intake pipe 410 is inserted.

The water outlet pipe 420 is connected to the water-cooled condenser 400 and may pass through the housing 210 and extend to the outside of the housing 210 . The housing 210 may form an insertion hole into which the water outlet pipe 420 is inserted.

For example, the water intake pipe 410 and the water outlet pipe 420 may pass through the rear surface of the housing 210 . However, it is not limited thereto, and the water inlet pipe 410 and the water outlet pipe 420 may pass through side portions of the housing 210 or may pass through different surfaces of the housing 210, respectively.

The water-cooled condenser 400 may be installed in the first installation space 211 among the installation spaces partitioned by the partition walls 216a, 216b, 216c, and 216d.

When the air conditioner 200 is not operating, refrigerant is not supplied to the water-cooled condenser 400 and the third evaporator 350, and a fluid to exchange heat with the refrigerant may not be supplied to the water-cooled condenser 400. .

When the air conditioner 200 is operated, refrigerant is supplied to the water-cooled condenser 400 and the third evaporator 350, and the third evaporation fan 355 may be driven. When the third evaporation fan 355 is driven, air in the indoor space may be introduced into the housing 210 through the suction part 231 .

The air introduced through the suction part 231 is sucked into the fan assembly 300b.

Some of the air sucked into the fan assembly 300b flows backward through the condensation fan 325 and may pass through the air-cooled condenser 320 .

Air is heated by exchanging heat with the air-cooled condenser 320 , and the heated air may be discharged to the outside of the housing 210 through the heat discharge unit 218 . In addition, air may be discharged to the outside of the indoor space through the heat radiation duct 90 .

The rest of the air sucked into the fan assembly 300b flows forward through the third evaporator fan 355 and may pass through the third evaporator 350 .

Air is cooled by heat exchange with the third evaporator 350, and the cooled air may be discharged into the indoor space through the cooling outlet 220.

13 is a cycle diagram showing the configuration of an air conditioner-integrated refrigerator according to a third embodiment of the present invention, and FIG. 14 is a diagram showing the configuration of a water-cooled condenser according to a third embodiment of the present invention.

Referring to FIGS. 13 and 14 , the integrated refrigerator 10b according to the third embodiment of the present invention may drive a refrigerating cycle.

The refrigerating cycle may include a condenser and an evaporator for driving one compressor, driving a refrigerator cycle, and another condenser and an evaporator for driving an air conditioner.

The integrated refrigerator 10 may include a compressor 310 for compressing refrigerant.

The outlet side of the compressor 310 may include a first control valve 341 for sending the high-temperature refrigerant compressed by the compressor 310 to at least one of a refrigerator-side condenser and an air conditioner-side condenser.

For example, the first control valve 341 may be configured as a three-way valve having one inlet and two outlets.

The refrigerant pipe 300a may include a discharge pipe 301 for guiding the refrigerant discharged from the compressor 310 to the first control valve 341 . The discharge pipe 301 may be connected to an inlet side of the first control valve 341 .

Depending on the mode of the first control valve 341, the refrigerant flowing into the first control valve 341 is branched and discharged through both of the two outlets, or flows to be discharged only through one of the two outlets. can be regulated.

For example, when only the refrigerator 100 is driven, the refrigerant may be supplied only to the air-cooled condenser 320 according to the first mode of the first control valve 341 .

On the other hand, when the refrigerator 100 and the air conditioner 200 are driven together, the refrigerant is supplied to both the air-cooled condenser 320 and the water-cooled condenser 400 according to the second mode of the first control valve 341. can

The refrigerator 100 may include an air-cooled condenser 320 disposed at an outlet side of the compressor 310 and condensing the high-pressure gas refrigerant compressed by the compressor 310 .

The air-cooled condenser 320 is connected to the first outlet side of the first control valve 341 and may introduce the refrigerant discharged from the first outlet.

The air conditioner 200 may include a water-cooled condenser 400 disposed at an outlet side of the compressor 310 and condensing the high-pressure gas refrigerant compressed by the compressor 310 .

The water-cooled condenser 400 is connected to the second outlet side of the first control valve 341 and can introduce the refrigerant discharged from the second outlet.

The refrigerant pipe 300a may include a condensation pipe 302 that is connected to the outlet of the air-cooled condenser 320 and allows the refrigerant condensed in the air-cooled condenser 320 to flow.

A second control valve 342 for supplying refrigerant to at least one of the first and second evaporators 330 and 340 may be provided at the outlet side of the air-cooled condenser 320 . The condensation pipe 302 may be connected to the inlet side of the second control valve 342 .

The integrated refrigerator 10 includes first and second expansion devices 361a and 362a for depressurizing the refrigerant condensed in the air-cooled condenser 320 and the refrigerant depressurized in the first and second expansion devices 361a and 362a. It may include a plurality of evaporators 330 and 340 for evaporating.

The first and second expansion devices 361a and 362a may constitute a “refrigerator expansion device”.

The plurality of evaporators 330 and 340 may include a first evaporator 330 and a second evaporator 340 . For example, the first and second evaporators 330 and 340 may constitute a "refrigerator compartment evaporator" and a "freezer compartment evaporator", respectively.

The second control valve 342 may be configured as a three-way valve having one inlet and two outlets.

A first evaporator inlet pipe 303a is connected to one of the two outlets of the second control valve 342 and may extend to the first evaporator 330 .

The first expansion device 361a may be installed in the first evaporator inlet pipe 303a.

For example, the first expansion device 361a may include a capillary tube. The tube diameter of the first expansion device 361 may be determined based on the freezing load of the refrigerating compartment.

A second evaporator inlet pipe 303b is connected to the other one of the two outlets of the second control valve 342 and may extend to the second evaporator 330 .

The second expansion device 362a may be installed in the second evaporator inlet pipe 303b.

For example, the second expansion device 362a may include a capillary tube. The tube diameter of the second expansion device 362 may be determined based on the freezing load of the freezing compartment.

The first and second expansion devices 361a and 362a may be referred to as "refrigerator expansion devices".

The first evaporator 330 is an evaporator for cooling the refrigerating compartment, and the evaporation pressure of the first evaporator 330 may be higher than that of the second evaporator 340 for cooling the freezing compartment. Therefore, the tube diameter of the first expansion device 361a is formed larger than that of the second expansion device 362a, so that the degree of pressure reduction can be reduced.

When the refrigerating chamber and the freezing chamber are simultaneously operated, the refrigerant condensed in the air-cooled condenser 320 may be branched from the second control valve 342 and introduced into the first and second evaporators 330 and 340 .

On the other hand, when the refrigerating chamber is operated independently, the refrigerant condensed in the air-cooled condenser 320 flows into the first evaporator 330 through the second control valve 342 and does not flow into the second evaporator 340. may not be

On the other hand, when the freezer compartment is operated independently, the refrigerant condensed in the air-cooled condenser 320 flows into the second evaporator 340 through the second control valve 342 and does not flow into the first evaporator 330. may not be

The refrigerant pipe 300a may include evaporator outlet pipes 304a and 304b connected to outlets of the first to third evaporators 330 , 340 , and 350 .

The evaporator outlet pipes 304a and 304b are the first evaporator outlet pipe 304a connected to the outlet side of the first evaporator 330 and the second evaporator outlet pipe 304b connected to the outlet side of the second evaporator 340. ) may be included.

The first and second evaporator outlet pipes 304a and 304b may be joined to the low pressure pipe 305 . The low pressure pipe 305 is connected to the second evaporator outlet pipe 304b and may be connected to the suction side of the compressor 310 .

The low pressure pipe 305 may include a joint portion 305c connected to the first evaporator outlet pipe 304a and the second evaporator outlet pipe 307 to be described later.

When the refrigerator 100 and the air conditioner 200 are operated together, the refrigerants evaporated in the first to third evaporators 330, 340, and 350 are discharged through the first to third evaporator outlet pipes 304a, 304b, and 307. and can be combined in the low pressure pipe 305. Also, the refrigerant of the low pressure pipe 305 may be sucked into the compressor 310 .

The evaporation pressure of the first evaporator 330 may be higher than that of the second evaporator 340 . In addition, the evaporation pressure of the third evaporator 350 may be higher than that of the first evaporator 330 .

When the refrigerants evaporated in the first to third evaporators 330, 340, and 350 are combined with the low-pressure pipe 305, the refrigerant flows through the first evaporator outlet pipe 304a or the second evaporator outlet pipe due to a difference in evaporation pressure. Check valves 381 and 382 may be provided to prevent reverse flow to 304b.

The check valves 381 and 382 may include a first check valve 381 installed in the first evaporator outlet pipe 304a.

The check valves 381 and 382 may include a second check valve 382 installed in the second evaporator outlet pipe 304b.

The low-pressure refrigerant combined in the low-pressure pipe 305 can be easily sucked into the compressor 310 by the check valves 381 and 382 .

A water-cooled condenser 400 may be connected to the second outlet side of the first control valve 341 . The water-cooled condenser 400 may be understood as a heat exchanger in which heat is exchanged between the high-temperature refrigerant compressed in the compressor 310 and a predetermined fluid.

For example, the fluid may include water.

The water-cooled condenser 400 may be configured by separating a refrigerant flow path and a fluid flow path. For example, the water-cooled condenser 400 may be configured as a double pipe heat exchanger.

The water-cooled condenser 400 may include a heat exchanger housing 401 forming a refrigerant flow path and a fluid flow path therein. For example, the heat exchanger housing 401 may have a cylindrical shape with an empty inside.

The water-cooled condenser 400 may include a refrigerant pipe 403.

The refrigerant pipe 403 is inserted from one side of the heat exchanger housing 401, passes through the inner space of the heat exchanger housing 401, and is connected to the other side of the housing 401 so as to extend to the outside. can

The refrigerant pipe 403 may include a refrigerant inlet port 431 connected to the outlet pipe of the first control valve 341 . The refrigerant inlet port 431 forms one end of the refrigerant pipe 403 and may protrude from one side of the heat exchanger housing 401 .

The refrigerant pipe 403 may include a refrigerant discharge port 432 connected to the condensation pipe 306 . The refrigerant discharge port 432 forms the other end of the refrigerant pipe 403 and may protrude from the other side of the heat exchanger housing 401 .

The water-cooled condenser 400 may form a fluid flow path. For example, the fluid passage may include a water passage.

The water passage may be formed in the inner space 402 of the heat exchanger housing 401 . The inner space 402 may form a water flow space.

The refrigerant pipe 403 may pass through the inner space 402 .

The water-cooled condenser 400 may include an intake port 412 connected to the intake pipe 410 to introduce fluid into the heat exchanger housing 401 . The intake port 412 may be provided on one side of the heat exchanger housing 401 .

The water-cooled condenser 400 may include a water outlet port 422 connected to the outlet pipe 420 to discharge the fluid heat-exchanged inside the heat exchanger housing 401 . The water outlet port 422 may be provided on the other side of the heat exchanger housing 401 .

A flow direction of the refrigerant through the refrigerant pipe 403 and a flow direction of the fluid from the inlet port 412 toward the outlet port 422 may cross each other.

For example, when the flow direction of the refrigerant through the refrigerant pipe 403 forms the left and right directions of the heat exchanger housing 401, the flow direction of the fluid forms the front and rear directions of the heat exchanger housing 401. can

As another example, when the flow direction of the refrigerant through the refrigerant pipe 403 forms the front and rear directions of the heat exchanger housing 401, the flow direction of the fluid forms the left and right directions of the heat exchanger housing 401. can

The fluid intake port 412 is disposed adjacent to the refrigerant outlet port 432, and the fluid outlet port 422 is disposed adjacent to the refrigerant inlet port 431 to counter-flow heat exchange. heat exchange) can be performed. Thus, heat exchange efficiency can be improved.

A water supply source S1 for supplying fluid may be connected to the water-cooled condenser 400 . The water supply source (S1) may be configured as, for example, a water tank, or may be configured by directly connecting to a water supply source.

The water supply source (S1) is connected to the water supply pipe 410, and the fluid of the water supply source (S1) may be supplied to the water-cooled condenser 400 through the water water supply pipe 410.

A water outlet pipe 420 is connected to the fluid outlet side of the water-cooled condenser 400, and the water outlet pipe 420 may be connected to the hot water storage tank S2. The fluid heated in the water-cooled condenser 400 may be supplied to the storage tank S2.

The water in the water outlet pipe 420 may be mixed with the water stored in the storage tank S2.

As another example, the water in the water outlet pipe 420 may be used only for heating the water in the storage tank S2 without being mixed with the water in the storage tank S2. And, the used water may be finally drained to the outside.

In this way, since the water used for heat dissipation of the water-cooled condenser 400 is supplied to the hot water storage tank S2 without being discarded and used as living water, energy can be saved.

A water outlet temperature sensor 392 for detecting the temperature (water outlet temperature) of the fluid discharged from the water-cooled condenser 400 may be provided in the outlet pipe 420 .

The amount of fluid supplied to the water-cooled condenser 400 may be adjusted based on the water outlet temperature detected by the outlet temperature sensor 392 .

The amount of fluid supplied to the water-cooled condenser 400 may be adjusted through the first water pipe valve 451. The amount of fluid supplied to the water-cooled condenser 400 may be increased or decreased by adjusting the opening of the first water pipe valve 451 .

When the water outlet temperature detected by the outlet temperature sensor 392 is higher than the set temperature range, the amount of fluid supplied to the water-cooled condenser 400 may be increased.

When the water outlet temperature detected by the outlet temperature sensor 392 is lower than the set temperature range, the amount of fluid supplied to the water-cooled condenser 400 may be reduced.

When the water outlet temperature detected by the outlet temperature sensor 392 is within a set temperature range, the amount of fluid supplied to the water-cooled condenser 400 may be maintained.

As such, since the amount of heat dissipation required to drive the air conditioner 200, which is a high-load device, can be implemented using the water-cooled condenser 420, a higher amount of heat dissipation can be secured compared to the air-cooled condenser.

In addition, since water may be used instead of air that may affect the temperature of the indoor space, an increase in the temperature of the indoor space due to driving of the water-cooled condenser 400 may be prevented.

The refrigerant-side outlet pipe of the water-cooled condenser 400 may constitute a condensation pipe 306 . The liquid refrigerant condensed in the water-cooled condenser 400 may flow through the condensation pipe 306 . For convenience of description, the condensation pipe 302 may be referred to as a "first condensation pipe" and the condensation pipe 306 may be referred to as a "second condensation pipe".

A third expansion device 363a as an “air conditioning expansion device” for decompressing the condensed refrigerant may be installed in the condensation pipe 306 . For example, the third expansion device 363a may be composed of an electronic expansion valve (EEV) capable of adjusting the opening.

Refrigerating loads of the refrigerator 100 and the air conditioner 200 may be formed differently. For example, the refrigerating load of the air conditioner 200 may be greater than that of the refrigerator 100 .

The evaporation pressure of the third evaporator 350 provided in the air conditioner 200 may be higher than that of the first evaporator 330 provided in the refrigerating compartment 101 . Also, the evaporation pressure of the first evaporator 330 may be greater than that of the second evaporator 340 provided in the freezing compartment 105 .

The amount of refrigerant required to drive the air conditioner 200 may be larger than the amount of refrigerant required to drive the refrigerator 100 . To this end, the third expansion device 363a for decompressing the refrigerant flowing into the third evaporator 350 may be configured as an expansion valve capable of adjusting the amount of refrigerant.

A third evaporator 350 may be connected to the condensation pipe 306 . The refrigerant depressurized by the third expansion device 363a may flow into the third evaporator 350 and be evaporated. At least a portion of the condensation pipe 306 may constitute a third evaporator inlet pipe provided at an inlet side of the third evaporator 350 .

A third evaporator outlet pipe 307 for guiding the refrigerant evaporated in the third evaporator 350 to the suction side of the compressor 310 may be provided at the outlet side of the third evaporator 350 .

The third evaporator outlet pipe 307 may be joined to the joint portion 305c of the low pressure pipe 305 . The refrigerant of the third evaporator outlet pipe 307 is combined with the refrigerant of the first and second outlet pipes 304a and 304b at the junction part 305c and may be sucked into the compressor 310 .

By such circulation of the refrigerating cycle, the integrated refrigerator 10b can be easily operated, and heat dissipation according to the driving of the refrigerating cycle can be easily performed.

10: integrated refrigerator 100: refrigerator
101: first storage compartment (refrigerating compartment) 105: second storage compartment (freezing compartment)
200: air conditioner 210: housing
218: heat discharge unit 220: cooling discharge unit
231: intake 310: compressor
320: condenser 325: condensation fan
330: first evaporator 335: first evaporator fan
340: second evaporator 345: second evaporator fan
350: third evaporator 355: third evaporator fan
400: water-cooled condenser

Claims (17)

In an air conditioner integrated refrigerator in which a refrigerator having a refrigerator evaporator for cooling a storage compartment, an air conditioner having an air conditioner evaporator and a discharge unit for cooling an indoor space are integrally formed,
a refrigerator body forming the storage compartment;
a housing provided on one side of the refrigerator body and forming a suction part for sucking in air and the discharge part;
an air-cooled condenser provided inside the housing and exchanging heat with some of the air sucked in through the suction part; and
It is provided inside the housing and includes the air conditioning evaporator that exchanges heat with the rest of the air sucked through the suction part,
The discharge unit includes a heat discharge discharge unit through which air exchanged with the air-cooled condenser is discharged and a cooling discharge unit through which air exchanged with the air conditioning evaporator is discharged,
The air conditioner integrated refrigerator further comprises a heat radiating duct extending to the outside of the heat radiating discharge unit so that the air discharged from the heat discharge unit does not flow into the indoor space. According to claim 1,
the housing,
A partition wall partitioning the inner space of the housing into a plurality of installation spaces,
The partition wall includes a first partition wall defining a first installation space for installing a compressor and a second partition wall defining a second installation space for installing the air-cooled condenser. According to claim 2,
The air conditioner integrated refrigerator is formed in the heat dissipation unit in the second installation space. According to claim 3,
The housing is disposed above the refrigerator body,
The housing includes a rear portion forming the heat dissipating portion and a front portion forming the cooling discharge portion. According to claim 2,
The partition wall includes a third partition wall defining a third installation space for installing the air conditioning evaporator,
The third partition wall divides the fourth installation space and the third installation space in which the fan assembly is installed. According to claim 5,
The fan assembly,
a condensing fan for sending air to the air-cooled condenser; and
An air conditioner integrated refrigerator including an air conditioner fan for sending air to the air conditioner evaporator. According to claim 6,
The condensing fan includes a first fan discharge unit for discharging air from the fourth installation space to the second installation space,
The air conditioner fan includes a second fan outlet for discharging air from the fourth installation space to the third installation space. According to claim 7,
The first fan discharge part is coupled to the second partition wall, and the second fan discharge part is coupled to the third partition wall. According to claim 2,
The partition wall includes a fourth partition wall defining a fifth installation space for installing electrical components, and the fifth installation space is partitioned from the first and second installation spaces by the fourth partition wall. According to claim 1,
a water-cooled condenser provided inside the housing;
an intake pipe connected to the water-cooled condenser and supplying water to the water-cooled condenser; and
An air conditioner integrated refrigerator further comprising a water outlet pipe connected to the water-cooled condenser and discharging water heat exchanged in the water-cooled condenser. According to claim 10,
At least one of the intake pipe and the water outlet pipe penetrates the housing and extends to the outside of the housing. An exhaust system including an air conditioner-integrated refrigerator in which a refrigerator having a refrigerator evaporator for cooling a storage compartment, an air conditioner evaporator for cooling an indoor space, and an air conditioner having a discharge unit are integrally formed,
a refrigerator body forming the storage compartment;
a housing provided on one side of the refrigerator body and forming a suction part for sucking in air and the discharge part;
an air-cooled condenser provided inside the housing and exchanging heat with some of the air sucked in through the suction part;
a heat discharge unit through which the air exchanged with the air-cooled condenser is discharged;
a heat radiation duct coupled to the heat radiation outlet; and
It is connected to the heat radiation duct and includes an exhaust device for discharging the air discharged from the heat discharge unit to the outside of the indoor space.
Exhaust system including air conditioner integrated refrigerator. According to claim 12,
The exhaust system is
Including at least one of an exhaust hood for discharging contaminated air from the cooking appliance and a window for ventilation,
Exhaust system including air conditioner integrated refrigerator. According to claim 12,
Further comprising a heat dissipation fan provided in the heat dissipation duct and forcing air to be discharged.
Exhaust system including air conditioner integrated refrigerator. According to claim 12,
an intake pipe for supplying water into the housing;
A water-cooled condenser connected to the water intake pipe; and
Further comprising a water outlet pipe connected to the water-cooled condenser and discharging water heat exchanged in the water-cooled condenser to the outside of the housing.
Exhaust system including air conditioner integrated refrigerator. According to claim 12,
an air conditioning evaporator provided inside the housing; and
It is formed in the housing and further comprises a cooling discharge unit for discharging the air heat-exchanged with the air conditioning evaporator to the indoor space.
Exhaust system including air conditioner integrated refrigerator. According to claim 16,
Further comprising a fan assembly disposed between the air-cooled condenser and the air-conditioning evaporator,
The fan assembly includes a condensing fan having a first fan discharge part directed to the air-cooled condenser and an air conditioner fan having a second fan discharge part directed to the air conditioning evaporator.
An exhaust system including an air conditioner integrated refrigerator.

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