DE102023116455A1 - Air conditioning and climate system with an integrated heat exchanger - Google Patents

Abstract

Air conditioning system with an integrated heat exchanger and air conditioning system using the integrated heat exchanger, the air conditioning system comprising an indoor heat exchanger (200) arranged in an air conditioning housing (100) and configured to heat air or cool air by selectively passing through a first cooling water for heating and a second To generate cooling water for cooling, a heater (300) which is arranged at a distance from the interior heat exchanger (200) in the air conditioning housing (100) and is configured to selectively dissipate heat, wherein a vent path (101) around the heater (300) is formed around, and a damper unit (400) configured to adjust the opening and closing of the vent path (101) and installed in the air conditioning case (100).

Description

The invention relates to an air conditioning system with an integrated heat exchanger to improve cooling and heating efficiency, and an air conditioning system using the integrated heat exchanger.

Recently, the realization of environmentally friendly technology and solutions to problems such as energy depletion are growing as social concerns associated with an electric vehicle. An electric vehicle is powered by an electric motor that is supplied with electricity from a battery and delivers power. Accordingly, an electric vehicle has the advantages of not emitting carbon dioxide, producing low noise, and having higher energy efficiency of an electric motor than the energy efficiency of an internal combustion engine, so it has proven to be an environmentally friendly vehicle.

The core technology for achieving such an electric vehicle is the technology related to a battery module, and recently studies on reducing the weight and size of a battery and reducing the charging time have been actively carried out. A battery module cannot maintain optimal performance and long life if it is not used in an optimal temperature environment. However, it has been found that it is essentially difficult to use a battery module in an optimal temperature environment due to heat generated during operation and a change in external temperature.

Further, an electric vehicle does not have a source of waste heat generated during combustion in a conventional internal combustion engine such as an internal combustion engine, so the interior of the electric vehicle is heated by an electric heater in winter time. In addition, warm-up is required to improve the charging and discharging ability of the battery in a very cold period, so a separate electric heater of the cooling water heating type is used. In other words, a technique of operating a heating and cooling system for controlling the temperature of a battery module separately from a heating and cooling system for interior air conditioning of a vehicle is used to maintain an optimal temperature environment for the battery module.

In this case, heat pump technology is used to minimize the consumption of thermal energy in the air conditioning system for interior air conditioning of a vehicle to increase mileage, thereby minimizing energy consumption. An air conditioning system has a temperature adjustment door for selectively adjusting the supply of cooling air and heating air, and components thereof, including an evaporator and a heater, are spaced apart from each other to increase the overall size. Further, when air conditioning is performed only by circulating a refrigerant, the volume of the components for circulating the refrigerant increases, so that the overall packaging of the air conditioning system increases in size.

The invention provides an air conditioner with an integrated heat exchanger, which improves cooling and heating efficiency by reducing the number of flaps for adjusting the temperature of conditioned air for each mode, to have a compact overall package due to the use of the integrated heat exchanger and the use of cooling water, and created an air conditioning system using the integrated heat exchanger.

In one embodiment of the invention, an air conditioner with an integrated heat exchanger includes an indoor heat exchanger disposed in an air conditioning housing (e.g., an air conditioning housing) and configured to generate heating air or cooling air by selectively passing cooling water for heating and cooling water for cooling, and a Heater spaced from the interior heat exchanger in the air conditioning housing and configured to selectively dissipate heat. Specifically, a vent path (e.g., a drain path or a passage path) is formed around the heater, and a damper unit (e.g., a door unit) is installed in the air conditioning case to adjust opening and closing of the vent path.

In one embodiment, the interior heat exchanger and the heater may be arranged such that their upper portions are disposed close to each other and the lower portions are disposed far away from each other.

In one embodiment, the vent path may be formed above the heater and a bypass path may be formed below the heater in the air conditioning housing.

In one embodiment, the vent path may pass air at a flow rate of 25% or less of the air passed through the heater.

The air conditioning housing may include an air inlet and a plurality of air outlets, and the plurality of air outlets include at least one defrost vent and one or more front vents, and the door unit may include a first door (e.g., a first door) configured to open and close the Adjust the vent path, and have a second flap (e.g., a second door) configured to adjust the opening and closing of the front vent.

The air conditioning enclosure may include a third door (e.g., a third door) configured to adjust opening and closing of the defrost vent.

The first door and the second door may be installed in the air conditioning housing to be adapted to rotate about respective axes of rotation and may have respective movement pins (e.g., movement pins) at ends. The door unit may further include a cam having a plurality of guide slots into which the movement pins of the doors are inserted, such that the cam is configured to change rotational positions of the first and second doors by means of the movement pins respectively associated along the guide slots move.

The guide slots of the cam may extend in a direction of rotation while curving (or bent) inwardly and outwardly, and may have different shapes so that the timing (or times) of opening or closing the vent path, the defrost vent and the front vent may be set differently.

The air conditioning housing may include at least one or more rear vents in a lower portion, and a rear door (e.g., a rear door) may be installed in the rear vent.

The rear door may include a fourth door (e.g., a fourth door) configured to allow air passed through the heater to selectively flow to the rear vent. The rear door may further include a fifth door (e.g., a fifth door) configured to allow air passed through the cabin heat exchanger to selectively flow through a bypass path under the heater to the rear vent without passing through the heater to step through.

In another embodiment, the damper unit may include an opening/closing damper configured to operate up and down (or operated up and down) in the vent path to adjust opening and closing of the vent path, and an actuator , which is configured to control a position of the opening/closing flap.

In another embodiment of the invention, an air conditioning system (e.g. an air conditioning system) with an integrated heat exchanger has a refrigerant circuit in which a refrigerant circulates and which has a compressor, a condenser, an expander and an evaporator. The air conditioning system further includes a first cooling water circuit in which cooling water circulates to exchange heat with the condenser of the refrigerant circuit for heating, a second cooling water circuit in which cooling water circulates to exchange heat with the evaporator of the refrigerant circuit for cooling, and a valve module , to which the first cooling water circuit and the second cooling water circuit are connected and which changes a flow direction of the cooling water for heating or cooling. The air conditioning system further has an interior heat exchanger which is arranged in an air conditioning housing (e.g. an air conditioning housing), to which the first cooling water circuit and the second cooling water circuit are connected, and which receives the cooling water for heating or the second cooling water for cooling and generates heating air or cooling air . In another embodiment, a heater spaced from the indoor heat exchanger and configured to selectively generate heat is disposed in the air conditioning housing, a vent path (e.g., a vent path or a passage path) is formed around the heater, and a Damper unit configured to adjust opening and closing of the vent path is disposed in the air conditioning housing.

The indoor heat exchanger may include a first heat exchange part connected to the first cooling water circuit and configured to remove heat via the cooling water for heating, and a second heat exchange part connected to the second cooling water circuit and configured to remove heat via the cooling water for heating to absorb cooling.

The first cooling water circuit may include a first water pump, and the second cooling water circuit may include a second water pump.

The cooling water in the first cooling water circuit and the cooling water in the second cooling water circuit may be selectively divided (e.g., distributed or shared) by a plurality of distribution valves.

According to the air conditioner with an integrated heat exchanger and the air conditioning system using an integrated heat exchanger configured in the above-described structures, since the heating air and the cooling air are generated by the integrated heat exchanger which enables heat exchange between cooling water and conditioned air, ensures cooling/heating efficiency.

Further, since the temperature of the cooling water circulated in the integrated heat exchanger is adjusted, there is no temperature adjustment door for adjusting the temperature of the conditioned air, so that the number of parts is reduced.

Furthermore, since an integrated heat exchanger is used, the components are optimally arranged so that the overall accommodation is reduced in size.

• 1 eine Ansicht einer Klimaanlage mit einem integrierten Wärmetauscher gemäß einer Ausführungsform der Erfindung;
• 2 eine Ansicht eines Entlüftungspfades und einer Klappeneinheit in der Klimaanlage mit einem integrierten Wärmetauscher aus 1;
• 3 eine Ansicht von Ergebnissen einer Luftströmungsanalyse zur Erläuterung der Effekte der Erfindung;
• 4 eine Ansicht von Klappen der Klappeneinheit und eines Nockens in der Klimaanlage mit einem integrierten Wärmetauscher gemäß einer Ausführungsform der Erfindung;
• 5 eine Ansicht einer ersten Klappe der Klappeneinheit in einer Ausführungsform der Erfindung;
• 6 eine Ansicht einer Verbindungsstruktur eines Klimagehäuses und der ersten Klappe der Klappeneinheit in einer Ausführungsform der Erfindung;
• 7 eine Ansicht einer Verbindungsstruktur des Nockens und der ersten Klappe der Klappeneinheit in einer Ausführungsform der Erfindung;
• 8 eine Ansicht der Innenraumkühlung durch die Klimaanlage mit einem integrierten Wärmetauscher in einer Ausführungsform der Erfindung;
• 9 eine Ansicht der Innenraumkühlung durch die Klimaanlage mit einem integrierten Wärmetauscher in einer Ausführungsform der Erfindung;
• 10 eine Ansicht der Entfrostung durch die Klimaanlage mit einem integrierten Wärmetauscher in einer Ausführungsform der Erfindung;
• 11 eine Ansicht einer Doppelstufe durch die Klimaanlage mit einem integrierten Wärmetauscher in einer Ausführungsform der Erfindung;
• 12 eine Ansicht einer Klimaanlage mit einem integrierten Wärmetauscher gemäß einer anderen Ausführungsform der Erfindung; und
• 13 ein Schaltbild eines Klimasystems unter Verwendung eines integrierten Wärmetauschers gemäß einer Ausführungsform der Erfindung.

The invention is explained in more detail with reference to the drawing. Show in the drawing:

• 1 a view of an air conditioning system with an integrated heat exchanger according to an embodiment of the invention;
• 2 a view of a vent path and a flap unit in the air conditioning system with an integrated heat exchanger 1 ;
• 3 a view of results of an air flow analysis for explaining the effects of the invention;
• 4 a view of flaps of the flap unit and a cam in the air conditioning system with an integrated heat exchanger according to an embodiment of the invention;
• 5 a view of a first flap of the flap unit in an embodiment of the invention;
• 6 a view of a connection structure of an air conditioning housing and the first flap of the flap unit in an embodiment of the invention;
• 7 a view of a connection structure of the cam and the first flap of the flap unit in an embodiment of the invention;
• 8th a view of the interior cooling by the air conditioning system with an integrated heat exchanger in an embodiment of the invention;
• 9 a view of the interior cooling by the air conditioning system with an integrated heat exchanger in an embodiment of the invention;
• 10 a view of defrosting by the air conditioning system with an integrated heat exchanger in an embodiment of the invention;
• 11 a view of a dual stage through the air conditioning system with an integrated heat exchanger in an embodiment of the invention;
• 12 a view of an air conditioning system with an integrated heat exchanger according to another embodiment of the invention; and
• 13 a circuit diagram of an air conditioning system using an integrated heat exchanger according to an embodiment of the invention.

Embodiments of the invention will now be described in detail with reference to the accompanying drawings, and the same or similar components will be designated by the same reference numerals regardless of the numbers of the figures and will not be described repeatedly.

The terms “module” and “unit” used for components in the following description are used only for convenience of description without having different meanings or functions.

In the following description, if it is determined that the detailed description of known techniques related to the present disclosure obscures the subject matter of the embodiments described herein, the detailed description will be omitted. Further, the accompanying drawings are provided solely for easy understanding of the embodiments disclosed in the specification, and the technical idea disclosed in the specification is not limited to the accompanying drawings, and all changes, modifications and substitutions should be understood to be within the scope included in the present disclosure.

Ordinal terms such as “first,” “second,” etc. may be used to describe various components, but the components should not be construed to be limited to the terms. The terms are used merely to distinguish one component from another component.

It is to be understood that when an element is referred to as "connected to" or "coupled to" another element, it may be directly connected or coupled to another element, or connected or coupled to another element via another element interposed therebetween can be. On the other hand, when an element is referred to as “directly connected to” or “directly coupled to” another element, it may be connected or coupled to another element without the other element in between.

Singular forms are intended to include plural forms unless the context clearly indicates otherwise.

It is further understood that the terms "comprising" or "having" as used in this specification specify the presence of mentioned features, steps, operations, components, parts, or a combination thereof, but not the presence or addition of one or more others Exclude features, steps, processes, components, parts, or a combination thereof.

When a component, device, element, or the like of the present disclosure is described as having a purpose or performing an operation, function, or the like, the component, device, or element should be considered herein that it is “configured to fulfill” that purpose or perform that operation or function.

Below, an air conditioning system with an integrated heat exchanger and an air conditioning system with an integrated heat exchanger according to embodiments of the invention will be described with reference to the accompanying drawings.

1 is a view of an air conditioner with an integrated heat exchanger according to an embodiment of the invention, and 2 is a view of a vent path and damper assembly in the air conditioning system with an integrated heat exchanger 1 .

3 is a view of air flow analysis results for explaining the effects of the invention.

4 is a view of flaps of the flap unit and a cam in the air conditioner with an integrated heat exchanger according to an embodiment of the invention, 5 is a view of a first flap for explaining the flap unit according to the invention, 6 is a view of a connection structure of an air conditioning case and the first flap for explaining the flap unit according to the invention, and 7 is a view of a connection structure of the cam and the first flap for explaining the flap unit according to the invention.

8th is a view of the interior cooling by the air conditioning system with an integrated heat exchanger according to the invention, 9 is a view of the interior cooling by the air conditioning system with an integrated heat exchanger according to the invention, 10 is a view of defrosting by the air conditioner with an integrated heat exchanger according to the invention, and 11 is a view of a dual stage through the air conditioning system with an integrated heat exchanger according to the invention.

12 is a view of an air conditioner with an integrated heat exchanger according to another embodiment of the invention.

Further is 13 a circuit diagram of an air conditioning system with the integrated heat exchanger according to the invention.

An air conditioning system with an integrated heat exchanger according to the invention, as in the 1 and 2 shown, has an interior heat exchanger 200, which is arranged in an air conditioning housing 100 and generates heating air or cooling air by selectively passing through cooling water for heating or cooling water for cooling, and a heater 300, which is arranged at a distance from the interior heat exchanger 200 in the air conditioning housing 100 and optionally dissipates heat.

In one embodiment of the invention, the interior heat exchanger 200 and the heater 300 are arranged in the air conditioning housing 100.

In this configuration, the cooling water for heating and the cooling water for cooling selectively flow through the indoor heat exchanger 200, making it possible to provide conditioned air corresponding to a required indoor temperature through the indoor heat exchanger 200. In other words, the temperature of the cooling water flowing through the indoor heat exchanger 200 can be managed by heat exchange with another heat exchange medium. In one embodiment of the invention, the cooling water and a refrigerant can exchange heat with each other so that the temperature of the cooling water is adjusted. For example, the cooling water flowing through the indoor heat exchanger 200 may be heated by heat exchanging with a high-temperature refrigerant using a condenser 12 and then flow through the indoor heat exchanger 200 as cooling water for heating, or may be cooled by heat exchanging with a low-temperature refrigerant using an evaporator 14 and then passed through the indoor heat exchanger 200 Interior heat exchanger 200 flows through as cooling water for cooling.

Therefore, heating air or cooling air is generated by the cooling water for heating and the cooling water for cooling selectively flowing through the indoor heat exchanger 200, so that it is possible to adjust the temperature of the conditioned air without a special temperature adjustment door.

In one embodiment, the heater 300 is arranged in the air conditioning housing 100 at a distance from the interior heat exchanger 200. The heater 300 may be a PTC (Positive Temperature Coefficient) heater for additional heating when the indoor heat exchanger 200 alone is insufficient for heating.

Specifically, according to the invention, a vent path 101 is formed around the heater 300, and a door unit 400 that opens or closes the vent path 101 is installed in the air conditioning case 100.

Since the vent path 101 is formed around the heater 300 in the air conditioning case 100, a part of the air passed through the indoor heat exchanger 200 bypasses the heater 300 via the vent path 101, so that a flow rate of the air is ensured.

Further, the damper unit 400 that opens or closes the vent path 101 is installed in the air conditioning case 100, and the air flowing through the vent path 101 can be passed or blocked, and a flow direction of the air can be changed depending on the opening and closing position of the damper unit 400 can be changed.

The door unit 400 may include a panel-shaped door adapted to close the vent path 101, and the door may be fully opened or closed depending on the rotational position of the door. Further, when the door is positioned to open only a portion of the vent path 101, the door is positioned at an angle in the vent path 101 so that the Air passing through the ventilation path 101 is guided to the heater 300 by means of the flap, whereby the air can be mixed with the air that has passed through the heater 300.

Therefore, according to the invention, it is possible to improve air conditioning efficiency by optimizing it for each of air conditioning modes by adjusting the flow rate of air passing through the vent path 101 by means of the damper unit 400 according to the indoor air conditioning modes.

The present invention having the above-described configuration will be described in detail. The interior heat exchanger 200 and the heater 300 each have an upper and a lower section. Specifically, the upper portions of the indoor heat exchanger 200 and the heater 300 are disposed close to each other and the lower portions are disposed far away from each other so that the indoor heat exchanger 200 and the heater 300 can form an inverted V shape.

Since the indoor heat exchanger 200 and the heater 300 are arranged at an angle in this manner, when condensation is generated in the indoor heat exchanger 200, the condensation is easily discharged and distributed, and the heater 300 is free from being influenced by that in the indoor heat exchanger 200 generated condensation, which ensures the stability of high-voltage parts.

Further, the resistance to air flow in the air conditioning case 100 is minimized by the arrangement of the indoor heat exchanger 200 and the heater 300, so that it is possible to ensure an air volume.

Accordingly, as can be seen from the in 3 As can be seen from the results of an air flow analysis shown, the flow resistance in the arrangement structure of the interior heat exchanger 200 and the heater 300 according to the invention is reduced compared to the prior art and a concept.

Furthermore, as can be seen from the following Table 1 according to the analysis result, the pressure values in the air conditioning case 100 decrease according to the air flow at the outlets just by comparing the concept with the embodiment of the invention. [Table 1] Analysis result mode Air volume to evaporator [m ³ /h] Integrated Heat Exchanger Specification Test [mmWS] concept Embodiment of the invention Ventilate 450 (+6.1) (+5.6) Floor 350 (-17.4) (-18.0) Defrost 350 (-14.0) (-14.5)

This analysis result was obtained in the state in which the same condition of air inflow, the same condition of the heater 300 and the same condition of the exhaust port resistance were satisfied.

In one embodiment, the vent path 101 may be formed to pass air at a flow rate of 25% or less of the air passed through the heater 300.

If the vent path 101 is set to pass air exceeding 25% of the flow rate of the air passed through the heater 300, the flow rate of the air passed through the heater 300 in interior heating decreases, so that the heating performance is deteriorated. Accordingly, the vent path 101 ensures that the flow rate of the air passing through the vent path 101 is set to 25% or less of the flow rate of the air passed through the heater 300, so that the heating performance is improved and the internal pressure of the air conditioning case 100 is improved by the improvement the air flow decreases.

Meanwhile, as in 1 shown, the vent path 101 is formed above the heater 300, and a bypass path 102 is formed below the heater 300 in the air conditioning housing 100, so that part of the Air that has passed through the interior heat exchanger 200 flows through the ventilation path 101 and the bypass path 102 without passing through the heater 300.

In other words, the air conditioning case 100 has a plurality of vents for discharging conditioned air to different positions in the interior, and the vents are distributed in the upper portion and the lower end of the air conditioning case 100. Accordingly, since the vent path 101 and the bypass path 102 are respectively formed above and below the heater 300 in the air conditioning case 100, the flow rate of the air flowing to the vents is ensured.

Further, since the vent path 101 and the bypass path 102 are formed around the heater 300 in the air conditioner case 100, the flow resistance due to the arrangement of the heater 300 in the air conditioner is eliminated. In other words, since a part of the air passing through the indoor heat exchanger 200 flows through the vent path 101 and the bypass path 102 without passing through the heater 300 in the air conditioning case 100, the pressure can be reduced and the flow in the air conditioning case 100 can be improved become.

According to this embodiment of the invention, the air conditioning housing 100 includes an air inlet 110 and a plurality of air outlets 120, the plurality of air outlets 120 includes at least one or more defrosting vents 121 and front vents 122, and the door unit 400 may include a first door 410 that controls opening and closing of the vent path 101, and a second flap 420 that adjusts the opening and closing of the front vent 122.

A third door 430 that adjusts the opening and closing of the defrosting vent 121 may be further disposed in the air conditioning case 100.

The second door 420 may be connected in a hinge structure depending on the position of the front vent 122, whereby the second door 420 may perform opening and closing by rotating in conjunction with the rotation of a cam 440.

The air flowing through the air inlet 110 in the air conditioning housing 100 flows to an interior via the air outlets 120. Specifically, the air outlets 120 may include the defrosting vent 121 and the front vent 122 so that the conditioned air is directed to various positions in an interior, and may further include a rear vent 123 described below. These vents can be added or can diverge so that air flows to different locations in an interior space.

In this configuration, the defrosting vent 121 and the front vent 122 are arranged in the upper portion in the air conditioning case 100 so that the air passed through the indoor heat exchanger 200 and the heater 300 and the air passed through the vent path 101 above the heater 300 go to the defrosting vent 121 and the front vent 122 flow while being mixed.

The air flowing in the air conditioning case 100 in this manner may selectively flow to the front vents 122 depending on the opening and closing positions of the second door 420, or may selectively flow to the defrosting vent 121 depending on the opening and closing positions of the third door 430 . Further, the air selectively flows through the vent path 101 depending on the opening and closing positions of the first door 410, making it possible to ensure optimal flow rates of air according to the indoor climate modes.

The third flap 430 may be included in the flap unit 400 or may be individually configured.

The flap unit 400 according to an embodiment of the invention will be described in detail. Like in the 4 until 7 shown, the first flap 410 and the second flap 420 are installed on the air conditioning housing 100 such that they are suitable for rotating about respective axes of rotation 401.

The flap unit 400 further includes the cam 440 having a plurality of guide slots 441 into which moving bolts 402 of the flaps are inserted, and changes the rotational positions of the flaps pen by means of the movement bolts 402, which respectively move along the guide slots 441, making it possible to adjust the opening and closing positions of the first flap 410 and the second flap 420 in conjunction with the rotation of the cam 440. The cam 440 can be rotated by an electric motor disposed in the air conditioning case 100, and the electric motor is controlled by a controller.

According to the invention as described above, the flap unit 400 includes the cam 440 and the flaps, and the opening and closing of the flaps are adjusted in conjunction with the cam 440.

Since the first flap 110 and the second flap 420 are arranged on the upper portion of the air conditioning case 100, the flaps can be arranged in the rotation range of the cam 440.

The first flap 410 and the second flap 420 each have the rotation axis 401 so that they are installed in the air conditioning case 100 such that they are capable of rotating around the rotation axes 401. The flaps each have the movement bolt 402 at one end thereof at a distance from the axis of rotation 401, so that the flaps are connected to the cam 440 via the movement bolts 402. In the present invention, the doors may be positioned in the air conditioning case 100, and the cam 440 may be positioned outside the air conditioning case 100, and a plurality of through holes 130 may be formed in the air conditioning case 100 so that the moving bolts 402 of the doors pass through the through holes 130 are arranged through. The cam 440 is designed such that it includes the areas of the movement bolts 402 of the flaps.

Accordingly, the moving bolts 402 of the flaps are inserted into the guide slots 441 of the cam 440, and when the cam 440 is rotated, the moving bolts 402 are moved along the paths of the guide slots 441, thereby adjusting the rotation positions of the flaps with the moving bolts 402 in conjunction with the movement can be set.

The guide slots 441 of the cam 440 extend in the rotation direction while curving inward and outward, and the shapes of the guide slots 441 are different so that the timings (i.e., times) of opening or closing the vent path 101 and the front Ventilation opening 122 can be set differently.

How out 4 As can be seen, the cam 440 has a plurality of guide slots 441 in which the moving bolts 402 of the flaps are respectively inserted, and the guide slot 441 curves inward and outward in the direction of rotation, so that when the cam 440 is rotated , the movement bolts 402 are moved by means of the slots 410, whereby the flaps can be rotated.

Specifically, since the extension shapes of the guide slots 441 of the cam 440 are different, the opening and closing time of the first door 410 and the second door 420 may be set differently according to the movement of the moving bolts 402 in the guide slots 441 when the cam 440 is rotated be. Accordingly, when the cam 440 is rotated, not only the first door 410 and the second door 420 may be set to be opened or closed simultaneously, but also one or more of the first door 410 and the second door 420 may be selectively opened opened or closed so that airflow can be optimized according to climate modes.

For example, according to one embodiment of the invention, during interior cooling, as in 8th As shown, cooling water for cooling passes through the indoor heat exchanger 200, and cooling air is generated in the air conditioning housing 100.

In this case, the damper unit 400 opens the first damper 410 and the second damper 420 by rotating the cam 440 so that the air flows through the vent path 101, thereby improving the air flow. Furthermore, the front ventilation opening 122 is opened so that the cooling air is led to an interior space.

When heating the interior, it circulates, as in 9 shown, cooling water for heating passes through the interior heat exchanger 200, and the heater 300 is operated so that heating air is generated in the air conditioning housing 100.

In this case, the damper unit 400 opens the first damper 410 and the second damper 420 by rotating the cam 440 so that the air flows through the vent path 101, thereby improving the air flow. Furthermore, the front ventilation opening 122 is opened so that the heating air is led to an interior space.

If a higher heater temperature is required, it is possible to close the first flap 410 so that all of the air that has passed through the interior heat exchanger 200 passes through the heater 300.

During this cooling or heating of the interior, the third flap 430 can be opened or closed depending on whether air flows to the defrosting side.

Meanwhile, when defrosting opens, as in 10 is shown, the flap unit 400 only partially closes the first flap 410 and closes the second flap 420 by rotating the cam 440. Furthermore, the third flap 430 is open.

Accordingly, the air passed through the indoor heat exchanger 200 and the heater 300 flows to the defrosting vent 121, and a flow rate of the air is ensured by the vent path 101 formed above the heater 300 so that the flow rate of the air required for defrosting , can be fulfilled. Since the first flap 410 is positioned so that it is only partially open, the air that has passed through the vent path 101 is guided downward by means of the first flap 410 and is mixed with the air that has passed through the heater 300, so that the air that has passed through the heater 300 is required for defrosting Conditioned air can be provided evenly.

Meanwhile, opens in a double stage to adjust the temperature of the conditioned air, as in 11 As shown, the flap unit 400 only partially opens the first flap 410 and opens the second flap 420 by rotating the cam 440. In this case, the third flap 430 can be closed or partially opened.

Accordingly, the temperature of the air is adjusted by the indoor heat exchanger 200 and the heater 300, and a flow rate of the air is ensured by the vent path 101 formed above the heater 300, so that the flow rate of the air to the front vent 122 and the defrosting vent 121 flowing air can be met. Further, since the first door 410 is positioned so that it is only partially opened, the air flow is guided so that the air passed through the vent path 101 and the air passed through the heater 300 are mixed, so that it is easy Adjust the temperature of the conditioned air.

In addition, at least one or more rear vents 123 are formed in the lower portion of the air conditioning case 100, and a rear door 450 may be installed in the rear vent 123.

The rear door 450 may include a fourth door 451 that allows air passed through the heater 300 to selectively flow to the rear vent 123 and a fifth door 452 that allows air passed through the cabin heat exchanger 200 to selectively flow through to flow through the bypass path 102 under the heater 300 to the rear vent 123 without passing through the heater 300.

Since the rear vent 123 is formed in the lower portion of the air conditioning case 100, the air passed through the indoor heat exchanger 200 and the heater 300 and the air passed through the bypass path 102 under the heater 300 flow to the rear vent 123 while being mixed.

Since the rear door 450 has the fourth door 451 and the fifth door 452, when cooling the interior, the cooling air that has passed through the interior heat exchanger 200 flows through the open fourth door 451 to an interior without passing through the heater 300, so that a flow rate of the to The air flowing into the rear room of the interior can be ensured.

Further, when heating the interior, the fourth door 451 is opened and the fifth door 452 is closed, whereby the air passed through the interior heat exchanger 200 and the heater 300 can flow to the rear space of the interior.

The fourth door 451 and the fifth door 452 may be individually operated by electric motors provided respectively, or the same structure as the above-described cam 440 may be used in the fourth door 451 and the fifth door 452, and the rotation positions thereof may be adjusted.

Meanwhile, according to another embodiment of the invention, a damper unit 400 may include an opening and closing damper 460 that is operated up and down in the vent path 101 to adjust the opening and closing of the vent path 101, and an actuator 470 that controls the position of the vent path 101 Opening and closing flap 460 controls.

As in 12 As shown, the door unit 400 may include the opening and closing door 460 and the actuator 470, and the opening and closing door 460 may be installed to move up and down in a straight line to thereby accommodate the vent path 101 selectively to open and close. The opening and closing flap 460 may be bent downward so that the air passed through the vent path 101 can be evenly mixed with the air passed through the heater 300.

Since the opening and closing door 460 is moved up and down in a straight line, the operational stability is ensured. The actuator 470, which controls the position of the opening and closing door 460, may be an electric motor or a solenoid, and may be configured to operate with another door by using the structure of the cam 440 described above.

Meanwhile, an air conditioning system using an integrated heat exchanger, as in 13 is shown, a refrigerant circuit 10 in which a refrigerant circulates and which has a compressor 11, a condenser 12, an expander 13 and an evaporator 14, a first cooling water circuit 20 in which cooling water circulates for heating, which exchanges heat with the condenser 12 of the Refrigerant circuit 10 exchanges, a second cooling water circuit 30, in which cooling water circulates for cooling, which exchanges heat with the evaporator 14 of the refrigerant circuit 10, and a valve module 40, to which the first cooling water circuit 20 and the second cooling water circuit 30 are connected and which the flow direction of the cooling water for heating or the cooling water for cooling changes. The air conditioning system further has an interior heat exchanger 200, which is arranged in an air conditioning housing 100, to which the first cooling water circuit 20 and the second cooling water circuit 30 are connected, and which receives the cooling water for heating or the cooling water for cooling and generates heating air or cooling air. In one embodiment, a heater 300, which is spaced from the interior heat exchanger 200 and selectively generates heat, is arranged in the air conditioning housing 100. In another embodiment, a vent path 101 is formed around the heater 300, and a damper unit 400 that adjusts opening and closing of the vent path 101 is disposed in the air conditioning case 100.

In another embodiment, the first cooling water circuit 20 has a first water pump 21 and an external heat exchanger 22, and the second cooling water circuit 30 has a second water pump 31. The outside heat exchanger 22 can be a radiator.

According to an embodiment of the invention, the compressor 11, the condenser 12, the expander 13 and the evaporator 14 are included in the refrigerant circuit 10, and a refrigerant sequentially circulates through the compressor 11, the condenser 12, the expander 13 and the evaporator 14.

A high-temperature and high-pressure refrigerant compressed by the compressor 11 flows into the condenser 12 in the refrigerant circuit 10, whereby the cooling water circulating in the first cooling water circuit 20 connected to the condenser 12 is heated by heat from the condenser 12 chilled. Accordingly, the first cooling water circuit 20 includes the condenser 12, and the cooling water exchanges heat with the refrigerant via the condenser 12 and circulates as cooling water for heating.

Further, in the refrigerant circuit 10, cooling water circulating in the second cooling water circuit 30 connected to the evaporator 14 is cooled via the evaporator 14 by an endothermic process. Accordingly, the second cooling water circuit 30 includes the evaporator 14, and cooling water exchanges heat with the refrigerant via the evaporator 14 and circulates as cooling water for cooling.

The cooling water flowing in the first cooling water circuit 20 and the second cooling water circuit 30 exchanges heat respectively via the condenser 12 and the evaporator 14, and the first cooling water circuit 20 and the second cooling water circuit 30 are connected to the indoor heat exchanger 200 which is in the air conditioning housing 100 is arranged so that the cooling water flows to the interior heat exchanger 200, whereby the cooling water exchanges heat with conditioned air via the interior heat exchanger 200. The first cooling water circuit 20 has the first water pump 21, whereby the cooling water circulates in the first cooling water circuit 20, and the second cooling water circuit 30 has the second water pump 31, whereby the cooling water circulates in the second cooling water circuit 30.

In particular, since the valve module 40 is connected to the first cooling water circuit 20 and the second cooling water circuit 30, cooling water for heating or cooling water for cooling flowing to the indoor heat exchanger 200 is selectively passed or blocked, whereby it can be determined whether heating air or cooling air is passing through the interior heat exchanger 200 is generated. The valve module 40, which is a multi-way valve, can be configured such that several four-way valves can be modularized.

Therefore, according to the present invention, the temperature of the cooling water circulating through the first cooling water circuit 20 and the second cooling water circuit 30 is adjusted by circulating the refrigerant in the refrigerant circuit 10. Further, since the cooling water flowing through the first cooling water circuit 20 and the second cooling water circuit 30 selectively flows to the indoor heat exchanger 200 through the valve module 40, conditioned air corresponding to a required indoor temperature can be provided by the indoor heat exchanger 200. Further, since the temperature of the cooling water is adjusted by circulating a refrigerant and heating air or cooling air in the air conditioning case 100 is generated by the cooling water, the configuration of the refrigerant cycle 10 is simplified and the accommodation for the refrigerant circulation is reduced. Further, the different temperature cooling water circulating through the first cooling water circuit 20 and the second cooling water circuit 30 flows into an indoor heat exchanger 200 and adjusts the temperature of the conditioned air, so that it is possible to selectively adjust the temperature of the conditioned air without a temperature adjustment door of cooling water through the valve module 40.

Accordingly, the cooling water is heated by the condenser 12 while being circulated in the first cooling water circuit 20 by the operation of the first water pump 21, and is cooled by the indoor heat exchanger 200, whereby the temperature of the cooling water can be managed. Further, in the second cooling water circuit 30, the cooling water may be cooled by the evaporator 14 while being circulated by the operation of the second water pump 31.

Furthermore, the cooling water in the first cooling water circuit 20 and the cooling water in the second cooling water circuit 30 can be selectively distributed through a plurality of distribution valves V. The distribution valves V can be arranged before and after the condenser 12 in the first cooling water circuit 20 and before and after the evaporator 14 in the second cooling water circuit 30, and the distribution valves V in the first cooling water circuit 20 and the distribution valves V in the second cooling water circuit 30 can be arranged via a distribution line L can be connected to each other. Accordingly, whether the distribution valves V in the first cooling water circuit 20 and the second cooling water circuit 30 are opened or closed, cooling water in the first cooling water circuit 20 and the second cooling water circuit 30 may circulate individually, or the cooling water circulating in the first cooling water circuit 20 and that in the second Cooling water circuit 30 circulating cooling water are distributed. Accordingly, it is easy to adjust the temperature of the cooling water to meet the temperatures required for indoor air conditioning, and it is possible to efficiently use the cooling water according to the environmental situation and the external environment.

Therefore, regarding the difference between the prior art and the present invention, in the prior art, a condenser for generating heating air and an evaporator for generating cooling water should be spaced apart from each other in an air conditioning case, and the condenser should be relatively downsized , so it is difficult to control the amount of heat for heating air ensure. However, in an embodiment of the invention, since a single indoor heat exchanger is arranged in the air conditioning case 100, the overall packaging of the air conditioning case 100 is reduced, and there is a temperature adjustment door, so that the number and weight of parts are reduced. Further, since the indoor heat exchanger 200 exchanges heat with air-conditioned air over the entire area thereof regardless of whether heating air or cooling air is generated, performance for both heating and cooling is ensured.

Meanwhile, the indoor heat exchanger 200 may include a first heat exchange part 210 connected to the first cooling water circuit 20 and dissipating heat through the cooling water for heating, and a second heat exchange part 220 connected to the second cooling water circuit 30 and absorbing heat through the cooling water for cooling .

In other words, the indoor heat exchanger 200 may have a first heat exchange part 210 and a second heat exchange part 220, and the second heat exchange part 220 through which the cooling water flows for cooling may be in front of the first heat exchange part 210 through which the cooling water flows for heating in the air flow direction. be arranged.

The first heat exchange part 210 and the second heat exchange part 220 may have the same area and may each have a plurality of tubes through which cooling water flows and fins connected to the tubes. In particular, when the first heat exchange part 210 and the second heat exchange part 220 are tubes, the corrosion resistance can be ensured by using a folded tube, and a plurality of fins can have the same fin pitch per decimeter (FPDM), where the FPDM is in the range of 108 to can be 125. The indoor heat exchanger 200, which is composed of the first heat exchange part 210 and the second heat exchange part 220, may be configured such that the cooling water flows at the same flow rate, the corrosion resistance is improved, the water resistance is reduced, and the generation of condensation is minimized.

According to the air conditioner with an integrated heat exchanger and the air conditioning system using an integrated heat exchanger configured in the above-described structures, since the heating air and the cooling air are generated by an integrated heat exchanger that enables heat exchange between cooling water and conditioned air, ensures cooling and heating efficiency.

Further, since the temperature of the cooling water circulated in the integrated heat exchanger is adjusted, there is no temperature adjustment door for adjusting the temperature of conditioned air, so that the number of parts is reduced.

Furthermore, since an integrated heat exchanger is used, the components are optimally arranged so that the overall accommodation is reduced in size.

Claims (15)

Air conditioning with an integrated heat exchanger, the air conditioning having: an indoor heat exchanger (200) arranged in an air conditioning housing (100) and configured to generate heating air or cooling air by selectively passing through a first cooling water for heating and a second cooling water for cooling, a heater (300) spaced from the indoor heat exchanger (200) in the air conditioning housing (100) and configured to selectively dissipate heat, a vent path (101) being formed around the heater (300), and a damper unit (400) configured to adjust opening and closing of the vent path (101) and installed in the air conditioning housing (100). Air conditioning after Claim 1 , wherein the indoor heat exchanger (200) and the heater (300) each have an upper section and a lower section, and the upper sections of the indoor heat exchanger (200) and the heater (300) are arranged close to each other and the lower sections are arranged far away from each other are arranged. Air conditioning after Claim 1 or 2 , wherein the vent path (101) is formed above the heater (300), and a bypass path (102) is formed below the heater (300) in the air conditioning housing (100). Air conditioning according to one of the Claims 1 until 3 , wherein the vent path (101) passes air at a flow rate of 25% or less of the air passed through the heater (300). Air conditioning according to one of the Claims 1 until 4 , wherein the air conditioning housing (100) has an air inlet (110) and a plurality of air outlets (120), and the plurality of air outlets (120) have a defrosting vent (121) and at least one front vent (122), and wherein the flap unit (400) has a first door (410) configured to adjust opening and closing of the vent path (101) and a second door (420) configured to adjust opening and closing of the at least one front vent (122). Air conditioning after Claim 5 , wherein the air conditioning housing (100) has a third door (430) configured to adjust the opening and closing of the defrosting vent (121). Air conditioning after Claim 5 or 6 , wherein the first flap (410) and the second flap (420) are installed in the air conditioning housing (100) and are configured to rotate about respective axes of rotation (401) and have respective movement bolts (402) at ends, and wherein the flap unit (400) further comprises a cam (440) with a plurality of guide slots (441) into which the movement bolts (402) are inserted and is configured to adjust rotational positions of the first flap (410) and the second flap ( 420) by means of the movement bolts (402), each of which moves along the plurality of guide slots (441). Air conditioning after Claim 7 , wherein the plurality of guide slots (441) of the cam (440) extend in a rotational direction while curving inwardly and outwardly and have different shapes so that the timing of opening or closing the vent path (101) and the at least one front ventilation opening (122) are set differently. Air conditioning according to one of the Claims 5 until 8th , wherein the air conditioning housing (100) has at least one rear vent (123) in a lower portion thereof, and a rear door (450) is installed in the at least one rear vent (123). Air conditioning after Claim 9 , wherein the rear door (450) comprises: a fourth door (451) configured to allow air passed through the heater (300) to selectively flow to the at least one rear vent (123), and one fifth flap (452) configured to allow air passed through the interior heat exchanger (200) to selectively flow through a bypass path (102) under the heater (300) to the at least one rear vent (123), without passing through the heater (300). Air conditioning according to one of the Claims 1 until 10 , wherein the flap unit (400) includes an opening and closing flap (460) configured to operate up and down in the vent path (101) to adjust the opening and closing of the vent path (101), and an actuator ( 470) configured to control a position of the opening and closing flap (460). Air conditioning system with an integrated heat exchanger, the air conditioning system having: a refrigerant circuit (10) in which a refrigerant circulates and which has a compressor (11), a condenser (12), an expander (13) and an evaporator (14). first cooling water circuit (20), in which a first cooling water circulates to exchange heat with the condenser (12) of the refrigerant circuit (10) for heating, a second cooling water circuit (30), in which a second cooling water circulates to exchange heat with the evaporator (14) of the refrigerant circuit (10) for cooling, a valve module (40) to which the first cooling water circuit (20) and the second cooling water circuit (30) are connected and which changes a flow direction of the first cooling water and the second cooling water, and an interior heat exchanger (200), which is arranged in an air conditioning housing (100), to which the first cooling water circuit (20) and the second cooling water circuit (30) are connected, and which receives the first cooling water for heating or the second cooling water for cooling and heating air or generates cooling air, wherein a heater (300) is arranged in the air conditioning housing (100), which is arranged at a distance from the interior heat exchanger (200) and is configured to selectively generate heat, a vent vent path (101) is formed around the heater (300), and a damper unit (400) configured to adjust the opening and closing of the vent path (101) is arranged. Air conditioning system according to, Claim 12 , wherein the indoor heat exchanger (200) has a first heat exchange part (210) connected to the first cooling water circuit (20) and configured to dissipate heat via the first cooling water for heating, and a second heat exchange part (220) connected to the second cooling water circuit (30) and is configured to absorb heat via the second cooling water for cooling. Air conditioning system Claim 12 or 13 , wherein the first cooling water circuit (20) has a first water pump (21), and the second cooling water circuit (30) has a second water pump (31). Air conditioning system according to one of the Claims 12 until 14 , wherein the first cooling water in the first cooling water circuit (20) and the second cooling water in the second cooling water circuit (30) are selectively divided by a plurality of distribution valves (V).

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