DE102012105804A1 - Condenser for a vehicle - Google Patents

Abstract

A vehicle condenser (100) is used in an air conditioner having an expansion valve (101), an evaporator (103) and a compressor (105) is provided and circulated between the compressor (105) and the expansion valve (101) Coolant supplied from a radiator (107) to condense refrigerant supplied from the compressor (105) by heat exchange between the coolant and the refrigerant. The condenser (100) may include a main heat-radiating portion (110) connected to the radiator (107) for circulating the coolant, and configured to circulate the refrigerant from the compressor (105) to the refrigerant condensing by heat exchange with the coolant, a header dryer section (130) formed integrally with the main heat-radiating section (110) for receiving the condensed refrigerant from the main heat-radiating section (110) and forming a gas-liquid Perform separation and moisture removal of the refrigerant; and a subcooling heat-radiating portion (140) which circulates the low-temperature, low-pressure gaseous refrigerant supplied from the evaporator (103), and which discharges the refrigerant supplied from the receiver-dryer portion (130) by heat exchange with the gaseous refrigerant Temperature and low pressure undercooled.

Description

CROSS-REFERENCE TO RELATED APPLICATION

The present application claims the priority of Korean Application No. 10-2011-0131299 , filed on Dec. 8, 2011, the entire contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

Field of the invention

The present invention relates to a condenser for a vehicle. More specifically, the present invention relates to a capacitor for a vehicle, which is of the stacked-plate type, in which a receiver dryer (collect collector-dryer, for short) is integrally molded, and which is of the water-cooled type a refrigerant is condensed using a refrigerant.

Description related technique

Typically, an air conditioning system for a vehicle maintains a cabin temperature independent of an outside temperature and generates a pleasant indoor climate.

Such an air conditioner includes a compressor that compresses a refrigerant, a condenser that condenses and liquefies the refrigerant that has been compressed by the compressor, an expansion valve that quickly expands the refrigerant condensed and liquefied by the condenser, and an evaporator which vaporizes the refrigerant expanded from the expansion valve and cools air by utilizing heat of vaporization supplied to the cabin in which the air conditioner is installed.

Here, the condenser cools the high-temperature / high-pressure compressed gaseous refrigerant by using outside air flowing into the running vehicle, and condenses it into low-temperature liquid refrigerant.

However, such a condenser is usually connected to a header with a header dryer provided for improving the condensation efficiency by gas-liquid separation and removal of moisture in the refrigerant.

An air-cooled condenser, which exchanges heat with the outside air, is predominantly used as a vehicle condenser. Since such an air-cooled condenser has pin-and-tube structures, the overall size of the condenser can be increased to improve the cooling performance. Therefore, it may be difficult to install the air-cooled condenser in a small engine compartment.

To solve this problem, a water-cooled condenser using refrigerant (eg, cooling water) as a refrigerant is applied to the vehicle.

However, compared with the air-cooled condenser, the water-cooled condenser has a lower refrigerant condensation temperature of about 5-15 ° C, and thus the difference between the condensation temperature and the ambient temperature is small. Therefore, the condensation efficiency may be deteriorated due to the small supercooling effect, and consequently, the cooling efficiency may also be deteriorated.

Moreover, the size of a radiator or the capacity of a cooling fan may be increased to increase the condensation efficiency or cooling efficiency of the water-cooled condenser for the vehicle. Therefore, cost and weight may increase and connections between the receiver dryer and the condenser may be complex.

The information disclosed in this Background section is only for the better understanding of the general background of the invention and therefore may contain information that does not represent the prior art that is already known to a person skilled in this country.

The information disclosed in this Background section is only for the better understanding of the general background of the invention and should not be taken as an indication or any suggestion that this information forms the prior art that is already known to a person skilled in the art.

BRIEF EXPLANATION OF THE INVENTION

Various aspects of the present invention provide a condenser for a vehicle that has advantages in that it is integrally formed with a collector-dryer and in which a plurality of plates are stacked.

According to the condenser for the vehicle, a dead volume of the receiver dryer can be minimized and the heat radiation area can be increased. Therefore, the cooling efficiency can be improved.

In addition, the condenser separates refrigerant into gaseous refrigerant and liquid refrigerant, and condenses the gaseous refrigerant and the liquid refrigerant by using a refrigerant, and cools the liquid refrigerant by using a refrigerant, and the condensed refrigerant is supercooled by heat exchange low temperature, low pressure gaseous refrigerant provided by an evaporator. Since additional components for supercooling the condensed refrigerant can be omitted, the number of components can be reduced, connections simplified and cost and weight reduced.

Various aspects of the present invention provide a condenser for a vehicle used in an air conditioner having an expansion valve, an evaporator, and a compressor provided between the compressor and the expansion valve and coolant supplied from a radiator. circulated to condense refrigerant supplied from the compressor by heat exchange between the refrigerant and the refrigerant.

The condenser may include a main heat-radiating portion formed by stacking a plurality of plates, which is connected to the radiator to circulate the coolant, and which is configured to be the refrigerant is supplied from the compressor to circulate to condense the refrigerant by heat exchange with the refrigerant and the refrigerant, a collector-dryer section or collector-dryer section (short: collector-dryer section), which integrally or is formed integrally with the main heat-radiating portion to receive the condensed refrigerant from the main heat-radiating portion and perform gas-liquid separation and moisture removal of the refrigerant, and which is connected to the main heat-radiating portion, and a subcooling Heat radiating section, which is integrally formed at a lower portion of the main heat-radiating portion, which circulates the low-temperature, low-pressure gaseous refrigerant supplied from the evaporator, and which supplies the refrigerant supplied from the header-dryer portion , Undercooled by heat exchange with the gaseous refrigerant of low temperature and low pressure.

The main heat-radiating portion may include a first refrigerant pipe and a first refrigerant channel assembly (short: first refrigerant pipe) formed in a middle portion of the main heat-radiating portion in a longitudinal direction, for example, wherein the refrigerant which is in an end portion of the main heat-radiating portion flows through the first refrigerant pipe, a gas-liquid separating portion which is formed at the other end portion of the main heat-radiating portion which is connected to the first refrigerant pipe and is configured, the refrigerant therein flows through the first refrigerant line to separate into gaseous refrigerant and liquid refrigerant, at least one second refrigerant pipe or a second refrigerant channel or a second refrigerant channel arrangement (in short: second refrigerant pipe), which over or o is formed above the first refrigerant pipe so that the light gaseous refrigerant separated in the gas-liquid separating portion flows therein, and at least one third refrigerant pipe and one third refrigerant channel assembly (short: third refrigerant pipe); which is formed below the first refrigerant piping so that the heavy liquid refrigerant separated in the gas-liquid separating portion flows therein.

The gas-liquid separating portion may be connected to the second and the third refrigerant piping of the second and third refrigerant pipings, respectively, which are close to an upper portion and a lower portion of the gas-liquid separating portion, and need not be connected to the other second and third refrigerant piping third refrigerant lines are connected by the plates or it is not necessary that it is.

The main heat-radiating portion may cause the coolant and the refrigerant to exchange heat with each other by means of a counterflow of the coolant and the refrigerant.

The main heat-radiating portion may further include a first connection passage (short: first connection passage) formed in an upper portion of the main heat-radiating portion to be connected to the second refrigerant passage, and a second one Connecting pipe or a second connecting channel (short: second connecting line), which is formed in a lower portion of the main heat-radiating portion to be connected to the third refrigerant pipe, wherein the main heat-radiating portion of the condensed refrigerant through the collector-dryer section first Connecting line and the second connecting line supplies.

The undercooling heat-radiating portion may cause the low-temperature and low-pressure gaseous refrigerant and the refrigerant supplied from the header-dryer section to exchange heat with each other by means of a counterflow of the low-temperature, low-pressure and refrigerant gaseous refrigerant.

The supercooling heat-radiating portion may be connected to the header-dryer portion through a third connection passage (short: third connection passage), the refrigerant at which gas-liquid separation and moisture removal are performed in the header-dryer section can flow through the third connection line into the sub-cooling heat-radiating section.

The sub-cooling heat-radiating portion may include a refrigerant pipe in which the refrigerant supplied from the header-dryer section through the third connection pipe flows, and a gaseous refrigerant pipe formed alternately with the refrigerant pipe, the gaseous refrigerant having low-temperature and low-pressure supplied from the evaporator flows in the gaseous refrigerant passage, the under-cooling heat-radiating portion being configured to heat the condensed refrigerant flowing in the refrigerant passage by heat exchange with the gaseous refrigerant contained in the refrigerant gas the line for gaseous refrigerant flows, subcooled.

A heat-insulating portion for avoiding heat exchange with and between the refrigerant flowing through the main heat-radiating portion and the subcooled refrigerant flowing through the under-cooling heat-radiating portion may be formed between the main heat-radiating portion and the sub-cooling heat-radiating portion.

The heat-insulating portion can easily receive nitrogen therein by a plurality of solder holes formed in the longitudinal direction thereof between the main heat-radiating portion and the sub-cooling heat-radiating portion in a case of welding.

The condenser may further include an upper cover and a lower cover, respectively, mounted on an upper surface and a lower surface of the main heat-radiating portion, the receiver-dryer portion, and the sub-cooling heat-radiating portion, respectively.

The upper cover may be provided with a coolant outlet formed at an end portion thereof and configured to discharge the coolant from the main heat-radiating portion, a coolant inlet formed at the other end portion thereof and connected to the radiator, for the coolant from the radiator and a refrigerant inlet formed at the end portion thereof and connected to the compressor to receive the refrigerant from the compressor.

The lower cover may be provided with a refrigerant outlet formed at the end portion thereof corresponding to the refrigerant inlet and connected to the expansion valve, a gaseous refrigerant inlet formed at the end portion thereof and connected to the refrigerant gas inlet Evaporator is connected, and a gaseous refrigerant outlet, which is formed at the other end portion thereof and connected to the compressor.

At one end portion, the plates forming the second refrigerant line may be bent to form a wall.

The third refrigerant line does not need to communicate directly with the refrigerant inlet through the top plate of the plates forming the third refrigerant line.

The collector-dryer section may be provided with a space formed therein, and an insertion hole may be formed on the lower cover corresponding to the space.

A desiccant may be introduced into the space through the insertion hole.

A fixing cap for preventing escape of the desiccant introduced into the space and preventing leakage of the refrigerant supplied to the header-dryer section may be mounted on the insertion hole.

The radiator may be connected to a reserve tank, and a cooling fan may be provided at a rear portion of the radiator.

The condenser may further comprise a heat exchanger formed by stacking a plurality of plates.

The methods and apparatus of the present invention have other features and advantages, which will be apparent from the accompanying drawings, or more particularly. Together with the "Detailed Description", they serve to explain certain principles of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

1 FIG. 12 is a schematic view of an exemplary air conditioning system of a vehicle having an exemplary condenser according to the present invention. FIG.

2 FIG. 13 is a perspective view of an exemplary condenser for a vehicle according to the present invention. FIG.

3 is a cross-sectional view along a line AA in 2 ,

4 is a cross-sectional view taken along a line BB in FIG 2 ,

DETAILED DESCRIPTION

Reference will now be made in detail to various embodiments of the present invention. Examples are explained by the attached drawings and the text below. Although the invention will be described in conjunction with exemplary embodiments, it is in no way limiting the invention to the embodiments. But the invention is intended to cover various alternatives, modifications, equivalents, and other embodiments, other than the embodiments given as an example, to the extent that they are within the scope of the claims.

Exemplary embodiments and drawings disclosed in this specification are only a few exemplary embodiments of the present invention and do not represent the full scope of the present invention. Thus, it should be understood that various correspondences and modifications may exist at the time of filing of the present invention.

1 Fig. 10 is a schematic view of an air conditioner of a vehicle to which a condenser according to various embodiments of the present invention is applied; 2 FIG. 12 is a perspective view of a vehicle's capacitor according to various embodiments of the present invention; FIG. 3 is a cross-sectional view along a line AA in 2 ; and 4 is a cross-sectional view taken along a line BB in FIG 2 ,

Referring to the figures, a capacitor is used 100 for a vehicle according to various embodiments of the present invention in an air conditioning system, comprising: an expansion valve 101 for expanding a liquid refrigerant, an evaporator 103 for vaporizing the refrigerant coming from the expansion valve 101 was expanded by heat exchange with air, as well as a compressor 105 for receiving a gaseous refrigerant from the evaporator 103 and to compact it.

That means the capacitor 100 between the compressor 105 and the expansion valve 101 is provided and configured to a coolant, which from a radiator 107 is supplied, circulates and the refrigerant, which from the compressor 105 is supplied condensed by heat exchange with the refrigerant.

The cooler 107 is with a reserve tank 108 connected, and a cooling fan 109 is at a rear section of the radiator 107 intended.

According to various embodiments of the present invention is in the capacitor 100 for the vehicle, a receiver dryer is integrally formed, and a plurality of plates are stacked. The capacitor 100 for the vehicle, the refrigerant separates into gaseous and liquid refrigerants and condenses the refrigerant using the refrigerant, and it cools the condensed refrigerant by heat exchange with low-temperature, low-pressure gaseous refrigerant discharged from the evaporator 103 is provided or supplied. Since additional components for subcooling the condensed refrigerant can be omitted, the number of components can be reduced, connections can be simplified, and costs and weight can be reduced. Moreover, because a dead volume of the receiver dryer can be minimized and the heat radiation area can be increased, a cooling efficiency according to the condenser 100 be improved for the vehicle.

As in 2 to 4 shows, for these purposes, the capacitor 100 for the vehicle according to various embodiments of the present invention, a main heat radiating portion 110 , a collector-dryer section 130 and a sub-cooling heat-radiating portion 140 each component being described in detail.

Here are a top cover 111 and a lower cover 113 at an upper and a lower portion of the capacitor 100 for the Vehicle mounted, the main heat radiating section 110 , the collector-dryer section 130 and the subcooling heat-radiating portion 140 between the upper and the lower cover 111 and 113 are arranged.

The main heat-radiating section 110 is formed by a plurality of plates 115 stacked or arranged one above the other.

The main heat-radiating section 110 is with the radiator 107 connected to circulate the coolant, and circulates that of the compressor 105 supplied refrigerant to condense the refrigerant by heat exchange with the refrigerant.

Here, the main heat-radiating portion 110 designed such that it performs a heat exchange by a countercurrent of the coolant and the refrigerant.

That means the majority of mats 115 in the main heat-radiating portion 110 is stacked, and refrigerant piping 117 and coolant lines 119 alternately between the plurality of plates 115 are formed. Because the refrigerant through the refrigerant pipe 117 flows and the coolant through the coolant line 119 flows, the refrigerant and the refrigerant are not mixed with each other, and they flow in opposite directions, as in 3 and 4 is shown. In this process, a heat exchange between refrigerant and coolant occurs.

As in 3 shown, the main heat-radiating portion 110 a first refrigerant line 117a , a second refrigerant line 117b , a third refrigerant line 117c and a gas-liquid separation section 118 on.

The majority of the first refrigerant pipelines 117a is in a central portion in the main heat-radiating portion 110 formed in the longitudinal direction. The refrigerant, which is an end portion of the main heat radiating portion 110 is supplied, flows into the first refrigerant line 117a ,

The gas-liquid separation section 118 is at the other end portion in the main heat-radiating portion 110 trained and with the first refrigerant line 117a connected. The gas-liquid separation section 118 is designed so that it contains the refrigerant which is in the first refrigerant line 117a flows, by gravity or gravity into the gaseous refrigerant and the liquid refrigerant separates.

When the refrigerant in which the gaseous refrigerant and the liquid refrigerant are mixed, into the gas-liquid separation section 118 flows in, the gas-liquid separation section separates 118 The refrigerant into the gaseous refrigerant and the liquid refrigerant by the difference in gravity between the gaseous refrigerant and the liquid refrigerant, At this time, the light gaseous refrigerant in an upper portion of the gas-liquid separating portion 118 disposed, and the heavy liquid refrigerant is in a lower portion of the gas-liquid separation section 118 arranged.

According to various embodiments, a plurality of the second refrigerant lines 117b above or above the first refrigerant line 117a arranged. The light gaseous refrigerant which is in the gas-liquid separation section 118 is separated, flows into the second refrigerant line 117b ,

The second refrigerant line 117b is configured so that when the gaseous refrigerant which is in the gas-liquid separation section 118 was separated, flows therein, performs a heat exchange between the gaseous refrigerant and the refrigerant to condense the gaseous refrigerant again.

In addition, a plurality of third refrigerant lines 117c below or below the first refrigerant line 117a educated. The heavy liquid refrigerant which is in the gas-liquid separation section 118 is separated, flows in the third refrigerant line 117c ,

The third refrigerant line 117c is configured so that when the liquid refrigerant, which in the gas-liquid separation section 118 was separated, flows therein, performs a heat exchange between the liquid refrigerant and the refrigerant to condense the liquid refrigerant.

Here, the gas-liquid separation section 118 with the respective second or third refrigerant line 117b and 117c from the plurality of second refrigerant lines 117b and third refrigerant lines 117c connected near the upper and lower portions of the gas-liquid separation portion, respectively 118 is not using other second and third refrigerant lines 117b and 117c through the plates 115 connected is.

That means the plates 115 are configured such that they the upper and the lower portion of the gas-liquid separation section 118 so close or close that the gaseous refrigerant and the liquid refrigerant do not enter the second and third refrigerant lines 117b and 117c flows in, except for the second or the third refrigerant line 117b respectively. 117c , which close to the upper and the lower portion of the gas-liquid separation section 118 is.

According to various embodiments, a coolant outlet 123 at an end portion of the top cover 111 formed, and a coolant inlet 121 is at the other end portion of the top cover 111 educated. The coolant inlet 121 and the coolant outlet 123 are with the main heat-radiating section 110 connected. Therefore, the coolant becomes the main heat-radiating portion 110 from the radiator 107 through the coolant inlet 121 supplied, and the coolant, which through the main heat-radiating portion 110 flows from the main heat-radiating portion 110 through the coolant outlet 123 issued.

In addition, there is a refrigerant inlet 125 through which the refrigerant from the compressor 105 is supplied to the end portion of the upper cover 111 educated.

Because so the refrigerant inlet 125 at a coolant inlet 121 is formed opposite side and on the same side as the coolant outlet 123 is formed, flow according to various embodiments, the coolant and the refrigerant in opposite directions.

Here is an end portion of each plate 115 , which is the second refrigerant line 117b trains, so bent that they have a wall 122 forms. The end section of each plate 115 is an end portion which is near the refrigerant inlet 125 is arranged.

The wall 122 is designed so that it through the refrigerant inlet 125 supplied refrigerant prevents, in the in an upper portion of the main heat radiating portion 110 trained second refrigerant line 117b flow into.

In addition, the third refrigerant line 117c not directly with the refrigerant inlet through the top plate 115 from the plates 115 , which is the third refrigerant line 117c training, communicating or not communicating with him.

That through the refrigerant inlet 125 supplied refrigerant is thereby prevented, directly into the third refrigerant line 117c through the top plate 115 from the plates 115 , which is the third refrigerant line 117c form, infuse, and flow into the first refrigerant line 117a into it.

According to various embodiments, the collector-dryer section 130 configured to receive the condensed refrigerant from the main heat-radiating portion 110 and performs a gas-liquid separation of the refrigerant and a moisture removal thereon. The collector-dryer section 130 is integral with the other end of the main heat-radiating portion 110 is formed and is connected to the main heat radiating portion 110 connected.

The refrigerant contained in the main heat-radiating portion 110 flows in the gas-liquid separation section 118 separated into the gaseous refrigerant and the liquid refrigerant, wherein the gaseous refrigerant and the liquid refrigerant through the second and the third refrigerant line 117b respectively. 117c flow to exchange heat with the coolant and to be condensed.

Thereafter, the condensed refrigerant is sent to the header-dryer section 130 delivered by a first connection line 126 , which in the upper portion of the main heat radiating portion 110 trained and with the second refrigerant line 117b is connected, and a second connection line 127 , which in the lower portion of the main heat radiating portion 110 trained and with the third refrigerant line 117c connected is.

Since the collector-dryer section 130 used a collector-dryer, which has the same shape as the capacitor 100 For example, a dead volume thereof can be minimized as compared with a conventional cylindrical type collector dryer, and additional connecting pipes can be eliminated.

According to various embodiments, a room 131 in the collector-dryer section 130 formed, with an insertion hole 133 on the lower cover 113 according to the room 131 is trained.

A desiccant 135 is in the room 131 through the insertion hole 133 introduced and removes moisture from the main heat-radiating section 110 condensed refrigerant.

The desiccant 135 can through the insertion hole 133 replaced or replaced according to a replacement period. That means the desiccant 135 in the collector-dryer section 130 is mounted replaceably.

In this case, a filter is integral with the desiccant 135 formed, wherein the filter foreign substances or foreign materials, which in the collector Dryer section 130 supplied refrigerant are removed.

That means the collector-dryer section 130 the moisture remaining in the refrigerant through the desiccant 135 removed and filters the foreign matter contained in the refrigerant through the filter or filter out. Thereby, foreign matters remaining in the refrigerant are prevented from being introduced into the expansion valve 101 to flow into it.

Accordingly, foreign matter remaining in the refrigerant is prevented from the expansion valve 101 to block.

A mounting cap 137 to prevent the escape or escape into the room 131 introduced desiccant 135 and to prevent leakage of the collector-dryer section 130 supplied refrigerant is at the insertion hole 133 assembled.

In addition, the subcooling heat-radiating portion 140 integrally in a lower portion of the main heat-radiating portion 110 educated.

That from the evaporator 103 supplied low-temperature, low-pressure gaseous refrigerant flows into the sub-cooling heat-radiating portion 140 , The low temperature, low pressure gaseous refrigerant passing through the subcooling heat radiating section 140 The refrigerant passes through the heat exchange with that from the receiver-dryer section 130 supplied refrigerant.

Here, the undercooling heat-radiating portion 140 is configured to heat exchange by means of a counterflow of the low-temperature and low-pressure gaseous refrigerant and the collector-dryer section 130 supplied refrigerant performs.

According to various embodiments, the undercooling heat-radiating portion 140 with the collector-dryer section 130 through a third connection line 128 connected. The undercooling heat-radiating section 140 is configured to receive the refrigerant on which gas-liquid separation and moisture removal has been performed from the header-dryer section 130 receives.

The refrigerant pipes 117 and wires 141 gaseous refrigerant are in the supercooling heat-radiating portion 140 alternately formed. That's why it flows from the collector-dryer section 130 to the subcooling heat-radiating section 140 through the third connection line 128 supplied refrigerant into the refrigerant line 117 , and that of the evaporator 103 supplied low-pressure, low-pressure gaseous refrigerant flows in the conduit 141 for gaseous refrigerant. In this process, heat exchange takes place between the condensed refrigerant and the gaseous refrigerant.

That means the majority of plates 115 in the subcooling heat-radiating portion 140 is stacked, with the refrigerant pipes 117 and the wires 141 for gaseous refrigerant between the plurality of plates 115 are formed. As the condensed refrigerant passing through the collector-dryer section 130 flows, in the refrigerant line 117 flows and the gaseous refrigerant with low temperature and low pressure in the line 141 for gaseous refrigerant, the condensed refrigerant and the low-temperature gaseous refrigerant flow at low pressure, as in FIG 3 and 4 shown in opposite directions. In this process, heat exchange takes place between the condensed refrigerant and the low temperature, low pressure gaseous refrigerant.

Herein is a refrigerant outlet 129 in an end portion of the lower cover 113 which is the refrigerant inlet 125 is assigned or corresponds, trained. The refrigerant outlet 129 is with the expansion valve 101 connected.

In addition, an inlet 143 for gaseous refrigerant in the end portion of the lower cover 113 trained, and an outlet 145 for gaseous refrigerant is at the other end portion of the lower cover 113 educated. The inlet 143 for gaseous refrigerant is with the evaporator 103 and the outlet 145 for gaseous refrigerant is connected to the compressor 105 connected.

Here is the collector-dryer section 130 integral with the other end of the main heat-radiating portion 110 and the sub-cooling heat-radiating portion 140 educated. The collector-dryer section 130 is not fluid with the main heat-radiating portion 110 and the subcooling heat-radiating portion 140 at positions except for the first and second and third connection lines 126 . 127 and 128 , connected. Therefore, the refrigerant can not enter the collector-dryer section 130 by other positions than the first, second and third connection lines 126 . 127 and 128 flow into.

According to various embodiments, a heat-insulating section 150 for preventing heat exchange between that in the main heat-radiating portion 110 flowing refrigerant and the undercooling Wärmeabstrahlabschnitt 140 flowing supercooled refrigerant between the main heat-radiating portion 110 and the subcooling heat-radiating portion 140 educated.

The heat-insulating section 150 may be configured to easily receive nitrogen through a plurality of solder holes 151 which during the stacking of the plurality of plates 115 be formed in a case of welding.

The solder holes 151 are designed to reduce a scrap rate in welding and the number of inferior welds, by gas, which occurs when the plurality of plates 115 is stacked, is allowed to flow out and nitrogen in the heat-insulating section 150 easy to introduce.

The solder holes 151 are closed after the nitrogen for forming the heat-insulating portion 150 is introduced.

As mentioned above, a capacitor 100 According to various embodiments of the present invention, a heat exchanger in which a plurality of plates 115 stacked on top of each other.

That in the cooler 107 cooled coolant flows into the main heat-radiating portion 110 through the coolant inlet 121 ,

The coolant circulates along the coolant lines 119 which is between the plurality of plates 115 in the main heat-radiating portion 110 are formed. Thereafter, the coolant from the condenser 100 through the coolant outlet 123 spent and the cooler 107 fed again.

At this time, the refrigerant from the compressor 105 the main heat-radiating portion 110 through the refrigerant inlet 125 supplied and flows to the gas-liquid separation section 118 along the first refrigerant line 117a from the refrigerant pipes 117 alternating with the coolant lines 119 are formed.

The refrigerant is in the gas-liquid separation section 118 in the gaseous refrigerant and the liquid refrigerant separated, wherein the gaseous refrigerant and the liquid refrigerant in the second refrigerant pipe 117b or the third refrigerant line 117c flow and exchange heat with the coolant.

At this time, the gaseous refrigerant and the liquid refrigerant flowing in the gas-liquid separation section flow 117 were separated, in a along the coolant lines 119 flowing coolant opposite direction and exchange heat with the coolant.

In addition, this flows in the main heat-radiating portion 110 cooled condensed refrigerant through the first connection line 126 and the second connection line 127 to the collector-dryer section 130 ,

The condensed refrigerant circulates in the header-dryer section 130 , At this time, gas-liquid separation is performed, and the moisture in the refrigerant is passed through the desiccant 135 away. Thereafter, the condensed refrigerant flows through the third connection line 128 to the subcooling heat-radiating portion 140 ,

The refrigerant entering the subcooling heat-radiating section 140 flows, circulates along the refrigerant line 117 in the subcooling heat-radiating portion 140 ,

At this time, it flows from the evaporator 103 supplied low-temperature, low-pressure gaseous refrigerant into the sub-cooling heat-radiating portion 140 through the inlet 143 for gaseous refrigerant.

The into the subcooling heat-radiating section 140 incoming gaseous refrigerant flows along the line 141 for gaseous refrigerant in one along the refrigerant line 117 flowing refrigerant opposite direction.

That through the main heat-radiating section 110 and the collector-dryer section 130 flowing refrigerant is therefore by heat exchange with the in the sub-cooling heat-radiating section 140 subcooled in flowing gaseous refrigerant.

This means that the refrigerant entering the subcooling heat-radiating section 140 flows in, flows in the opposite direction of the gaseous refrigerant and is subcooled by heat exchange with the gaseous refrigerant. Thereafter, the supercooled refrigerant becomes the expansion valve 101 through the refrigerant outlet 129 fed.

Meanwhile, the gaseous refrigerant entering the undercooling heat-radiating section 140 through the inlet 143 for gaseous refrigerant flows in, after a heat exchange with the along the refrigerant line 117 flowing refrigerant, the compressor 105 through the outlet 145 supplied for gaseous refrigerant.

Since the collector-dryer section 130 integral with the main heat-radiating portion 110 and the subcooling heat-radiating portion 140 is formed, additional connecting pipes for connecting the collector-dryer section 130 with the main heat-radiating portion 110 and the subcooling heat-radiating portion 140 removed or omitted. Because beyond that, a Collector Dryer section Collector Dryer 130 has the same shape as the capacitor 100 , dead volume can be minimized.

In addition, the heat insulating portion prevents 150 a heat exchange between the main heat-radiating portion 110 and the subcooling heat-radiating portion 140 , Therefore, capacitor efficiency and cooling efficiency of the capacitor 100 be improved.

It is exemplified, but not limited to, that the main heat-radiating portion 110 , the collector-dryer section 130 and the subcooling heat-radiating portion 140 by stacking the plurality of plates 115 between the upper and the lower cover 111 and 113 are formed. The majority of plates 115 without the top and bottom covers 111 and 113 can the main heat-radiating section 110 , the collector-dryer section, and the sub-cooling heat-radiating section 140 form.

The capacitor 100 The vehicle according to various embodiments of the present invention is formed integrally with the receiver dryer, is formed by stacking the plurality of plates, and is configured to separate the refrigerant into the gaseous refrigerant and the liquid refrigerant and the gaseous refrigerant and the refrigerant liquid refrigerant condenses. In addition, the capacitor 100 designed so that it condenses the refrigerant by heat exchange with that of the evaporator 103 supplied low-temperature and low-pressure refrigerant separates. Therefore, the number of components can be reduced and the connections between them can be simplified. In addition, costs and weight can be reduced.

Since that at the main heat-radiating section 110 condensed refrigerant by heat exchange with the low-temperature, low-pressure gaseous refrigerant in the sub-cooling heat-radiating portion 140 can be supercooled, additional components or pipes, which are necessary for a subcooling of the refrigerant removed or omitted. Therefore, no additional costs need to be consumed or charged.

The capacitor 100 separates this in the main heat-radiating section 110 flowing refrigerant in the gas-liquid separation section 118 in the gaseous refrigerant and the liquid refrigerant. The gaseous refrigerant and the liquid refrigerant exchange heat with the refrigerant and are condensed. Thereby, a heat exchange efficiency can be improved.

Because the collector-dryer is integral with heat-radiating sections 110 and 140 is formed, a dead volume in the capacitor 100 be reduced. Therefore, a heat radiation surface of the condenser 100 increases and condensing efficiency and cooling efficiency can be improved without the size of the capacitor 100 to enlarge. This can improve the marketability.

In order to simplify the explanation and to provide a thorough definition in the appended claims, the terms "higher" or "lower", "front" or "rear", "inner" or "outer" etc. are used to refer to elements of the exemplary embodiments Designating with respect to the positioning of these elements as shown in the drawings.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• KR 10-2011-0131299 [0001]

Claims (19)

A capacitor ( 100 ) for a vehicle which is used in an air conditioner, which is an expansion valve ( 101 ), an evaporator ( 103 ) and a compressor ( 105 ) is between the compressor ( 105 ) and the expansion valve ( 101 ) and circulates coolant, which from a cooler ( 107 ) is supplied to refrigerant, which from the compressor ( 105 ) is condensed by heat exchange between the refrigerant and the refrigerant, wherein the condenser ( 100 ): a main heat-radiating portion ( 110 ) comprising a plurality of stacked plates ( 115 ), which with the radiator ( 107 ) is connected to circulate the coolant, and which is configured, the refrigerant, which from the compressor ( 105 ) is circulated to condense the refrigerant by heat exchange with the refrigerant and the refrigerant, a header-dryer section ( 130 ) integral with the main heat-radiating portion (FIG. 110 ) is formed to remove the condensed refrigerant from the main heat-radiating portion (14). 110 ) and gas-liquid separation and moisture removal of the refrigerant, and which with the main heat-radiating portion (FIG. 110 ) connected is; and a subcooling heat-radiating portion (FIG. 140 ) integrally formed at a lower portion of the main heat-radiating portion (FIG. 110 ) formed by the evaporator ( 103 ) supplied low-temperature and low-pressure gaseous refrigerant, and which of the collector-dryer section ( 130 ) subcooled refrigerant supplied by heat exchange with the gaseous refrigerant of low temperature and low pressure; wherein the main heat-radiating portion (FIG. 110 ) comprises: a first refrigerant line ( 117a ), which in a central portion of the main heat radiating portion (FIG. 110 is formed in a longitudinal direction, wherein the refrigerant, which in an end portion of the main heat radiating portion ( 110 ), through the first refrigerant line ( 117a ) flows; a gas-liquid separation section ( 118 ), which at the other end portion of the main heat-radiating portion (FIG. 110 ), which with the first refrigerant line ( 117a ), is formed and is configured, the refrigerant which is therein by the first refrigerant line ( 117a ) flows to separate into gaseous refrigerant and liquid refrigerant; at least one second refrigerant line ( 117b ), which are above the first refrigerant line ( 117a ) is formed, so that the light gaseous refrigerant, which in the gas-liquid separation section ( 118 ) was separated, flows therein; and at least one third refrigerant line ( 117c ), which are below the first refrigerant line ( 117a ) is formed so that the heavy liquid refrigerant, which in the gas-liquid separation section ( 118 ) was separated, flows therein. The capacitor ( 100 ) according to claim 1, wherein the gas-liquid separation section ( 118 ) each with the second and the third refrigerant line ( 117b and 117c )) of the second and third refrigerant lines ( 117b and 117c ) connected near an upper portion and a lower portion of the gas-liquid separation portion (FIG. 118 ), and not with the other second and third refrigerant lines ( 117b and 117c ) through the plates ( 115 ) connected is. The capacitor ( 100 ) according to claim 1 or 2, wherein the main heat-radiating portion (FIG. 110 ) causes the coolant and the refrigerant to exchange heat with each other by means of a counterflow of the coolant and the refrigerant. The capacitor ( 100 ) according to one of the preceding claims, wherein the main heat-radiating portion ( 110 ) furthermore has a first connection line ( 126 ), which in an upper portion of the main heat-radiating portion (FIG. 110 ) is configured to communicate with the second refrigerant line ( 117b ) and a second connection line ( 127 ) disposed in a lower portion of the main heat-radiating portion (FIG. 110 ) is designed to communicate with the third refrigerant line ( 117c ), and wherein the main heat-radiating portion (FIG. 110 ) the condensed refrigerant to the collector-dryer section ( 130 ) through the first connection line ( 126 ) and the second connection line ( 127 ) feeds. The capacitor ( 100 ) according to one of the preceding claims, wherein the undercooling heat-radiating section ( 140 ) causes the gaseous low-temperature, low-pressure refrigerant and the refrigerant discharged from the header-dryer section (FIG. 130 ), heat exchange with each other by means of a counterflow of the low-temperature and low-pressure gaseous refrigerant and the refrigerant. The capacitor ( 100 ) according to one of the preceding claims, wherein the undercooling heat-radiating section ( 140 ) with the collector-dryer section ( 130 ) by a third connecting line ( 128 the refrigerant at which gas-liquid separation and moisture removal in the header dryer section (FIG. 130 ), by the third Connection line ( 128 ) into the sub-cooling heat-radiating section ( 140 ) flows in. The capacitor ( 100 ) according to claim 6, wherein the supercooling heat-radiating portion (FIG. 140 ) comprises: a refrigerant line ( 117 ), in which the refrigerant, which from the collector-dryer section ( 130 ) through the third connection line ( 128 ) is supplied, flows; and a line ( 141 ) for gaseous refrigerant, which alternately with the refrigerant line ( 117 ), wherein the low-temperature, low-pressure gaseous refrigerant discharged from the evaporator ( 103 ), in the line ( 141 ) flows for gaseous refrigerant; and wherein the subcooling heat-radiating portion ( 140 ) is configured so that it the condensed refrigerant, which in the refrigerant line ( 117 ) flows, by heat exchange with the gaseous refrigerant, which in the line ( 141 ) flows for gaseous refrigerant, undercooled. The capacitor ( 100 ) according to one of the preceding claims, wherein a heat-insulating section ( 150 ) for avoiding heat exchange between the refrigerant flowing through the main heat-radiating portion (14) 110 ), and the supercooled refrigerant passing through the subcooling heat-radiating section (FIG. 140 ) flows between the main heat-radiating portion (FIG. 110 ) and the sub-cooling heat-radiating section (FIG. 140 ) is trained. The capacitor ( 100 ) according to claim 8, wherein the heat-insulating portion ( 150 ) Receives nitrogen easily through a plurality of solder holes ( 151 ) longitudinally thereof between the main heat-radiating portion (FIG. 110 ) and the sub-cooling heat-radiating section (FIG. 140 ) are formed in a case of welding. The capacitor ( 100 ) according to one of the preceding claims, further comprising a top cover ( 111 ) or a lower cover ( 113 ), which on an upper surface or a lower surface of the main Wärmeabstrehlabschnitts ( 110 ), the collector-dryer section ( 130 ) and the sub-cooling heat-radiating section (FIG. 140 ) are mounted. The capacitor ( 100 ) according to claim 10, wherein the top cover ( 111 ) is provided with a coolant outlet ( 123 ) formed on an end portion thereof and configured to discharge the coolant from the main heat-radiating portion (FIG. 110 ), a coolant inlet ( 121 ) which is formed at the other end portion thereof and connected to the radiator ( 107 ) is connected to the coolant from the radiator ( 107 ) and a refrigerant inlet ( 125 ) formed at the end portion thereof and connected to the compressor ( 105 ) is connected to the refrigerant from the compressor ( 105 ). The capacitor ( 100 ) according to claim 10 or 11, wherein the lower cover is provided with a refrigerant outlet ( 129 ) formed at the end portion thereof facing the refrigerant inlet (FIG. 125 ), and which with the expansion valve ( 101 ), an inlet ( 143 gaseous refrigerant formed at the end portion thereof and connected to the evaporator (FIG. 103 ) and an outlet ( 145 gaseous refrigerant formed at the other end portion thereof and connected to the compressor (FIG. 105 ) connected is. The capacitor ( 100 ) according to one of claims 10 to 12, wherein at one end portion the plates ( 115 ), which the second refrigerant line ( 117b ) are bent, so they have a wall ( 122 ) form. The capacitor ( 100 ) according to any one of claims 10 to 13, wherein the third refrigerant line ( 117c ) directly with the refrigerant inlet ( 125 ) through the top plate ( 115 ) from the plates ( 115 ), which the third refrigerant line ( 117c ) is in communication. The capacitor ( 100 ) according to one of the preceding claims, wherein the collector-dryer section ( 130 ) with a space formed therein ( 131 ), and an insertion hole ( 133 ) on the lower cover according to the room ( 131 ) is trained. The capacitor ( 100 ) according to claim 15, wherein a desiccant in the room ( 131 ) through the insertion hole ( 133 ) is introduced. The capacitor ( 100 ) according to claim 16, wherein a fixing cap ( 137 ) for preventing escape into the room ( 131 ) and to prevent leakage of the collector-dryer section ( 130 ) supplied refrigerant at the insertion hole ( 133 ) is mounted. The capacitor ( 100 ) according to one of the preceding claims, wherein the cooler ( 107 ) with a reserve tank ( 108 ), and a cooling fan ( 109 ) at a rear portion of the radiator ( 107 ) is provided. The capacitor ( 100 ) according to one of the preceding claims, wherein the capacitor ( 100 ) further comprises a heat exchanger, which by stacking a plurality of mats ( 115 ) is trained.

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