DE102014222373A1 - capacitor - Google Patents

Abstract

In a condenser (10), an inlet connector (12) to which a coolant is supplied is connected to a side wall of a first head (12). The inlet connector (22) is disposed near an upper end portion of the first head (12) and is connected to the side wall of the first head (12) by a sloped portion (32) inclined downward at a predetermined angle. Moreover, when the coolant is supplied from the inlet connector (22) to the inside of the first head (12), the coolant is supplied to an approximately central portion in the height direction of the first head (12) through the inclined portion (32). Therefore, the coolant can flow substantially uniformly with respect to a plurality of tubes (16) arranged in parallel in the height direction of the first head (12), and the heat exchange can be performed.

Description

The present invention relates to a condenser capable of heat exchange with a refrigerant by flowing the refrigerant through an inner part of the condenser while passing air through the condenser.

Conventionally, in an air conditioner disposed in a vehicle such as an automobile or the like, a condenser is used which provides heat exchange with coolant flowing through the interior of the condenser. The condenser is equipped with a pair of heads through which the coolant is introduced and a plurality of tubes connected between the heads. Moreover, the coolant supplied to one of the heads flows through each of the connected plural tubes separated at equal intervals from each other, and thereafter the coolant flows through the other head and is returned to the one head. In this way, there is a heat exchange between the coolant circulated through the tubes and the air flowing through fins disposed between the tubes to thereby cool the gaseous refrigerant to be liquefied.

In this condenser, generally, the refrigerant should flow uniformly with respect to the plural tubes, respectively, so that the heat exchange between the air and the refrigerant can be performed with maximum efficiency and an ideal output can be achieved. However, in practice, it is such that the coolant easily flows to the pipes near the inlet pipe connected to the head and to which the coolant is supplied, whereas the fluid hardly flows to the pipes at positions spaced from have the inlet pipe. Therefore, the flow amount of the refrigerant in the plural tubes is uneven, resulting in deviations (unevenness) in the heat exchange performance in the entire condenser.

To solve this problem, for example, in the capacitor of JP 2004-353936 A an alignment plate is disposed inside the head perpendicular with respect to the direction in which the inlet pipe and the tubes extend, and a plurality of communication holes communicating with the sides of the tubes are arranged in the alignment plate. The communication holes in the alignment plate are formed in a circular shape in the vicinity of the inlet pipe, and an elongated hole shape having a large opening area at regions away from the inlet pipe. In addition, when the refrigerant is supplied from the inlet pipe to the inside of the head, a direct flow of the refrigerant to the tubes in the vicinity of the inlet pipe is suppressed, and the refrigerant flows through the communication holes to the side of the tubes. Further, by making the opening cross sections of the communication holes different, a larger amount of the coolant easily flows to the pipes spaced from the inlet pipe, and therefore, the coolant flows substantially uniformly with respect to the plural pipes.

Furthermore, in the capacitor JP 06-074609A a forked branch portion is provided on the inlet pipe connected to the head. By connecting the branch portion with respect to the head without disposing an alignment plate inside the head, the supply positions for the coolant are distributed along the vertical direction of the head, whereby the flow amount of the coolant supplied to the plurality of tubes can be made substantially uniform.

The object of the present invention is to provide a condenser in which it is possible with a simple structure to circulate the refrigerant uniformly with respect to a plurality of tubes and uniformly carry out heat exchange without increasing the flow resistance for the refrigerant through the To cause pipes.

The condenser according to the present invention has a pair of heads interposed with an interval therebetween and containing spaces into which coolant is introduced, a plurality of tubes extending in the longitudinal direction and opposite ends of which are connected to the heads, respectively a plurality of fins disposed between adjacent ones of the tubes, wherein a condenser core is formed of the tubes and the fins, and heat exchange of the refrigerant is performed in the condenser core. An inlet connector and an outlet connector are both connected to one of the heads. A first tube is connected to the inlet connector, wherein the coolant is supplied to the first tube. A second tube is connected to the outlet connector, wherein the coolant is discharged from the second tube. The inlet connector has in its interior a flow path through which the coolant flows. Further, the flow path is inclined at a predetermined angle to the center of the space along an extending direction of the space, with the space in the one of the heads being arranged at the top in the direction of gravity.

According to the invention, in the condenser having the pair of heads interposed with an interval therebetween, the inlet connector, with the first pipe connected thereto, to which the coolant is supplied, is connected to one of the heads, and the inlet connector has a flow path through which the coolant flows. The flow path is inclined at a predetermined angle to the center of the space located in the direction of gravity at the top of the head.

Therefore, even if in the case that the space for the first pipe connected to the inlet connector is restricted, and the inlet connector is located at the head near its one end along the extending direction of the space, the coolant flows is inserted from the first pipe into the inlet connector, through the flow path inclined toward the center along the extending direction of the space, and therefore, can be deflected in the extending direction of the head.

As a result, the coolant can be supplied from the inlet connector to the center along the extending direction of the space in the head. Since the refrigerant flows substantially uniformly with respect to the plural tubes connected to the head, the heat exchange with the refrigerant flowing through the plural tubes can be made uniform. Further, with a simple structure in which the flow path of the inlet connector is inclined to the center along the extending direction of the space, the flow resistance does not increase as the coolant flows through the flow path. As it passes through the head, the coolant is properly distributed and can flow evenly divided to each of the tubes.

Further, the flow path may include a first opening to which the first pipe is connected and a second opening connected to one of the heads, wherein the first opening and the second opening are arranged to be on a virtual projection plane do not overlap one another perpendicular to the axis of the first opening. As a result, the coolant can flow even more efficiently through the head and can be appropriately distributed to each of the tubes.

Further, the flow path may include a changing unit configured to change the flow direction of the coolant from the first opening to the second opening. As a result, the flow direction of the coolant flowing through the flow path can be changed, and the flow resistance can be reduced.

Still further, the changing unit may have a sloped portion inclined toward the center of the height of the condenser core. As a result, the flow direction of the coolant can be easily changed by passing only through the inclined portion.

Still further, the condenser core may include a first core portion through which the coolant flows from one of the heads in which the inlet connector is disposed to another one of the heads, and a second core portion through which the coolant, after flowing in the other Heads is circulated, then flows to the one of the heads. In addition, the space located at the top in the direction of gravity may be disposed in the first core portion, and the inlet connector may be arranged upward or downward in the direction of gravity with respect to a height center of the space. By virtue of this construction, when the coolant is supplied from the inlet connector to the head, the coolant can be efficiently introduced to an approximately central area along the height direction of the head.

Further, the inlet connector and the one of the heads can be connected by soldering. For example, if the plural tubes are connected to the head by soldering or welding, this feature can reduce the manufacturing processes for manufacturing the capacitor since the operation of connecting the inlet connector can be performed simultaneously as compared to a situation where the operation the connection of the inlet connector is carried out separately from the head.

According to the invention, the following effects and advantages can be obtained.

In the condenser with the pair of heads interposed with an interval therebetween, the inlet connector to which the first pipe is connected and to which the coolant is supplied is connected to one of the heads. The inlet connector has in its interior a flow path through which the coolant flows. For example, by connecting the inlet connector to the head such that the flow path is inclined toward the center of the space located in the top of the head in the direction of gravity, even in the case where the inlet connector is located near the one end along the Extension direction of the space is arranged to deflect the flow of the coolant in the direction of extension of the head and the coolant can be introduced into the head. As a result, the coolant can be supplied from the inlet connector to the center along the extending direction of the space in the head. Thus, since the refrigerant can flow substantially uniformly with respect to the plural tubes connected to the head, the heat exchange with the refrigerant flowing through the plural tubes can be made uniform. Further, with one takes simple structure in which the flow path of the inlet connector is inclined to the center along the extending direction of the space, the flow resistance is not to, when the coolant flows through the flow path. As it passes through the head, the coolant is evenly distributed and can flow evenly divided to each of the tubes.

The above and other objects, features and advantages of the present invention will become more apparent from the following description when taken in conjunction with the accompanying drawings in which preferred embodiments of the present invention are shown by way of illustrative example.

1 FIG. 10 is an overall cross-sectional view of a capacitor according to a first embodiment; FIG.

2 FIG. 12 is an enlarged cross-sectional view of the vicinity of an inlet connector of a first head in the condenser of FIG 1 ;

3A FIG. 10 is an enlarged cross-sectional view of the condenser with an inlet connector according to a first modification; FIG.

3B Fig. 10 is an enlarged cross-sectional view of the condenser with an inlet connector according to a second modification;

4 FIG. 10 is an overall cross-sectional view of a capacitor according to a second configuration; FIG.

5 FIG. 12 is an enlarged cross-sectional view of the vicinity of an inlet connector of a first head in the condenser of FIG 4 ; and

6 FIG. 10 is an overall cross-sectional view of a capacitor according to a third embodiment. FIG.

As in 1 shown, contains a capacitor 10 a pair of heads, ie a first head 12 and a second head 14 , several pipes 16 that is between the first head 12 and the second head 14 are arranged several ribs 18 that waved between the pipes 16 are arranged, as well as a third head 20 that with the second head 14 connected is. In addition, in the capacitor 10 the pipes 16 arranged substantially parallel to each other, and the first and second heads 12 . 14 and the third head 20 are at both ends of the pipes 16 arranged extending in the vertical direction (directions of the arrows A1 and A2). Along with it are the ribs 18 which are bent, for example, in a wave-like shape from a thin sheet material, such as aluminum or the like, in the height direction (directions of the arrows A1 and A2) between two adjacent tubes 16 arranged.

The first and second heads 12 . 14 have a hollow cylindrical shape with a predetermined length in the height direction of the capacitor 10 (Directions of arrows A1 and A2). At the first head 12 at the one end side in the width direction (direction of arrow B1) of the capacitor 10 is arranged are connected: an inlet connector 22 to which the coolant is supplied from the outside, and an outlet connector 24 from which the coolant circulates in the interior of the condenser 10 is left out.

The inlet connector 22 is on a sidewall near the top of the first head 12 arranged, and the outlet connector 24 is on the sidewall near the bottom of the first head 12 arranged. The inlet connector 22 and the outlet connector 24 are arranged substantially parallel to each other. On the other hand, inside, are the first and second heads 12 . 14 , respective interiors 26a . 26b designed, to which the coolant is supplied.

As in the 1 and 2 shown is the inlet connector 22 For example, formed of a metal material and includes a main body portion 30 with which a feed tube (first tube, first opening) 28 is connected and through which the coolant is supplied, and a sloped portion 32 which is at a predetermined angle with respect to the main body portion 30 is inclined.

The main body section 30 is substantially perpendicular to the extension direction of the first head 12 arranged (directions of the arrows A1 and A2), and an end of the inclined portion 32 is with the sidewall of the first head 12 connected. Further, in a state where the inclined portion 32 in the direction of gravity downward (direction of arrow A1) on the side wall of the first head 12 inclined, the inlet connector 22 connected to the side wall by soldering.

On the other hand, in the interior of the main body portion 30 a first feed channel (flow path) 34 formed therethrough along the axial direction (directions of the arrows B1 and B2). The feed tube 28 to which unillustrated refrigerant is supplied is in the internal space of the main body portion 30 used and connected.

Inside the inclined section 32 is a second feed channel (flow path) 36 formed along the axial direction and at a predetermined angle to the first feed channel 34 is inclined. One end of the second feed channel 36 is with the first feed channel 34 connected, and whose other end is with the first head 12 connected and stands with the interior of the first head 12 through a connection hole (second opening) 38 connected to the sidewall of the first head 12 located.

In particular, when the coolant from the first supply channel 34 to the second feed channel 36 flows, whose flow direction through the inlet connector 22 through the inclined second feed channel 36 changed. In other words, the second feed channel 36 functions as a changing unit for changing the flow direction of the refrigerant flowing from the first supply passage 34 flows.

In addition, the inclination angle of the inclined portion 32 an acute angle smaller than 90 ° to the extending direction of the main body portion 30 is (directions of arrows B1 and B2).

The connection hole 38 is in the direction perpendicular to the axis of the first feed channel 34 offset, and in particular in the extension direction of the first head 12 (Directions of arrows A1 and A2). The connection hole 38 is formed at a position spaced by a predetermined distance in the downward direction (direction of arrow A1) with respect to the first supply passage 34 is offset. In other words, the first feed channel 34 and the connection hole 38 (the end of the second feed channel 36 ) are spaced apart so that they are on a virtual projection plane perpendicular to the axis of the first feed channel 34 do not overlap each other.

The outlet connector 24 is, for example, cylindrically formed of metal material and is perpendicular to the extending direction (directions of arrows A1 and A2) of the first head 12 connected. A discharge channel 40 goes along the interior of the outlet connector 24 therethrough. In addition, a discharge pipe (second pipe) 42 , through which the coolant is discharged to the outside, with the one end of the outlet connector 24 connected, while the other end to the interior 26a of the first head 12 through a connection hole 44 communicating in the sidewall of the first head 12 opens. This feature represents the interior 26a of the first head 12 with the discharge pipe 42 through the discharge channel 40 of the outlet connector 24 in connection. In the same way as the inlet connector 22 is the outlet connector 24 in the sidewall of the first head 12 connected by soldering.

Furthermore, a partition wall 46 in the interior 26a of the first head 12 at a position above (in the direction of arrow A2) the junction of the outlet connector 24 arranged. Through the partition 46 becomes the interior 26a divided into a first room 48 that with the inlet connector 22 communicates, and a second room 50 that with the outlet connector 24 communicates. In particular, the coolant coming from the inlet connector 22 in the first room 48 of the first head 12 is fed through the partition 46 from the coolant in the second room 50 of the first head 12 through the outlet connector 24 is discharged to the outside, separated.

Beyond that are in the first head 12 Ends of the several tubes 16 connected to a side wall disposed on a side opposite from the side wall, with which the inlet connector 22 and the outlet connector 24 are connected, so that the ends of the tubes 16 each with the first and second rooms 48 . 50 keep in touch.

The second head 14 is essentially parallel to the first head 12 and has a length shorter in the height direction (directions of the arrows A1 and A2) than that of the first head 12 , An upper end of the second head 14 is essentially the same height as the top of the first head 12 whereas its lower end (in the direction of arrow A2) is located above the lower end of the first head 12 is arranged.

Further, in the second head 14 the other ends of the several tubes 16 connected to a side wall that faces the side of the first head 12 point (in the direction of arrow B1).

The third head 20 is for example hollow-cylindrical and in the direction (from arrow B2) from the first head 12 away sideways to the second head 14 arranged. In addition, the third head 20 from the second head 14 offset by a predetermined distance downwards (direction of arrow A1), and is substantially parallel to the second head 14 arranged.

A lower end sidewall of the second head 14 and a side wall of the third head 20 , which face each other, are connected by a connecting tube. The connecting pipe 53 contains in its interior a connecting path. One end of the connecting pipe 52 is in the interior of the second head 14 inserted, and its other end is in the interior of the third head 20 used to thereby the respective interiors 26b . 26c to contact each other. As a result, the coolant flowing into the second head flows 14 is introduced through the connecting pipe 52 and gets in the third head 20 directed.

Further, on the third head 20 , from the several pipes 16 , the other ends of a section the pipes 16 not with the second head 14 are connected to a side wall of the third head 20 connected with respect to the second head 14 projecting downwards (in the direction of arrow A1), and these tubes 16 stand with the interior 26c in connection. In particular, of the several tubes 16 the section of the pipes 16 that with the third head 20 are formed, formed with a length dimension which is longer than the tubes 16 that with the second head 14 are connected.

The pipes 16 are flattened tubes made of, for example, aluminum material, and are rectilinear in shape, with predetermined lengths. In addition, as in 1 shown the pipes 16 in an approximately horizontal direction (directions of the arrows B1 and B2) and are arranged in a plurality of a predetermined distance therebetween in the height direction (directions of the arrows A1 and A2). The one ends of the pipes 16 are each with the first head 12 whereas the other ends of the tubes are connected 16 each with the second head 14 or the third head 20 are connected.

The coolant coming from the inlet connector 22 the first head 12 is fed, after it flows along the direction of arrow B2 through the several tubes 16 to the second head 14 flowed from the interior 26b of the second head 14 through the connecting pipe 52 and then into the interior 26c of the third head 20 , Then the coolant flows through the pipes again 16 along the direction of arrow B1 and flows into the second room 50 of the first head 12 , whereupon the coolant through the outlet connector 24 is delivered.

At the condenser 10 acts from the several tubes 16 , an area where the first head 12 and the second head 14 through a plurality of tubes 16 connected to each other and the coolant from the first head 12 in the second head 14 flows as a capacitor section (first core section) S1. On the other hand, an area where the third head acts 20 and the first head 12 through a plurality of tubes 16 are connected, and the coolant from the third head 20 to the first head 12 is returned as a supercooling section (second core section) S2.

In addition, the inlet connector 22 at a position on the first head 12 which is higher (in the direction of arrow A2) than an imaginary line M (= L / 2) defined at the half of the height dimension L of the capacitor section S1.

It should be noted that, with respect to the capacitor described above 10 , a case has been described in which the capacitor 10 is a disposable passage structure, in the condenser section S1, the refrigerant in only one direction (direction of arrow B2) from the first head 12 to the side of the second head 14 flows down.

The capacitor 10 according to the first embodiment is basically as described above. The following are the operations and benefits of the capacitor 10 described.

First, the refrigerant, which has been compressed by a compressor, not shown, and has a high-temperature, high-pressure gaseous state, flows through the supply pipe 28 and becomes the inlet connector 22 supplied, and the coolant is through the first and second feed channels 34 . 36 of the inlet connector 22 in the first room 48 of the first head 12 directed. In the inlet connector 22 is the inclined section 32 who with the first head 12 is connected at a predetermined angle downward in the direction of gravity (direction of arrow A1) with respect to the main body portion 30 inclined and stands with the first room 48 through the second feed channel 36 in connection. Therefore, the coolant is in the first head 12 while approaching the center area along the height direction (direction of arrows A1 and A2) of the first space 48 is aligned.

In this way, the coolant is not directed only to the vicinity of the upper end in the height direction (direction of the arrows A1 and A2) of the first head, where the inlet connector 22 but also becomes approximately equal to the approximate central region downstream in the vicinity along the height direction (direction of the arrows A1 and A2) of the first head 12 introduced. In other words, in the first head 12 For example, the coolant becomes approximately equal to the approximate center area and the lower end side in the first space 48 fed while avoiding concentrated feed near the top where the inlet connector 22 connected.

In addition, that flows the first head 12 supplied coolant substantially uniformly with respect to each of the plurality of tubes 16 , After passing through the pipes 16 is the coolant that passes through the pipes 16 has flowed when it is to the side of the second head 14 (in the direction of arrow B2) flows, through the air, through and between the ribs 18 flows through, cooled and liquefied, and the liquefied refrigerant is in the interior 26b of the second head 14 introduced. In this case, the coolant flows evenly with respect to the plurality of tubes 16 whereby the coolant can be cooled evenly and efficiently.

The coolant then flows from the second head 14 through the connecting pipe 52 and then into the interior 26c of the third head 20 into it. To Separation into gas and liquid components, only the liquid coolant flows through the several tubes 16 that with the third head 20 are connected, and will flow through the pipes 16 to the side of the first head 12 (in the direction of arrow B1) further cooled.

At the condenser 10 acts from the several tubes 16 , an area where the first head 12 and the second head 14 through a part of the several tubes 16 connected to each other and the coolant from the first head 12 in the second head 14 flows as the sole condenser portion (first core portion) S1, whereas an area where the third head 20 and the first head 12 through the remaining pipes 16 connected to each other and the coolant from the third head 20 to the first head 12 is returned as the supercooling section (second core section) S2.

Finally, the coolant flows in the liquefied state, through the pipes 16 in the second room 50 of the first head 20 has been introduced through the discharge channel 40 of the outlet connector 24 and becomes the discharge pipe 20 let out.

According to the first embodiment, the capacitor includes 10 the inlet connector 22 through which the coolant of the side wall of the first head 12 is supplied, and the outlet connector 24 through which the coolant is discharged. If, for example, due to the layout relationship of the feed pipe to be connected 28 the inlet connector 22 near the top of the first head 12 can be arranged, the direction in which the coolant with respect to the first head 12 is deflected downward in the direction of gravity (in the direction of arrow A1) by the inclined portion 32 is connected, which is inclined in the direction of gravity (in the direction of arrow A1) with respect to the side wall downwards.

For this reason, from the first inlet connector 22 that is near the top of the first head 12 is connected, the coolant to an approximately central region in the height direction of the first head 12 be supplied, wherein the coolant is capable of substantially uniformly with respect to the plurality of tubes 16 to flow, which are arranged in parallel in the height direction. As a result, heat exchange occurs evenly between the coolant and the air passing between the plural pipes 16 flows through, wherein the cooling of the coolant can be done efficiently and the heat exchange performance of the capacitor 10 can be improved.

It also comes with a simple structure, in which the downwardly sloping section 32 in the inlet connector 22 is provided, the coolant the first head 12 supplies, the flow resistance is not increased when the coolant through the first and second feed channels 34 . 36 flows. In the first room 48 of the first head 12 the coolant is evenly distributed and flows evenly divided to each of the tubes 16 , whereby the flow rate of the coolant can be made substantially uniform.

In addition, if the inlet connector 22 near the top of the first head 12 and at a position above (in the direction of arrow A2) from the center (imaginary line M) of the height dimension L of the condenser section S1 in the first head, the coolant can efficiently be substantially uniform in each of the respective tubes 16 flow, as the coolant suitable through the inlet connector 22 to the approximately central area along the height direction (directions of arrows A1 and A2) of the first head 12 can be introduced.

Still further, by providing the inlet connector 22 with the inclined section 32 which in relation to the main body section 30 is inclined, and by connecting the inlet connector 22 with the first head 12 refrigerant is introduced while being at the approximately central area along the height direction (directions of arrows A1 and A2) of the first head 12 is aligned. Therefore, as compared with a structure as in the condenser of the conventional art, in which the connection portion where the inlet pipe is connected to the head is forked, the components of the condenser can be bifurcated 10 , Can be simplified, and the flow resistance of the coolant flowing through the interior, can be further reduced.

Still further, by connecting the inlet connector 22 and the outlet connector 24 by soldering with respect to the sidewall of the first head 12 , the several pipes 16 simultaneously by soldering to the first and second heads 12 . 14 get connected. As a result, compared to a situation where the inlet connector 22 and the outlet connector 24 in relation to the first head 12 separate from the pipes 16 connected, the manufacturing process steps to manufacture the capacitor 10 be reduced.

Further, the above-described inlet connector 22 not limited to the case where the first feed channel 34 with which the feed tube 28 is connected substantially in the horizontal direction (directions of the arrows B1 and B2), whereas the second supply channel 36 with respect to the first feed channel 34 is inclined downwards (in the direction of arrow A1). For example, with an inlet connector 62 according to a first modification of the capacitor 60 , as in 3A shown, one first feed channel 34 and a second feed channel 66 along a straight line, and could be the second feed channel 66 in relation to the first head 12 to the approximately central area along the direction in which the first head 12 extends, inclined to be connected.

In other words, in the inlet connector 62 there is no need to provide a feed channel which extends substantially horizontally, and only feed channels inclined in a downward direction could be provided.

If with the inlet connector 62 for example, according to the first modification, the end of the feed tube 28 that with the first feed channel 64 is connected, inclined downwards from a location above the inlet connector 62 can be connected, the feed tube 28 substantially rectilinear with respect to the first feed channel 64 be connected.

Further, with an inlet connector 72 according to a second modification of a capacitor 70 , as in 3B shown, a first feed channel 74 (in the direction of arrow A2) to the side of a second feed channel 76 (upwards in the direction of arrow B2), and could be the second feed channel 76 (in the direction of arrow A1) to the side of the first head 12 (in the direction of arrow B2) be inclined downwards and with the first head 12 be connected. Together then the first feed channel could 74 and the second feed channel 76 through a connection channel 78 be connected to each other, which extends substantially in a horizontal direction. In addition, the first supply channel need 74 and the second feed channel 76 not necessarily through the connection channel 78 but could also be directly connected.

If, at the inlet connector 72 according to the second modification, for example the end of the feed tube 28 that with the first feed channel 74 connected from a location below the inlet connector 72 Upwardly inclined, the feed tube can 28 suitable in a straight line with respect to the first feed channel 74 be connected.

In this respect, the second feed channels 36 . 66 . 76 the inlet connector 22 . 62 . 72 with the first head 12 while being connected at a predetermined angle to the approximately central area along the extending direction (direction of arrow A1) of the first head 12 are inclined, it is unlimited, whether the first feed channels 34 . 64 . 74 be connected in a straight line or at a predetermined angle with respect to the second feed channels 36 . 66 . 76 inclined to be connected.

In other words, depending on the layout of the feed pipe to be connected 28 become the first feed channels 34 . 64 . 74 the inlet connector 22 . 62 . 72 formed at an angle which is the connection from the end of the feed tube 28 in a straight line along with the first feed channels 34 . 64 . 74 allows, eliminating the feed tube 28 light and reliable in relation to the first feed channels 34 . 64 . 74 can be connected.

Next is a capacitor 100 according to a second embodiment with respect to 4 to 5 described. Those components with those of the capacitor 10 are common to the above-described first embodiment, are denoted by the same reference numerals, and a detailed description of these features will be omitted.

As in 4 shown, the capacitor is different 100 according to the second embodiment of the capacitor 10 according to the first embodiment in that the one with the first head 102 connected inlet connectors 104 with respect to the center (imaginary line M) of the height dimension L of the condenser section S1 downward (in the direction of arrow A1).

As in the 4 and 5 shown is the inlet connector 104 of the capacitor 100 formed of metal material, for example, and includes a main body portion 30 with which a feed tube 28 is connected and through which the coolant is supplied, and a sloped portion 106 which is at a predetermined angle with respect to the main body portion 30 is inclined. The main body section 30 is substantially perpendicular to the extension direction of the first head 102 arranged, and the inclined section 106 is inclined at a predetermined angle upward to the direction of gravity (direction of arrow A2) and is aligned with the side wall of the first head 102 connected. In addition, the inlet connector 104 at a position on the first head 102 which is lower (in the direction of arrow A1) than an imaginary line M (= L / 2) defined at half the height dimension L of the capacitor section S1.

Inside the inclined section 106 is a second feed channel 108 formed with respect to the first feed channel 34 of the main body portion 30 is inclined. The second feed channel 108 goes along the axial direction, and its one end is to the first feed channel 34 connected while his other end with the first head 102 is connected and with the inside of the first head 102 through a connection hole (second opening) 110 communicates, which is located on the side wall of the first head 102 opens.

The connection hole 110 is in the direction perpendicular to the axis of the first feed channel 34 offset, and in particular in the extension direction of the first head 102 (Directions of arrows A1 and A2). The connection hole 110 is formed at a position that is a predetermined distance in the outward direction (direction of arrow A2) with respect to the first supply channel 34 is offset. In other words, the first feed channel 34 and the connection hole 110 (the end of the second feed channel 108 ) are arranged at a distance such that they are on a virtual projection plane perpendicular to the axis of the first feed channel 34 do not overlap each other.

If, moreover, in the case of the capacitor described above 100 , the high temperature and high pressure refrigerant in the gaseous state through the feed tube 28 flows and the first supply channel 34 of the inlet connector 104 is supplied, is the inclined portion 106 thereof inclined at a predetermined angle upward to the direction of gravity (direction of arrow A2) and communicates with the interior 26a through the second feed channel 108 in connection. Therefore, the coolant is in the first head 102 while being brought to the approximately central portion thereof along the height direction (direction of arrows A1 and A2) of the first space 48 is aligned.

In this way, the coolant is not only in the vicinity of the lower end of the height direction (direction of arrow A1 and A2) of the first head 102 initiated where the inlet connector 104 but also becomes the approximate central area and the upward neighborhood along the height direction of the first head 102 initiated. In particular, the coolant is relative to the first head 102 Approximately uniformly supplied to the approximately central region and the upper end side, while a concentrated supply in the vicinity of the lower end is avoided, where the inlet connector 22 connected.

In addition, that flows the first head 102 supplied coolant substantially uniformly with respect to each of the tubes 16 , If the coolant to the side of the second head 14 through the pipes 16 flowing, the coolant passes through the air, passing through and between the ribs 18 flows through, cooled and liquefied, and the liquefied refrigerant is in the interior 26b of the second head 14 introduced. In this case, the coolant flows evenly with respect to the plurality of tubes 16 whereby the coolant can be cooled evenly and efficiently.

Even if, according to the second embodiment, the capacitor 100 for example, in the case due to the layout relationship of the supply pipe to be connected 28 the inlet connector 104 who with the first head 102 is arranged in the vicinity of the lower end can, in this way, by connecting the inclined portion 106 inclined to the direction of gravity (direction of arrow A2) upwardly with respect to the side wall, the direction in which the coolant relative to the first head 102 is deflected upward with respect to the direction of gravity (in the direction of arrow A2).

For this reason, even in the case that the inlet connector 104 near the bottom of the first head 102 is arranged, the coolant in the approximately central region in the height direction of the first head 102 supplied along with the coolant being substantially uniform with respect to the plurality of tubes 16 can flow, which are arranged in parallel in the height direction. As a result, the heat exchange takes place equally between the refrigerant and the air, the cooling of the refrigerant can be performed efficiently, and the heat exchange performance of the condenser 100 be improved.

Further, with a simple structure, in which the upwardly inclined section 106 in the inlet connector 104 is provided, the coolant the first head 102 feeds, in the first room 48 of the first head 102 , which distributes coolant evenly and flows evenly divided to each of the pipes 16 , whereby the flow rate of the coolant can be made substantially uniform.

Further, in the case that the inlet connector 104 near the bottom of the first head 102 and at a position downward (in the direction of arrow A1) from the center of the height dimension L of the capacitor section S1 in the first head 102 , the coolant is substantially uniform to each of the respective tubes 16 flow, as the coolant through the inlet connector 104 to the approximately central area along the height direction (direction of arrows A1 and A2) of the first head 102 can be introduced.

In addition, by the inlet connector 104 by soldering to the sidewall of the first head 102 Connected, the multiple tubes can 16 simultaneously with soldering in relation to the first and second heads 102 . 14 get connected. As a result, compared to a situation where the inlet connector 104 with the first head 102 separate from the pipes 16 is connected, the manufacturing process steps used to manufacture the capacitor 100 are required to be reduced.

Furthermore, with the capacitors 10 . 100 According to the first and second embodiments described above, cases have been described in which the inlet connectors 22 . 104 essentially perpendicular to the extension direction of the first heads 12 . 102 are connected (directions of the arrows A1 and A2). However, the invention is not limited to this feature. For example, if the second feed channels 36 . 108 in the inlet connectors 22 . 104 to the middle of the extension direction of the first heads 12 . 102 can be connected inclined, the first feed channels 34 the inlet connector 22 . 104 in the lateral left-right direction (width direction) with respect to the extending direction (directions of the arrows A1 and A2) of the first heads 12 . 102 to open.

Below is a capacitor 150 according to a third embodiment of the present invention with respect to 6 described. Those components with those of the capacitor 10 are common to the above-described first embodiment, are denoted by the same reference numerals, and a detailed description of these features will be omitted.

The capacitor 150 according to the third embodiment differs from the capacitor 10 according to the first embodiment, in that a three-passage structure is provided, wherein, in the condenser section S1, a first head 152 through two first and second partitions 154 . 156 (in three parts), whereas a second head 158 through a third partition 160 (in two parts), and the coolant one and a half times through the multiple tubes 16 between the first head 152 and the second head 158 is circulated.

As in 6 is shown in the capacitor 150 the first head 152 through the first partition 154 , which are approximately centered near along the height direction (direction of arrows A1 and A2) of the first head 152 is arranged and the second partition 156 near the outlet connector 24 is arranged, divided into three parts. In addition, the interior is 26a divided into a first room 162 between the first partition 154 and the upper wall portion of the first head 152 , and a second room 164 passing through the first partition 154 and the second partition 152 is divided. In the first head 152 serve the first and second rooms 162 . 164 as parts of the condenser section S1.

In addition, in the first head 152 the inlet connector 22 in relation to the first room 162 connected, and together with it is the inlet connector 122 at a position higher (in the direction of arrow A2) than the center of the height (imaginary line M) of the first space 162 , Similar to the capacitor 10 According to the first embodiment, the inlet connector includes 22 the second feed channel 36 which is at a predetermined angle with respect to the first feed channel 24 is inclined downwards.

There is also a third room 166 between the lower end of the interior 26a of the first head 152 and the second partition 156 formed, and the outlet connector 24 is with the interior 26a connected.

On the other hand, in the second head 158 the third partition 160 higher than the position where the connecting pipe 52 connected. The interior 26b is through the third partition 160 in a fourth room 170 which is located upwards and a fifth room 172 inside the second head 158 is arranged below. In addition, the connecting pipe 152 with the fifth room 172 connected.

If with the above-described capacitor 150 According to the third embodiment, the coolant, which has a high-temperature and high-pressure gaseous state, through the supply pipe 28 flows and the first supply channel 34 of the inlet connector 22 is supplied, the coolant is in the first head 152 while being directed to the approximately central portion thereof along the height direction (directions of arrows A1 and A2) of the first space 162 is aligned.

In this way, the coolant becomes not only near the upper end in the height direction (direction of the arrows A1 and A2) of the first space 162 in the first head 152 initiated where the inlet connector 22 but also becomes the approximate central area and the downstream neighborhood along the height direction of the first space 162 initiated. In particular, the coolant is relative to the first space 162 approximately evenly to the approximate central area and to the lower end side in the first room 162 fed while avoiding the concentrated feed in the vicinity of the top where the inlet connector 22 connected.

In addition, the coolant flows to the first room 162 this first head 152 is fed, approximately uniformly with respect to each of the tubes 16 , After the coolant through the pipes 16 in the fourth room 170 of the second head 158 has flowed, the coolant flows through the respective tubes again 16 , flows (in the direction of arrow B1) to the side of the first head 152 and will be in the second room 164 initiated. The coolant then flows through the respective tubes again 16 from the second room 164 , flows to the side of the second head 158 (Direction from arrow B2) and becomes the fifth room 172 initiated. After the coolant to the interior 26c of the third head 20 through the connecting pipe 52 has moved, the refrigerant is divided into gas and liquid components, whereupon only the liquid refrigerant through the plurality of tubes 16 passes through, and the coolant is further cooled by passing it through the pipes 16 to the side of the first head 152 towards (in the direction of arrow B1) flows.

Finally, the coolant flows in the liquefied state, through the pipes 16 in the third room 166 of the first head 152 has been introduced through the discharge channel 40 of the outlet connector 24 and gets through the discharge pipe 52 omitted.

In the capacitors described above 10 . 100 . 150 the number of passes through the capacitor section S1 is not limited. Also in the case where the inlet connector 22 at a position upwards or downwards with respect to the height center of the spaces of the first heads 12 . 102 . 152 connected in the direction of gravity (in the direction of arrow A2) at the top, as far as the flow paths inclined toward the center in the height direction, the coolant without deflection (ie, uniformly) with respect to each of Tube 16 flow, which are connected to these pipes.

In a condenser ( 10 ) is an inlet connector ( 12 ), to which a coolant is supplied, with a side wall of a first head ( 12 ) connected. The inlet connector ( 22 ) is near an upper end portion of the first head ( 12 ) and is connected to the side wall of the first head ( 12 ) by a sloping section ( 32 ) inclined at a predetermined angle downwards. In addition, if the coolant from the inlet connector ( 22 ) the interior of the first head ( 12 ), the coolant is drawn to an approximately central area in the height direction of the first head (FIG. 12 ) through the inclined section ( 32 ). Therefore, the coolant may be substantially uniform with respect to a plurality of tubes (FIG. 16 ) in the height direction of the first head ( 12 ) are arranged in parallel, and the heat exchange can take place.

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

• JP 2004-353936 A [0004]
• JP 06-074609A [0005]

Claims (6)

Capacitor ( 10 . 60 . 70 . 100 . 150 ), which comprises: a pair of heads ( 12 . 14 . 102 . 152 . 158 ) arranged at an interval therebetween and containing spaces into which coolant is introduced; several pipes ( 16 ), which extend in the longitudinal direction and whose opposite ends in each case with the heads ( 12 . 14 . 102 . 152 . 158 ) are connected; as well as several ribs ( 18 ) between adjacent tubes ( 16 ) are arranged, wherein a capacitor core from the tubes ( 16 ) and the ribs ( 18 ) is formed, and in the condenser core, a heat exchange of the coolant is performed, wherein: an inlet connector ( 22 . 62 . 72 . 104 ) and an outlet connector ( 24 ) both with one of the heads ( 12 . 102 . 152 ) are connected; a first pipe ( 28 ) with the inlet connector ( 22 . 62 . 72 . 104 ) and the coolant is connected to the first pipe ( 28 ) is supplied; and a second tube ( 42 ) with the outlet connector ( 24 ) and the coolant from the second tube ( 42 ) is delivered; the inlet connector ( 22 . 62 . 72 . 104 ) in its interior a flow path ( 34 . 36 . 64 . 66 . 74 . 76 . 78 . 108 ) through which the coolant flows; and the flow path ( 34 . 36 . 64 . 66 . 74 . 76 . 78 . 108 ) at a predetermined angle to the center of the room ( 48 ) along an extension direction of the space ( 48 ), the space ( 48 ) in one of the heads ( 12 . 102 . 152 ) is arranged in the direction of gravity (A1) at the top. The condenser of claim 1, wherein the flow path ( 34 . 36 . 64 . 66 . 74 . 76 . 78 . 108 ) a first opening ( 34 ), with which the first pipe ( 28 ), and a second opening ( 38 . 110 ) with the one of the heads ( 12 . 102 . 152 ), and the first opening ( 34 ) and the second opening ( 38 . 110 ) are arranged so that they are arranged on a virtual projection plane perpendicular to the axis of the first opening ( 34 ) do not overlap each other. The condenser of claim 2, wherein the flow path ( 34 . 36 . 64 . 66 . 74 . 76 . 78 . 108 ) a change unit ( 36 configured to adjust the flow direction of the coolant from the first port (FIG. 34 ) to the second opening ( 38 . 110 ) to change. The capacitor according to claim 3, wherein said changing unit ( 36 ) an inclined section ( 32 . 106 ), which is inclined towards the center of the condenser core. The condenser of claim 1, wherein the condenser core has a first core portion (S1) through which the coolant from the one of the heads ( 12 . 102 . 152 ), in which the inlet connector ( 22 . 62 . 72 . 104 ) is arranged to another of the heads ( 14 . 158 ), and a second core section (S2) through which the coolant flows, after being in the other of the heads (S2). 14 . 158 ) is circulated, then to the one of the heads ( 12 . 102 . 152 ), where the space ( 48 . 162 ) disposed at the top in the direction of gravity (A1), is disposed in the first core portion (S1), and the inlet connector (A1). 22 . 62 . 72 . 104 ) in the direction of gravity with respect to a mid-height of the space ( 48 . 162 ) is arranged upward or downward. The capacitor of claim 1, wherein the inlet connector ( 22 . 62 . 72 . 104 ) and one of the heads ( 12 . 102 . 152 ) are connected by soldering.

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