Abstract:
The invention relates to a condenser for an air conditioning system, especially an air conditioning system of a vehicle, said condenser comprising a gill block and laterally arranged headers, the gill block comprising horizontal pipes, a condensing section and a supercooling section arranged above the condensing section. Said condenser also comprises a collector ( 5 ) arranged parallel to one of the headers and receiving a drier ( 16 ), a filter ( 18 ), a downpipe ( 15 ) and a rising pipe. The collector ( 5 ) is connected to the condensing section by means of a first overflow opening ( 8 ) and to the supercooling section by means of a second overflow opening ( 9 ) in such a way that a coolant can circulate. The downpipe ( 15 ) communicates with the first overflow opening ( 8 ), on the inlet side, by means of an inflow chamber ( 10 ) arranged in the collector ( 5 ).

Description:
BACKGROUND OF THE INVENTION 
     The invention relates to a condenser for an air. conditioning system. 
     The Applicants&#39; prior German patent application DE 10 2005 005 187.1 relates to a refrigerant condenser having a condensing section and having a supercooling section—a so-called supercooling path—arranged above said condensing section, in which supercooling section the refrigerant is cooled to below its condensation temperature. The condenser also has laterally arranged collecting tubes and an integrated collector which communicates via a first and a second transfer opening with the adjacent collecting tube or the condenser. Arranged in the collector is an insert which has a down pipe, a filter-dryer unit and an ascending pipe, with the down pipe communicating at the inlet side with the final condensing section and with the ascending pipe communicating at the outlet side with the supercooling path. The filter-dryer unit has arranged in it a dryer material (a so-called molecular sieve) and a mechanical sieve, such that as the refrigerant passes through the filter-dryer unit, said refrigerant is firstly freed from particles such as impurities and is secondly dried. Arranged in the upper part of the collector, in the region of the transfer openings, is a plug which separates the inflowing and outflowing refrigerant flows from one another. 
     Similar refrigerant condensers, that is to say with an overhead supercooling path and having an ascending pipe in the collector, are known from the applicant&#39;s DE 199 12 381 A1 and from DE 102 50 384 A1 and from DE 103 45 921 A1. 
     SUMMARY OF THE INVENTION 
     It is an object of the present invention to further improve the subject matter of the applicant&#39;s above-cited prior patent application, in particular with regard to the filter-dryer function. 
     Said object is achieved in each case by means of the features of the two independent patent claims  1  and  14 . The subclaims relate to advantageous refinements of the invention. 
     According to the first independent solution, an inflow chamber is arranged in the region of the first transfer opening (inflow opening) and an outflow chamber is arranged in the region of the second transfer opening (outflow opening), which inflow chamber and outflow chamber are delimited firstly by the cylindrical wall of the collector and secondly by two plates or partitions and a closure part. This provides the advantage that the guidance of the refrigerant in the inflow and outflow region is simplified; for example, a corresponding plug, which is provided in said region in the prior application, is dispensed with. 
     In one advantageous refinement of the invention, the down pipe adjoins the inflow chamber in the downward direction, through which down pipe the refrigerant flow which enters from the condensing section is channeled and directed downward in terms of its flow direction, that is to say in the direction of the base of the collector. The down pipe ends at a significant distance above the base. This provides the advantage that the downwardly emerging refrigerant flow is decelerated as a result of the sudden cross-sectional widening, as a result of which entrained gas bubbles are separated and can rise up. Said gas bubbles collect in a space below the inflow chamber. 
     In a further advantageous refinement of the invention, a dryer element is arranged on the base in the collector, which dryer element is preferably designed as a nonwoven bag containing dryer granules and extends upward up to below the inflow chamber. The refrigerant flow emerging from the down pipe can therefore make contact with the dryer material, as a result of which water is extracted from the refrigerant. 
     In a further advantageous refinement of the invention, an ascending pipe or suction pipe which runs continuously from the base up to the outflow chamber is arranged in the collector, through which ascending pipe or suction pipe the refrigerant is conducted from the bottom to the top into the outflow chamber. The ascending pipe is advantageously widened in its lower cross-sectional region and holds within it a filter element, preferably designed as a filter cap, in a positively locking or non-positively locking fashion. This provides a simple, exchangeable and space-saving arrangement of the filter element within the suction pipe, together with an effective filter action. At the same time, the filter and dryer element are therefore physically separated, which allows them to be exchanged more easily. 
     In a further advantageous refinement of the invention, the down pipe and the ascending pipe are formed in one piece with one another and have a doubled cross section, characterized by a common partition. It is also optionally possible for the lower and upper plates to be formed in one piece with the ascending pipe and down pipe, such that, in the case of a design as a plastic injection-molded part, an insert is provided which is easy to handle and which is inserted into the collector and secured by means of a closure part. Assembly—or if appropriate also disassembly—can therefore take place with one or two hand movements. 
     In the second independent solution, the down pipe of the first solution is replaced by a flow duct which is formed by a partition insert, the outer wall of the ascending pipe and the inner wall of the collector, so as to form two injection ducts. This provides the advantage of better volume utilization of the collector: it is possible in particular for more drying agent to be accommodated in the storage space. Furthermore, the entire insert can be produced more easily, and with less material expenditure, by injection molding. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Exemplary embodiments of the invention are illustrated in the drawing and are described in more detail below. In the drawing: 
         FIG. 1  shows a cross-flow condenser with an overhead supercooling path and a laterally arranged integrated collector, 
         FIG. 2  shows the collector in a sectional illustration, 
         FIG. 3  shows a further modified collector in a sectional illustration, 
         FIG. 4  shows the collector according to  FIG. 3  in a 3-D illustration, and 
         FIG. 5  shows a section along the line V-V in  FIG. 3 . 
     
    
    
     DETAILED DESCRIPTION 
       FIG. 1  shows a cross-flow condenser  1  which can be traversed by a plurality of flows and which has a tube-fin block  2 , laterally arranged collecting tubes  3 ,  4  and an integrated collector  5 . The arrows P 1 , P 2 , P 3 , P 4 , P 5  and P 6 , which point in alternating directions, represent the flow directions of the refrigerant in individual tube groups (not illustrated in any more detail) of the tube-fin block  2 , with the refrigerant entering via a connecting pipe  3   a  situated at the bottom and emerging via a connecting pipe  3   b  situated at the top. The tube-fin block  2  is composed of a condensing section, which corresponds to the arrows P 1  to P 5 , and a supercooling section which is arranged above the condensing section and which is denoted by the arrow P 6 . Substantially liquid refrigerant flows in the supercooling section, which refrigerant is cooled to below the condensation temperature of the refrigerant by the ambient air which impinges on the condenser  1 . The refrigerant subsequently leaves the condenser  1  via the connecting pipe  3   b.    
       FIG. 2  shows—as a first exemplary embodiment of the invention—the collector  5  in a sectional illustration, without the adjacent collecting tube  4 . The collector  5  is composed of two pipe pieces, an upper, extruded pipe piece  5   a , and a lower, welded pipe piece  5   b  which is cohesively connected to the upper pipe piece  5   a . The collector  5  is closed off in the downward direction by a base  6  (non-detachable) and in the upward direction by a closure plug  7  (detachable). The extruded pipe piece  5   a  has a first transfer opening (inflow opening) and a second transfer opening  9  (outflow opening), through which refrigerant flows in from the adjacent collecting tube (not illustrated) corresponding to the arrow E, and flows out corresponding to the arrow A. The design and the arrangement of the adjacent collecting tube  4  (not illustrated) correspond to the prior patent application with the file reference 10 2005 005 187.1 cited in the introductory part of the description, the entire content of which is hereby incorporated into the content of disclosure of the present application. An inflow chamber  10  for the refrigerant is arranged in the region of the inflow opening  8  and an outflow chamber  11  for the emerging refrigerant is arranged in the region of the outflow opening  9 , with the inflow chamber  10  being delimited in the axial direction by a lower plate  12  and by an upper plate  13  which is arranged as a partition between the two transfer openings  8 ,  9 . The outflow chamber  11  is formed by the upper plate  13 , which has an encircling sealing ring  14 , and by the detachable closure plug  7 . The lower plate  12  has, in its central region, an inlet opening  12   a  which is adjoined in the downward direction by a down pipe  15  which has a lower outlet opening  15   a . A dryer element, designed as a nonwoven bag  16  filled with dryer granules, is arranged below the inflow chamber  10  so as to rest on the base  6 . The nonwoven bag  16  is designed corresponding to the installation conditions, that is to say in this case has an elongate shape which extends in the longitudinal direction of the collector and which provides sufficient space for the refrigerant flow emerging from the down pipe  15  to flow around the nonwoven bag  16 . Refrigerant is stored in the collector  5 , which refrigerant is present in a liquid and gaseous phase; the liquid level should lie above the outlet opening  15   a  of the down pipe  15 . 
     An ascending pipe  17  is connected, preferably in one piece, to the down pipe  15 , which ascending pipe  17  extends in the longitudinal direction of the collector  5  from the base  6  to the upper plate  13 . The latter has an outlet opening  13   a  which is adjoined by the upper end  17   a  of the ascending pipe  17 . The ascending pipe  17  extends with its upper region  17   a  through the inflow chamber  10  and the plate  12  and, with its central region  17   b , forms a doubled cross section together with the adjacent down pipe  15 , that is to say two cross sections, which are separated by a common partition, for the refrigerant flowing in opposite directions. The lower region  17   c  of the ascending pipe  17  is widened in terms of its cross section and holds within it —as can be seen from the drawing—a cylindrical filter element which is designed as a so-called filter cap  18 . An annular gap  19  is provided between the cylindrical filter cap  18  and the cylindrical section  17   c  of the ascending pipe  17 . The filter cap  18  has window-like filter sieves  18   b  (particle filters) on its cylindrical circumference, is closed off at its upper face-side end  18   a  and is open at the opposite end  18   c . The ascending pipe  17  stands with its lower face end on the base  6  and has an aperture  17   d  as an inlet for refrigerant. Four approximately circumferentially distributed, rod-shaped spacers  20  are arranged on the upper side of the upper plate  13  and are connected to the plate  13 —said spacers  20  abut with their upper ends against the underside of the closure plug  7  and thereby fix the plate  13  in the upward direction. The ascending pipe  17 , the down pipe  15 , the lower plate  12 , the upper plate  13  and the spacers  20  are preferably produced in one piece as a plastic injection-molded part and thereby form an insert which can be inserted into the collector  5  from above when the closure plug  7  is removed. The nonwoven bag  16  is also inserted either at the same time as or before the insert. The closure plug  7  is then inserted and fixed so as to form an upper stop for the entire insert with ascending pipe  17 . 
     The function of the dryer and filter device according to the invention will be described below: the substantially condensed refrigerant passes, corresponding to the arrow E (analogously to the cited prior application), into the inflow chamber  10  and flows downward through the inlet opening  12   a  and the down pipe  15  in the direction of an arrow F. As the refrigerant emerges from the outlet opening  15   a , which is immersed in liquid refrigerant, the flow speed of the refrigerant is slowed on account of the cross-sectional widening, such that entrained gas bubbles are separated and can rise upward. As a result of the flow guidance in the down pipe  15 , therefore, the liquid refrigerant does not come into contact with the gas phase. The refrigerant flows further downward and, here, makes contact with the nonwoven bag  16  and the dryer granules contained therein, as a result of which moisture is extracted from the refrigerant. Having arrived at the base  6  of the collector  5 , the refrigerant is deflected corresponding to an arrow G and enters into the filter cap  18  through the lower opening  18   c  in the axial direction. The refrigerant then flows outward in the radial direction through the window-like sieves  18   b  into the annular gap  19 , with any entrained particles being retained by the sieves  18   b  and falling down onto the base  6 . The refrigerant rises up, corresponding to an arrow H, into the central region  17   b  and further into the upper region  17   a  of the ascending pipe  17 . The refrigerant leaves the collector  5  via the outlet opening  13   a  in the upper plate  13 , corresponding to the arrow A, and enters via the adjacent collecting tube (not illustrated) into the upper supercooling section (likewise not illustrated) of the condenser. 
       FIGS. 3 ,  4  and  5  show a second exemplary embodiment of the invention having a collector  21  which—as in the preceding exemplary embodiment—is composed of two pipe pieces, an upper, extruded pipe piece  21   a  and a lower, welded pipe piece  21   b . An inflow opening  22 , which communicates with an inflow chamber  23 , and an outflow opening  24 , which communicates with an outflow chamber  25 , are situated in the upper pipe piece  21   a . The inflow chamber  23  and outflow chamber  25  are separated from one another by means of a partition  26  which is formed as a disk, is sealed off at its circumference and has spacers  26   a . The collector  21  is closed off in the downward direction by a base  27  and in the upward direction by a detachable closure plug  28 . A flow duct which is designed as an ascending pipe  29  is arranged in the collector  21  for refrigerant flowing from the base  27  into the outflow chamber  25 . The ascending pipe  29  stands on the base  27  and extends upward, that is to say in the longitudinal direction of the collector  21 , up to the partition  26  which holds the upper end  29   a  of the ascending pipe  29 . The lower end  29   b  has a step  29   c  for the inlet of the refrigerant. In the central region, the ascending pipe  29  has a sleeve  30  which enables the ascending pipe  29  to be produced in one piece. As can be seen from  FIG. 4 , a filter element  31  is arranged in the lower region of the ascending pipe  29 , which filter element  31  corresponds to the filter element  18  according to the exemplary embodiment of  FIG. 2 , that is to say in terms of form, arrangement and function. 
     In contrast to the first exemplary embodiment according to  FIG. 2 , a flow duct for inflowing refrigerant is provided, which flow duct is formed not by a closed pipe cross section (in the form of a down pipe) but rather by a partition insert  32 , the outer wall of the ascending pipe  29  and the inner wall of the pipe piece  21   b . The partition insert  32  is composed of two partition strips  32   a ,  32   b  which abut with their inner longitudinal edges against the ascending pipe  29  and with their outer longitudinal edges against the inner wall of the collector  21 . The partition strips  32   a ,  32   b  are connected to a base part  33  which delimits the inflow chamber  23  in the downward direction (in the direction of the base  27 ) but which leaves free two throughflow cross sections for the inflowing refrigerant at both sides of the ascending pipe  29 , which throughflow cross sections form the inlet into two injection ducts  34  (cf.  FIG. 5 ). The partition strips  32   a ,  32   b  and the base part  33  are preferably formed in one piece and connected to the ascending pipe  29 , inter alia by means of a web  33   a . Arranged below the base part  33 , that is to say on the side facing away from the inflow chamber  23 , is a storage space  35  in which in particular the gaseous phase of the refrigerant can collect. The liquid level S of the refrigerant, that is to say the parting plane between the liquid and gaseous phase, is situated in the region of the partition strips  32   a ,  32   b . A dryer element in the form of a nonwoven bag  36  filled with granules is arranged within the storage space  35  which extends from the base part  33  to the base  27  of the collector  21 . 
       FIG. 5  shows a cross section corresponding to the plane V-V, showing the base part  33  and the injection ducts  34  arranged at both sides of the ascending pipe  29 . The cross section of the injection pipe  29  is slightly flattened, so as to provide a good utilization of space within the round cross section of the collector  21  for the injection ducts  34  and secondly to make a sufficiently large cross section available for the storage space  35 , in particular for accommodating the drying agent  36 . 
     The ascending pipe  29 , the base part  33  with the partition insert  32  and the partition  26  with spacers  26   a  may preferably be produced in one piece as a plastic injection-molded part and thereby form an insert which—together with the nonwoven bag  36 —can be inserted into and fixed in the collector  21 . 
     The function of the above-described collector is, in principle, the same as that of the preceding exemplary embodiment according to  FIG. 2 . What is different is—as already mentioned—the geometric design of the flow duct which adjoins the inflow chamber  23  and leads downward. The down pipe  15  according to  FIG. 2  is substituted here by the injection ducts  34 . The refrigerant which flows in as per the arrow E thus flows downward through the two injection ducts  34 , following the arrow F, with moisture being extracted from the refrigerant by the granules. The refrigerant enters into the ascending pipe  29  through the opening  29   c  at the base  27  corresponding to the arrow G, and flows upward corresponding to the dashed arrow H into the outflow chamber  25 , from which the refrigerant emerges corresponding to the arrow A. 
     By means of the injection ducts  34 , it is ensured that the inflowing refrigerant does not come into contact with any gas cushion which may be situated in the upper part of the storage space  35 , but rather is conducted so far downward that the entering refrigerant flow opens out directly into the liquid phase of the refrigerant. The liquid level S is shown by way of example in the storage chamber  35 , which liquid level S has a geodetic height h over the lower edge of the partition strips  32   a ,  32   b . The level S may vary during the operation of the air conditioning system, that is to say said level S may lie higher or lower. The length of the injection ducts  34  should however be dimensioned such that the height h is always positive, that is to say the lower edges of the partition strips  32   a ,  32   b  are immersed in liquid refrigerant.