JP3610632B2 - Condenser device - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a condenser device that can efficiently condense high-pressure refrigerant in a mixed refrigerant together with low-pressure refrigerant.
[0002]
[Prior art]
In general, in an air conditioner, as shown in FIG. 3, the refrigerant compressed by the compressor 51 is condensed by the condenser 52, evaporated by the evaporator 53, and then returned to the compressor 51 again. It has become. Reference numeral 54 is a capillary, and 55 is an expansion valve.
[0003]
In recent years, for example, a mixed refrigerant of R32 / R134a = 1: 1 has been used as an alternative CFC for R-22, and R32 is a high-pressure refrigerant, and R134a is a low-pressure refrigerant.
[0004]
The condenser 52 condenses the gas refrigerant supplied from the compressor 51 by heat exchange into a liquid refrigerant and supplies it to the evaporator 53 via the expansion valve 55.
[0005]
[Problems to be solved by the invention]
However, the conventional condenser 52 has a problem that when the high-pressure refrigerant in the mixed refrigerant cannot be sufficiently condensed, the high-pressure refrigerant (gas) accumulates in the condenser 52 and the high pressure rises.
[0006]
In addition, in order to sufficiently condense the high-pressure refrigerant together with the low-pressure refrigerant, there has been a problem that the capacity of the condenser has to be extremely increased.
[0007]
Therefore, an object of the present invention is to provide a condenser device that can efficiently condense high-pressure refrigerant in a mixed refrigerant.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 is a condenser device for condensing a mixed refrigerant.
Inlet pipe 8a, 9 a and outlet pipe 8b, 9 b an upper condenser part 8 and the lower condenser section 9 having respectively,
The connected to the outlet pipe 9 b of the lower condenser section 9, and the lower condenser section 9 hardly throttling means 1 4 passes is condensed not gas refrigerant in the supplied mixed refrigerant to,
First pipe extending the outlet pipe 9 b of the lower condenser section 9 connected to the upstream portion of the throttle means 1 4 in the vertical direction are connected to the inlet pipe 8 a of the upper condenser part 8 1 and 6 ,
E Bei a second pipe 1 7 that the outlet pipe 8 b of the upper condenser part 8 connected to the piping downstream of the throttle means 1 4,
The mixed refrigerant is supplied from the inlet side pipe 9a of the lower condenser part 9 .
[0009]
The invention of claim 2 is a condenser device for condensing a mixed refrigerant,
Inlet pipe 2 8a, 29a and the outlet pipe 2 8b, an upper condenser part 2 8 and the lower condenser section 2 9 each having a 29 b,
The upper condenser section is connected to the outlet pipe 2 8b of 2 8, and the upper condenser part 2 8 hardly throttle means 3 4 passes is condensed not gas refrigerant in the supplied mixed refrigerant to,
The extending vertically connecting the outlet pipe 2 8b of the upper condenser section 28 connected to the upstream portion of the throttle means 3 4 to the inlet-side pipe 2 9a of the lower condenser section 2 9 1 and the piping 3 6,
E Bei a second pipe 3 7 that the outlet pipe 2 9b of the lower condenser section 2 9 connected to the piping downstream of the throttle means 3 4,
The mixed refrigerant is supplied from the inlet side pipe 28a of the upper condenser part 28, and
A connection portion between the outlet side pipe 28b of the upper condenser portion 28 and the first pipe 36 has a curved portion 36a that is curved so as to protrude above the outlet side pipe 28b .
[0010]
[Action]
According to the present invention, when the mixed refrigerant is supplied from the inlet-side pipes 9a and 28a of the one condenser section 9 and 28 to the one condenser section 9 and 28, the low-pressure refrigerant in the mixed refrigerant at the one condenser section 9 and 28. Is condensed by heat exchange and passes smoothly through the throttle means 14 and 34 connected to the outlet side pipes 9b and 28b as liquid refrigerant.
[0011]
In addition, the high-pressure refrigerant in the mixed refrigerant that has not been condensed in one of the condenser portions 9 and 28 is less likely to pass through the throttle means 14 connected to the outlet-side pipes 9b and 28b as a gas refrigerant, and thus is connected to the outlet-side pipe 9b. The first pipes 16 and 36 are supplied to the other condenser parts 8 and 29 from the inlet side pipes 8 a and 29 a of the other condenser parts 8 and 29.
[0012]
The high-pressure refrigerant supplied to the other condenser parts 8 and 29 is condensed by the second heat exchange, passes through the second pipes 17 and 37 from the outlet side pipes 8b and 29b as liquid refrigerant, and passes through the second condenser parts 9 and 29. , 28 merge with the liquid refrigerant of the low-pressure refrigerant in the downstream portion of the throttle means 14, 34 connected to the outlet side pipes 9b, 28b.
[0013]
Thereby, since the high-pressure refrigerant in the mixed refrigerant is condensed twice, the high-pressure refrigerant does not accumulate in the condenser device, and the high pressure does not increase.
[0014]
Moreover, since the high-pressure refrigerant that has not been condensed is not supplied to the evaporator, the evaporation performance is improved.
[0015]
Further, since heat is exchanged twice in the upper and lower condenser sections, the high-pressure refrigerant is also sufficiently condensed, so that a large-capacity condenser device is not required.
[0016]
Further, when the mixed refrigerant is supplied from the inlet side pipe 9 a of the lower condenser part 9 as in claim 1 , it passes through the first pipe 16 and passes from the inlet side pipe 8 a of the upper condenser part 8 to the upper condenser part. A high-pressure refrigerant is supplied to 8. Accordingly, when the condenser parts 8 and 9 are defrosted, the defrosting is performed in order from the lower condenser part 9, so that even if ice frosted on the upper condenser part 8 falls on the lower condenser part 9, There is no risk of stacking.
[0017]
Further, as in claim 2, the mixed refrigerant is supplied from the inlet side pipe 28a of the upper condenser part 28, and the connection part between the outlet side pipe 28b of the upper condenser part 28 and the first pipe 36 is connected to the outlet side pipe 28b. If the high-pressure refrigerant that has not been condensed in the upper condenser portion 28 passes only upward through the curved portion 36a of the outlet side pipe 28b and the first pipe 36, the curved portion 36a that is curved so as to protrude upward is formed. Therefore, the head difference is small and the pressure loss is small.
[0018]
【Example】
Hereinafter, the present invention will be described in detail based on the illustrated embodiments.
[0019]
[First embodiment]
FIG. 1 shows a capacitor device 7 of the first embodiment. The condenser device 7 is connected between the compressor 1 and the expansion valve 5.
[0020]
The capacitor device 7 has an upper capacitor portion 8 at an upper position and a lower capacitor portion 9 at a lower position.
[0021]
In the first embodiment, the upper condenser section 8 has an inlet side pipe 8a on the right side in the figure and an outlet side pipe 8b on the left side. Moreover, the lower capacitor | condenser part 9 has the inlet side piping 9a on the left side in the figure, and has the outlet side piping 9b on the right side.
[0022]
A header 10 is connected to the outlet side pipe 8 b of the upper condenser part 8, and a header 11 is connected to the inlet side pipe 9 a of the lower condenser part 9.
[0023]
An outlet side pipe 12 from the compressor 1 is connected to a header 11 connected to an inlet side pipe 9 a of the lower condenser unit 9. The outlet side pipe 9b of the lower condenser part 9 is connected to a liquid storage pipe 13, and the liquid storage pipe 13 is connected to a capillary 14 as a throttling means that is difficult for gas refrigerant to pass through. In addition, the capillary 14 is connected to an evaporator (not shown) through the expansion valve 5 through a junction pipe 15.
[0024]
A first pipe 16 extending in the vertical (vertical) direction upstream of the capillary 14 connects the outlet side pipe 9 b of the lower condenser part 9 and the inlet side pipe 8 a of the upper condenser part 8. The first pipe 16 functions as a gas vent pipe.
[0025]
Further, the second pipe 17 having the check valve 18 connects the header 10 connected to the outlet side pipe 8 b of the upper condenser section 8 to the junction pipe 15 at an intermediate portion between the capillary 14 and the expansion valve 15. The check valve 18 allows the refrigerant to pass only in the direction of the arrow y1 in the figure.
[0026]
Further, the third pipe 20 having the check valve 19 connects the header 10 connected to the outlet side pipe 8 b of the upper condenser part 8 to the middle part of the outlet side pipe 12. The check valve 19 allows the refrigerant to pass only in the direction of the arrow y2 in the figure.
[0027]
If it is the structure of the said 1st Example, a mixed refrigerant is supplied to the lower condenser part 9 from the inlet side piping 9a via the outlet side piping 12 and the header 11 from the compressor 1. FIG. Then, in the lower condenser unit 9, mainly the low-pressure refrigerant in the mixed refrigerant is condensed by heat exchange, and the low-pressure refrigerant-rich liquid refrigerant a containing a large amount of low-pressure refrigerant as shown in FIG. And the liquid storage pipe 13 smoothly passes through the capillary 14 and reaches the merging pipe 15.
[0028]
Further, the high-pressure refrigerant that has not been condensed in the lower condenser portion 9 is unlikely to pass through the capillary 14 of the outlet-side pipe 9b as the gas refrigerant b, so that the outlet at the upstream portion of the capillary 14 as shown in FIG. The first pipe 16 connected to the side pipe 9 b passes smoothly and is supplied from the inlet side pipe 8 a of the upper condenser section 8 to the upper condenser section 8.
[0029]
The high-pressure refrigerant (gas refrigerant) supplied to the upper condenser part 8 is condensed by the second heat exchange in the upper condenser part 8 following the lower condenser part 9 and becomes liquid refrigerant. This liquid refrigerant passes through the outlet side pipe 8b, the header 10 and the second pipe 17 in this order, and merges with the liquid refrigerant of the low-pressure refrigerant in the merge pipe 15 between the capillary 14 and the expansion valve 5, and the expansion valve 5 To be supplied to the evaporator.
[0030]
As described above, the high-pressure refrigerant in the mixed refrigerant supplied from the compressor 1 is efficiently condensed together with the low-pressure refrigerant in the lower condenser unit 9 and the upper condenser unit 8, so that the high-pressure refrigerant is contained in the condenser device 7. It will not accumulate and high pressure will not rise. Therefore, the condensation performance of the condenser device 7 is improved.
[0031]
Further, since the high-pressure refrigerant (gas refrigerant) that has not been condensed by the condenser device 7 is not supplied to the evaporator, the evaporation performance of the evaporator is also improved.
[0032]
Further, since the high-pressure refrigerant is sufficiently heat-exchanged and condensed twice in the lower condenser part 9 and the upper condenser part 8, a large-capacity condenser device is not necessary.
[0033]
Furthermore, since the mixed refrigerant is supplied to the lower condenser part 9 and the high-pressure refrigerant is supplied to the upper condenser part 8, the defrosting is sequentially performed from the lower condenser part 9 when the condenser parts 9 and 8 are defrosted. Therefore, when ice frosted on the upper condenser part 8 falls on the lower condenser part 9, defrosting of the lower condenser part 9 has progressed, so that there is no possibility of ice accumulating on the lower condenser part 9.
[0034]
[Second Embodiment]
Next, the capacitor | condenser apparatus 27 of 2nd Example is shown in FIG. The condenser device 27 is connected between the compressor 21 and the expansion valve 35.
[0035]
The capacitor device 27 has an upper capacitor portion 28 at an upper position and a lower capacitor portion 29 at a lower position.
[0036]
The upper condenser part 28 has an inlet side pipe 28a on the left side in the figure and an outlet side pipe 28b on the right side. Further, the lower condenser part 29 has an inlet side pipe 29a on the right side in the figure and an outlet side pipe 29b on the left side.
[0037]
Headers 30 and 31 are connected to the inlet side pipe 28 a of the upper condenser part 28 and the outlet side pipe 29 b of the lower condenser part 29.
[0038]
The outlet side piping 32 of the compressor 21 is connected to the header 30 connected to the inlet side piping 28 a of the upper condenser portion 28. On the other hand, a liquid storage pipe 33 is connected to the outlet side pipe 28 b of the upper condenser section 28, and a capillary 34 is connected to the liquid storage pipe 33 as a throttling means that hardly allows the gas refrigerant to pass through. A merging pipe 35 is connected to the capillary 34, and the merging pipe 35 is connected to an evaporator (not shown) via the expansion valve 25.
[0039]
The first pipe 36 extending in the vertical (vertical) direction connects the outlet side pipe 28 b of the upper condenser part 28 to the inlet side pipe 29 a of the lower condenser part 29 in the upstream part of the capillary 34. The first pipe 36 functions as a gas vent pipe. Further, the second pipe 37 having the check valve 38 connects the header 31 connected to the outlet side pipe 29 b of the lower condenser part 29 to the junction pipe 35 at the intermediate part between the capillary 34 and the expansion valve 35. The check valve 38 allows the refrigerant to pass only in the direction of the arrow y4 in the figure.
[0040]
Further, the third pipe 40 having the check valve 39 connects the header 31 connected to the outlet side pipe 29 b of the lower condenser part 29 to the middle part of the outlet side pipe 32 of the compressor 21. The check valve 39 allows the refrigerant to pass only in the direction of the arrow y3 in the figure.
[0041]
As shown in detail in FIG. 2B, the connection portion between the outlet side pipe 28b of the upper condenser portion 28 and the first pipe 36 has a connection end portion of the first pipe 36 slightly more than the upper part of the outlet side pipe 28b. And a curved portion 36a curved so as to protrude upward. The first pipe 36 extends downward from the curved portion 36a.
[0042]
In the configuration of the second embodiment, the mixed refrigerant is supplied from the compressor 21 through the outlet side pipe 32 and the header 30 to the upper condenser portion 28 from the inlet side pipe 28a. Then, mainly the low-pressure refrigerant in the mixed refrigerant is condensed by heat exchange in the upper condenser section 28, and as shown in FIG. 2B, the low-pressure refrigerant-rich liquid refrigerant a containing a large amount of low-pressure refrigerant is connected to the outlet side pipe 28b. The liquid storage pipe 33 smoothly passes through the capillary 34 and reaches the merging pipe 35.
[0043]
Also, the high-pressure refrigerant that has not been condensed in the upper condenser portion 28 is unlikely to pass through the capillary 34 connected to the outlet side pipe 28b. Therefore, the high-pressure refrigerant smoothly passes through the first pipe 36 connected to the outlet-side pipe 28b upstream of the capillary 34 as the gas refrigerant b as shown in FIG. It is supplied to the lower condenser part 29 from the inlet side pipe 29a.
[0044]
The high-pressure refrigerant (gas refrigerant) supplied to the lower condenser part 29 is condensed by the second heat exchange in the lower condenser part 29 following the upper condenser part 28 to become a liquid refrigerant. This liquid refrigerant passes through the outlet side pipe 29 b, the header 31, and the second pipe 37, and merges with the liquid refrigerant of the low-pressure refrigerant through the merge pipe 35 between the capillary 34 and the expansion valve 25. The combined liquid refrigerant is supplied to the evaporator via the expansion valve 5.
[0045]
As described above, in the second embodiment, as in the first embodiment, the high-pressure refrigerant in the mixed refrigerant supplied from the compressor 21 is condensed twice by the upper condenser portion 28 and the lower condenser portion 29. . Therefore, the high-pressure refrigerant does not accumulate in the condenser device 27, and the high-pressure rise does not occur.
[0046]
Further, since the high-pressure refrigerant (gas refrigerant) that has not been condensed by the condenser device 27 is not supplied to the evaporator (not shown), the evaporation performance of the evaporator is also improved.
[0047]
Further, since the high-pressure refrigerant is sufficiently condensed twice by the upper condenser portion 28 and the lower condenser portion 29, a large-capacity condenser device is not necessary.
[0048]
Furthermore, since the curved portion 36a is formed at the connection portion between the outlet side pipe 28b of the upper condenser portion 28 and the first pipe 36, the high-pressure refrigerant (gas refrigerant b) that has not been condensed in the upper condenser portion 28 is Only the curved portion 36a needs to pass upward, and after this passage, the first pipe 36 can smoothly pass downward. Therefore, according to this embodiment, since the head difference h is small, the pressure loss is reduced.
[0049]
【The invention's effect】
As is clear from the above description, the condenser device of the invention of claim 1 condenses the low-pressure refrigerant in the mixed refrigerant supplied to one of the condenser parts by heat exchange, passes the capillary as a liquid refrigerant, The high-pressure refrigerant in the mixed refrigerant that has not been condensed in one condenser part is supplied to the other condenser part and condensed by performing a second heat exchange to form a liquid refrigerant at the downstream part of the capillary. Are combined with the condensed liquid refrigerant.
[0050]
Therefore, since the high-pressure refrigerant in the mixed refrigerant can be efficiently condensed together with the low-pressure refrigerant, the high-pressure refrigerant does not accumulate in the condenser device, and the high pressure does not increase. Therefore, the condensation performance is improved. Further, since the high-pressure refrigerant that has not been condensed is not supplied to the evaporator, the evaporation performance is improved.
[0051]
In addition, since heat is exchanged twice in the upper and lower condenser sections, the high-pressure refrigerant can be sufficiently condensed, and therefore a large-capacity condenser apparatus is unnecessary.
[0052]
Further, as in the first aspect of the present invention, the mixed refrigerant is supplied from the lower condenser portion, whereby the high-pressure refrigerant is supplied to the upper condenser portion. Therefore, at the time of defrosting each capacitor part, the lower capacitor part can be defrosted earlier than the upper capacitor part. Therefore, even if ice frosted on the upper condenser part falls on the lower condenser part, there is no possibility that the ice will accumulate on the lower condenser part.
[0053]
Furthermore, in the invention of claim 2, the mixed refrigerant is supplied from the upper condenser part, and the connection part between the outlet side pipe and the first pipe of the upper condenser part is curved so as to protrude above the outlet side pipe. It has a curved part. Therefore, the high-pressure refrigerant that has not been condensed in the upper condenser portion only needs to pass upward only through the curved portion. That is, since the head difference can be reduced, the pressure loss is reduced.
[Brief description of the drawings]
FIG. 1 (A) is a configuration diagram of a condenser device according to a first embodiment of the present invention, and FIG. FIG.
FIG. 2 (A) is a configuration diagram of the condenser device of the second embodiment, and FIG. 2 (B) is an enlarged cross-sectional view of a connection portion between the outlet side piping of the upper condenser portion and the first piping. .
FIG. 3 is a configuration diagram of a conventional condenser device.
[Explanation of symbols]
1,21 ... Compressor, 53 ... Evaporator, 5,25 ... Expansion valve,
7,27 ... Condenser device, 8,28 ... Upper condenser part,
8a, 28a ... Inlet side piping, 8b, 28b ... Outlet side piping,
9, 29 ... lower condenser part, 9a, 29a ... inlet side piping,
9b, 29b ... outlet side piping, 14, 34 ... capillary,
16, 36 ... 1st piping, 36a ... Curved part, 17, 37 ... 2nd piping.

Claims (2)

In the condenser device that condenses the mixed refrigerant,
An upper condenser part ( 8 ) and a lower condenser part ( 9 ) having an inlet side pipe (8 a, 9 a ) and an outlet side pipe (8 b, 9 b ) , respectively;
The lower condenser section (9) is connected to the outlet pipe (9 b) of said lower capacitor section (9) is supplied to the condensed no gas refrigerant passes hardly throttle means in the mixed refrigerant (1 4) When,
And the throttling means (1 4) the lower condenser section connected to the upstream portion of the outlet pipe (9 b) of (9) connected to the inlet side pipe (8 a) of the upper condenser section (8) A first pipe (1 6 ) extending in the vertical direction,
E Bei and the upper condenser part and the second pipe (1 7) to the outlet side piping (8 b) is connected to the piping downstream of the throttle means (1 4) (8),
A condenser device, wherein a mixed refrigerant is supplied from an inlet side pipe ( 9a ) of the lower condenser part ( 9 ) . In the condenser device that condenses the mixed refrigerant,
Inlet pipe (2 8a, 29a) and an upper condenser section having outlet pipe (2 8b, 29 b) respectively (28) and the lower condenser section (2 9),
Is connected to the upper condenser part outlet pipe (28) (2 8b), said upper condenser section (28) is supplied to the condensed no gas refrigerant passes hardly throttle means in the mixed refrigerant (3 4) and
The throttle means (3 4) the upper capacitor section connected to the upstream portion of the outlet pipe (28) and (2 8b) connected to the inlet side pipe (2 9a) of the lower condenser section (2 9) and it has a first pipe extending vertically and (3 6),
E Bei and the lower condenser section second pipe (3 7) to the outlet side piping (2 9b) is connected to the piping downstream of the throttle means (3 4) (2 9),
The mixed refrigerant is supplied from the inlet side pipe ( 28a ) of the upper condenser part ( 28 ) ,
Curved portion connecting portion of the outlet pipe and (28b) and said first pipe (36) is curved so as to protrude above the said outlet pipe (28b) of the upper condenser section (28) and (36a) Condenser device characterized by having .

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