EP1348921B1

EP1348921B1 - Refrigerant distributor and air conditioner using the same

Info

Publication number: EP1348921B1
Application number: EP02254634A
Authority: EP
Inventors: Akira c/o Mitsubishi Denki Kabushiki K. Takamori
Original assignee: Mitsubishi Electric Corp
Current assignee: Mitsubishi Electric Corp
Priority date: 2002-03-28
Filing date: 2002-07-02
Publication date: 2008-04-09
Anticipated expiration: 2022-07-02
Also published as: EP1348921A3; AU2002300117B2; JP2003287320A; EP1348921A2; AU2002300117A1; ES2300422T3

Description

The present invention relates to a refrigerant distributor and an air conditioner using the same.
Fig. 5 is a schematic block diagram showing a common refrigerant circuit of an air conditioner of the kind disclosed, for example, in the Japanese Patent Laid-Open Publication No. Hei. 10-253196 . In the figure, reference numeral 1 denotes a compressor, 2 an outdoor heat exchanger (condenser), 3 a pressure reduction capillary tube (pressure reduction device), 4 a refrigerant distributor, 5 an indoor heat exchanger (evaporator), 6 an accumulator, and 7 refrigerant pipes. The refrigerant circuit is constituted by connecting, one by one with the refrigerant pipes 7, the compressor 1, the outdoor heat exchanger 2, the pressure reduction capillary tube 3, the refrigerant distributor 4, the indoor heat exchanger 5, and the accumulator 6.
Fig. 6 is a side cross-sectional view of a conventional refrigerant distributor of an air conditioner. In the figure, reference numeral 7a denotes a distributor refrigerant-pipe and 8 denotes a refrigerant-distributor main body having distributor holes and a gas-liquid mixing chamber 9. Reference numeral 10 denotes an orifice member having a conical orifice 10a with a cross-sectional area gradually reducing toward an end of the orifice so as to increase of a contracted refrigerant flow through the orifice. A flat-plate orifice 11 is arranged at an end of the orifice member on the side of the gas-liquid mixing chamber 9. The distributor refrigerant-pipe 7a is inserted into a bore of the refrigerant-distributor main body 8, and the orifice member 10 and the flat-plate orifice 11 are sandwiched and fixed between an end face of the distributor refrigerant-pipe 7a and a stepped portion of the bore of the refrigerant-distributor main body 8. Reference numeral 12 denotes a fine particle conversion mean having a large number of holes, which divides the gas-liquid mixing chamber 9 into a first gas-liquid mixing chamber 9a and a second gas-liquid mixing chamber 9b, and is formed, for example, of a cage-formed steel net. Reference numeral 13 denotes a plurality of distribution holes formed in the refrigerant-distributor main body 8 and connected to the second gas-liquid mixing chamber 9b. Reference numeral 14 denotes a distribution pipe inserted into a distribution hole 13.
Next, operation of a conventional air conditioner will be described below. A gaseous refrigerant with high temperature and high pressure compressed and discharged by the compressor 1 is condensed through the exchange of heat with the outdoor air to turn into a liquid refrigerant with high pressure, while passing through the outdoor heat exchanger 2. Next, the refrigerant is rapidly reduced in pressure and expanded to turn into a gas-liquid two-phase refrigerant with low pressure while the refrigerant passes through the pressure reduction capillary tube 3. The refrigerant is then distributed by the refrigerant distributor 4 and the distribution pipe 14 and sent to respective refrigerant flow passages of the indoor heat exchanger 5. The gas-liquid two-phase refrigerant evaporates through the exchange of heat with the indoor air to turn into a gaseous refrigerant with low pressure. The gaseous refrigerant with low pressure flows through the accumulator 6, and is sucked by the compressor 1. Then, the refrigerant is again compressed and discharged, thereby the same operation is repeated in this refrigerant flow passage.
In the refrigerant distributor 4 arranged in the refrigerant flow passage, the low pressure gas-liquid two phase refrigerant first passes through the distributor refrigerant-pipe 7a, and its flow is contracted by the conical orifice 10a and then discharged into the gas-liquid mixing portion 9 to uniformly mix the gaseous portion and liquid portion of the gas-liquid two-phase refrigerant, so that the gas-liquid two-phase refrigerant is made homogeneous. The refrigerant is then led to the distribution pipe 14 to be equally distributed.
The conical orifice 10a gradually increases flow speed of the gas-liquid two-phase refrigerant so that rapid pressure drop of the refrigerant is prevented. Further, through the flat-plate orifice 11 arranged at the outlet of the conical orifice 10a, the gas-liquid two-phase refrigerant is discharged into the first gas-liquid mixing chamber 9a, so that its flow speed becomes a maximum value, and the difference in flow speed between the gaseous portion and liquid portion of the gas-liquid two-phase refrigerant becomes a minimum value. The gaseous and liquid portions of the refrigerant are diffused and mixed, there. After that, the liquid portion of the refrigerant is made finer in size by the steel net 12 as the fine particle conversion means, and the finer refrigerant liquid for distribution is distributed from the second gas-liquid mixing chamber 9b to each of the distribution holes 13.
The conventional refrigerant distributor of an air conditioner is, as described above, basically constituted by a plurality of parts including the distributor refrigerant-pipe 7a, the refrigerant-distributor main body 8, the conical orifice 10a, the flat plate orifice 11, and the steel net 12 that are not unified together. Therefore, a problem has occurred, where individual parts become loose and collision sounds are generated between them while the refrigerant flows.
Besides the above-mentioned example of a conventional refrigerant distributor, other techniques are disclosed by, for example, Japanese Patent Laid-Open Publication Nos. Hei. 9-138036 and 2001-194028 in which a steel net as a fine particle conversion means is fitted under pressure into a pipe, an orifice is directly formed in a pipe or a refrigerant distributor is unified with a portion into which a steel net is fitted. However, in such disclosures, there are no proposals to fit a steel net integrally and securely in a distributor. Therefore, the refrigerant distributors in such disclosures have the same problem as the above-described example that the steel net becomes loose and generates collision sounds while the refrigerant flows.
JP 2000-081256A relates to a distributor for uniformly distributing a mixture fluid and for reducing noise generation.
An object of the invention is to further promote the fixing and unifying of parts constituting a refrigerant distributor to prevent generation of collision sounds between the parts while a refrigerant flows.
The refrigerant distributor according to the invention is constituted as described below. As set forth in claim 1, a refrigerant distributor arranged between a pressure reduction device and an evaporator in a refrigerant circuit, comprises; a distributor refrigerant-pipe, an orifice member which is received in the distributor refrigerant-pipe and has an orifice for increasing flow speed of refrigerant introduced from the distributor refrigerant-pipe, a fine particle conversion means for converting liquid droplets included in the refrigerant having the flow speed increased by the orifice, into finer particles, and a refrigerant-distributor main body which is externally fitted on the refrigerant pipe and has distribution holes for distributing the refrigerant including the liquid droplets converted into finer particles by the fine particle conversion means, that are arranged in order in a flow direction of the refrigerant. In this constitution, the orifice member is firmly fixed to and unified with the fine particle conversion means, and the orifice member unified with the fine particle conversion means is firmly fixed to and unified with the distributor refrigerant-pipe.
In the refrigerant distributor, as set forth in claim 1, the orifice member has at its one end a short outer tube in a monolithic structure, the orifice is formed as a conical orifice having a cross-sectional area gradually reducing toward an end of the orifice so that a speed of a contracted refrigerant flow through the orifice is increased, the fine particle conversion means is constituted by a cage-formed member having a large number of holes, the orifice member is firmly fixed to and unified with the fine particle conversion means in such a manner that an edge portion of the fine particle conversion means is sandwiched between the inner periphery of the short outer tube and the outer periphery of an inner tube constituted by a main body of the orifice member. The orifice member unified with the fine particle conversion means is firmly fixed to and unified with the distributor refrigerant-pipe by swaging an edge of the distributor refrigerant-pipe from outside with the short outer tube of the orifice member.
Further, as set forth in claim 2, annular projection portions are provided on the inner periphery of the short outer tube and the outer periphery of the inner tube of the orifice member, to be arranged at positions separated from one another in an axial direction of the tubes, so that the edge portion of the fine particle conversion means is sandwiched by the annular projection portions in a labyrinth form, and fixed to the orifice member firmly.
Further, an air conditioner using the refrigerant distributor of the present invention is constituted as described below. That is, as set forth in claim 3, in an air conditioner having a refrigerant distributor arranged between a pressure reduction device and an evaporator in a refrigerant circuit comprising a compressor, a condenser, the pressure reduction device, and the evaporator that are connected by refrigerant pipes, the refrigerant distributor is constituted by a distributor refrigerant-pipe connected with the refrigerant-pipe, an orifice member which is received in the distributor refrigerant-pipe and has an orifice for increasing flow speed of refrigerant introduced from the distributor refrigerant-pipe, a fine particle conversion means for converting liquid droplets included in the refrigerant having the flow speed increased by the orifice into finer particles, and a refrigerant-distributor main body which is externally fitted onto the distributor refrigerant-pipe and has distribution holes for distributing the refrigerant including the liquid droplets converted into finer particles by the fine particle conversion means. Further, the orifice member is firmly fixed to and unified with the fine particle conversion means, and the orifice member unified with the fine particle conversion means is firmly fixed to and unified with the distributor refrigerant-pipe.
Further, in an air conditioner using the refrigerant distributor, as set forth in claim 3, the orifice member has at its one end a short outer tube in a monolithic structure, the orifice is formed as a conical orifice with a cross-sectional area gradually reducing toward an end of the orifice so that a speed of a contracted refrigerant flow through the orifice is increased, the fine particle conversion means is constituted by a cage-formed member having a large number of holes, the orifice member is firmly fixed to and unified with the fine particle conversion means in such a manner that an edge portion of the fine particle conversion means is sandwiched between the inner periphery of the short outer tube and the outer periphery of an inner tube constituted by a main body of the orifice member. Further, the orifice member unified with the fine particle conversion means is fixed to and unified with the distributor refrigerant-pipe by swaging an edge of the distributor refrigerant-pipe from the outside with the outer tube of the orifice member.
Further, as set forth in claim 3, annular projection portions are provided on the inner periphery of the short outer tube and the outer periphery of the inner tube of the orifice member to be arranged at positions separated from one another in an axial direction of the pipe. The edge portion of the fine particle conversion means is sandwiched by the annular projection portions in a labyrinth form and fixed to the orifice member firmly.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a side cross-sectional view of a refrigerant distributor assembly according to a first embodiment of the invention.
Fig. 2 is an explanatory drawing showing assembling procedures of parts constituting the refrigerant distributor according to the first embodiment of the invention.
Fig. 3 is an explanatory drawing showing assembling procedures of parts constituting the refrigerant distributor according to the first embodiment of the invention.
Fig. 4 is an explanatory drawing showing the relationship between an orifice member and a fine particle conversion means which are essential elements of a refrigerant distributor, according to a second embodiment of the invention.
Fig. 5 is a schematic block diagram showing a common refrigerant circuit of an air conditioner.
Fig. 6 is a side cross-sectional view of a conventional refrigerant distributor of an air conditioner.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiment

1

The present invention will be described below referring to embodiments illustrated in the figures. Fig. 1 is a side cross-sectional view of a refrigerant distributor assembling according to a first embodiment of the invention, and Figs. 2 and 3 are explanatory drawings illustrating assembling procedures of parts constituting the refrigerant distributor. Parts in the figures that correspond to those in the example described above of a conventional refrigerant distributor are denoted by the same reference numerals.
In Fig. 1, reference numeral 4A denotes a refrigerant distributor, 7A a refrigerant pipe, 7a a distributor refrigerant-pipe, 8A a refrigerant-distributor main body which is externally fitted onto the refrigerant pipe 7A and has a bore and distribution holes. A step portion 8a is arranged in the bore of the main body at a position halfway in an axial direction along the bore, and a gas-liquid mixing chamber 9 is formed at the deepest portion of the bore. Reference numeral 10A denotes an orifice member having a flange portion 10b at the outer periphery of its base end and formed as a conical orifice 10a with its inside cross-sectional area gradually reducing toward the end of the orifice so that speed of a refrigerant flow contracted by the orifice is increased. The flange portion 10b of the orifice member 10A is bent at its outer periphery side, toward a main body of the orifice member to form a short outer tube 10c. An edge portion 12a (Fig. 2) of a cage-formed steel net 12A as a fine particle conversion means which is provided with a large number of holes for dividing the gas-liquid mixing chamber 9 into a first gas-liquid mixing chamber 9a and a second a gas-liquid mixing chamber 9b, is sandwiched between the inner periphery of the short outer tube 10c and the outer periphery of an inner tube constituted by the main body of the orifice member and is firmly fixed to the orifice member 10A. Further, the distributor refrigerant-pipe 7a is swaged, from the outside, at its end at a swage portion 7b together with the end of the outer tube 10c. Thus, the orifice member 10A, the steel net 12A, and the distributor refrigerant-pipe 7a are solidly fixed to each other and unified together. The assembly of the orifice member 10A, the steel net 12A, and the distributor refrigerant-pipe 7a that are solidly fixed to each other and unified together is further solidly fixed to the refrigerant-distributor main body 8A in such a manner that the swage portion 7b contacts with the step portion 8a in the bore of the refrigerant-distributor main body 8A, and the refrigerant-distributor main body 8A and the distributor refrigerant-pipe 7a are connected by welding 15. Reference numeral 13 denotes a plurality of distribution holes formed in the refrigerant-distributor main body 8A and connected through to the second gas-liquid mixing chamber 9b. Reference numeral 14 denotes a distribution pipe inserted into a distribution hole 13.
Incidentally, the constitution and operation of a refrigerant circuit in an air conditioner using the refrigerant distributor 4A according to the invention are basically the same as those of the conventional example described above (Fig. 5), and the description thereof is omitted.
Next, assembling procedures of the parts constituting the refrigerant distributor according to the embodiment will be described below referring to Figs. 1 to 3. As shown in Fig. 2, the main body of the orifice member 10A is first inserted into the cage-formed steel net 12A. Then, the flange portion 10b of the orifice member 10A is bent to form the outer tube 10c. Also at the same time, the edge portion 12a of the steel net 12A is sandwiched between the outer tube 10c and the inner tube that is formed as a part of the main body of the orifice member 10A so that a first unified part comprising the orifice member 10A and the steel net 12A firmly fixed thereto is formed.
Then, as shown in Fig. 3, the first unified part described above is inserted into the distributor refrigerant-pipe 7a from the side of the flange 10b, and an end side of the distributor refrigerant-pipe 7a is swaged at the swage portion 7b, to form a second unified part comprising the first unified part and the distributor refrigerant-pipe 7a firmly fixed thereto.
Next, as shown in Fig. 1, the second unified part is inserted into the refrigerant-distributor main body 8A up to the position where the swaged portion 7b contacts with the step portion 8a. Then, the distributor refrigerant-pipe 7a and the refrigerant-distributor main body 8A are welded at a weld portion 15. Thereby, a third unified part (a complete unit) comprising the second unified part and the refrigerant-distributor main body 8A firmly fixed thereto is formed.
As described above, in the refrigerant distributor according to the embodiment, the constituent parts are fixed to each other and unified together in the steps of the first, second, and third unified parts, taken toward the complete unit. Therefore, when the distributor is incorporated into and used in the refrigerant circuit of an air conditioner, collisions do not occur between the respective parts while a refrigerant flows, so that generation of collision sounds is prevented.

Embodiment 2

Fig. 4 is an explanatory drawing showing the relationship between an orifice member and a fine particle conversion means, both of which are essential elements of the refrigerant distributor according to a second embodiment of the invention. Parts in the figures that correspond to those in the first embodiment are denoted by the same reference numerals.
The refrigerant distributor according to the embodiment is different from that of the first embodiment as follows. In the second embodiment, annular projection portions 10d are provided on a surface of the flange 10b, which will turn to the inner periphery of the outer tube 10c after bending, and an annular projection portion 10e is provided on the outer periphery of the inner tube constituted by the main body of the orifice member 10A. In this constitution, the annular projection portions 10d and 10e are arranged such that, when the flange 10b is bent, they are at positions separated from one another in an axial direction of the tubes. Accordingly, when the flange 10b is bent to form the short outer tube 10c, the edge portion 12a of the cage-formed steel net 12A as fine particle conversion means is sandwiched in a labyrinth form by the annular projections 10d and 10e, so that the orifice member 10A and the steel net 12A are firmly fixed to each other and unified together. Constitutions other than those described above are the same as those of the first embodiment described above.
Next, assembling procedures of parts constituting the refrigerant distributor according to the embodiment will be described below using Fig. 4 and referring to Figs. 1 and 3. First, as shown in Fig. 4, the main body of the orifice member 10A is inserted into the cage-formed steel net 12A. Then, the flange 10b of the orifice member 10A is bent to form the outer tube 10c, while at the same time, the edge portion 12a of the steel net 12A is sandwiched in a labyrinth form by the annular projections 10d and 10e. Thus, a first unified part comprising the orifice member 10A and the steel net 12A firmly fixed thereto is formed.
Then, as shown in Fig. 3, the first unified part described above is inserted into the distributor refrigerant-pipe 7a from the side of the flange 10b, and an end side of the distributor refrigerant-pipe 7a is swaged at the swage portion 7b. Thereby, a second unified part comprising the first unified part and the distributor refrigerant-pipe 7a firmly fixed thereto is formed.
Next, as shown in Fig. 1, the second unified part is inserted into the refrigerant-distributor main body 8A up to the position where the swaged portion 7b contacts with the step portion 8a. Then, the distributor refrigerant-pipe 7a and the refrigerant-distributor main body 8A are welded at a weld portion 15. Thus, a third unified part (a complete unit) comprising the second unified part and the refrigerant-distributor main body 8A firmly fixed thereto is formed.
In the refrigerant distributor according to the embodiment, as described above, in the step of producing the first unified part comprising the orifice member 10A and the steel net 12A firmly fixed thereto, the edge portion 12a of the steel net 12A is sandwiched, in a labyrinth form, by the annular projection portions 10d and 10e of the orifice member 10A so as to be more solidly fixed. Therefore, when the refrigerant distributor is incorporated into and used in the refrigerant circuit of an air conditioner, collisions do not occur between respective parts while the refrigerant flows, so that the generation of collision sounds is prevented.
Although each of the above embodiments is described with an example of a refrigerant distributor using the cage-formed steel net as a fine particle conversion mean, a cage-formed punched metal can be used instead. Function and effect equivalent to those of each embodiment described above are obtainable in this case as well.
Further, in each of the above embodiments, the orifice of the orifice member has a conical shape as an example. However, the shape of the orifice is not limited to a conical one, and any shape that gradually reduces its bore cross-sectional area can satisfy the requirement. Other shape such as a pyramid shape, for example, can also be adopted.
As described above, according to the invention as set forth in claim 1, the orifice member is firmly fixed to and unified with the fine particle conversion means, and the orifice member unified with the fine particle conversion means is further firmly fixed to and unified with the refrigerant pipe. Accordingly, the parts constituting the refrigerant distributor can be solidly unified together at a plurality of steps taken toward the complete unit.
Further, according to the invention as set forth in claim 1, the orifice member has at its one end a short outer tube unified therewith, and is formed as a conical orifice having a cross-sectional area gradually reducing toward an end of the orifice so that a speed of a contracted refrigerant flow through the orifice is increased, the fine particle conversion means is constituted by a cage-formed member having a large number of holes, the orifice member and the fine particle conversion means are firmly fixed to each other and unified together in such a manner that an edge portion of the fine particle conversion means is sandwiched between the inner periphery of the outer tube of the orifice member and the outer periphery of an inner tube constituted by the main body of the orifice member, and the orifice member unified with the fine particle conversion means is firmly fixed to and unified with the distributor refrigerant-pipe by swaging the distributor refrigerant-pipe, from the outside, at its end at a swage portion together with an edge of the outer tube of the orifice member. Because of the constitution described above, individual parts constituting the refrigerant distributor can be solidly fixed at a plurality of steps taken toward the complete unit, so that the refrigerant distributor solidly unified together can be easily obtained.
Further, according to the invention as set forth in claim 2, the annular projection portions are provided on the inner periphery of the outer tube of the orifice member and the outer periphery of the inner tube constituted by the orifice-member main body, so as to be arranged at positions separated from one another in an axial direction of the tube and the edge portion of the fine particle conversion means is sandwiched between the annular projection portions in a labyrinth form, so as to be firmly fixed to the orifice member. Therefore, the refrigerant distributor can be more solidly unified from the early stage of the assembling procedures of the parts.
Further, in the air conditioner, according to the invention as set forth in claim 3, a refrigerant distributor is arranged between the pressure reduction device and the evaporator in a refrigerant circuit which comprises a compressor, a condenser, a pressure reduction device, and an evaporator that are connected by refrigerant pipes. The refrigerant distributor is constituted by an orifice member which is received in the distributor refrigerant-pipe and has an orifice for increasing flow speed of a refrigerant, fine particle conversion means for converting liquid droplets in the refrigerant with a speed increased by the orifice, into finer particles, and a refrigerant-distributor main body which is externally fitted onto the distributor refrigerant-pipe and has distribution holes for distributing the refrigerant converted to fine particles by the fine particle conversion means. Further, the orifice member and the fine particle conversion means are firmly fixed to each other and unified together, and the orifice member unified with the fine particle conversion means is further firmly fixed to and unified with the distributor refrigerant-pipe. Because of the constitution described above, no collisions occur between respective parts while the refrigerant flows, so that generation of collision sounds can be prevented.
Further, in the air conditioner, according to the invention as set forth in claim 3, the orifice member has at its one end a short outer tube unified therewith, and is formed as a conical orifice having a cross-sectional area gradually reducing toward an end of the orifice so that a speed of a contracted refrigerant flow through the orifice is increased, the fine particle conversion means is constituted by a cage-formed member having a large number of holes, the orifice member and the fine particle conversion means are firmly fixed to each other and unified together in such a manner that an edge portion of the fine particle conversion means is sandwiched between the inner periphery of the outer tube of the orifice member and the outer periphery of the inner tube constituted by the main body of the orifice member, and the orifice member unified with the fine particle conversion means is firmly fixed to and unified with the distributor refrigerant-pipe by swaging the distributor refrigerant-pipe, from the outside, at its end at a swage portion together with an edge of the outer tube of the orifice member. Because of the constitution described above, no collisions occurs between respective parts while the refrigerant flows, so that an air conditioner in which generation of collision sounds can be prevented is easily obtained.
Further, in the air conditioner according to the invention as set forth in claim 3, the annular projection portions are provided on the inner periphery of the outer tube of the orifice member and the outer periphery of the inner tube constituted by the orifice-member main body, so as to be arranged at positions separated from one another in an axial direction of the tube. The edge portion of the fine particle conversion means is sandwiched, in a labyrinth form, between the annular projection portions, so as to be firmly fixed to the orifice member. Because of the constitution described above, individual parts constituting the refrigerant distributor are solidly unified, and collisions between the individual parts are completely eliminated, so that generation of collision sounds can be securely prevented.

Claims

A refrigerant distributor (4A) arranged between a pressure reduction device (3) and an evaporator (5) in a refrigerant circuit, comprising a distributor refrigerant-pipe (7a), an orifice member (10A) which is received in the distributor refrigerant-pipe (7a) and has an orifice (10a) for increasing flow speed of refrigerant introduced from the distributor refrigerant-pipe (7a), a fine particle conversion means (12A) for converting liquid droplets included in the refrigerant having the flow speed increased by the orifice (10a), into finer particles, and a refrigerant-distributor main body (8A) which is externally fitted on the distributor refrigerant-pipe (7a) and has distribution holes for distributing the refrigerant including the liquid droplets converted into finer particles by the fine particle conversion means (12A), that are arranged in order in a flow direction of the refrigerant, characterised in that
the orifice member (10A) is firmly fixed to and unified with the fine particle conversion means (12A), and the orifice member (10A) unified with the fine particle conversion means (12A) is firmly fixed to and unified with the distributor refrigerant-pipe (7a), wherein the orifice member (10A) has at its one end a short outer tube (10c) in a monolithic structure, the orifice (10a) is formed as a conical orifice having a cross-sectional area gradually reducing toward an end of the orifice (10a) so that a speed of a contracted refrigerant flow through the orifice (10a) is increased,
the fine particle conversion means (12A) is constituted by a cage-formed member having a large number of holes,
the orifice member (10A) is firmly fixed to and unified with the fine particle conversion means (12A) in such a manner that an edge portion of the fine particle conversion means (12A) is sandwiched between an inner periphery of the short outer tube (10c) and an outer periphery of an inner tube constituted by a main body of the orifice member (10A), and
the orifice member (10A) unified with the fine particle conversion means (12A) is firmly fixed and unified with the distributor refrigerant-pipe (7a) by swaging an edge of the distributor refrigerant-pipe (7a) from outside with the short outer tube (10c) of the orifice member (10A).
A refrigerant distributor (4A) according to claim 1, wherein annular projection portions (10d, 10e) are provided on the inner periphery of the short outer tube (10c) and the outer periphery of the inner tube of the orifice member (10A) to be arranged at positions separated from one another in an axial direction of the tubes, so that the edge portion of the fine particle conversion means (12A) is sandwiched by the annular projection portions (10d, 10e) in a labyrinth form, and fixed to the orifice member firmly.
An air conditioner having a refrigerant distributor according to claim 1 or 2 the refrigerant circuit comprising a compressor (1), a condenser (2), the pressure reduction device (3), and the evaporator (5) that are connected by refrigerant pipes (7), and
the distributor refrigerant-pipe (7a) being connected with the refrigerant pipe (7).