JP2010127601A - Air conditioner - Google Patents

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JP2010127601A
JP2010127601A JP2008306427A JP2008306427A JP2010127601A JP 2010127601 A JP2010127601 A JP 2010127601A JP 2008306427 A JP2008306427 A JP 2008306427A JP 2008306427 A JP2008306427 A JP 2008306427A JP 2010127601 A JP2010127601 A JP 2010127601A
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heat exchanger
pipe
refrigerant
branch
outdoor heat
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JP5071685B2 (en
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Makoto Araki
誠 荒木
Hideji Taki
英司 滝
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Fujitsu General Ltd
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Fujitsu General Ltd
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Abstract

<P>PROBLEM TO BE SOLVED: To equalize a heat exchanging capacity by decreasing circulation resistance at an upper section and increasing the same at a lower section according to distribution of wind velocity while standardizing constitutions of a flow dividing pipe, a flow divider and a branch pipe for the upper section and the lower section. <P>SOLUTION: In this air conditioner which includes a compressor, a four-way valve, an outdoor heat exchanger, a pressure reducer and an indoor heat exchanger, and in which the outdoor heat exchanger is vertically disposed, and the outside air is sucked by an upper air blower to exchange heat, further includes a lower flow divider for dividing the refrigerant so that the refrigerant flows to the flow dividing pipe connected with a heat transfer pipe at a lower section of the outdoor heat exchanger, a plurality of upper flow dividers of the number more than that of the lower flow divider for dividing the refrigerant so that the refrigerant flows to the flow dividing pipe connected with a heat transfer pipe at an upper section of the outdoor heat exchanger, a main pipe connected with a refrigerant inlet/outlet pipe, a branch pipe for the lower heat exchanger branched from the main pipe and connected with the lower flow divider, and a plurality of branch pipes for upper heat exchanger, branched from the main pipe and connected with the plurality of upper flow dividers. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

本発明は、室外機の熱交換器を、内部の機器の外周を囲むように縦向きに配置し、上部に設けた送風機で外部空気を熱交換器の放熱フィンの間から吸引して外部空気と熱交換を行うようにした上吹きタイプの室外機を備えた空気調和機に関するものである。   In the present invention, the heat exchanger of the outdoor unit is arranged vertically so as to surround the outer periphery of the internal device, and the external air is sucked from between the radiating fins of the heat exchanger by the blower provided at the top. The present invention relates to an air conditioner including an up-blowing type outdoor unit that exchanges heat with the outside.

図2に示すように、一般的な空気調和機は、室外機10と室内機11からなり、室外機10の室外熱交換器12、四方弁13、圧縮機14から室内機11の室内熱交換器16、減圧器17へと順次環状に配置して構成される。なお、減圧器17は、室外機10側に設けてもよい。
図3(a)(b)及び図4(a)(b)に示すように、前記室外熱交換器12は、例えば、正面の操作部28以外の3方から内部の機器の外周を囲むように縦向きに配置され、室外熱交換器12の伝熱管24を流れる冷媒は、機枠27の上部に設けた送風機15で外部空気を放熱フィン33の間から吸引して外部空気と熱交換されて蒸発又は凝縮する。図示例では、前記室外熱交換器12は、上部室外熱交換器12aと下部室外熱交換器12bを上下2段に重ねて設けている。
As shown in FIG. 2, a general air conditioner includes an outdoor unit 10 and an indoor unit 11. The outdoor heat exchanger 12, the four-way valve 13, and the compressor 14 of the outdoor unit 10 exchange indoor heat in the indoor unit 11. Are arranged in an annular fashion in order to the decompressor 16 and the decompressor 17. Note that the decompressor 17 may be provided on the outdoor unit 10 side.
As shown in FIGS. 3 (a), 3 (b) and 4 (a), 4 (b), the outdoor heat exchanger 12 surrounds the outer periphery of the internal device from, for example, three sides other than the operation unit 28 on the front. The refrigerant flowing vertically through the heat transfer pipe 24 of the outdoor heat exchanger 12 is exchanged with the external air by sucking external air from between the radiation fins 33 by the blower 15 provided at the top of the machine frame 27. Evaporate or condense. In the illustrated example, the outdoor heat exchanger 12 includes an upper outdoor heat exchanger 12a and a lower outdoor heat exchanger 12b that are stacked in two upper and lower stages.

このような上吹きタイプの室外熱交換器12では、図3(b)に示すように、風速分布特性が室外熱交換器12の上端からやや下方が最も速く、下部に至るに従い順次遅くなり、これに伴い、熱交換能力も下部に行くに従い低下する傾向を有する。そのため、伝熱管24を流れる冷媒の分流比を、上方で大きく、下方で小さくなるようにすることが望ましい。   In such an up-blowing type outdoor heat exchanger 12, as shown in FIG. 3 (b), the wind speed distribution characteristic is the fastest from the top to the bottom of the outdoor heat exchanger 12, and gradually slows down to the bottom. Along with this, the heat exchange capacity also tends to decrease as it goes downward. For this reason, it is desirable that the diversion ratio of the refrigerant flowing through the heat transfer tube 24 is large at the top and small at the bottom.

この問題点を解決するために、図5に示すように、内部で分流比を調整できる主分流器19と、同様に内部で分流比を調整できる副分流器20を用いる方法が提案されている(特許文献1)。
詳細に説明すると、水平な複数の伝熱管24をU字管34で順次接続して室外熱交換器12を構成し、この室外熱交換器12の最下方部に位置し、かつ、出入り口配管21に接続して主分流器19を設け、この主分流器19の下流(暖房時の冷媒の流れの方向で、機械的構成では上部)に2個の副分流器20a、20bを設け、これらの副分流器20a、20bにそれぞれ分流管23a1、23a2、23b1、23b2の一端部を接続し、これらの分流管23a1、23a2、23b1、23b2の他端部を各伝熱管24の端部の連結部35に接続している。
In order to solve this problem, as shown in FIG. 5, there has been proposed a method using a main shunt 19 capable of adjusting the shunt ratio internally and a sub shunt 20 capable of adjusting the shunt ratio similarly. (Patent Document 1).
More specifically, a plurality of horizontal heat transfer tubes 24 are sequentially connected by a U-shaped tube 34 to constitute the outdoor heat exchanger 12, located at the lowermost portion of the outdoor heat exchanger 12, and the entrance / exit pipe 21. The main shunt 19 is connected to the main shunt 19, and two sub shunts 20 a, 20 b are provided downstream of the main shunt 19 (in the direction of the refrigerant flow during heating, and in the upper part in the mechanical configuration). One end of each of the flow dividing pipes 23a1, 23a2, 23b1, 23b2 is connected to the auxiliary flow dividers 20a, 20b, and the other end of these flow dividing pipes 23a1, 23a2, 23b1, 23b2 is connected to the end of each heat transfer pipe 24. 35 is connected.

このような構成において、冷媒は、主分流器19により2つに分流されて冷媒配管22aを経て副分流器20aに至り、また、冷媒配管22bを経て副分流器20bに至り、これら副分流器20a、20bによりそれぞれさらに分流されて分流管23a1、23a2、23b1、23b2を介して室外熱交換器12に流入する。
そして、最も下方に位置する分流管23b2は、他の分流管23a1、23a2、23b1に比べて小径に設定されて流通抵抗が大きくなるようにしている。
冷媒の分流比率を変える手段として、配管の径を異ならせる以外に、副分流器20bの内部の2つの冷媒通路のうち分流管23b2が接続されている側に流動抵抗を設ける方法、内部の2つの冷媒通路を偏心させておく方法が開示されている。
特開2008−75929号公報。
In such a configuration, the refrigerant is divided into two by the main flow divider 19 and reaches the sub-divider 20a via the refrigerant pipe 22a, and further reaches the sub-divider 20b via the refrigerant pipe 22b. The flow is further divided by 20a and 20b and flows into the outdoor heat exchanger 12 through the flow dividing pipes 23a1, 23a2, 23b1 and 23b2.
The lowermost branch pipe 23b2 is set to have a smaller diameter than the other branch pipes 23a1, 23a2, and 23b1, so that the flow resistance is increased.
As a means for changing the refrigerant branching ratio, in addition to changing the pipe diameter, a method of providing a flow resistance on the side where the branch pipe 23b2 is connected in the two refrigerant paths inside the sub-divider 20b, A method of keeping one refrigerant passage eccentric is disclosed.
Japanese Patent Application Laid-Open No. 2008-75929.

以上のような特許文献1記載の方法には、次のような問題点を有する。
(1)分流管23a1、23a2、23b1、23b2は、1本ずつしか図示されていないが、実際は、多数本で構成されているため、図5のように副分流器20bに接続された分流管23b1と23b2の径を異ならせると、分流管と副分流器20bとの接続個所と、分流管と連結部35との接続個所が多数あるにもかかわらず、管径に応じて決められた個所にしか接続できず、製造、組み立ての作業性が悪い。
(2)分流管の管径を同一にして、副分流器20bの内部の冷媒通路のうち分流管23b2が接続される側に流動抵抗を設ける方法では、複数本ずつの分流管23b1、23b2の接続される個所が同一形状であるにもかかわらず、分流管23b1、23b2の接続個所が流動抵抗の有無によって予め決められており、組み立て作業性が悪いだけでなく、誤接続の恐れがある。
(3)内部の2つの冷媒通路を偏心させて分流管23b2が接続されている側の流量を少なくする方法でも前記(2)と同様に、分流管23b1、23b2の接続個所が偏心個所によって決められており、組み立て作業性が悪いだけでなく、誤接続の恐れがある。
などの問題があった。
The method described in Patent Document 1 as described above has the following problems.
(1) Although only one shunt pipe 23a1, 23a2, 23b1, 23b2 is shown in the figure, it is actually composed of a plurality of shunt pipes, so that the shunt pipe connected to the sub-shunt 20b as shown in FIG. When the diameters of 23b1 and 23b2 are made different, there are many places where the shunt pipe and the sub-divider 20b are connected and many places where the shunt pipe and the connecting portion 35 are connected. It can only be connected to, and the workability of manufacturing and assembly is poor.
(2) In the method of providing the flow resistance on the side where the branch pipe 23b2 is connected in the refrigerant passage inside the sub-divider 20b with the same pipe diameter, the plurality of branch pipes 23b1 and 23b2 are provided. In spite of having the same shape, the connecting points of the flow dividing pipes 23b1 and 23b2 are determined in advance depending on the presence or absence of flow resistance, and not only the assembly workability is bad, but also there is a risk of erroneous connection.
(3) Even in the method of reducing the flow rate on the side where the flow dividing pipe 23b2 is connected by decentering the two refrigerant passages inside, the connection point of the flow dividing pipes 23b1 and 23b2 is determined by the eccentric position as in the case (2). As a result, not only the assembly workability is poor, but there is a risk of erroneous connection.
There were problems such as.

本発明は、すべての分流管と分流器を統一した構成としながら、送風機による風速分布に伴う伝熱管の上下部での熱交換能力に差違が生じないようにした空気調和機を提供することを目的とものである。   It is an object of the present invention to provide an air conditioner in which all the shunt pipes and shunts are unified, and the difference in heat exchange capacity between the upper and lower portions of the heat transfer pipe due to the wind speed distribution by the blower is not caused. It is a purpose.

本発明の空気調和機は、圧縮機と、四方弁と、室外熱交換器と、減圧器と、室内熱交換器とを具備し、前記室外熱交換器を縦向きに配置し、上部に設けた送風機で外部空気を吸引して熱交換を行うようにした上吹きタイプの空気調和機において、前記室外熱交換器の下方部の伝熱管に接続された分流管に冷媒を分流する下部分流器と、前記室外熱交換器の上方部の伝熱管に接続された分流管に冷媒を分流する前記下部分流器より個数の多い複数の上部分流器と、冷媒の出入り口配管に接続された本管と、この本管から分岐接続され前記下部分流器に接続するための下部熱交換器用分岐管と、前記本管から分岐接続され前記複数の上部分流器に接続するための複数の上部熱交換用分岐管とからなることを特徴とする。   The air conditioner of the present invention comprises a compressor, a four-way valve, an outdoor heat exchanger, a decompressor, and an indoor heat exchanger, and the outdoor heat exchanger is disposed vertically and provided at the top. In a top-blow type air conditioner in which external air is sucked by a blower to exchange heat, a lower partial flow that divides the refrigerant into a branch pipe connected to a heat transfer pipe at a lower portion of the outdoor heat exchanger And a plurality of upper partial flow distributors having a number larger than that of the lower partial flow distributor for diverting the refrigerant to a diverter pipe connected to a heat transfer pipe at an upper portion of the outdoor heat exchanger, and a refrigerant inlet / outlet pipe A main pipe, a branch pipe for a lower heat exchanger that is branched from the main pipe and connected to the lower partial flower, and a plurality of pipes that are branched from the main pipe and connected to the plurality of upper partial flow pipes It consists of a branch pipe for upper heat exchange.

下部熱交換器用分岐管と複数の上部熱交換用分岐管は、本管より小さな直径のもので構成し、流通抵抗を分岐管の数で調整する。   The lower heat exchanger branch pipe and the plurality of upper heat exchange branch pipes are configured with a smaller diameter than the main pipe, and the flow resistance is adjusted by the number of branch pipes.

上部分流器と下部分流器は、各分流管に略均等に分流するものに統一して製造、組立等を容易にする。   The upper partial flow device and the lower partial flow device are unified into those for dividing the flow into each of the flow dividing pipes so as to facilitate manufacture and assembly.

室外熱交換器は、同一構成の上部熱交換器と下部熱交換器を上下2段に配置し、前記上部熱交換器の伝熱管に分流管を直接接続し、前記下部熱交換器の伝熱管に分流管をT字管を介して接続することにより、熱交換器の構成は同一としながらT字管の有無で上部熱交換器として使用するか、下部熱交換器として使用するかを選択する。   The outdoor heat exchanger has an upper heat exchanger and a lower heat exchanger having the same configuration arranged in two stages, and a shunt pipe is directly connected to the heat transfer pipe of the upper heat exchanger, and the heat transfer pipe of the lower heat exchanger By connecting the shunt pipe through the T-shaped tube, it is possible to select whether to use as the upper heat exchanger or the lower heat exchanger with or without the T-shaped tube with the same heat exchanger configuration. .

上部熱交換器の伝熱管に接続された分流管の本数を、下部熱交換器の伝熱管に接続された分流管の本数より多くして流通抵抗を少なくする。   The number of shunt tubes connected to the heat transfer tubes of the upper heat exchanger is increased from the number of shunt tubes connected to the heat transfer tubes of the lower heat exchanger to reduce the flow resistance.

下部分流器を下部熱交換器の下方部に臨ませた本管の下方部で分岐接続し、上部分流器を上部熱交換器の下方部に臨ませた本管の上方部で分岐接続することにより、暖房の除霜運転時と冷房運転時おいて、配管の高低差による圧力損失が小さくなり、無駄なエネルギー損失がなくなる。   Branch connection at the lower part of the main pipe facing the lower part of the lower heat exchanger, and branch connection at the upper part of the main pipe facing the lower part of the upper heat exchanger By doing so, the pressure loss due to the height difference of the piping is reduced during the defrosting operation and the cooling operation of heating, and unnecessary energy loss is eliminated.

請求項1記載の発明によれば、圧縮機と、四方弁と、室外熱交換器と、減圧器と、室内熱交換器とを具備し、前記室外熱交換器を縦向きに配置し、上部に設けた送風機で外部空気を吸引して熱交換を行うようにした上吹きタイプの空気調和機において、前記室外熱交換器の下方部の伝熱管に接続された分流管に冷媒を分流する下部分流器と、前記室外熱交換器の上方部の伝熱管に接続された分流管に冷媒を分流する前記下部分流器より個数の多い複数の上部分流器と、冷媒の出入り口配管に接続された本管と、この本管から分岐接続され前記下部分流器に接続するための下部熱交換器用分岐管と、前記本管から分岐接続され前記複数の上部分流器に接続するための複数の上部熱交換用分岐管とからなるので、分流器、分流管、熱交換器、分岐管の形状を統一し、分岐管と分流管の数、本管の太さだけで流通抵抗を変えればよく、誤接続の恐れがなく、製造、組み立てがきわめて容易になる。   According to invention of Claim 1, it comprises a compressor, a four-way valve, an outdoor heat exchanger, a pressure reducer, and an indoor heat exchanger, the outdoor heat exchanger is arranged vertically, and an upper part In the top-blow type air conditioner in which external air is sucked by a blower provided in the air exchanger and heat exchange is performed, the refrigerant is divided into a branch pipe connected to a heat transfer pipe at a lower portion of the outdoor heat exchanger. Connected to a partial flow unit, a plurality of upper partial flow units having a larger number than the lower partial flow unit that divides the refrigerant into a diversion pipe connected to a heat transfer pipe at the upper part of the outdoor heat exchanger, and a refrigerant inlet / outlet pipe A main heat pipe, a branch pipe for a lower heat exchanger that is branched from the main pipe and connected to the lower partial flow device, and a branch pipe that is branched from the main pipe and connected to the plurality of upper partial flow devices. Since it consists of multiple branch pipes for upper heat exchange, shunt, shunt pipe, heat exchanger, branch Shape unified, the number of the branch pipe and distribution pipe may be changed flow resistance in only the thickness of the main pipe, without fear of erroneous connection, manufacturing, assembling is extremely easy.

請求項2記載の発明によれば、下部熱交換器用分岐管と複数の上部熱交換用分岐管は、本管より小さな直径のものとすることにより、下部熱交換器用分岐管と複数の上部熱交換用分岐管は、同一径とすることができる。また、分岐管に対する本管の管径の比率を変えることにより、下部室外熱交換器の伝熱管に流れる冷媒量に対する上部室外熱交換器の各伝熱管に流れる冷媒量の比率を変えることができる。   According to the second aspect of the present invention, the lower heat exchanger branch pipe and the plurality of upper heat exchange branch pipes have a smaller diameter than the main pipe, whereby the lower heat exchanger branch pipe and the plurality of upper heat exchanger branch pipes are formed. The replacement branch pipes can have the same diameter. Further, by changing the ratio of the main pipe diameter to the branch pipe, the ratio of the refrigerant amount flowing in each heat transfer tube of the upper outdoor heat exchanger to the refrigerant amount flowing in the heat transfer tube of the lower outdoor heat exchanger can be changed. .

請求項3記載の発明によれば、上部分流器と下部分流器は、各分流管に略均等に冷媒を分流するものとすることにより、上部分流器と下部分流器に接続された複数本の分流管の製造、組み立てが容易になる。   According to the third aspect of the present invention, the upper partial flow device and the lower partial flow device are connected to the upper partial flow device and the lower partial flow device by dividing the refrigerant into the respective divided pipes substantially evenly. In addition, it is easy to manufacture and assemble multiple shunt tubes.

請求項4記載の発明によれば、室外熱交換器は、同一構成の上部熱交換器と下部熱交換器を上下2段に配置し、前記上部熱交換器の伝熱管に分流管を直接接続し、前記下部熱交換器の伝熱管に分流管をT字管を介して接続するようにしたので、組み立て効率のよい空気調和機を提供できる。   According to the invention described in claim 4, the outdoor heat exchanger has an upper heat exchanger and a lower heat exchanger having the same configuration arranged in two upper and lower stages, and a shunt pipe is directly connected to the heat transfer pipe of the upper heat exchanger. In addition, since the shunt pipe is connected to the heat transfer pipe of the lower heat exchanger via the T-shaped pipe, an air conditioner with high assembly efficiency can be provided.

請求項5記載の発明によれば、上部熱交換器の伝熱管に接続された分流管の本数を、下部熱交換器の伝熱管に接続された分流管の本数より多くなるようにしたので、上部での冷媒の流れがよくなる。   According to the invention of claim 5, since the number of the shunt tubes connected to the heat transfer tubes of the upper heat exchanger is made larger than the number of the shunt tubes connected to the heat transfer tubes of the lower heat exchanger, Improved refrigerant flow at the top.

請求項6記載の発明によれば、下部分流器を下部熱交換器の下方部に臨ませた本管の下方部で分岐接続し、上部分流器を上部熱交換器の下方部に臨ませた本管の上方部で分岐接続したので、暖房の除霜運転時と冷房運転時おいて、配管の高低差による圧力損失が小さくなり、無駄なエネルギー損失がなくなる。   According to the sixth aspect of the present invention, the lower partial flow device is branched and connected at the lower portion of the main pipe facing the lower portion of the lower heat exchanger, and the upper partial flow device is exposed to the lower portion of the upper heat exchanger. Since the branch connection is made at the upper part of the main pipe, the pressure loss due to the height difference of the piping is reduced during the defrosting operation and the cooling operation of heating, and unnecessary energy loss is eliminated.

本発明は、圧縮機と、四方弁と、室外熱交換器と、減圧器と、室内熱交換器とを具備し、前記室外熱交換器を縦向きに配置し、上部に設けた送風機で外部空気を吸引して熱交換を行うようにした上吹きタイプの室外熱交換器を備えた空気調和機に適用される。
分流器は、その内部で分流比を調整するのではなく、すべての分流管に均等に冷媒が流れるように構成する。
室外熱交換器の上方部の伝熱管に接続された分流管に冷媒を分流する上部分流器は、室外熱交換器の下方部の伝熱管に接続された分流管に冷媒を分流する下部分流器より個数を多くする。
The present invention comprises a compressor, a four-way valve, an outdoor heat exchanger, a decompressor, and an indoor heat exchanger, wherein the outdoor heat exchanger is disposed vertically and externally provided by a blower provided at the top. The present invention is applied to an air conditioner including an up-blowing type outdoor heat exchanger that sucks air to perform heat exchange.
The flow divider is not configured to adjust the flow dividing ratio therein, but is configured so that the refrigerant flows evenly through all the flow dividing tubes.
The upper part flow distributor for diverting the refrigerant to the diversion pipe connected to the heat transfer pipe in the upper part of the outdoor heat exchanger is the lower part for diverting the refrigerant to the diversion pipe connected to the heat transfer pipe in the lower part of the outdoor heat exchanger. Increase the number more than the flow

冷媒の出入り口配管に本管を接続し、この本管に下部分流器に接続するための下部熱交換器用分岐管を分岐接続し、また、本管に複数の上部分流器に接続するための複数の上部熱交換用分岐管を分岐接続する。
本管の直径は、下部熱交換器用分岐管と複数の上部熱交換用分岐管の直径より大きくする。
室外熱交換器は、同一構成の上部熱交換器と下部熱交換器を上下2段に配置し、上部熱交換器の伝熱管に分流管を直接接続し、下部熱交換器の伝熱管に分流管をT字管を介して接続することで、可能な限り共通の構成とする。
上部熱交換器の伝熱管に接続された分流管の本数を、下部熱交換器の伝熱管に接続された分流管の本数より多くして流通抵抗を少なくする。
下部分流器を下部熱交換器の下方部に臨ませた本管の下方部で分岐接続し、上部分流器を上部熱交換器の下方部に臨ませた本管の上方部で分岐接続したので、暖房の除霜運転時と冷房運転時おいて、配管の高低差による圧力損失が小さくなり、無駄なエネルギー損失がなくなる。
To connect the main pipe to the refrigerant inlet / outlet pipe, to connect the main pipe to the lower heat exchanger branch pipe for connecting to the lower partial flow pipe, and to connect the main pipe to multiple upper partial flow pipes A plurality of upper heat exchange branch pipes are branched and connected.
The diameter of the main pipe is made larger than the diameters of the lower heat exchanger branch pipe and the plurality of upper heat exchange branch pipes.
In the outdoor heat exchanger, the upper and lower heat exchangers with the same configuration are arranged in two stages, and the shunt pipe is directly connected to the heat transfer pipe of the upper heat exchanger, and the shunt pipe is divided into the heat transfer pipe of the lower heat exchanger. By connecting the tubes via a T-shaped tube, the common configuration is made as much as possible.
The number of shunt tubes connected to the heat transfer tubes of the upper heat exchanger is increased from the number of shunt tubes connected to the heat transfer tubes of the lower heat exchanger to reduce the flow resistance.
Branch connection at the lower part of the main pipe facing the lower part of the lower heat exchanger, and branch connection at the upper part of the main pipe facing the lower part of the upper heat exchanger Therefore, the pressure loss due to the height difference of the piping is reduced during the defrosting operation and the cooling operation of heating, and unnecessary energy loss is eliminated.

本発明による空気調和機の実施例1を図面に基づき説明する。
図1において、12は、室外熱交換器である。この室外熱交換器12は、図3(a)及び図4(a)(b)に示すものと同様に、水平な多数の伝熱管24と垂直な多数の放熱フィン33とが互いに直角に交差したいわゆるクロスフィンチューブ型に構成されている。この室外熱交換器12は、同一構成の上部室外熱交換器12aと下部室外熱交換器12bを上下2段に重ねて設けられている。また、この室外熱交換器12は、正面の操作部28以外の3方から内部機器の外周を囲むように縦向きに配置され、前記伝熱管24を流れる冷媒は、機枠27の上部に設けられた送風機15で外部空気を前記放熱フィン33の間から吸引して外部空気と熱交換されて蒸発又は凝縮するように構成されている。
A first embodiment of an air conditioner according to the present invention will be described with reference to the drawings.
In FIG. 1, 12 is an outdoor heat exchanger. In this outdoor heat exchanger 12, as shown in FIGS. 3 (a), 4 (a) and 4 (b), a large number of horizontal heat transfer tubes 24 and a large number of vertical radiating fins 33 intersect each other at right angles. The so-called cross fin tube type is configured. This outdoor heat exchanger 12 is provided with an upper outdoor heat exchanger 12a and a lower outdoor heat exchanger 12b having the same configuration stacked in two upper and lower stages. The outdoor heat exchanger 12 is vertically arranged so as to surround the outer periphery of the internal device from three sides other than the operation unit 28 on the front side, and the refrigerant flowing through the heat transfer tube 24 is provided in the upper part of the machine frame 27. The blower 15 is configured to suck external air from between the heat radiation fins 33 and exchange heat with the external air to evaporate or condense.

前記上部室外熱交換器12aは、図1に示すように、例えば、72本の水平な伝熱管24を有する。そのうちの上半分の36本は、順次U字管34で接続された6本の伝熱管24を1グループとして連結部34a11、34a12、…34a16を経て各分流管23a1、…に接続されている。また、下半分の36本も同様に、順次U字管34で接続された6本の伝熱管24を1グループとして連結部34a21、34a22、…34a26を経て各分流管23a2、…に接続されている。
前記下部室外熱交換器12bは、例えば、72本の水平な伝熱管24を有し、順次U字管34で接続された6本の伝熱管24を1グループとし、さらに2個一対の連結部34b01と34b02、34b03と34b04、…、34b11と34b12がそれぞれT字管36で合流されて、12本の伝熱管24を1グループとして各分流管23bに接続されている。
したがって、上部室外熱交換器12aの分流管は、上半分の6本の各分流管23a1、…と、下半分の6本の各分流管23a2、…との合計12本を有する。下部室外熱交換器12bの分流管は、T字管36で合流しているので6本の各分流管23b、…を有し、上部室外熱交換器12aの半分の本数である。
前記伝熱管24の本数、上部室外熱交換器12aと下部室外熱交換器12bのグループ分けする分流管23の本数等は、一例でありこれに限られるものではないが、上部室外熱交換器12a側の分流管23の本数が下部室外熱交換器12b側の分流管23の本数より多くすることが望ましい。
As shown in FIG. 1, the upper outdoor heat exchanger 12 a has, for example, 72 horizontal heat transfer tubes 24. 36 of the upper half of them are connected to each of the flow dividing pipes 23a1,... Via the connecting portions 34a11, 34a12,... 34a16, with the six heat transfer tubes 24 sequentially connected by the U-shaped pipe 34 as one group. Similarly, the 36 of the lower half are connected to each of the flow dividing pipes 23a2,... Through the connecting portions 34a21, 34a22,... 34a26, with the six heat transfer tubes 24 sequentially connected by the U-shaped pipe 34 as one group. Yes.
The lower outdoor heat exchanger 12b has, for example, 72 horizontal heat transfer tubes 24, and six heat transfer tubes 24 sequentially connected by a U-shaped tube 34 form one group, and further two pairs of connecting portions. 34b01 and 34b02, 34b03 and 34b04,..., 34b11 and 34b12 are joined together by a T-shaped tube 36, and twelve heat transfer tubes 24 are grouped and connected to each branch pipe 23b.
Therefore, the branch pipes of the upper outdoor heat exchanger 12a have a total of twelve pipes, that is, the upper half six branch pipes 23a1,... And the lower half six branch pipes 23a2,. Since the branch pipes of the lower outdoor heat exchanger 12b are joined by the T-shaped pipe 36, each of the branch pipes has six branch pipes 23b, which is half the number of the upper outdoor heat exchanger 12a.
The number of the heat transfer tubes 24, the number of the branch pipes 23 that are grouped into the upper outdoor heat exchanger 12a and the lower outdoor heat exchanger 12b, and the like are only examples, and the upper outdoor heat exchanger 12a is not limited thereto. It is desirable that the number of the side branch pipes 23 be larger than the number of the branch pipes 23 on the lower outdoor heat exchanger 12b side.

前記上部室外熱交換器12aと下部室外熱交換器12bからなる室外熱交換器12の他方側は、各伝熱管がT字管36で合流されてヘッダ25に接続され、このベッダ25の他端は、図2と同様に四方弁13に接続される。
なお、上部室外熱交換器12aでは、各連結部34a11、34a12、…34a16に各分流管23を直接接続し、下部室外熱交換器12bは、2個一対の連結部34b01と34b02、34b03と34b04、…、34b11と34b12にそれぞれT字管36介在して各分流管23を接続しているが、上部室外熱交換器12aと下部室外熱交換器12bの基本構成は可能な限り共通としている。
The other side of the outdoor heat exchanger 12 composed of the upper outdoor heat exchanger 12a and the lower outdoor heat exchanger 12b is connected to the header 25 with the heat transfer tubes joined by a T-shaped tube 36, and the other end of the bed 25 Is connected to the four-way valve 13 as in FIG.
In the upper outdoor heat exchanger 12a, each branch pipe 23 is directly connected to each connecting portion 34a11, 34a12,... 34a16, and the lower outdoor heat exchanger 12b has two pairs of connecting portions 34b01 and 34b02, 34b03 and 34b04. ,..., 34b11 and 34b12 are connected to the respective branch pipes 23 via T-shaped pipes 36, but the basic configurations of the upper outdoor heat exchanger 12a and the lower outdoor heat exchanger 12b are made as common as possible.

前記出入り口配管21は、前記下部室外熱交換器12bの下端部に位置して配置される。
この出入り口配管21には、図1に示すように、垂直な太い本管29が接続され、この本管29は、上部室外熱交換器12aの略下端部の位置まで延びて設けられる。この本管29の上方部には、前記本管29より細い上半部用分岐管29a1と下半部用分岐管29a2が上向きにU字形に分岐接続され、また、この本管29の下方部には、前記本管29より細い下部熱交換器用分岐管29bが上向きに分岐接続される。
前記上半部用分岐管29a1、下半部用分岐管29a2、下部熱交換器用分岐管29bの内径は、すべて本管29より細く、かつ、同一径にすることが規格統一のために望ましい。
The entrance / exit pipe 21 is disposed at the lower end of the lower outdoor heat exchanger 12b.
As shown in FIG. 1, a vertical main pipe 29 is connected to the entrance / exit pipe 21, and the main pipe 29 extends to the position of the substantially lower end of the upper outdoor heat exchanger 12 a. An upper half branch pipe 29 a 1 and a lower half branch pipe 29 a 2, which are thinner than the main pipe 29, are branched and connected to the upper part of the main pipe 29 in a U-shape. The lower heat exchanger branch pipe 29b, which is thinner than the main pipe 29, is branched and connected upward.
The inner diameters of the upper half branch pipe 29a1, the lower half branch pipe 29a2, and the lower heat exchanger branch pipe 29b are all thinner than the main pipe 29, and it is desirable that the same diameter be used for standardization.

さらに詳しくは、出入り口配管21から本管29の接続部分P1を経て送られてきた冷媒を、本管29と下部熱交換器用分岐管29bの分岐点P2では、下部熱交換器用分岐管29b側に少なく、本管29側に多く流通させる。
本管29を流通した冷媒は、上端の分岐点P3で上半部用分岐管29a1と下半部用分岐管29a2に分流される。すなわち、上半部用分岐管29a1、下半部用分岐管29a2、下部熱交換器用分岐管29bは、すべて同一径に設定し、本管29のみ太くする。
その結果、下部熱交換器用分岐管29bの1個分の分流比率よりも、上半部用分岐管29a1と下半部用分岐管29a2を加えた2個分の分流比率が大きくなり、伝熱管24を流れる冷媒の分流比が、上方で大きく、下方で小さくなる。
More specifically, the refrigerant sent from the inlet / outlet pipe 21 via the connection portion P1 of the main pipe 29 is moved to the lower heat exchanger branch pipe 29b side at a branch point P2 between the main pipe 29 and the lower heat exchanger branch pipe 29b. A small amount is distributed on the main pipe 29 side.
The refrigerant flowing through the main pipe 29 is divided into the upper half branch pipe 29a1 and the lower half branch pipe 29a2 at the upper branch point P3. That is, the upper half branch pipe 29a1, the lower half branch pipe 29a2, and the lower heat exchanger branch pipe 29b are all set to the same diameter, and only the main pipe 29 is thickened.
As a result, the diversion ratio for two parts including the upper half branch pipe 29a1 and the lower half branch pipe 29a2 is larger than the diversion ratio for one of the lower heat exchanger branch pipes 29b. The flow dividing ratio of the refrigerant flowing through 24 is large at the top and small at the bottom.

上記例では、冷媒が出入り口配管21側から流れ込み、分岐点P2とP3で分岐する暖房運転時の例を示したが、逆に、冷媒が分岐点P3とP2で合流してP1から出入り口配管21に流れ込む冷房運転時であっても分流比率は同様である。
このように、冷媒の分流比率を変える手段として、従来のように、多数の分流管の径を異ならせたり、分流管が接続されている側に流動抵抗を設けたり、内部の冷媒通路を偏心させたりするのではなく、本発明では、上半部用分岐管29a1、下半部用分岐管29a2、下部熱交換器用分岐管29bは、すべて同一径に設定し、上下の分流管の個数を変え、本管29の径を太くすることにより、簡単な構成で冷媒の分流比を、風速分布に可能な限り対応させるようにしている。
In the above example, the refrigerant flows from the inlet / outlet pipe 21 side and the example of the heating operation in which the refrigerant branches at the branch points P2 and P3 is shown, but conversely, the refrigerant merges at the branch points P3 and P2 and enters the inlet / outlet pipe 21 from P1. The diversion ratio is the same even during the cooling operation that flows into the.
As described above, as a means for changing the refrigerant diversion ratio, as in the prior art, the diameter of a number of diversion pipes is varied, a flow resistance is provided on the side where the diversion pipes are connected, or the internal refrigerant passage is eccentric. In the present invention, the upper half branch pipe 29a1, the lower half branch pipe 29a2, and the lower heat exchanger branch pipe 29b are all set to the same diameter, and the number of upper and lower branch pipes is set. In other words, by increasing the diameter of the main pipe 29, the refrigerant diversion ratio is made to correspond as much as possible to the wind speed distribution with a simple configuration.

前記上部熱交換器用分岐管29a1と29a2には、それぞれ上半部用分流器30a1と下半部用分流器30a2が接続される。これらの上半部用分流器30a1と下半部用分流器30a2は、暖房時の除霜運転のために上部室外熱交換器12aの下端部に出来るだけ近づけて設置される。これらの上半部用分流器30a1と下半部用分流器30a2には、前記6本ずつの分流管23a1と23a2が接続される。これら6本ずつの分流管23a1と23a2への分流が出来るだけ均等に行われるように所定長だけ立ち上がらせてから前記各連結部34a11、…と34a21、…に接続される。   An upper half flow divider 30a1 and a lower half flow divider 30a2 are connected to the upper heat exchanger branch pipes 29a1 and 29a2, respectively. These upper half flow divider 30a1 and lower half flow divider 30a2 are installed as close as possible to the lower end of the upper outdoor heat exchanger 12a for the defrosting operation during heating. Each of the six flow dividing pipes 23a1 and 23a2 is connected to the upper half flow divider 30a1 and the lower half flow divider 30a2. These six branch pipes 23a1 and 23a2 are connected to the connecting portions 34a11,..., 34a21,.

前記下部熱交換器用分岐管29bには、下部分流器31が接続される。この下部分流器31は、暖房時の前記下部室外熱交換器12bの除霜運転のために下部室外熱交換器12bの下端部に出来るだけ近づけて設置される。この下部分流器31には、前記6本の分流管23bが接続される。これら6本の分流管23bへの分流が出来るだけ均等に行われるようにすべてを所定長だけ立ち上がらせてから前記T字管36を介して各連結部34b01、…に接続される。
前記上半部用分流器30a1、下半部用分流器30a2、下部分流器31は、すべて同一径の6本の分流管が接続されるように同一形状に構成して、誤接続の恐れがないようにしている。
A lower partial flow device 31 is connected to the lower heat exchanger branch pipe 29b. The lower partial flow device 31 is installed as close as possible to the lower end portion of the lower outdoor heat exchanger 12b for the defrosting operation of the lower outdoor heat exchanger 12b during heating. The six branch pipes 23b are connected to the lower partial flow device 31. All of them are raised by a predetermined length so that the flow to the six flow dividing pipes 23b is performed as evenly as possible, and then connected to each connecting portion 34b01,... Via the T-shaped pipe 36.
The upper half flow divider 30a1, the lower half flow divider 30a2, and the lower partial flow vessel 31 are all configured in the same shape so that six branch pipes having the same diameter are connected, and there is a risk of erroneous connection. There is no such thing.

次に空気調和機の動作を説明する。
暖房運転時には、四方弁13のポートAとDが連通し、ポートBとCが連通するように切り替える(図2の点線矢印状態)。すると、冷媒は、圧縮機14により高圧過熱蒸気となり室内機11の室内熱交換器16に送られ、この室内熱交換器16で高圧過熱蒸気が凝縮し放熱(暖房効果)され、高圧飽和液となって減圧器17で減圧され、湿り蒸気となり室外機10の室外熱交換器12に送られる。この室外熱交換器12で湿り蒸気が蒸発し、吸熱をして低圧の飽和蒸気となって四方弁13を経て圧縮機14に戻される。
Next, the operation of the air conditioner will be described.
During the heating operation, switching is performed so that the ports A and D of the four-way valve 13 communicate with each other and the ports B and C communicate with each other (dotted line arrow state in FIG. 2). Then, the refrigerant becomes high-pressure superheated steam by the compressor 14 and is sent to the indoor heat exchanger 16 of the indoor unit 11, where the high-pressure superheated steam is condensed and radiated (heating effect), Then, the pressure is reduced by the pressure reducer 17, becomes wet steam and is sent to the outdoor heat exchanger 12 of the outdoor unit 10. The wet steam evaporates in this outdoor heat exchanger 12, absorbs heat, becomes low-pressure saturated steam, and returns to the compressor 14 through the four-way valve 13.

この暖房運転時において、減圧器17で減圧され出入り口配管21のP1から送られてきた冷媒は、分岐点P2にて管径に応じて本管29側が多く、下部熱交換器用分岐管29bが少なくなるように分岐される。本管29側を流れてきた冷媒は、上端部で上半部用分流器30a1と下半部用分流器30a2に分岐される。
下部熱交換器用分岐管29bは、下部室外熱交換器12bに接続されて冷媒が流れやすいので、個数を1個とし、これに対し、上部熱交換器用分岐管29aは、上側なので冷媒が重力に逆らい流れにくいので、上半部用分岐管29a1と下半部用分岐管29a2の2個と個数を多くして並列接続とすることにより下部熱交換器用分岐管29bよりも流通抵抗を小さくして冷媒を流れ易くしている。
During this heating operation, the refrigerant depressurized by the pressure reducer 17 and sent from P1 of the inlet / outlet pipe 21 is mostly on the main pipe 29 side according to the pipe diameter at the branch point P2, and the lower heat exchanger branch pipe 29b is small. It is branched to become. The refrigerant flowing on the main pipe 29 side is branched at the upper end portion into the upper half flow divider 30a1 and the lower half flow divider 30a2.
Since the lower heat exchanger branch pipe 29b is connected to the lower outdoor heat exchanger 12b and the refrigerant flows easily, the number of the lower heat exchanger branch pipe 29b is one. On the other hand, since the upper heat exchanger branch pipe 29a is on the upper side, the refrigerant is brought into gravity. Since it is difficult to flow in the reverse direction, the flow resistance is made smaller than the branch pipe 29b for the lower heat exchanger by increasing the number of the upper half branch pipe 29a1 and the lower half branch pipe 29a2 and connecting them in parallel. It makes it easier for the refrigerant to flow.

この結果、冷媒は、上半部用分岐管29a1と下半部用分岐管29a2の2個に分岐されて2個の上半部用分流器30a1と下半部用分流器30a2へ送られ、各6本ずつ12本の分流管23a1と23a2に分流され、各連結部34a11、…と34a21、…を経て上部室外熱交換器12aの72本の各伝熱管24に送られる。
また、1個の下部熱交換器用分岐管29bからの冷媒は、1個の下部分流器31へ送られ、6本の分流管23bに分流され、各連結部34b01、…を経て下部室外熱交換器12bの72本の各伝熱管24に送られる。
このようにして、上部の流通抵抗を下部より小さくして上部室外熱交換器12aの各伝熱管24と下部室外熱交換器12bの伝熱管24に風速分布に対応させて冷媒が流される。
As a result, the refrigerant is branched into two, an upper half branch pipe 29a1 and a lower half branch pipe 29a2, and sent to the two upper half flow dividers 30a1 and the lower half branch pipe 30a2. Each of the six is divided into twelve branch pipes 23a1 and 23a2, and is sent to each of the 72 heat transfer pipes 24 of the upper outdoor heat exchanger 12a through the respective connecting portions 34a11,.
Further, the refrigerant from one lower heat exchanger branch pipe 29b is sent to one lower partial flow distributor 31, and is divided into six branch pipes 23b, and the lower outdoor heat is passed through the connecting portions 34b01,. It is sent to each of the 72 heat transfer tubes 24 of the exchanger 12b.
In this way, the upper flow resistance is made smaller than the lower portion, and the refrigerant is caused to flow through the heat transfer tubes 24 of the upper outdoor heat exchanger 12a and the heat transfer tubes 24 of the lower outdoor heat exchanger 12b in accordance with the wind speed distribution.

なお、上半部用分岐管29a1と下半部用分岐管29a2は本管29から2個並列に分岐し、下部熱交換器用分岐管29bは、本管29から1個だけ分岐しているので、分岐管に対する本管29の管径の比率をより大きくすれば、下部室外熱交換器12bの伝熱管24に流れる冷媒量に対する上部室外熱交換器12aの各伝熱管24に流れる冷媒量の比率を多くすることができる。つまり、分岐管に対する本管の管径の比率を変えることにより、下部室外熱交換器12bの伝熱管24に流れる冷媒量に対する上部室外熱交換器12aの各伝熱管24に流れる冷媒量の比率を変えることができる。   Since the upper half branch pipe 29a1 and the lower half branch pipe 29a2 are branched from the main pipe 29 in parallel, only one lower heat exchanger branch pipe 29b is branched from the main pipe 29. If the ratio of the pipe diameter of the main pipe 29 to the branch pipe is made larger, the ratio of the refrigerant amount flowing through each heat transfer pipe 24 of the upper outdoor heat exchanger 12a to the refrigerant quantity flowing through the heat transfer pipe 24 of the lower outdoor heat exchanger 12b Can be more. That is, by changing the ratio of the pipe diameter of the main pipe to the branch pipe, the ratio of the refrigerant amount flowing in each heat transfer tube 24 of the upper outdoor heat exchanger 12a to the amount of refrigerant flowing in the heat transfer tube 24 of the lower outdoor heat exchanger 12b is changed. Can be changed.

冷房運転時には、四方弁22のポートAとBが連通し、ポートCとDが連通するように切り替える(図2の実線矢印状態)。すると、冷媒は、圧縮機14により高圧過熱蒸気となり室外熱交換器12の伝熱管24に送られ、この伝熱管24で蒸気が凝縮しファン15により放熱され、高圧飽和液となって上部室外熱交換器12aから各分流管23a1、23a2、上部分流器30a1、30a2、上部熱交換器用分岐管29a1、29a2を経て本管29に合流し、また、下部室外熱交換器12bから各分流管23b、下部分流器31、下部熱交換器用分岐管29bを経て本管29に合流し、本管29から出入り口配管21により室内機11の減圧器17に送られる。この減圧器17で高圧湿り液となって室内熱交換器16に供給され、この室内熱交換器16で湿り蒸気が蒸発し、吸熱(冷房効果)をして低圧の飽和蒸気となって四方弁13を経て圧縮機14に戻される。   During the cooling operation, switching is performed so that the ports A and B of the four-way valve 22 communicate with each other and the ports C and D communicate with each other (solid arrow state in FIG. 2). Then, the refrigerant becomes high-pressure superheated steam by the compressor 14 and is sent to the heat transfer pipe 24 of the outdoor heat exchanger 12. The steam is condensed in the heat transfer pipe 24 and is radiated by the fan 15, and becomes high-pressure saturated liquid, and the upper outdoor heat. From the exchanger 12a, the branch pipes 23a1 and 23a2, the upper partial flowrs 30a1 and 30a2, the upper heat exchanger branch pipes 29a1 and 29a2 are joined to the main pipe 29, and from the lower outdoor heat exchanger 12b to the respective branch pipes 23b. The main pipe 29 is merged through the lower partial flowr 31 and the lower heat exchanger branch pipe 29 b, and is sent from the main pipe 29 to the decompressor 17 of the indoor unit 11 through the entrance / exit pipe 21. The decompressor 17 supplies a high-pressure dampening solution to the indoor heat exchanger 16, and the wet steam evaporates in the indoor heat exchanger 16, absorbs heat (cooling effect), and becomes a low-pressure saturated steam, which is a four-way valve. 13 is returned to the compressor 14.

前記実施例では、室外機10の室外熱交換器12を上下2段重ねとしたが、分割しないものでもよいし、3分割以上に分割したものでもよい。
前記実施例では、上部分流器30の個数を下部分流器31が1個に対して2個としたが、2個以上でもよい。このように、複数の上部分流器30を並列接続とすることにより、下部分流器31より流通抵抗が減少し、室外熱交換器12の上部と下部での熱交換能力が均等化される。
前記実施例では、出入り口配管21は、本管29に接続され、この本管29の下方部で下部熱交換器用分岐管29bが分岐接続され、前記本管29の上端部では、上半部用分岐管29a1と下半部用分岐管29a2に分岐された二股の上部室外熱交換器12aを接続した。しかし、これに限られるものではなく、前記本管29の上端部で三股又はそれ以上に分岐したものを接続してもよい。また、上半部用分岐管29a1と下半部用分岐管29a2のいずれか一方又は両方を上端部でさらに二股以上に分岐してもよい。
In the said Example, although the outdoor heat exchanger 12 of the outdoor unit 10 was made into 2 steps | paragraphs of upper and lower sides, what was not divided | segmented may be sufficient and what was divided | segmented into 3 or more divisions may be sufficient.
In the above embodiment, the number of the upper partial flow devices 30 is two for one lower partial flow device 31, but two or more may be used. As described above, by connecting the plurality of upper partial flowers 30 in parallel, the flow resistance is reduced from that of the lower partial flower 31, and the heat exchange capacity at the upper and lower portions of the outdoor heat exchanger 12 is equalized. .
In the embodiment, the entrance / exit pipe 21 is connected to the main pipe 29, and the lower heat exchanger branch pipe 29 b is branched and connected to the lower portion of the main pipe 29. The bifurcated upper outdoor heat exchanger 12a branched to the branch pipe 29a1 and the lower half branch pipe 29a2 was connected. However, the present invention is not limited to this, and the upper end of the main pipe 29 may be branched into three branches or more. Further, one or both of the upper half branch pipe 29a1 and the lower half branch pipe 29a2 may be further branched into two or more branches at the upper end.

本発明による空気調和機における室外空気交換器の一実施例を示す説明図である。It is explanatory drawing which shows one Example of the outdoor air exchanger in the air conditioner by this invention. 上吹きタイプの空気調和機の縦断面図である。It is a longitudinal cross-sectional view of an up-blowing type air conditioner. (a)は、従来の上吹きタイプの室外機を備えた空気調和機の説明図、(b)は、風速分布と熱交換能力の特性図である。(A) is explanatory drawing of the air conditioner provided with the conventional top blowing type outdoor unit, (b) is a characteristic view of a wind speed distribution and heat exchange capability. (a)は、室外空気交換器の一部の斜視図であり、(b)は、上吹きタイプの空気調和機の横断平面図である。(A) is a perspective view of a part of the outdoor air exchanger, and (b) is a cross-sectional plan view of the top blow type air conditioner. 従来の室外空気交換器を示す説明図である。It is explanatory drawing which shows the conventional outdoor air exchanger.

符号の説明Explanation of symbols

10…室外機、11…室内機、12…室外熱交換器、13…四方弁、14…圧縮機、15…送風機、16…室内熱交換器、17…減圧器、18…送風機、19…主分流器、20…副分流器、21…出入り口配管、22…冷媒配管、23…分流管、24…伝熱管、25…ヘッダ、26…仕切り板、27…機枠、28…操作部、29…本管、29a,29b…分岐管、30…上部分流器、31…下部分流器、32…分流器、33…放熱フィン、34…U字管、35…連結部、36…T字管。   DESCRIPTION OF SYMBOLS 10 ... Outdoor unit, 11 ... Indoor unit, 12 ... Outdoor heat exchanger, 13 ... Four-way valve, 14 ... Compressor, 15 ... Blower, 16 ... Indoor heat exchanger, 17 ... Decompressor, 18 ... Blower, 19 ... Main 20: Sub-divider, 21: Entrance / exit pipe, 22 ... Refrigerant pipe, 23 ... Shunt pipe, 24 ... Heat transfer pipe, 25 ... Header, 26 ... Partition plate, 27 ... Machine frame, 28 ... Operation unit, 29 ... Main pipe, 29a, 29b ... branch pipe, 30 ... upper partial flow, 31 ... lower partial flow, 32 ... shunt, 33 ... radiating fin, 34 ... U-shaped pipe, 35 ... connecting part, 36 ... T-shaped pipe .

Claims (6)

圧縮機と、四方弁と、室外熱交換器と、減圧器と、室内熱交換器とを具備し、前記室外熱交換器を縦向きに配置し、上部に設けた送風機で外部空気を吸引して熱交換を行うようにした上吹きタイプの空気調和機において、前記室外熱交換器の下方部の伝熱管に接続された分流管に冷媒を分流する下部分流器と、前記室外熱交換器の上方部の伝熱管に接続された分流管に冷媒を分流する前記下部分流器より個数の多い複数の上部分流器と、冷媒の出入り口配管に接続された本管と、この本管から分岐接続され前記下部分流器に接続するための下部熱交換器用分岐管と、前記本管から分岐接続され前記複数の上部分流器に接続するための複数の上部熱交換用分岐管とからなることを特徴とする空気調和機。   A compressor, a four-way valve, an outdoor heat exchanger, a decompressor, and an indoor heat exchanger, the outdoor heat exchanger is arranged vertically, and external air is sucked by a blower provided at the top. In the upper-blow type air conditioner that performs heat exchange, a lower partial flow distributor that diverts refrigerant to a diversion pipe connected to a heat transfer pipe in a lower part of the outdoor heat exchanger, and the outdoor heat exchanger A plurality of upper partial flowers having a number larger than that of the lower partial flow device for diverting the refrigerant to the diversion tube connected to the upper heat transfer tube, a main pipe connected to the refrigerant inlet / outlet pipe, and the main pipe A branch pipe for a lower heat exchanger that is branched and connected to the lower partial flower, and a plurality of branch pipes for upper heat exchange that are branched from the main pipe and connected to the plurality of upper partial flowers An air conditioner characterized by 下部熱交換器用分岐管と複数の上部熱交換用分岐管は、本管より小さな直径のものからなることを特徴とする請求項1記載の空気調和機。   The air conditioner according to claim 1, wherein the lower heat exchanger branch pipe and the plurality of upper heat exchange branch pipes are made of a smaller diameter than the main pipe. 上部分流器と下部分流器は、各分流管に略均等に冷媒を分流するものからなることを特徴とする請求項1記載の空気調和機。   The air conditioner according to claim 1, wherein the upper partial flow device and the lower partial flow device are configured to distribute the refrigerant substantially equally to the respective branch pipes. 室外熱交換器は、同一構成の上部熱交換器と下部熱交換器を上下2段に配置し、前記上部熱交換器の伝熱管に分流管を直接接続し、前記下部熱交換器の伝熱管に分流管をT字管を介して接続するようにしたことを特徴とする請求項1記載の空気調和機。   The outdoor heat exchanger has an upper heat exchanger and a lower heat exchanger having the same configuration arranged in two stages, and a shunt pipe is directly connected to the heat transfer pipe of the upper heat exchanger, and the heat transfer pipe of the lower heat exchanger 2. The air conditioner according to claim 1, wherein the shunt pipe is connected to the pipe via a T-shaped pipe. 上部熱交換器の伝熱管に接続された分流管の本数を、下部熱交換器の伝熱管に接続された分流管の本数より多くなるようにしたことを特徴とする請求項4記載の空気調和機。   5. The air conditioner according to claim 4, wherein the number of shunt tubes connected to the heat transfer tubes of the upper heat exchanger is larger than the number of shunt tubes connected to the heat transfer tubes of the lower heat exchanger. Machine. 下部分流器を下部熱交換器の下方部に臨ませた本管の下方部で分岐接続し、上部分流器を上部熱交換器の下方部に臨ませた本管の上方部で分岐接続したことを特徴とする請求項1記載の空気調和機。   Branch connection at the lower part of the main pipe facing the lower part of the lower heat exchanger, and branch connection at the upper part of the main pipe facing the lower part of the upper heat exchanger The air conditioner according to claim 1, wherein
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