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JPH07205633A - Air conditioner for vehicle - Google Patents

Air conditioner for vehicle

Info

Publication number
JPH07205633A
JPH07205633A JP533094A JP533094A JPH07205633A JP H07205633 A JPH07205633 A JP H07205633A JP 533094 A JP533094 A JP 533094A JP 533094 A JP533094 A JP 533094A JP H07205633 A JPH07205633 A JP H07205633A
Authority
JP
Japan
Prior art keywords
air
heat exchanger
duct
vehicle
layer
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
JP533094A
Other languages
Japanese (ja)
Inventor
Katsuya Tanaka
勝也 田中
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Denso Corp
Original Assignee
NipponDenso Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by NipponDenso Co Ltd filed Critical NipponDenso Co Ltd
Priority to JP533094A priority Critical patent/JPH07205633A/en
Publication of JPH07205633A publication Critical patent/JPH07205633A/en
Pending legal-status Critical Current

Links

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  • Air-Conditioning For Vehicles (AREA)

Abstract

PURPOSE:To dehumidify/heat inside a car room without providing a heat exchanger to dehumidity air in an air conditioning duct to jet the air into the car room. CONSTITUTION:An exterior heat exchanger 3 which serves as a condenser during a cooling period, and serves as an evaporator during a heating period and a dehumidification/heating period is provided outside a car room. An outside air introducing duct 5 wherein outside air passed through the exterior heat exchanger 3 is introduced into an air conditioning duct 7 during the humidification/heating period is connected to the exterior heat exchanger 3. An interior heat exchanger 20 which serves as the evaporator during the cooling period, and serves as the condenser during the humidification/heating period is arranged in the air conditioning duct 7. The inside of the air conditioning duct 7 is divided in a first layer 23 to jet air to a face and a differential and a second layer 24 to introduce the air to a foot, and the upper stream of the first layer 23 is closed during the humidification/heating period so that the dehumidified outside air passed from an outside air introducing duct 5 through the exterior heat exchanger 3 is introduced into the first layer 23. Therefore, the dehumidified outside air is jet from the differential and the face so as to dehumidify/ heat the inside of the car room without providing a heat exchanger for dehumidification in the air conditioning duct 7.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】本発明は、車両の窓ガラスの曇り
を防ぐことのできる車両用空気調和装置に関する。特に
暖房の熱量の発生に動力が必要な電気自動車用エアコ
ン、またはエンジン冷却水を利用した温水ヒータのう
ち、エンジンの熱効率が高く温水の温度が低いディーゼ
ル車やリーンバーンエンジン車用エアコンに用いて好適
なものである。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle air conditioner capable of preventing fogging of window glass of a vehicle. Especially for electric vehicle air conditioners that require power to generate heat for heating, or hot water heaters that use engine cooling water for air conditioners for diesel vehicles and lean burn engine vehicles that have high engine thermal efficiency and low hot water temperature. It is suitable.

【0002】[0002]

【従来の技術】窓ガラスの曇りを防止する除湿機能を備
えた空気調和装置として、車室内に空気を吹き出す空調
ダクトの上流に、除湿時にエバポレータとして作動する
室内上流熱交換器を設け、空調ダクトの下流に除湿時に
コンデンサとして作動する室内下流熱交換器を設けた技
術が知られている。この空気調和装置は、除湿時に室外
空気(外気)を空調ダクト内に吸引し、室内上流熱交換
器によって空調ダクト内を流れる空気を冷却、除湿し、
その後、室内下流熱交換器によって除湿空気を加熱し
て、足元吹出口とデフロスタ吹出口へ吹き出し、車室内
の湿度を低下させて窓ガラスの曇りを防ぐものである。
2. Description of the Related Art As an air conditioner having a dehumidifying function for preventing fogging of window glass, an indoor upstream heat exchanger that operates as an evaporator at the time of dehumidification is provided upstream of an air conditioning duct that blows air into the vehicle interior. There is known a technique in which an indoor downstream heat exchanger that operates as a condenser at the time of dehumidification is provided downstream of the above. This air conditioner sucks outdoor air (outside air) into the air conditioning duct during dehumidification, cools and dehumidifies the air flowing in the air conditioning duct by the indoor upstream heat exchanger,
After that, the dehumidified air is heated by the indoor downstream heat exchanger and blown to the foot outlet and the defroster outlet to reduce the humidity in the vehicle compartment and prevent the window glass from fogging.

【0003】なお、この空気調和装置は、外気と熱交換
するべく室外に配置され、暖房運転時にエバポレータと
して作動する室外熱交換器を備え、暖房運転時は、室内
上流熱交換器および室内下流熱交換器の両方、あるいは
何れか一方をコンデンサとして作動させて室内を暖房す
るように設けられている。
This air conditioner is provided with an outdoor heat exchanger which is arranged outdoors to exchange heat with the outside air and operates as an evaporator during heating operation. During heating operation, the indoor upstream heat exchanger and indoor downstream heat exchanger are provided. Both or one of the exchangers is operated as a condenser to heat the room.

【0004】[0004]

【発明が解決しようとする課題】内燃機関車両において
は燃費向上および近年の地球環境保全に対する意識の高
まりにより、空気調和装置にかかるエネルギー消費を低
く抑える要求が高い。また、電気自動車では、1充電当
たりの走向距離を延ばす要求からも、空気調和装置にか
かる電力消費を低く抑える要求がいっそう高い。
In an internal combustion engine vehicle, there is a strong demand for keeping the energy consumption of the air conditioner low due to the improvement of fuel consumption and the recent increasing awareness of global environment conservation. In addition, in the electric vehicle, there is an even higher demand for suppressing the power consumption of the air conditioner from the requirement of extending the running distance per charge.

【0005】しかるに、上記の技術では、冷凍サイクル
の冷媒圧縮機は、室内上流熱交換器、室内下流熱交換
器、および室外熱交換器の3つの熱交換器を流れる冷媒
を駆動する必要があるため、冷媒圧縮機の負荷が大き
く、冷媒圧縮機にかかるエネルギーが大きくなる不具合
がある。また、空調ダクトを流れる空気は、室内上流熱
交換器および室内下流熱交換器を通過するため、空調ダ
クト内の通風抵抗が大きくなり、送風機の消費電力が大
きくなる不具合も有していた。
However, in the above technique, the refrigerant compressor of the refrigeration cycle needs to drive the refrigerant flowing through the three heat exchangers of the indoor upstream heat exchanger, the indoor downstream heat exchanger, and the outdoor heat exchanger. Therefore, there is a problem that the load on the refrigerant compressor is large and the energy applied to the refrigerant compressor is large. Further, since the air flowing through the air conditioning duct passes through the indoor upstream heat exchanger and the indoor downstream heat exchanger, there is also a problem that ventilation resistance in the air conditioning duct increases and power consumption of the blower increases.

【0006】さらに、冷凍サイクルは、室内上流熱交換
器、室内下流熱交換器、室外熱交換器の3つの熱交換器
を備えるため、空気調和装置にかかるコストが高くなる
とともに、空気調和装置にかかる重量が大きくなる。ま
た、冷媒配管の取回しが複雑化する不具合も有してい
た。
Further, since the refrigeration cycle is equipped with three heat exchangers, an indoor upstream heat exchanger, an indoor downstream heat exchanger, and an outdoor heat exchanger, the cost of the air conditioner increases and the air conditioner becomes expensive. This weight becomes large. In addition, there is a problem that the handling of the refrigerant pipe is complicated.

【0007】[0007]

【発明の目的】本発明は、上記の事情に鑑みてなされた
もので、その目的は、車室内に空気を吹き出す空調ダク
ト内に、空気を除湿する熱交換器を設けなくても、外気
を除湿して車室内に吹き出すことのできる車両用空気調
和装置の提供にある。
SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances. An object of the present invention is to remove outside air without providing a heat exchanger for dehumidifying air in an air conditioning duct for blowing air into the passenger compartment. (EN) Provided is a vehicle air conditioner which can be dehumidified and blown into a vehicle interior.

【0008】[0008]

【課題を解決するための手段】[Means for Solving the Problems]

〔請求項1〕請求項1の車両用空気調和装置は、車室外
の空気と熱交換する室外熱交換器がエバポレータとして
作動可能な冷凍サイクルと、前記室外熱交換器がエバポ
レータとして作動する際に、前記室外熱交換器を通過し
た空気を車室内に導くことが可能な外気導入ダクトとを
備える技術的手段を採用する。
[Claim 1] The vehicle air conditioner according to claim 1 has a refrigeration cycle in which an outdoor heat exchanger for exchanging heat with air outside the vehicle compartment can operate as an evaporator, and an outdoor heat exchanger when operating as an evaporator. And an external air introducing duct capable of guiding the air passing through the outdoor heat exchanger into the vehicle compartment.

【0009】〔請求項2〕請求項1にかかる車両用空気
調和装置は、車室内に向けて空気を吹き出される空調ダ
クトと、このダクト内に配置され、車室内に吹き出され
る空気を加熱するコンデンサとして作動可能な前記冷凍
サイクルの室内熱交換器とを備える。そして、前記外気
導入ダクトは、前記空調ダクトに接続され、エバポレー
タとして作動する前記室外熱交換器を通過した空気が、
前記外気導入ダクトおよび前記空調ダクトを介して車室
内に吹き出し可能に設けられた技術的手段を採用する。
According to a second aspect of the present invention, an air conditioning apparatus for a vehicle according to the first aspect is provided with an air conditioning duct for blowing air toward a passenger compartment, and an air conditioning duct arranged in the duct to heat the air blown into the passenger compartment. And an indoor heat exchanger of the refrigeration cycle operable as a condenser. Then, the outside air introduction duct is connected to the air conditioning duct, the air that has passed through the outdoor heat exchanger that operates as an evaporator,
The technical means provided so as to be blown into the vehicle interior through the outside air introduction duct and the air conditioning duct is adopted.

【0010】〔請求項3〕請求項2にかかる車両用空気
調和装置の前記空調ダクトは、乗員の上半身へ向けて空
気を吹き出させるフェイス吹出口、フロントガラスへ向
けて空気を吹き出させるデフロスタ吹出口、および乗員
の足元へ向けて空気を吹き出させるフット吹出口を備え
るとともに、前記室内熱交換器を通過して前記フェイス
吹出口および前記デフロスタ吹出口に導かれる第1層
と、前記室内熱交換器を通過して前記フット吹出口に導
かれる第2層とに分かれて設けられる。そして、前記外
気導入ダクトは、前記室内熱交換器よりも上流の前記第
1層に接続され、エバポレータとして作動する前記室外
熱交換器を通過した空気が、前記フェイス吹出口あるい
は前記デフロスタ吹出口から吹き出し可能に設けられた
技術的手段を採用する。
[Claim 3] The air-conditioning duct of the vehicle air conditioner according to claim 2 has a face outlet for blowing air toward the upper half of the occupant and a defroster outlet for blowing air toward the windshield. And a first layer that is provided with a foot outlet that blows air toward the feet of an occupant, passes through the indoor heat exchanger, and is guided to the face outlet and the defroster outlet, and the indoor heat exchanger. And a second layer that is guided to the foot air outlet. The outside air introduction duct is connected to the first layer upstream of the indoor heat exchanger, and the air that has passed through the outdoor heat exchanger that operates as an evaporator is discharged from the face outlet or the defroster outlet. Adopt technical means that can be blown out.

【0011】〔請求項4〕請求項3にかかる車両用空気
調和装置の前記第1層は、前記外気導入ダクトとの接続
箇所よりも上流に、前記第1層を開閉する第1層開閉ド
アを備える。そして、前記室内熱交換器がコンデンサと
して作動する暖房運転時あるいは除湿暖房運転時に、前
記第1層開閉ドアを閉じて、エバポレータとして作動す
る前記室外熱交換器を通過した空気を前記フェイス吹出
口あるいは前記デフロスタ吹出口から吹き出し、前記第
2層を通過し、前記室内熱交換器を通過して加熱された
空気が前記フット吹出口から吹き出される技術的手段を
採用する。
[Claim 4] The first layer of the vehicle air conditioner according to claim 3 is a first layer opening / closing door that opens and closes the first layer upstream of a connection point with the outside air introducing duct. Equipped with. Then, during the heating operation or the dehumidifying heating operation in which the indoor heat exchanger operates as a condenser, the first layer opening / closing door is closed, and the air that has passed through the outdoor heat exchanger that operates as an evaporator is transferred to the face outlet or The technical means is adopted in which the air blown from the defroster outlet, passed through the second layer, and passed through the indoor heat exchanger to be heated is blown out through the foot outlet.

【0012】[0012]

【発明の作用】室外熱交換器をエバポレータとして作動
させる。すると、室外熱交換器を通過する外気は、冷却
され、除湿される。そして、除湿された外気は、外気導
入ダクトを介して車室内に導かれ、車室内の湿度を抑え
て窓ガラスの曇りを防ぐ。特に、外気導入ダクトから導
かれた除湿された外気を、窓ガラスに導くことにより、
効率的に窓ガラスの曇りを抑えることができる。
The outdoor heat exchanger is operated as an evaporator. Then, the outside air passing through the outdoor heat exchanger is cooled and dehumidified. Then, the dehumidified outside air is introduced into the vehicle compartment through the outside air introduction duct to suppress the humidity in the vehicle compartment and prevent the window glass from fogging. In particular, by introducing the dehumidified outside air introduced from the outside air introduction duct to the window glass,
It is possible to efficiently suppress the fogging of the window glass.

【0013】[0013]

【発明の効果】本発明の車両用空気調和装置は、上記の
作用で示したように、室外熱交換器を外気を除湿する熱
交換器として利用しているので、他に室内に吹き出す空
気を除湿するための熱交換器を設ける必要がない。
As described above, the vehicle air conditioner of the present invention uses the outdoor heat exchanger as a heat exchanger for dehumidifying the outside air. There is no need to provide a heat exchanger for dehumidification.

【0014】このため、例えば従来技術で示したよう
に、車室内に空気を吹き出す空調ダクト内に、空気を除
湿する熱交換器を設けなくても、窓ガラスの曇りを抑え
ることができる。
Therefore, for example, as shown in the prior art, it is possible to suppress the fogging of the window glass without providing a heat exchanger for dehumidifying the air in the air conditioning duct for blowing the air into the passenger compartment.

【0015】また、除湿暖房運転するために、従来技術
で示したように、室内上流熱交換器、室内下流熱交換
器、および室外熱交換器の3つの熱交換器を流れる冷媒
を駆動する必要がなく、エバポレータとして作動する室
外熱交換器と、コンデンサとして作動する熱交換器(例
えば室内熱交換器)との、2つの熱交換器を流れる冷媒
を駆動するのみで良く、従来に比較して冷媒圧縮機にか
かる負荷が小さくなる。この結果、冷媒圧縮機にかかる
エネルギー消費を小さく抑えることができる。
In order to perform the dehumidifying and heating operation, it is necessary to drive the refrigerant flowing through the three heat exchangers of the indoor upstream heat exchanger, the indoor downstream heat exchanger, and the outdoor heat exchanger, as shown in the prior art. There is no need to drive the refrigerant flowing through two heat exchangers, an outdoor heat exchanger that operates as an evaporator and a heat exchanger that operates as a condenser (for example, an indoor heat exchanger). The load on the refrigerant compressor is reduced. As a result, the energy consumption of the refrigerant compressor can be reduced.

【0016】室外熱交換器を通過した空気によって除湿
を行うため、例えば空調ダクト内には、除湿を行うため
の熱交換器を配置する必要がなく、空調ダクトの通風抵
抗を小さくすることができる。このため、空調ダクト内
に空気流を生じさせる送風機の消費電力を小さく抑える
ことができる。
Since dehumidification is performed by the air that has passed through the outdoor heat exchanger, it is not necessary to dispose a heat exchanger for dehumidification in, for example, the air conditioning duct, and the ventilation resistance of the air conditioning duct can be reduced. . Therefore, it is possible to suppress the power consumption of the blower that causes the air flow in the air conditioning duct to be small.

【0017】さらに、冷凍サイクルは、エバポレータと
して作動する室外熱交換器と、コンデンサとして作動す
る熱交換器(例えば室内熱交換器)との2つの熱交換器
で済むため、空気調和装置にかかるコストを低く抑える
ことができるとともに、空気調和装置にかかる重量も小
さくなる。また、冷媒配管の取回しも簡素化できる効果
も奏する。
Further, since the refrigeration cycle requires only two heat exchangers, an outdoor heat exchanger that operates as an evaporator and a heat exchanger (for example, an indoor heat exchanger) that operates as a condenser, the cost of the air conditioner is low. Can be kept low, and the weight of the air conditioner can be reduced. Further, there is an effect that the handling of the refrigerant pipe can be simplified.

【0018】[0018]

【実施例】次に、本発明の車両用空気調和装置を、図に
示す一実施例に基づき説明する。 〔実施例の構成〕図1ないし図3は請求項1ないし請求
項4を採用した実施例を示すもので、図1は空気調和装
置のダクトの概略構成図、図2はヒートポンプ式冷凍サ
イクルの冷媒回路図である。 (室外熱交換器の説明)本実施例の車両用空気調和装置
1は、例えば電気自動車に搭載されるもので、車両が走
行した際に走行風を受ける位置に、ヒートポンプ式冷凍
サイクル2の室外熱交換器3が配置されている。
DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, a vehicle air conditioner of the present invention will be described based on an embodiment shown in the drawings. [Structure of Embodiments] FIGS. 1 to 3 show an embodiment in which claims 1 to 4 are adopted. FIG. 1 is a schematic structure diagram of a duct of an air conditioner, and FIG. 2 is a heat pump type refrigeration cycle. It is a refrigerant circuit diagram. (Explanation of Outdoor Heat Exchanger) The vehicle air conditioner 1 of this embodiment is installed in, for example, an electric vehicle, and is placed outside the heat pump type refrigeration cycle 2 at a position where the vehicle receives traveling wind when the vehicle travels. The heat exchanger 3 is arranged.

【0019】この室外熱交換器3は、車室外に配置され
て、室外ファン4によって強制的に熱交換される外気
と、内部を流れる冷媒との熱交換を行うもので、冷房運
転時にコンデンサとして作動し、暖房運転時、除湿暖房
運転時にエバポレータとして作動する。
The outdoor heat exchanger 3 is arranged outside the vehicle compartment and exchanges heat between the outside air forcibly exchanged with heat by the outdoor fan 4 and the refrigerant flowing inside, and serves as a condenser during cooling operation. It operates and operates as an evaporator during heating operation and dehumidifying heating operation.

【0020】この室外熱交換器3は、室外熱交換器3が
エバポレータとして作動する除湿暖房運転時に、室外熱
交換器3を通過した空気を車室内に導く外気導入ダクト
5が接続されている。この外気導入ダクト5は、室外フ
ァン4の発生した空気流によって、室外熱交換器3を通
過した空気を車室内に導くもので、図1に示すように、
2つの室外ファン4のうちの一方の室外ファン4のファ
ンシュラウド6に、室外熱交換器3を通過した空気を車
室内へ導く外気導入ダクト5が設けられている(請求項
1にかかる構成)。なお、上述のように、室外熱交換器
3は、走行風を受ける位置に配置されるため、例え室外
ファン4が作動しなくても、車両の走行風によって室外
熱交換器3を通過した空気が、外気導入ダクト5を介し
て車室内に導かれる。そして、外気導入ダクト5は、車
室内に向けて空調風を吹き出す空調ダクト7に接続され
ている(請求項2にかかる構成)。
The outdoor heat exchanger 3 is connected to an outdoor air introducing duct 5 for guiding the air passing through the outdoor heat exchanger 3 into the vehicle compartment during the dehumidifying and heating operation in which the outdoor heat exchanger 3 operates as an evaporator. The outdoor air introducing duct 5 guides the air passing through the outdoor heat exchanger 3 into the vehicle interior by the air flow generated by the outdoor fan 4, and as shown in FIG.
The fan shroud 6 of one of the two outdoor fans 4 is provided with an outside air introduction duct 5 that guides the air that has passed through the outdoor heat exchanger 3 into the vehicle interior (configuration according to claim 1). . As described above, since the outdoor heat exchanger 3 is arranged at a position to receive the traveling wind, the air that has passed through the outdoor heat exchanger 3 due to the traveling wind of the vehicle even if the outdoor fan 4 does not operate. Are introduced into the vehicle compartment through the outside air introduction duct 5. The outside air introduction duct 5 is connected to an air conditioning duct 7 that blows out conditioned air toward the passenger compartment (configuration according to claim 2).

【0021】(空調ダクト7の説明)空調ダクト7は、
室内へ向けて空気を送る空気通路をなすダクトで、この
空調ダクト7の一端には、空調ダクト7内において室内
へ向かう空気流を生じさせる電動モータ駆動の送風機8
が接続されている。そして、この送風機8は、車室内空
気(内気)を吸引する内気導入口9のみを備える。
(Explanation of the air conditioning duct 7)
A duct that forms an air passage for sending air toward the room. At one end of the air conditioning duct 7, a blower 8 driven by an electric motor that creates an air flow toward the room in the air conditioning duct 7.
Are connected. The blower 8 is provided only with the inside air introduction port 9 for sucking the air (inside air) inside the vehicle.

【0022】空調ダクト7の他端には、空調ダクト7内
を通過した空気を室内の各部へ向けて吹き出す吹出口が
形成されている。この吹出口は、室内前部の中央より、
乗員の上半身へ向けて主に冷風を吹き出すセンタフェイ
ス吹出口10と、室内前部の両脇より、乗員の上半身あ
るいはサイドガラスへ向けて主に冷風を吹き出すサイド
フェイス吹出口11と、フロントガラスへ向けて主に温
風を吹き出すデフロスタ吹出口12と、乗員の足元へ向
けて主に温風を吹き出すフット吹出口13とからなる。
そして、空調ダクト7内には、サイドフェイス吹出口1
1を除く他の吹出口へ通じる空気通路に、各吹出口への
空気流を制御するセンタフェイスドア14、デフロスタ
ドア15、およびフットドア16が設けられている。
At the other end of the air conditioning duct 7, there is formed an air outlet for blowing the air passing through the air conditioning duct 7 toward each part in the room. This outlet is from the center of the front of the room,
Center face outlet 10 that mainly blows cool air toward the upper body of the occupant, and side face outlets 11 that mainly blows cool air toward the upper body of the occupant or the side glass from both sides of the front of the room, and toward the windshield The defroster outlet 12 mainly blows warm air, and the foot outlet 13 mainly blows warm air toward the feet of the occupant.
Then, in the air conditioning duct 7, the side face outlet 1
A center face door 14, a defroster door 15, and a foot door 16 that control the air flow to each of the air outlets are provided in the air passages that communicate with the other air outlets except 1.

【0023】空調ダクト7内には、空調ダクト7内を流
れる空気を冷却または加熱する室内熱交換器20が配置
されている。この室内熱交換器20は、ヒートポンプ式
冷凍サイクル2の構成部品で、冷房運転時にエバポレー
タとして作動し、暖房運転時にコンデンサとして作動す
る。そして、空調ダクト7内には、室内熱交換器20を
迂回させるバイパス通路21を備える。このバイパス通
路21には、バイパス通路21の開閉を行い、バイパス
通路21の開度を変化させるクールドア22が設けられ
ている。
An indoor heat exchanger 20 for cooling or heating the air flowing in the air conditioning duct 7 is arranged in the air conditioning duct 7. The indoor heat exchanger 20 is a component of the heat pump refrigeration cycle 2, and operates as an evaporator during cooling operation and as a condenser during heating operation. A bypass passage 21 that bypasses the indoor heat exchanger 20 is provided in the air conditioning duct 7. The bypass passage 21 is provided with a cool door 22 that opens and closes the bypass passage 21 and changes the opening degree of the bypass passage 21.

【0024】また、空調ダクト7内の室内熱交換器20
の上流および下流には、室内熱交換器20を通過した空
気あるいはバイパス通路21を通過した空気をセンタフ
ェイス吹出口10、サイドフェイス吹出口11、デフロ
スタ吹出口12へ導く第1層23と、室内熱交換器20
を通過した空気をフット吹出口13へ導く第2層24と
に分けるための仕切壁25が設けられている。そして、
第1層23の室内熱交換器20およびバイパス通路21
の上流に、外気導入ダクト5が接続され、室外熱交換器
3を通過した外気が第1層23を通ってセンタフェイス
吹出口10、サイドフェイス吹出口11、デフロスタ吹
出口12へ吹き出されるように設けられている(請求項
3にかかる構成)。
The indoor heat exchanger 20 in the air conditioning duct 7
Upstream and downstream of the first layer 23 that guides the air that has passed through the indoor heat exchanger 20 or the air that has passed through the bypass passage 21 to the center face outlet 10, the side face outlet 11, and the defroster outlet 12; Heat exchanger 20
A partition wall 25 is provided to divide the air passing through the second layer 24 into the foot outlet 13. And
The indoor heat exchanger 20 and the bypass passage 21 of the first layer 23
Is connected to the outside air introduction duct 5 so that the outside air passing through the outdoor heat exchanger 3 is blown out to the center face outlet 10, the side face outlet 11, and the defroster outlet 12 through the first layer 23. (The structure according to claim 3).

【0025】なお、外気導入ダクト5には、外気導入ダ
クト5内に導かれた外気が車室外へ排出する排出ポート
26が形成されている。そして、外気導入ダクト5の下
流部分には、排出ポート26あるいは外気導入ダクト5
の下流を塞ぐ外気切替ドア27が設けられている。この
外気切替ドア27は、外気を空調ダクト7内(車室内)
に導かないモード時(本実施例では、冷房運転時と暖房
運転時であるが、暖房運転時に外気を車室内に一部導
き、防曇するように設けても良い)に、排出ポート26
を開いて外気導入ダクト5の下流を閉じ、空調ダクト7
内に外気が導入されるのを阻止するように設けられてい
る。なお、外気切替ドア27の開度を変化させて、除湿
の要求割合(例えば乗員の数や、使用者の設定値など)
に応じて、車室内に導かれる外気量を調節するように設
けても良い。
The outside air introduction duct 5 is formed with a discharge port 26 through which the outside air introduced into the outside air introduction duct 5 is discharged to the outside of the vehicle compartment. The exhaust port 26 or the outside air introducing duct 5 is provided at the downstream portion of the outside air introducing duct 5.
An outside air switching door 27 that closes the downstream side of is provided. The outside air switching door 27 allows the outside air to enter the air conditioning duct 7 (inside the passenger compartment).
In the mode in which the air is not guided to the exhaust port 26 (in the present embodiment, it is during the cooling operation and the heating operation, but it may be provided so that part of the outside air is introduced into the vehicle interior during the heating operation to prevent fogging).
To close the downstream side of the outside air introduction duct 5,
It is provided so as to prevent the outside air from being introduced therein. In addition, by changing the opening degree of the outside air switching door 27, the required ratio of dehumidification (for example, the number of passengers, the set value of the user, etc.)
According to the above, it may be provided so as to adjust the amount of outside air introduced into the vehicle compartment.

【0026】一方、第1層23は、外気導入ダクト5と
の接続箇所よりも上流に、第1層23を開閉する第1層
開閉ドア28を備える。この第1層開閉ドア28は、暖
房除湿運転時に第1層23の上流を塞ぎ、第1層23を
通ってセンタフェイス吹出口10、サイドフェイス吹出
口11、デフロスタ吹出口12へ吹き出される空気が、
室外熱交換器3を通過した空気のみにするものである
(請求項4にかかる構成)。なお、第1層開閉ドア28
の開度を変化させて、除湿の要求割合(例えば乗員の数
や、使用者の設定値など)に応じて、第1層23を通過
する内気と、外気導入ダクト5から導入された外気との
割合を調節するように設けても良い。
On the other hand, the first layer 23 is provided with a first layer opening / closing door 28 for opening / closing the first layer 23 upstream of the connection point with the outside air introducing duct 5. The first layer opening / closing door 28 closes the upstream of the first layer 23 during the heating / dehumidifying operation, and blows air through the first layer 23 to the center face outlet 10, the side face outlet 11, and the defroster outlet 12. But,
Only the air that has passed through the outdoor heat exchanger 3 is used (the configuration according to claim 4). The first layer opening / closing door 28
Of the inside air passing through the first layer 23 and the outside air introduced from the outside air introduction duct 5 in accordance with the dehumidification request ratio (for example, the number of occupants, the set value of the user, etc.). You may provide so that the ratio of may be adjusted.

【0027】なお、室内熱交換器20は、仕切壁25を
貫通した状態で空調ダクト7内に配置される。また、仕
切壁25の下流には、フェイスモード時およびデフロス
タモード時に、第1層23と第2層24とを連通させる
ための連通口29が設けられている。この連通口29に
は、この連通口29の開閉を行う連通ドア30が設けら
れ、フェイスモードあるいはデフロスタモードが選択さ
れた際に、連通ドア30が連通口29を開くように設け
られている。
The indoor heat exchanger 20 is arranged in the air conditioning duct 7 while penetrating the partition wall 25. Further, a communication port 29 for communicating the first layer 23 and the second layer 24 in the face mode and the defroster mode is provided downstream of the partition wall 25. The communication port 29 is provided with a communication door 30 that opens and closes the communication port 29. When the face mode or the defroster mode is selected, the communication door 30 opens the communication port 29.

【0028】室外熱交換器3および室内熱交換器20
は、上述のように、ヒートポンプ式冷凍サイクル2の構
成部品で、本実施例に採用される冷凍サイクル2の一例
を、図2の冷媒回路図に示す。本実施例の冷凍サイクル
2は、アキュムレータサイクルで、室外熱交換器3およ
び室内熱交換器20の他に、冷媒圧縮機31、冷房用減
圧装置32、暖房用減圧装置33、アキュムレータ3
4、および冷媒の流れ方向を切り替える流路切替手段3
5を備える。
The outdoor heat exchanger 3 and the indoor heat exchanger 20
2 is a component of the heat pump refrigeration cycle 2 as described above, and an example of the refrigeration cycle 2 used in this embodiment is shown in the refrigerant circuit diagram of FIG. The refrigeration cycle 2 of the present embodiment is an accumulator cycle, and in addition to the outdoor heat exchanger 3 and the indoor heat exchanger 20, a refrigerant compressor 31, a cooling decompression device 32, a heating decompression device 33, an accumulator 3 are provided.
4, and the flow path switching means 3 for switching the flow direction of the refrigerant
5 is provided.

【0029】冷媒圧縮機31は、冷媒の吸入、圧縮、吐
出を行うもので、図示しない電動モータにより駆動され
る。この冷媒圧縮機31は、電動モータと一体的に密封
ケース内に配置される。冷媒圧縮機31を駆動する電動
モータは、図示しないインバータによる制御によって回
転速度が可変して、冷媒圧縮機31の冷媒吐出容量が変
化する。そして、インバータにより冷媒圧縮機31の回
転速度を変化させることによる冷媒圧縮機31の容量変
化により、吹出温度の制御を行っている。
The refrigerant compressor 31 sucks, compresses and discharges the refrigerant, and is driven by an electric motor (not shown). The refrigerant compressor 31 is arranged inside the sealed case integrally with the electric motor. The rotation speed of the electric motor that drives the refrigerant compressor 31 is changed by control by an inverter (not shown), and the refrigerant discharge capacity of the refrigerant compressor 31 changes. The outlet temperature is controlled by changing the capacity of the refrigerant compressor 31 by changing the rotation speed of the refrigerant compressor 31 with the inverter.

【0030】冷房用減圧装置32は、冷房運転時に室内
熱交換器20へ流入する冷媒を減圧膨張する膨張弁であ
る。暖房用減圧装置33は、暖房運転時および除湿暖房
運転時に室外熱交換器3へ流入する冷媒を減圧膨張する
膨張弁で、例えば、除湿暖房運転時に室内熱交換器20
のスーパークール量を調節するように設けられる。
The cooling decompression device 32 is an expansion valve that decompresses and expands the refrigerant flowing into the indoor heat exchanger 20 during the cooling operation. The heating decompression device 33 is an expansion valve that decompresses and expands the refrigerant flowing into the outdoor heat exchanger 3 during the heating operation and the dehumidifying and heating operation. For example, the indoor heat exchanger 20 during the dehumidifying and heating operation.
It is provided to adjust the amount of super cool.

【0031】冷媒の流路切替手段35は、冷房運転、暖
房運転、および除湿暖房運転で冷媒の流れ方向を切り替
えるもので、図2に示すように、冷媒圧縮機31の吐出
方向を室内熱交換器20か、室外熱交換器3かに切り替
える四方弁36、バイパス冷媒配管37、複数の電磁開
閉弁38、および複数の逆止弁39から構成される。
The refrigerant flow path switching means 35 switches the flow direction of the refrigerant in the cooling operation, the heating operation, and the dehumidifying and heating operation. As shown in FIG. 2, the discharge direction of the refrigerant compressor 31 is changed to indoor heat exchange. A four-way valve 36 for switching between the device 20 or the outdoor heat exchanger 3, a bypass refrigerant pipe 37, a plurality of electromagnetic opening / closing valves 38, and a plurality of check valves 39.

【0032】そして、流路切替手段35は、冷房運転
時、暖房運転時および除湿暖房運転時に応じて、次のよ
うに冷媒の流れを切り替える。冷房運転時は、冷媒圧縮
機31の吐出した冷媒を、四方弁36→室外熱交換器3
→冷房用減圧装置32→室内熱交換器20→四方弁36
→アキュムレータ34→冷媒圧縮機31の順に流す(図
中矢印C参照)。暖房運転時は、冷媒圧縮機31の吐出
した冷媒を、四方弁36→室内熱交換器20→暖房用減
圧装置33→室外熱交換器3→四方弁36→アキュムレ
ータ34→冷媒圧縮機31の順に流す(図中矢印H参
照)。除湿暖房運転時は、暖房運転時と同様、冷媒圧縮
機31の吐出した冷媒を、四方弁36→室内熱交換器2
0→暖房用減圧装置33→室外熱交換器3→四方弁36
→アキュムレータ34→冷媒圧縮機31の順に流す(図
中矢印D参照)。
Then, the flow path switching means 35 switches the flow of the refrigerant as follows according to the cooling operation, the heating operation and the dehumidifying heating operation. During the cooling operation, the refrigerant discharged from the refrigerant compressor 31 is discharged from the four-way valve 36 to the outdoor heat exchanger 3
→ Cooling decompression device 32 → Indoor heat exchanger 20 → Four-way valve 36
The flow is made in the order of the accumulator 34 and the refrigerant compressor 31 (see arrow C in the figure). During the heating operation, the refrigerant discharged from the refrigerant compressor 31 is transferred in the order of the four-way valve 36, the indoor heat exchanger 20, the heating decompression device 33, the outdoor heat exchanger 3, the four-way valve 36, the accumulator 34, and the refrigerant compressor 31. Flow (see arrow H in the figure). During the dehumidifying heating operation, the refrigerant discharged from the refrigerant compressor 31 is transferred to the four-way valve 36 → the indoor heat exchanger 2 as in the heating operation.
0 → decompression device for heating 33 → outdoor heat exchanger 3 → four-way valve 36
The flow is made in the order of the accumulator 34 and the refrigerant compressor 31 (see arrow D in the figure).

【0033】上述の室外ファン4、送風機8、電動モー
タのインバータ、四方弁36、各電磁開閉弁38、外気
切替ドア27を駆動するアクチュエータ(図示しな
い)、第1層開閉ドア28を駆動するアクチュエータ
(図示しない)などの電気部品は、制御装置40によっ
て通電制御される。
The outdoor fan 4, the blower 8, the inverter of the electric motor, the four-way valve 36, each electromagnetic opening / closing valve 38, the actuator (not shown) for driving the outside air switching door 27, and the actuator for driving the first layer opening / closing door 28. Electric components such as (not shown) are controlled by the control device 40.

【0034】制御装置40は、乗員によって操作される
操作パネル41(図3参照)の操作信号等に従って、各
電気部品の通電制御を行うもので、操作パネル41は室
内の操作性の良い位置に設置される。操作パネル41
は、各吹出モードの設定を行う吹出モード切替スイッチ
42、空調ダクト7より室内へ吹き出される風量を設定
する風量設定スイッチ43、冷凍サイクル2の起動、停
止を指示する冷暖房スイッチ44、除湿指示を与える除
湿スイッチ45、車室内への吹出温度を調節する温度調
節レバー46を備える。
The control device 40 controls energization of each electric component in accordance with an operation signal of an operation panel 41 (see FIG. 3) operated by an occupant, and the operation panel 41 is located at a position where operability is good in a room. Is installed. Operation panel 41
Is a blowout mode switch 42 for setting each blowout mode, an air volume setting switch 43 for setting the amount of air blown into the room from the air conditioning duct 7, a cooling / heating switch 44 for instructing start and stop of the refrigeration cycle 2, and a dehumidification instruction. A dehumidifying switch 45 for giving and a temperature adjusting lever 46 for adjusting the temperature of air blown into the vehicle compartment are provided.

【0035】なお、吹出モード切替スイッチ42は、乗
員の上半身へ向けて空調ダクト7内の空気を吐出させる
フェイスモードスイッチ47、乗員の上半身へ比較的冷
たい空気、乗員の足元へ比較的温かい空気を吐出させる
バイレベルモードスイッチ48、主に乗員の足元へ比較
的温かい空気を吐出させるフットモードスイッチ49、
主にフロントガラスへ比較的温かい空気を吐出させるデ
フモードスイッチ50からなる。また、冷暖房スイッチ
44は、冷凍サイクル2の冷媒圧縮機31のオン、オフ
を行うもので、この冷暖房スイッチ44とフェイスモー
ドスイッチ47の両方がONされると冷凍サイクル2は冷
房運転を行い、またバイレベルモードスイッチ48、フ
ットモードスイッチ49およびデフモードスイッチ50
のいずれか1つと冷暖房スイッチ44の両者がONされる
と冷凍サイクル2が暖房運転を行うように設けられてい
る。
The blow-out mode switch 42 is a face mode switch 47 for discharging the air in the air conditioning duct 7 toward the upper body of the occupant, relatively cool air to the upper body of the occupant, and relatively warm air to the feet of the occupant. A bi-level mode switch 48 for ejecting, a foot mode switch 49 for ejecting relatively warm air mainly to the occupant's feet,
It mainly comprises a differential mode switch 50 for discharging relatively warm air to the windshield. Further, the cooling / heating switch 44 turns on / off the refrigerant compressor 31 of the refrigeration cycle 2. When both the cooling / heating switch 44 and the face mode switch 47 are turned on, the refrigeration cycle 2 performs cooling operation, and Bi-level mode switch 48, foot mode switch 49 and differential mode switch 50
The refrigeration cycle 2 is provided so as to perform the heating operation when any one of the above and the cooling / heating switch 44 are turned on.

【0036】また、温度調節レバー46は、設定位置に
応じて冷媒圧縮機31の回転速度が設定されるもので、
例えば冷房運転時に温度調節レバー46をクール側へ移
動させるに従い、冷媒圧縮機31の回転が速くなり、エ
バポレータとして作動する室内熱交換器20を通過する
空気の冷却能力を連続的に高くさせるものである。逆に
暖房運転時に温度調節レバー46をホット側へ移動させ
るに従い冷媒圧縮機31の回転が速くなり、コンデンサ
として作動する室内熱交換器20を通過する空気の加熱
能力を連続的に高くさせるものである。なお、除湿暖房
運転時に温度調節レバー46をホット側へ移動させるに
従い冷媒圧縮機31の回転が速くなり、コンデンサとし
て作動する室内熱交換器20を通過する空気の加熱能力
を連続的に高くさせ、除湿時の暖房能力を調節する。
The temperature adjusting lever 46 sets the rotational speed of the refrigerant compressor 31 in accordance with the set position.
For example, as the temperature control lever 46 is moved to the cool side during the cooling operation, the rotation of the refrigerant compressor 31 becomes faster and the cooling capacity of the air passing through the indoor heat exchanger 20 that operates as an evaporator is continuously increased. is there. Conversely, as the temperature control lever 46 is moved to the hot side during the heating operation, the rotation of the refrigerant compressor 31 becomes faster, and the heating capacity of the air passing through the indoor heat exchanger 20 that operates as a condenser is continuously increased. is there. In addition, as the temperature control lever 46 is moved to the hot side during the dehumidification heating operation, the rotation of the refrigerant compressor 31 becomes faster, and the heating capacity of the air passing through the indoor heat exchanger 20 that operates as a condenser is continuously increased. Adjust the heating capacity during dehumidification.

【0037】〔実施例の作動〕次に、上記実施例の作動
を説明する。 (冷房運転)乗員により操作パネル41のフェイスモー
ドスイッチ47と冷暖房スイッチ44がONされ、風量設
定スイッチ43がONされ、温度調節レバー46がクール
側に設定されると、冷凍サイクル2は冷房運転を行うと
ともに、外気切替ドア27が外気導入ダクト5を閉じ、
第1層開閉ドア28が第1層23の上流を開いた状態
で、送風機8が作動する。すると、室外熱交換器3がコ
ンデンサとして作動し、室内熱交換器20がエバポレー
タとして作動する。このモードでは、クールドア22は
閉じられ、送風機8が空調ダクト7内に送り込んだ内気
が全て室内熱交換器20を通り、冷却されて、主にセン
タフェイス吹出口10、サイドフェイス吹出口11よ
り、車室内へ吹き出される。なお、このモードでは、外
気切替ドア27によって排出ポート26が開かれ、外気
導入ダクト5の下流が閉じられるため、コンデンサとし
て作動する室外熱交換器3を通過した温かい外気は、空
調ダクト7内には導かれない。
[Operation of Embodiment] Next, the operation of the above embodiment will be described. (Cooling operation) When the occupant turns on the face mode switch 47 and the cooling / heating switch 44 of the operation panel 41, turns on the air volume setting switch 43, and sets the temperature adjusting lever 46 to the cool side, the refrigeration cycle 2 starts the cooling operation. At the same time, the outside air switching door 27 closes the outside air introduction duct 5,
The blower 8 operates while the first layer opening / closing door 28 is open upstream of the first layer 23. Then, the outdoor heat exchanger 3 operates as a condenser, and the indoor heat exchanger 20 operates as an evaporator. In this mode, the cool door 22 is closed, and all the inside air sent by the blower 8 into the air conditioning duct 7 passes through the indoor heat exchanger 20 and is cooled, mainly from the center face outlet 10 and the side face outlet 11, It is blown out into the passenger compartment. In this mode, since the exhaust port 26 is opened by the outside air switching door 27 and the downstream side of the outside air introduction duct 5 is closed, the warm outside air that has passed through the outdoor heat exchanger 3 that operates as a condenser enters the inside of the air conditioning duct 7. Is not guided.

【0038】(暖房運転)乗員により操作パネル41の
バイレベルモードスイッチ48、フットモードスイッチ
49およびデフモードスイッチ50のいずれか1つと冷
暖房スイッチ44の両者がONされ、風量設定スイッチ4
3がONされ、温度調節レバー46がホット側に設定され
ると、冷凍サイクル2は暖房運転を行うとともに、外気
切替ドア27が外気導入ダクト5を閉じ、第1層開閉ド
ア28が第1層23の上流を開いた状態で、送風機8が
作動する。すると、室外熱交換器3がエバポレータとし
て作動し、室内熱交換器20がコンデンサとして作動す
る。このモードでも、バイレベルモード以外はクールド
ア22は閉じられ、送風機8が空調ダクト7内に送り込
んだ内気が全て室内熱交換器20を通り加熱され、主に
フット吹出口13およびデフロスタ吹出口12から温風
が吹き出される。
(Heating operation) An occupant turns on any one of the bi-level mode switch 48, the foot mode switch 49 and the diff mode switch 50 of the operation panel 41 and both the cooling and heating switch 44, and the air volume setting switch 4
3 is turned on and the temperature control lever 46 is set to the hot side, the refrigeration cycle 2 performs the heating operation, the outside air switching door 27 closes the outside air introduction duct 5, and the first layer opening / closing door 28 opens the first layer. The blower 8 operates with the upstream side of 23 open. Then, the outdoor heat exchanger 3 operates as an evaporator, and the indoor heat exchanger 20 operates as a condenser. Even in this mode, the cool door 22 is closed except in the bi-level mode, and all the inside air sent by the blower 8 into the air conditioning duct 7 is heated through the indoor heat exchanger 20, and mainly from the foot outlet 13 and the defroster outlet 12. Hot air is blown out.

【0039】なお、バイレベルモードでは、クールドア
22を開くことによって、第1層23を流れる空気の加
熱度合を小さくすることができる。この時、外気導入ダ
クト5の開度を大きくすることにより、上下の温度差を
大きく調節できる。また、この暖房運転時に、外気導入
ダクト5の開度を開いて、エバポレータとして作動する
室外熱交換器3を通過した除湿された空気の一部を、空
調ダクト7内に導き、窓ガラスの曇りを抑えて暖房運転
を行うように設けても良い。
In the bilevel mode, the degree of heating of the air flowing through the first layer 23 can be reduced by opening the cool door 22. At this time, by increasing the opening degree of the outside air introduction duct 5, the temperature difference between the upper and lower sides can be adjusted significantly. Further, during this heating operation, the opening degree of the outside air introduction duct 5 is opened, and a part of the dehumidified air that has passed through the outdoor heat exchanger 3 that operates as an evaporator is introduced into the air conditioning duct 7 so that the window glass becomes cloudy. You may provide so that heating operation may be suppressed and suppressed.

【0040】(除湿暖房運転)上記暖房運転中に、除湿
スイッチ45がONされた状態では、外気切替ドア27に
よって排出ポート26が閉じられ、外気導入ダクト5が
開かれるため、エバポレータとして作動する室外熱交換
器3を通過した除湿された外気は、空調ダクト7の第1
層23内に導かれる。この時、第1層開閉ドア28によ
って第1層23の上流が閉じられ、第1層23への内気
の導入が阻止される。この結果、第1層23には、エバ
ポレータとして作動する室外熱交換器3を通過した除湿
された外気のみが導かれる。そして、第1層23を通過
する除湿された外気は、コンデンサとして作動する室内
熱交換器20によって再加熱され、湿度の大変低い温か
い外気となってサイドフェイス吹出口11やデフロスタ
吹出口12から吹き出され、フロントガラスおよびサイ
ドガラスの曇りを防ぐ。
(Dehumidifying and Heating Operation) During the heating operation, when the dehumidifying switch 45 is turned on, the outside air switching door 27 closes the discharge port 26 and opens the outside air introducing duct 5, so that the outside air that operates as an evaporator is operated. The dehumidified outside air that has passed through the heat exchanger 3 receives the first air from the air conditioning duct 7.
Guided into layer 23. At this time, the upstream of the first layer 23 is closed by the first layer opening / closing door 28, and the introduction of the inside air into the first layer 23 is blocked. As a result, only the dehumidified outside air that has passed through the outdoor heat exchanger 3 that operates as an evaporator is guided to the first layer 23. The dehumidified outside air passing through the first layer 23 is reheated by the indoor heat exchanger 20 that operates as a condenser, and becomes warm outside air with extremely low humidity, and is blown out from the side face outlet 11 and the defroster outlet 12. Prevents fogging of the windshield and side windows.

【0041】〔実施例の効果〕本実施例の空気調和装置
1は、暖房運転時にエバポレータとして作動する室外熱
交換器3を、外気を除湿する熱交換器として利用してい
るので、空調ダクト7内に、暖房運転時に空気を除湿す
るための熱交換器を設ける必要がない。このため、従来
技術で示したように、空調ダクト7内に、空気を除湿す
るための熱交換器と、除湿された空気を再加熱するため
の熱交換器とを設けなくても、窓ガラスの曇りを抑える
ことができる。
[Effects of Embodiment] In the air conditioner 1 of this embodiment, since the outdoor heat exchanger 3 that operates as an evaporator during heating operation is used as a heat exchanger that dehumidifies the outside air, the air conditioning duct 7 is used. It is not necessary to provide a heat exchanger therein to dehumidify the air during heating operation. For this reason, as shown in the prior art, even if the heat exchanger for dehumidifying the air and the heat exchanger for reheating the dehumidified air are not provided in the air conditioning duct 7, the window glass The cloudiness of can be suppressed.

【0042】また、除湿暖房運転するために、空気を除
湿するための熱交換器と、除湿された空気を再加熱する
ための熱交換器と、室外熱交換器3との3つの熱交換器
を流れる冷媒を冷媒圧縮機31が駆動する必要がなく、
エバポレータとして作動する室外熱交換器3と、コンデ
ンサとして作動する熱交換器(例えば室内熱交換器2
0)との2つの熱交換器を流れる冷媒を冷媒圧縮機31
は駆動するのみで良く、従来に比較して冷媒圧縮機31
にかかる負荷を小さくできる。この結果、冷媒圧縮機3
1にかかるエネルギー消費を小さく抑えることができ
る。
In order to perform dehumidifying and heating operation, there are three heat exchangers: a heat exchanger for dehumidifying air, a heat exchanger for reheating dehumidified air, and an outdoor heat exchanger 3. It is not necessary for the refrigerant compressor 31 to drive the refrigerant flowing through
The outdoor heat exchanger 3 operating as an evaporator and the heat exchanger operating as a condenser (for example, the indoor heat exchanger 2
0) and the refrigerant flowing through the two heat exchangers to the refrigerant compressor 31
Need only be driven.
The load on the can be reduced. As a result, the refrigerant compressor 3
The energy consumption of 1 can be suppressed to be small.

【0043】さらに、除湿暖房運転するために、空調ダ
クト7内に、空気を除湿するための熱交換器と、除湿さ
れた空気を再加熱するための熱交換器との2つの熱交換
器を設けなくても、空調ダクト7内には、1つの室内熱
交換器20を設けるのみで除湿暖房ができるため、空調
ダクト7の通風抵抗が小さくなる。このため、空調ダク
ト7内に空気流を生じさせる送風機8の消費電力を小さ
く抑えることができる。
Further, in order to perform the dehumidifying and heating operation, two heat exchangers, a heat exchanger for dehumidifying the air and a heat exchanger for reheating the dehumidified air, are provided in the air conditioning duct 7. Even if it is not provided, dehumidifying and heating can be performed by providing only one indoor heat exchanger 20 in the air conditioning duct 7, so the ventilation resistance of the air conditioning duct 7 becomes small. Therefore, it is possible to reduce the power consumption of the blower 8 that causes an air flow in the air conditioning duct 7.

【0044】冷凍サイクル2は、エバポレータとして作
動する室外熱交換器3と、コンデンサとして作動する室
内熱交換器20との2つの熱交換器で済むため、空気調
和装置1にかかるコストを低く抑えることができる。ま
た、空気調和装置1にかかる重量が小さくなるととも
に、熱交換器が2つで済むことにより、冷媒配管の取回
しも簡素化できる。
Since the refrigeration cycle 2 needs only two heat exchangers, the outdoor heat exchanger 3 which operates as an evaporator and the indoor heat exchanger 20 which operates as a condenser, the cost of the air conditioner 1 can be kept low. You can Further, since the weight applied to the air conditioner 1 is reduced and only two heat exchangers are needed, the handling of the refrigerant pipe can be simplified.

【0045】また、従来では、除湿暖房運転時は、上流
で除湿のために冷却された空気を、下流で再加熱してい
たために、足元に吹き出される空気の温度を高く維持す
ることが困難であったが、本実施例では内気を再加熱し
て足元に吹き出すため、足元に吹き出される空気の温度
を高く維持することができる。このため、従来技術に比
較して、除湿暖房運転時の吹出温度の制御が容易にでき
る。
Further, conventionally, during the dehumidifying and heating operation, the air cooled for dehumidification at the upstream side is reheated at the downstream side, so it is difficult to maintain the temperature of the air blown at the feet high. However, in this embodiment, since the inside air is reheated and blown to the feet, the temperature of the air blown to the feet can be kept high. Therefore, the blowout temperature during the dehumidifying and heating operation can be controlled more easily than in the related art.

【0046】サイドフェイス吹出口11は、暖房除湿運
転時には、除湿された外気が吹き出されるため、サイド
ガラスの曇りが抑えられ、ドアミラーの視認性に優れ
る。また、サイドフェイス吹出口11同様、センタフェ
イス吹出口10も第1層23に通じているため、センタ
フェイス吹出口10およびサイドフェイス吹出口11か
ら、乗員の上半身に新鮮な外気を吹き出すことが可能
で、乗員にフレッシュ感を与え、乗員の快適性を向上さ
せることができる。
Since the dehumidified outside air is blown out from the side face outlet 11 during the heating and dehumidifying operation, the side glass is prevented from fogging and the visibility of the door mirror is excellent. Further, like the side face outlet 11, the center face outlet 10 communicates with the first layer 23, so that fresh outside air can be blown out from the center face outlet 10 and the side face outlet 11 to the upper body of the occupant. Thus, it is possible to give the occupant a fresh feeling and improve the comfort of the occupant.

【0047】冷房運転時、室内の比較的温度の低い内気
を吸引して冷却するため、冷房負荷を小さく抑えること
ができる。また、暖房運転時も、室内の比較的温度の高
い内気を吸引して加熱するため、暖房負荷を小さく抑え
ることができる。さらに、除湿暖房運転時は、足元に吹
き出される温風は、温かい内気を吸引して加熱するた
め、除湿暖房にかかる暖房負荷を低く抑えることができ
る。この結果、本実施例の車両用空気調和装置1は、余
剰熱をほとんど発生しない電気自動車に適している。
During the cooling operation, since the inside air having a relatively low temperature in the room is sucked and cooled, the cooling load can be kept small. Further, even during the heating operation, since the inside air having a relatively high temperature in the room is sucked and heated, the heating load can be suppressed. Furthermore, during the dehumidifying and heating operation, the warm air blown to the feet sucks and heats warm inner air, so that the heating load on the dehumidifying and heating can be suppressed low. As a result, the vehicle air conditioner 1 of this embodiment is suitable for an electric vehicle that generates almost no excess heat.

【0048】〔変形例〕本実施例では空気調和装置を電
気自動車に搭載した例を示したが、内燃機関、特にディ
ーゼルエンジンやリーンバーンエンジンによって駆動さ
れる自動車に搭載しても良い。空調ダクトの送風機は、
内気のみを吸引するように設けたが、例えば第1層のみ
に、あるいは第2層にも外気が導入できるように、内外
気切替手段を設けても良い。
[Modification] In this embodiment, the air conditioner is mounted on an electric vehicle. However, the air conditioner may be mounted on an automobile driven by an internal combustion engine, particularly a diesel engine or a lean burn engine. The air conditioner duct blower
The inside / outside air switching means may be provided so that the outside air can be introduced only into the first layer or into the second layer, for example.

【0049】空調ダクトを第1層と第2層に分けた例を
示したが、2つの層に分けない空調ダクトに外気導入ダ
クトを接続しても良い。外気導入ダクトを空調ダクトの
途中に接続した例を示したが、送風機の空気導入口に、
外気導入ダクトを通過した空気が導入されるように設け
ても良い。外気導入ダクトを空調ダクトに接続した例を
示したが、空調ダクトとは独立して車室内(好ましくは
窓ガラス)に吹き出すように設けても良い。
Although the example in which the air conditioning duct is divided into the first layer and the second layer is shown, the outside air introducing duct may be connected to the air conditioning duct which is not divided into two layers. An example was shown in which the outside air introduction duct was connected in the middle of the air conditioning duct, but at the air introduction port of the blower,
It may be provided so that the air that has passed through the outside air introduction duct is introduced. Although the example in which the outside air introducing duct is connected to the air conditioning duct is shown, it may be provided so as to blow out into the vehicle interior (preferably window glass) independently of the air conditioning duct.

【0050】室外熱交換器がエバポレータとして作動す
る際に、コンデンサとして作動する熱交換器の例として
空調ダクト内にその熱交換器を配置した例を示したが、
例えば断熱庫内を高い温度に保つ温蔵庫の熱源に冷凍サ
イクルのコンデンサを用いる車両に適用しても良い。つ
まり、車室内にコンデンサとして作動する熱交換器がな
くても、エバポレータとして作動する室外熱交換器を搭
載する車両では、エバポレータとして作動する室外熱交
換器を通過する外気を車室内に導くように設けても良
い。
As an example of the heat exchanger that operates as a condenser when the outdoor heat exchanger operates as an evaporator, an example in which the heat exchanger is arranged in an air conditioning duct has been shown.
For example, it may be applied to a vehicle that uses a condenser of a refrigerating cycle as a heat source of a warm storage that keeps the inside of the heat insulation at a high temperature. That is, even if there is no heat exchanger that operates as a condenser in the vehicle compartment, in a vehicle that is equipped with an outdoor heat exchanger that operates as an evaporator, the outside air that passes through the outdoor heat exchanger that operates as an evaporator should be introduced into the vehicle interior. It may be provided.

【図面の簡単な説明】[Brief description of drawings]

【図1】空気調和装置のダクトの概略構成図である。FIG. 1 is a schematic configuration diagram of a duct of an air conditioner.

【図2】冷凍サイクルの冷媒回路図である。FIG. 2 is a refrigerant circuit diagram of a refrigeration cycle.

【図3】操作パネルの正面図である。FIG. 3 is a front view of an operation panel.

【符号の説明】[Explanation of symbols]

1 車両用空気調和装置 2 冷凍サイクル 3 室外熱交換器 5 外気導入ダクト 7 空調ダクト 10 センタフェイス吹出口 11 サイドフェイス吹出口 12 デフロスタ吹出口 13 フット吹出口 20 室内熱交換器 23 第1層 24 第2層 28 第1層開閉ドア 1 Vehicle Air Conditioner 2 Refrigeration Cycle 3 Outdoor Heat Exchanger 5 Outdoor Air Inducting Duct 7 Air Conditioning Duct 10 Center Face Outlet 11 Side Face Outlet 12 Defroster Outlet 13 Foot Outlet 20 Indoor Heat Exchanger 23 First Layer 24th 2nd layer 28 1st layer open / close door

Claims (4)

【特許請求の範囲】[Claims] 【請求項1】車室外の空気と熱交換する室外熱交換器が
エバポレータとして作動可能な冷凍サイクルと、 前記室外熱交換器がエバポレータとして作動する際に、
前記室外熱交換器を通過した空気を車室内に導くことが
可能な外気導入ダクトとを備えた車両用空気調和装置。
1. A refrigeration cycle in which an outdoor heat exchanger for exchanging heat with the air outside a vehicle is operable as an evaporator, and when the outdoor heat exchanger is operated as an evaporator,
An air conditioner for a vehicle, comprising: an outside air introduction duct capable of guiding the air that has passed through the outdoor heat exchanger into the vehicle interior.
【請求項2】請求項1の車両用空気調和装置は、 車室内に向けて空気を吹き出される空調ダクトと、 このダクト内に配置され、車室内に吹き出される空気を
加熱するコンデンサとして作動可能な前記冷凍サイクル
の室内熱交換器とを備え、 前記外気導入ダクトは、前記空調ダクトに接続され、エ
バポレータとして作動する前記室外熱交換器を通過した
空気が、前記外気導入ダクトおよび前記空調ダクトを介
して車室内に吹き出し可能に設けられたことを特徴とす
る車両用空気調和装置。
2. An air conditioner for a vehicle according to claim 1, wherein the air conditioning duct blows air toward the passenger compartment, and the air conditioner operates as a condenser arranged in the duct to heat the air blown into the passenger compartment. An indoor heat exchanger of the possible refrigeration cycle, the outside air introduction duct is connected to the air conditioning duct, the air that has passed through the outdoor heat exchanger that operates as an evaporator, the outside air introduction duct and the air conditioning duct An air conditioner for a vehicle, wherein the air conditioner for a vehicle is provided so as to be blown into the vehicle interior via the.
【請求項3】請求項2の前記空調ダクトは、 乗員の上半身へ向けて空気を吹き出させるフェイス吹出
口、フロントガラスへ向けて空気を吹き出させるデフロ
スタ吹出口、および乗員の足元へ向けて空気を吹き出さ
せるフット吹出口を備えるとともに、 前記室内熱交換器を通過して前記フェイス吹出口および
前記デフロスタ吹出口に導かれる第1層と、前記室内熱
交換器を通過して前記フット吹出口に導かれる第2層と
に分かれて設けられ、 前記外気導入ダクトは、前記室内熱交換器よりも上流の
前記第1層に接続され、エバポレータとして作動する前
記室外熱交換器を通過した空気が、前記フェイス吹出口
あるいは前記デフロスタ吹出口から吹き出し可能に設け
られたことを特徴とする車両用空気調和装置。
3. The air conditioning duct according to claim 2, wherein a face outlet for blowing air toward the upper body of the occupant, a defroster outlet for blowing air toward the windshield, and air toward the feet of the occupant. A first layer that is provided with a foot outlet that blows out, passes through the indoor heat exchanger and is guided to the face outlet and the defroster outlet, and passes through the indoor heat exchanger and is guided to the foot outlet. The air is introduced separately from the second layer, and the outside air introduction duct is connected to the first layer upstream of the indoor heat exchanger, and the air that has passed through the outdoor heat exchanger that operates as an evaporator is An air conditioner for a vehicle, which is provided so as to be blown from a face outlet or the defroster outlet.
【請求項4】請求項3の前記第1層は、前記外気導入ダ
クトとの接続箇所よりも上流に、前記第1層を開閉する
第1層開閉ドアを備え、 前記室内熱交換器がコンデンサとして作動する暖房運転
時あるいは除湿暖房運転時に、前記第1層開閉ドアを閉
じて、エバポレータとして作動する前記室外熱交換器を
通過した空気を前記フェイス吹出口あるいは前記デフロ
スタ吹出口から吹き出し、前記第2層を通過し、前記室
内熱交換器を通過して加熱された空気が前記フット吹出
口から吹き出されることを特徴とする車両用空気調和装
置。
4. The first layer according to claim 3, further comprising a first layer opening / closing door for opening / closing the first layer upstream of a connection point with the outside air introducing duct, wherein the indoor heat exchanger is a condenser. During the heating operation or the dehumidifying heating operation, the air that has passed through the outdoor heat exchanger that operates as an evaporator is blown from the face outlet or the defroster outlet, and the first layer opening / closing door is closed. The air conditioner for a vehicle, wherein the air that has passed through two layers and has passed through the indoor heat exchanger and is heated is blown out from the foot outlet.
JP533094A 1994-01-21 1994-01-21 Air conditioner for vehicle Pending JPH07205633A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP533094A JPH07205633A (en) 1994-01-21 1994-01-21 Air conditioner for vehicle

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP533094A JPH07205633A (en) 1994-01-21 1994-01-21 Air conditioner for vehicle

Publications (1)

Publication Number Publication Date
JPH07205633A true JPH07205633A (en) 1995-08-08

Family

ID=11608240

Family Applications (1)

Application Number Title Priority Date Filing Date
JP533094A Pending JPH07205633A (en) 1994-01-21 1994-01-21 Air conditioner for vehicle

Country Status (1)

Country Link
JP (1) JPH07205633A (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2011037082A1 (en) * 2009-09-24 2011-03-31 カルソニックカンセイ株式会社 Air conditioning device for vehicle

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2011037082A1 (en) * 2009-09-24 2011-03-31 カルソニックカンセイ株式会社 Air conditioning device for vehicle

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