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JPH06211036A - Cooling device for automobile - Google Patents

Cooling device for automobile

Info

Publication number
JPH06211036A
JPH06211036A JP623393A JP623393A JPH06211036A JP H06211036 A JPH06211036 A JP H06211036A JP 623393 A JP623393 A JP 623393A JP 623393 A JP623393 A JP 623393A JP H06211036 A JPH06211036 A JP H06211036A
Authority
JP
Japan
Prior art keywords
refrigerant
regenerator
cold storage
cold
cooling
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
JP623393A
Other languages
Japanese (ja)
Inventor
Kazuo Saito
和男 齋藤
Shizuo Ishizawa
静雄 石澤
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.)
Nissan Motor Co Ltd
Original Assignee
Nissan Motor 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 Nissan Motor Co Ltd filed Critical Nissan Motor Co Ltd
Priority to JP623393A priority Critical patent/JPH06211036A/en
Publication of JPH06211036A publication Critical patent/JPH06211036A/en
Pending legal-status Critical Current

Links

Landscapes

  • Compression-Type Refrigeration Machines With Reversible Cycles (AREA)
  • Air-Conditioning For Vehicles (AREA)

Abstract

PURPOSE:To provide an automobile cooling device of such constitution as to perform cooling by the cold accumulated in a cold accumulator. CONSTITUTION:An automobile cooling device provided with a compressor 1, a condenser 2, an expansion valve 4 and an evaporator 5 is further provided with a cold accumulator 9; three-way valves 7, 8 for leading refrigerant, fed through the expansion valve 4 at the cold accumulating time of the cold accumulator 9, to the cold accumulator 9; change-over valves 10, 11 for leading refrigerant, fed through a condenser 2 at the cold release time of the cold accumulator 9, to the cold accumulator 9; and a means for controlling the flow of refrigerant through the respective valves 7, 8, 10, 11 according to the operating state.

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、自動車用冷房装置に関
するものである。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle cooling device.

【0002】[0002]

【従来の技術】自動車を炎天下にエンジンを止めたまま
停車するような場合、車室内はかなりの高温となるの
で、エンジンの始動後に車室内を急速に冷房したいとい
う要求がある。
2. Description of the Related Art When an automobile is stopped in the hot sun with the engine stopped, the interior temperature of the interior becomes considerably high. Therefore, there is a demand for rapid cooling of the interior of the interior after starting the engine.

【0003】この対策として、従来の自動車用冷房装置
では、例えば特開平2−220923号公報に見られる
ように、冷熱を蓄える蓄冷器を蓄冷用エバポレータを介
して冷房装置の冷媒と熱交換可能に接続し、蓄冷器から
送られる蓄冷媒体を放冷用エバポレータに循環させて車
室内に送られる空気を冷却するものが提案されている。
As a countermeasure against this, in a conventional automotive air conditioner, for example, as shown in Japanese Patent Laid-Open No. 2-220923, a regenerator that stores cold heat can exchange heat with a refrigerant of the air conditioner via a regenerator evaporator. It has been proposed to connect and circulate a storage refrigerant body sent from a regenerator to a cooling evaporator to cool air sent to the vehicle interior.

【0004】[0004]

【発明が解決しようとする課題】しかしながら、このよ
うな蓄冷器を備える従来の自動車用冷房装置にあって
は、蓄冷器の他にエバポレータ、コンプレッサ、ファン
等を増設しなければならず、自動車に搭載するにはスペ
ースや重量が大きくなり過ぎるという問題点があった。
However, in the conventional vehicle air conditioner provided with such a regenerator, an evaporator, a compressor, a fan, etc. must be additionally installed in addition to the regenerator, and the car regenerator needs to be added. There was a problem that the space and weight became too large to be mounted.

【0005】本発明は上記の問題点に着目し、蓄冷器に
蓄えられた冷熱により冷房を行う自動車用冷房装置を提
供することを目的としている。
The present invention has been made in view of the above problems, and an object of the present invention is to provide an air conditioner for an automobile which cools air by the cold heat stored in the regenerator.

【0006】[0006]

【課題を解決するための手段】請求項1記載の発明は、
冷媒を圧縮するコンプレッサと、冷媒の熱を外部に放出
するコンデンサと、冷媒を膨張させる膨張弁と、冷媒の
冷熱を車室内に送られる空気に放出するエバポレータと
を備える自動車用冷房装置において、冷熱を蓄える蓄冷
器と、蓄冷器の蓄冷時に前記膨張弁を経て送られる冷媒
を蓄冷器に導き、かつ蓄冷器の放冷時に前記コンデンサ
を経て送られる冷媒を蓄冷器に導く弁手段と、運転状態
に応じて各弁手段を介して冷媒の流れを制御する手段と
を備える。
The invention according to claim 1 is
A compressor for compressing a refrigerant, a condenser for discharging heat of the refrigerant to the outside, an expansion valve for expanding the refrigerant, and an evaporator for discharging cold heat of the refrigerant to air sent to the vehicle interior, a cooling device for an automobile, And a valve means for guiding the refrigerant sent through the expansion valve to the regenerator when the regenerator stores the cold, and for guiding the refrigerant sent through the condenser when the regenerator cools to the regenerator, and the operating state. And means for controlling the flow of the refrigerant via the respective valve means.

【0007】請求項2記載の発明は、冷媒を圧縮するコ
ンプレッサと、冷媒の熱を外部に放出するコンデンサ
と、冷媒を膨張させる膨張弁と、冷媒の冷熱を車室内に
送られる空気に放出するエバポレータとを備える自動車
用冷房装置において、蓄冷器に冷熱を蓄える複数の蓄冷
カプセルを備え、蓄冷器の蓄冷時に前記膨張弁を経て送
られる冷媒を各蓄冷カプセルに独立して導き、かつ蓄冷
器の放冷時に前記コンデンサを経て送られる冷媒を各蓄
冷カプセルに独立して導く弁手段を備え、運転状態に応
じて各弁手段を介して冷媒の流れを制御する手段を備え
る。
According to a second aspect of the present invention, a compressor for compressing the refrigerant, a condenser for discharging the heat of the refrigerant to the outside, an expansion valve for expanding the refrigerant, and the cold heat of the refrigerant are discharged to the air sent into the vehicle interior. In an automobile air conditioner provided with an evaporator, a plurality of regenerator capsules for storing cold heat in a regenerator is provided, and a refrigerant sent through the expansion valve during regenerator storage is independently guided to each regenerator capsule, and of the regenerator A valve means for independently guiding the refrigerant sent through the condenser to the cold storage capsules during cooling is provided, and means for controlling the flow of the refrigerant via the valve means according to the operating state.

【0008】[0008]

【作用】請求項1記載の発明においては、従来から設け
られている冷房装置に加えて、冷熱を蓄える蓄冷器と、
冷媒の流れを変える弁手段等を備える比較的簡素な構造
により、蓄冷器に蓄えられた冷熱により冷房を行う自動
車用冷房装置を提供することができる。
According to the invention of claim 1, in addition to the conventional cooling device, a regenerator for storing cold heat,
With a relatively simple structure including a valve means for changing the flow of the refrigerant, it is possible to provide a vehicle air-conditioning device that cools by the cold heat stored in the regenerator.

【0009】通常の冷房時は、コンプレッサから送られ
る冷媒を弁手段を介して蓄冷器を迂回して循環させる。
During normal cooling, the refrigerant sent from the compressor is circulated around the regenerator via the valve means.

【0010】蓄冷時は、膨張弁を経て導かれる冷媒を弁
手段を介して蓄冷器を循環させ、冷媒の冷熱を蓄冷器に
蓄える。
During cold storage, the refrigerant guided through the expansion valve is circulated through the cold storage via the valve means, and the cold heat of the refrigerant is stored in the cold storage.

【0011】放冷時は、コンデンサを経て導かれる冷媒
を弁手段を介して蓄冷器を循環させ、蓄冷器に蓄えられ
た冷熱を冷媒に放出し、冷房効果が高められる。
During cooling, the refrigerant guided through the condenser is circulated through the regenerator via the valve means, and the cold heat stored in the regenerator is released to the refrigerant, so that the cooling effect is enhanced.

【0012】請求項2記載の発明においては、蓄冷器に
冷熱を蓄える複数の蓄冷カプセルを備え、各蓄冷カプセ
ルを独立して蓄冷あるいは放冷を行わせる構成としたた
め、蓄冷カプセルを独立して短時間で蓄冷し、放冷時に
全蓄冷カプセルが蓄冷されていなくても、蓄冷を完了し
た蓄冷カプセルから放冷して冷房効果を高めるので、蓄
冷器の使用頻度を増やすことができる。
According to the second aspect of the present invention, the regenerator is provided with a plurality of regenerator capsules for storing cold heat, and each regenerator capsule is independently cooled or released, so that the regenerator capsules are independently short-circuited. Even if not all of the cold storage capsules are cold stored at the time of cold storage, the cold storage capsules that have completed cold storage are cooled to enhance the cooling effect, so that the frequency of use of the cold storage device can be increased.

【0013】[0013]

【実施例】以下、本発明の実施例を添付図面に基づいて
説明する。
Embodiments of the present invention will be described below with reference to the accompanying drawings.

【0014】図1において、1は外部から容量を変えら
れる可変容量タイプのコンプレッサ、2はコンデンサ、
3はリキッドタンク、4は膨張弁、5はエバポレータで
ある。コンプレッサ1で圧縮された高圧高温の冷媒のガ
スはコンデンサ2に送られ、コンデンサ2で外気に放熱
して液化した後、膨張弁4を通過して膨張することによ
り低温低圧の液体となってエバポレータ5に入り、エバ
ポレータ5にてブロワ(送風機)15を介して送られる
空気に冷熱を放出しながら気化し、低圧ガスとなってコ
ンプレッサ1に再び吸入される。一方、エバポレータ5
を通過することにより冷却された空気は空調用ダクト1
5を通して車室内に送られ、車室内を冷房する。
In FIG. 1, 1 is a variable capacity type compressor whose capacity can be changed from the outside, 2 is a condenser,
3 is a liquid tank, 4 is an expansion valve, and 5 is an evaporator. The high-pressure and high-temperature refrigerant gas compressed by the compressor 1 is sent to the condenser 2, radiates heat to the outside in the condenser 2 and liquefies, and then passes through the expansion valve 4 to expand and become a low-temperature and low-pressure liquid, thus becoming an evaporator. 5, the evaporator 5 vaporizes the air sent through the blower (blower) 15 while releasing cold heat, and becomes low-pressure gas, which is sucked into the compressor 1 again. On the other hand, the evaporator 5
The air cooled by passing through the
It is sent to the vehicle interior through 5 to cool the vehicle interior.

【0015】11はエアミックスダンパ、9はヒータコ
アである。ブロワ15から送られる空気はエアミックス
ダンパ17を介してヒータコア14を通過することによ
り暖められる。
Reference numeral 11 is an air mix damper, and 9 is a heater core. The air sent from the blower 15 is warmed by passing through the heater core 14 via the air mix damper 17.

【0016】空調用ダクト15には内外気取入れ口切換
ダンパ16と3つの吹出口切換ダンパ17,18,19
が設けられ、車室内への吹出口が3カ所で切換えられる
ようになっている。
In the air-conditioning duct 15, an inside / outside air intake switching damper 16 and three outlet switching dampers 17, 18, 19 are provided.
Is provided so that the outlets to the passenger compartment can be switched at three locations.

【0017】図2に示すように、9は冷熱を蓄える蓄冷
器である。蓄冷器9は例えば断熱材で覆われたり、魔法
瓶のような断熱構造をした本体31の内部に複数の蓄冷
カプセル22が設けられる。
As shown in FIG. 2, 9 is a regenerator for storing cold heat. The regenerator 9 is covered with, for example, a heat insulating material, or a plurality of regenerator capsules 22 are provided inside a main body 31 having a heat insulating structure such as a thermos.

【0018】膨張弁4とエバポレータ5の間に冷媒流路
30と蓄冷器本体31は互いに並列に配設される。
The refrigerant passage 30 and the regenerator body 31 are arranged in parallel between the expansion valve 4 and the evaporator 5.

【0019】蓄冷器本体31の入口32と冷媒流路30
の分岐部にはバルブ7が介装され、蓄冷器本体31の出
口33と冷却配管30の分岐部にはバルブ8が介装され
る。
The inlet 32 of the regenerator body 31 and the refrigerant passage 30
A valve 7 is provided at a branch portion of the valve, and a valve 8 is provided at an outlet 33 of the regenerator body 31 and a branch portion of the cooling pipe 30.

【0020】各三方弁7,8は膨張弁4を経て送られて
くる冷媒を図1に破線の矢印で示すように蓄冷器本体3
1を通して循環させる蓄冷時のポジションと、同じく膨
張弁4を経て送られてくる冷媒を図1に実線の矢印で示
すように冷媒流路30を通して循環させる冷房時のポジ
ションとに切換えられる。各三方弁7,8が蓄冷時のポ
ジションにあるとき、蓄冷器本体31はその内部を冷媒
が循環することにより、冷媒の冷熱を蓄冷カプセル22
に放出する熱交換が行われる。
Each of the three-way valves 7 and 8 represents the refrigerant sent through the expansion valve 4 as shown by the broken line arrow in FIG.
1 is switched between a cold storage position and a cooling position in which the refrigerant sent through the expansion valve 4 is circulated through the refrigerant passage 30 as indicated by a solid arrow in FIG. When each of the three-way valves 7 and 8 is in the cold storage position, the cold storage main body 31 circulates the refrigerant therein to cool the cold heat of the cold storage capsule 22.
The heat is released to the heat exchanger.

【0021】各蓄冷カプセル22は平面的に並べられて
いるが、多段に重ねたり、円筒状に並べても良い。ま
た、各蓄冷カプセル22は円筒形をしているが、箱形等
に形成しても良い。
Although the cold storage capsules 22 are arranged in a plane, they may be stacked in multiple stages or arranged in a cylindrical shape. Further, although each cold storage capsule 22 has a cylindrical shape, it may be formed in a box shape or the like.

【0022】図3にも示すように、蓄冷器本体31の内
部には各蓄冷カプセル22の内側を貫通する格子状の冷
媒流路(伝熱管)13が設けられるとともに、断熱材2
1に覆われた1本の冷媒流路12が設けられる。
As shown in FIG. 3, a lattice-shaped refrigerant passage (heat transfer tube) 13 penetrating the inside of each regenerator capsule 22 is provided inside the regenerator body 31, and the heat insulating material 2 is also provided.
One refrigerant channel 12 covered with 1 is provided.

【0023】リキッドタンク3と膨張弁4の間に冷媒流
路13と冷媒流路12が互いに並列に配設される。
A refrigerant passage 13 and a refrigerant passage 12 are arranged in parallel between the liquid tank 3 and the expansion valve 4.

【0024】冷媒流路13と冷媒流路12の上流側分岐
部と下流側分岐部には切換弁10,11がそれぞれ介装
される。
Switching valves 10 and 11 are provided at the upstream branch portion and the downstream branch portion of the refrigerant flow path 13 and the refrigerant flow path 12, respectively.

【0025】各切換弁10,11はリキッドタンク3を
経て送られてくる冷媒を図3に破線の矢印で示すように
冷媒流路13を通して循環させる放冷時のポジション
と、同じくリキッドタンク3を経て送られてくる冷媒を
図3に実線の矢印で示すように冷媒流路12を通して循
環させる通常冷房時のポジションとに切換えられる。
Each of the switching valves 10 and 11 has a position at the time of cooling in which the refrigerant sent through the liquid tank 3 is circulated through the refrigerant flow path 13 as shown by a dashed arrow in FIG. It is possible to switch to the normal cooling position in which the refrigerant sent therethrough is circulated through the refrigerant passage 12 as shown by the solid line arrow in FIG.

【0026】各蓄冷カプセル22の内部に蓄冷材23が
充填され、蓄冷材23は蓄冷器本体31内あるいは冷媒
流路13内を循環する冷媒との間で熱交換しながら相変
化するようになっている。すなわち、蓄冷材23は蓄冷
器本体31内を循環する冷媒によってその潜熱が吸収さ
れながら液体から固体へと相変化することにより蓄熱が
行われる一方、冷媒流路13内を循環する冷媒からその
潜熱を吸収しながら固体から液体へと相変化して放冷が
行われる。
The regenerator material 23 is filled in each regenerator capsule 22, and the regenerator material 23 undergoes phase change while exchanging heat with the refrigerant circulating in the regenerator body 31 or the refrigerant passage 13. ing. That is, the regenerator material 23 stores heat by changing its phase from liquid to solid while absorbing its latent heat by the refrigerant circulating in the regenerator body 31, while the latent heat from the refrigerant circulating in the refrigerant passage 13 is stored. The solid is changed to a liquid while absorbing the heat and cooled.

【0027】なお、蓄冷器9は蓄冷材23を廃止して、
低温の冷媒そのものを蓄えるようにしても良い。
In the regenerator 9, the regenerator material 23 is eliminated,
The low temperature refrigerant itself may be stored.

【0028】図示しない制御回路には、冷房装置の作動
状態を知るために、冷媒流路13の入口と出口でそれぞ
れ蓄冷媒体の温度を検出するセンサ、エバポレータ5の
出口で冷媒の温度を検出するセンサ、エバポレータを通
過した空気の温度を検出するセンサ、車室内の温度を検
出するセンサ、エアコンスイッチおよび室温設定スイッ
チからの各信号が入力されるとともに、自動車の運転状
態を知るために、エンジンの冷却水温センサ、車速セン
サ、アクセルペダルの開度センサ、ブレーキペダルの踏
み込みを検出するブレーキペダルスイッチからの各信号
が入力される。
A control circuit (not shown) detects the temperature of the refrigerant storage element at the inlet and outlet of the refrigerant passage 13 and the refrigerant temperature at the outlet of the evaporator 5 in order to know the operating state of the cooling device. Sensors, sensors that detect the temperature of air that has passed through the evaporator, sensors that detect the temperature inside the vehicle, air conditioner switches, and room temperature setting switches are input, and in order to know the operating state of the vehicle, Each signal is input from a cooling water temperature sensor, a vehicle speed sensor, an accelerator pedal opening sensor, and a brake pedal switch that detects depression of the brake pedal.

【0029】制御回路はこれらの各信号を入力し、コン
プレッサ1、ブロワ15、エアミックスダンパ17、吹
出口切換ダンパ17,18,19、各三方弁7,8、各
切換弁10,11を以下に説明する各モードに切換えて
総合的に制御するようになっている。
The control circuit inputs each of these signals and controls the compressor 1, the blower 15, the air mix damper 17, the outlet switching dampers 17, 18, 19, the three-way valves 7, 8 and the switching valves 10, 11 as follows. It is designed to be controlled comprehensively by switching to each of the modes described in 1.

【0030】[通常冷房モード]検出された冷房負荷が
設定値より小さいことを検知した場合、通常冷房モード
に設定される。通常冷房モードは、冷媒を冷媒流路12
を通して膨張弁4に導き、膨張弁4から冷媒流路30を
通してエバポレータ5に導くように、各三方弁7,8お
よび各切換弁10,11のポジションを切換え、蓄冷器
9の蓄冷温度の高低にかかわらず、冷房負荷に応じてコ
ンプレッサ1の容量が制御される。
[Normal Cooling Mode] When it is detected that the detected cooling load is smaller than the set value, the normal cooling mode is set. In the normal cooling mode, the refrigerant flows through the refrigerant passage 12
The three-way valves 7 and 8 and the switching valves 10 and 11 so as to guide the expansion valve 4 to the evaporator 5 through the refrigerant passage 30 from the expansion valve 4 to increase or decrease the cold storage temperature of the regenerator 9. Regardless, the capacity of the compressor 1 is controlled according to the cooling load.

【0031】[蓄冷モード1]通常冷房モードにおい
て、蓄冷器本体31の冷媒出入口温度の検出値に基づい
て十分な蓄冷量がなく、かつ検出された冷房負荷に対し
てコンプレッサ1の容量に余力がある場合、蓄冷モード
1に設定される。蓄冷モード1は、コンプレッサ1の容
量を最大とし、蓄冷器本体31の冷媒出入口温度と冷房
負荷に応じて蓄冷器本体31への流路を全開、あるいは
半開とし、膨張弁4を経て送られる低温の冷媒を蓄冷器
本体31のみに流すか、蓄冷器本体31と冷媒流路30
の両方に流すように制御する。
[Cold storage mode 1] In the normal cooling mode, there is not a sufficient amount of cold storage based on the detected value of the refrigerant inlet / outlet temperature of the regenerator body 31, and the capacity of the compressor 1 has a surplus capacity for the detected cooling load. If there is, the cold storage mode 1 is set. In the cold storage mode 1, the capacity of the compressor 1 is maximized, and the flow path to the cold storage body 31 is fully opened or half-opened according to the refrigerant inlet / outlet temperature of the cold storage body 31 and the cooling load, and the low temperature is sent via the expansion valve 4. Of the refrigerant of only the regenerator body 31 or the regenerator body 31 and the refrigerant passage 30
Control so that it flows to both.

【0032】そして、蓄冷器本体31の冷媒出入口温度
の検出値に基づいて十分に蓄冷が行われたと判定された
場合、三方弁7,8を冷媒流路30のみを開通させる通
常の冷房モードのポジションに切換える。
When it is determined that the cold storage is sufficiently performed based on the detected value of the refrigerant inlet / outlet temperature of the regenerator main body 31, the three-way valves 7 and 8 are opened in the normal cooling mode only. Switch to the position.

【0033】[蓄冷モード2]冷房装置の運転を停止し
て走行中、十分な蓄冷量がなく車速検出手段、ブレーキ
踏込検出手段からの信号に基づき車両が減速しているこ
とを検知した場合、蓄冷モード2に設定される。蓄冷モ
ード2は、乗員に直接風が当たらないように吹出口切換
ダンパ17,18,19を窓に向けて風を送るDEF位
置に切換え、ブロワ15とコンプレッサ1を駆動すると
ともに、三方弁7,8を蓄冷器本体31のみを開通させ
るポジションに切換える。
[Cold storage mode 2] When it is detected that the vehicle is decelerating based on signals from the vehicle speed detection means and the brake pedal depression detection means while the vehicle is running with the operation of the cooling device stopped, there is no sufficient amount of cold storage. The cold storage mode 2 is set. In the cold storage mode 2, the blower outlet switching dampers 17, 18, 19 are switched to the DEF position for sending the wind toward the window so that the wind is not directly applied to the occupant, the blower 15 and the compressor 1 are driven, and the three-way valve 7, 8 is switched to a position where only the regenerator body 31 is opened.

【0034】そして、検出された車速が設定値以下にな
るか、あるいは蓄冷器9に十分に蓄冷したことを検知す
ると、コンプレッサ1の駆動を停止する。
Then, when it is detected that the detected vehicle speed becomes equal to or lower than the set value or that the regenerator 9 has sufficiently stored cold, the driving of the compressor 1 is stopped.

【0035】[急速冷房モード]検出された冷房負荷が
設定値より大きく、かつ蓄冷量が十分にあることを検知
すると、急速冷房モードに設定される。このとき、蓄冷
器9内の切換弁10,11が冷媒流路13を開通させる
ポジションに切換えられ、コンデンサ2を経て送られる
冷媒は蓄冷カプセル22内の蓄冷材23と熱交換して膨
張弁4へと流れる。三方弁7,8は冷媒を冷媒流路30
を通ってエバポレータ5にのみ導くポジションに切換え
られる。これにより、急速に低温の冷媒がエバポレータ
5に供給されるため、冷房能力が増し、車室内に直ちに
冷風が吹出して、急速に冷房が行われる。
[Rapid cooling mode] When it is detected that the detected cooling load is larger than the set value and the amount of cold storage is sufficient, the rapid cooling mode is set. At this time, the switching valves 10 and 11 in the regenerator 9 are switched to the position where the refrigerant flow path 13 is opened, and the refrigerant sent through the condenser 2 exchanges heat with the regenerator material 23 in the regenerator capsule 22 to expand the expansion valve 4. Flows to. The three-way valves 7 and 8 allow the refrigerant to flow through the refrigerant passage 30.
It is switched to the position where it is guided only to the evaporator 5 through. As a result, the low-temperature refrigerant is rapidly supplied to the evaporator 5, so that the cooling capacity is increased, and the cool air is immediately blown into the vehicle compartment to perform the rapid cooling.

【0036】[放冷モード]検知されたエンジン回転数
と冷却水温度に基づいて暖機中におけるアイドル時と判
定された場合、蓄冷量が十分にあることを検知すると、
検出された冷房負荷が急速冷房を必要とする程大きくな
い場合、放冷モードに設定される。このとき、蓄冷器9
内の切換弁10,11が冷媒流路13を開通させるポジ
ションに切換えられ、コンデンサ2を経て送られる冷媒
は蓄冷カプセル22内の蓄冷材23と熱交換して膨張弁
4へと流れる。三方弁7,8は冷媒を冷媒流路30を通
ってエバポレータ5にのみ導くポジションに切換えられ
る。これにより、低温の冷媒がエバポレータ5に供給さ
れるため、冷房能力の向上分だけコンプレッサ1の容量
を小さくすることでコンプレッサ1の駆動負荷が低減さ
れ、アイドル時の燃費を向上させることができる。
[Cooling Mode] When it is determined that the engine is idling during warm-up based on the detected engine speed and cooling water temperature, when it is detected that the amount of cold storage is sufficient,
If the detected cooling load is not great enough to require rapid cooling, the cooling mode is set. At this time, the regenerator 9
The switching valves 10 and 11 therein are switched to a position where the refrigerant passage 13 is opened, and the refrigerant sent through the condenser 2 exchanges heat with the cold storage material 23 in the cold storage capsule 22 and flows to the expansion valve 4. The three-way valves 7 and 8 are switched to a position in which the refrigerant is guided to the evaporator 5 only through the refrigerant flow passage 30. As a result, the low-temperature refrigerant is supplied to the evaporator 5, so that the drive load of the compressor 1 is reduced by reducing the capacity of the compressor 1 by the amount corresponding to the improvement of the cooling capacity, and the fuel efficiency during idling can be improved.

【0037】図4の流れ図は制御回路において実行され
る上記制御内容を示しており、一定周期で実行される。
The flow chart of FIG. 4 shows the contents of the above control executed in the control circuit, which is executed in a fixed cycle.

【0038】これについて説明すると、エンジンが始動
されると三方弁7,8が冷媒流路30を開通させるポジ
ションに切換えられ(ステップ1,2)、エアコンスイ
ッチのON・OFFに基づいて冷房装置が運転されてい
るかどうかを判断する(ステップ3)。
Explaining this, when the engine is started, the three-way valves 7 and 8 are switched to the position for opening the refrigerant passage 30 (steps 1 and 2), and the cooling device is turned on or off based on the ON / OFF state of the air conditioner switch. It is determined whether or not the vehicle is being driven (step 3).

【0039】[急速冷房モード]のルーチンは、冷房負
荷として、例えば車室内温度の検出値と乗員による設定
温度との差が第一の設定値より大きいことを判定し(ス
テップ4)、蓄冷器9内の冷媒の温度が基準値より低く
十分な蓄冷量がある場合を判定し(ステップ5)、切換
弁10,11を冷媒流路13を開通させる放冷ポジショ
ンに切換えるとともに、三方弁7,8を冷媒流路30を
開通させる放冷ポジションに切換えて放冷を行う(ステ
ップ6)。これにより、コンプレッサ1から送られる冷
媒はコンデンサ2と蓄冷器9の二段階で冷却され、エバ
ポレータ5に導かれる冷媒の温度を低下させて車室内を
急速に冷房する。
The [quick cooling mode] routine determines, as the cooling load, that the difference between the detected value of the vehicle interior temperature and the temperature set by the occupant is larger than the first set value (step 4), and the regenerator is stored. When the temperature of the refrigerant in 9 is lower than the reference value and there is a sufficient amount of cold storage (step 5), the switching valves 10 and 11 are switched to the cooling position where the refrigerant flow path 13 is opened, and the three-way valve 7, 8 is switched to a cooling position where the refrigerant flow passage 30 is opened, and cooling is performed (step 6). As a result, the refrigerant sent from the compressor 1 is cooled in two stages of the condenser 2 and the regenerator 9, and the temperature of the refrigerant introduced to the evaporator 5 is lowered to rapidly cool the vehicle interior.

【0040】そして、冷房負荷が大きく、エアコンスイ
ッチがONとなっている状態が続く間はこの急速冷房モ
ードを維持する一方(ステップ7,20,21)、蓄冷
器9に蓄冷した冷熱を放出しきったことを検知すると
(ステップ7)、冷媒を冷媒流路12を通して膨張弁4
に導き、膨張弁4から冷媒流路30を通してエバポレー
タ5に導くように、各三方弁7,8および各切換弁1
0,11を通常の冷房ポジションに切換える(ステップ
8)。
While the cooling load is large and the air conditioner switch remains ON, this rapid cooling mode is maintained (steps 7, 20, 21), while the cold heat stored in the regenerator 9 is completely discharged. When it is detected (step 7), the refrigerant flows through the refrigerant flow path 12 and the expansion valve 4
The three-way valves 7 and 8 and the switching valves 1 so that the expansion valve 4 leads to the evaporator 5 through the refrigerant flow path 30.
0 and 11 are switched to the normal cooling position (step 8).

【0041】[放冷モード]のルーチンは、ステップ4
で冷房負荷が第一の設定値以下と判定された場合、暖機
中におけるアイドル時で、かつ蓄冷器9に十分な蓄冷量
があることを判定し(ステップ12,13)、各三方弁
7,8、切換弁10,11を放冷ポジションに切換えて
放冷を行う(ステップ14)。これにより、冷房能力が
増した分だけコンプレッサ1の容量を小さくしてその駆
動負荷を低減する。
The routine of [cooling mode] is step 4
If it is determined that the cooling load is less than or equal to the first set value, it is determined that the cool storage 9 has a sufficient amount of cold storage during warm-up (steps 12 and 13), and each three-way valve 7 , 8 and the switching valves 10 and 11 are switched to the cooling position to perform cooling (step 14). As a result, the capacity of the compressor 1 is reduced by the amount of the increased cooling capacity, and the drive load thereof is reduced.

【0042】そして、エアコンスイッチがOFFになる
と(ステップ15)、各三方弁7,8、切換弁10,1
1を通常の冷房ポジションに切換え(ステップ16)、
後述する[蓄冷モード2]のルーチンに進む。
When the air conditioner switch is turned off (step 15), the three-way valves 7, 8 and the switching valves 10, 1 are turned on.
Switch 1 to normal cooling position (step 16),
The procedure proceeds to the [Cold storage mode 2] routine described later.

【0043】また、暖気中のアイドル時以外の運転条件
になるか(ステップ12)、蓄冷器9に蓄冷した冷熱を
放出しきると(ステップ13)、各三方弁7,8、切換
弁10,11を冷媒流路12と冷媒流路30を開通する
ように通常の冷房ポジションを切換える(ステップ1
6)。
When the operating conditions other than the idling state during warming up are satisfied (step 12) or the cold heat stored in the regenerator 9 is completely discharged (step 13), the three-way valves 7, 8 and the switching valves 10, 11 are selected. The normal cooling position is switched so that the refrigerant passage 12 and the refrigerant passage 30 are opened (step 1
6).

【0044】その後エアコンスイッチがONのままであ
り(ステップ18)、蓄冷量が十分であると(ステップ
19)、各三方弁7,8、切換弁10,11を通常の冷
房ポジションに保持される(ステップ17)。
After that, if the air conditioner switch remains ON (step 18) and the amount of cold storage is sufficient (step 19), the three-way valves 7, 8 and the switching valves 10, 11 are held in the normal cooling position. (Step 17).

【0045】[蓄冷モード1]のルーチンは、コンプレ
ッサ1の容量が最大に設定され(ステップ22)、検出
された冷房負荷が第二の設定値(第二の設定値<第一の
設定値)と比較される(ステップ23)。冷房負荷が第
二の設定値より大きいと、三方弁7,8を半開状態と
し、冷媒流路30と蓄冷器9に冷媒が半分づつ流れるよ
うに切換えられる(ステップ25)。また、冷房負荷が
第二の設定値以下の場合、三方弁7,8は蓄冷器9側を
全開にするポジションに切換えられる。
In the [Cold storage mode 1] routine, the capacity of the compressor 1 is set to the maximum (step 22), and the detected cooling load is the second set value (second set value <first set value). (Step 23). When the cooling load is larger than the second set value, the three-way valves 7 and 8 are half-opened, and the refrigerant is switched so that the refrigerant flows through the refrigerant passage 30 and the regenerator 9 half by half (step 25). When the cooling load is equal to or less than the second set value, the three-way valves 7 and 8 are switched to the positions where the regenerator 9 side is fully opened.

【0046】そして、冷熱が十分に蓄えられたことを検
知すると(ステップ26)、三方弁7,8は冷媒流路3
0を全開とするポジションに切換えられるとともに、コ
ンプレッサ1を通常時の容量に復帰させる(ステップ2
7)。
When it is detected that the cold energy has been sufficiently stored (step 26), the three-way valves 7 and 8 cause the refrigerant passage 3 to flow.
The switch is switched to the position where 0 is fully opened, and the compressor 1 is returned to the normal capacity (step 2).
7).

【0047】ステップ3,10,11,18,20,2
8において、エアコンスイッチがOFFになると、図5
に示す[蓄冷モード2]のルーチンに進む。
Steps 3, 10, 11, 18, 20, 2
In FIG. 5, when the air conditioner switch is turned off, FIG.
[Cold storage mode 2] routine shown in FIG.

【0048】[蓄冷モード2]のルーチンは、ステップ
29,30でエンジン運転中で蓄冷器9の蓄冷量が不足
していることを検知した後、ステップ31で車速が基準
値Vh以上で、かつブレーキペダルが踏み込まれている
減速時を検知した場合、ステップ32に進んでコンプレ
ッサ1の電磁クラッチをONにし、人体に直接風が当た
らないように吹出口切換ダンパ17,18,19を窓に
向けて風を送るDEF位置に切換えるとともに、切換弁
10,11を冷媒流路12を開通させる蓄冷ポジション
に切換えるとともに、三方弁7,8を蓄冷器9を開通さ
せる蓄冷ポジションに切換えて蓄冷を行う。これによ
り、減速時の車両の運動エネルギを利用して蓄冷を行う
ことができる。
In the routine of [Cold storage mode 2], it is detected in Steps 29 and 30 that the cool storage amount of the cool storage unit 9 is insufficient while the engine is operating, and then in Step 31, the vehicle speed is equal to or higher than the reference value Vh, and When the deceleration when the brake pedal is depressed is detected, the program proceeds to step 32, the electromagnetic clutch of the compressor 1 is turned on, and the outlet switching dampers 17, 18, 19 are directed toward the window so that the human body is not directly exposed to the wind. In addition to switching to the DEF position for sending the wind, the switching valves 10 and 11 are switched to the cold storage position where the refrigerant passage 12 is opened, and the three-way valves 7 and 8 are switched to the cold storage position where the regenerator 9 is opened to perform cold storage. This makes it possible to store cold by utilizing the kinetic energy of the vehicle during deceleration.

【0049】そして、蓄冷量が十分になるか(ステップ
33)、車速が基準値Vl以下になる低速走行状態を検
知すると(ステップ34)、コンプレッサ1の電磁クラ
ッチをOFFにし、各三方弁7,8、切換弁10,11
を通常の冷房ポジションを切換えるとともに、吹出口切
換ダンパ17,18,19を元の位置に戻す(ステップ
35)。その後、エアコンスイッチがONになるとスタ
ートに戻り(ステップ36)、エンジンが停止されると
終了となる。
Then, when the cold storage amount is sufficient (step 33) or a low speed running state in which the vehicle speed is equal to or lower than the reference value Vl is detected (step 34), the electromagnetic clutch of the compressor 1 is turned off and the three-way valves 7, 8, switching valve 10, 11
Is switched to the normal cooling position, and the outlet switching dampers 17, 18 and 19 are returned to their original positions (step 35). After that, when the air conditioner switch is turned on, the process returns to the start (step 36) and ends when the engine is stopped.

【0050】次に、図6に示す他の実施例は、蓄冷器本
体31の内部を各蓄冷カプセル22が介装される6つの
冷媒室41が仕切られ、蓄冷時に各冷媒室41毎に膨張
弁7を経て送られる冷媒の流れを遮断するストップ弁4
2が配設されるとともに、放冷時に各蓄冷カプセル22
内の冷媒流路13に凝縮器2を経て送られる冷媒の流れ
を遮断するストップ弁24が各蓄冷カプセル22毎に配
設されるものである。なお、図1〜3との対応部分には
同一符号を付して示すことにする。
Next, in another embodiment shown in FIG. 6, the inside of the regenerator body 31 is divided into six refrigerant chambers 41 in which the cold storage capsules 22 are interposed, and each refrigerant chamber 41 expands during cold storage. Stop valve 4 for shutting off the flow of refrigerant sent through the valve 7.
2 are provided, and each cold storage capsule 22 is provided at the time of cooling.
A stop valve 24 that shuts off the flow of the refrigerant sent through the condenser 2 to the refrigerant passage 13 therein is provided for each cold storage capsule 22. It should be noted that parts corresponding to those in FIGS.

【0051】制御回路は、蓄冷時に蓄冷未完了の蓄冷カ
プセル22に冷媒を送るように各ストップ弁42を選択
的に開弁させて、各蓄冷カプセル22を1本づつ蓄冷す
る一方、放冷時に蓄冷が完了した蓄冷カプセル22のみ
に冷媒を送るように各ストップ弁24を選択的に開弁さ
せる。
The control circuit selectively opens each of the stop valves 42 so as to send the refrigerant to the cold storage capsules 22 that have not completed cold storage at the time of cold storage, and cools each of the cold storage capsules 22 one by one. Each stop valve 24 is selectively opened so that the refrigerant is sent only to the cold storage capsule 22 that has completed the cold storage.

【0052】図7の流れ図は制御回路において実行され
る上記制御内容を示しており、一定周期で実行される。
The flow chart of FIG. 7 shows the above-mentioned control contents executed in the control circuit, which is executed in a constant cycle.

【0053】これについて説明すると、[急速冷房モー
ド]のルーチンは、ステップ5で蓄冷が完了した蓄冷カ
プセル22があることを判定し、ステップ6で切換弁1
0,11を冷媒流路13を開通させる放冷ポジションに
切換えるとともに、蓄冷が完了した蓄冷カプセル22の
みに冷媒を送るように各ストップ弁24を選択的に開弁
させる。これにより、全て蓄冷カプセル22の蓄冷が完
了していないときでも、コンプレッサ1から送られる冷
媒はコンデンサ2と蓄冷器9の二段階で冷却され、エバ
ポレータ5に導かれる冷媒の温度を低下させて車室内を
急速に冷房する。
To explain this, in the routine of [quick cooling mode], it is judged in step 5 that there is a cold storage capsule 22 for which cold storage is completed, and in step 6, the switching valve 1
0 and 11 are switched to the cooling position where the refrigerant flow path 13 is opened, and each stop valve 24 is selectively opened so that the refrigerant is sent only to the cold storage capsule 22 that has completed the cold storage. As a result, even when the cold storage of all the cold storage capsules 22 is not completed, the refrigerant sent from the compressor 1 is cooled in two stages of the condenser 2 and the regenerator 9, and the temperature of the refrigerant introduced to the evaporator 5 is lowered to reduce the vehicle temperature. Cool the room rapidly.

【0054】そして、冷房負荷が大きく、エアコンスイ
ッチがONとなっている状態が続く間はこの急速冷房モ
ードを維持する一方(ステップ7,20,21)、全て
の蓄冷カプセル22の冷熱を放出しきったことを検知す
ると(ステップ7)、冷媒を冷媒流路12を通して膨張
弁4に導き、膨張弁4から冷媒流路30を通してエバポ
レータ5に導くように、各三方弁7,8および各切換弁
10,11を通常の冷房ポジションに切換える(ステッ
プ8)。
While the cooling load is large and the air conditioner switch remains ON, this rapid cooling mode is maintained (steps 7, 20, 21), while the cold heat of all the cold storage capsules 22 is completely discharged. When the fact is detected (step 7), the refrigerant is guided to the expansion valve 4 through the refrigerant flow path 12 and then to the evaporator 5 from the expansion valve 4 through the refrigerant flow path 30 to the three-way valves 7 and 8 and the switching valves 10 respectively. , 11 are switched to the normal cooling position (step 8).

【0055】[放冷モード]のルーチンは、ステップ4
で冷房負荷が第一の設定値以下と判定された場合、暖機
中におけるアイドル時で、かつ蓄冷器9に蓄冷が完了し
た蓄冷カプセル22があることを判定し(ステップ1
2,13)、切換弁10,11を冷媒流路13を開通さ
せる放冷ポジションに切換えるとともに、蓄冷が完了し
た蓄冷カプセル22のみに冷媒を送るように各ストップ
弁24を選択的に開弁させて放冷を行う(ステップ1
4)。これにより、冷房能力が増した分だけコンプレッ
サ1の容量を小さくしてその駆動負荷を低減する。
The routine of [cooling mode] is step 4
When it is determined that the cooling load is less than or equal to the first set value, it is determined that there is a cold storage capsule 22 that has completed cold storage in the cold storage 9 during idling during warm-up (step 1
2 and 13), the switching valves 10 and 11 are switched to a cooling position where the refrigerant flow path 13 is opened, and each stop valve 24 is selectively opened so that the refrigerant is sent only to the cold storage capsule 22 that has completed the cold storage. To cool down (Step 1
4). As a result, the capacity of the compressor 1 is reduced by the amount of the increased cooling capacity, and the drive load thereof is reduced.

【0056】そして、全ての蓄冷カプセル22の冷熱を
放出しきったことを検知すると(ステップ13)、各三
方弁7,8、切換弁10,11を冷媒流路12と冷媒流
路30を開通するように通常の冷房ポジションを切換え
る(ステップ17)。
When it is detected that the cold heat of all the cold storage capsules 22 has been discharged (step 13), the three-way valves 7, 8 and the switching valves 10, 11 are opened to the refrigerant passage 12 and the refrigerant passage 30. Then, the normal cooling position is switched (step 17).

【0057】[蓄冷モード1]のルーチンは、コンプレ
ッサ1の容量が最大に設定され(ステップ22)、検出
された冷房負荷が第二の設定値(第二の設定値<第一の
設定値)と比較される(ステップ23)。冷房負荷が第
二の設定値より大きいと、三方弁7,8を半開状態と
し、冷媒流路30と蓄冷器9に冷媒が半分づつ流れるよ
うに切換えられる(ステップ25)。また、冷房負荷が
第二の設定値以下の場合、三方弁7,8は蓄冷器9側を
全開にするポジションに切換えられる。
In the [Cold storage mode 1] routine, the capacity of the compressor 1 is set to the maximum (step 22), and the detected cooling load is the second set value (second set value <first set value). (Step 23). When the cooling load is larger than the second set value, the three-way valves 7 and 8 are half-opened, and the refrigerant is switched so that the refrigerant flows through the refrigerant passage 30 and the regenerator 9 half by half (step 25). When the cooling load is equal to or less than the second set value, the three-way valves 7 and 8 are switched to the positions where the regenerator 9 side is fully opened.

【0058】ステップ51,52で ステップ3,1
0,11,18,20,36において、エアコンスイッ
チがOFFになると、図8に示す[蓄冷モード2]のル
ーチンに進む。
In Steps 51 and 52, Steps 3 and 1
At 0, 11, 18, 20, 36, when the air conditioner switch is turned off, the routine proceeds to the [cool storage mode 2] routine shown in FIG.

【0059】[蓄冷モード2]のルーチンは、ステップ
29,30でエンジン運転中で蓄冷器9の蓄冷量が不足
していることを検知した後、ステップ31で車速が基準
値Vh以上で、かつブレーキペダルが踏み込まれている
減速時を検知した場合、ステップ32に進んでコンプレ
ッサ1の電磁クラッチをONにし、人体に直接風が当た
らないように吹出口切換ダンパ17,18,19を窓に
向けて風を送るDEF位置に切換えるとともに、切換弁
10,11を冷媒流路12を開通させる蓄冷ポジション
に切換え、三方弁7,8を蓄冷器9を開通させる蓄冷ポ
ジションに切換えるとともに、蓄冷未完了の蓄冷カプセ
ル22に冷媒を送るように各ストップ弁42を選択的に
開弁させ、各蓄冷カプセル22を1本づつ蓄冷する。こ
れにより、減速時の車両の運動エネルギを利用して蓄冷
が行われる。
In the routine of [Cold storage mode 2], it is detected in Steps 29 and 30 that the cool storage amount of the cool storage unit 9 is insufficient during engine operation, and then in Step 31, the vehicle speed is equal to or higher than the reference value Vh, and When the deceleration when the brake pedal is depressed is detected, the program proceeds to step 32, the electromagnetic clutch of the compressor 1 is turned on, and the outlet switching dampers 17, 18, 19 are directed toward the window so that the human body is not directly exposed to the wind. The DEF position for sending the wind, the switching valves 10 and 11 are switched to the cold storage position where the refrigerant flow path 12 is opened, the three-way valves 7 and 8 are switched to the cold storage position where the regenerator 9 is opened, and the cold storage is not completed. Each stop valve 42 is selectively opened to send the refrigerant to the cold storage capsules 22, and the cold storage capsules 22 are stored one by one. As a result, cold storage is performed using the kinetic energy of the vehicle during deceleration.

【0060】そして、全ての蓄冷カプセル22の蓄冷が
完了したことを検知するか(ステップ61)、車速が基
準値Vl以下になる低速走行状態を検知すると(ステッ
プ34)、コンプレッサ1の電磁クラッチをOFFに
し、各三方弁7,8、切換弁10,11を通常の冷房ポ
ジションを切換えるとともに、吹出口切換ダンパ17,
18,19を元の位置に戻す(ステップ35)。その
後、エアコンスイッチがONになるとスタートに戻り
(ステップ36)、エンジンが停止されると終了とな
る。
Then, when it is detected that the cold storage of all the cold storage capsules 22 is completed (step 61) or the low speed running state in which the vehicle speed becomes equal to or lower than the reference value Vl (step 34), the electromagnetic clutch of the compressor 1 is turned on. The three-way valves 7 and 8 and the switching valves 10 and 11 are switched to the normal cooling position, and the blower outlet switching damper 17 is turned off.
18 and 19 are returned to their original positions (step 35). After that, when the air conditioner switch is turned on, the process returns to the start (step 36) and ends when the engine is stopped.

【0061】[0061]

【発明の効果】以上説明したように請求項1記載の発明
によれば、冷媒を圧縮するコンプレッサと、冷媒の熱を
外部に放出するコンデンサと、冷媒を膨張させる膨張弁
と、冷媒の冷熱を車室内に送られる空気に放出するエバ
ポレータとを備える自動車用冷房装置において、冷熱を
蓄える蓄冷器と、蓄冷器の蓄冷時に前記膨張弁を経て送
られる冷媒を蓄冷器に導き、かつ蓄冷器の放冷時に前記
コンデンサを経て送られる冷媒を蓄冷器に導く弁手段
と、運転状態に応じて各弁手段を介して冷媒の流れを制
御する手段とを備えたため、例えば夏季の車室内灼熱時
等に冷媒をコンプレッサと蓄冷器の二段階で冷却して急
速に冷房することができ、また従来から用いられている
センサ類やアクチュエータ等に対して大幅な変更を必要
とせずに実現することができる。
As described above, according to the first aspect of the invention, the compressor for compressing the refrigerant, the condenser for releasing the heat of the refrigerant to the outside, the expansion valve for expanding the refrigerant, and the cold heat of the refrigerant are provided. In a vehicle air conditioner including an evaporator that discharges to the air sent to the passenger compartment, a regenerator that stores cold heat, and a refrigerant that is sent through the expansion valve when the regenerator stores cold are guided to the regenerator, and the regenerator is discharged. Since valve means for guiding the refrigerant sent through the condenser to the regenerator during cooling is provided, and means for controlling the flow of the refrigerant through each valve means according to the operating state, for example, during burning in the passenger compartment in summer, etc. The refrigerant can be cooled in two stages, the compressor and the regenerator, for rapid cooling, and can be realized without requiring major changes to the sensors and actuators that have been used conventionally. Can.

【0062】請求項2記載の発明によれば、蓄冷器に冷
熱を蓄える複数の蓄冷カプセルを備え、蓄冷器の蓄冷時
に前記膨張弁を経て送られる冷媒を各蓄冷カプセルに独
立して導き、かつ蓄冷器の放冷時に前記コンデンサを経
て送られる冷媒を各蓄冷カプセルに独立して導く弁手段
を備え、運転状態に応じて各弁手段を介して冷媒の流れ
を制御する手段を備えたため、蓄冷カプセルを独立して
短時間で蓄冷し、放冷時に全蓄冷カプセルが蓄冷されて
いなくても、蓄冷を完了した蓄冷カプセルから放冷して
冷房効果を高めるので、蓄冷器の使用頻度を増やすこと
ができる。
According to the second aspect of the invention, the regenerator is provided with a plurality of regenerator capsules for storing cold heat, and the refrigerant sent through the expansion valve is independently guided to each regenerator during regenerator regenerator storage. The cool storage is equipped with a valve means for independently guiding the refrigerant sent through the condenser to each cold storage capsule when the cool storage cools down, and means for controlling the flow of the refrigerant via each valve means according to the operating state. Increase the frequency of use of the regenerator because it independently cools the capsules in a short time, and even if not all of the cold accumulating capsules are stored when the cool is released, the cool storage capsules that have completed cool storage are allowed to cool and the cooling effect is enhanced. You can

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

【図1】本発明の実施例を示す機械的構成図。FIG. 1 is a mechanical configuration diagram showing an embodiment of the present invention.

【図2】同じく蓄冷器の概略断面図。FIG. 2 is a schematic sectional view of the regenerator.

【図3】同じく蓄冷器の一部斜視図。FIG. 3 is a partial perspective view of the regenerator.

【図4】同じく作用を説明するための流れ図。FIG. 4 is a flowchart for explaining the same operation.

【図5】同じく作用を説明するための流れ図。FIG. 5 is a flowchart for explaining the same operation.

【図6】他の実施例を示す蓄冷器の概略断面図。FIG. 6 is a schematic sectional view of a regenerator showing another embodiment.

【図7】同じく作用を説明するための流れ図。FIG. 7 is a flowchart for explaining the same operation.

【図8】同じく作用を説明するための流れ図。FIG. 8 is a flowchart for explaining the same operation.

【符号の説明】[Explanation of symbols]

1 コンプレッサ 2 コンデンサ 4 膨張弁 5 エバポレータ 7 三方弁 8 三方弁 9 蓄冷器 10 切換弁 11 切換弁 12 冷媒流路 13 冷媒流路 22 蓄冷カプセル 24 ストップ弁 41 冷媒室 42 ストップ弁 1 Compressor 2 Condenser 4 Expansion valve 5 Evaporator 7 Three-way valve 8 Three-way valve 9 Regenerator 10 Switching valve 11 Switching valve 12 Refrigerant flow path 13 Refrigerant flow path 22 Cold storage capsule 24 Stop valve 41 Refrigerant chamber 42 Stop valve

Claims (2)

【特許請求の範囲】[Claims] 【請求項1】 冷媒を圧縮するコンプレッサと、冷媒の
熱を外部に放出するコンデンサと、冷媒を膨張させる膨
張弁と、冷媒の冷熱を車室内に送られる空気に放出する
エバポレータとを備える自動車用冷房装置において、冷
熱を蓄える蓄冷器と、蓄冷器の蓄冷時に前記膨張弁を経
て送られる冷媒を蓄冷器に導き、かつ蓄冷器の放冷時に
前記コンデンサを経て送られる冷媒を蓄冷器に導く弁手
段と、運転状態に応じて各弁手段を介して冷媒の流れを
制御する手段とを備えたことを特徴とする自動車用冷房
装置。
1. A vehicle, comprising: a compressor for compressing a refrigerant; a condenser for discharging heat of the refrigerant to the outside; an expansion valve for expanding the refrigerant; and an evaporator for discharging cold heat of the refrigerant to air sent into a vehicle interior. In the cooling device, a regenerator that stores cold heat, and a valve that guides the refrigerant that is sent through the expansion valve to the regenerator when the regenerator stores heat, and that guides the refrigerant that is sent through the condenser when the regenerator cools to the regenerator. An air conditioner for an automobile, comprising: means and means for controlling a flow of a refrigerant through each valve means according to an operating state.
【請求項2】 冷媒を圧縮するコンプレッサと、冷媒の
熱を外部に放出するコンデンサと、冷媒を膨張させる膨
張弁と、冷媒の冷熱を車室内に送られる空気に放出する
エバポレータとを備える自動車用冷房装置において、蓄
冷器に冷熱を蓄える複数の蓄冷カプセルを備え、蓄冷器
の蓄冷時に前記膨張弁を経て送られる冷媒を各蓄冷カプ
セルに独立して導き、かつ蓄冷器の放冷時に前記コンデ
ンサを経て送られる冷媒を各蓄冷カプセルに独立して導
く弁手段を備え、運転状態に応じて各弁手段を介して冷
媒の流れを制御する手段を備えたことを特徴とする自動
車用冷房装置。
2. A vehicle for automobiles, comprising: a compressor for compressing a refrigerant; a condenser for discharging heat of the refrigerant to the outside; an expansion valve for expanding the refrigerant; and an evaporator for discharging cold heat of the refrigerant to air sent into the passenger compartment. In the cooling device, the regenerator is provided with a plurality of regenerator capsules for storing cold heat, and the refrigerant sent through the expansion valve is independently guided to each regenerator capsule during regenerator storage, and the condenser is released during regenerator cooling. An air conditioner for an automobile, comprising valve means for independently guiding a refrigerant to be sent to each cold storage capsule, and means for controlling a flow of the refrigerant via each valve means according to an operating state.
JP623393A 1993-01-18 1993-01-18 Cooling device for automobile Pending JPH06211036A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP623393A JPH06211036A (en) 1993-01-18 1993-01-18 Cooling device for automobile

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP623393A JPH06211036A (en) 1993-01-18 1993-01-18 Cooling device for automobile

Publications (1)

Publication Number Publication Date
JPH06211036A true JPH06211036A (en) 1994-08-02

Family

ID=11632805

Family Applications (1)

Application Number Title Priority Date Filing Date
JP623393A Pending JPH06211036A (en) 1993-01-18 1993-01-18 Cooling device for automobile

Country Status (1)

Country Link
JP (1) JPH06211036A (en)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2002337538A (en) * 2001-05-16 2002-11-27 Zexel Valeo Climate Control Corp Regenerative air conditioner for vehicle
US7266967B2 (en) 2004-02-02 2007-09-11 Denso Corporation Air conditioner for automotive vehicle
JP2008247198A (en) * 2007-03-30 2008-10-16 Equos Research Co Ltd On-vehicle air conditioning system
US7669647B2 (en) 2002-07-16 2010-03-02 Toyota Jidosha Kabushiki Kaisha Air conditioning apparatus

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2002337538A (en) * 2001-05-16 2002-11-27 Zexel Valeo Climate Control Corp Regenerative air conditioner for vehicle
US7669647B2 (en) 2002-07-16 2010-03-02 Toyota Jidosha Kabushiki Kaisha Air conditioning apparatus
US7266967B2 (en) 2004-02-02 2007-09-11 Denso Corporation Air conditioner for automotive vehicle
JP2008247198A (en) * 2007-03-30 2008-10-16 Equos Research Co Ltd On-vehicle air conditioning system

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