JP3098889B2 - refrigerator - Google Patents
refrigeratorInfo
- Publication number
- JP3098889B2 JP3098889B2 JP05118207A JP11820793A JP3098889B2 JP 3098889 B2 JP3098889 B2 JP 3098889B2 JP 05118207 A JP05118207 A JP 05118207A JP 11820793 A JP11820793 A JP 11820793A JP 3098889 B2 JP3098889 B2 JP 3098889B2
- Authority
- JP
- Japan
- Prior art keywords
- heat storage
- refrigerator
- heat
- regenerator
- condenser
- 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.)
- Expired - Fee Related
Links
Landscapes
- Devices That Are Associated With Refrigeration Equipment (AREA)
- Compression-Type Refrigeration Machines With Reversible Cycles (AREA)
Description
【0001】[0001]
【産業上の利用分野】本発明は、蓄熱材を用いて庫内を
保冷する蓄熱式の冷蔵庫に関するものである。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a regenerative refrigerator in which the interior of a refrigerator is kept cool by using a heat storage material.
【0002】[0002]
【従来の技術】近年、深夜電力の有効利用ないし電力需
要のピ−クカットによる平準化等の観点より蓄熱材を利
用して庫内の冷却を行う蓄熱式の冷蔵庫が特開昭63−
247577号公報に示されるごとく、考えられてい
る。2. Description of the Related Art In recent years, a regenerative refrigerator that cools the inside of a refrigerator using a regenerative material has been proposed from the viewpoint of effective use of late-night power or leveling by peak-cutting power demand.
As shown in Japanese Patent No. 247577, this is considered.
【0003】以下図面を参照しながら、上述した従来の
蓄熱式の冷蔵庫の一例について説明する。An example of the above-described conventional regenerative refrigerator will be described below with reference to the drawings.
【0004】図6は冷凍サイクルの構成を示しており、
コンプレッサ4と凝縮器5と第1のキャピラリ7と第2
のキャピラリ7aと冷却器4を順次接続し、通常の冷凍
冷蔵庫の基本冷凍サイクルを構成している。19は冷却
器8の冷却ファンである。FIG. 6 shows a configuration of a refrigeration cycle.
Compressor 4, condenser 5, first capillary 7 and second
The capillary 7a and the cooler 4 are sequentially connected to form a basic refrigeration cycle of a normal refrigerator-freezer. 19 is a cooling fan of the cooler 8.
【0005】そして第2のキャピラリ7aと冷却器8と
並列に、第1の開閉弁6aと第3のキャピラリ7Cと冷
蔵室用蓄熱器16の直列回路と、凝縮器用蓄熱器16a
と第2の開閉弁6Bの直列回路をそれぞれ接続してい
る。冷蔵用蓄熱器16は内部に潜熱タイプの蓄熱材21
を充填し、蓄熱材21を冷却凍結させる冷媒管22を熱
交換的に配置し、外部にはフィン15を設けている。2
0は冷蔵庫用蓄熱器用冷却ファンである。[0005] In parallel with the second capillary 7a and the cooler 8, a series circuit of the first on-off valve 6a, the third capillary 7C and the regenerator 16 for the refrigerator, and the regenerator 16a for the condenser are provided.
And the series circuit of the second on-off valve 6B. The regenerator 16 has a latent heat type heat storage material 21 inside.
, And a refrigerant tube 22 for cooling and freezing the heat storage material 21 is disposed in a heat exchange manner, and a fin 15 is provided outside. 2
Reference numeral 0 denotes a cooling fan for a regenerator for a refrigerator.
【0006】そして凝縮器5の出口と凝縮器用蓄熱器1
6aと第2の開閉弁6B間とを接続する第3の開閉弁6
を有する冷媒回路を設けて冷凍サイクルを構成してい
る。23は制御回路で、点線矢印で示すようにコンプレ
ッサ4と第1の開閉弁6aと第2の開閉弁6Bと第3の
開閉弁6と冷却ファン19と蓄冷用冷却ファン20を制
御するものである。The outlet of the condenser 5 and the condenser regenerator 1
Third on-off valve 6 that connects between 6a and second on-off valve 6B
Is provided to form a refrigeration cycle. Reference numeral 23 denotes a control circuit for controlling the compressor 4, the first on-off valve 6a, the second on-off valve 6B, the third on-off valve 6, the cooling fan 19, and the regenerative cooling fan 20 as indicated by dotted arrows. is there.
【0007】図7は冷凍冷蔵庫の構造を示す縦断面であ
り、図4と対応する部分に同一符号を付している。冷却
器8は冷凍室21に配置し、冷蔵室用蓄熱器16は冷蔵
室22に配置し、凝縮器用蓄熱器16aは冷凍室21の
断熱壁23内に配置している。FIG. 7 is a longitudinal sectional view showing the structure of the refrigerator-freezer, and portions corresponding to those in FIG. 4 are denoted by the same reference numerals. The cooler 8 is disposed in the freezer compartment 21, the regenerator 16 for the refrigerating compartment is disposed in the refrigerating compartment 22, and the regenerator 16 a for the condenser is disposed in the heat insulating wall 23 of the refrigerating compartment 21.
【0008】23はダンパーサーモで冷却器8で冷却さ
れた冷気の一部を冷蔵室22に吐出させ、冷蔵室22を
任意の温度に冷却制御するものである。Reference numeral 23 denotes a part for discharging a part of the cool air cooled by the cooler 8 to the refrigerating room 22 by a damper thermostat, and controlling the cooling of the refrigerating room 22 to an arbitrary temperature.
【0009】本構成において、通常冷却運転時には第1
の開閉弁6aと第2の開閉弁6Bと第3の開閉弁6はい
ずれも閉路し、コンプレッサ4〜凝縮器5〜第1のキャ
ピラリ7〜第2のキャピラリ7a〜冷却器8〜コンプレ
ッサ4の経路からなる冷凍サイクルを形成し冷却ファン
19とダンパサーモ23により冷凍室21と冷蔵室22
を所定の温度に冷却する。In this configuration, during the normal cooling operation, the first
, The second on-off valve 6B, the third on-off valve 6B and the third on-off valve 6 are all closed, and the compressor 4 to the condenser 5 to the first capillary 7 to the second capillary 7a to the cooler 8 to the compressor 4 A refrigeration cycle consisting of a path is formed, and a freezing room 21 and a refrigeration room 22 are
Is cooled to a predetermined temperature.
【0010】また深夜の蓄熱運転時には間欠的に第1の
開閉弁6aと第2の開閉弁6Bが開路され、冷蔵室用蓄
熱器16と凝縮器用蓄熱器16aの冷媒管12、22に
それぞれ冷媒が流れ、蓄熱材11、21を凍結し冷熱源
が蓄熱される。During the heat storage operation at midnight, the first open / close valve 6a and the second open / close valve 6B are opened intermittently, and the refrigerant pipes 12 and 22 of the regenerator 16 for the refrigerating compartment and the regenerator 16a for the condenser are respectively connected to the refrigerant. Flows, the heat storage materials 11 and 21 are frozen, and the cold heat source is stored.
【0011】そして昼間の所定の蓄熱利用運転時には、
第1の開閉弁6aと第2の開閉弁6Bが閉路、第3の開
閉弁6が開路され、コンプレッサ4〜凝縮器5〜凝縮用
蓄熱器16a〜第2のキャピラリ7a〜冷却器8〜コン
プレッサ4の経路からなる冷凍サイクルを形成する。At the time of a predetermined heat storage operation in the daytime,
The first opening / closing valve 6a and the second opening / closing valve 6B are closed, the third opening / closing valve 6 is opened, and the compressor 4 to the condenser 5 to the condenser regenerator 16a to the second capillary 7a to the cooler 8 to the compressor A refrigeration cycle consisting of four routes is formed.
【0012】そして凝縮器用蓄熱器16aの冷熱源を凝
縮器5の冷却熱源とする圧縮比の小さい冷凍サイクルに
て冷凍室21を冷却する。また冷蔵室22は蓄熱器用冷
却ファン20を運転し冷蔵室用蓄熱器16の冷熱源で冷
却するので通常冷却運転時に比べて使用電力を少なくす
ることができる。Then, the freezing chamber 21 is cooled by a refrigeration cycle having a small compression ratio using the cold heat source of the condenser regenerator 16a as the cooling heat source of the condenser 5. Further, since the refrigerating compartment 22 operates the regenerator cooling fan 20 to cool the refrigerating compartment with the cold source of the refrigerating compartment regenerator 16, the power consumption can be reduced as compared with the normal cooling operation.
【0013】[0013]
【発明が解決しようとする課題】しかしながら上記の様
な構成では、冷蔵庫キャビネット内に埋設した凝縮器5
にて冷凍サイクルを形成しているので冷蔵庫内に凝縮器
5から侵入する負荷熱量があり、蓄熱運転において夏期
等の高室温時には蓄熱に要する時間が不足して必要蓄熱
量を蓄熱運転時間帯に蓄熱できないという課題を有して
いた。However, in the above-described structure, the condenser 5 embedded in the refrigerator cabinet is not provided.
Since a refrigeration cycle is formed in the refrigerator, there is a load amount of heat entering from the condenser 5 into the refrigerator, and in a heat storage operation, the time required for the heat storage is insufficient at a high room temperature in summer or the like, and the necessary heat storage amount is reduced in the heat storage operation time zone. There was a problem that heat could not be stored.
【0014】本発明は上記課題を解決するもので、蓄熱
運転時は機械室に配置しているアウタ−コンデンサのみ
を使用して蓄熱を行うので冷蔵庫内に侵入する負荷熱量
が低減でき、夏期等の高室温時においても蓄熱運転にお
ける蓄熱に要する時間を十分に確保できる。さらに蓄熱
器を冷蔵室内に設置していることで蓄熱器からの放熱は
冷蔵室の冷却に利用できるので電力の有効利用ができる
冷蔵庫を提供するものである。The present invention solves the above-mentioned problem. During the heat storage operation, heat is stored using only the outer condenser arranged in the machine room, so that the amount of load heat entering the refrigerator can be reduced, and the heat storage operation can be performed in the summer. Even at a high room temperature, the time required for heat storage in the heat storage operation can be sufficiently ensured. Furthermore, since the heat storage device is installed in the refrigerator compartment, the heat radiation from the heat storage device can be used for cooling the refrigerator room, so that a refrigerator that can effectively use electric power is provided.
【0015】[0015]
【課題を解決するための手段】上記課題を解決するため
に本発明の冷蔵庫は並列または直列に接続した冷却器と
冷蔵室内に配置した内部に蓄熱材を有する蓄熱器と、並
列または直列に接続した冷蔵庫キャビネット内に埋設し
たインナ−コンデンサと機械室に配置したアウタ−コン
デンサと、前記蓄熱器内の冷気を送出する蓄熱器ファン
と、任意の時間帯に前記蓄熱器に熱を蓄熱する蓄熱運転
と蓄熱した熱により冷蔵庫内を冷却する蓄熱冷却運転の
時間制御を行う時間制御手段とを備え、前記蓄熱運転時
は前記アウタ−コンデンサのみを使用し、その他の運転
時はインナ−コンデンサとアウタ−コンデンサの両方を
使用するものである。In order to solve the above-mentioned problems, a refrigerator according to the present invention is connected in parallel or in series with a cooler connected in parallel or in series and a regenerator having a heat storage material disposed inside a refrigerator compartment. An inner condenser buried in a refrigerator cabinet and an outer condenser disposed in a machine room, a regenerator fan for sending cool air in the regenerator, and a heat storage operation for storing heat in the regenerator at an arbitrary time zone. And a time control means for performing time control of a heat storage cooling operation for cooling the inside of the refrigerator by the stored heat, wherein only the outer capacitor is used during the heat storage operation, and the inner capacitor and the outer capacitor are used during other operations. It uses both capacitors.
【0016】[0016]
【作用】本発明は上記した構成によって、冷蔵庫内に侵
入する負荷熱量が低減でき、夏期等の高室温時において
も蓄熱運転における蓄熱に要する時間を十分に確保でき
る。さらに蓄熱器を冷蔵室内に設置していることで蓄熱
器からの放熱は冷蔵室の冷却に利用できるので電力の有
効利用ができる。According to the present invention, the amount of load heat entering the refrigerator can be reduced by the above-described configuration, and the time required for heat storage in the heat storage operation can be sufficiently secured even at a high room temperature in summer or the like. Further, since the heat storage device is installed in the refrigerator compartment, the heat radiation from the heat storage device can be used for cooling the refrigerator compartment, so that the electric power can be effectively used.
【0017】[0017]
【実施例】以下本発明の一実施例の冷蔵庫について図面
を参照しながら説明する。DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A refrigerator according to one embodiment of the present invention will be described below with reference to the drawings.
【0018】図1は本発明の一実施例における冷蔵庫の
機能ブロック図であり、図2は本発明の一実施例におけ
る冷凍システム図であり、図3は本発明の一実施例にお
ける要部の電気回路図であり、図4は本発明の一実施例
におけるフロ−チャ−トであり、図5は本発明の一実施
例における室温に応じた一日の運転状態図である。FIG. 1 is a functional block diagram of a refrigerator in one embodiment of the present invention, FIG. 2 is a diagram of a refrigeration system in one embodiment of the present invention, and FIG. FIG. 4 is an electric circuit diagram, FIG. 4 is a flowchart in one embodiment of the present invention, and FIG. 5 is a one-day operation state diagram according to room temperature in one embodiment of the present invention.
【0019】図1及び図3において、30は保冷庫本体
で断熱材を内蔵したキャビネット2と、ドア3と、ドア
3とキャビネット2をシ−ルするガスケット14とで構
成されている。その内部は、水平に配置された断熱区画
壁33により上部の冷凍室17と下部の冷蔵室18との
2室に仕切られ、断熱区画壁33内には冷蔵室吸込口3
5を形成している。In FIG. 1 and FIG. 3, reference numeral 30 denotes a cool box main body including a cabinet 2 having a built-in heat insulating material, a door 3, and a gasket 14 for sealing the door 3 and the cabinet 2. The interior is partitioned into two compartments, an upper freezer compartment 17 and a lower refrigerating compartment 18, by a horizontally disposed heat insulating partition wall 33.
5 are formed.
【0020】62は冷凍室17内に設けた冷却室で、冷
却室62内には冷却器8と冷却ファン19と冷却器の除
霜を行うヒ−タ58を内装し、36は冷凍室吸込口であ
る。Numeral 62 denotes a cooling chamber provided in the freezing chamber 17, in which the cooler 8, the cooling fan 19 and a heater 58 for defrosting the cooler are provided. Mouth.
【0021】26はダンパ−で、冷却ファン19により
冷蔵室ダクト25に送風された冷気の冷蔵室18への吐
出送風量を調整し、冷蔵室18を設定温度に制御するも
のである。Reference numeral 26 denotes a damper for controlling the amount of cold air blown into the refrigerator compartment duct 25 by the cooling fan 19 to the refrigerator compartment 18 to control the refrigerator compartment 18 to a set temperature.
【0022】31は蓄熱器であり、内部に蓄熱材32を
充填している蓄熱容器34と蓄熱容器34内の蓄熱材3
2を冷却する蓄熱器冷却パイプ38と、蓄熱器31内の
冷気を送風する蓄熱ファン39と蓄熱材温度センサ57
を配置している。Reference numeral 31 denotes a heat storage unit, and a heat storage container 34 in which a heat storage material 32 is filled and a heat storage material 3 in the heat storage container 34.
2, a heat storage fan 39 for blowing cool air in the heat storage 31, and a heat storage material temperature sensor 57.
Has been arranged.
【0023】37は蓄熱器31に形成された蓄熱器吸込
口であり、56は蓄熱器31内に取付られた蓄熱材温度
センサ57により蓄熱材32温度を検知する蓄熱温度検
知手段であり、55は冷蔵室背面に設けた蓄熱器31と
冷却室62を連通した通風ダクトである。Numeral 37 denotes a heat storage unit suction port formed in the heat storage unit 31, reference numeral 56 denotes a heat storage temperature detecting means for detecting the temperature of the heat storage material 32 by a heat storage material temperature sensor 57 mounted in the heat storage unit 31, and 55. Is a ventilation duct which connects the heat storage unit 31 and the cooling chamber 62 provided on the back of the refrigerator compartment.
【0024】63は除霜開始判定手段であり、室温検知
手段40の信号に応じて冷却器8の除霜開始時間を判定
する。Reference numeral 63 denotes a defrosting start judging means for judging the defrosting start time of the cooler 8 in accordance with a signal from the room temperature detecting means 40.
【0025】電気回路図のうち本発明の要旨に関係した
部分のみ示されており、46は時間制御手段としてのC
PUで、周知の如く図示しない記憶回路に記憶されたプ
ログラムにより動作するもので、現在の時刻を出力する
時計回路45と室温検知手段40、冷凍庫内温度検知手
段44及び冷蔵庫内温度検知手段75からの出力信号に
よってリレ−47、49、51、53、59、66、8
1、83の通電制御を行う。即ち、各リレ−47、4
9、51、53、59、66、81、83に接続された
各トランジスタ48、50、52、54、60、67、
82、84のベ−スにハイレベルの信号を与えることに
より各リレ−47、49、51、53、59、66、8
1、83に通電される。Only the portions of the electric circuit diagram relevant to the gist of the present invention are shown, and reference numeral 46 denotes C as time control means.
The PU operates according to a program stored in a storage circuit (not shown) as is well known, and includes a clock circuit 45 that outputs the current time, a room temperature detection unit 40, a freezer temperature detection unit 44, and a refrigerator temperature detection unit 75. Relays 47, 49, 51, 53, 59, 66, 8
The energization control of 1, 83 is performed. That is, each relay 47, 4
9, 51, 53, 59, 66, 81, 83, transistors 48, 50, 52, 54, 60, 67,
By applying a high level signal to the bases 82 and 84, each of the relays 47, 49, 51, 53, 59, 66, 8
1, 83 are energized.
【0026】リレ−47が通電されるとコンプレッサ4
が運転する。リレ−49が通電されると電磁弁64が作
動してインナ−コンデンサ77もしくはアウタ−コンデ
ンサ78と冷却器8が連通し、リレ−51が通電される
と電磁弁65が作動してインナ−コンデンサ77もしく
はアウタ−コンデンサ78と蓄熱器31が連通する。リ
レ−53が通電されると冷却ファン19が運転する。リ
レ−59が通電されるとヒ−タ58により冷却器8を除
霜し、リレ−66が通電されると蓄熱器ファン39が運
転する。リレ−81が通電されると電磁弁79が作動し
てインナ−コンデンサ77とコンプレッサ4が連通し、
リレ−83が通電されると電磁弁80が作動してアウタ
−コンデンサ78とコンプレッサ4が連通する。When the relay 47 is energized, the compressor 4
Drives. When the relay 49 is energized, the solenoid valve 64 is operated to communicate the inner condenser 77 or the outer condenser 78 with the cooler 8. When the relay 51 is energized, the solenoid valve 65 is operated to activate the inner condenser. 77 or the outer condenser 78 communicates with the heat accumulator 31. When the relay 53 is energized, the cooling fan 19 operates. When the relay 59 is energized, the cooler 8 is defrosted by the heater 58, and when the relay 66 is energized, the regenerator fan 39 operates. When the relay 81 is energized, the solenoid valve 79 operates and the inner condenser 77 and the compressor 4 communicate with each other.
When the relay 83 is energized, the solenoid valve 80 operates and the outer condenser 78 communicates with the compressor 4.
【0027】また、冷凍庫内温度検知手段44は冷凍室
温度センサ43により検出した値が設定温度以上の時に
時間制御手段46に信号を出力する。また、冷蔵庫内温
度検知手段75は冷蔵室温度センサ74により検出した
値が設定温度以上の時に時間制御手段46に信号を出力
する。また、室温検知手段40は、冷蔵庫の周囲室温を
室温度センサ41からの信号をA/D変換器42により
出力電圧をデジタル化して時間制御手段46に信号を出
力する。また、蓄熱温度検知手段56は蓄熱材温度セン
サ57により検出した値が設定温度以上の時に時間制御
手段46に信号を出力する。The freezer temperature detecting means 44 outputs a signal to the time control means 46 when the value detected by the freezer compartment temperature sensor 43 is higher than the set temperature. The refrigerator temperature detecting means 75 outputs a signal to the time control means 46 when the value detected by the refrigerator temperature sensor 74 is equal to or higher than the set temperature. Further, the room temperature detecting means 40 digitizes an output voltage of the signal from the room temperature sensor 41 by the A / D converter 42 and outputs a signal to the time control means 46 for the room temperature around the refrigerator. Further, the heat storage temperature detecting means 56 outputs a signal to the time control means 46 when the value detected by the heat storage material temperature sensor 57 is equal to or higher than the set temperature.
【0028】図2において、4はコンプレッサであり電
磁弁79と電磁弁80からインナ−コンデンサ77とア
ウタ−コンデンサ80を介して電磁弁64と電磁弁65
に接続される。さらに、電磁弁64はキャピラリ7、冷
却器8及びアキュムレ−タ13を順次介して前記コンプ
レッサ4に接続される。また、電磁弁65は、蓄熱器用
キャピラリ9及び蓄熱器31内に配置した蓄熱器冷却パ
イプ38を順次介して前記アキュムレ−タ13接続され
る。Referring to FIG. 2, reference numeral 4 denotes a compressor, which is a solenoid valve 64 and a solenoid valve 65 from a solenoid valve 79 and a solenoid valve 80 via an inner capacitor 77 and an outer capacitor 80.
Connected to. Further, the solenoid valve 64 is connected to the compressor 4 via the capillary 7, the cooler 8 and the accumulator 13 in this order. The solenoid valve 65 is connected to the accumulator 13 via a regenerator capillary 9 and a regenerator cooling pipe 38 arranged in the regenerator 31 in order.
【0029】以上の様に構成された冷蔵庫について図1
と図2と図3と図4及び図5を用いてその動作を説明す
る。FIG. 1 shows a refrigerator constructed as described above.
The operation will be described with reference to FIGS. 2, 3, 4, and 5.
【0030】通常冷却運転は、冷却器8を用いて庫内を
冷却し設定温度に保冷するものである。即ち、CPU4
6によりリレ−49、83、81をONしリレ−66を
OFFとすることで冷媒流路は、インナ−コンデンサ7
7とアウタ−コンデンサ78の両方を介して(ステップ
S14)冷却器8と連通する側(ステップS1)、蓄熱
器ファン39は停止(ステップS2)となり、庫内温度
が設定値以上の時は冷凍庫内温度検知手段44からの信
号によりCPU46は、リレ−47及び53をONとし
コンプレッサ4及び冷却ファン19を運転する(ステッ
プS3)ことで冷却器8からの冷気は冷凍室17につい
ては冷凍室上部吹出口20から冷凍室17内を経て冷凍
室吸込口36を循環し、冷蔵室18については冷蔵室ダ
クト25、ダンパ26、冷蔵室18内を経て冷蔵室吸込
口35を循環することで各庫内を設定温度以下に冷却す
る。In the normal cooling operation, the inside of the refrigerator is cooled by using the cooler 8 and kept at a set temperature. That is, CPU4
By turning relays 49, 83 and 81 ON and turning relay 66 OFF by means of 6, the refrigerant flow path becomes the inner condenser 7
The regenerator fan 39 is stopped (step S2) on the side that communicates with the cooler 8 (step S1) via both the outer condenser 7 and the outer condenser 78 (step S14). In response to a signal from the internal temperature detecting means 44, the CPU 46 turns on the relays 47 and 53 to operate the compressor 4 and the cooling fan 19 (step S3). By circulating from the outlet 20 through the freezer compartment 17 through the freezer compartment suction port 36 and circulating through the refrigerator compartment duct 25, the damper 26, and the refrigerator compartment 18, the refrigerator compartment 18 is circulated through the refrigerator compartment suction port 35. Cool the inside to below the set temperature.
【0031】そして、庫内温度が設定値以下になると冷
凍庫内温度検知手段44の信号がOFFとなりCPU4
6は、リレ−47及び53をOFFとし、冷媒と冷気の
循環を停止する(ステップS4)。以上の動作を繰り返
すことにより庫内を設定温度に保冷する。When the temperature in the refrigerator falls below the set value, the signal of the temperature detector 44 in the refrigerator becomes OFF and the CPU 4
6 turns off the relays 47 and 53 and stops the circulation of the refrigerant and the cool air (step S4). By repeating the above operation, the inside of the refrigerator is kept cool to the set temperature.
【0032】蓄熱運転は、夜間の電力需要が低い所定の
時間帯(23時から翌日の7時まで)において(ステッ
プS5)、蓄熱器31内に充填されている蓄熱材32に
夜間の所定の時間帯の電力を熱に代えて蓄熱するもので
ある。即ち、庫内温度が設定値以上の時は冷凍庫内温度
検知手段44からの信号によりCPU46は、リレ−4
7及び53をONとしコンプレッサ4及び冷却ファン1
9を運転する通常運転を行い(ステップS6)、庫内温
度が設定値以下になると冷凍庫内温度検知手段44の信
号にからCPU46によりリレ−51、47及び83を
ONとすることで冷媒流路を、アウタ−コンデンサ78
を介して(ステップS13)蓄熱器31が連通する側に
保持し、コンプレッサ4を運転することで冷媒を蓄熱器
31内の蓄熱器冷却パイプ38で蒸発させ、蓄熱材32
を凍結させる(ステップS7)。In the heat storage operation, during a predetermined time period during which nighttime power demand is low (from 23:00 to 7:00 of the next day) (step S5), the heat storage material 32 filled in the heat storage device 31 is stored in the heat storage material 32 during the night. The electric power in the time zone is stored instead of heat. That is, when the temperature in the freezer is equal to or higher than the set value, the signal from the freezer temperature detecting means 44 causes the CPU 46 to execute the relay-4
7 and 53 are turned on, the compressor 4 and the cooling fan 1
9 (step S6), and when the temperature in the refrigerator becomes equal to or lower than the set value, the CPU 46 turns on the relays 51, 47, and 83 from the signal of the temperature detector 44 in the freezer, thereby turning on the refrigerant flow path. To the outer condenser 78
(Step S13), the refrigerant is held on the side to which the regenerator 31 communicates, and the compressor 4 is operated to evaporate the refrigerant in the regenerator cooling pipe 38 in the regenerator 31, and the heat storage material 32
Is frozen (step S7).
【0033】凝縮器としてアウタ−コンデンサ78のみ
を使用するので、凝縮器からの冷蔵庫内への侵入熱量は
なく夏期等の高室温時においても蓄熱材32を凍結させ
る時間を十分に確保できる。Since only the outer condenser 78 is used as the condenser, there is no heat entering the refrigerator from the condenser, and a sufficient time for freezing the heat storage material 32 can be secured even at a high room temperature such as in summer.
【0034】また、蓄熱材32の重量としては、春季、
秋季等の低室温(15℃)時における冷蔵温度帯の室を
基準とした重量としておく。即ち、低室温時において昼
間の電力需要が多い所定の時間帯(7時から23時ま
で)の冷蔵室の合計した負荷熱量と同等の熱量を全て蓄
熱できる重量とすることである。The weight of the heat storage material 32 is as follows:
The weight is set based on the room in the refrigerated temperature zone at the time of low room temperature (15 ° C.) such as in autumn. That is, the weight is such that all the heat amount equivalent to the total load heat amount of the refrigerating compartment in a predetermined time zone (from 7:00 to 23:00) when the power demand in the daytime is high at the low room temperature can be stored.
【0035】蓄熱冷却運転は、昼間の電力需要がピ−ク
の時間帯に蓄熱器31が蓄熱した熱を利用して冷凍室以
外の室の戻り空気冷却するものである。即ち、冷凍室内
温度が設定値以上の時は冷凍庫内温度検知手段44から
の信号によりCPU46は、リレ−47、53をONと
しコンプレッサ4、冷却ファン19を運転することで冷
凍室を設定温度以下に冷却する。In the heat storage cooling operation, the air stored in the heat storage unit 31 is used to cool the return air in a room other than the freezing room by utilizing the heat stored by the heat storage unit 31 during the peak time of daytime power demand. That is, when the freezing room temperature is equal to or higher than the set value, the CPU 46 turns on the relays 47 and 53 according to the signal from the freezer temperature detecting means 44 and operates the compressor 4 and the cooling fan 19 to lower the freezing room to the set temperature. Cool.
【0036】また、冷蔵室18の温度調節は蓄熱器ファ
ン39の運転を制御することにより設定温度に制御す
る。冷蔵室内温度が設定以上の時は冷蔵庫内温度検知手
段75からの信号によりCPU46は、リレ−66をO
Nとし(ステップS8)、蓄熱器ファン39を運転する
ことで冷蔵室ダクト25から冷蔵室18内に吐出された
冷気は蓄熱器吸込口37から蓄熱器31内に吸い込ま
れ、冷却されてから通風ダクト55を経て冷却器8に戻
る。これにより冷却器8で冷却する熱量は、冷凍室の負
荷熱量だけとなる。The temperature of the refrigerating compartment 18 is controlled to a set temperature by controlling the operation of the regenerator fan 39. When the temperature in the refrigerator compartment is equal to or higher than the set temperature, the CPU 46 sets the relay 66 to O by a signal from the refrigerator temperature detecting means 75.
N (step S8), and by operating the regenerator fan 39, the cool air discharged from the refrigerating room duct 25 into the refrigerating room 18 is sucked into the regenerator 31 from the regenerator suction port 37, and is cooled before being ventilated. It returns to the cooler 8 via the duct 55. Thus, the amount of heat to be cooled by the cooler 8 is only the amount of heat applied to the freezing compartment.
【0037】そして、庫内温度が設定値以下になると冷
凍庫内温度検知手段44の信号がOFFとなりCPU4
6は、リレ−47、53及び66をOFFとし、コンプ
レッサ及び冷気の循環を停止する。以上の動作を繰り返
すことにより各庫内を設定温度に保冷する。When the internal temperature of the refrigerator falls below the set value, the signal of the freezer internal temperature detecting means 44 is turned off and the CPU 4
6 turns off the relays 47, 53 and 66 and stops the circulation of the compressor and the cool air. By repeating the above operation, the inside of each refrigerator is kept at the set temperature.
【0038】次に、冷却器8の除霜開始時刻の制御方法
について図4及び図5を用いて説明する。Next, a method for controlling the defrosting start time of the cooler 8 will be described with reference to FIGS.
【0039】蓄熱運転の時間は室温により変化する。そ
れは、キャビネット2から侵入する熱量やシステムの冷
凍能力が室温によって変化するためであり蓄熱運転時間
が長い室温の高い夏季等は、任意に設定温度以上である
ことを室温検知手段40から信号を受けた除霜開始判定
手段63が蓄熱運転時間を充分確保するべく昼間におい
て電力需要がピ−クの時間帯を除く時間に冷却器8の除
霜を開始させる。The time of the heat storage operation varies depending on the room temperature. This is because the amount of heat entering from the cabinet 2 and the refrigeration capacity of the system change depending on the room temperature. In summer, when the heat storage operation time is long and the room temperature is high, a signal from the room temperature detecting means 40 that the temperature is arbitrarily set or higher is received. The defrosting start determining means 63 starts defrosting of the cooler 8 during the daytime except for the peak time period in order to secure sufficient heat storage operation time.
【0040】また、蓄熱運転時間が短い室温が低い季節
は、除霜開始判定手段63が電力需要の少ない夜間の所
定の時間帯に冷却器8の除霜を開始させる。In a season in which the heat storage operation time is short and the room temperature is low, the defrosting start determining means 63 starts defrosting the cooler 8 in a predetermined time zone at night when power demand is small.
【0041】例えば図5に示す如く、室温が設定温度以
上の時は7時と21時に、室温が設定温度以下の時は2
3時に除霜を開始させる。For example, as shown in FIG. 5, when the room temperature is higher than the set temperature, 7:00 and 21:00, and when the room temperature is lower than the set temperature, 2 hours.
At 3 o'clock, start defrosting.
【0042】次に、各運転の制御方法を説明する。時間
制御手段46により夜間電力需要が低い所定の時間帯
(23時から翌日の7時まで)23時から通常冷却運転
と蓄熱運転の交互運転をする。即ち、庫内温度が設定値
以上の時は通常冷却運転で庫内を冷却し、庫内温度が設
定値以下の時は蓄熱運転により電力を熱に代えて蓄熱す
る(ステップS5)制御を行い、蓄熱温度検知手段56
により蓄熱材32の凍結終了を検知し蓄熱運転を終了す
る(ステップS10)。Next, a control method for each operation will be described. The time control means 46 performs the alternate operation of the normal cooling operation and the heat storage operation from 23:00 in a predetermined time period during which nighttime power demand is low (from 23:00 to 7:00 the next day). That is, when the inside temperature is equal to or higher than the set value, the inside is cooled by the normal cooling operation, and when the inside temperature is equal to or less than the set value, the heat is stored in the heat storage operation instead of heat (step S5). , Heat storage temperature detecting means 56
Detects the end of freezing of the heat storage material 32, and ends the heat storage operation (step S10).
【0043】また、昼間の負荷量に対しては、室温検知
手段40により検知した前日の昼間の平均室温より時間
制御手段46が推測する。The daytime load amount is estimated by the time control means 46 from the average daytime room temperature of the day before detected by the room temperature detection means 40.
【0044】この推測値より、時間制御手段46が少な
くとも昼間の電力需要がピ−クの時間帯(13時から1
6時)を含むように蓄熱冷却運転を開始する(ステップ
S11)。そして、蓄熱温度検知手段56が蓄熱材32
が設定温度以上になり蓄熱器31の冷却能力がなくなっ
たことの信号を時間制御手段46に送出することで蓄熱
冷却運転が終了する。Based on this estimated value, the time control means 46 determines that at least the daytime power demand is in the peak time zone (13:00 from 13:00).
6:00) is started (step S11). Then, the heat storage temperature detecting means 56
Is sent to the time control means 46, indicating that the cooling capacity of the heat accumulator 31 has been lost due to the temperature exceeding the set temperature.
【0045】例えば図5に示す如く、蓄熱冷却運転の時
間は室温30℃の場合は7時間であり、室温15℃の場
合は16時間となる。For example, as shown in FIG. 5, the time of the heat storage cooling operation is 7 hours when the room temperature is 30 ° C., and 16 hours when the room temperature is 15 ° C.
【0046】以上のように本実施例によれば、並列また
は直列に接続した冷却器と冷蔵室内に配置した内部に蓄
熱材を有する蓄熱器と、並列または直列に接続した冷蔵
庫キャビネット内に埋設したインナ−コンデンサと機械
室に配置したアウタ−コンデンサと、前記蓄熱器内の冷
気を送出する蓄熱器ファンと、任意の時間帯に前記蓄熱
器に熱を蓄熱する蓄熱運転と蓄熱した熱により冷蔵庫内
を冷却する蓄熱冷却運転の時間制御を行う時間制御手段
とを備え、前記蓄熱運転時は前記アウタ−コンデンサの
みを使用し、その他の運転時はインナ−コンデンサとア
ウタ−コンデンサの両方を使用するので、冷蔵庫内に侵
入する負荷熱量が低減でき、夏期等の高室温時において
も蓄熱運転における蓄熱に要する時間を十分に確保でき
る。As described above, according to the present embodiment, a cooler connected in parallel or in series and a heat accumulator having a heat storage material disposed inside the refrigerator compartment and a refrigerator built in parallel or in series are embedded. An inner condenser and an outer condenser arranged in a machine room, a regenerator fan for sending out cool air in the regenerator, and a heat storage operation for storing heat in the regenerator at an arbitrary time and heat stored in the refrigerator. And time control means for controlling the time of the heat storage cooling operation for cooling the heat storage operation.In the heat storage operation, only the outer capacitor is used, and in other operations, both the inner capacitor and the outer capacitor are used. In addition, the amount of load heat entering the refrigerator can be reduced, and the time required for heat storage in the heat storage operation can be sufficiently ensured even at a high room temperature such as in summer.
【0047】さらに蓄熱器を冷蔵室内に設置しているこ
とで蓄熱器からの放熱は冷蔵室の冷却に利用できるので
電力の有効利用ができる。Further, since the heat storage device is installed in the refrigerator compartment, the heat radiated from the heat storage device can be used for cooling the refrigerator compartment, so that the electric power can be effectively used.
【0048】さらに室温に応じて除霜開始時間を決める
ので室温の高い夏季等には夜間の蓄熱運転時間を充分確
保でき、室温の低い季節には電力需要の少ない夜間に除
霜を開始できるので、年間を通じて電力の有効利用がで
きる。Further, since the defrosting start time is determined according to the room temperature, sufficient heat storage operation time at night can be ensured in summer when the room temperature is high, and defrosting can be started at night when power demand is low in the season when the room temperature is low. Power can be used effectively throughout the year.
【0049】[0049]
【発明の効果】以上のように本発明は、並列または直列
に接続した冷却器と冷蔵室内に配置した内部に蓄熱材を
有する蓄熱器と、並列または直列に接続した冷蔵庫キャ
ビネット内に埋設したインナ−コンデンサと機械室に配
置したアウタ−コンデンサと、前記蓄熱器内の冷気を送
出する蓄熱器ファンと、任意の時間帯に前記蓄熱器に熱
を蓄熱する蓄熱運転と蓄熱した熱により冷蔵庫内を冷却
する蓄熱冷却運転の時間制御を行う時間制御手段とを備
え、前記蓄熱運転時は前記アウタ−コンデンサのみを使
用し、その他の運転時はインナ−コンデンサとアウタ−
コンデンサの両方を使用するので、冷蔵庫内に侵入する
負荷熱量が低減でき、夏期等の高室温時においても蓄熱
運転における蓄熱に要する時間を十分に確保できる。As described above, the present invention relates to a refrigerator connected in parallel or in series and a heat storage having a heat storage material disposed inside the refrigerator compartment, and an inner buried in a refrigerator cabinet connected in parallel or in series. A condenser and an outer condenser arranged in the machine room, a regenerator fan for sending out cool air in the regenerator, and a heat storage operation for storing heat in the regenerator at an arbitrary time zone, and the heat stored in the refrigerator. Time control means for performing time control of a heat storage cooling operation for cooling, wherein only the outer capacitor is used during the heat storage operation, and the inner capacitor and the outer capacitor are used during other operations.
Since both of the condensers are used, the amount of load heat entering the refrigerator can be reduced, and the time required for heat storage in the heat storage operation can be sufficiently ensured even at a high room temperature in summer or the like.
【0050】さらに蓄熱器を冷蔵室内に設置しているこ
とで蓄熱器からの放熱は冷蔵室の冷却に利用できるので
電力の有効利用ができる冷蔵庫となる。Further, since the regenerator is installed in the refrigerator compartment, the heat radiated from the regenerator can be used for cooling the refrigerator compartment, so that the refrigerator can effectively use electric power.
【図1】本発明の一実施例における冷蔵庫の機能ブロッ
ク図FIG. 1 is a functional block diagram of a refrigerator according to an embodiment of the present invention.
【図2】図1の冷蔵庫の冷凍システム図FIG. 2 is a refrigeration system diagram of the refrigerator of FIG. 1;
【図3】図1の冷蔵庫の要部の電気回路図FIG. 3 is an electric circuit diagram of a main part of the refrigerator of FIG. 1;
【図4】図1の冷蔵庫のフロ−チャ−ト図FIG. 4 is a flowchart of the refrigerator shown in FIG. 1;
【図5】図1の室温に応じた一日の運転状態図FIG. 5 is a diagram showing an operation state of the day according to the room temperature in FIG. 1;
【図6】従来の冷蔵庫の冷凍システム図FIG. 6 is a refrigeration system diagram of a conventional refrigerator.
【図7】図7の冷蔵庫の構造を示す縦断面図FIG. 7 is a longitudinal sectional view showing the structure of the refrigerator in FIG. 7;
8 冷却器 31 蓄熱器 32 蓄熱材 39 蓄熱器ファン 46 時間制御手段 77 インナ−コンデンサ 78 アウタ−コンデンサ Reference Signs List 8 cooler 31 regenerator 32 regenerator material 39 regenerator fan 46 time control means 77 inner condenser 78 outer condenser
───────────────────────────────────────────────────── フロントページの続き (58)調査した分野(Int.Cl.7,DB名) F25D 16/00 F25B 5/00 F25D 19/00 530 ──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int. Cl. 7 , DB name) F25D 16/00 F25B 5/00 F25D 19/00 530
Claims (1)
室内に配置した内部に蓄熱材を有する蓄熱器と、並列ま
たは直列に接続した冷蔵庫キャビネット内に埋設したイ
ンナ−コンデンサと機械室に配置したアウタ−コンデン
サと、前記蓄熱器内の冷気を送出する蓄熱器ファンと、
任意の時間帯に前記蓄熱器に熱を蓄熱する蓄熱運転と蓄
熱した熱により冷蔵庫内を冷却する蓄熱冷却運転の時間
制御を行う時間制御手段とを備え、前記蓄熱運転時は前
記アウタ−コンデンサのみを使用し、その他の運転時は
インナ−コンデンサとアウタ−コンデンサの両方を使用
することを特徴とする冷蔵庫。1. A refrigerator connected in parallel or in series with a regenerator having a heat storage material disposed in a refrigerator and an inner condenser embedded in a refrigerator cabinet connected in parallel or in series, and disposed in a machine room. An outer condenser, and a regenerator fan for delivering cool air in the regenerator;
A heat storage operation for storing heat in the heat storage device in an arbitrary time zone and time control means for performing time control of a heat storage cooling operation for cooling the refrigerator with the stored heat, wherein only the outer capacitor is used during the heat storage operation. A refrigerator using both the inner condenser and the outer condenser during other operations.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP05118207A JP3098889B2 (en) | 1993-05-20 | 1993-05-20 | refrigerator |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP05118207A JP3098889B2 (en) | 1993-05-20 | 1993-05-20 | refrigerator |
Publications (2)
Publication Number | Publication Date |
---|---|
JPH06331259A JPH06331259A (en) | 1994-11-29 |
JP3098889B2 true JP3098889B2 (en) | 2000-10-16 |
Family
ID=14730856
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP05118207A Expired - Fee Related JP3098889B2 (en) | 1993-05-20 | 1993-05-20 | refrigerator |
Country Status (1)
Country | Link |
---|---|
JP (1) | JP3098889B2 (en) |
Cited By (1)
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---|---|---|---|---|
KR20130023873A (en) * | 2011-08-30 | 2013-03-08 | 엘지전자 주식회사 | Refrigerator and controlling method for the same |
Families Citing this family (1)
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JP2024051960A (en) * | 2022-09-30 | 2024-04-11 | パナソニックIpマネジメント株式会社 | Cooling device, method for operating cooling device, and system for controlling cooling device |
-
1993
- 1993-05-20 JP JP05118207A patent/JP3098889B2/en not_active Expired - Fee Related
Cited By (2)
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---|---|---|---|---|
KR20130023873A (en) * | 2011-08-30 | 2013-03-08 | 엘지전자 주식회사 | Refrigerator and controlling method for the same |
KR101943314B1 (en) * | 2011-08-30 | 2019-01-29 | 엘지전자 주식회사 | Refrigerator and Controlling Method for the same |
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Publication number | Publication date |
---|---|
JPH06331259A (en) | 1994-11-29 |
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