JP2005069655A - Multi-type air conditioner - Google Patents
Multi-type air conditioner Download PDFInfo
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- JP2005069655A JP2005069655A JP2003303883A JP2003303883A JP2005069655A JP 2005069655 A JP2005069655 A JP 2005069655A JP 2003303883 A JP2003303883 A JP 2003303883A JP 2003303883 A JP2003303883 A JP 2003303883A JP 2005069655 A JP2005069655 A JP 2005069655A
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B2600/00—Control issues
- F25B2600/21—Refrigerant outlet evaporator temperature
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Abstract
Description
本発明は、2台以上の室内機が接続されたマルチ式空気調和機に関するものである。 The present invention relates to a multi-type air conditioner to which two or more indoor units are connected.
従来のマルチ式空気調和機の膨張弁制御方法を、図15のフローチャート及び図16のタイムチャート並びに図17のブロック図に示す。同図のように、2台以上の室内機が接続されたマルチ式空気調和機において、室内熱交温度及び熱交出口温度を検知しその温度差から過熱度を算出する一方で、過熱度の目標値を設定し、上記過熱度が目標値に収束するように膨張弁の開度を補正していた(例えば、特許文献1参照)。
しかしながら、上記従来の構成では、目標とする過熱度に早く近づけるために、1回に補正するパルス値を大きくすれば、冷凍サイクルがハンチングし不安定となる。逆に1回当たりの補正パルス値を小さくすれば冷凍サイクルは安定するが、目標とする過熱度になかなか近づかなくなり、ひいては所定の能力が発揮できないという課題を有していた。また過熱度が0K以下の場合、目標値に収束するように膨張弁の開度を絞っていくと、室内熱交温度が下がり能力は上昇するが、図18のフローチャートに示すように、室内熱交温度が低くなりすぎると凍結防止制御が動作し、設定値DT01を下回ってダウンゾーンに入り圧縮機の運転周波数を下げる。室内熱交温度がさらに低くなると、停止ゾーンに入り圧縮機を停止させてしまい返って不快感を増幅させるという課題を有していた。
膨張弁の開度をPI制御採用により問題の解決を図ろうとするものもあるが、マルチでしかも2室以上運転時は負荷変動が大きくこのような制御で冷凍サイクルの最適化を図るには限界があった。
However, in the above-described conventional configuration, if the pulse value to be corrected once is increased in order to quickly approach the target degree of superheat, the refrigeration cycle will hunt and become unstable. On the contrary, if the correction pulse value per one time is decreased, the refrigeration cycle is stabilized, but it is difficult to approach the target degree of superheat, and as a result, the predetermined ability cannot be exhibited. When the degree of superheat is 0K or less, if the opening degree of the expansion valve is reduced so as to converge to the target value, the indoor heat exchange temperature decreases and the capacity increases, but as shown in the flowchart of FIG. When the AC temperature becomes too low, anti-freezing control is activated and falls below the set value DT01 to enter the down zone and lower the operating frequency of the compressor. When the indoor heat exchange temperature is further lowered, there is a problem that the compressor enters the stop zone and returns to amplify discomfort.
Some attempts to solve the problem by adopting PI control for the opening of the expansion valve, but the load fluctuation is large when operating in multiple and more than two rooms, and it is the limit to optimize the refrigeration cycle with such control. was there.
本発明はこのような従来の課題を解決するものであり、室内熱交過熱度を検知して 膨張弁の開度を補正して冷媒の流量を調節し、最適な冷凍サイクル状態を維持し能力を最大限に引き出すことを可能にした空気調和機の膨張弁制御方法を提供することを目的とする。 The present invention solves such a conventional problem, detects the degree of indoor heat exchange, corrects the opening of the expansion valve, adjusts the flow rate of the refrigerant, and maintains the optimum refrigeration cycle state. It is an object of the present invention to provide an expansion valve control method for an air conditioner that can extract the maximum amount of air.
上記課題を解決するために本発明は、室内吸込み温度検出手段及び冷媒の蒸発温度が検知可能な室内熱交温度検出手段、及び前記熱交出口温度検出手段、前記熱交温度と出口温度から冷媒の過熱度を算出する演算手段、電動膨張弁駆動回路及び室内機形態及び馬力によって決定された膨張弁パルス設定値記憶手段より構成され、冷房運転または除湿運転開始時において、室温と設定温度との差から膨張弁の目標パルスを初期パルスとして設定し、室内熱交過熱度が目標値を超えたら、膨張弁を開弁し、前記過熱度が目標値を下回ったら膨張弁を閉弁し、前記過熱度が所定の範囲内であれば、膨張弁は現状のパルスを保持することにより冷媒流量を調節し、しかも前記過熱度が目標値を下回ったとしても、室温が第1の設定値を下回っていたらこれ以上パルスは変化しないものである。 In order to solve the above-mentioned problems, the present invention provides an indoor heat exchange temperature detecting means, an indoor heat exchange temperature detecting means capable of detecting the evaporation temperature of the refrigerant, the heat exchange outlet temperature detecting means, and the refrigerant from the heat exchange temperature and the outlet temperature. The calculation means for calculating the degree of superheat, the electric expansion valve drive circuit and the expansion valve pulse set value storage means determined by the indoor unit configuration and horsepower, and at the start of the cooling or dehumidifying operation, the room temperature and the set temperature The target pulse of the expansion valve is set as an initial pulse from the difference, and when the indoor heat exchange superheat degree exceeds the target value, the expansion valve is opened, and when the superheat degree falls below the target value, the expansion valve is closed, If the degree of superheat is within a predetermined range, the expansion valve adjusts the flow rate of the refrigerant by maintaining the current pulse, and even if the degree of superheat falls below the target value, the room temperature falls below the first set value. If you were Is more pulses are those that do not change.
この構成をなすことによって、最適な冷凍サイクル状態を維持し、性能を最大限に引き出すことができる。 With this configuration, the optimum refrigeration cycle state can be maintained and the performance can be maximized.
また、本発明は、室内吸込み温度検出手段及び冷媒の蒸発温度が検知可能な室内熱交温度検出手段、及び前記熱交出口温度検出手段、前記熱交温度と出口温度から冷媒の過熱度を算出する演算手段、電動膨張弁駆動回路及び室内機形態及び馬力によって決定された膨張弁パルス設定値記憶手段より構成され、冷房運転または除湿運転開始時において、室温と設定温度との差から膨張弁の目標パルスを初期パルスとして設定し、室内熱交過熱度が目標値を超えたら、膨張弁を開弁し、前記過熱度が目標値を下回ったら膨張弁を閉弁し、前記過熱度が所定の範囲内であれば、膨張弁は現状のパルスを保持することにより冷媒流量を調節し、しかも前記過熱度が目標値を下回ったとしても、前記熱交温度が第2の設定値を下回っていたらこれ以上パルスは変化しないものである。 Further, the present invention calculates the superheat degree of the refrigerant from the indoor heat exchange temperature detection means, the indoor heat exchange temperature detection means capable of detecting the evaporation temperature of the refrigerant, the heat exchange outlet temperature detection means, and the heat exchange temperature and the outlet temperature. And an expansion valve pulse set value storage means determined by the configuration of the indoor unit and the horsepower, and at the start of the cooling operation or the dehumidifying operation, the expansion valve When the target pulse is set as an initial pulse and the indoor heat exchange superheat degree exceeds the target value, the expansion valve is opened.When the superheat degree falls below the target value, the expansion valve is closed, and the superheat degree is a predetermined value. If it is within the range, the expansion valve adjusts the refrigerant flow rate by holding the current pulse, and even if the superheat degree falls below the target value, the heat exchange temperature falls below the second set value. No more Vinegar is one that does not change.
この構成をなすことにより、最適な冷凍サイクル状態を維持し、性能を最大限に引き出すことができる。 With this configuration, the optimum refrigeration cycle state can be maintained and the performance can be maximized.
また、本発明はは第3図の制御ブロック図に示すように、室内吸込み温度検出手段及び冷媒の蒸発温度が検知可能な室内熱交温度検出手段、及び前記熱交出口温度検出手段、前記熱交温度と出口温度から冷媒の過熱度を算出する演算手段、電動膨張弁駆動回路及び室内機形態及び馬力によって決定された膨張弁パルス設定値記憶手段より構成され、冷房運転または除湿運転開始時において、室温と設定温度との差から膨張弁の目標パルスを初期パルスとして設定し、室内熱交過熱度が目標値を上回ったら膨張弁を開弁し、例え上限パルスまで到達しても、室温が第3の設定値を超えていたら、第2の上限値を設け、引続き継続して開弁するものである。 Further, in the present invention, as shown in the control block diagram of FIG. 3, the indoor heat exchange temperature detecting means, the indoor heat exchange temperature detecting means capable of detecting the evaporation temperature of the refrigerant, the heat exchange outlet temperature detecting means, the heat Comprising calculation means for calculating the degree of superheat of the refrigerant from the alternating temperature and outlet temperature, an electric expansion valve drive circuit, and an expansion valve pulse set value storage means determined by the indoor unit configuration and horsepower, at the start of cooling operation or dehumidification operation The target pulse of the expansion valve is set as the initial pulse based on the difference between the room temperature and the set temperature.When the indoor heat exchange superheat exceeds the target value, the expansion valve is opened. If it exceeds the third set value, the second upper limit value is provided and the valve is continuously opened.
この構成をなすことにより、最適な冷凍サイクル状態を維持し、性能を最大限に引き出すことが出来る。 With this configuration, the optimum refrigeration cycle state can be maintained and the performance can be maximized.
また本発明は、第4図の制御ブロック図に示すように、室内吸込み温度検出手段及び冷媒の蒸発温度が検知可能な室内熱交温度検出手段、及び前記熱交出口温度検出手段、前記熱交温度と出口温度から冷媒の過熱度を算出する演算手段、電動膨張弁駆動回路及び室内機形態及び馬力によって決定された膨張弁パルス設定値記憶手段より構成され、冷房運転または除湿運転開始時において、室温と設定温度との差から膨張弁の目標パルスを初期パルスとして設定し、室内熱交過熱度が目標値を下回ったら膨張弁を閉弁するが、このとき現在の室温と10分前の室温を比較して差が第4の設定値を下回っていたら、これ以上パルスは変化しないものである。
In addition, as shown in the control block diagram of FIG. 4, the present invention includes an indoor heat exchange temperature detection means, an indoor heat exchange temperature detection means capable of detecting the evaporation temperature of the refrigerant, the heat exchange outlet temperature detection means, and the heat exchange. Comprising calculation means for calculating the degree of superheat of the refrigerant from the temperature and the outlet temperature, an electric expansion valve drive circuit and an expansion valve pulse set value storage means determined by the indoor unit configuration and horsepower, at the start of cooling operation or dehumidification operation, The target pulse of the expansion valve is set as an initial pulse from the difference between the room temperature and the set temperature, and the expansion valve is closed when the indoor heat exchange superheat degree falls below the target value. At this time, the current room temperature and the
この構成をなすことにより、最適な冷凍サイクル状態を維持し、性能を最大限に引き出すことが出来る。 With this configuration, the optimum refrigeration cycle state can be maintained and the performance can be maximized.
上記から明らかなように、本発明は、
(1)30秒毎に室内熱交温度及び熱交出口温度から過熱度を算出し、前記過熱度が0Kを下回るとΔp1パルス閉弁し、また前記過熱度が0Kとsh1Kの間にあれば現状のパルスを保持し、前記過熱度がsh1Kを超えればΔp2パルス開弁する。このとき補正後のパルスが上下限パルス設定値と比較し、前記設定範囲を超えたら補正パルスを上限または下限パルスとする。また室温が第1の設定値を下回ったら、例え前記過熱度が0Kを下回っていても膨張弁パルスを変化させない。しかも室外圧縮機周波数がΔHz以上変化すると室外より初期パルス信号を受信し、一旦初期パルスに戻すがこのとき初期パルスは当初のパルスではなく異なるΔD領域での初期パルスに戻って再び過熱度制御を継続することにより最適な冷凍サイクルを維持し、性能を最大限に引き出すことができる。
(2)30秒毎に室内熱交温度及び熱交出口温度から過熱度を算出し、前記過熱度が0Kを下回るとΔp1パルス閉弁し、また前記過熱度が0Kとsh1Kの間にあれば現状のパルスを保持し、前記過熱度がsh1Kを超えればΔp2パルス開弁する。このとき補正後のパルスが上下限パルス設定値と比較し、前記設定範囲を超えたら補正パルスを上限または下限パルスとする。また前記熱交温度が設定値DT00℃を下回ったら凍結防止制御により圧縮機は停止し、返って不快感を増幅させてしまうので、圧縮機は連続運転可能なように、前記熱交温度が第2の設定値を下回ったら例え前記過熱度が0Kを下回っていても膨張弁パルスを変化させない。しかも室外圧縮機周波数がΔHz以上変化すると室外より初期パルス信号を受信し、一旦初期パルスに戻すがこのとき初期パルスは当初のパルスではなく異なるΔD領域での初期パルスに戻って再び過熱度制御を継続することにより最適な冷凍サイクルを維持し、性能を最大限に引き出すことができる。
(3)30秒毎に室内熱交温度及び熱交出口温度から過熱度を算出し、前記過熱度が0Kを下回るとΔp1パルス閉弁し、また前記過熱度が0Kとsh1Kの間にあれば現状のパルスを保持し、前記過熱度がsh1Kを超えればΔp2パルス開弁する。このとき補正後のパルスが上下限パルス設定値と比較し、前記設定範囲を超えたら補正パルスを上限または下限パルスとする。しかし室温が第3の設定値を上回ったら例え膨張弁パルスが上限パルスまで到達していても、第2の上限値を設け、引続き継続して開弁することにより、過熱度を低減し大きくなり過ぎるのを防ぐことができる。しかも室外圧縮機周波数がΔHz以上変化すると室外より初期パルス信号を受信し、一旦初期パルスに戻すがこのとき初期パルスは当初のパルスではなく異なるΔD領域での初期パルスに戻って再び過熱度制御を継続することにより最適な冷凍サイクルを維持し、性能を最大限に引き出すことができる。
(4)30秒毎に室内熱交温度及び熱交出口温度から過熱度を算出し、前記過熱度が0Kを下回るとΔp1パルス閉弁し、また前記過熱度が0Kとsh1Kの間にあれば現状のパルスを保持し、前記過熱度がsh1Kを超えればΔp2パルス開弁する。このとき補正後のパルスが上下限パルス設定値と比較し、前記設定範囲を超えたら補正パルスを上限または下限パルスとする。このとき現在の室温と10分前の室温を比較して差が第4の設定値以下であれば、室温は設定温度に達したと判断し、例え過熱度が0Kを下回っていても膨張弁パルスを変化させない。しかも室外圧縮機周波数がΔHz以上変化すると室外より初期パルス信号を受信し、一旦初期パルスに戻すがこのとき初期パルスは当初のパルスではなく異なるΔD領域での初期パルスに戻って再び過熱度制御を継続することにより最適な冷凍サイクルを維持し、性能を最大限に引き出すことができる。
As is apparent from the above, the present invention
(1) The degree of superheat is calculated from the indoor heat exchange temperature and the heat exchange outlet temperature every 30 seconds. When the superheat degree falls below 0K, the Δp1 pulse is closed, and if the superheat degree is between 0K and sh1K. If the current pulse is held and the superheat exceeds sh1K, the Δp2 pulse is opened. At this time, the corrected pulse is compared with the upper / lower limit pulse set value, and if it exceeds the set range, the corrected pulse is set to the upper limit or lower limit pulse. If the room temperature falls below the first set value, the expansion valve pulse is not changed even if the degree of superheat is below 0K. In addition, when the outdoor compressor frequency changes by ΔHz or more, an initial pulse signal is received from the outside and once returned to the initial pulse. At this time, the initial pulse returns to the initial pulse in a different ΔD region instead of the initial pulse, and the superheat degree control is performed again. By continuing, the optimum refrigeration cycle can be maintained and the performance can be maximized.
(2) Every 30 seconds, the degree of superheat is calculated from the indoor heat exchange temperature and the heat exchange outlet temperature. When the degree of superheat falls below 0K, the Δp1 pulse is closed, and if the degree of superheat is between 0K and sh1K. If the current pulse is held and the superheat exceeds sh1K, the Δp2 pulse is opened. At this time, the corrected pulse is compared with the upper / lower limit pulse set value, and if it exceeds the set range, the corrected pulse is set to the upper limit or lower limit pulse. When the heat exchange temperature falls below the set value DT00 ° C., the compressor is stopped by anti-freezing control and returns to amplify discomfort, so that the heat exchange temperature is set so that the compressor can be continuously operated. If the set value is less than 2, the expansion valve pulse is not changed even if the superheat is less than 0K. In addition, when the outdoor compressor frequency changes by ΔHz or more, an initial pulse signal is received from the outside and once returned to the initial pulse. At this time, the initial pulse returns to the initial pulse in a different ΔD region instead of the initial pulse, and the superheat degree control is performed again. By continuing, the optimum refrigeration cycle can be maintained and the performance can be maximized.
(3) The superheat degree is calculated from the indoor heat exchange temperature and the heat exchange outlet temperature every 30 seconds, and when the superheat degree falls below 0K, the Δp1 pulse is closed, and if the superheat degree is between 0K and sh1K. If the current pulse is held and the superheat exceeds sh1K, the Δp2 pulse is opened. At this time, the corrected pulse is compared with the upper / lower limit pulse set value, and if it exceeds the set range, the corrected pulse is set to the upper limit or lower limit pulse. However, if the room temperature exceeds the third set value, even if the expansion valve pulse has reached the upper limit pulse, the second upper limit value is provided and the valve is continuously opened to reduce the degree of superheat and increase it. It can be prevented from passing. In addition, when the outdoor compressor frequency changes by ΔHz or more, an initial pulse signal is received from the outside and once returned to the initial pulse. At this time, the initial pulse returns to the initial pulse in a different ΔD region instead of the initial pulse, and the superheat degree control is performed again. By continuing, the optimum refrigeration cycle can be maintained and the performance can be maximized.
(4) The degree of superheat is calculated from the indoor heat exchange temperature and the heat exchange outlet temperature every 30 seconds. When the superheat degree falls below 0K, the Δp1 pulse is closed, and if the superheat degree is between 0K and sh1K. If the current pulse is held and the superheat exceeds sh1K, the Δp2 pulse is opened. At this time, the corrected pulse is compared with the upper / lower limit pulse set value, and if it exceeds the set range, the corrected pulse is set to the upper limit or lower limit pulse. At this time, if the difference between the current room temperature and the
以下、本発明の実施の形態について図面を参照して説明する。 Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(実施の形態1)
第5図は発明の第1の実施例を示す冷凍サイクル図である。同図において、冷凍サイクルは能力可変型圧縮機1、室内側熱交換器2、室内送風機3、室内膨張弁4、室外側熱交換器5、室外送風機6、暖房運転と除霜運転を切換える4方弁7、室温を検出するサーミスタ8、室内熱交換器出口温度を検出するサーミスタ9、とで構成されている。暖房運転時には4方弁6が切り変わることにより、同図の矢印の方向に冷媒が流れるようになっている。
(Embodiment 1)
FIG. 5 is a refrigeration cycle diagram showing the first embodiment of the invention. In the figure, the refrigeration cycle switches between a
次に第6図フローチャート及び第7図のタイムチャートにより、膨張弁制御の動作を説明する。 Next, the operation of the expansion valve control will be described with reference to the flowchart of FIG. 6 and the time chart of FIG.
冷房または除湿運転で起動制御終了後、膨張弁は通常制御に移行すると室内機の形態及び馬力、さらに室温及び設定温度からΔTを検知してΔTがT1未満であれば第1の初期パルス、ΔTがT1とT2の間にあれば第2の初期パルス、ΔTがT2を超えれば第3の初期パルスとして設定し(S101)、膨張弁は前記パルスまで開弁あるいは閉弁しここを開始点として過熱度制御に移行する。すなわち30秒毎に室内熱交温度及び熱交出口温度から過熱度を算出し、前記過熱度が0Kを下回るとΔp1パルス閉弁し、また前記過熱度が0Kとsh1Kの間にあれば現状のパルスを保持し、前記過熱度がsh1Kを超えればΔp2パルス開弁する(S102)。このとき補正後のパルスが上下限パルス設定値と比較し、前記設定範囲を超えたら補正パルスを上限または下限パルスとする(S104)。ここで膨張弁の開度と熱交過熱度の関係を図8’に示す。弁開度が小さいときは1パルス当りの過熱度変化が大きいが、弁開度が大きい場合は1パルス当りの過熱度変化は小さく同じ過熱度が0Kであっても、弁開度を絞り過ぎると、低圧が下がりひいては凍結防止制御で圧縮機が停止する確率が高くなり返って不快感を増幅させる。そこで室温が第1の設定値を下回ったら、冷房能力を抑えるために、例え前記過熱度が0Kを下回っていても膨張弁パルスを変化させない(S103)。しかも室外圧縮機周波数がΔHz以上変化すると室外より初期パルス信号を受信し、一旦初期パルスに戻す(S105)がこのとき初期パルスは当初のパルスではなく異なるΔD領域での初期パルスに戻って再び過熱度制御を継続ことにより最適な冷凍サイクルを維持し、性能を最大限に引き出すことができる。 After the start-up control is completed in the cooling or dehumidifying operation, when the expansion valve shifts to the normal control, ΔT is detected from the form and horsepower of the indoor unit, and the room temperature and the set temperature. If ΔT is less than T1, the first initial pulse, ΔT Is set as the second initial pulse if ΔT is between T1 and T2, and as the third initial pulse if ΔT exceeds T2 (S101), the expansion valve opens or closes to the pulse and starts here. Transition to superheat control. That is, every 30 seconds, the degree of superheat is calculated from the indoor heat exchange temperature and the heat exchange outlet temperature. When the degree of superheat falls below 0K, Δp1 pulse is closed, and if the degree of superheat is between 0K and sh1K, If the pulse is held and the superheat degree exceeds sh1K, the Δp2 pulse is opened (S102). At this time, the corrected pulse is compared with the upper / lower limit pulse set value, and if it exceeds the set range, the corrected pulse is set to the upper limit or lower limit pulse (S104). Here, the relationship between the opening of the expansion valve and the degree of heat exchange superheat is shown in FIG. When the valve opening is small, the change in superheat per pulse is large. However, when the valve opening is large, the change in superheat per pulse is small and the valve opening is too narrow even if the same superheat is 0K. As a result, the low pressure drops and the anti-freezing control increases the probability that the compressor will stop, increasing the discomfort. Therefore, if the room temperature falls below the first set value, the expansion valve pulse is not changed even if the superheat degree is below 0K in order to suppress the cooling capacity (S103). In addition, when the outdoor compressor frequency changes by ΔHz or more, an initial pulse signal is received from the outside and once returned to the initial pulse (S105). At this time, the initial pulse returns to the initial pulse in a different ΔD region instead of the initial pulse, and is overheated again. By maintaining the degree control, the optimum refrigeration cycle can be maintained and the performance can be maximized.
(実施の形態2)
次に第9図フローチャート及び第10図のタイムチャートにより、本発明の第2の実施の形態について説明する。
(Embodiment 2)
Next, a second embodiment of the present invention will be described with reference to the flowchart of FIG. 9 and the time chart of FIG.
冷房または除湿運転で起動制御終了後、膨張弁は通常制御に移行すると室内機の形態及び馬力、さらに室温及び設定温度からΔTを検知してΔTがT1未満であれば第1の初期パルス、ΔTがT1とT2の間にあれば第2の初期パルス、ΔTがT2を超えれば第3の初期パルスとして設定し(S201)、膨張弁は前記パルスまで開弁あるいは閉弁しここを開始点として過熱度制御に移行する。すなわち30秒毎に室内熱交温度及び熱交出口温度から過熱度を算出し、前記過熱度が0Kを下回るとΔp1パルス閉弁し、また前記過熱度が0Kとsh1Kの間にあれば現状のパルスを保持し、前記過熱度がsh1Kを超えればΔp2パルス開弁する(S202)。このとき補正後のパルスが上下限パルス設定値と比較し、前記設定範囲を超えたら補正パルスを上限または下限パルスとする(S204)。また前記熱交温度が設定値DT00℃を下回ったら凍結防止制御により圧縮機は停止し、返って不快感を増幅させてしまうので、圧縮機は連続運転可能なように、前記熱交温度が第2の設定値を下回ったら例え前記過熱度が0Kを下回っていても膨張弁パルスを変化させない(S203)。しかも室外圧縮機周波数がΔHz以上変化すると室外より初期パルス信号を受信し、一旦初期パルスに戻す(S205)がこのとき初期パルスは当初のパルスではなく異なるΔD領域での初期パルスに戻って再び過熱度制御を継続することにより最適な冷凍サイクルを維持し、性能を最大限に引き出すことができる。 After the start-up control is completed in the cooling or dehumidifying operation, when the expansion valve shifts to the normal control, ΔT is detected from the form and horsepower of the indoor unit, and the room temperature and the set temperature. If ΔT is less than T1, the first initial pulse, ΔT Is set as the second initial pulse if ΔT is between T1 and T2, and as the third initial pulse if ΔT exceeds T2 (S201), the expansion valve opens or closes to the pulse and starts here. Transition to superheat control. That is, the degree of superheat is calculated from the indoor heat exchange temperature and the heat exchange outlet temperature every 30 seconds. When the superheat degree falls below 0K, the Δp1 pulse is closed, and if the superheat degree is between 0K and sh1K, If the pulse is held and the superheat degree exceeds sh1K, the Δp2 pulse is opened (S202). At this time, the corrected pulse is compared with the upper / lower limit pulse set value, and if it exceeds the set range, the corrected pulse is set to the upper limit or lower limit pulse (S204). When the heat exchange temperature falls below the set value DT00 ° C., the compressor is stopped by anti-freezing control and returns to amplify discomfort, so that the heat exchange temperature is set so that the compressor can be continuously operated. If it falls below the set value of 2, even if the degree of superheat is below 0K, the expansion valve pulse is not changed (S203). In addition, when the outdoor compressor frequency changes by ΔHz or more, an initial pulse signal is received from the outdoor and once returned to the initial pulse (S205). At this time, the initial pulse returns to the initial pulse in a different ΔD region instead of the initial pulse and is overheated again. By maintaining the degree control, the optimum refrigeration cycle can be maintained and the performance can be maximized.
(実施の形態3)
次に第11図フローチャート及び第12図のタイムチャートにより、本発明の第3の実施の形態について説明する。
(Embodiment 3)
Next, a third embodiment of the present invention will be described with reference to the flowchart of FIG. 11 and the time chart of FIG.
冷房または除湿運転で起動制御終了後、膨張弁は通常制御に移行すると室内機の形態及び馬力、さらに室温及び設定温度からΔTを検知してΔTがT1未満であれば第1の初期パルス、ΔTがT1とT2の間にあれば第2の初期パルス、ΔTがT2を超えれば第3の初期パルスとして設定し(S301)、膨張弁は前記パルスまで開弁あるいは閉弁しここを開始点として過熱度制御に移行する。すなわち30秒毎に室内熱交温度及び熱交出口温度から過熱度を算出し、前記過熱度が0Kを下回るとΔp1パルス閉弁し、また前記過熱度が0Kとsh1Kの間にあれば現状のパルスを保持し、前記過熱度がsh1Kを超えればΔp2パルス開弁する(S302)。このとき補正後のパルスが上下限パルス設定値と比較し、前記設定範囲を超えたら補正パルスを上限または下限パルスとする(S304)。しかし室温が第3の設定値を上回ったら例え膨張弁パルスが上限パルスまで到達していても、第2の上限値を設け、引続き継続して開弁することにより、過熱度を低減し大きくなり過ぎるのを防ぐことができる(S303)。しかも室外圧縮機周波数がΔHz以上変化すると室外より初期パルス信号を受信し、一旦初期パルスに戻す(S305)がこのとき初期パルスは当初のパルスではなく異なるΔD領域での初期パルスに戻って再び過熱度制御を継続することにより最適な冷凍サイクルを維持し、性能を最大限に引き出すことができる。 After the start-up control is completed in the cooling or dehumidifying operation, when the expansion valve shifts to the normal control, ΔT is detected from the form and horsepower of the indoor unit, and the room temperature and the set temperature. If ΔT is less than T1, the first initial pulse, ΔT Is set as the second initial pulse if ΔT is between T1 and T2, and as the third initial pulse if ΔT exceeds T2 (S301), the expansion valve opens or closes to the pulse and starts here. Transition to superheat control. That is, the degree of superheat is calculated from the indoor heat exchange temperature and the heat exchange outlet temperature every 30 seconds. When the superheat degree falls below 0K, the Δp1 pulse is closed, and if the superheat degree is between 0K and sh1K, If the pulse is held and the superheat degree exceeds sh1K, the Δp2 pulse is opened (S302). At this time, the corrected pulse is compared with the upper / lower limit pulse set value, and if it exceeds the set range, the corrected pulse is set to the upper limit or lower limit pulse (S304). However, if the room temperature exceeds the third set value, even if the expansion valve pulse has reached the upper limit pulse, the second upper limit value is provided and the valve is continuously opened to reduce the degree of superheat and increase. This can be prevented (S303). In addition, when the outdoor compressor frequency changes by ΔHz or more, an initial pulse signal is received from the outdoor and once returned to the initial pulse (S305). At this time, the initial pulse returns to the initial pulse in a different ΔD region instead of the initial pulse and is overheated again. By maintaining the degree control, the optimum refrigeration cycle can be maintained and the performance can be maximized.
(実施の形態4)
次に第13図フローチャート及び第14図のタイムチャートにより、本発明の第4の実施の形態について説明する。
(Embodiment 4)
Next, a fourth embodiment of the present invention will be described with reference to the flowchart of FIG. 13 and the time chart of FIG.
冷房または除湿運転で起動制御終了後、膨張弁は通常制御に移行すると室内機の形態及び馬力、さらに室温及び設定温度からΔTを検知してΔTがT1未満であれば第1の初期パルス、ΔTがT1とT2の間にあれば第2の初期パルス、ΔTがT2を超えれば第3の初期パルスとして設定し(S401)、膨張弁は前記パルスまで開弁あるいは閉弁しここを開始点として過熱度制御に移行する。すなわち30秒毎に室内熱交温度及び熱交出口温度から過熱度を算出し、前記過熱度が0Kを下回るとΔp1パルス閉弁し、また前記過熱度が0Kとsh1Kの間にあれば現状のパルスを保持し、前記過熱度がsh1Kを超えればΔp2パルス開弁する(S402)。このとき補正後のパルスが上下限パルス設定値と比較し、前記設定範囲を超えたら補正パルスを上限または下限パルスとする(S404)。このとき現在の室温と10分前の室温を比較して差が第4の設定値以下であれば、室温は設定温度に達したと判断し、例え過熱度が0Kを下回っていても膨張弁パルスを変化させない(S403)。しかも室外圧縮機周波数がΔHz以上変化すると室外より初期パルス信号を受信し、一旦初期パルスに戻す(S405)がこのとき初期パルスは当初のパルスではなく異なるΔD領域での初期パルスに戻って再び過熱度制御を継続することにより最適な冷凍サイクルを維持し、性能を最大限に引き出すことができる。
After the start-up control is completed in the cooling or dehumidifying operation, when the expansion valve shifts to the normal control, ΔT is detected from the form and horsepower of the indoor unit, and the room temperature and the set temperature. If ΔT is less than T1, the first initial pulse, ΔT If T is between T1 and T2, the second initial pulse is set. If ΔT exceeds T2, the third initial pulse is set (S401). The expansion valve opens or closes to the pulse and starts from here. Transition to superheat control. That is, the degree of superheat is calculated from the indoor heat exchange temperature and the heat exchange outlet temperature every 30 seconds. When the superheat degree falls below 0K, the Δp1 pulse is closed, and if the superheat degree is between 0K and sh1K, If the pulse is held and the superheat degree exceeds sh1K, the Δp2 pulse is opened (S402). At this time, the corrected pulse is compared with the upper / lower limit pulse set value, and if it exceeds the set range, the corrected pulse is set to the upper limit or lower limit pulse (S404). At this time, if the difference between the current room temperature and the
1圧縮機
2 室内熱交換器
3室内送風機
4室外膨張弁
5室外熱交換器
6室外送風機
7 4方弁
8 室内吸込み温度センサー
9 室内熱交温度センサー
10 室内熱交出口温度センサー
1
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
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JP2009250479A (en) * | 2008-04-03 | 2009-10-29 | Sharp Corp | Air conditioner |
CN108981101A (en) * | 2018-06-28 | 2018-12-11 | 珠海格力电器股份有限公司 | A kind of control method of electric expansion valve, control device and a kind of unit |
CN113375301A (en) * | 2020-12-11 | 2021-09-10 | 珠海格力电器股份有限公司 | Air conditioner control method and device, storage medium and air conditioner |
CN115789908A (en) * | 2022-11-15 | 2023-03-14 | 宁波奥克斯电气股份有限公司 | Expansion valve opening degree control method and device of air conditioner and multi-connected air conditioner |
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Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
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JP2009250479A (en) * | 2008-04-03 | 2009-10-29 | Sharp Corp | Air conditioner |
CN108981101A (en) * | 2018-06-28 | 2018-12-11 | 珠海格力电器股份有限公司 | A kind of control method of electric expansion valve, control device and a kind of unit |
CN108981101B (en) * | 2018-06-28 | 2020-06-05 | 珠海格力电器股份有限公司 | Control method and control device of electronic expansion valve and unit |
CN113375301A (en) * | 2020-12-11 | 2021-09-10 | 珠海格力电器股份有限公司 | Air conditioner control method and device, storage medium and air conditioner |
CN113375301B (en) * | 2020-12-11 | 2022-04-12 | 珠海格力电器股份有限公司 | Air conditioner control method and device, storage medium and air conditioner |
CN115789908A (en) * | 2022-11-15 | 2023-03-14 | 宁波奥克斯电气股份有限公司 | Expansion valve opening degree control method and device of air conditioner and multi-connected air conditioner |
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