TW201522873A - Apparatus with dehumidification and defrosting ability and controlling method thereof - Google Patents
Apparatus with dehumidification and defrosting ability and controlling method thereof Download PDFInfo
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- TW201522873A TW201522873A TW102144882A TW102144882A TW201522873A TW 201522873 A TW201522873 A TW 201522873A TW 102144882 A TW102144882 A TW 102144882A TW 102144882 A TW102144882 A TW 102144882A TW 201522873 A TW201522873 A TW 201522873A
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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
- F25B47/00—Arrangements for preventing or removing deposits or corrosion, not provided for in another subclass
- F25B47/02—Defrosting cycles
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/89—Arrangement or mounting of control or safety devices
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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
- F25B13/00—Compression machines, plants or systems, with reversible cycle
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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
- F25B41/00—Fluid-circulation arrangements
- F25B41/20—Disposition of valves, e.g. of on-off valves or flow control valves
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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
- F25B41/00—Fluid-circulation arrangements
- F25B41/30—Expansion means; Dispositions thereof
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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
- F25B49/00—Arrangement or mounting of control or safety devices
- F25B49/02—Arrangement or mounting of control or safety devices for compression type machines, plants or systems
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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
- F25B2313/00—Compression machines, plants or systems with reversible cycle not otherwise provided for
- F25B2313/027—Compression machines, plants or systems with reversible cycle not otherwise provided for characterised by the reversing means
- F25B2313/02741—Compression machines, plants or systems with reversible cycle not otherwise provided for characterised by the reversing means using one four-way valve
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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
- F25B2347/00—Details for preventing or removing deposits or corrosion
- F25B2347/02—Details of defrosting cycles
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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
- F25B2347/00—Details for preventing or removing deposits or corrosion
- F25B2347/02—Details of defrosting cycles
- F25B2347/022—Cool gas defrosting
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Physics & Mathematics (AREA)
- Thermal Sciences (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Air Conditioning Control Device (AREA)
- Compression-Type Refrigeration Machines With Reversible Cycles (AREA)
Abstract
Description
一種具除濕與除霜功能之裝置及其控制方法,尤指一種能夠除濕不升溫或除霜不降溫的裝置及其控制方法。 A device with dehumidification and defrosting function and a control method thereof, in particular to a device capable of dehumidifying without heating or defrosting without cooling and a control method thereof.
空調系統,其係廣泛地於人們日常生活中被應用,現有的空調系統約略能夠提供冷氣、除濕、除霜與暖氣等功效,該些功效係應用冷媒循環回路所達成。 The air conditioning system is widely used in people's daily life. The existing air conditioning system can provide air conditioning, dehumidification, defrosting and heating functions, which are achieved by applying a refrigerant circulation circuit.
現有的冷媒循環回路僅具有膨脹回路之功能,當冷媒循環回路於進行冷氣除濕時,其會造成室內溫度忽高忽低,而造成位於室內的人們的不舒適。另外,當冷媒循環回路於進行暖氣除霜時,其會造成暖氣溫度不足與除霜不完全的現象。 The existing refrigerant circulation circuit only has the function of an expansion circuit. When the refrigerant circulation circuit performs cold air dehumidification, it will cause the indoor temperature to fluctuate and fall, which causes people in the room to be uncomfortable. In addition, when the refrigerant circulation circuit performs defrosting of the heating, it may cause insufficient heating temperature and incomplete defrosting.
如上所述,如何使現有的冷媒循環回路能夠於進行冷氣除濕時,提供一具有穩定溫度的冷氣,或者進行暖氣除霜時,提供足夠溫度的暖氣與完全除霜,其係成為現有的冷媒循環回路仍待改善的空間。 As described above, how to make the existing refrigerant circulation circuit capable of providing cold air with a stable temperature when performing cold air dehumidification, or providing sufficient temperature heating and complete defrosting when performing heating defrosting, which is an existing refrigerant circulation The loop still has room for improvement.
本發明係提供一種具除濕與除霜功能之裝置,其包含有一壓縮機、一室內熱交換器、一室外熱交換器與一四方閥;該壓縮機係耦接該四方閥,該四方閥係耦接該室外熱交換器,該室內熱交換器係耦接該室內熱交換器,該室內熱交換器係耦接該四方閥,其特徵在於:一冷媒控流機構,其係分別耦接該室內熱交換器、該室外熱交換器與該四方閥,以控制一低溫冷媒與一高溫冷媒於流入該室內熱交換器前進行混合,或者一低溫冷媒與一高溫冷媒於流入該 壓縮機前進行混合,或者一低溫冷媒與一高溫冷媒於流入該室外熱交換器前進行混合。 The invention provides a device with dehumidification and defrosting function, comprising a compressor, an indoor heat exchanger, an outdoor heat exchanger and a square valve; the compressor is coupled to the square valve, the square valve The indoor heat exchanger is coupled to the indoor heat exchanger, and the indoor heat exchanger is coupled to the square valve, wherein a refrigerant flow control mechanism is coupled The indoor heat exchanger, the outdoor heat exchanger and the square valve control a low temperature refrigerant and a high temperature refrigerant to be mixed before flowing into the indoor heat exchanger, or a low temperature refrigerant and a high temperature refrigerant flow into the Mixing is performed before the compressor, or a low temperature refrigerant and a high temperature refrigerant are mixed before flowing into the outdoor heat exchanger.
本發明係提供一種除濕的控制方法,其包含有:一室內溫度大於一第一溫度,一低溫冷媒會與一高溫冷媒混合,以形成一中溫冷媒,該中溫冷媒係流入一室內熱交換器。 The invention provides a dehumidification control method, which comprises: a room temperature greater than a first temperature, a low temperature refrigerant mixed with a high temperature refrigerant to form a medium temperature refrigerant, the medium temperature refrigerant flowing into an indoor heat exchange Device.
本發明係提供一種除霜的控制方法,其包含有:一室外溫度小於一第二溫度時,一低溫冷媒會與一高溫冷媒混合,以形成一中溫冷媒,該中溫冷媒係流入一室外熱交換器。 The invention provides a method for controlling defrosting, which comprises: when an outdoor temperature is lower than a second temperature, a low temperature refrigerant is mixed with a high temperature refrigerant to form a medium temperature refrigerant, and the medium temperature refrigerant flows into an outdoor Heat exchanger.
10‧‧‧壓縮機 10‧‧‧Compressor
11‧‧‧四方閥 11‧‧‧tetragonal valve
12‧‧‧室內熱交換器 12‧‧‧ indoor heat exchanger
13‧‧‧冷媒控流機構 13‧‧‧Refrigerant flow control mechanism
130‧‧‧第一膨脹閥 130‧‧‧First expansion valve
131‧‧‧第二膨脹閥 131‧‧‧Second expansion valve
132‧‧‧第三膨脹閥 132‧‧‧third expansion valve
14‧‧‧室外熱交換器 14‧‧‧Outdoor heat exchanger
15‧‧‧第一感知器 15‧‧‧First Sensor
16‧‧‧第二感知器 16‧‧‧Second sensor
17‧‧‧室外溫度感知器 17‧‧‧Outdoor temperature sensor
18‧‧‧室內溫度感知器 18‧‧‧Indoor temperature sensor
20‧‧‧第一管體 20‧‧‧First tube
21‧‧‧第二管體 21‧‧‧Second body
22‧‧‧第三管體 22‧‧‧3rd body
23‧‧‧第四管體 23‧‧‧Fourth body
24‧‧‧第五管體 24‧‧‧ fifth body
25‧‧‧第六管體 25‧‧‧6th body
26‧‧‧第七管體 26‧‧‧ seventh tube
27‧‧‧第八管體 27‧‧‧8th tube
270‧‧‧第一位置 270‧‧‧ first position
271‧‧‧第二位置 271‧‧‧ second position
28‧‧‧閥體 28‧‧‧ valve body
A~F‧‧‧曲線 A~F‧‧‧ Curve
圖1為本發明之一種具除濕與除霜功能之裝置之第一實施例於一冷氣運運轉模式之示意圖。 1 is a schematic view showing a first embodiment of a device having a dehumidifying and defrosting function according to the present invention in a cold air operation mode.
圖2為本發明之具除濕與除霜功能之裝置之第一實施例於一暖氣運運轉模式之示意圖。 2 is a schematic view showing a first embodiment of the apparatus for dehumidifying and defrosting according to the present invention in a heating operation mode.
圖3為本發明之具除濕與除霜功能之裝置之第二實施例於一冷氣運運轉模式之示意圖。 3 is a schematic view showing a second embodiment of the apparatus for dehumidifying and defrosting according to the present invention in a cold air operation mode.
圖4為本發明之具除濕與除霜功能之裝置之第二實施例於一暖氣運運轉模式之示意圖。 4 is a schematic view showing a second embodiment of the apparatus for dehumidifying and defrosting according to the present invention in a heating operation mode.
圖5為本發明於暖氣運運轉模式之時間與室外溫度對比圖。 Fig. 5 is a comparison diagram of time and outdoor temperature in the heating and running mode of the present invention.
圖6為本發明於冷氣運運轉模式之時間與室內溫度對比圖。 Figure 6 is a comparison of the time of the cold air operation mode and the indoor temperature of the present invention.
以下係藉由特定的具體實施例說明本發明之實施方式,所屬技術領域中具有通常知識者可由本說明書所揭示之內容,輕易地瞭解本發明之其他優點與功效。 The embodiments of the present invention are described below by way of specific embodiments, and those skilled in the art can readily understand the other advantages and advantages of the present invention.
請配合參考圖1所示,本發明係一種具除濕與除霜功能之裝置之第一實施例,其具有一壓縮機10、一四方閥11、一室內熱交換器12、一冷媒控流機構13、一室外熱交換器14、一第一感知器15、一第二感知器16、一室外溫度感知器17、一室內溫度感知器18、一第一管體20、一第二管體21、一第三管體22、一第四管體23、一第五管體24、一第六管體25、一第七管體26與一第八管體27。 Referring to FIG. 1 , the present invention is a first embodiment of a device having a dehumidifying and defrosting function, comprising a compressor 10 , a square valve 11 , an indoor heat exchanger 12 , and a refrigerant control flow . The mechanism 13 , an outdoor heat exchanger 14 , a first sensor 15 , a second sensor 16 , an outdoor temperature sensor 17 , an indoor temperature sensor 18 , a first tube 20 , and a second tube 21. A third tubular body 22, a fourth tubular body 23, a fifth tubular body 24, a sixth tubular body 25, a seventh tubular body 26 and an eighth tubular body 27.
壓縮機10係以第四管體23耦接四方閥11。 The compressor 10 is coupled to the square valve 11 by a fourth pipe body 23.
四方閥11係以第五管體24耦接室外熱交換器14,該室外熱交換器14能夠為一冷凝蒸發器或一蒸發器。 The four-way valve 11 is coupled to the outdoor heat exchanger 14 by a fifth pipe body 24, which can be a condensing evaporator or an evaporator.
室外熱交換器14係以第六管體25耦接冷媒控流機構13。冷媒控流機構13具有一第一膨脹閥130、一第二膨脹閥131與一第三膨脹閥132。 The outdoor heat exchanger 14 is coupled to the refrigerant flow control mechanism 13 by a sixth pipe body 25. The refrigerant flow control mechanism 13 has a first expansion valve 130, a second expansion valve 131 and a third expansion valve 132.
上述之第六管體25係分別耦接遞第一膨脹閥130與第二膨脹閥131。 The sixth pipe body 25 is coupled to the first expansion valve 130 and the second expansion valve 131 respectively.
第二感知器16係設於第六管體25與第二膨脹閥131之間。 The second sensor 16 is disposed between the sixth tube body 25 and the second expansion valve 131.
冷媒控流機構13(Means for Refrigerant Flow Controlling)係以第一管體20耦接室內熱交換器12,若更進一步說明,第二膨脹閥131與第三膨脹閥132係以第一管體20耦接室內熱交換器12。該室內熱交換器12能夠為一蒸發器或一冷凝器。若室內熱交換器12為一蒸發器,則室外熱交換器14則為一冷凝器。反之,若室內熱交換器12為一冷凝器,則室外熱交換器14為一蒸發器。 The first tube body 20 is coupled to the indoor heat exchanger 12, and the second expansion valve 131 and the third expansion valve 132 are connected to the first tube body 20, as further described. The indoor heat exchanger 12 is coupled. The indoor heat exchanger 12 can be an evaporator or a condenser. If the indoor heat exchanger 12 is an evaporator, the outdoor heat exchanger 14 is a condenser. On the other hand, if the indoor heat exchanger 12 is a condenser, the outdoor heat exchanger 14 is an evaporator.
第三膨脹閥132係以第八管體27耦接第五管體24,第八管體27更進一步繞設於壓縮機10的外側。 The third expansion valve 132 is coupled to the fifth pipe body 24 by the eighth pipe body 27, and the eighth pipe body 27 is further wound around the outside of the compressor 10.
第一感知器15係設於第一管體20與第二膨脹閥131之間。 The first sensor 15 is disposed between the first tube body 20 and the second expansion valve 131.
室內熱交換器12係以第二管體21耦接四方閥11。四方閥11更進一步以第三管體22耦接壓縮機10。 The indoor heat exchanger 12 is coupled to the square valve 11 by the second pipe body 21. The square valve 11 is further coupled to the compressor 10 with a third tubular body 22.
室外溫度感知器17係設於室外熱交換器14。 The outdoor temperature sensor 17 is provided in the outdoor heat exchanger 14.
室內溫度感知器18係設於室內熱交換器12。 The indoor temperature sensor 18 is provided in the indoor heat exchanger 12.
請再配合參考圖1所示,若本發明係進行一冷氣運轉模式,壓縮機10將冷媒壓縮後吐出。冷媒係經過四方閥11與第五管體24進入室外熱交換器14。該壓縮機10所吐出之冷媒係為一高溫高壓之冷媒。 Referring to FIG. 1 again, if the present invention performs a cool air operation mode, the compressor 10 compresses the refrigerant and discharges it. The refrigerant enters the outdoor heat exchanger 14 through the square valve 11 and the fifth pipe body 24. The refrigerant discharged from the compressor 10 is a high temperature and high pressure refrigerant.
冷媒於室外熱交換器14進行一散熱的動作,以形成一低溫冷媒,該低溫冷媒會經由第六管體25分別進入第一膨脹閥130與第二膨脹閥131。該低溫冷媒係為一低溫高壓之冷媒。 The refrigerant heats the outdoor heat exchanger 14 to form a low-temperature refrigerant that enters the first expansion valve 130 and the second expansion valve 131 via the sixth pipe body 25, respectively. The low temperature refrigerant is a low temperature and high pressure refrigerant.
該低溫冷媒會於第二膨脹閥131中進行膨脹的動作,以形成 一低溫低壓之冷媒。該低溫低壓之低溫冷媒會經由第一管體20進入室內熱交換器12,以進行一吸熱的動作,藉此將一冷氣提供給一室內,經過吸熱的低溫低壓係形成為一高溫低壓冷媒。 The low temperature refrigerant is expanded in the second expansion valve 131 to form A low temperature low pressure refrigerant. The low-temperature low-pressure low-temperature refrigerant enters the indoor heat exchanger 12 via the first pipe body 20 to perform an endothermic action, thereby supplying a cold air to a room, and the low-temperature low-pressure system through the heat absorption is formed into a high-temperature low-pressure refrigerant.
該高溫冷媒係由第二管體21流入四方閥11,再由第三管體22流入壓縮機10中,以再進行壓縮冷媒之動作,以形成一高溫高壓之冷媒。 The high-temperature refrigerant flows into the square valve 11 from the second pipe body 21, and then flows into the compressor 10 from the third pipe body 22 to further compress the refrigerant to form a high-temperature high-pressure refrigerant.
假若本發明之裝置因負載變化或室外環境變化,而處於一種不平衡的狀態時,前述之第一膨脹閥130就會開啟,以供低溫高壓冷媒進行膨脹,經過膨脹的低溫低壓冷媒會由第七管體26流入第二管體21,並與來自室內熱交換器12的高溫低壓冷媒混合,以形成一中溫低壓冷媒,該中溫低壓冷媒係流入四方閥11,再由由第三管體22流入壓縮機10中,以再進行壓縮冷媒之動作。藉由兩種溫度與壓力的冷媒進行混合,以到該裝置呈現一平衡的狀態。該中溫低壓之低壓係大於該高溫低壓之低壓。第一膨脹閥130的開度係取決於該裝置所需達到平衡的程度,若該裝置所欲達到之平衡程度越大時,則第一膨脹閥130的開度越大。反之,假若該裝置所欲達到之平衡程度越小時,則第一膨脹閥130的開度越小。 If the device of the present invention is in an unbalanced state due to load changes or changes in the outdoor environment, the aforementioned first expansion valve 130 is opened for the low temperature and high pressure refrigerant to expand, and the expanded low temperature and low pressure refrigerant will be The seven pipe body 26 flows into the second pipe body 21 and is mixed with the high temperature and low pressure refrigerant from the indoor heat exchanger 12 to form a medium temperature low pressure refrigerant, which flows into the square valve 11 and then from the third pipe. The body 22 flows into the compressor 10 to perform the operation of compressing the refrigerant. The two devices are mixed with a temperature of pressure to bring the device to a balanced state. The low temperature of the medium temperature and low pressure is greater than the low pressure of the high temperature and low pressure. The degree of opening of the first expansion valve 130 depends on the degree to which the device needs to be balanced, and the greater the degree of balance desired by the device, the greater the opening of the first expansion valve 130. On the other hand, if the degree of balance desired by the device is small, the opening degree of the first expansion valve 130 is smaller.
若第二感知器16與室內溫度感知器18感測出室內應進行一除濕的動作時,第三膨脹閥132就會開啟,一冷媒會由第八管體27流入第五管體24,位於第八管體27的冷媒會被壓縮機10提昇至一特定溫度,以形成一高溫高壓冷媒,再進入第三膨脹閥132中膨脹,以形成一高溫低壓之冷媒,位於第八管體27之高溫高壓之冷媒的高溫係大於位於第五管體24之高溫高壓之冷媒的高溫。該高溫低壓之冷媒會流入第一管體20,並與來自第二膨脹閥131的低溫低壓之冷媒進行混合,以形成一中溫低壓冷媒,再進入室內熱交換器12中,以進行一熱交換,故可使室內溫度能夠維持於穩定,並能達到除濕的效果。來自第三膨脹閥132之高溫低壓之冷媒的低壓係大於來自第二膨脹閥131的低溫低壓之冷媒的低壓。該第三膨脹閥132的開度係取決於該裝置所需達到除濕的程 度,若該裝置所欲達到之除濕程度越大時,則第三膨脹閥132的開度越大。反之,假若該裝置所欲達到之除濕程度越小時,則第三膨脹閥132的開度越小。 If the second sensor 16 and the indoor temperature sensor 18 sense that the room should perform a dehumidification operation, the third expansion valve 132 is opened, and a refrigerant flows from the eighth pipe body 27 into the fifth pipe body 24, which is located. The refrigerant of the eighth pipe body 27 is lifted by the compressor 10 to a specific temperature to form a high temperature and high pressure refrigerant, and then expanded into the third expansion valve 132 to form a high temperature and low pressure refrigerant, which is located in the eighth pipe body 27. The high temperature and high pressure refrigerant has a higher temperature than the high temperature and high pressure refrigerant of the fifth tube body 24. The high temperature and low pressure refrigerant flows into the first pipe body 20 and is mixed with the low temperature and low pressure refrigerant from the second expansion valve 131 to form a medium temperature low pressure refrigerant, and then enters the indoor heat exchanger 12 to perform a heat. Exchange, so that the indoor temperature can be maintained stable, and can achieve the effect of dehumidification. The low pressure of the high temperature and low pressure refrigerant from the third expansion valve 132 is greater than the low pressure of the low temperature and low pressure refrigerant from the second expansion valve 131. The opening degree of the third expansion valve 132 depends on the degree of dehumidification required by the device. The degree of opening of the third expansion valve 132 is greater if the degree of dehumidification desired by the device is greater. On the other hand, if the degree of dehumidification desired by the apparatus is small, the opening degree of the third expansion valve 132 is smaller.
請配合參考圖2所示,若本發明進行一暖氣模式運轉,壓縮機10係將一高溫高壓之冷媒吐出。該高溫高壓之冷媒係經過第四管體23進入四方閥11,再由第二管體21進入室內熱交換器12,以進行一放熱的動作,藉此提供一暖氣給室內。經過放熱的該高溫高壓之冷媒係形成為一低溫高壓之冷媒。 Referring to FIG. 2, if the present invention performs a heating mode operation, the compressor 10 discharges a high temperature and high pressure refrigerant. The high-temperature high-pressure refrigerant enters the square valve 11 through the fourth pipe body 23, and then enters the indoor heat exchanger 12 from the second pipe body 21 to perform a heat release operation, thereby providing a heating to the room. The exothermic high temperature and high pressure refrigerant is formed into a low temperature and high pressure refrigerant.
該低溫高壓之冷媒會由第一管體20流入第二膨脹閥131與第三膨脹閥132。該低溫高壓之冷媒係於第二膨脹閥131進行一膨脹的動作,以形成一低溫低壓之冷媒,該低溫低溫冷媒係由第六管體25流入室外熱交換器14,以進行一吸熱的動作,以形成為一高溫低壓冷媒,再由第五管體24流入四方閥11,並由第三管體22流入壓縮機10中,以進行一壓縮冷媒的動作,以形成一高溫高壓之冷媒。 The low-temperature high-pressure refrigerant flows into the second expansion valve 131 and the third expansion valve 132 from the first pipe body 20. The low-temperature high-pressure refrigerant is subjected to an expansion operation by the second expansion valve 131 to form a low-temperature low-pressure refrigerant that flows from the sixth pipe body 25 into the outdoor heat exchanger 14 to perform an endothermic action. In order to form a high temperature and low pressure refrigerant, the fifth pipe body 24 flows into the square valve 11 and flows into the compressor 10 from the third pipe body 22 to perform a compression refrigerant operation to form a high temperature and high pressure refrigerant.
若本發明欲進行一平衡時,第三膨脹閥132就會開啟,來自第一管體20的低溫高壓之冷媒就會進入第三膨脹閥132,以進行一膨脹的動作,以形成一低溫低壓之冷媒。來自第三膨脹閥132之低溫低壓之冷媒的低壓係大於來自第一膨脹閥131之低溫低壓之冷媒的低壓。 If the present invention is to perform an equilibrium, the third expansion valve 132 is opened, and the low-temperature high-pressure refrigerant from the first pipe body 20 enters the third expansion valve 132 to perform an expansion operation to form a low-temperature low pressure. The refrigerant. The low pressure of the low temperature and low pressure refrigerant from the third expansion valve 132 is greater than the low pressure of the low temperature and low pressure refrigerant from the first expansion valve 131.
來自第三膨脹閥132之低溫低壓之冷媒會由第八管體27進入第五管體24。位於第八管體27的低溫冷媒會被壓縮機10提昇至一特定的溫度,以形成為一高溫低壓之冷媒。該高溫低壓之冷媒之高溫係低於位於第五管體24之高溫低壓之冷媒的高溫。 The low temperature and low pressure refrigerant from the third expansion valve 132 enters the fifth pipe body 24 from the eighth pipe body 27. The low temperature refrigerant located in the eighth pipe body 27 is lifted by the compressor 10 to a specific temperature to form a high temperature and low pressure refrigerant. The high temperature and low pressure refrigerant has a higher temperature than the high temperature and low pressure refrigerant of the fifth tube body 24.
因室外熱交換器14可能處於一種結霜的情況,故原先進入室外交換器14的低溫低壓之冷媒係無法吸熱,而形成高溫低壓之冷媒,反而釋出更多的熱能,並形成更為低溫的低溫低壓之冷媒,若該低溫低壓之冷媒直接流入壓縮機10中,則有可能造成液壓縮的情況。 Because the outdoor heat exchanger 14 may be in a frosting condition, the low temperature and low pressure refrigerant originally entering the outdoor exchanger 14 cannot absorb heat, and the high temperature and low pressure refrigerant is formed, which in turn releases more heat energy and forms a lower temperature. The low-temperature low-pressure refrigerant may cause liquid compression if the low-temperature low-pressure refrigerant directly flows into the compressor 10.
所以來自第八管體27的高溫低壓之冷媒與上述之低溫低壓之 冷媒係於第五管體24中混合,以形成為一中溫低壓之冷媒,該高溫低壓之冷媒的低壓係大於該中溫低壓之冷媒的低壓。該中溫低壓之冷媒係經由四方閥11與第三管體22,再流入壓縮機10中,以避免該冷媒發生液壓縮的現象,並能使本發明達到一平衡的效果。 Therefore, the high temperature and low pressure refrigerant from the eighth pipe body 27 and the above low temperature and low pressure The refrigerant is mixed in the fifth pipe body 24 to form a medium temperature and low pressure refrigerant, and the low pressure of the high temperature and low pressure refrigerant is greater than the low pressure of the medium temperature and low pressure refrigerant. The medium-temperature low-pressure refrigerant flows into the compressor 10 via the square valve 11 and the third pipe body 22 to prevent the refrigerant from being compressed, and the present invention achieves a balanced effect.
該第三膨脹閥132的開度係取決於該裝置所需達到平衡的程度,若該裝置所欲達到之平衡程度越大時,則第三膨脹閥132的開度越大。反之,假若該裝置所欲達到之平衡程度越小時,則第三膨脹閥132的開度越小。 The opening degree of the third expansion valve 132 depends on the degree to which the device needs to reach equilibrium. If the degree of balance desired by the device is greater, the opening degree of the third expansion valve 132 is larger. On the other hand, if the degree of balance desired by the device is small, the opening degree of the third expansion valve 132 is smaller.
若室外溫度感知器17與第一感知器15感測出應進行一除霜動作時,第一膨脹閥130就會開啟,位於第二管體21中之高溫高壓冷媒係由第七管體26流入第一膨脹閥130中,以進行一膨漲動作,而形成一高溫低壓之冷媒。, If the outdoor temperature sensor 17 and the first sensor 15 sense that a defrosting action should be performed, the first expansion valve 130 is opened, and the high temperature and high pressure refrigerant located in the second pipe body 21 is the seventh pipe body 26 The first expansion valve 130 flows into the first expansion valve 130 to perform a swelling operation to form a high temperature and low pressure refrigerant. ,
該高溫低壓之冷媒流入第六管體25中,而與來自第二膨脹閥131之低溫低壓之冷媒混合後,以形成一中溫低壓冷媒,再流入室外熱交換器14,以進行一除霜的動作,並同時進行一吸熱的動作,以形成一高溫低壓之冷媒,來自第一膨脹閥130之高溫低壓之冷媒的高溫係大於外熱交換器14之高溫低壓之冷媒的高溫。如無法形成該高溫低壓之冷媒則如上述之平衡效果,來自室外熱交換器14的低溫冷媒係與來自第八管體27的高溫冷媒於第五管體24中進行混合,以形成一中溫低壓之冷媒,如上之暖氣模式運轉所述,該高溫冷媒或該中溫冷媒係經由第五管體24流入四方閥11,並由第三管體22流入壓縮機10中。 The high temperature and low pressure refrigerant flows into the sixth pipe body 25, and is mixed with the low temperature and low pressure refrigerant from the second expansion valve 131 to form a medium temperature low pressure refrigerant, and then flows into the outdoor heat exchanger 14 to perform a defrosting. The action is performed simultaneously with an endothermic action to form a high temperature and low pressure refrigerant. The high temperature and low pressure refrigerant from the first expansion valve 130 has a higher temperature than the high temperature and low pressure refrigerant of the outer heat exchanger 14. If the high temperature and low pressure refrigerant cannot be formed, the low temperature refrigerant from the outdoor heat exchanger 14 and the high temperature refrigerant from the eighth pipe body 27 are mixed in the fifth pipe body 24 to form a medium temperature. In the low-pressure refrigerant, as described above in the heating mode operation, the high-temperature refrigerant or the intermediate-temperature refrigerant flows into the square valve 11 through the fifth pipe body 24, and flows into the compressor 10 from the third pipe body 22.
請配合圖3所示,其為本發明之具除濕與除霜功能之裝置之第二實施例。於本實施例中,壓縮機10、四方閥11、室內熱交換器12、冷媒控流機構13、室外熱交換器14、第一感知器15、第二感知器16、室外溫度感知器17、室內溫度感知器18、第一管體20、第二管體21、第三管體22、第四管體23、第五管體24、第六管體25、第七管體26與第八管體27的配置方式係如上述之第一實施例,故元件符號係沿用上一實施例。 Please refer to FIG. 3, which is a second embodiment of the device with dehumidification and defrosting function of the present invention. In the present embodiment, the compressor 10, the square valve 11, the indoor heat exchanger 12, the refrigerant flow control mechanism 13, the outdoor heat exchanger 14, the first sensor 15, the second sensor 16, the outdoor temperature sensor 17, Indoor temperature sensor 18, first tube body 20, second tube body 21, third tube body 22, fourth tube body 23, fifth tube body 24, sixth tube body 25, seventh tube body 26 and eighth The arrangement of the tubular body 27 is as in the first embodiment described above, so that the component symbols follow the previous embodiment.
於本實施例中,一閥體28係設於第八管體27,該閥體28係分別耦接第八管體27的一第一位置270與一第二位置271。該第一位置270係位於第三膨脹閥132與壓縮機10之間。該第二位置271係位於壓縮機10與第五管體24之間。該閥體28為一單向閥,故僅允許冷媒遵循單一方向流動。 In the present embodiment, a valve body 28 is coupled to the eighth tubular body 27, and the valve body 28 is coupled to a first position 270 and a second position 271 of the eighth tubular body 27, respectively. The first position 270 is located between the third expansion valve 132 and the compressor 10. The second position 271 is located between the compressor 10 and the fifth tubular body 24. The valve body 28 is a one-way valve, so that only the refrigerant is allowed to flow in a single direction.
若於冷氣運轉模式中進行除濕動作時,假設欲降低除濕效果,則閥體28就會開啟,因流體具有由高壓流向低壓的特性,故高溫冷媒會自動由該第二位置271流向該第一位置270,而不會通過繞設於壓縮機10的第八管體27,而使該高溫冷媒不會藉由壓縮機10再提昇至一特定溫度,藉此降低除濕的效果。 If the dehumidification operation is performed in the air-conditioning operation mode, it is assumed that the dehumidification effect is to be lowered, the valve body 28 is opened, and since the fluid has a characteristic of flowing from a high pressure to a low pressure, the high-temperature refrigerant automatically flows from the second position 271 to the first. At position 270, the high temperature refrigerant is not lifted by the compressor 10 to a specific temperature by winding the eighth pipe body 27 of the compressor 10, thereby reducing the effect of dehumidification.
同理,請配合參考圖4所示,因閥體28為一單向閥,若於暖氣模式運轉模式中進行一平衡動作時,來自第三膨脹閥132的低溫冷媒無法通過閥體28,而僅能於第八管體27中流動,並被壓縮機所加熱,以形成一高溫冷媒,該高溫冷媒再流入第五管體24中。 Similarly, please refer to FIG. 4, since the valve body 28 is a one-way valve, if a balancing operation is performed in the heating mode operation mode, the low-temperature refrigerant from the third expansion valve 132 cannot pass through the valve body 28, and It can only flow in the eighth pipe body 27 and is heated by the compressor to form a high temperature refrigerant which flows into the fifth pipe body 24.
本發明係一種具除濕的控制方法,其包含下列步驟: The present invention is a control method with dehumidification, which comprises the following steps:
請再配合參考圖1所示,第一感知器15係感測一第一溫度。第二感知器16係感測一第二溫度。室內溫度感知器18係感測一室內溫度。 Referring to FIG. 1 again, the first sensor 15 senses a first temperature. The second sensor 16 senses a second temperature. The indoor temperature sensor 18 senses an indoor temperature.
若於冷氣運轉模式,當第一溫度小於第二溫度時,第二膨脹閥131就會開啟,第二膨脹閥131的開度係取決於第一溫度與第二溫度的差值,若第一溫度減去第二溫度的數值越小時,則該開度就會越大,以增強冷氣效果。 If in the cold air operation mode, when the first temperature is lower than the second temperature, the second expansion valve 131 is opened, and the opening degree of the second expansion valve 131 is determined by the difference between the first temperature and the second temperature, if the first The smaller the value of the temperature minus the second temperature, the larger the opening will be to enhance the cooling effect.
如上所述,一低溫冷媒係流入室內熱交換器12,進行一吸熱的動作,藉此提供一冷氣給一室內,若第二膨脹閥131的開度越大,則流入室內熱交換器12的低溫冷媒之量就越多,如此能夠提高較多的冷氣給該室內。 As described above, a low-temperature refrigerant flows into the indoor heat exchanger 12 to perform an endothermic operation, thereby providing a cold air to the inside of the room, and if the opening degree of the second expansion valve 131 is larger, flowing into the indoor heat exchanger 12 The more the amount of low-temperature refrigerant is, the more cold air can be supplied to the room.
當第一溫度小於室內溫度時,第三膨脹閥132就會開啟,第三膨脹閥132的開度係取決於第一溫度與室內溫度的差值,若第一溫度減去室內溫度的數值越小時,則該開度就會越大,以提升除濕效果。 When the first temperature is lower than the indoor temperature, the third expansion valve 132 is opened, and the opening degree of the third expansion valve 132 is determined by the difference between the first temperature and the indoor temperature, and the value of the first temperature minus the indoor temperature is increased. In hours, the opening will be larger to enhance the dehumidification effect.
如上所述,一高溫冷媒會與一低溫冷媒混合,以形成一中溫冷媒,該中溫冷媒係流入室內熱交換器12中,以進行一熱交換,而達到除溼的效果。 As described above, a high temperature refrigerant is mixed with a low temperature refrigerant to form an intermediate temperature refrigerant which flows into the indoor heat exchanger 12 to perform a heat exchange to achieve the dehumidification effect.
當第二溫度小於室外溫度時,第一膨脹閥130就會開啟,第一膨脹閥130的開度係取決於第二溫度與室外溫度的差值,若第二溫度減去室外溫度的數值越小時,則開度就會越大,以提升平衡效果。 When the second temperature is lower than the outdoor temperature, the first expansion valve 130 is opened, and the opening degree of the first expansion valve 130 depends on the difference between the second temperature and the outdoor temperature, and if the second temperature is subtracted from the outdoor temperature, the value is increased. In hours, the opening will be larger to improve the balance.
如上所述,一低溫冷媒會與一高溫冷媒混合,以形成一中溫冷媒,該中溫冷媒係流入壓縮機10中,以使本發明呈一平衡狀態。 As described above, a low temperature refrigerant is mixed with a high temperature refrigerant to form an intermediate temperature refrigerant which flows into the compressor 10 to bring the present invention into an equilibrium state.
本發明係一種除霜的控制方法,其包含下列步驟: The present invention is a defrosting control method comprising the following steps:
請再配合參考圖2所示,若於暖氣模式運轉模式,當第一溫度大於第二溫度時,第二膨脹閥131的開度係取決於第一溫度與第二溫度的差值,若第一溫度減去第二溫度的數值越大時,則該開度就會越大,以增強暖氣效果。 Referring to FIG. 2 again, if in the heating mode operation mode, when the first temperature is greater than the second temperature, the opening degree of the second expansion valve 131 depends on the difference between the first temperature and the second temperature, if When the value of a temperature minus the second temperature is larger, the opening degree is increased to enhance the heating effect.
如上所述,一高溫冷媒係流入室內熱交換器12,以進行一散熱的動作,藉此提供一暖氣給一室內。 As described above, a high-temperature refrigerant flows into the indoor heat exchanger 12 to perform a heat-dissipating operation, thereby providing a heating to the room.
當第一溫度大於室內溫度時,第三膨脹閥132就會開啟,第三膨脹閥132的開度係取決於第一溫度與室內溫度的差值,若第一溫度減去室內溫度的數值越大時,則該開度就會越大,以提升平衡效果。 When the first temperature is greater than the indoor temperature, the third expansion valve 132 is opened, and the opening degree of the third expansion valve 132 is determined by the difference between the first temperature and the indoor temperature, and the value of the first temperature minus the indoor temperature is increased. When it is large, the opening will be larger to improve the balance.
如上所述,一高溫冷媒係與一低溫冷媒混合,以形成一中溫冷媒,該中溫冷媒係流入壓縮機10中,除可避免冷媒發生液壓縮的現象,並能使本發明達到一平衡的效果 As described above, a high temperature refrigerant is mixed with a low temperature refrigerant to form a medium temperature refrigerant which flows into the compressor 10, in addition to avoiding the phenomenon of liquid compression of the refrigerant, and can achieve a balance of the present invention. Effect
當第二溫度大於室外溫度時,第一膨脹閥130就會開啟,第一膨脹閥130的開度係取決於第二溫度與室外溫度的差值,若第二溫度減去室外溫度的數值越大時,則開度就會越大,以提升除霜效果。 When the second temperature is greater than the outdoor temperature, the first expansion valve 130 is opened, and the opening degree of the first expansion valve 130 is determined by the difference between the second temperature and the outdoor temperature, and if the second temperature is subtracted from the outdoor temperature, the value is increased. When it is large, the opening will be larger to enhance the defrosting effect.
如上所述,一高溫冷媒係與一低溫冷媒混合,以形成一中溫冷媒,該中溫冷媒係流入一室外熱交換器14中,,以進行一除霜的動作。 As described above, a high temperature refrigerant is mixed with a low temperature refrigerant to form an intermediate temperature refrigerant which flows into an outdoor heat exchanger 14 to perform a defrosting operation.
請配合參考圖5所示,本發明係處於一暖氣運轉模式。如圖所示,曲線A係表示本發明係處於一種提供暖氣的狀態,室外溫度約為7℃或以上,約於數分鐘後,曲線A係開始呈現一平坦狀,即暖氣提供係趨於一穩定狀態,若運轉時間越長,曲線A所呈現平坦狀會越明顯。 Referring to FIG. 5, the present invention is in a heating operation mode. As shown in the figure, curve A indicates that the present invention is in a state of providing heating, and the outdoor temperature is about 7 ° C or more. After about several minutes, the curve A starts to appear flat, that is, the heating supply system tends to In the steady state, if the running time is longer, the flatness of the curve A will be more obvious.
曲線B係表示室外溫度約界於7℃至0℃之間,本發明係進行一除霜運轉,並調整冷段回路與熱段回路。該冷段回路係上述之低溫冷媒所流經的路線。該熱段回路係上述之高溫冷媒所流經的路線。約於數分鐘後,曲線B與貼近於曲線A,並呈現一平坦狀,即除霜與暖氣提供係趨於一穩定狀態。 Curve B indicates that the outdoor temperature is between about 7 ° C and 0 ° C. The present invention performs a defrosting operation and adjusts the cold section circuit and the hot section circuit. The cold section circuit is a route through which the above-mentioned low temperature refrigerant flows. The hot section circuit is a route through which the high temperature refrigerant described above flows. After about a few minutes, the curve B is close to the curve A and presents a flat shape, that is, the defrosting and heating supply tends to be in a stable state.
若要更進一步論述曲線B,請再配合參考圖2所示,一高溫高壓之冷媒係流入室內熱交換器12,並經過一放熱過程,以形成一低溫高壓之冷媒。該低溫高壓之冷媒係由第一管體20流入冷媒控流機構13中,並進行一膨脹過程,以形成一低溫低壓之冷媒。 To further discuss curve B, please refer to FIG. 2 again, a high temperature and high pressure refrigerant flows into the indoor heat exchanger 12 and undergoes a heat release process to form a low temperature and high pressure refrigerant. The low-temperature high-pressure refrigerant flows into the refrigerant flow control mechanism 13 from the first pipe body 20, and performs an expansion process to form a low-temperature low-pressure refrigerant.
該低溫低壓之冷媒係由第六管體25流入室外熱交換器中,並進行一吸熱過程,以形成一高溫低壓之冷媒。 The low temperature and low pressure refrigerant flows into the outdoor heat exchanger from the sixth pipe body 25, and performs an endothermic process to form a high temperature and low pressure refrigerant.
該高溫低壓之冷媒係依序由第五管體24、四方閥11與第三管體22流入壓縮機10中,以形成上述之高溫高壓之冷媒。該高溫高壓之冷媒在依序由第四管體23、四方閥11與第二管體21流入室內熱交換器12中。 The high-temperature and low-pressure refrigerant sequentially flows into the compressor 10 from the fifth pipe body 24, the square valve 11 and the third pipe body 22 to form the high-temperature high-pressure refrigerant described above. The high-temperature high-pressure refrigerant flows into the indoor heat exchanger 12 from the fourth pipe body 23, the square valve 11 and the second pipe body 21 in this order.
若欲呈現出曲線B之現象,則要分為兩個部份解釋,一為冷段回路的調整,二為熱段回路的調整。 If you want to show the phenomenon of curve B, it is divided into two parts, one is the adjustment of the cold section loop, and the other is the adjustment of the hot section loop.
來自第一管體20之低溫高壓之冷媒係流入冷媒控流機構13中,並進行一膨脹過程,以形成一低溫低壓之冷媒。該低溫低壓之冷媒係流入第八管體27,並被壓縮機10所加熱,再流入第五管體24中,以形成一高溫低壓之冷媒。但被壓縮機10所加熱後之高溫低壓之冷媒的高溫係小於位於第五管體24之高溫低壓之冷媒的高溫。位於第八管體之高溫低壓之低壓係小於位於第五管體24之高溫低壓的低壓。故二冷媒於第五管體24中混合後會形成為一中溫低壓之冷媒,然為了便於論述,仍以一高溫低壓之冷媒論述, 此為熱段回路的調整。 The low temperature and high pressure refrigerant from the first pipe body 20 flows into the refrigerant flow control mechanism 13 and undergoes an expansion process to form a low temperature and low pressure refrigerant. The low-temperature low-pressure refrigerant flows into the eighth pipe body 27, is heated by the compressor 10, and flows into the fifth pipe body 24 to form a high-temperature low-pressure refrigerant. However, the high temperature of the high temperature and low pressure refrigerant heated by the compressor 10 is lower than the high temperature of the high temperature and low pressure refrigerant located in the fifth pipe body 24. The low pressure of the high temperature and low pressure of the eighth pipe body is lower than the low pressure of the high temperature and low pressure of the fifth pipe body 24. Therefore, after the second refrigerant is mixed in the fifth pipe body 24, it will form a medium-temperature low-pressure refrigerant, but for the sake of convenience, it is still discussed by a high-temperature and low-pressure refrigerant. This is an adjustment of the hot section loop.
來自壓縮機10之高溫高壓之冷媒係由第七管體26流入冷媒控流機構13,並經一膨脹過程,以形成一高溫低壓之冷媒。該高溫低壓之冷媒係與位於第六管體25中之低溫低壓之冷媒進行混合,以形成一中溫低壓之冷媒。該中溫低壓之冷媒係流入室外熱交換器14中,以進行一吸熱過程,而形成為一高溫低壓之冷媒。該高溫低壓之冷媒係依序由第五管體24、四方閥11與第三管體22流入壓縮機10中,此為熱段回路的調整。該中溫低壓之低壓係大於位於第五管體24之高溫低壓的低壓。 The high temperature and high pressure refrigerant from the compressor 10 flows from the seventh pipe body 26 into the refrigerant flow control mechanism 13 and undergoes an expansion process to form a high temperature and low pressure refrigerant. The high temperature and low pressure refrigerant is mixed with the low temperature and low pressure refrigerant located in the sixth pipe body 25 to form a medium temperature low pressure refrigerant. The medium-temperature low-pressure refrigerant flows into the outdoor heat exchanger 14 to perform an endothermic process to form a high-temperature and low-pressure refrigerant. The high temperature and low pressure refrigerant is sequentially flowed into the compressor 10 from the fifth pipe body 24, the square valve 11 and the third pipe body 22, which is an adjustment of the hot section circuit. The low temperature of the medium temperature and low pressure is greater than the low pressure of the high temperature and low pressure of the fifth body 24.
承上所述,本發明係利用冷媒的分流與混流的方式,以改變流入室外內熱交換器14之冷媒的壓力與溫度,以及流入壓縮機10之冷媒的壓力與溫度,進而達到調整冷段回路與熱段回路之目的。 As described above, the present invention utilizes the method of splitting and mixing of the refrigerant to change the pressure and temperature of the refrigerant flowing into the outdoor heat exchanger 14 and the pressure and temperature of the refrigerant flowing into the compressor 10, thereby achieving the adjustment of the cold section circuit. With the purpose of the hot section circuit.
曲線C係表示室外溫度低於0℃,本發明係進行一除霜運轉,並調整一熱段回路,於此時,本發明要同時進行三個動作,一為提供暖氣,二為除霜,三為進行上述之平衡本發明的動作。如圖所示,約於數分鐘後,曲線C與貼近於曲線A,並呈現一平坦狀,即除霜、平衡本發明與暖氣提供係趨於一穩定狀態。 Curve C indicates that the outdoor temperature is lower than 0 ° C. The present invention performs a defrosting operation and adjusts a hot section circuit. At this time, the present invention performs three actions simultaneously, one for providing heating and the other for defrosting. Third, the above-described operation of the present invention is balanced. As shown in the figure, after about a few minutes, the curve C is close to the curve A and presents a flat shape, that is, the defrosting and balancing the present invention and the heating supply system tend to be in a stable state.
請配合參考圖6所示,本發明係處於一冷氣運轉模式。如圖所示,曲線D係表示室外溫度約為27℃或以上,並處於一種提供冷氣的狀態,約於數分鐘後,曲線D係開始呈現一平坦狀,即冷氣提供係趨近於一穩定狀態,若運轉時間越長,曲線D所呈現的平坦狀會越明顯。 Referring to FIG. 6, the present invention is in a cool air operation mode. As shown in the figure, the curve D indicates that the outdoor temperature is about 27 ° C or above, and is in a state of providing cold air. After a few minutes, the curve D begins to assume a flat shape, that is, the cold air supply system approaches a stable state. State, if the running time is longer, the flatness of the curve D will be more obvious.
曲線E係表示室外溫度約介於27℃至24℃之間,本發明係進行一除濕運轉,並調整冷段回路與熱段回路。約於一段時間後,曲線E與貼近於曲線D,並呈現一平坦狀,即除溼與冷氣提供係趨於一穩定狀態。該段時間能夠為數分鐘至十多分鐘,或者少於十多分鐘。 Curve E shows that the outdoor temperature is between about 27 ° C and 24 ° C. The present invention performs a dehumidification operation and adjusts the cold section circuit and the hot section circuit. After about a period of time, the curve E is close to the curve D and presents a flat shape, that is, the dehumidification and cold air supply systems tend to be in a stable state. This period of time can range from a few minutes to more than ten minutes, or less than ten minutes.
若要更進一步論述曲線E,請再配合參考圖1所示,來自第一管體20的低溫低壓之冷媒,於室內熱交換器12經過一吸熱過程後,該低溫低壓之冷媒形成為一高溫低壓之冷媒。 To further discuss the curve E, please refer to the low temperature and low pressure refrigerant from the first pipe body 20 as shown in FIG. 1. After the indoor heat exchanger 12 passes through an endothermic process, the low temperature and low pressure refrigerant is formed into a high temperature. Low pressure refrigerant.
該高溫低壓之冷媒係由第二管路21流入壓縮機10中,以形成一高溫高壓之冷媒。該高溫高壓之冷媒係由第四管體23流入室外熱交換器14中,並經過一放熱過程,以形成一低溫高壓之冷媒。 The high temperature and low pressure refrigerant flows into the compressor 10 from the second line 21 to form a high temperature and high pressure refrigerant. The high temperature and high pressure refrigerant flows into the outdoor heat exchanger 14 from the fourth pipe body 23 and undergoes a heat release process to form a low temperature and high pressure refrigerant.
該低溫高壓之冷媒係由第六管體25流入冷媒控流機構13中,並進行一膨脹過程,以形成上述之低溫低壓之冷媒。該低溫低壓之冷媒再由第一管體20流入室內熱交換器12中。 The low-temperature high-pressure refrigerant flows into the refrigerant flow control mechanism 13 from the sixth pipe body 25, and performs an expansion process to form the above-mentioned low-temperature low-pressure refrigerant. The low temperature and low pressure refrigerant is further flowed into the indoor heat exchanger 12 by the first pipe body 20.
若欲呈現出曲線E之現象,則要分為兩個部份解釋,一為冷段回路的調整,二為熱段回路的調整。 If you want to show the phenomenon of curve E, it must be divided into two parts, one is the adjustment of the cold section loop, and the other is the adjustment of the hot section loop.
壓縮機10所吐出的高溫高壓之冷媒係依序流經第四管體23、四方閥11、第五管體24與第八管體27後,再被壓縮機10加熱後,並流入冷媒控流機構13中,經一膨脹過程後,以形成一高溫低壓之冷媒,並與位於第一管體20中之低溫低壓之冷媒進行混合,以形成一中溫低壓之冷媒,再流入室內熱交換器12中,此為冷段回路的調整。該中溫低壓之低壓係大於該低溫低壓之低壓。 The high-temperature high-pressure refrigerant discharged from the compressor 10 sequentially flows through the fourth pipe body 23, the square valve 11, the fifth pipe body 24, and the eighth pipe body 27, and is then heated by the compressor 10, and flows into the refrigerant control. In the flow mechanism 13, after a expansion process, a high temperature and low pressure refrigerant is formed, and mixed with the low temperature and low pressure refrigerant located in the first pipe body 20 to form a medium temperature and low pressure refrigerant, and then flow into the indoor heat exchange. In the device 12, this is the adjustment of the cold section circuit. The low temperature of the medium temperature and low pressure is greater than the low pressure of the low temperature and low pressure.
來自室外熱交換器14之低溫高壓之冷媒係由第六管體25流入冷媒控流機構13中,經一膨脹過程後,以形成一低溫低壓之冷媒,再由第七管體26流入第二管體21中,並與位於第二管體21中之高溫低壓之冷媒進行混合,以形成一中溫低壓之冷媒,此為熱段回路的調整。該中溫低壓之低壓係大於該高溫低壓之低壓。 The low-temperature high-pressure refrigerant from the outdoor heat exchanger 14 flows into the refrigerant flow control mechanism 13 from the sixth pipe body 25, and after a expansion process, a low-temperature low-pressure refrigerant is formed, and then the seventh pipe body 26 flows into the second body. The tubular body 21 is mixed with the high temperature and low pressure refrigerant located in the second tubular body 21 to form a medium temperature and low pressure refrigerant, which is an adjustment of the hot section circuit. The low temperature of the medium temperature and low pressure is greater than the low pressure of the high temperature and low pressure.
承上所述,本發明係利用冷媒的分流與混流的方式,以改變流入室內熱交換器12之冷媒的壓力與溫度,以及流入壓縮機10之冷媒的壓力與溫度,進而達到調整冷段回路與熱段回路之目的。 As described above, the present invention utilizes the splitting and mixing of the refrigerant to change the pressure and temperature of the refrigerant flowing into the indoor heat exchanger 12, and the pressure and temperature of the refrigerant flowing into the compressor 10, thereby achieving the adjustment of the cold section circuit. With the purpose of the hot section circuit.
曲線F係表示室外溫度低於24℃,本發明係進行一除濕運轉,並調整一熱段回路,於此時,本發明要同時進行三個動作,一為提供冷氣,二為除濕,三為進行上述之平衡本發明的動作。如圖所示,約於數分鐘後,曲線F與貼近於曲線D,並呈現一平坦狀,即除濕、平衡本發明與冷氣提供係趨於一穩定狀態。 The curve F indicates that the outdoor temperature is lower than 24 ° C. The present invention performs a dehumidification operation and adjusts a hot section circuit. At this time, the present invention performs three actions simultaneously, one for providing cold air and the other for dehumidification, three for The above-described operation of balancing the present invention is performed. As shown, after about a few minutes, the curve F is close to the curve D and assumes a flat shape, that is, the dehumidification and balance of the present invention and the cold air supply system tend to be in a stable state.
綜合上述,現有的空調系統或除濕系統,於提供冷氣或除濕時常會造成室內溫度增溫,或者於提供暖氣時常會造成室內溫度降溫,而造成位於室內的人們不舒適的情況產生。本發明係藉由 提供一種平衡的方式,即一高溫冷媒與一低溫冷媒混合所形成的一中溫冷媒,而達到除濕或除霜的功能,並能進一步達到除濕或除霜,並維持於一溫度,而保持位於室內的人們的舒適感。 In summary, the existing air conditioning system or dehumidification system often causes room temperature to increase when providing air conditioning or dehumidification, or often causes room temperature to drop when heating is provided, thereby causing uncomfortable situations in the room. The invention is based on Providing a balanced way, that is, a medium temperature refrigerant formed by mixing a high temperature refrigerant and a low temperature refrigerant to achieve the function of dehumidification or defrosting, and further dehumidification or defrosting, and maintaining at a temperature while remaining at a temperature The comfort of people in the room.
以上所述之具體實施例,僅係用於例釋本發明之特點及功效,而非用於限定本發明之可實施範疇,於未脫離本發明上揭之精神與技術範疇下,任何運用本發明所揭示內容而完成之等效改變及修飾,均仍應為下述之申請專利範圍所涵蓋。 The specific embodiments described above are only used to exemplify the features and functions of the present invention, and are not intended to limit the scope of the present invention, and may be used without departing from the spirit and scope of the invention. Equivalent changes and modifications made to the disclosure of the invention are still covered by the scope of the following claims.
10‧‧‧壓縮機 10‧‧‧Compressor
11‧‧‧四方閥 11‧‧‧tetragonal valve
12‧‧‧室內熱交換器 12‧‧‧ indoor heat exchanger
13‧‧‧冷媒控流機構 13‧‧‧Refrigerant flow control mechanism
130‧‧‧第一膨脹閥 130‧‧‧First expansion valve
131‧‧‧第二膨脹閥 131‧‧‧Second expansion valve
132‧‧‧第三膨脹閥 132‧‧‧third expansion valve
14‧‧‧室外熱交換器 14‧‧‧Outdoor heat exchanger
15‧‧‧第一感知器 15‧‧‧First Sensor
16‧‧‧第二感知器 16‧‧‧Second sensor
17‧‧‧室外溫度感知器 17‧‧‧Outdoor temperature sensor
18‧‧‧室內溫度感知器 18‧‧‧Indoor temperature sensor
20‧‧‧第一管體 20‧‧‧First tube
21‧‧‧第二管體 21‧‧‧Second body
22‧‧‧第三管體 22‧‧‧3rd body
23‧‧‧第四管體 23‧‧‧Fourth body
24‧‧‧第五管體 24‧‧‧ fifth body
25‧‧‧第六管體 25‧‧‧6th body
26‧‧‧第七管體 26‧‧‧ seventh tube
27‧‧‧第八管體 27‧‧‧8th tube
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CN201310729023.1A CN104697253A (en) | 2013-12-06 | 2013-12-18 | Device with dehumidification and defrosting functions and control method thereof |
US14/220,831 US20150159935A1 (en) | 2013-12-06 | 2014-03-20 | Apparatus with dehumidification and defrosting abilities and controlling method thereof |
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KR101598624B1 (en) * | 2008-11-10 | 2016-02-29 | 엘지전자 주식회사 | Air conditioning system |
CN201335582Y (en) * | 2009-01-05 | 2009-10-28 | 江苏新誉空调系统有限公司 | Track train air conditioner refrigerating system with pressure compensation function |
JP5615561B2 (en) * | 2010-01-26 | 2014-10-29 | パナソニック株式会社 | Refrigeration cycle equipment |
-
2013
- 2013-12-06 TW TW102144882A patent/TWI539120B/en active
- 2013-12-18 CN CN201310729023.1A patent/CN104697253A/en active Pending
-
2014
- 2014-03-20 US US14/220,831 patent/US20150159935A1/en not_active Abandoned
Also Published As
Publication number | Publication date |
---|---|
TWI539120B (en) | 2016-06-21 |
CN104697253A (en) | 2015-06-10 |
US20150159935A1 (en) | 2015-06-11 |
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