WORKING MEDIUM AND HEAT CYCLE SYSTEM

Abstract

To provide a working medium for heat cycle which has less influence over the ozone layer, which has less influence over global warming and which provides a heat cycle system excellent in the cycle performance (the efficiency and the capacity), and a heat cycle system excellent in the cycle performance (the efficiency and the capacity). A working medium for heat cycle comprising 1,2-difluoroethylene is employed for a heat cycle system (such as a Rankine cycle system, a heat pump cycle system, a refrigerating cycle system 10 or a heat transport system).

Description

TECHNICAL FIELD

The present invention relates to a working medium and a heat cycle system employing the working medium.

BACKGROUND ART

Heretofore, as a working medium for heat cycle such as a coolant for a refrigerator, a coolant for an air conditioner, a working fluid for power generation system (such as exhaust heat recovery power generation), a working medium for a latent heat transport apparatus (such as a heat pipe) or a secondary cooling medium, a chlorofluorocarbon (CFC) such as chlorotrifluoromethane or dichlorodifluoromethane or a hydrochlorofluorocarbon (HCFC) such as chlorodifluoromethane has been used. However, influences of CFCs and HCFCs over the ozone layer in the stratosphere have been pointed out, and their use are regulated at present.

Accordingly, as a working medium for heat cycle, a hydrofluorocarbon (HFC) which has less influence over the ozone layer, such as difluoromethane (HFC-32), tetrafluoroethane or pentafluoroethane, has been used. However, it is pointed out that HFCs may cause global warming. Accordingly, development of a working medium for heat cycle which has less influence over the ozone layer and has a low global warming potential is an urgent need.

For example, 1,1,1,2-tetrafluoroethane (HFC-134a) used as a coolant for an automobile air conditioner has a global warming potential so high as 1,430 (100 years). Further, in an automobile air conditioner, the coolant is highly likely to leak out to the air e.g. from a connection hose or a bearing.

As a coolant which replaces HFC-134a, carbon dioxide and 1,1-difluoroethane (HFC-152a) having a global warming potential of 124 (100 years) which is low as compared with HFC-134a, have been studied.

However, with carbon dioxide, the equipment pressure tends to be extremely high as compared with HFC-134a, and accordingly there are many problems to be solved in application to all the automobiles. HFC-152a has a range of inflammability, and has a problem for securing the safety.

As a working medium for heat cycle which has less influence over the ozone layer and has less influence over global warming, a hydrofluoroolefin (HFO) having a carbon-carbon double bond which is easily decomposed by OH radicals in the air is conceivable.

As a working medium for heat cycle comprising a HFO, for example, the following have been known.

(1) 3,3,3-Trifluoropropene (HFO-1243zf), 1,3,3,3-tetrafluoropropene (HFO-1234ze), 2-fluoropropene (HFO-1261yf), 2,3,3,3-tetrafluoropropene (HFO-1234yf) and 1,1,2-trifluoropropene (HFO-1243yc) (Patent Document 1).

(2) 1,2,3,3,3-Pentafluoropropene (HFO-1225ye), trans-1,3,3,3-tetrafluoropropene (HFO-1234ze(E)), cis-1,3,3,3-tetrafluoropropene (HFO-1234ze(Z)) and HFO-1234yf (Patent Document 2).

However, each of HFOs in (1) is insufficient in the cycle performance (capacity).

Each of HFOs in (2) is also insufficient in the cycle performance (capacity).

PRIOR ART DOCUMENTS

Patent Documents

• Patent Document 1: JP-A-04-110388
• Patent Document 2: JP-A-2006-512426

DISCLOSURE OF INVENTION

Technical Problem

The present invention provides a working medium for heat cycle, which has less influence over the ozone layer, which has less influence over global warming and which provides a heat cycle system excellent in the cycle performance (efficiency and capacity), and a heat cycle system excellent in the cycle performance (efficiency and capacity).

Solution to Problem

The present invention provides a working medium for heat cycle (hereinafter sometimes referred to as working medium), which comprises 1,2-difluoroethylene (hereinafter sometimes referred to as HFO-1132).

The working medium of the present invention preferably further contains a hydrocarbon.

The working medium of the present invention preferably further contains a HFC.

The working medium of the present invention preferably further contains a hydrochlorofluoroolefin (HCFO) or a chlorofluoroolefin (CFO).

The heat cycle system of the present invention employs the working medium of the present invention.

Advantageous Effects of Invention

The working medium of the present invention, which comprises HFO-1132 having a carbon-carbon double bond which is easily decomposed by OH radicals in the air, has less influence over the ozone layer and has less influence over global warming.

The heat cycle system of the present invention, which employs the working medium of the present invention excellent in the thermodynamic properties due to HFO-1132, is excellent in the cycle performance (efficiency and capacity). Further, due to excellent efficiency, a reduction in the power consumption will be attained, and due to excellent capacity, downsizing of a system can be achieved.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a schematic construction view illustrating an example of a refrigerating cycle system.

FIG. 2 is a cycle diagram illustrating the state change of a working medium in a refrigerating cycle system on a temperature-entropy chart.

FIG. 3 is a cycle diagram illustrating the state change of a working medium in a refrigerating cycle system on a pressure-enthalpy chart.

DESCRIPTION OF EMBODIMENTS

<Working Medium>

The working medium of the present invention comprises 1,2-difluoroethylene.

The working medium of the present invention may contain, as the case requires, another working medium which will be gasified or liquefied together with HFO1132, such as a hydrocarbon, a HFC, a HCFO, a CFO or other HFO. Further, the working medium of the present invention may be used in combination with a component other than the working medium, used together with the working medium (hereinafter, a composition containing the working medium and a component other than the working medium will be referred to as a working medium-containing composition). The component other than the working medium may, for example, be a lubricating oil, a stabilizer, a leak detecting substance, a desiccating agent or other additives.

(HFO-1132)

As HFO-1132, there are two stereoisomers of trans-1,2-difluoroethylene (HFO-1132(E)) and cis-1,2-difluoroethylene (HFO-1132(Z)). In the present invention, HFO-1132(E) may be used alone, HFO-1132(Z) may be used alone, or a mixture of HFO-1132(E) and HFO-1132(Z) may be used.

The content of HFO-1132 is preferably at least 60 mass %, more preferably at least 70 mass %, further preferably at least 80 mass %, particularly preferably 100 mass % in the working medium (100 mass %).

(Hydrocarbon)

The hydrocarbon is a working medium component which improves solubility of the working medium in a mineral lubricating oil.

The hydrocarbon has preferably from 3 to 5 carbon atoms, and may be linear or branched.

The hydrocarbon is specifically preferably propane, propylene, cyclopropane, butane, isobutane, pentane or isopentane.

The hydrocarbons may be used alone or in combination of two or more.

The content of the hydrocarbon is preferably from 1 to 30 mass %, more preferably from 2 to 30 mass %, in the working medium (100 mass %). When the content of the hydrocarbon is at least 1 mass %, the solubility of the lubricating oil in the working medium will sufficiently be improved.

(HFC)

The HFC is a working medium component which improves the cycle performance (capacity) of a heat cycle system.

The HFC is preferably a HFC which has less influence over the ozone layer and which has less influence over global warming.

The HFC has preferably from 1 to 5 carbon atoms, and may be linear or branched.

The HFC may, for example, be specifically difluoromethane, difluoroethane, trifluoroethane, tetrafluoroethane, pentafluoroethane, pentafluoropropane, hexafluoropropane, heptafluoropropane, pentafluorobutane or heptafluorocyclopentane. Among them, particularly preferred is difluoromethane (HFC-32), 1,1-difluoroethane (HFC-152a), 1,1,2,2-tetrafluoroethane (HFC-134), 1,1,1,2-tetrafluoroethane (HFC-134a) or pentafluoroethane (HFC-125), which has less influence over the ozone layer and which has less influence over global warming.

The HFCs may be used alone or in combination of two more.

The content of the HFC in the working medium (100 mass %) is preferably from 1 to 99 mass %, more preferably from 1 to 60 mass %. For example, in a case where the HFC is HFC-125, it is possible to suppress a decrease in the coefficient of performance and to remarkably improve the refrigerating capacity within a content range of from 1 to 60 mass %. In the case of HFC-134a, it is possible to improve the refrigerating capacity without a decrease in the coefficient of performance, within a content range of from 1 to 40 mass %. Further, in the case of HFC-32, it is possible to suppress a decrease in the coefficient of performance and to remarkably improve the refrigerating capacity within a content range of from 1 to 99 mass %. Improvement is possible depending upon the required properties of the working medium.

(HCFO, CFO)

The HCFO and the CFO are working medium components which suppress combustibility of the working medium. Further, they are components which improve the solubility of the lubricating oil in the working medium.

As the HCFO and the CFO, preferred is a HCFO which has less influence over the ozone layer and which has less influence over global warming.

The HCFO has preferably from 2 to 5 carbon atoms, and may be linear or branched.

The HCFO may, for example, be specifically hydrochlorofluoropropene or hydrochlorofluoroethylene. Among them, particularly preferred is 1-chloro-2,3,3,3-tetrafluoropropene (HCFO-1224yd) or 1-chloro-1,2-difluoroethylene (HCFO-1122), with a view to sufficiently suppressing combustibility of the working medium without substantially decreasing the cycle performance (capacity) of the heat cycle system.

The HCFOs may be used alone or in combination of two or more.

The CFO has preferably from 2 to 5 carbon atoms, and may be linear or branched.

The CFO may, for example, be specifically chlorofluoropropene or chlorofluoroethylene. Among them, particularly preferred is 1,1-dichloro-2,3,3,3-tetrafluoropropene (CFO-1214ya) or 1,2-dichloro-1,2-difluoroethylene (CFO-1112) with a view to sufficiently suppressing combustibility of the working medium without substantially decreasing the cycle performance (capacity) of the heat cycle system.

The total content of the HCFO and the CFO is preferably from 1 to 60 mass %, more preferably from 1 to 40 mass % in the working medium (100 mass %). When the total content of the HCFO and the CFO is from 1 to 40 mass %, it is possible to sufficiently suppress combustibility of the working medium without substantially decreasing the cycle performance (capacity) of the heat cycle system.

(Other HFO)

Other HFO is preferably a HFO which has less influence over the ozone layer and which has less influence over global warming.

Such other HFO may, for example, be HFO-1224ye, HFO-1234ze or HFO-1243zf.

(Lubricating Oil)

As the lubricating oil to be used for the working medium-containing composition, a known lubricating oil used for the heat cycle system may be used.

The lubricating oil may, for example, be an oxygen-containing synthetic oil (such as an ester lubricating oil or an ether lubricating oil), a fluorinated lubricating oil, a mineral oil or a hydrocarbon synthetic oil.

The ester lubricating oil may, for example, be a dibasic acid ester oil, a polyol ester oil, a complex ester oil or a polyol carbonate oil.

The dibasic acid ester oil is preferably an ester of a C_5-10 dibasic acid (such as glutaric acid, adipic acid, pimelic acid, suberic acid, azelaic acid or sebacic acid) with a C monohydric alcohol which is linear or has a branched alkyl group (such as methanol, ethanol, propanol, butanol, pentanol, hexanol, heptanol, octanol, nonanol, decanol, undecanol, dodecanol, tridecanol, tetradecanol or pentadecanol). Specifically, ditridecyl glutarate, di(2-ethylhexyl) adipate, diisodecyl adipate, ditridecyl adipate or di(3-ethylhexyl) sebacate may, for example, be mentioned.

The polyol ester oil is preferably an ester of a diol (such as ethylene glycol, 1,3-propanediol, propylene glycol, 1,4-butanediol, 1,2-butandiol, 1,5-pentadiol, neopentyl glycol, 1,7-heptanediol or 1,12-dodecanediol) or a polyol having from 3 to 20 hydroxy groups (such as trimethylolethane, trimethylolpropane, trimethylolbutane, pentaerythritol, glycerol, sorbitol, sorbitan or sorbitol/glycerin condensate) with a C_6-20 fatty acid (such as a linear or branched fatty acid such as hexanoic acid, heptanoic acid, octanoic acid, nonanoic acid, decanoic acid, undecanoic acid, dodecanoic acid, eicosanoic acid or oleic acid, or a so-called neo acid having a quaternary a carbon atom).

The polyol ester oil may have a free hydroxy group.

The polyol ester oil is preferably an ester (such as trimethylolpropane tripelargonate, pentaerythritol 2-ethylhexanoate or pentaerythritol tetrapelargonate) of a hindered alcohol (such as neopentyl glycol, trimethylolethane, trimethylolpropane, trimethylolbutane or pentaerythritol).

The complex ester oil is an ester of a fatty acid and a dibasic acid, with a monohydric alcohol and a polyol. The fatty acid, the dibasic acid, the monohydric alcohol and the polyol may be as defined above.

The polyol carbonate oil is an ester of carbonic acid with a polyol.

The polyol may be the above-described diol or the above-described polyol. Further, the polyol carbonate oil may be a ring-opening polymer of a cyclic alkylene carbonate.

The ether lubricating oil may be a polyvinyl ether oil or a polyoxyalkylene lubricating oil.

The polyvinyl ether oil may be one obtained by polymerizing a vinyl ether monomer such as an alkyl vinyl ether, or a copolymer obtained by copolymerizing a vinyl ether monomer and a hydrocarbon monomer having an olefinic double bond.

The vinyl ether monomers may be used alone or in combination of two or more.

The hydrocarbon monomer having an olefinic double bond may, for example, be ethylene, propylene, various forms of butene, various forms of pentene, various forms of hexene, various forms of heptene, various forms of octene, diisobutylene, triisobutylene, styrene, α-methylstyrene or alkyl-substituted styrene. The hydrocarbon monomers having an olefinic double bond may be used alone or in combination of two or more.

The polyvinyl ether copolymer may be either of a block copolymer and a random copolymer.

The polyvinyl ethers may be used alone or in combination of two or more.

The polyoxyalkylene lubricating oil may, for example, be a polyoxyalkylene monool, a polyoxyalkylene polyol, an alkyl ether of a polyoxyalkylene monool or a polyoxyalkylene polyol, or an ester of a polyoxyalkylene monool or a polyoxyalkylene polyol. The polyoxyalkylene monool or the polyoxyalkylene polyol may be one obtained by e.g. a method of subjecting a C_2-4 alkylene oxide (such as ethylene oxide or propylene oxide) to ring-opening addition polymerization to man initiator such as water or a hydroxy group-containing compound in the presence of a catalyst such as an alkali hydroxide. Further, one molecule of the polyoxyalkylene chain may contain single oxyalkylene units or two or more types of oxyalkylene units. It is preferred that at least oxypropylene units are contained in one molecule.

The initiator may, for example, be water, a monohydric alcohol such as methanol or butanol, or a polyhydric alcohol such as ethylene glycol, propylene glycol, pentaerythritol or glycerol.

The polyoxyalkylene lubricating oil is preferably an alkyl ether or an ester of a polyoxyalkylene monool or polyoxyalkylene polyol. Further, the polyoxyalkylene polyol is preferably a polyoxyalkylene glycol. Particularly preferred is an alkyl ether of a polyoxyalkylene glycol having the terminal hydroxy group of the polyoxyalkylene glycol capped with an alkyl group such as a methyl group, which is called a polyglycol oil.

The fluorinated lubricating oil may, for example, be a compound having hydrogen atoms of a synthetic oil (such as the after-mentioned mineral oil, poly-α-olefin, alkylbenzene or alkylnaphthalene) substituted by fluorine atoms, a perfluoropolyether oil or a fluorinated silicone oil.

The mineral oil may, for example, be a naphthene mineral oil or a paraffin mineral oil obtained by purifying a lubricating oil fraction obtained by atmospheric distillation or vacuum distillation of crude oil by a purification treatment (such as solvent deasphalting, solvent extraction, hydrocracking, solvent dewaxing, catalytic dewaxing, hydrotreating or clay treatment) optionally in combination.

The hydrocarbon synthetic oil may, for example, be a poly-α-olefin, an alkylbenzene or an alkylnaphthalene.

The lubricating oils may be used alone or in combination of two or more.

The lubricating oil is preferably a polyol ester oil and/or a polyglycol oil in view of the compatibility with the working medium, particularly preferably a polyalkylene glycol oil with a view to obtaining a remarkable antioxidant effect by a stabilizer.

The content of the lubricating oil is not limited within a range not to remarkably decrease the effects of the present invention, varies depending upon e.g. the application and the form of a compressor, and is preferably from 10 to 100 parts by mass, more preferably from 20 to 50 parts by mass based on the working medium (100 parts by mass).

(Stabilizer)

The stabilizer to be used for the working medium-containing composition is a component which improves the stability of the working medium against heat and oxidation.

The stabilizer may, for example, be an oxidation resistance-improving agent, a heat resistance-improving agent or a metal deactivator.

The oxidation resistance-improving agent and the heat resistance-improving agent may, for example, be N,N′-diphenylphenylenediamine, p-octyldiphenylamine, p,p′-dioctyldiphenylamine, N-phenyl-1-naphthyamine, N-phenyl-2-naphthylamine, N-(p-dodecyl)phenyl-2-naphthylamine, di-1-naphthylamine, di-2-naphthylamine, N-alkylphenothiazine, 6-(t-butyl)phenol, 2,6-di-(t-butyl)phenol, 4-methyl-2,6-di-(t-butyl)phenol or 4,4′-methylenebis(2,6-di-t-butylphenol). The oxidation resistance-improving agents and the heat resistance-improving agents may be used alone or in combination of two or more.

The metal deactivator may, for example, be imidazole, benzimidazole, 2-mercaptobenzothiazole, 2,5-dimercaptothiadiazole, salicylysine-propylenediamine, pyrazole, benzotriazole, tritriazole, 2-methylbenzamidazole, 3,5-dimethylpyrazole, methylenebis-benzotriazole, an organic acid or an ester thereof, a primary, secondary or tertiary aliphatic amine, an amine salt of an organic acid or inorganic acid, a heterocyclic nitrogen-containing compound, an amine salt of an alkyl phosphate, or a derivative thereof.

The content of the stabilizer is not limited within a range not to remarkably decrease the effects of the present invention, and is preferably at most 5 mass %, more preferably at most 1 mass % in the working medium-containing composition (100 mass %).

(Leak Detecting Substance)

The leak detecting substance to be used for the working medium-containing composition may, for example, be an ultraviolet fluorescent dye, an odor gas or an odor masking agent.

The ultraviolet fluorescent dye may be known ultraviolet fluorescent dyes as disclosed in e.g. U.S. Pat. No. 4,249,412, JP-A-10-502737, JP-A-2007-511645, JP-A-2008-500437 and JP-A-2008-531836.

The odor masking agent may be known perfumes as disclosed in e.g. JP-A-2008-500437 and JP-A-2008-531836.

In a case where the leak detecting substance is used, a solubilizing agent which improves the solubility of the leak detecting substance in the working medium may be used.

The solubilizing agent may be ones as disclosed in e.g. JP-A-200T511645, JP-A-2008-500437 and JP-A-2008-531836.

The content of the leak detecting substance is not particularly limited within a range not to remarkably decrease the effects of the present invention, and is preferably at most 2 mass %, more preferably at most 0.5 mass % in the working medium-containing composition (100 mass %).

(Other Compound)

The working medium of the present invention and the working medium-containing composition may contain a C_1-4 alcohol or a compound used as a conventional working medium, coolant or heat transfer medium (hereinafter the alcohol and the compound will generally be referred to as other compound).

As such other compound, the following compounds may be mentioned.

Fluorinated ether: Perfluoropropyl methyl ether (C₃F₇OCH₃), perfluorobutyl methyl ether (C₄F₉OCH₃), perfluorobutyl ethyl ether (C₄F₉OC₂H₅), 1,1,2,2-tetrafluoroethyl-2,2,2-trifluoroethyl ether (CF₂HCF₂OCH₂CF₃, manufactured by Asahi Glass Company, Limited, AE-3000), etc.

The content of such other compound is not limited within a range not to remarkably decrease the effects of the present invention, and is preferably at most 30 mass %, more preferably at most 20 mass %, particularly preferably at most 15 mass % in the working medium-containing composition (100 mass %).

<Heat Cycle System>

The heat cycle system of the present invention is a system employing the working medium of the present invention.

The heat cycle system may, for example, be a Rankine cycle system, a heat pump cycle system, a refrigerating cycle system or a heat transport system.

(Refrigerating Cycle System)

As an example of the heat cycle system, a refrigerating cycle system will be described.

The refrigerating cycle system is a system wherein in an evaporator, a working medium removes heat energy from a load fluid to cool the load fluid thereby to accomplish cooling to a lower temperature.

FIG. 1 is a schematic construction view illustrating an example of a refrigerating cycle system of the present invention. A refrigerating cycle system 10 is a system generally comprising a compressor 11 to compress a working medium vapor A to form a high temperature/high pressure working medium vapor B, a condenser 12 to cool and liquefy the working medium vapor B discharged from the compressor 11 to form a low temperature/high pressure working medium C, an expansion valve 13 to let the working medium C discharged from the condenser 12 expand to form a low temperature/low pressure working medium D, an evaporator 14 to heat the working medium D discharged from the expansion valve 13 to form a high temperature/low pressure working medium vapor A, a pump 15 to supply a load fluid E to the evaporator 14, and a pump 16 to supply a fluid F to the condenser 12.

In the refrigerating cyclic system 10, the following cycle is repeated.

(i) A working medium vapor A discharged from an evaporator 14 is compressed by a compressor 11 to form a high temperature/high pressure working medium vapor B.

(ii) The working medium vapor B discharged from the compressor 11 is cooled and liquefied by a fluid F in a condenser 12 to form a low temperature/high pressure working medium C. At that time, the fluid F is heated to form a fluid F′, which is discharged from the condenser 12.

(iii) The working medium C discharged from the condenser 12 is expanded in an expansion valve 13 to form a low temperature/low pressure working medium D.

(iv) The working medium D discharged from the expansion valve 13 is heated by a load fluid E in an evaporator 14 to form a high temperature/low pressure working medium vapor A. At that time, the load fluid E is cooled and becomes a load fluid E′, which is discharged from the evaporator 14.

The refrigerating cycle system 10 is a cycle comprising an adiabatic isentropic change, an isenthalpic change and an isobaric change, and the state change of the working medium may be shown as in FIG. 2, when it is represented on a temperature-entropy chart.

In FIG. 2, the AB process is a process wherein adiabatic compression is carried out by the compressor 11 to change the high temperature/low pressure working medium vapor A to a high temperature/high pressure working medium vapor B. The BC process is a process wherein isobaric cooling is carried out in the condenser 12 to change the high temperature/high pressure working medium vapor B to a low temperature/high pressure working medium C. The CD process is a process wherein isenthalpic expansion is carried out by the expansion valve 13 to change the low temperature/high pressure working medium C to a low temperature/low pressure working medium D. The DA process is a process wherein isobaric heating is carried out in the evaporator 14 to have the low temperature/low pressure working medium D returned to a high temperature/low pressure working medium vapor A.

In the same manner, the state change of the working medium may be shown as in FIG. 3, when it is represented on a pressure-enthalpy chart.

(Moisture Concentration)

There is a problem of inclusion of moisture in the heat cycle system. Inclusion of moisture may cause freezing in a capillary tube, hydrolysis of the working medium or the lubricating oil, deterioration of materials by an acid component formed in heat cycle, formation of contaminants, etc. Particularly, the above-described ether lubricating oil, ester lubricating oil and the like have extremely high moisture absorbing properties and are likely to undergo hydrolysis, and inclusion of moisture decreases properties of the lubricating oil and may be a great cause to impair the long term reliability of a compressor. Further, in an automobile air conditioner, moisture tends to be included from a coolant hose or a bearing of a compressor used for the purpose of absorbing vibration. Accordingly, in order to suppress hydrolysis of the lubricating oil, it is necessary to suppress the moisture concentration in the heat cycle system. The moisture concentration of the working medium in the heat cycle system is preferably at most 100 ppm, more preferably at most 20 ppm.

As a method of suppressing the moisture concentration in the heat cycle system, a method of using a desiccating agent (such as silica gel, activated aluminum or zeolite) may be mentioned. The desiccating agent is preferably a zeolite desiccating agent in view of chemical reactivity of the desiccating agent and the working medium, and the moisture absorption capacity of the desiccating agent.

The zeolite desiccating agent is, in a case where a lubricating oil having a large moisture absorption as compared with a conventional mineral lubricating oil is used, preferably a zeolite desiccating agent containing a compound represented by the following formula (1) as the main component in view of excellent moisture absorption capacity.

M_2/nO.Al₂O₃.xSiO₂.yH₂O  (1)

wherein M is a group 1 element such as Na or K or a group 2 element such as Ca, n is the valence of M, and x and y are values determined by the crystal structure. The pore size can be adjusted by changing M.

To select the desiccating agent, the pore size and the fracture strength are important.

In a case where a desiccating agent having a pore size larger than the molecular size of the working medium is used, the working medium is adsorbed in the desiccating agent and as a result, chemical reaction between the working medium and the desiccating agent will occur, thus leading to undesired phenomena such as formation of non-condensing gas, a decrease in the strength of the desiccating agent, and a decrease in the adsorption capacity.

Accordingly, it is preferred to use as the desiccating agent a zeolite desiccating agent having a small pore size. Particularly preferred is sodium/potassium type A synthetic zeolite having a pore size of at most 3.5 Å. By using a sodium/potassium type A synthetic zeolite having a pore size smaller than the molecular size of the working medium, it is possible to selectively adsorb and remove only moisture in the heat cycle system without adsorbing the working medium. In other words, the working medium is less likely to be adsorbed in the desiccating agent, whereby heat decomposition is less likely to occur and as a result, deterioration of materials constituting the heat cycle system and formation of contaminants can be suppressed.

The size of the zeolite desiccating agent is preferably from about 0.5 to about 5 mm, since if it is too small, a valve or a thin portion in pipelines may be clogged, and if it is too large, the drying capacity will be decreased. Its shape is preferably granular or cylindrical.

The zeolite desiccating agent may be formed into an optional shape by solidifying powdery zeolite by a binding agent (such as bentonite). So long as the desiccating agent is composed mainly of the zeolite desiccating agent, other desiccating agent (such as silica gel or activated alumina) may be used in combination.

The proportion of the zeolite desiccating agent based on the working medium is not particularly limited.

(Chlorine Concentration)

If chlorine is present in the heat cycle system, it has adverse effects such as formation of a deposit by reaction with a metal, abrasion of the bearing, and decomposition of the working medium or the lubricating oil.

The chlorine concentration in the heat cycle system is preferably at most 100 ppm, particularly preferably at most 50 ppm by the mass ratio based on the working medium.

(Non-Condensing Gas Concentration)

If non-condensing gas is included in the heat cycle system, it has adverse effects such as heat transfer failure in the condenser or the evaporator and an increase in the working pressure, and it is necessary to suppress its inclusion as far as possible. Particularly, oxygen which is one of non-condensing gases reacts with the working medium or the lubricating oil and promotes their decomposition.

The non-condensing gas concentration is preferably at most 1.5 vol %, particularly preferably at most 0.5 vol % by the volume ratio based on the working medium, in a gaseous phase of the working medium.

Examples

Now, the present invention will be described in further detail with reference to Examples. However, it should be understood that the present invention is by no means restricted to such specific Examples.

(Evaluation of Refrigerating Cycle Performance)

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated as the cycle performance (the capacity and the efficiency) in a case where a working medium was applied to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14, the average condensing temperature of the working medium in a condenser 12, the supercooling degree of the working medium in the condenser 12, and the degree of superheat of the working medium in the evaporator 14, respectively. Further, it was assumed that there was no pressure loss in the equipment efficiency and in the pipelines and heat exchanger.

The refrigerating capacity Q and the coefficient of performance η are obtained from the following formulae (2) and (3) using the enthalpy h in each state (provided that a suffix attached to h indicates the state of the working medium).

Q=h _A −h _D  (2)

η=refrigerating capacity/compression work=(h_A−h_D)/(h_B−h_A)  (3)

The coefficient of performance means the efficiency in the refrigerating cycle system, and a higher coefficient of performance means that a higher output (refrigerating capacity) can be obtained by a smaller input (electric energy required to operate a compressor).

Further, the refrigerating capacity means a capacity to cool a load fluid, and a higher refrigerating capacity means that more works can be done in the same system. In other words, it means that with a working medium having a larger refrigerating capacity, the desired performance can be obtained with a smaller amount, whereby the system can be downsized.

The thermodynamic properties required for calculation of the refrigerating cycle performance were calculated based on the generalized equation of state (Soave-Redlich-Kwong equation) based on the law of corresponding state and various thermodynamic equations. If a characteristic value was not available, it was calculated employing an estimation technique based on a group contribution method.

Example 1

The refrigerating cycler performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where HFO-1132(Z) and HFO-1132(E) in a proportion as identified in Table 1 were applied as a working medium to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14 to be 0° C., the average condensing temperature of the working medium in a condenser 12 to be 50° C., the supercooling degree of the working medium in the condenser 12 to be 5° C., and the degree of superheat of the working medium in the evaporator 14 to be 5° C.

Based on the refrigerating cycle performance of HFC-134a in Example 2, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Table 1.

	TABLE 1
	Relative performance
	(based on HFC-134a) [—]
HFO-1132(Z)	HFO-1132(E)	Refrigerating	Coefficient of
[mass %]	[mass %]	capacity	performance
0	100	1.022	1.358
20	80	1.022	1.368
40	60	1.022	1.376
60	40	1.021	1.383
80	20	1.020	1.389
100	0	1.020	1.393

From the results in Table 1, it was confirmed that there was no distinct difference among cases where HFO-1132(Z) and HFO-1132(E) were used alone and a case where they were used in combination.

Example 2

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where a working medium comprising HFO-1132(Z) and a HFC as identified in Table 2 was applied to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14 to be 0° C., the average condensing temperature of the working medium in a condenser 12 to be 50° C., the supercooling degree of the working medium in the condenser 12 to be 5° C., and the degree of superheat of the working medium in the evaporator 14 to be 5° C.

Based on the refrigerating cycle performance of HFC-134a, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Table 2.

TABLE 2
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-	HFC-	134a) [—]	HFO-	HFC-	134a) [—]
1132(Z)	125	Coefficient of	Refrigerating	1132(Z)	134a	Coefficient of
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance
0	100	0.795	1.517	0	100	1.000
20	80	0.864	1.635	20	80	0.992
40	60	0.924	1.641	40	60	0.994
60	40	0.968	1.583	60	40	1.004
80	20	0.998	1.495	80	20	1.012
100	0	1.020	1.393	100	0	1.020
	Relative performance			Relative performance
	(based on HFC-			(based on HFC-
	134a) [—]	HFO-	HFC-	134a) [—]
	Refrigerating	1132(Z)	32	Coefficient of	Refrigerating
	capacity	[mass %]	[mass %]	performance	capacity
	1.000	0	100	0.918	2.518
	1.186	20	80	0.920	2.422
	1.310	40	60	0.932	2.243
	1.381	60	40	0.954	2.003
	1.404	80	20	0.989	1.732
	1.393	100	0	1.020	1.393

From the results in Table 2, it was confirmed that the refrigerating capacity of HFO-1132(Z) could be improved by adding HFC-125 or HFC-32 to HFO-1132(Z). Further, by addition of HFC-134a, the refrigerating capacity could be maintained without a remarkable decrease of the coefficient of performance.

Example 3

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where a working medium comprising HFO-1132(E) and a HFC as identified in Table 3 was applied to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14 to be 0° C., the average condensing temperature of the working medium in a condenser 12 to be 50° C., the supercooling degree of the working medium in the condenser 12 to be 5° C., and the degree of superheat of the working medium in the evaporator 14 to be 5° C.

Based on the refrigerating cycle performance of HFC-134a in Example 2, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Table 3.

TABLE 3
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-	HFC-	134a) [—]	HFO-	HFC-	134a) [—]
1132(E)	125	Coefficient of	Refrigerating	1132(E)	134a	Coefficient of
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance
0	100	0.795	1.517	0	100	1.000
20	80	0.859	1.616	20	80	0.989
40	60	0.918	1.613	40	60	0.991
60	40	0.964	1.550	60	40	1.001
80	20	0.997	1.460	80	20	1.012
100	0	1.022	1.358	100	0	1.022
	Relative performance			Relative performance
	(based on HFC-			(based on HFC-
	134a) [—]	HFO-	HFC-	134a) [—]
	Refrigerating	1132(E)	32	Coefficient of	Refrigerating
	capacity	[mass %]	[mass %]	performance	capacity
	1.000	0	100	0.918	2.518
	1.177	20	80	0.921	2.410
	1.293	40	60	0.934	2.220
	1.356	60	40	0.958	1.974
	1.372	80	20	0.988	1.689
	1.358	100	0	1.022	1.358

From the results in Table 3, it was confirmed that the refrigerating capacity of HFC-1132(E) could be improved by adding HFC-125 or HFC-32 to HFC-1132(E). Further, by addition of HFC-134a, the refrigerating capacity could be maintained without a remarkable decrease of the coefficient of performance.

Example 4

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where a working medium comprising HFC-1132(Z) and a HFC as identified in Table 4 or 5 was applied to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14 to be 0° C., the average condensing temperature of the working medium in a condenser 12 to be 50° C., the supercooling degree of the working medium in the condenser 12 to be 5° C., and the degree of superheat of the working medium in the evaporator 14 to be 5° C.

Based on the refrigerating cycle performance of HFC-134a in Example 2, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Tables 4 and 5.

TABLE 4
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-	HFO-	134a) [—]	HFO-	HFO-	134a) [—]
1132(Z)	1225ye(E)	Coefficient of	Refrigerating	1132(Z)	1225ye(Z)	Coefficient of	Refrigerating
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance	capacity
0	100	1.024	0.663	0	100	1.005	0.767
20	80	1.019	0.921	20	80	1.004	1.014
40	60	1.014	1.109	40	60	1.005	1.183
60	40	1.016	1.248	60	40	1.012	1.297
80	20	1.019	1.340	80	20	1.017	1.362
100	0	1.020	1.393	100	0	1.020	1.393

TABLE 5
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-	HFO-	134a) [—]	HFO-	HFO-	134a) [—]
1132(Z)	1234ze(E)	Coefficient of	Refrigerating	1132(Z)	1243zf	Coefficient of	Refrigerating
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance	capacity
0	100	0.996	0.752	0	100	0.995	0.978
20	80	0.995	0.986	20	80	0.997	1.135
40	60	0.998	1.161	40	60	1.002	1.252
60	40	1.007	1.288	60	40	1.009	1.333
80	20	1.015	1.362	80	20	1.015	1.377
100	0	1.020	1.393	100	0	1.020	1.393

From the results in Tables 4 and 5, it was confirmed that HFO1132(Z) had a higher refrigerating capacity as compared with conventional HFO. Further, by combination of HFO-1132(Z) and HFO-1225ye(E) or HFO-1225ye(Z), the coefficient of performance could be maintained without a remarkable decrease of the refrigerating capacity.

Example 53

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where a working medium comprising HFO-1132(E) and a HFC as identified in Table 6 or 7 was applied to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14 to be 0° C., the average condensing temperature of the working medium in a condenser 12 to be 50° C., the supercooling degree of the working medium in the condenser 12 to be 5° C., and the degree of superheat of the working medium in the evaporator 14 to be 5° C.

Based on the refrigerating cycle performance of HFC-134a in Example 2, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Tables 6 and 7.

TABLE 6
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-	HFO-	134a) [—]	HFO-	HFO-	134a) [—]
1132(E)	1225ye(E)	Coefficient of	Refrigerating	1132(E)	1225ye(Z)	Coefficient of	Refrigerating
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance	capacity
0	100	1.024	0.663	0	100	1.005	0.767
20	80	1.016	0.914	20	80	1.000	1.005
40	60	1.010	1.093	40	60	1.000	1.166
60	40	1.012	1.224	60	40	1.008	1.271
80	20	1.018	1.309	80	20	1.016	1.330
100	0	1.022	1.358	100	0	1.022	1.358

TABLE 7
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-	HFO-	134a) [—]	HFO-	HFO-	134a) [—]
1132(E)	1234ze(E)	Coefficient of	Refrigerating	1132(E)	1243zf	Coefficient of	Refrigerating
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance	capacity
0	100	0.996	0.752	0	100	0.995	0.978
20	80	0.992	0.978	20	80	0.994	1.126
40	60	0.993	1.145	40	60	0.998	1.235
60	40	1.002	1.263	60	40	1.005	1.308
80	20	1.013	1.331	80	20	1.013	1.347
100	0	1.022	1.358	100	0	1.022	1.358

From the results in Tables 6 and 7, it was confirmed that HFO1132(E) had a higher refrigerating capacity as compared with conventional HFO. Further, by combination of HFO-1132(E) and HFO-1225ye(E) or HFO-1225ye(Z), the coefficient of performance could be maintained without a remarkable decrease of the refrigerating capacity.

Example 6

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where a working medium comprising HFO-1132(E) and a hydrocarbon as identified in Table 8 was applied to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14 to be 0° C., the average condensing temperature of the working medium in a condenser 12 to be 50° C., the supercooling degree of the working medium in the condenser 12 to be 5° C., and the degree of superheat of the working medium in the evaporator 14 to be 5° C.

Based on the refrigerating cycle performance of HFC-134a in Example 2, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Table 8.

TABLE 8
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-		134a) [—]	HFO-		134a) [—]
1132(E)	Isobutane	Coefficient of	Refrigerating	1132(E)	Butane	Coefficient of
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance
0	100	1.038	0.540	0	100	1.065
20	80	1.039	0.670	20	80	1.063
40	60	1.040	0.816	40	60	1.067
60	40	1.034	0.979	60	40	1.055
80	20	1.026	1.165	80	20	1.034
90	10	1.025	1.265	90	10	1.027
92	8	1.024	1.284	92	8	1.026
94	6	1.024	1.303	94	6	1.026
96	4	1.023	1.322	96	4	1.025
98	2	1.023	1.340	98	2	1.024
100	0	1.022	1.358	100	0	1.022
	Relative performance			Relative performance
	(based on HFC-			(based on HFC-
	134a) [—]	HFO-		134a) [—]
	Refrigerating	1132(E)	Propane	Coefficient of	Refrigerating
	capacity	[mass %]	[mass %]	performance	capacity
	0.393	0	100	0.977	1.340
	0.516	20	80	0.977	1.391
	0.666	40	60	0.980	1.432
	0.841	60	40	0.987	1.453
	1.060	80	20	1.001	1.436
	1.201	90	10	1.010	1.407
	1.232	92	8	1.012	1.399
	1.263	94	6	1.015	1.390
	1.294	96	4	1.017	1.380
	1.326	98	2	1.020	1.370
	1.358	100	0	1.022	1.358

From the results in Table 8, it was confirmed that the refrigerating capacity of HFO-1132(E) could be improved by adding propane to HFO-1132(E). Further, it was confirmed that by addition of isobutane or butane, the coefficient of performance was improved, and the decrease of the refrigerating capacity could be suppressed up to an addition amount of about 20 mass %.

Example 7

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where a working medium comprising HFO-1132(Z) and a hydrocarbon as identified in Table 9 was applied to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14 to be 0° C., the average condensing temperature of the working medium in a condenser 12 to be 50° C., the supercooling degree of the working medium in the condenser 12 to be 5° C., and the degree of superheat of the working medium in the evaporator 14 to be 5° C.

Based on the refrigerating cycle performance of HFC-134a in Example 2, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Table 9.

TABLE 9
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-		134a) [—]	HFO-		134a) [—]
1132(Z)	Isobutane	Coefficient of	Refrigerating	1132(Z)	Butane	Coefficient of
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance
0	100	1.038	0.540	0	100	1.065
20	80	1.042	0.673	20	80	1.065
40	60	1.044	0.824	40	60	1.070
60	40	1.038	0.992	60	40	1.058
80	20	1.029	1.188	80	20	1.035
90	10	1.026	1.293	90	10	1.027
92	8	1.025	1.314	92	8	1.026
94	6	1.024	1.334	94	6	1.025
96	4	1.022	1.354	96	4	1.023
98	2	1.021	1.374	98	2	1.021
100	0	1.020	1.393	100	0	1.020
	Relative performance			Relative performance
	(based on HFC-			(based on HFC-
	134a) [—]	HFO-		134a) [—]
	Refrigerating	1132(Z)	Propane	Coefficient of	Refrigerating
	capacity	[mass %]	[mass %]	performance	capacity
	0.393	0	100	0.977	1.340
	0.518	20	80	0.979	1.397
	0.672	40	60	0.984	1.446
	0.851	60	40	0.991	1.475
	1.079	80	20	1.003	1.466
	1.226	90	10	1.011	1.440
	1.259	92	8	1.012	1.432
	1.292	94	6	1.014	1.424
	1.325	96	4	1.016	1.415
	1.359	98	2	1.018	1.404
	1.393	100	0	1.020	1.393

From the results in Table 9, it was confirmed that the refrigerating capacity of HFC-1132(Z) could be improved by adding propane to HFO-1132(Z). Further, it was confirmed that by addition of isobutane or butane, the coefficient of performance was improved, and the decrease of the refrigerating capacity could be suppressed up to an addition amount of about 20 mass %.

Example 8

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where a working medium comprising HFC-1132(Z) and a HCFC as identified in Table 10 was applied to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14 to be 0° C., the average condensing temperature of the working medium in a condenser 12 to be 50° C., the supercooling degree of the working medium in the condenser 12 to be 5° C., and the degree of superheat of the working medium in the evaporator 14 to be 5° C.

Based on the refrigerating cycle performance of HFC-134a in Example 2, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Table 10.

TABLE 10
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-	HCFO-	134a) [—]	HFO-	HCFO-	134a) [—]
1132(Z)	1224yd	Coefficient of	Refrigerating	1132(Z)	1122	Coefficient of	Refrigerating
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance	capacity
0	100	1.061	0.357	0	100	1.099	0.526
20	80	1.061	0.638	20	80	1.078	0.729
40	60	1.043	0.863	40	60	1.058	0.909
60	40	1.022	1.056	60	40	1.038	1.077
80	20	1.020	1.242	80	20	1.027	1.242
90	10	1.021	1.324	90	10	1.023	1.321
92	8	1.021	1.338	92	8	1.022	1.336
94	6	1.021	1.353	94	6	1.022	1.350
96	4	1.020	1.367	96	4	1.021	1.365
98	2	1.020	1.380	98	2	1.020	1.379
100	0	1.020	1.393	100	0	1.020	1.393

From the results in Table 10, it was confirmed that the coefficient of performance was increased without an extreme decrease of the refrigerating capacity of HFO-1132(Z), by adding HCFO to HFO-1132(Z).

Example 9

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where a working medium comprising HFO-1132(E) and a HCFO as identified in Table 11 was applied to a refrigerating cycle system 10 shown in FIG. 1.

Evaluation was carried out by setting the average evaporation temperature of the working medium in an evaporator 14 to be 0° C., the average condensing temperature of the working medium in a condenser 12 to be 50° C., the supercooling degree of the working medium in the condenser 12 to be 5° C., and the degree of superheat of the working medium in the evaporator 14 to be 5° C.

Based on the refrigerating cycle performance of HFC-134a in Example 2, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Table 11.

TABLE 11
		Relative performance			Relative performance
		(based on HFC-			(based on HFC-
HFO-	HCFO-	134a) [—]	HFO-	HCFO-	134a) [—]
1132(E)	1224yd	Coefficient of	Refrigerating	1132(E)	1122	Coefficient of	Refrigerating
[mass %]	[mass %]	performance	capacity	[mass %]	[mass %]	performance	capacity
0	100	1.061	0.357	0	100	1.099	0.526
20	80	1.058	0.633	20	80	1.078	0.724
40	60	1.040	0.852	40	60	1.059	0.899
60	40	1.021	1.038	60	40	1.040	1.061
80	20	1.020	1.215	80	20	1.029	1.217
90	10	1.022	1.293	90	10	1.026	1.291
92	8	1.022	1.307	92	8	1.025	1.305
94	6	1.022	1.320	94	6	1.025	1.318
96	4	1.023	1.333	96	4	1.024	1.332
98	2	1.022	1.346	98	2	1.023	1.345
100	0	1.022	1.358	100	0	1.022	1.358

From the results in Table 11, it was confirmed that the coefficient of performance was increased without an extreme decrease of the refrigerating capacity of HFC-1132(E), by adding HCFC to HFO-1132(E).

Example 10

The refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) was evaluated in a case where HFC-1132(E), FIFO-1132(Z) or 1,1-difluoroethylene (HFC-1132a) was applied as a working medium to a refrigerating cycle system 10 shown in FIG. 1.

The evaporation temperature of the working medium in an evaporator 14, the condensing temperature of the working medium in a condenser 12, the supercooling degree of the working medium in the condenser 12 and the degree of superheat of the working medium in the evaporator 14 were temperatures as identified in Table 12.

Based on the refrigerating cycle performance of HFC-134a in Example 2, the relative performance (each working medium/HFC-134a) of the refrigerating cycle performance (the refrigerating capacity and the coefficient of performance) of each working medium based on HFC-134a was obtained. The results of each working medium are shown in Table 12.

	TABLE 12
	Relative performance (based on HFC-134a) [—]
Evaporation	Condensing	Degree of	Supercooling	HFO-1132(Z)	HFO-1132(E)	HFO-1132a
temperature	temperature	superheat	degree	Coefficient of	Refrigerating	Coefficient of	Refrigerating	Coefficient of	Refrigerating
[° C.]	[° C.]	[° C.]	[° C.]	performance	capacity	performance	capacity	performance	capacity
−40	10	5	5	0.987	1.619	1.001	1.582	0.800	7.271
−30	20	5	5	0.995	1.543	1.006	1.507	—	—
−20	30	5	5	1.004	1.481	1.012	1.446	—	—
−10	40	5	5	1.012	1.432	1.017	1.397	—	—
0	50	5	5	1.020	1.393	1.022	1.358	—	—
10	60	5	5	1.029	1.364	1.029	1.328	—	—
20	70	5	5	1.040	1.346	1.039	1.308	—	—
30	80	5	5	1.057	1.340	1.053	1.300	—	—
40	90	5	5	1.087	1.355	1.079	1.310	—	—

From the results in Table 12, it was confirmed that HFO-1132 had a higher coefficient of performance as compared with FIFO-1132a. Here, HFO-1132a has a too low critical temperature, whereby a supercritical cycle will form at a condensing temperature of at least 20° C., and accordingly evaluation was not conducted.

INDUSTRIAL APPLICABILITY

The working medium of the present invention is useful as a working medium for heat cycle such as a coolant for a refrigerator, a coolant for an air conditioner, a working fluid for power generation system (such as exhaust heat recovery power generation), a working medium for a latent heat transport apparatus (such as a heat pipe) or a secondary cooling medium.

This application is a continuation of PCT Application No. PCT/JP2012/062844, filed on May 18, 2012, which is based upon and claims the benefit of priority from Japanese Patent Application No. 2011-112416 filed on May 19, 2011. The contents of those applications are incorporated herein by reference in its entirety.

REFERENCE SYMBOL

• • 10: Refrigerating cycle system

Claims

1-13. (canceled)

14. A working medium for heat cycle, comprising: 1,2-difluoroethylene,at least one hydrofluoroolefin other than 1,2-difluoroethylene, andoptionally, at least one hydrofluorocarbon.

15. The working medium of claim 14, comprising the at least one hydrofluorocarbon.

16. The working medium of claim 15, wherein the at least one hydrofluorocarbon is difluoromethane.

17. The working medium of claim 14, comprising at least 60 mass %, based on the mass of the working medium, of the 1,2-difluoroethylene.

18. The working medium of claim 15, comprising from 1 to 30 mass %, based on the mass of the working medium, of the at least one hydrocarbon.

19. The working medium of claim 18, wherein the at least one hydrocarbon is selected from the group consisting of propane, propylene, cyclopropane, butane, isobutane, pentane, and isopentane.

20. The working medium of claim 14, comprising from 1 to 99 mass %, based on the mass of the working medium, of difluoromethane.

21. The working medium of claim 14, comprising from 1 to 60 mass %, based on the mass of the working medium, of difluoromethane.

22. The working medium of claim 14, comprising difluoromethane and pentafluoroethane.

23. The working medium of claim 14, further comprising at least one compound selected from the group consisting of a hydrochlorofluoroolefin or a chlorofluoroolefin.

24. The working medium of claim 23, wherein a total content of the hydrochlorofluoroolefin and the chlorofluoroolefin is from 1 to 60 mass %, based on the mass of the working medium.

25. A heat cycle system, comprising the working medium according to claim 14, an evaporator, a compressor, a condenser, an expansion valve, and a load fluid.

26. The working medium of claim 14, wherein the 1,2-difluoroethylene is (E)-1,2-difluoroethylene.