CN101892033A - Hydrocarbon-containing medium-high temperature heat pump mixture - Google Patents

Abstract

The invention discloses a set of hydrocarbon-containing medium-high temperature heat pump mixture, which is suitable for serving as a low-temperature organic Rankine cycle system refrigerant the evaporation temperature of which is 60-100 DEG C. The set of mixed working fluid can be a binary, tertiary or quaternary mixture prepared from eight substances (R600, R600a, R290, R245fa, R13I1, R152a, R124 and R142b) according to different mass ratios. The preparation method comprises the step of physically mixing the various components according to a specific proportion at ordinary temperature to obtain the corresponding mixed working fluid. The working fluid does not cause damage to the ozonosphere, and the greenhouse effect potential is lower, thereby meeting the environmental requirements. The thermal parameters are eligible and the cycle performance is fine, so the working fluid can be directly filled in an HFC134a air conditioning compressor, thereby avoiding specially designing a compressor for the working fluid. Besides, COP under design conditions is 4 or so, and the output net work per unit mass is above 150kJ/kg.

Description

The moderate and high temperature heat mixing medium that contains hydrocarbon polymer

Technical field

The invention belongs to the refrigeration agent in heat pump or the air-conditioning system, being specifically related to as condensing temperature is refrigeration working medium in 60-100 ℃ the moderate and high temperature heat system.

Background technology

For produce and life in a large amount of that exist, to heat energy grade requirement relatively low (temperature is 60-100 ℃) with alleviating, adopt the heat pump heat supply technology that the total energy utilising efficiency higher than conventional energy-provision way not only arranged, reduce the CO2 discharging, can also effectively utilize the low grade heat energy that contains in industrial exhaust heat, Geothermal energy, sun power and the environment (air, soil, surface water or shallow ground water), reduce the thermal pollution that the waste heat discharging causes.Current, high temperature in the heat pump techniques forward (condensing temperature 80-100 ℃), high temperature (condensing temperature is higher than 100 ℃) heat pump direction develop, and restrict one of key issue of its development, are exactly to lack the cycle fluid that is fit to.The material that in the past once was used as high temperature heat pump system working medium has CFC11, CFC113, CFC114 etc., they are CFC class material, its depletion of the ozone layer gesture (ODP) and global warming potential (GWP) are all very big, and developed country is in forbidding in 1996, and developing country also will be in forbidding in 2010.Using at present more is to be the air-conditioning-heat pump of working medium with HCFC22 or its surrogate R407C etc., and the hot water top temperature that can provide is 50-55 ℃, and the heat energy of higher temperature level can't be provided.Development environment close friend, the good novel working medium of thermal performance are most important to the development of moderate and high temperature heat technology.

Mixing medium provided by the invention is for condensing temperature is that 60-100 ℃ moderate and high temperature heat system applies is developed, and also can be used as centrifugal refrigerating, air conditioning unit working medium.

Summary of the invention

The objective of the invention is, provide one group to contain the new working medium that hydrocarbon polymer is suitable for the application of moderate and high temperature heat unit, make its environmental characteristics and environmental performance all good.

Content introduction of the present invention: carry out the constituent element combination according to the principle of having complementary advantages, screening obtains the moderate and high temperature heat mixing medium of following excellent property.Specifically comprise: butane (R600), Trimethylmethane (R600a), propane (R290), 1,1,1,3,3-pentafluoropropane (R245fa), CF3I (R13I1), 1,1-C2H4F2 C2H4F2 (R152a), a chloro-1,2,2, a 2-Tetrafluoroethane (R124) and a chloro-1,1-C2H4F2 C2H4F2 (R142b).The basic parameter of each constituent element material is as shown in table 1.

The moderate and high temperature heat mixing medium that contains HC600, HC600a and HC290 that the present invention proposes, by butane (R600) and 1,1,1,3,3-pentafluoropropane (R245fa) is formed; Or by Trimethylmethane (R600a) and 1,1,1,3,3-pentafluoropropane (R245fa); Trimethylmethane (R600a) is formed, or by 1,1,1,3,3-pentafluoropropane (R245fa) and CF3I (R13I1) are formed; Or by butane (R600), 1,1,1,3,3-pentafluoropropane (R245fa) and 1,1-C2H4F2 C2H4F2 (R152a) is formed; Or by Trimethylmethane (R600a), 1,1,1,3,3-pentafluoropropane (R245fa) and 1,1-C2H4F2 C2H4F2 (R152a) is formed; Or by a chloro-1,1-C2H4F2 C2H4F2 (R142b), a chloro-1,2,2,2-Tetrafluoroethane (R124), Trimethylmethane (R600a) and 1,1,1,3,3-pentafluoropropane (R245fa) is formed; Or by a Trimethylmethane (R600a) and a chloro-1,1-C2H4F2 C2H4F2 (R142b) is formed; Or form by Trimethylmethane (R600a) and CF3I (R13I1); Or form by butane (R600) and CF3I (R13I1); Or by propane (R290) and 1,1,1,3,3-pentafluoropropane (R245fa) is formed; Or by a propane (R290) and a chloro-1,2,2,2-Tetrafluoroethane (R124) is formed; Or by a propane (R290) and a chloro-1,1-C2H4F2 C2H4F2 (R142b) is formed.

The concrete proportioning (mass percent) of above-mentioned each constituent element material is:

R600/R245fa 2-97/3-98％，

R600a/R245fa 3-98/2-97％，

R600a/R245fa/R13I1 3-97/2-96/1-95％，

R600/R245fa/R152a 4-90/5-91/5-91％，

R600a/R245fa/R152a 3-93/4-94/3-93％，

R142b/R124/R600a/R245fa 2-94/3-95/2-94/1-93％，

R600a/R142b 2-97/3-98％，

R600a/R13I1 2-97/3-98％，

R600/R13I1 2-97/3-98％，

R290/R245fa 2-97/3-98％，

R290/R124 2-97/3-98％，

R290/R142b 2-97/3-98％，

More than each constituent element material mass percentage ratio sum of every kind of mixing medium be 100%.

The preparation method of above-mentioned mixing medium is each constituent element material to be carried out physical mixed at normal temperatures by its specified quality proportioning get final product.More than each constituent element material mass percentage ratio sum of every kind of mixing medium be 100%.

The present invention has the following advantages and beneficial effect:

(1) environmental performance: ODP of the present invention equals zero or is lower, and environmental characteristics is good.

(2) thermal parameter is suitable: under moderate and high temperature heat system design operating mode, stress level is not higher than the stress level of HFC134a under the standard air conditioning condition, and row's temperature is lower than the exhaust temperature restriction of HFC134a compressor.Therefore, can directly working medium of the present invention be poured into the compressor of air conditioner of HFC134a, need not to be working medium otherwise designed compressor of the present invention.

(3) cycle performance is good: the present invention is heating that COP is about 4, more than 150kJ/kg, the unit volume heating capacity is at 3000kJ/m substantially for the unit mass heat supplied under the above-mentioned design conditions ³More than, cycle performance is good.

The basic parameter of contained constituent element in the table 1 moderate and high temperature heat mixing medium

T _b: normal boiling point, T _c: critical temperature, P _c: emergent pressure

Embodiment

Embodiment 1: get 20 ^Mass%R600 and 80 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 2: get 55 ^Mass%R600 and 45 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 3: get 75 ^Mass%R600 and 25 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 4: get 25 ^Mass%R600a and 75 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 5: get 50 ^Mass%R600a and 50 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 6: get 70 ^Mass%R600a and 30 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 7: get 20 ^Mass%R600a, 70 ^Mass%R245fa and 10 ^Mass%R13I1 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 8: get 30 ^Mass%R600a, 10 ^Mass%R245fa and 60 ^Mass%R13I1 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 9: get 70 ^Mass%R600a, 20 ^Mass%R245fa and 10 ^Mass%R13I1 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 10: get 10 ^Mass%R600,70 ^Mass%R245fa and 20 ^Mass%R152a carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 11: get 30 ^Mass%R600,20 ^Mass%R245fa and 50 ^Mass%R152a carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 12: get 70 ^Mass%R600,20 ^Mass%R245fa and 10 ^Mass%R152a carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 13: get 25 ^Mass%R600a, 65 ^Mass%R245fa and 10 ^Mass%R152a carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 14: get 30 ^Mass%R600a, 10 ^Mass%R245fa and 60 ^Mass%R152a carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 15: get 70 ^Mass%R600a, 20 ^Mass%R245fa and 10 ^Mass%R152a carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 16: get 20 ^Mass%R142b, 60 ^Mass%R124,10 ^Mass%R600a and 10 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 17: get 30 ^Mass%R142b, 10 ^Mass%R124,50 ^Mass%R600a and 10 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 18: get 70 ^Mass%R142b, 10 ^Mass%R124,10 ^Mass%R600a and 10 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 19: get 30 ^Mass%R600a and 70 ^Mass%R142b carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 20: get 50 ^Mass%R600a and 50 ^Mass%R142b carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 21: get 75 ^Mass%R600a and 25 ^Mass%R142b carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 22: get 25 ^Mass%R600a and 75 ^Mass%R13I1 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 23: get 50 ^Mass%R600a and 50 ^Mass%R13I1 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 24: get 95 ^Mass%R600a and 5 ^Mass%R13I1 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 25: get 20 ^Mass%R600 and 80 ^Mass%R13I1 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 26: get 50 ^Mass%R600 and 50 ^Mass%R13I1 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 27: get 90 ^Mass%R600 and 10 ^Mass%R13I1 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 28: get 30 ^Mass%R290 and 70 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 29: get 55 ^Mass%R290 and 45 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 30: get 80 ^Mass%R290 and 20 ^Mass%R245fa carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 31: get 2 ^Mass%R290 and 98 ^Mass%R124 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 32: get 45 ^Mass%R290 and 55 ^Mass%R124 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 33: get 85 ^Mass%R290 and 15 ^Mass%R124 carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 34: get 6 ^Mass%R290 and 94 ^Mass%R142b carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 35: get 30 ^Mass%R290 and 70 ^Mass%R142b carries out after the physical mixed at normal temperatures as refrigeration agent.

Embodiment 36: get 80 ^Mass%R290 and 20 ^Mass%R142b carries out after the physical mixed at normal temperatures as refrigeration agent.

The design conditions of heat pump are taken as: average vaporization temperature is 45 ℃, 90 ℃ of average condensing temperatures, and 2 ℃ of suction superheat (, avoiding wet compression with assurance) with suitable exhaust superheating temperature to some working medium, condensate depression is 0 ℃.With closed piston compressor is example, and compressor heat efficient gets 0.9, and electrical efficiency, mechanical efficiency are 0.75, and the clearance volume coefficient gets 0.03.

According to cycle calculations, above-mentioned 36 embodiment have related parameter and cycle performance index as shown in table 2.

Table 2 embodiment of the invention performance

Parameter and performance	Embodiment 1	Embodiment 2	Embodiment 3	Embodiment 4	Embodiment 5	Embodiment 6
							Evaporating pressure MPa	0.35	0.39	0.41	0.41	0.48	0.54
Condensing pressure MPa	1.11	1.19	1.22	1.26	1.43	1.53
							Pressure ratio	3.2	3.01	2.95	3.11	2.95	2.85
Exhaust temperature ℃	96.7	97	97	98	98	97.5
							COP h	4.34	4.35	4.36	4.25	4.20	4.16
Heat supplied kJ/kg	141	181	204	140	159	173
							Unit volume heating capacity kJ/m 3	2019	2185	2248	2244	2487	2624

Parameter and performance	Embodiment 7	Embodiment 8	Embodiment 9	Embodiment 10	Embodiment 11	Embodiment 12
							Evaporating pressure MPa	0.41	0.63	0.56	0.45	0.64	0.45
Condensing pressure MPa	1.28	1.75	1.58	1.45	1.9	1.34
							Pressure ratio	3.11	2.78	2.8	3.2	3.0	2.97
Exhaust temperature ℃	98.8	102	97.8	105	110	99.7
							COP h	4.26	4.15	4.15	4.29	4.23	4.34
Heat supplied kJ/kg	130	105	16	149	189	207
							Unit volume heating capacity kJ/m 3	2281	3000	2703	2625	3383	2452
Parameter and performance	Embodiment 13	Embodiment 14	Embodiment 15	Embodiment 16	Embodiment 17	Embodiment 18
							Evaporating pressure MPa	0.46	0.79	0.59	0.60	0.58	0.58
Condensing pressure MPa	1.44	2.26	1.66	1.75	1.64	1.68
							Pressure ratio	3.1	2.8	2.8	2.9	2.8	2.9
Exhaust temperature ℃	101	110	99	102	99	104
							COP h	4.23	4.06	4.14	4.12	4.17	4.25
Heat supplied kJ/kg	149	175	179	108	156	130
							Unit volume heating capacity kJ/m 3	2546	3785	2837	2963	2827	2989

Parameter and performance	Embodiment 19	Embodiment 20	Embodiment 21	Embodiment 22	Embodiment 23	Embodiment 24
							Evaporating pressure MPa	0.61	0.61	0.61	0.70	0.65	0.60
Condensing pressure MPa	1.71	1.69	1.67	1.89	1.76	1.66
							Pressure ratio	2.8	2.8	2.8	2.7	2.7	2.7
Exhaust temperature ℃	102	100	98	103	100	97
							COP h	4.22	4.18	4.14	4.13	4.12	4.11
Heat supplied kJ/kg	147	160	177	91	125	187
							Unit volume heating capacity kJ/m 3	3001	2919	2836	3212	2979	2784

Parameter and performance	Embodiment 25	Embodiment 26	Embodiment 27	Embodiment 28	Embodiment 29	Embodiment 30
							Evaporating pressure MPa	0.61	0.50	0.44	0.68	0.99	1.30
Condensing pressure MPa	1.70	1.43	1.28	2.13	2.83	3.41
							Pressure ratio	2.8	2.9	2.9	3.1	2.8	2.6
Exhaust temperature ℃	106	101	97	112	113	111
							COP h	4.27	4.33	4.36	3.99	3.67	3.33
Heat supplied kJ/kg	94	147	215	155	160	149
							Unit volume heating capacity kJ/m 3	3056	2610	2350	3489	4137	4301

Parameter and performance	Embodiment 31	Embodiment 32	Embodiment 33	Embodiment 34	Embodiment 35	Embodiment 36
							Evaporating pressure MPa	0.71	1.19	1.46	0.68	0.93	1.38
Condensing pressure MPa	2.03	3.13	3.65	1.93	2.55	3.50
							Pressure ratio	2.9	2.6	2.5	2.8	2.7	2.5
Exhaust temperature ℃	103	109	109	108	111	109
							COP h	3.92	3.44	3.12	4.22	3.92	3.30
Heat supplied kJ/kg	84	114	128	133	145	142
							Unit volume heating capacity kJ/m 3	3218	4125	4148	3407	4075	4330

Claims (2)

1. the moderate and high temperature heat mixing medium that contains hydrocarbon polymer is characterized in that by butane (R600) and 1,1,1,3, and 3-pentafluoropropane (R245fa) is formed; Or by Trimethylmethane (R600a) and 1,1,1,3,3-pentafluoropropane (R245fa); Trimethylmethane (R600a) is formed, or by 1,1,1,3,3-pentafluoropropane (R245fa) and CF3I (R13I1) are formed; Or by butane (R600), 1,1,1,3,3-pentafluoropropane (R245fa) and 1,1-C2H4F2 C2H4F2 (R152a) is formed; Or by Trimethylmethane (R600a), 1,1,1,3,3-pentafluoropropane (R245fa) and 1,1-C2H4F2 C2H4F2 (R152a) is formed; Or by a chloro-1,1-C2H4F2 C2H4F2 (R142b), a chloro-1,2,2,2-Tetrafluoroethane (R124), Trimethylmethane (R600a) and 1,1,1,3,3-pentafluoropropane (R245fa) is formed; Or by a Trimethylmethane (R600a) and a chloro-1,1-C2H4F2 C2H4F2 (R142b) is formed; Or form by Trimethylmethane (R600a) and CF3I (R13I1); Or form by butane (R600) and CF3I (R13I1); Or by propane (R290) and 1,1,1,3,3-pentafluoropropane (R245fa) is formed; Or by a propane (R290) and a chloro-1,2,2,2-Tetrafluoroethane (R124) is formed; Or by a propane (R290) and a chloro-1,1-C2H4F2 C2H4F2 (R142b) is formed.

2. according to the described moderate and high temperature heat mixing medium that contains hydrocarbon polymer of claim 1, it is characterized in that the concrete proportioning (mass percent) of described each constituent element material is:

R600/R245fa 2-97/3-98％，

R600a/R245fa 3-98/2-97％，

R600a/R245fa/R13I1 3-97/2-96/1-95％，

R600/R245fa/R152a 4-90/5-91/5-91％，

R600a/R245fa/R152a 3-93/4-94/3-93％，

R142b/R124/R600a/R245fa 2-94/3-95/2-94/1-93％，

R600a/R142b 2-97/3-98％，

R600a/R13I1 2-97/3-98％，

R600/R13I1 2-97/3-98％，

R290/R245fa 2-97/3-98％，

R290/R124 2-97/3-98％，

R290/R142b 2-97/3-98％，

More than each constituent element material mass percentage ratio sum of every kind of mixing medium be 100%.