KR20140091139A - Vapor compression refrigeration/airconditioning equipment with suction line heat exchanger for improving energy efficiency using R1234ze - Google Patents

Abstract

The present invention relates to a vapor compression air conditioner/heat pump, a chiller, a vending machine cooler, a water purifier cooler, or a water heater (referred to as ′a vapor compression refrigeration/air-conditioning equipment′) which uses an eco-friendly R1234ze refrigerant, which is used in the form of a pure refrigerant or a mixed refrigerant, and is applied with a suction line heat exchanger (referred to as SLHX) so that the coefficient of performance (referred to as COP) of the vapor compression refrigeration/air-conditioning equipment can be increased, wherein the R1234ze refrigerant can be used for a long time because ozone depletion potential (referred to as ODP) of the R1234ze refrigerant is zero and the global warming potential (referred to as GWP) of the R1234ze refrigerant is remarkably lower than existing refrigerants.

Description

[0001] The present invention relates to a vapor compression refrigeration / aeration system using a suction pipe heat exchanger for increasing the performance coefficient of the R1234ze as a working fluid,

The present invention relates to a vapor compression type refrigeration / air conditioning apparatus using an environmentally friendly R1234ze refrigerant in the form of a pure refrigerant or a mixed refrigerant, which has an ozone layer decay index of 0 and a global warming index significantly lower than that of conventional refrigerants, And a suction pipe heat exchanger are used to increase the performance coefficient.

The present invention relates to an ozone depletion potential (ODP) for increasing the coefficient of performance (hereinafter referred to as COP) in a vapor compression refrigeration / air-conditioning equipment. And the Global Warming Potential (GWP) is significantly lower than that of conventional refrigerants. Therefore, the environmentally friendly R1234ze refrigerant, which can be used for a long time, is used in the form of pure refrigerant or mixed refrigerant, and at the same time, heat pump, chiller, vending machine cooler, water purifier cooler, water heater, etc. (hereinafter referred to as "steam compression refrigeration / air conditioner") using a heat exchanger (hereinafter referred to as SLHX) .

The vapor compression type refrigeration / air conditioner using the R1234ze refrigerant and the suction pipe heat exchanger according to the present invention uses a pure refrigerant of R1234ze or a mixed refrigerant containing R1234ze as a working fluid and at the same time, by using a suction pipe heat exchanger, , The chiller, the vending machine cooler, the water purifier cooler, the water heater, etc., can be increased to 4.1%.

Until now, Chlorofluorocarbon (hereinafter referred to as CFC) and Hydrochlorofluorocarbon (HCFC) derived from methane or ethane have been mainly used as the refrigerant of the vapor compression refrigerating / air-conditioning system, / Heat pump, commercial chiller, etc., HCFC22 having a boiling point of -40.8 ° C and a molecular mass of 86.47 kg / kmol has been most widely used.

In recent years, however, the collapse of the stratospheric ozone layer by CFCs and HCFCs has emerged as an important global environmental issue, and the production and consumption of CFCs and HCFCs, which disrupt stratospheric ozone, are regulated by the Montreal Protocol of 1987. As can be seen in Table 1, the HCFC22 is now free from ODP in 2010 under the Montreal Protocol in developed countries. Therefore, most countries around the world must find and use alternative refrigerants with an ODP of zero.

Recently, not only the problem of ozone depletion but also the problem of global warming has started to grow rapidly, and the Kyoto Protocol of 1997 strongly recommends that GWPs refrain from using high refrigerant. Reflecting this trend, manufacturers of vapor compression refrigerators / air conditioners in the US, Europe, Japan and Korea are attempting to develop and use low GWP refrigerants.

Table 1 shows the environmental index of refrigerants that can replace HCFC22 for air conditioning / heat pumps and commercial chillers. DuPont and Honeywell of the United States have developed and sold a binary mixed refrigerant called R410A that can replace HCFC22 for more than a decade. However, as can be seen in Table 1, this refrigerant has zero ozone depletion index, but the global warming index is higher than that of HCFC22.

In order to prevent global warming, HFC32, which is one third of the conventional HCFC22, has emerged as an alternative refrigerant for HCFC22. However, GWP is higher than that required by environmental groups and is flammable, and the refrigerant discharge temperature It is difficult to use it as a refrigerant of a heat pump operating in winter.

Recently, in Europe, from January 1, 2011, mandatory regulations have been passed for newly manufactured cars to only use refrigerants with a GWP of 150 or less. As a result, automotive air conditioning manufacturers around the world are focusing on developing new refrigerants and automotive air conditioning systems to comply with these mandatory regulations. As part of this effort, a new refrigerant called HFO-1234ze (hereinafter referred to as R1234ze) was developed. One of the greatest features of R1234ze is that the ODP is zero and the GWP is very low at six, so it can meet the EU mandatory requirements. In the case of the R1234ze, it is advantageous in terms of production and manufacturing since it can be applied immediately if the compressor stroke volume of the automobile air conditioner system which is already commercialized is slightly increased.

Because of these excellent features, refrigerant manufacturers and vapor compression refrigeration / air conditioner manufacturers can use the long-term, environmentally friendly R1234ze instead of HCFC22, R410A, and HFC32 in the home air conditioner / heat pump, commercial / Cooler, water purifier cooler, and water heater.

For a substance to be useful as an alternative refrigerant for existing refrigerants, it should first have a coefficient of performance (COP) similar to that of conventional refrigerants. Here, the performance coefficient (COP) means the total refrigeration effect as compared with the work done to the compressor. The larger the COP, the higher the energy efficiency of the vapor compression type refrigerator / air conditioner.

In the case of vapor compression refrigeration / air conditioning systems, the direct warming effect from the refrigerant itself accounts for about 5% of the total warming effect during the lifetime of the device, and the remaining 95% is the lifetime of the device, usually 20 years This is an indirect warming effect due to the emission of carbon dioxide from the power plant due to the use of electricity.

Table 1 Environmental Index of HCFC22 and HCFC22 Alternative Refrigerants

Refrigerant Ozone layer decay index
(ODP) Global Warming Index
(GWP) HCFC22 0.05 1,700 R410A 0.0 1,890 HFC32 0.0 550 R1234ze 0.0 6

(*) ODP is based on CFC11 set at 1.0.

(**) GWP is based on the assumption that carbon dioxide in the 100th year is 1.0.

Therefore, to solve global warming, which is a global environmental problem, it is most important to reduce the generation of carbon dioxide in the power plant by increasing the coefficient of performance (COP) of the vapor compression refrigeration / air conditioning system. Therefore, COP is one of the most important system performance indicators to be considered when applying environmentally friendly new refrigerants. Refrigerant / air-conditioner manufacturers use environment-friendly products to adjust the compressor and heat exchanger size when the COP of the refrigerant is low and the COP of the refrigerant is lower than ± 5% Is ready to release.

It is an object of the present invention to provide a vapor compression type refrigeration / air conditioning apparatus using a suction pipe heat exchanger to improve performance coefficient while using R1234ze, which is a long-term environmentally friendly refrigerant.

The object of the present invention is achieved by a vapor compression type refrigeration / air conditioning apparatus using R1234ze as a working fluid and including an evaporator, a condenser, a compressor, an expansion valve, and a suction pipe heat exchanger for increasing the performance coefficient .

The present invention also provides a vapor compression refrigeration / refrigeration system using a mixed refrigerant including R1234ze as a working fluid and including an evaporator, a condenser, a compressor, an expansion valve, and a suction pipe heat exchanger for increasing a performance coefficient. Can also be achieved by an air conditioning system.

The present invention also provides a steam compression refrigeration / air conditioning system comprising a refrigerant mixture of R134a / R1234ze as a working fluid and an evaporator, a condenser, a compressor, an expansion valve, and a suction pipe heat exchanger for increasing a performance coefficient. Device can also be achieved.

The present invention also provides a vapor compression type refrigeration / air conditioning system, comprising: an evaporator, a condenser, a compressor, an expansion valve, and a suction pipe heat exchanger for increasing the performance factor, wherein the R152a / R1234ze mixed refrigerant is used as a working fluid. Device can also be achieved.

The present invention also provides a vapor compression type refrigeration / air conditioning system comprising a refrigerant mixture of R32 / R1234ze as a working fluid and an evaporator, a condenser, a compressor, an expansion valve, and a suction pipe heat exchanger for increasing a performance coefficient. Device can also be achieved.

The vapor compression refrigeration / air conditioning apparatus includes an air conditioner, a heat pump, a chiller, a vending machine cooler, a water purifier cooler, or a hot water heater.

The vapor compression type refrigeration / air conditioner using the R1234ze refrigerant and the suction pipe heat exchanger according to the present invention uses a pure refrigerant of R1234ze or a mixed refrigerant containing R1234ze as a working fluid and at the same time, by using a suction pipe heat exchanger, , The chiller, the vending machine cooler, the water purifier cooler, the water heater, etc., can be significantly increased up to 4.1%.

1 is a configuration diagram of a refrigeration / air-conditioning apparatus including an evaporator, a condenser, a compressor, an expansion valve, and a suction pipe heat exchanger (SLHX) according to the present invention.
2 is a graph showing changes in the coefficient of performance of refrigerants in the case of 'SLHX is absent' and 'SLHX is applied' in the vapor compression refrigeration / air conditioning system.

Hereinafter, the structure of a vapor compression type refrigeration / air conditioning apparatus using a suction pipe heat exchanger for increasing the performance coefficient will be described in detail with reference to the accompanying drawings, in which R1234ze according to a preferred embodiment of the present invention is used as a working fluid.

The present invention relates to a vapor compression type refrigeration / air conditioning apparatus using an environmentally friendly R1234ze refrigerant in the form of a pure refrigerant or a mixed refrigerant, which has an ozone layer decay index of 0 and a global warming index significantly lower than that of conventional refrigerants, And the suction pipe heat exchanger are simultaneously applied to increase the performance coefficient. The vapor compression type refrigeration / air conditioner includes a vapor compression type air conditioner / heat pump, chiller, vending machine cooler, water purifier cooler, water heater, and the like.

The present invention relates to the application of a suction line heat exchanger (SLHX) to improve the performance of a vapor compression refrigeration / air conditioning system using a long-term environmentally friendly refrigerant R1234ze. To accomplish this object, the present inventor used a program that simulates the performance of a refrigeration / air conditioning system. This program is a Cycle-D refrigeration / air conditioning cycle analysis program developed by the National Institute of Standards and Technology (NIST). This is a proven program widely used by leading companies, universities, and research institutes around the world.

One of the important factors determining the accuracy of this program is the properties of the refrigerant. This program calculates the properties of all refrigerants using the REFPROP program, which is based on the US, Japan and EU. The REFPROP program, developed by the National Institute of Standards and Technology (NIST), has proved its accuracy and applicability, making it the most widely used program in leading companies, research institutes and universities worldwide. The program and material used here are the latest models with the most recent data.

1 is a configuration diagram of a refrigeration / air-conditioning apparatus including an evaporator, a condenser, a compressor, an expansion valve, and a suction pipe heat exchanger (SLHX) according to the present invention.

The suction pipe heat exchanger (SLHX) is a device used mainly to increase the refrigerating effect by exchanging the liquid refrigerant from the condenser and the gaseous refrigerant entering the compressor from the evaporator. However, SLHX has not been used at all in the past half-century for home and car air conditioners / heat pumps, commercial / building / industrial chillers.

Referring first to the flow of refrigerant in the refrigeration / air conditioning system, the refrigerant in state 7 enters the evaporator in an abnormal state (two liquid and two phases mixed) as shown in FIG. At this time, the refrigerant in an abnormal state evaporates while exchanging heat with the secondary fluid, and generally exits the evaporator in an overheated steam state (state 1). Steam refrigerant from the evaporator is further heated in the SLHX by heat exchange with liquid refrigerant exiting the condenser and enters the compressor at a temperature close to ambient temperature (State 2). Usually at the outlet of the condenser the refrigerant is subcooled (state 6). The supercooled refrigerant exiting the condenser undergoes heat exchange with the superheated steam at the compressor inlet at the SLHX and is further subcooled (state 9). The liquid refrigerant finally expands through the expansion valve and completes one cycle.

Table 2 shows the relationship between the existing HCFC22 and the R410A, HFC32, R1234ze, R134a / R1234ze, R152a / R1234ze, R32 / R1234ze refrigerant that can replace it with the existing HCFC22 under the same refrigeration capacity in the summer cooling condition of the refrigerator / The results are summarized in the case of 'without SLHX' and 'with SLHX'. In case of SLHX in the cycle simulation, the heat exchanger effectiveness of SLHX is assumed to be 90%.

Table 2 shows the performance coefficients of 14 refrigerants without 'SLHX' and 'with SLHX'

(Cooling operation during summer: evaporator refrigerant temperature: 7 캜, condenser refrigerant temperature: 45 캜)

Refrigerant No SLHX With SLHX COP _diff.
(%) GWP COP _c COP _c One HCFC22 3.97 3.92 -1.3 1700 2 R410A 3.70 3.68 -0.5 1890 3 HFC32 3.78 3.65 -3.4 550 4 R1234ze 4.02 4.18 4.0 6 5 40% R134a /
60% R1234ze 3.99 4.12 3.3 576 6 15% R134a /
85% R1234ze 4.01 4.16 3.7 220 7 10% R134a /
90% R1234ze 4.01 4.17 4.0 148 8 50% R152a /
50% R1234ze 4.07 4.12 1.2 73 9 20% R152a /
80% R1234ze 4.04 4.15 2.7 33 10 10% R152a /
90% R1234ze 4.03 4.16 3.2 19 11 10% R32 /
90% R1234ze 3.99 4.15 4.0 60 12 20% R32 /
80% R1234ze 3.97 4.07 2.5 115 13 30% R32 /
70% R1234ze 3.91 3.97 1.5 169 14 40% R32 /
60% R1234ze 3.86 3.88 0.8 224

(Calculated by the Cycle-D program of the American National Standards Institute)

○ COP _c : Cooling performance coefficient

○ COP _diff : Difference in performance between 'Without SLHX' and 'With SLHX'

 ○ SLHX: Suction line heat exchanger

(*) In mixed refrigerant,% of composition means weight%.

As mentioned above, in recent years, due to the global warming problem, there has been a rapid movement to use environmentally friendly R1234ze for air conditioner / heat pump, chiller, vending machine cooler, and R1234ze is mixed with R1234ze such as R134a / R1234ze, R152a / R1234ze, R32 / There is also a tendency to use it as a constituent of the.

As shown in Table 2, the GWP of these mixed refrigerants is similar to or lower than the GWP of HFC32, which is currently being considered as an alternative refrigerant for HCFC22.

Figure 2 shows COP changes for the 14 refrigerants in Table 2, with or without SLHX.

Referring to Table 2 and FIG. 2, it can be seen that the use of SLHX for conventional refrigerants such as HCFC22, R410A and HFC32 results in a reduction in COP. For existing refrigerants such as HCFC22, R410A, and HFC32, SLHX was not used at all for refrigeration / air conditioning systems that used HCFC22, R410A, and HFC32 for the past half century because COPs were rather reduced.

However, as shown in Table 2 and Fig. 2, when the R1234ze is used as the working fluid, the COP increases by 4% when SLHX is applied to the vapor compression refrigeration / air conditioning system.

An increase of 4% in COP means that the electricity consumption of the vapor compression type refrigerator / air conditioner is reduced accordingly. Considering that many thousands of vapor compression refrigerating / air conditioning units such as air conditioner / heat pump, chiller and vending machine cooler are manufactured every year, consuming a large amount of electricity worldwide, 4% increase in performance and decrease in energy consumption Is very important for energy conservation / conservation and global environmental protection.

As can be seen in Table 2, this phenomenon was similar for R134a / R1234ze, R152a / R1234ze and R32 / R1234ze mixed refrigerants using R1234ze as one component.

For these mixed refrigerants, the larger the composition of R1234ze, the greater the increase in the coefficient of performance due to the use of SLHX. Thus, for a vapor compression refrigerant / air conditioner using a pure refrigerant containing R1234ze or R1234ze, an increase of 4% is seen with SLHX.

This phenomenon is very unusual. As described above, in the case of conventional refrigerants such as HCFC22, R410A, and HFC32, the refrigerant / air conditioner using HCFC22, R410A, HFC32 for the past half century due to the reduction of COP by using SLHX No SLHX was used at all.

However, when R1234ze is used as a refrigerant, the coefficient of performance is increased as described above. Therefore, it is the core of the present invention to apply the suction pipe heat exchanger only when R1234ze (or a mixed refrigerant containing R1234ze) is used as the working fluid.

Table 3 summarizes the results of calculating the performance of the same refrigerants by using the Cycle-D program in the winter heating condition of the vapor compression type refrigerator / air conditioner for 'when there is no SLHX' and 'when there is SLHX' will be.

Table 3 Performance curves of 14 refrigerants without SLHX and with SLHX

(Winter heating driving condition: evaporator refrigerant temperature: -7 ° C, condenser refrigerant temperature: 41 ° C)

Refrigerant No SLHX With SLHX COP _diff.
(%) GWP COP _h COP _h One HCFC22 3.94 3.90 -1.0 1700 2 R410A 3.75 3.74 -0.3 1890 3 HFC32 3.81 3.69 -3.1 550 4 R1234ze 3.94 4.10 4.1 6 5 40% R134a /
60% R1234ze 3.92 4.06 3.6 576 6 15% R134a /
85% R1234ze 3.93 4.09 4.1 220 7 10% R134a /
90% R1234ze 3.93 4.09 4.1 148 8 50% R152a /
50% R1234ze 4.00 4.05 1.3 73 9 20% R152a /
80% R1234ze 3.96 4.08 2.0 33 10 10% R152a /
90% R1234ze 3.95 4.09 3.5 19 11 10% R32 /
90% R1234ze 3.92 4.08 4.1 60 12 20% R32 /
80% R1234ze 3.91 4.02 2.8 115 13 30% R32 /
70% R1234ze 3.88 3.95 1.8 169 14 40% R32 /
60% R1234ze 3.85 3.88 0.8 224

(Calculated by the Cycle-D program of the American National Standards Institute)

○ COP _h : Heating performance coefficient

○ COP _diff : Difference in performance between 'Without SLHX' and 'With SLHX'

 ○ SLHX: Suction line heat exchanger

(*) In mixed refrigerant,% of composition means weight%.

As can be seen in Table 3, in the case of a vapor compression refrigerating / air-conditioning system using a pure refrigerant containing R1234ze or R1234ze, the use of a suction pipe heat exchanger (SLHX) %, Respectively.

Qcond: Heat flow direction in the condenser (refrigerant → air)
Qevap: Direction of heat flow in the evaporator (air → refrigerant)
TS1: Evaporator air inlet temperature, TS7: Evaporator air outlet temperature
TS3: Condenser air outlet temperature, TS6: Condenser air inlet temperature
Evaporator: Evaporator, Compressor: Compressor
Condenser: Condenser, Expansion Valve: Inflator
SLHX: Suction tube heat exchanger

Claims (6)

Wherein the evaporator, the condenser, the compressor, the expansion valve, and the suction pipe heat exchanger for increasing the coefficient of performance are used. A condenser, a compressor, an expansion valve, and a suction pipe heat exchanger for increasing the performance coefficient, using a mixed refrigerant containing R1234ze as a working fluid. And a suction pipe heat exchanger for using an R134a / R1234ze mixed refrigerant as a working fluid and for increasing an evaporator, a condenser, a compressor, an expansion valve, and a performance coefficient. A condenser, a compressor, an expansion valve, and a suction pipe heat exchanger for increasing the performance coefficient, wherein the R152a / R1234ze mixed refrigerant is used as a working fluid. And a suction pipe heat exchanger for using the R32 / R1234ze mixed refrigerant as a working fluid, the evaporator, the condenser, the compressor, the expansion valve, and the performance coefficient enhancing device. The steam compression refrigeration / air conditioning system according to any one of claims 1 to 5, wherein the vapor compression type refrigeration / air conditioning apparatus includes an air conditioner, a heat pump, a chiller, a vending machine cooler, a water purifier cooler, Device.

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