Passive organic working fluid ejector refrigeration method

Abstract

The present invention relates to a passive type organic working fluid ejector refrigeration method. The liquid organic working fluid of the reservoir is added to evaporator using gravity. Then the refrigerant absorbs heat during evaporation in the evaporator. When the refrigerant temperature and pressure increases to a certain value, the self-operated pressure regulator valve automatically opens and the ejector begins to work. After condensing in the condenser, the working fluid divided into two streams. One stream returns to the reservoir and the other one flows into the cooling evaporator of refrigeration cycle to produce chilled water about 12° C. When the liquid refrigerant is completely evaporated in the evaporator, the self-operated pressure regulator valve opens and the working fluid flows into the evaporator from the reservoir. A certain quality of the working fluid is closed in the evaporator, preparing for a new work cycle as above-mentioned. The system of the present invention can use organic fluid as the working fluid to utilize the low-temperature heat sources range from 60 to 200° C., using groundwater, river (sea) water or air as cold source and using gravity to transport liquid working fluid.

Claims

1. A method of a passive type organic working fluid ejector in a refrigeration cycle, comprises the following steps of: (1) through monitoring a low pressure in an evaporator, a first self-operated pressure regulator valve and a second self-operated pressure regulator valve are closed, a third self-operated pressure regulator valve is opened, a liquid organic working fluid of a reservoir flows into the evaporator under an action of gravity until surface equilibrium, then the third self-operated pressure regulator valve is closed, the working fluid will be closed in the evaporator; (2) the working fluid absorbs heat and evaporates in the evaporator, a temperature and pressure of the working fluid is increasing until reaching 101 ° C. and 2MPa, the first self-operated pressure regulator valve is opened, and an ejector begins to work; (3) vapor working fluid is ejected into a condenser through the ejector and condenses to liquid, then the working fluid is divided into two streams, one stream returns to the reservoir, and the other stream flows into the evaporator of the refrigeration cycle, by ejecting effect, resulting in cooling water of 12° C.; (4) during operation process, liquid working fluid continues to absorb heat and evaporate in the evaporator constantly until completely evaporated, and the pressure drops to a set pressure of the first self-operated pressure regulator valve, then the third self-operated pressure regulator valve is opened, and the working fluid flows into the evaporator from the reservoir; (5) after the operation process, the third self-operated pressure regulator valve and the second self-operated pressure regulator valve are closed, the liquid working fluid is closed again in the evaporator preparing for a new cycle repeating the above steps.

2. The method of the passive type organic working fluid ejector in the refrigeration cycle as set in claim 1, characterized in that wherein said ejector includes a nozzle, entrained flow inlet, receiving chamber, a mixing chamber and diffuser cavity; the nozzle and entrained flow inlet are within the receiving chamber; the receiving chamber, mixing chamber and the diffuser cavity connect sequentially.

3. The method of the passive type organic working fluid ejector in the refrigeration cycle as set in claim 1, characterized in that: wherein a reservoir's position is 100-1000 mm higher than a relative position of the evaporator, in order to use gravity to transport of the working fluid.

4. The method of the passive type organic working fluid ejector in the refrigeration cycle as set in claim 1, characterized in that: wherein the cycle uses gravity to transport liquid working fluid and uses the self-operated pressure regulator valves and a self-operated thermostatic regulator valve to control an entire ejection refrigeration process.

5. The method of the passive type organic working fluid ejector in the refrigeration cycle as set in claim 1, characterized in that: wherein said organic working fluid is R245fa, R60Q, R600a, R141b or R142b.

6. The method of the passive type organic working fluid ejector in the refrigeration cycle as set in claim 1, characterized in that: wherein an entrainment ratio of the ejector is from 0.1 to 0.5; a mass flow rate of the working fluid in the ejector is 0.01 to 2.0 kg/s; and a working pressure is 0.8-2.5MPa.

7. The method of the passive type organic working fluid ejector in the refrigeration cycle as set in claim 1, characterized in that: wherein a working pressure of the condenser is a condensation pressure of liquid working fluid at 10° C.-38° C., namely temperature range of a cooling water or cooling air.

8. The method of the passive type organic working fluid ejector in the refrigeration cycle as set in claim 1, characterized in that: wherein a working pressure of the evaporator is a corresponding evaporation pressure of liquid working fluid with an evaporation temperature of 5° C.-15° C.

Description

DESCRIPTION OF DRAWINGS

Brief Description

(1) FIG. 1 is a schematic structural view of the invention the device;

(2) FIG. 2 is a schematic structural view of the ejector.

DETAILED DESCRIPTION

(3) Combining with the accompanying drawings and specific embodiments, the present invention will be described in detail.

EXAMPLE 1

(4) This embodiment uses refrigerant R600a as working fluid. The temperature of heat sources is 120° C. The output temperature of chilled water is 12° C. The specific implementation steps are as follows:

(5) First, the third self-operated pressure regulator valve is opened, the liquid organic working fluid in reservoir flows into the evaporator by gravity, until liquid surface equilibrium. After the third self-operated pressure regulator valve is closed, 100 kg working fluid is closed in the evaporator.

(6) The second step, the liquid refrigerant in the evaporator absorbs heat during evaporation. The working fluid temperature and pressure is increasing, and ultimately achieves 101° C. and 2 MPa, namely, the design parameters of the ejector.

(7) The third step, the first self-operated pressure regulator valve at the outlet of evaporator opens automatically under certain pressure. The steam as the working fluid with the mass flow rate of 0.175 kg/s flows into the ejector and produces ejecting effect for the gas at the outlet of refrigeration evaporator.

(8) The fourth step, the lead working fluid mixes with the entrain stream in the mixing chamber. The mixing fluid flows into the diffuser chamber and then discharges from the ejection outlet, into the condenser. The outlet pressure and temperature of ejector working fluid are 0.438 MPa and 64.2° C.

(9) The fifth step, the working fluid vapor is condensed into liquid in the condenser, and then divided into two streams. One stream flows into the reservoir, and the other one is throttled into the refrigeration evaporator through self-operated pressure regulator valve, then absorbs heat from the chilled water. The water temperature is cooled down to 12° C., completing the refrigeration cycle. The mass flow rate of refrigerant in refrigeration circuit is 0.03 Kg/s. The corresponding evaporation pressure and evaporation temperature are 0.21 MPa and 10° C. This process is controlled by self-operated temperature regulator valve.

(10) The sixth step, the cooling evaporator provides chilled water of 12° C., and the output cooling capacity is 12 kW. The steam at outlet of refrigeration evaporator entrained by the ejector into the ejector inlet and mixed with work steam.

(11) The seventh step, in the work process, the liquid refrigerant in the evaporator absorbs heat and evaporates constantly. After about 570 seconds, the fluid evaporates completely, and the evaporation pressure of refrigerant rapidly declines.

(12) The eighth step, when the working fluid pressure drops to the set pressure of first self-operated pressure regulator valve, the first self-operated pressure regulator valve and a second self-operated pressure regulator valve is closed. The third self-operated pressure regulator valve opens, and the saturated liquid refrigerant of reservoir flows into the evaporator by gravity.

(13) The ninth step, when the working fluid injection process finishes, the third self-operated pressure regulator valve and the second self-operated pressure regulator valve close automatically. A certain quality of the working fluid is closed in the evaporator for a new circulation. In this case, the cooling COP is about 0.31 and the cooling capacity is up to about 12 kW.

EXAMPLE 2

(14) This embodiment uses refrigerant R245fa as working fluid. The temperature of heat sources is 120° C. The output temperature of chilled water is 12° C. The specific implementation steps are as follows:

(15) First, the third self-operated pressure regulator valve is opened, the liquid organic working fluid in reservoir flows into the evaporator by gravity, until liquid surface equilibrium. After the third self-operated pressure regulator valve is closed, 100 kg working fluid is closed in the evaporator.

(16) The second step, the liquid refrigerant in the evaporator absorbs heat during evaporation. The working fluid temperature and pressure is increasing, and ultimately achieves 100° C. and 1.26 MPa, namely, the design parameters of the ejector.

(17) The third step, the first self-operated pressure regulator valve at the outlet of evaporator opens automatically under certain pressure. The steam as the working fluid with the mass flow rate of 0.175 Kg/s flows into the ejector and produces ejecting effect for the gas at the outlet of refrigeration evaporator.

(18) The fourth step, the lead working fluid mixes with the entrain stream in the mixing chamber. The mixing fluid flows into the diffuser chamber and then discharges from the ejection outlet, into the condenser. The outlet pressure and temperature of ejector working fluid are 0.197 MPa and 64.9° C.

(19) The fifth step, the working fluid vapor is condensed into liquid in the condenser, and then divided into two streams. One stream flows into the reservoir, and the other is throttled into the refrigeration evaporator through self-operated pressure regulator valve, then absorbs heat from the chilled water. The water temperature is cooled down to 12° C., completing the refrigeration cycle. The mass flow rate of refrigerant in circuit is 0.0525 Kg/s. The corresponding evaporation pressure and evaporation temperature are 0.08 MPa and 10° C. This process controlled by self operated temperature regulator valve.

(20) The sixth step, the cooling evaporator provides chilled water of 12° C., and the output cooling capacity is 13 kW. The steam at outlet of refrigeration evaporator entrained by the ejector into the ejector inlet and mixed with work steam.

(21) The seventh step, in the work process, the liquid refrigerant in the evaporator absorbs heat and evaporates constantly. After about 570 seconds, the fluid evaporates completely, and the evaporation pressure of refrigerant rapidly declines.

(22) The eighth step, when the working fluid pressure drops to the set pressure of first self-operated pressure regulator valve, the first self-operated pressure regulator valve and a second self-operated pressure regulator valve is closed. The third self-operated pressure regulator valve opens, and the saturated liquid refrigerant of reservoir flows into the evaporator by gravity.

(23) The ninth step, when the working fluid injection process finishes, the third self-operated pressure regulator valve and the second self-operated pressure regulator valve close automatically. A certain quality of the working fluid is dosed in the evaporator for a new circulation. In this case, the cooling COP is about 0.35 and the cooling capacity is up to about 13 kW.

EXAMPLE 3

(24) This embodiment uses refrigerant R600a as working fluid. The temperature of heat sources is 120° C. The output temperature of chilled water is 12° C. The specific implementation steps are as follows:

(25) First, the third self-operated pressure regulator valve is opened, the liquid organic working fluid in reservoir flows into the evaporator by gravity, until liquid surface equilibrium. After the third self-operated pressure regulator valve is closed, 1000 kg working fluid is closed in the evaporator.

(26) The second step, the liquid refrigerant in the evaporator absorbs heat during evaporation. The working fluid temperature and pressure is increasing, and ultimately achieves 100° C. and 0.68 MPa, namely, the design parameters of the ejector.

(27) The third step, the first self-operated pressure regulator valve at the outlet of evaporator opens automatically under certain pressure. The steam as the working fluid with the mass flow rate of 1.75 kg/s flows into the ejector and produces ejecting effect for the gas at the outlet of refrigeration evaporator.

(28) The fourth step, the lead working fluid mixes with the entrain stream in the mixing chamber. The mixing fluid flows into the diffuser chamber and then discharges from the ejection outlet, into the condenser. The outlet pressure and temperature of ejector working fluid are 0.104 MPa and 70.4° C.

(29) The fifth step, the working fluid vapor is condensed into liquid in the condenser, and then divided into two streams. One stream flows into the reservoir, and the other is throttled into the refrigeration evaporator through self-operated pressure regulator valve, then absorbs heat from the chilled water. The water temperature is cooled down to 12° C., completing the refrigeration cycle. The mass flow rate of refrigerant in circuit is 0.525 kg/s. The corresponding evaporation pressure and evaporation temperature are 0.043 MPa and 10° C. The process is controlled by self operated temperature regulator valve.

(30) The sixth step, the cooling evaporator provides cooling water of 12° C., and the output cooling capacity is 130 kW. The steam at outlet of refrigeration evaporator entrained by the ejector into the ejector inlet and mixed with work steam.

(31) The seventh step, in the work process, the liquid refrigerant in the evaporator absorbs heat and evaporates constantly. After about 560 seconds, the fluid evaporates completely, and the evaporation pressure of refrigerant rapidly declines.

(32) The eighth step, when the working fluid pressure drops to the set pressure of first self-operated pressure regulator valve, the first self-operated pressure regulator valve and a second self-operated pressure regulator valve is closed. The third self-operated pressure regulator valve opens, and the saturated liquid refrigerant of reservoir flows into the evaporator by gravity.

(33) The ninth step, when the working fluid injection process finishes, the third self-operated pressure regulator valve and the second self-operated pressure regulator valve close automatically. A certain quality of the working fluid is closed in the evaporator for a new circulation. In this case, the cooling COP is about 0.35 and the cooling capacity is up to about 130 kW.

(34) The apparatus of the passive type organic working fluid ejector refrigeration method is shown in FIG. 1, comprising of: an evaporator 1, a first self-operated pressure regulator valve 2, the ejector 3, a condenser 4, the second self-operated pressure regulator valve-5, the reservoir 6, the third self-operated pressure regulator valve 7 the evaporator 8 and self-operated temperature regulator valve 9. Wherein: The reservoir 6 is connected to the evaporator 1 through the third self-operated pressure regulator valve 7. The evaporator 1 is connected to the inlet of injector 3 through the first self-operated pressure regulator valve 2. The outlet of ejector 3 is connected to the condenser 4 through a pipe. The pipes at outlet of the condenser 4 are divided into two ways. One way is connected to the reservoir 6, the another is connected the refrigeration evaporator 8 through self-operated temperature regulator valve 9. The outlet of refrigeration evaporator 8 is connected to the ejector body 3 through the pipes and inlet connector of entrained flow.

(35) As shown in FIG. 2, The ejector 11 of the system consists of the nozzle 3, the inlet of entrained flow 12, the receiving chamber 13, the mixing chamber 14 and the diffuser cavity 15. The nozzle 11 and the inlet of entrained flow 12 are within the receiving chamber 13. The receiving chamber 13, the mixing chamber 14 and the diffuser cavity 15 is connected in sequence.

(36) Next, the components will be further described: the location of the reservoir 6 is 100-1000 mm higher than that of the evaporator 1, which can take advantage of gravity to transfer liquid medium. The liquid refrigerant is organic working fluid such as R245fa, R600, R600a, R141b or R142b. The ejection coefficient of ejector 3 is from 0.1 to 0.5.The mass flow of the ejector 3 is 0.01-2.0 kg/s with a working pressure of 0.8-2.5 MPa. The working pressure of condenser 4 is the condensation pressure of liquid refrigerant at 10° C.-38° C., namely temperature range of the cooling water or cooling air. The working pressure of the refrigerant evaporator 8 is the corresponding evaporation pressure of liquid refrigerant with a evaporation temperature of 5° C.˜15° C.