The present invention generally relates to a system for purging non-condensable gas from a refrigeration circuit, and a refrigeration circuit equipped with the purge system. More specifically, the present invention relates to system for purging non-condensable gas from a chiller circuit that uses a low pressure type refrigerant without requiring a separate dedicated compressor.
A refrigeration circuit for a chiller system typically includes a purge system for removing non-condensable gases from the refrigerant circuit. Accumulation of non-condensable gases in the refrigeration circuit can degrade the operating efficiency of the chiller system. The purge system removes the accumulated non-condensable gases to prevent or suppress such a degradation of the operating efficiency.
A conventional purge system has a complete refrigeration circuit that includes a condenser, an expansion valve, a heat exchanger coil (evaporator coil), and a dedicated compressor (which is separate from the compressor of the main refrigeration circuit of the chiller system). The purge system also includes a purge tank that defines a condensing chamber and houses the heat exchanger coil of the purge system refrigeration circuit. The purge tank has an inlet for introducing refrigerant containing non-condensable gases from the main refrigeration circuit of the chiller system to the condensing chamber, an outlet for returning condensed refrigerant back to the main refrigeration circuit from the condensing chamber, and a purge outlet for purging accumulated non-condensable gases to the ambient atmosphere. A purge line communicating to the ambient atmosphere is connected to the purge outlet, and a pump-out compressor and a carbon filter or other device for removing residual refrigerant from purged gases are provided in the purge line. The purge line also includes valves for opening and closing different sections of the purge line.
Refrigerant containing non-condensable gases is introduced into the condensing chamber of the purge tank from the main refrigeration circuit and condensed by the evaporator coil. Liquid refrigerant collects in the bottom of the condensing chamber and the non-condensable gases accumulate in the condensing tank and remain in a gaseous state. Periodically, the non-condensable gases are purged from the condensing chamber by opening the valves of the purge line and operating the pump-out compressor to draw the non-condensable gas from the condensing chamber and pump the non-condensable gas out to the atmosphere. When the non-condensable gas is purged, residual refrigerant exiting the condensing chamber along with the non-condensable gas is captured by the carbon filter such that the refrigerant is not released to the atmosphere.
A conventional purge system has a comparatively large footprint because it includes a complete refrigeration circuit with a dedicated compressor as explained above. A conventional purge system also requires a dedicated controller to control the refrigeration cycle (compressor) of the purge system refrigeration circuit and to operate the valves and the pump-out compressor when the accumulated non-condensable gas is exhausted from the condensing chamber (e.g., see
Therefore, objects of the present invention include providing a relatively smaller, simpler, and less expensive purge system for a chiller system or other refrigeration circuit that utilizes a low pressure refrigerant.
It has been discovered that when a low pressure refrigerant (e.g., R1233zd) is used in the main refrigeration circuit of a chiller system, it is possible to direct a portion of refrigerant from the main refrigeration circuit to the purge system for condensing the refrigerant in the condensing chamber of the purge tank. In other words, a portion of refrigerant from the main refrigeration circuit is passed through the heat exchanger coil of the purge tank. In this way, the purge system can share the same low pressure refrigerant as is used in the main refrigeration circuit of the chiller system. As a result, it is not necessary to provide a separate type of refrigerant for the purge system.
It has been further discovered that a dedicated compressor for the purge system is not necessary if the components of the purge system are arranged appropriately with respect to the components of the main refrigeration circuit and the inlet and outlet of the heat exchanger coil of the purge tank are connected to appropriate portions of the main refrigeration circuit. Thus, the purge system can be simplified by eliminating the need for a dedicated compressor and a complete dedicated refrigeration circuit for the purge system. Consequently, the size and cost of the purge system can be significantly reduced.
It has been further discovered that a dedicated controller for the purge system may not be required when the heat exchanger coil is connected to the main refrigeration circuit and the dedicated compressor of the conventional purge system is eliminated. In other words, since the proposed purge system does not require a complete dedicated refrigeration circuit, the proposed purge system is simpler to operate and a separate controller may not be necessary. Thus, for example, the main controller of the chiller system can control the purge system as well.
Based on these discoveries, the forgoing objects can basically be achieved by providing a non-condensable gas purge system having a purge heat exchanger coil configured to be connected to a refrigeration circuit. The non-condensable gas purge system is configured to be connected to a refrigeration circuit that includes a compressor, a condenser, an expansion valve, and an evaporator connected to form a loop. The refrigeration circuit contains a low pressure refrigerant. The purge system comprises a purge tank and the purge heat exchanger coil. An interior of the purge tank defines a liquid condensing chamber. The purge tank has a tank inlet for receiving the low pressure refrigerant from the condenser of the refrigeration circuit, a tank outlet for returning the low pressure refrigerant from the liquid condensing chamber to the evaporator of the refrigeration circuit, and a purge outlet for purging non-condensable gas from the liquid condensing chamber to an ambient atmosphere. The purge heat exchanger coil is disposed inside the liquid condensing chamber of the purge tank. The purge heat exchanger coil is configured to be fluidly connected to the refrigeration circuit such that the low pressure refrigerant contained in the loop can pass through the purge heat exchanger coil without using a dedicated purge system compressor.
Additionally, the forgoing objects can basically be achieved by providing a refrigeration circuit for a chiller system and providing a non-condensable gas purge system having a purge heat exchanger coil connected to the loop of the refrigeration circuit so as to share the same refrigerant as is contained in the loop. The refrigeration circuit includes the loop and the non-condensable gas purge system. The loop contains a low pressure refrigerant and comprises a compressor, a condenser, an expansion valve, and an evaporator connected together. The non-condensable gas purge system includes a purge tank, a vapor feed line, a liquid return line, a purge vent line, and a purge heat exchanger coil. The purge tank has an interior defining a liquid condensing chamber. The purge tank also has a tank inlet, a tank outlet, and a purge outlet. The vapor feed line is connected to the tank inlet and arranged to feed the low pressure refrigerant from the condenser to the liquid condensing chamber. The liquid return line is connected to the tank outlet and arranged to return the low pressure refrigerant from the liquid condensing chamber to the evaporator. The purge vent line is connected to the purge outlet and arranged to guide non-condensable gas from the liquid condensing chamber to an ambient atmosphere. The purge heat exchanger coil is disposed inside the liquid condensing chamber of the purge tank. The purge heat exchanger coil is fluidly connected to the loop such that the low pressure refrigerant contained in the loop can pass through the purge heat exchanger coil without using a dedicated purge system compressor.
These and other objects, features, aspects and advantages of the present invention will become apparent to those skilled in the art from the following detailed description, which, taken in conjunction with the annexed drawings, discloses a preferred embodiment.
Referring now to the attached drawings which form a part of this original disclosure:
Select embodiments will now be explained with reference to the drawings. It will be apparent to those skilled in the art from this disclosure that the following descriptions of the embodiments are provided for illustration only and not for the purpose of limiting the invention as defined by the appended claims and their equivalents.
Referring initially to
The method of producing refrigeration of the illustrated chiller system 10 includes compressing a low pressure refrigerant composition including R1233zd in the compressor 22. The compressed refrigerant is then sent to the condenser 24 where heat is transferred from the refrigerant to a medium (water in this case). The refrigerant cooled in the condenser 24 is then expanded by the expansion valve 27 and sent to the evaporator 28. In the evaporator 28, the refrigerant absorbs heat from the medium (water in this case) to chill the medium. In this way, refrigeration is produced. The refrigerant is then sent back to the compressor 22 and the cycle is repeated in a conventional manner. The method of producing refrigeration of the illustrated chiller system 10′ shown in
The components of the non-condensable gas purge system 1 will now be explained with reference to
More specifically, the purge heat exchanger coil 55 is arranged to receive the low pressure refrigerant in a liquid state from an appropriate portion of the loop refrigeration circuit and return the liquid refrigerant to the evaporator 28. In the illustrated embodiment, purge heat exchanger coil 55 is connected to receive liquid refrigerant from a bottom portion of the condenser 24 (see *C in
Meanwhile, the purge heat exchanger coil 55 is arranged to return the liquid low pressure refrigerant to the evaporator 28. For example, in the illustrated embodiment, the outlet end of the purge heat exchanger coil 55 is connected to a bottom portion of the evaporator 28 (see *D in
Referring to
In the illustrated embodiment, the tank inlet 52 is disposed on an upper portion of the purge tank 51 and the tank outlet 54 is disposed on a lower portion of the purge tank 51. An internal pipe 57 is provided inside the liquid condensing chamber 53 and arranged to extend downward from the tank inlet 52. Preferably, the internal pipe 57 is dimensioned to extend to a position below a predetermined normal liquid level (explained later) of the low pressure refrigerant collected in a liquid state in the liquid condensing chamber 53.
Still referring to
The tank outlet 54 is connected to the evaporator 28 by a liquid return line 70 (see also *B in
The purge outlet 56 of the purge tank 51 is connected to a purge vent line 60 for venting the liquid condensing chamber 53 to the ambient atmosphere. In the illustrated embodiment, a carbon filter CF and a vacuum pump VP are provided in the purge vent line 60. The carbon filter CF is provided between the vacuum pump VP and the purge outlet 56. The carbon filter CF serves to extract refrigerant from non-condensable gases exiting the purge tank 51 through the purge vent line 60 by adsorption (the present invention is not limited to a carbon filter and any other appropriate device for removing refrigerant intermixed with the non-condensable gas may be used). A heater HE is arranged on the carbon filter CF to heat the carbon filter during a recovery mode (explained later) in order to cause the adsorbed refrigerant to be de-adsorbed from the carbon filter CF and return to the liquid condensing chamber 53. A first solenoid valve SV1 is provided in the purge vent line 60 between the purge outlet 56 and the carbon filter CF, and a second solenoid valve SV2 is provided in the purge vent line 60 between the carbon filter CF and the vacuum pump VP. The vacuum pump VP serves to lower the pressure in the purge vent line 60 such that the non-condensable gases accumulated in the liquid condensing chamber 53 will flow out through the purge outlet 56 and the purge vent line 60 when the pressure inside the liquid condensing chamber 53 is lower than the ambient atmospheric pressure.
As shown in
A first pressure sensor P1 and a first temperature sensor T1 are provided on the purge tank 51 to measure a pressure and a temperature, respectively, inside the liquid condensing chamber 53. More specifically, the sensors P1 and T1 detect the pressure and temperature at a position higher than the high liquid level inside the liquid condensing chamber 53 such that the pressure and temperature of non-condensable gas accumulated inside the purge tank 51 can be ascertained. A second pressure sensor P2 and a second temperature sensor T2 are also provided to detect a pressure and a temperature of the low pressure refrigerant exiting the purge heat exchanger coil 55. The detection values of the second pressure sensor P2 and the second temperature sensor T2 can be used to determine a degree of superheating of the low pressure refrigerant exiting the purge heat exchanger coil 55. The degree of superheating can be used as an optional condition for controlling the third solenoid valve SV3 as explained later. A third temperature sensor T3 detects a temperature of gas in the purge vent line 60.
As shown in
Since the non-condensable gas purge system 51 does not have a separate dedicated refrigeration circuit and, thus, does not require a dedicated compressor, the majority of the size of the non-condensable gas purge system 1 comes from the purge tank 51 and the carbon filter CF (e.g., see
The operation of the non-condensable gas purge system 1 will now be explained with reference to the flowcharts of
The non-condensable gas purge system I basically has three operating modes: a normal mode, a purge mode, and a recovery mode. The normal mode is the mode normally used when the chiller system 10 is operating. In the normal mode, the first and second solenoid valves SV1 and SV2 are closed and the third solenoid valve SV3 is generally held open. During the normal mode, non-condensable gases entering the liquid condensing chamber 53 via the tank inlet 52 are allowed to accumulate in the purge tank 51. The purge mode is a mode in which the non-condensable gases accumulated inside the purge tank 51 are vented to the ambient atmosphere. In the purge mode, the first solenoid valve SV1 and the second solenoid valve SV2 are opened and the third solenoid valve SV3 is controlled in the same manner as during the normal mode. As the non-condensable gases flow out through the purge vent line 60, refrigerant intermixed with the non-condensable gases is adsorbed by the carbon filter CF. The recovery mode is a mode in which refrigerant adsorbed by the carbon filter CF is de-adsorbed and returned to the liquid condensing chamber 53. During the recovery mode, the first solenoid valve SV1 is open, the second solenoid valve SV2 is closed, and the third solenoid valve SV3 is operated in the same manner as during the normal mode.
The operation of the non-condensable gas purge system 1 in each of the normal mode, the purge mode, and the recovery mode will now be explained in detail with reference to
More specifically, referring to the flowchart shown in
Meanwhile, the controller 20 executes step S105 to determine if a degree of superheating (SH) of the low pressure refrigerant exiting the purge heat exchanger coil 55 is too low based on the temperature and pressure detected by sensors T2 and P2 shown in
If the result of either of steps S101 and S105 is “No,” then the controller 20 proceeds to step S109. The controller also proceeds to step S109 after executing either of steps S104 and S108. In step S109, the controller 20 checks if a difference between the pressure inside the liquid condensing chamber 53 and a condensation temperature of the low pressure refrigerant is larger than 1 psig. If the pressure difference is larger than 1 psig, then the controller 20 switches to the purge mode. Otherwise, the controller 20 returns to steps S101 and S105.
Optionally, as shown in
In this way, during the normal mode, the controller 20 basically opens and closes the third solenoid valve SV3 as necessary based on the liquid level of the low pressure refrigerant in the liquid condensing chamber 53 and, optionally, the degree of superheating of the low pressure refrigerant exiting the purge heat exchanger coil 55. The controller 20 also continuously checks if it is necessary to switch to the purge mode.
The purge mode will now be explained with reference to
In step S209, the controller 20 determines if the pressure inside the liquid condensing chamber 53 is lower than 1 atmosphere based on the detection value of the first pressure sensor P1. If the pressure inside the liquid condensing chamber 53 is lower than 1 atmosphere, then the controller 20 proceeds to step S210 and turns on the vacuum pump VP for a prescribed amount of time. Then, the controller 20 proceeds to step S212 and determines if the purge mode has been executed a prescribed number of times (e.g., ten times with a purge duration of 30 minutes each time). Alternatively, in step S212 the controller 20 may determine if the purge mode has been executed a prescribed total amount of time (e.g., five hours) since the last time the recovery mode was executed. If the purge mode has been executed the prescribed number of times, then the controller 20 switches to the recovery mode. Meanwhile, if the result of step S209 is “No,” then the controller 20 proceeds to step S211 and determines if the pressure inside the liquid condensing chamber (detected by the first pressure sensor P1) is equal to the condensation pressure of the low pressure refrigerant. If the result of step S211 is “Yes,” then the controller 20 proceeds to switch to step S212. Otherwise, the controller 20 returns to steps S201, S205, and S209.
Optionally, as shown in
In this way, during the purge mode, the controller 20 continues to open and close the third solenoid valve SV3 as necessary based on the liquid level of the low pressure refrigerant in the liquid condensing chamber 53 and, optionally, the degree of superheating of the low pressure refrigerant exiting the purge heat exchanger coil 55. The controller 20 also determines if it is necessary to operate the vacuum pump VP based on the pressure detected by the first pressure sensor P1. Additionally, the controller 20 continuously checks if it is necessary to switch to the recovery mode.
The recovery mode will now be explained with reference to
In step S309, the controller 20 determines if a temperature of the carbon filter CF has reached a prescribed temperature, e.g., 70° C. If the temperature of the carbon filter CF is equal to or larger than the prescribed temperature, then the controller 20 returns to the normal mode. Otherwise, the controller 20 returns to steps S301, S305, and S309.
Optionally, as shown in
In this way, during the recovery mode, the controller 20 continues to open and close the third solenoid valve SV3 as necessary based on the liquid level of the low pressure refrigerant in the liquid condensing chamber 53 and, optionally, the degree of superheating of the low pressure refrigerant exiting the purge heat exchanger coil 55. The controller 20 also determines if the recovery of refrigerant from the carbon filter CF has been completed by monitoring the temperature of the carbon filter CF. When it determines that the recovery has been completed, the carbon filter CF ends the recovery mode and returns to the normal mode.
As mentioned previously, in the present invention, the same controller as controls the chiller refrigeration circuit can also be used to control the non-condensable gas purge system because the non-condensable gas purge system is comparatively simple to operate (of course, it is also acceptable to use a separate controller for the purge system 1). In the illustrated embodiment, the chiller controller 20 is conventional except for the programming required to execute the normal mode, the purge mode, and the recovery mode operations (see
The controller 20 receives signals from the first pressure sensor P1, the first temperature sensor T1, the second pressure sensor P2, the second temperature sensor T2, the level sensor LS and other sensors (not shown) to control the chiller system 10 or 10′ and the non-condensable gas purge system 1. The controller 20 also transmits electrical signals to the compressor 22 (or 22′) of the chiller system 10 (or 10′) and to the solenoid valves SV1, SV2, and SV3, the heater HE, and the vacuum pump VP of the non-condensable gas purge system 1. More specifically, the controller 20 is programmed to control the rotation speed of the motor 38 to control the capacity of the compressor 22 (or 22′) in a conventional manner. Additionally, the controller 20 is programmed to control the opening degree of the expansion valve 26 to control the capacity of the chiller system 10 in a conventional manner. The controller 20 is also programmed to control the non-condensable gas purge system 1 as explained above based on information obtained from the sensors P1, P2, T1, T2 and the level switch LS.
According to calculations, it is estimated that the flow of non-condensable gas to the purge tank will be 4.36 cc/hour during operation of the chiller system at a minimum temperature of −10° C. (at 4.37 pisa), and 1.19 cc/hour while the chiller system is stopped at a machine ambient temperature of 0° C. (at 6.94 pisa). Also, the mass ratio of non-condensable gas with respect to refrigerant flowing into the purge tank is 5% non-condensable gas versus 95% refrigerant (i.e., 0.15E-3 kg/hr of non-condensable gas versus 2.89E-3 kg/hr of refrigerant, combined total 3.04E-3 kg/hr). The surface area of the purge heat exchanger coil is estimated to be 6.69E-2 m2. The estimated frequency of executing the purge mode is 30 minutes per day. This is much smaller than current conventional purge systems. The rate at which refrigerant discharged from the purge tank is adsorbed by the carbon filter is estimated to be 1.5E-3 kg/hr. The required frequency of executing the recovery mode is estimated to be as low as once per 100 days. However, it is anticipated that the recovery mode will be executed once every ten days to prevent the carbon filter from becoming saturated with refrigerant.
In understanding the scope of the present invention, the term “comprising” and its derivatives, as used herein, are intended to be open ended terms that specify the presence of the stated features, elements, components, groups, integers, and/or steps, but do not exclude the presence of other unstated features, elements, components, groups, integers and/or steps. The foregoing also applies to words having similar meanings such as the terms, “including”, “having” and their derivatives. Also, the terms “part,” “section,” “portion,” “member” or “element” when used in the singular can have the dual meaning of a single part or a plurality of parts.
The term “detect” as used herein to describe an operation or function carried out by a component, a section, a device or the like includes a component, a section, a device or the like that does not require physical detection, but rather includes determining, measuring, modeling, predicting or computing or the like to carry out the operation or function.
The term “configured” as used herein to describe a component, section or part of a device includes hardware and/or software that is constructed and/or programmed to carry out the desired function.
The terms of degree such as “substantially”, “about” and “approximately” as used herein mean a reasonable amount of deviation of the modified term such that the end result is not significantly changed.
While only a selected embodiment has been chosen to illustrate the present invention, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made herein without departing from the scope of the invention as defined in the appended claims. For example, the size, shape, location or orientation of the various components can be changed as needed and/or desired, so long as the purge tank 51 is arranged generally higher than the condenser. Components that are shown directly connected or contacting each other can have intermediate structures disposed between them. The functions of one element can be performed by two, and vice versa. The structures and functions of one embodiment can be adopted in another embodiment. It is not necessary for all advantages to be present in a particular embodiment at the same time. Every feature which is unique from the prior art, alone or in combination with other features, also should be considered a separate description of further inventions by the applicant, including the structural and/or functional concepts embodied by such feature(s). Thus, the foregoing descriptions of the embodiments according to the present invention are provided for illustration only, and not for the purpose of limiting the invention as defined by the appended claims and their equivalents.
As used herein, such directional terms as “vertical,” “up”, “down”, “upper,” “lower,” “higher,” “lower,” “above,” “below”, “upward”, “downward”, “top”, and “bottom”, as well as any other similar directional terms, refer to those directions of the components and or the system as a whole in an installed state. Accordingly, these directional terms, as utilized to describe the non-condensable gas purge system and the refrigeration circuit for a chiller system should be interpreted relative to a chiller system in typically installed state.
Additionally, the term “low pressure refrigerant” as used herein refers to any refrigerant or blend of refrigerants that is suitable for use in the refrigeration circuit of a low-pressure chiller system. A low pressure refrigerant is typically characterized by having an evaporation pressure equal to or lower than atmospheric pressure. Although the low pressure refrigerant R1233zd is used in the illustrated embodiment, one of ordinary skill in the refrigeration field will recognize that the present invention is not limited to R1233zd. The low pressure refrigerant R1233zd is a candidate for centrifugal chiller applications because it is non-flammable, non-toxic, low cost, and has a high COP compared to other refrigerants like R1234ze, which are current major alternatives for the refrigerant R134a. R1233zd is also a low GWP (Global Warming Potential) refrigerant and, thus, has the additional advantage of having a lower impact on global warming than conventional refrigerants having a higher GWP.
Also it will be understood that although the terms “first” and “second” may be used herein to describe various components these components should not be limited by these terms. These terms are only used to distinguish one component from another. Thus, for example, a first component discussed above could be termed a second component and vice versa without departing from the teachings of the present invention. The term “attached” or “attaching”, as used herein, encompasses configurations in which an element is directly secured to another element by affixing the element directly to the other element; configurations in which the element is indirectly secured to the other element by affixing the element to the intermediate member(s) which in turn are affixed to the other element; and configurations in which one element is integral with another element, i.e. one element is essentially part of the other element. This definition also applies to words of similar meaning, for example, “joined”, “connected”, “coupled”, “mounted”, “bonded”, “fixed” and their derivatives.