Patent Grant
11874041
The present disclosure relates to devices, methods, and systems for extracting heat, and more particularly, to devices, methods, and systems for extracting heat from air to produce gases having different temperatures.
Refrigerants, such as chlorofluorocarbons (CFCs) and hydrochlorofluorocarbons (HCFCs), are commonly used in air conditioning systems. However, conventional refrigerants or their alternatives may result in environmental impacts, such as causing the greenhouse gas emission or adversely affecting the stratospheric ozone layer. In addition, some refrigerants may be flammable or toxic. While liquid-cooling systems have been applied in various applications, such as industrial cooling towers, most of those systems consume significant amount of water. Many systems also require continuously circulating cooling water through heat exchangers to dissipate heat. Water consumption frequently presents constraints for regions where water resource is limited.
Accordingly, as the awareness of sustainability grows, it may be desirable or beneficial to improve air conditioning or cooling systems to provide energy-efficient and/or environment-friendly systems. It may also be desirable to meet increasingly stringent eco-friendliness standards in various sectors.
The present disclosure provides a pump. Consistent with one of the embodiments, the pump includes a first chamber containing a working fluid and providing a first space, the first space being above at least a portion of the working fluid that is within the first chamber; an input passage coupled to the first chamber and configured to provide gas having a first temperature; a second chamber coupled with the first chamber, the working fluid flowable between the first chamber and the second chamber via at least one first flow passage between the first chamber and the second chamber, the second chamber providing a second space, the second space being above at least a portion of the working fluid that is within the second chamber; a first output passage coupled to the second chamber and configured to output the gas having a second temperature, the second temperature being lower than the first temperature; and a control device coupled to the first chamber and the second chamber via one or more second flow passages, wherein the one or more second flow passages have a controllable gas flow between the first chamber and the control device or between the second chamber and the control device.
Consistent with some other embodiments, the present disclosure further provides a method for extracting heat. The method includes during a first period: opening a first passage between a first chamber and a third chamber to compress gas in the third chamber; and opening a second passage between a second chamber and a fourth chamber to decompress gas in the fourth chamber. The method also includes during a second period following the first period: closing the first passage and the second passage; enabling a gas flow into the first chamber, the gas flow including gas having a first temperature; and outputting gas having a temperature that is lower than the first temperature of the gas in the second chamber.
Consistent with further embodiments, the present disclosure further provides an air conditioning system. The air conditioning system includes a first chamber and a second chamber coupled with each other, a working fluid being flowable between the first chamber and the second chamber via at least one first flow passage between the first chamber and the second chamber; a control device coupled to the first chamber and the second chamber via one or more second flow passages having a controllable gas flow between the first chamber and the control device or between the second chamber and the control device; an input passage configured to provide gas having a first temperature; and a first output passage configured to output gas having a second temperature, the second temperature being lower than the first temperature.
It is to be understood that the foregoing general descriptions and the following detailed descriptions are exemplary and explanatory only, and are not restrictive of the disclosure, as claimed.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate several embodiments and, together with the description, serve to explain the disclosed principles. In the drawings:
Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings and disclosed herein. Wherever convenient, the same reference numbers will be used throughout the drawings to refer to the same or like parts. The implementations set forth in the following description of exemplary embodiments are examples of devices and methods consistent with the aspects related to the disclosure as recited in the appended claims, and not meant to limit the scope of the present disclosure.
Chambers 120 and 140 are coupled with each other via a flow passage 110. Chambers 140 and 160 are coupled with each other via a flow passage 130. In some embodiments, the gas may flow between chambers 120 and 140 via flow passage 110. On the other hand, a control valve 150 is arranged at an end of flow passage 130 and configured to open or close, partially or fully, to control the gas flow between chambers 140 and 160.
Then, during a second period, control valves 126, 146, 150, and 166 may be closed to block the gas flow. Piston 124 is configured to move back to its TDC position. During this process, the movement of piston 124 causes an adiabatic compression of the gas in chambers 120 and 140, and the pressure and the temperature of the gas in chamber 140 both rise accordingly. For example, the gas in chamber 140 may be at a temperature (e.g., temperature T1, such as temperature around 390K-520K depending on the compression ratio) higher than the initial temperature.
Next, during a third period, control valve 150 may be opened while control valves 126, 146, and 166 may be closed to block the gas flow. Piston 164 is configured to move to its BDC position. During this process, the movement of piston 164 causes the gas in chamber 140 flows into chamber 160, which is an adiabatic expansion process and causes a drop in the temperature.
Next, during a fourth period, control valves 126 and 150 may be closed, while control valves 146 and 166 may be opened. Pistons 144 and 164 are both configured to move back to their TDC positions, causing pump 100 separately outputting the gas in chamber 140 and the gas in chamber 160 via output passages 142 and 162. When pistons 144 and 164 are positioned back at their TDC positions, a cycle is completed and pump 100 may return to the initializing period shown in
Assuming that the heat loss is nominal or can be ignored and the volume of chambers 120, 140 and 160 are the same, after the adiabatic compression and expansion in the second and the third periods, the average temperature of the gas in chambers 140 and 160 should be equal to the temperature of the inputted gas (e.g., temperature T0). However, temperatures of the gas in chamber 140 and of the gas in chamber 160 would be different. Particularly, during the adiabatic expansion, the work done by the gas results in the temperature drop. When the gas expands by dV, the work done by the gas in the expansion can be denoted as dW=(P1−P2)dV, in which P1 denotes the pressure in chamber 140 and P2 denotes the pressure in chamber 160, while the total work done by the gas in the expansion should be dW=(P1)dV to follow an adiabatic expansion to have the temperature of the gas in chamber 140 be back to the initial temperature.
Accordingly, in reality, the temperature of the gas in chamber 140 would be slightly lower than the temperature of the compressed gas (e.g., temperature T1) in the second period, but much higher than the initial temperature (e.g., temperature T0). Because the average temperature of chambers 140 and 160 would equal to the initial temperature, the gas in chamber 160 would be at a temperature (e.g., temperature T2) lower than the initial temperature. In addition, because during the expansion process, the pressure of chamber 140 is greater than the pressure of chamber 160, some gas moves from chamber 140 to chamber 160 via flow passage 130. Thus, the gas with the relatively low temperature does not flow back from chamber 160 to chamber 140.
By the adiabatic compression and expansion in the second and the third periods, the gas is divided into the gas having a relatively high temperature within chamber 140 and the gas having a relatively low temperature within chamber 160. Accordingly, when pistons 144 and 164 move from BDC positions to TDC positions, pump 100 outputs the high temperature gas in chamber 140 via output passage 142, and outputs the low temperature gas in chamber 160 via output passage 162.
In some embodiments, liquid pistons can be used to provide a greater adiabatic efficiency.
Chamber 220 also provides a space above at least a portion of the working fluid that is within chamber 220. Chambers 230 and 240 collectively form a control device for the adiabatic compression and expansion process, which will be discussed in detail in the following paragraphs. Particularly, chambers 230 and 240 are both coupled to chambers 210 and 220 via flow passages 284 and 286.
By the operations of control valves 214, 216, 224, and 226, flow passages 284 and 286 may be selectively opened or closed to control the gas flow between chamber 210 and the control device (e.g., chambers 230 and 240), or between chamber 220 and the control device (e.g., chambers 230 and 240). Alternatively stated, flow passages 284 and 286 have controllable gas flows between the chamber 210 and the control device or between the chamber 220 and the control device.
Input passage 202 is coupled to chamber 210 via a control valve 212 and is configured to provide the input gas having a first temperature into the space in chamber 210. Output passage 204 is coupled to chamber 220 via a control valve 222 and is configured to output the gas having a second temperature lower than the first temperature from the space in chamber 220.
Output passages 206 and 208 are separately coupled to chambers 230 and 240, via control valves 232 and 242 and are configured to output the gas having a third temperature higher than the first temperature from chambers 230 and 240.
As shown in
Air blower 270 is coupled to chambers 230 and 240 and configured to enable a gas flow into chambers 230 or 240 via a passage 296. In some embodiments, the gas flow includes a gas having a temperature lower than a current temperature of the gas in chamber 230 or 240. Control valves 236 and 246 arranged at two ends of passage 296 coupling chambers 230 and 240 are configured to respectively control whether the gas is flowable from air blower 270 to chambers 230 and 240, in order to adjust the temperature within chambers 230 and 240 and facilitate the operations of pump 200.
Then, as shown in
That is, when control valve 226 is opened to connect chamber 220 and chamber 240, as the pressure in chamber 220 becoming greater than the pressure in chamber 210, a portion of the working fluid in chamber 220 flows to chamber 210 via flow passage 282. Accordingly, the surface of working liquid within chamber 210 rises as the surface of working liquid within chamber 220 falls. As a result, a portion of the gas in the space of chamber 210 flows into chamber 230 via flow passage 284 to compress the gas in chamber 230, and the air pressure within chamber 230 increases to a pressure value P1, which is greater than the initial pressure value P0.
Then, as shown in
In addition, control valves 242 and 246 are also opened so that air blower 270 can provide the gas having a temperature (e.g., the initial temperature T0) lower than the current temperature T2 of chamber 240 via passage 296 and control valve 246 into chamber 240. Accordingly, a portion of the gas having the higher temperature (e.g., temperature T2) will be outputted via control valve 242 and output passage 208. Alternatively stated, in the second period, output passage 208 is configured to output a portion of the gas having a temperature higher than the initial temperature T0 from chamber 240 of the control device.
In order to facilitate the following operations, in some embodiments, control valve 234 can also be opened in the second period. By such operations, a portion of the gas compressed by air compressor 250 and stored in gas container 260 can flow into chamber 230 via passage 294 and control valve 234 to increase the air pressure within chamber 230, to ensure that the air pressure within chamber 230 is equal to or greater than the operating pressure value (e.g., pressure value P2).
During a third period following the second period, as shown in
That is, when control valve 224 is opened to connect chamber 220 and chamber 230, similar to the first period, the pressure in chamber 220 again becomes greater than the pressure in chamber 210, and thus a portion of the working fluid in chamber 220 flows to chamber 210 via flow passage 282. Again, the surface of working liquid within chamber 210 rises as the surface of working liquid within chamber 220 falls. As a result, a portion of the gas in the space of chamber 210 now flows into chamber 240 via flow passage 286 to compress the gas in chamber 240, and the air pressure within chamber 240 increases to the pressure value P1, which is greater than the initial pressure value P0.
Then, as shown in
In addition, control valves 232 and 236 are also opened so that air blower 270 can now provide a portion of the gas having the temperature (e.g., the initial temperature T0) lower than the current temperature T2 of chamber 230 via passage 296 and control valve 236 into chamber 230. Accordingly, a portion of the gas having the higher temperature (e.g., temperature T2) will now be outputted via control valve 232 and output passage 206. Alternatively stated, in the fourth period, output passage 206 is configured to output the gas having the temperature T2 higher than the temperature T0 from chamber 230 of the control device. By such operations, the control device having two chambers 230 and 240 can output the high-temperature gas via different output passages 208 and 206 in the second period and in the fourth period.
Similarly, to ensure that the air pressure within chamber 240 is equal to or greater than the operating pressure value (e.g., pressure value P2) for the first period in the next cycle, in some embodiments, control valve 244 can be opened in the fourth period so that a portion of the gas compressed by air compressor 250 and stored in gas container 260 can flow into chamber 240 via passage 294 and control valve 244 to increase the air pressure within chamber 240.
The operations shown in
The outputted high-temperature gas and low-temperature gas can be used in various applications. For example, an air conditioning system can include pump 200 to provide low-temperature air as the refrigerant. Compared to air conditioning systems using conventional refrigerants, which may be flammable or toxic and result in harmful environmental effects, air conditioning systems applying pump 200 can achieve simultaneous heating and cooling for residential or automobiles, with lower environmental impact than conventional heating and refrigeration devices. For example, air conditioning systems using low-temperature air as the refrigerant can reduce the greenhouse gas emission or the destruction of the stratospheric ozone layer contributed by conventional refrigerants. Moreover, liquid-cooling systems generally require a large amount of water resource. Air conditioning systems applying pump 200 provide gas cooling with improved efficiency, and thus are suitable to provide cooling where water resource is limited.
In addition, compared to other systems using air as the refrigerant, embodiments of the present disclosure provide a practical solution in various applications with an improved coefficient of performance (COP) and energy efficiency, and thus achieve the heating and cooling with lower energy consumption.
In some other embodiments, alternative devices or methods may be applied to replace air blower 270 and configured to exchange the high-temperature gas within chambers 230 and 240. For example, in some other embodiments, the control device may include one or more pistons (e.g., liquid pistons) arranged in chamber 230 and chamber 240 to exchange the gas within chamber 230 and chamber 240, so the heat energy stored in the high-temperature gas can be kept and reused in other energy forms. For example, a waste-heat-to-power system can be deployed to convert the heat into electricity.
In some other embodiments, the control device may include one or more spray devices coupled to chamber 230 or chamber 240. The spray device(s) can be configured to cool the gas in chamber 230 or chamber 240 by spraying liquid.
At step 512, during a first period (e.g., the period shown in
At step 522, during a second period (e.g., the period shown in
At step 532, during a third period (e.g., the period shown in
At step 542, during a fourth period (e.g., the period shown in
In some embodiments, the pump can repeat steps 512-548 continuously to generate high temperature and low temperature gases for air conditioning systems to heat or cool buildings or automobiles.
By performing method 500 described above, the pump can extract the heat from the inputted air to produce and output both high-temperature and low-temperature gases for various applications. In view of the above, as proposed in various embodiments of the present disclosure, the proposed devices and methods can improve the coefficient of performance and energy efficiency of air-cooling or conditioning systems.
In the foregoing specification, embodiments have been described with reference to numerous specific details that can vary from implementation to implementation. Certain adaptations and modifications of the described embodiments can be made. It is also intended that the sequence of steps shown in figures are only for illustrative purposes and are not intended to be limited to any particular sequence of steps. As such, those skilled in the art can appreciate that these steps can be performed in a different order while implementing the same method.
As used herein, unless specifically stated otherwise, the term “or” encompasses all possible combinations, except where infeasible. For example, if it is stated that a database may include A or B, then, unless specifically stated otherwise or infeasible, the database may include A, or B, or A and B. As a second example, if it is stated that a database may include A, B, or C, then, unless specifically stated otherwise or infeasible, the database may include A, or B, or C, or A and B, or A and C, or B and C, or A and B and C.
In the drawings and specification, there have been disclosed exemplary embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made to the disclosed system and related methods. Other embodiments will be apparent to those skilled in the art from consideration of the specification and practice of the disclosed system and related methods. It is intended that the specification and examples be considered as exemplary only, with a true scope being indicated by the following claims and their equivalents.
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|---|---|---|---|
| 3608311 | Roesel, Jr. | Sep 1971 | A |
| 20060059912 | Romanelli et al. | Mar 2006 | A1 |
| 20120055145 | Blieske | Mar 2012 | A1 |
| Number | Date | Country |
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| S 63162974 | Jul 1988 | JP |
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| 2006-336546 | Dec 2006 | JP |
| WO 9219924 | Nov 1992 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 20220186990 A1 | Jun 2022 | US |
