It should be noted that the figures are not drawn to scale and that elements of similar structures or functions are generally represented by like reference numerals for illustrative purposes throughout the figures. It also should be noted that the figures are only intended to facilitate the description of the preferred embodiments. The figures do not illustrate every aspect of the described embodiments and do not limit the scope of the present disclosure.
Compressors can be part of many thermodynamic systems, including vapor compression cycles (see e.g.,
For example, referring to the system 400 of
This can be depicted via a temperature-entropy diagram (e.g.,
In some embodiments, the most costly and performance-critical component of such a process can be the compressor. The compressor can serve to increase the pressure of the gas as efficiently as possible in some embodiments. In various examples, the compressor does this with an inlet valve, a compression chamber that changes volume along the compression stroke, and an exit valve.
Several problems can exist with compressors. First, compressor technologies used in vapor compression cycles can require lubricants and can have metal sliding or rolling seals which contain the fluid being compressed, which can be undesirable in some implementations. Such lubricants can include Polyolester (POE) and Polyvinyl Ether oil (PVE), or other oils. POE oils are hygroscopic, meaning they have a tendency to absorb moisture, and any moisture can combine with the oil to create acid, which can corrode components in the system. PVE oils are not hygroscopic, but they are slightly toxic. If lubricant is lost for any reason, these sliding metal surfaces can wear or seize, causing the compressor to fail.
Second, compressor technologies used in vapor compression cycles often cannot reliably accept liquid/gas mixtures, only pure gases. This means that in some examples the cycle must be designed to operate such that the inlet to the compressor does not contain any liquid droplets. The reason a compressor in various examples cannot accept any liquid/gas mixtures can be because of failure methods including: the liquid can wash away the lubricants causing wear or seizing and/or a pool of liquid which is not compressible can cause the compression chamber to experience undesirably large forces when the compressor tries to compress an incompressible fluid, which can damage components of the compressor.
Finally, some compressor technologies can have relatively small displacement volumes, or total inlet compression chamber volumes, for their total physical size. This can be because in some examples the compression chamber itself must have one sliding surface that moves in a rigid chamber, and such mechanisms and structure tend to not be space-efficient in various example. The result is that, in some examples, when the motor drive is included, the volume of the compressor can be much larger than the volume of the compression chamber.
One problem that can arise from the lack of capabilities of some compressors is that the selection of the fluid used in a vapor compression cycle, or the “refrigerant,” must be compatible with the displacement and lubricant used in a compressor. Various refrigerants can be harmful for the environment. A compressor that does not need lubricants and has a larger displacement would enable, in some embodiments, alternative fluids as refrigerants in vapor compression cycles that are more environmentally friendly, lower cost, and more efficient.
A compressor that is more space-efficient, that does not use lubricants (e.g., oil-based or synthetic lubricants), and that is compatible with small amounts of liquid in liquid-gas mixtures can increase the capabilities and reliability of vapor compression cycles in various embodiments. For example,
In various embodiments as discussed herein, reference to a “roll diaphragm,” and/or “roll-sock/diaphragm hybrid” should not be construed to mean a roll-sock with diaphragm-like mounting flanges. A roll diaphragm of various embodiments departs significantly from an arc profile shape, assuming more of a bell shape where the rolling section spans a large proportion of the total radius. In some embodiments, a “roll diaphragm,” and/or “roll-sock/diaphragm hybrid” can be differentiated from a roll sock or diaphragm. Accordingly, in various embodiments, one or more of the following can define a roll diaphragm and/or roll-sock/diaphragm hybrid:
The roll diaphragm structurally performs in tension, (e.g., like a roll sock) but not bending, like a diaphragm;
The roll diaphragm is capable of much greater displacement than a diaphragm, because in some embodiments the roll diaphragm operates in tension and not in bending, and so is capable of deforming by a much larger amount;
The roll diaphragm is capable of much greater pressure than a diaphragm because in some embodiments, while a diaphragm must support the pressure of the compression chamber in bending, a roll diaphragm can support the pressure of the compression chamber in tension, and the tensile strength of the diaphragm can be comparably high due to fiber reinforcement;
The roll diaphragm makes direct rolling contact with surrounding walls of the compressor, which can eliminate or substantially reduce dead volume within the compressor;
The curvature of a roll diaphragm is the inverse of a diaphragm (e.g., a balloon not a deflecting plate);
The roll diaphragm, like a roll sock, comprises tensile reinforcement (e.g., reinforcing fibers/elements);
The roll diaphragm, unlike a roll sock, does not operate between cylindrical walls—the constraining walls vary both axially and radially and have significant curvature (e.g., they can be bell-shaped); and
Unlike a roll sock, the radius of curvature of the roll diaphragm is a significant proportion of the diameter of the roll diaphragm, which can enable much higher wall thickness and higher fatigue life. For example, in the configuration shown in
In some embodiments, a refrigerant can comprise water or alcohols (e.g. methanol, ethanol, glycol), or mixtures of any of such compounds. These refrigerants may not be compatible with some lubricants, and such refrigerants can be more efficient in some examples if the inlet to the compressor is a mixture of gas and liquid. Some refrigerant mixtures can require operation at sub-atmospheric pressures and high volumes in some examples. For example, the cycle depicted in
Turning to
The compressor head 110 defines a concave portion 117 that includes a bell-shaped interface wall 111 that defines a portion of the compression chamber 130 along with the roll-diaphragm 120. The compressor head 110 further comprises an apex portion 116 that includes an inlet port 112 and outlet port 113, with a one-way inlet valve 114 and a one-way outlet valve 115 associated with the inlet port 112 and outlet port 113 respectively. The roll-diaphragm 120 couples with the head 110 at an edge 122. The roll-diaphragm 120 also comprises a central portion 123 that is coupled to and driven by the piston head 140.
The compressor 100 further includes a crank assembly 150 that comprises a crank-wheel 151 with a pin 152 is coupled to the crank-wheel 151 and a piston shaft 153 are rotatably coupled to the pin 152 and to the roll-diaphragm 120. Accordingly, rotation of the crank-wheel 151 can drive the roll-diaphragm 120 as discussed herein.
As illustrated in
As shown in
The piston head 140 rolls away from the head 110 as shown in
As shown in
Accordingly, as shown in
As shown in
The piston head 140 continues toward the head 110 until the roll-diaphragm 120 engages and/or nearly engages the interface wall 111. The compression chamber 130 is at its minimum volume and all or nearly all of the fluid is expelled from the compression chamber 130 via the open one-way outlet valve 115 and through the outlet port 113.
Accordingly, the roll-diaphragm compressor 100 can expel fluid from the compression chamber 130 by moving from configuration C to D to A, where the piston head 140 moves toward the head 110 such that the roll-diaphragm 120 moves toward and engages the interface wall 111. The compression chamber 130 decreases in volume and fluid leaves the compression chamber 130 through the outlet port 113 and via the open one-way outlet valve 115. In contrast to conventional compressor systems, the present embodiment leave little if any dead space (i.e., volume remaining in the compression chamber 130 at the end of the discharge cycle), which can substantially improve compressor efficiency. In various embodiments, the flexible roll-diaphragm 120 pressing against the interface wall 111 provides the benefit of forcing all or nearly all of the fluid out of the compression chamber 130 during the discharge stroke.
In various embodiments, a bell-shaped rounded interface wall 111 as shown herein can be beneficial because it can minimize the dead volume in the compression chamber 130 to improve compression efficiency of the roll-diaphragm compressor 100 as discussed above. In other words, because the roll-diaphragm 120 can conform to and engage with the curvature of the interface wall 111 and the inlet and outlet ports 112, 113, as shown in configuration A (
Some embodiments can include a sub-atmospheric pressure compressor 100 that is high-displacement, has no sliding seals, and/or has no lubricants. For example, such a compressor can comprise a roll diaphragm 120 and a bell-shaped “cylinder” head 110. The roll diaphragm 120 can be fixed/sealed to a base or edge 122 of the bell-shaped “cylinder” head 110, with the head 110 and diaphragm 120 defining the compression chamber 130 in which fluid can be compressed (e.g., as shown in
In some examples, the roll diaphragm 120 can be pushed against the “cylinder” head 120 by the force of atmospheric pressure, which can largely eliminate dead volume in the compression chamber 130 various examples, and can then be pulled away from the “cylinder” head 110 with a tensile rod connected to a motor, which pulls the working fluid into the compression chamber 130.
Because the “cylinder” head 110 contains no sliding surfaces in some examples, the entirety of the head 110 can be available as a valved surface, whereas the cylinder walls of a piston compressor can be sliding surfaces and thus cannot be easily used as a valved surface. This means that the “cylinder” head 110 of various embodiments can support very large valves or multiple valves in comparison to a piston compressor of the same capacity of some embodiments. Based on dimensions of some common piston compressors, the increased area for valves in the “cylinder” head 110 can be three times greater. In some examples, valves can be flat so as to minimize dead volume, or volume available for gas when the compressor 130 is in its completely compressed, or minimum internal volume (e.g., configuration A of
In various embodiments, valve location is not constrained to the surface area of a cylinder head 110, which can enable twice larger valves in various examples. Larger valves can have larger flow cross-sectional area, which can mean one fourth lower flow losses and higher efficiency compression in some examples.
The roll diaphragm 120 can be made in various suitable ways and comprise various suitable materials. For example, the roll diaphragm can comprise multiple layers, including, protective layers, insulating layers, wear resistant layers, impermeable layers, and the like. In various example, the roll diaphragm 120 can comprise a fiber-reinforced elastomer, (e.g., as in automobile timing belts). For example, in some embodiments the roll diaphragm 120 can comprise an elastomer body (e.g., rubber) having fiber chords (e.g., Kevlar, polyester, or the like) embedded therein that serve to reinforce the elastomer body. Such fiber chords can be inextensible along a main axis such that the fiber is substantially rigid and strong along its length while being flexible in other direction to allow for rolling of the roll diaphragm 120 as discussed herein. Fiber-reinforced elastomers used for a roll diaphragm 120 can provide for longevity at reasonable cost. Similar to automotive timing belts, in various embodiments, a roll diaphragm 120 can have low hysteresis loss, (i.e., can have low deformation energy and/or efficient energy recovery of the energy used to deform the roll diaphragm).
In some embodiments, a roll diaphragm compressor 100 can only have moving seals at the valves 114, 115, which can be non-sliding. The seal between the roll diaphragm 120 and the compressor “cylinder” head 110 can be static, enabling hermetic sealing, meaning leakages and the associated losses can be minimized in various embodiments (unlike some examples of sliding piston ring seals). This can mean that loss of the fluid being compressed can be minimized in some examples, which can be desirable for high-value fluids being compressed such as hydrogen or refrigerants, and can also be desirable for fluids that are harmful to the environment or people, such as some toxic refrigerants or explosive fluids.
Sliding seals of some compressors are friction surfaces that can generate heat, which can be a loss of energy and a reduction of compressor efficiency. For example, piston compressors can have piston rings that slide against the piston cylinder. A roll diaphragm compressor 100 of various embodiments can have no such sliding surfaces, meaning friction losses can be minimized or eliminated in various embodiments.
In some pressurized cylinder piston arrangements, the connecting rod can be under compressive load and can require a pivot or bearing surface at the piston. For sub-atmospheric operation of a roll diaphragm compressor 100, in accordance with some embodiments, the connecting rod 153 can always be in tension and can be replaced by a low-mass tensile flexural element. In some examples, such an element can provide for flexing the roll diaphragm 120 itself to achieve angular motion, which can eliminate another source of friction, wear and maintenance.
In various examples, a roll diaphragm compressor 100 that does not use sliding seals does not need lubrication to maintain those sliding seals. This means that lubrication does not need to be compatible with, and will not contaminate, the working fluid being compressed by the roll diaphragm compressor 100 in such examples. Accordingly, various embodiments of a roll diaphragm compressor 100 can operate without lubrication and/or sliding seals. Some compressor maintenance cycles can be centered around inspection of wear surfaces and management of lubricant. The removal of wear surfaces and/or lubricant in a roll diaphragm compressor can reduce the required maintenance cycle.
In some embodiments, elastomer/fiber composite material used for the roll diaphragm 120 can comprise meridional and/or radial tensile fiber elements with a small degree (for example, less than 10%) of circumferential compliance supplied by an elastomer of the roll diaphragm 120 to allow for the rolling motion of various embodiments. This can be because the primary direction of stress is in the radial direction, and the primary need for elasticity can be in the circumferential direction in some examples.
Vapor compression cycles of various embodiments can be well suited to the use of roll diaphragm compressors 100 as vapor compression cycles can operate at near-ambient temperature in various examples. Accordingly, high strength fibers and elastomers, from which the roll diaphragm 120 may be constructed, can be designed for near ambient temperature operation.
Several compression chambers 130 (each comprised of a roll diaphragm 120 and an interfacing bell-shaped cylinder head 110) can be configured in radial or in-line configurations, in order to improve dynamic balancing and/or to reduce torque ripple and/or bearing loads in some examples.
In some embodiments, a compressor 100 can be directly integrated with a direct drive electric motor so as to reduce bearing number, friction, system volume, and cost. For example, a crank assembly 150 can be directly mounted on an electric motor shaft.
In some embodiments, a roll diaphragm 1020 can be constructed similarly to a power transmission belt or tire, with high strength fiber reinforcement of an elastomer. Although, material selection and construction methods are not limited to conventional power transmission belt and tire materials and construction methods. For example, multiple layer construction can be included in some embodiments, including insulating layers, impermeable layers, and/or protective coatings. A roll diaphragm 120 can also use metallic wires or metallic leafs as the flexible tensile elements in accordance with further embodiments.
A roll diaphragm 120 can be constructed via a molding process. However other construction processes can include, for example, a concentric circle corrugated form constructed from a thin metallic sheet so as to engender axial compliance, with appropriate radial structural support.
In some embodiments, the roll diaphragm 120 does not strictly have to be circular in plan form, for example, elliptical shapes and rectangular shapes with semicircular ends can be present in various examples of a roll diaphragm 120. This can aid in the construction of more compact roll diaphragm compressors 100, and can also reduce circumferential elastomer compliance requirements of various embodiments.
Given that in various embodiments the roll diaphragm compressor 100 does not have piston rings that require a high tolerance lubricated sliding surface cylinder face, alternate materials can be used for the roll diaphragm accompanying housing face 111. For example, polymers and composite materials can be used, as can thin-wall metallic forms constructed in low-precision low-cost manners such as by simple press forming.
Vapor compression cycles can operate at near ambient temperatures. A methanol-water working fluid mixture is one example of a near-ambient-temperature vapor compression cycle. Near-ambient-temperature operation can allow for use of materials that operate at near ambient temperature, for example, composites, polymers, elastomers, and so forth. This can also enable the use of low-cost construction methods associated with some of these materials, for example, injection molding.
In some embodiments, a roll diaphragm compressor 100 can more easily work with two-phase liquid/gas fluids because the roll diaphragm 120 is flexible, reducing susceptibility to hydraulic lock, and because the lack of lubricants can mean that one does not have lubricant washing out problems.
Because the roll diaphragm 120 and interfacing bell-shaped cylinder head 110 can be hermetically sealed in various embodiments, a drive motor for the crank assembly 150 does not need to be part of the hermetic envelope in some examples. In some systems, a diaphragm compressor 100 can comprise both an electric motor and piston in the same hermetic envelope, since the compression chamber itself can leak. By having the electric motor outside the hermetic envelope in some examples, it can be more easily replaced or serviced and does not need to be sold as part of the compressor 100.
Sub-atmospheric pressure vapor compression cycles can use different working fluids. For example: methanol, ethanol, glycerol (antifreeze), water, and mixes of all the above. For example, the cycle depicted in
When various pure substances boil or condense, such substances do so at a constant temperature, meaning that a saturated mixture of gas and liquid at equilibrium, if heat is added, can stay at the same temperature until all of the liquid has evaporated into gas. Similarly, a saturated mixture of gas and liquid at equilibrium can stay at the same temperature if heat is removed, until all of the gas has condensed into liquid. This can approximate the thermodynamic process that happens in the condenser and evaporator of a vapor compression cycle using a single-component refrigerant. Mixtures of water and alcohols (for example, a mixture of 85% methanol and 15% water, as depicted in
This is depicted in the thermodynamic temperature-entropy diagram of
In embodiments where a compressor 100 is able to compress fluids which are mixtures of gas and liquid, further improvements to vapor compression cycle efficiency can be possible. The reason for this can be because compressing a gas causes it to heat up, and the amount of temperature which the gas increases can depend on if any evaporation process is taking place concurrently with the compression process. By introducing small amounts of liquid to the inlet 112 of the compressor 100, the gas at the outlet 113 of the compressor 100 can be slightly cooler which can result in a more thermodynamically efficient cycle. For example, in
Further examples can include a mixture having 91%-93% vapor by mass; 90%-94% vapor by mass; 89%-95% vapor by mass; 88%-96% vapor by mass; 87%-97% vapor by mass; 90%-92% vapor by mass; 85%-92% vapor by mass; 90%-70% vapor by mass, or the like. Further examples can include a mixture having 7%-9% liquid by mass; 6%-10% liquid by mass; 5%-11% liquid by mass; 4%-12% liquid by mass; 3%-13% liquid by mass; 2%-14% liquid by mass; 1%-15% liquid by mass; 8%-6% liquid by mass; 8%-4% liquid by mass; 8%-10% liquid by mass; 8%-12% liquid by mass, and the like.
This can be seen in
In some compression cycles, the inlet 112 to the compressor 100 is slightly to the right of the vapor saturation line 310V, meaning that the fluid is 100% gas. As a result, the exit 113 of the compressor 100 is superheated by a significant temperature amount. In
Some otherwise relatively efficient vapor compressor types, for example scroll compressors, can have a fixed compression ratio which can reduce their efficiency in operating over a range of pressures and temperatures. One-way-valve-based positive displacement compression can automatically adapt the output pressure ratio to that of the condensers and evaporators, enabling near optimal operation over a broad range of pressures and temperatures in some examples. A roll diaphragm vapor compressor 100 can be a positive displacement compressor that uses valves. In some examples, the compressor 100 can be capable of high efficiency over a broad range of pressures and temperatures.
Variable speed operation can directly control the mass flow rate of the working fluid independently of the pressure ratio. This can allow for direct control of the heating/cooling output of the vapor compression cycle independently of operating pressure ratio/temperature differential.
A sub-atmospheric vapor compression cycle (for example, the cycle in
A sub-atmospheric vapor compression cycle can be well suited to operation with secondary heat transfer loops, for example, ground source water loops and hydronic heating/cooling. Operation in conjunction with polymer heat exchangers that favor low pressure water loops can be desirable in some examples.
The depressed freezing point of water-alcohol mixes (antifreeze) can allow a sub-atmospheric vapor compression cycle to operate below the freezing point of water, though icing of external heat exchangers must still be mitigated in various examples, as per air source heat pump systems.
One preferred application of a sub-atmospheric vapor compression cycle is for air conditioning, and ideally, also space heating, in the same combined unit, where the local climate prompts the desire for both capabilities. Such air conditioning units can take the form of window units, central residential systems, commercial units, and industrial systems, for example.
Alcohol-water mixes can have depressed freezing points, for example antifreeze (ethylene glycol, see
Given the non-isothermal evaporation and condensation made possible by the working fluid soluble mixture in various embodiments, a vapor compression cycle can be used efficiently for sensible (i.e., heating of a substance which temperature changes as heat is added) heating and cooling. For example, a multistage vapor compression cycle can be constructed for efficient hot water heating using a near-ambient temperature thermal reservoir, such as air, a ground source thermal reservoir, lake, river, sea, and so forth. With multiple condenser steps, each with a temperature gradient such that the output temperature of one step matches the input temperature of the next, it can be possible to smoothly and efficiently heat water from ambient temperature with a minimum of exergy loss.
The temperature gradient of the evaporator, which only has a temperature differential corresponding to a single step in various embodiments, can be matched to the near-ambient temperature reservoir (e.g., as in
For example, referring to the system 700 of
The fluid from the condensers 710 can then go through one or more throttling valves 730, where the fluid experiences a pressure drop. The fluid from the throttling valves 730 can then flow to an evaporator 720, where the fluid draws heat from the evaporator 720 which can cause the fluid to vaporize. For example, fluid from the first condenser 710A can flow through a first, second and third throttling valve 730A, 730B, 730C to the evaporator 720; fluid from the second condenser 710B can flow through the second and third throttling valves 730B, 730C to the evaporator 720; and fluid from the third condenser 710C can flow through the third throttling valve 730C to the evaporator 720. The evaporator 720 can draw heat from a region that is to be cooled. The vaporized fluid can go back to the compressors 100 to restart the cycle.
Each condenser 710 can correspond to a different pressure ratio and the compressors 100 and throttling valves 730 can be tuned to match. For example, the first condenser 710A can correspond to a first pressure ratio and the first compressor 100A can be tuned to match the first pressure ratio; the second condenser 710B can correspond to a second pressure ratio and the second compressor 100B can be tuned to match the second pressure ratio; and the third condenser 710C can correspond to a third pressure ratio and the third compressor 100C can be tuned to match the third pressure ratio. The series of the first, second and third throttling valves 730A, 730B, 730C can be tuned based on the first, second and third pressure ratio. For example,
To this end, in some examples, the compressors 100 comprise, for example, multiple roll diaphragm compressors 100 of differing pressures, volumes and/or time based separation where different compressor strokes are used to pump to different pressures/condensers 710. For example, each of the compressors 100 can operate with the compression chambers 130 having a different maximum operating volume of respective compression cycles of the compressors 100. Additionally, each of the compressors 100 can operate with the compression chambers 130 having a different average operating pressure of respective compression cycles of the compressors 100. Also, each of the compressors 100 can operate with the compression timing of each of the compressors being synchronized at the same frequency, being non-synchronized but staggered at the same frequency, or non-synchronized having different frequencies.
For example, since the pressure in the condenser and evaporator can be set by the temperature of the heat exchanger and the heat transfer rate, because a liquid/vapor mixture at thermodynamic equilibrium can have a pressure of the saturation pressure at the temperature of the heat exchanger, or at least close to it depending on the heat transfer rate and the closeness to thermodynamic equilibrium. In various embodiments, the expansion valve and the compressor speed can be adjusted to ensure that the liquid/vapor mixture is at the right flow rate to evaporate and condense to the desired vapor quality at the exit of the evaporator and condenser, respectively. This can be similar to how standard vapor compression cycles are controlled. The difference can be that the evaporator of one cycle will transfer energy from the condenser of the adjacent cycle, and so on, so that a device can be designed to operate similar to the example shown in
As for water heating, a vapor compression cycle can be used for sensible heating and cooling as applied to industrial processes. For example, the heating or cooling of fluids. In the case of sensible cooling, multiple sub-ambient temperature (e.g., below 22 degrees C.) evaporator steps can be used in some embodiments instead of above-ambient-temperature (e.g., above 22 degrees C.) condenser steps. In some examples, sub-ambient temperatures can in include below 20, 18, 16, 14, 12, 10, 8, or 6 degrees C., or the like. In some examples, above-ambient-temperature can include above 24, 26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46, or 28 degrees C., or the like.
Similar to the example vapor compression cycles shown in
The described embodiments are susceptible to various modifications and alternative forms, and specific examples thereof have been shown by way of example in the drawings and are herein described in detail. It should be understood, however, that the described embodiments are not to be limited to the particular forms or methods disclosed, but to the contrary, the present disclosure is to cover all modifications, equivalents, and alternatives.
This application is a non-provisional of and claims the benefit of U.S. Provisional Application No. 62/636,733, filed Feb. 28, 2018, which application is hereby incorporated herein by reference in its entirety and for all purposes.
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