RU2631471C2 - Rotary valve for piston compressors and method related thereto - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: piston compressor 300 includes a compression chamber 310 for compressing fluid introduced through a suction opening into the compression chamber and discharged from said chamber after compression through a discharge opening. The actuator 350 is configured to generate angular movement. The rotary valve 340 is adapted to receive said angular movement and regulate opening and closing of the suction and discharge openings depending on the angular movement. The rotary valve 340 comprises a rotary disc made rotatable due to angular movement. There is a first opening providing input of the input fluid flow into a compression chamber when the first opening is aligned with the suction opening and a second opening providing outlet of the outlet fluid flow from the compression chamber when the second opening is aligned with the outlet opening. It is possible to adjust both the suction and discharge flow channels with a single actuator.

EFFECT: improvement of the rotary valve.

13 cl, 7 dwg

Description

Embodiments of the invention discussed herein generally relate to devices and methods for using a single actuator to control both the inlet and outlet of a fluid in a compression chamber of a reciprocating compressor, and more specifically, to actuate a rotary valve made with the possibility of closing or opening the inlet flow channel into the compression chamber and the exhaust flow channel from the compression chamber.

Compressors can be divided into volumetric (for example, screw or vane compressors) or dynamic compressors (for example, centrifugal or axial compressors). In volume compressors, compression is achieved by trapping gas and then decreasing its volume. In dynamic compressors, gas compression is obtained by transferring kinetic energy, usually from a rotating element, such as a blade impeller, to gas compressed by the compressor.

FIG. 1 illustrates a conventional reciprocating reciprocating compressor 10 with a dual chamber. The compression of the fluid occurs inside the housing 20, which is usually cylindrical in shape. The fluid to be compressed (eg, natural gas) is introduced into the housing 20 through the inlet 30 and the suction valves 32 and 34, and then, after compression, the fluid is discharged through the exhaust valves 42 and 44 and the outlet 40. This compression is a cyclic process in which the compression of the fluid occurs due to the movement of the piston 50 inside the housing 20 between the end face 26 from the side of the piston head and the end face 28 from the side of the crank. The piston 50 divides the housing 20 into two compression chambers 22 and 24, operating in different phases of the compression cycle, so that with a minimum value of the volume of the chamber 22, the volume of the chamber 24 has a maximum value and vice versa.

The suction valves 32 and 34 are configured to open to allow incoming fluid (having a first pressure P ₁ ) to enter the compression chambers 22 and 24, respectively. The exhaust valves 42 and 44 are configured to open to allow the release of the outgoing compressed fluid (having a second pressure P ₂ > P ₁ ), respectively, from the compression chambers 22 and 24. The piston 50 moves due to the energy transmitted to it by the crank 60 through the slider 70 and the piston rod 80. Valves 32, 34, 42 and 44 are shown located on the side walls of the housing 20, however, they can also be located at the ends 26 and 28 of the housing 20.

Typically, the suction and exhaust valves used in a reciprocating compressor are automatic valves that switch between a closed state and an open state due to the pressure difference across the valve (i.e., between the pressure on one side of the moving part of the valve and the pressure on its other side). The disadvantage of automatic valves is that they significantly increase the free unused volume of the compression chamber, since such a volume (for example, indicated by 25) is a volume that cannot be effectively used in the compression cycle. The greater the free unused volume, the lower the compression efficiency.

Actuated rotary valves minimize a portion of the unused volume of the compression chamber occupied by the valves and increase the flow cross section. FIG. 2A and 2B illustrate a conventional rotary valve 200 that can be installed to open and close a duct between inlet 30 and compression chamber 22. The valve 200 may be considered to be used in place of any of the valves 32, 34, 42 and 44. The valve 200 has a seat (or stator) 210 and a rotary part 220. The saddle 210 and the rotary part 220 are coaxial disks with holes occupying a sector of one and the same size around the rod 230. The pivot portion 220 can rotate around the rod 230 from a first position (FIG. 2A), in which its hole 222 is aligned with the hole 212 of the saddle, in a second position (FIG. 2B), in which the hole 222 and the hole 212 (shown by the dashed line) occupy different with the ector. When the rotary part 220 is located in the first position, the valve 200 is in the open state, allowing fluid to pass through the valve. When the portion 220 is located in the second position, the valve 200 is in the closed state, thereby preventing the passage of fluid through the valve.

The use of rotary valves in compressors used in the oil and gas industry is difficult, if not impossible. Compressors used in the oil and gas industry must meet the specific requirements of this industry, which take into account, for example, the fact that compressed fluid is often corrosive and flammable. The American Petroleum Institute (API), an organization setting an official industry standard for equipment used in the oil and gas industry, has released API618, listing a number of minimum requirements for reciprocating compressors.

Given the fact that the actuation time of valves used in the oil and gas industry is usually about 5 ms, actuators will require large-sized (as regards the available space) actuators for actuating rotary valves. Due to the possible danger of an explosion, the electric actuators for the valves (providing the required actuation time) are preferably arranged so that they are not in contact with the flammable gas, while the movement imparted by these actuators is mechanically transmitted to the movable part of the valve located in fluid contact. The space necessary to accommodate the actuator and means for transmitting the movement specified by the actuator to the movable part of the valve may not always be available. In addition, the end face of a reciprocating compressor with a dual chamber located on the side of the crank usually has less free space than its end on the side of the piston head.

Accordingly, there is a need for a technical solution alternative to automated valves for reciprocating compressors used in the oil and gas industry, satisfying these requirements and taking into account limited space.

The use of rotary valves in reciprocating compressors has the advantage of controlling both the suction and exhaust flow channels using a single actuator. Rotary valves can be installed on the end face of a reciprocating compressor with a dual chamber located on the side of the piston head and on its end on the side of the crank. In a twin-chamber reciprocating compressor, two rotary valves can be actuated using the same actuator.

In accordance with an illustrative embodiment, the reciprocating compressor comprises (1) a compression chamber configured to compress a fluid entering the compression chamber through the inlet and discharged from the compression chamber after the compression process through the outlet, (2) an actuator configured to creating an angular displacement, and (3) a rotary valve configured to sense angular displacement and regulate the opening or closing of the suction port or outlet depending on the angular displacement. The rotary valve comprises a rotary disk configured to rotate due to the indicated angular displacement and having a first opening allowing the flow of suction fluid to enter the compression chamber when the first opening is aligned with the suction opening and a second opening allowing the outlet of the fluid media from the compression chamber when the second hole is aligned with the outlet.

In accordance with another illustrative embodiment, the reciprocating compressor with a dual chamber has (1) a housing divided into two compression chambers, each of which is configured to compress the fluid entering it through the suction port and discharged from the compression chamber through the outlet port, ( 2) a piston made with the possibility of movement along the housing with the provision of changing the volume of two compression chambers, (3) an actuator configured to create angular movement, and (4) two rotary th valve located on opposite ends of the housing and made with the possibility of perception of the specified angular displacement and regulation of the opening or closing of the suction port or outlet of the corresponding chamber depending on the angular displacement. Each rotary valve comprises a rotary disk configured to rotate due to the indicated angular movement, and having (A) a first hole allowing the flow of suction fluid to flow into the corresponding compression chamber when it is aligned with the suction hole, and (B) a second hole allowing the fluid outlet to exit the corresponding compression chamber when it is aligned with the outlet. The specified angular movement causes the rotation of at least one of the two rotary valves.

According to another illustrative embodiment, a rotary valve, which can be used at one end of the compression chamber, comprises an end plate with a suction port configured to allow the flow of suction fluid to enter the compression chamber, and an outlet configured to allow outlet fluid flow from the compression chamber. The rotary valve comprises a rotary disk having a first hole and a second hole located in different angular positions, so that when the first hole is aligned with the suction hole, a stream of suction fluid passes through them, and when the second hole is aligned with the outlet, the outlet passes through them fluid flow.

In accordance with another illustrative embodiment, a method for upgrading a reciprocating compressor, initially comprising two automated valves located on the end plate of the compression chamber of the reciprocating compressor, is proposed. The specified method includes (1) removing the movable parts of the valves while maintaining the seats of these valves in place, each seat having an opening extending into the inside of the compression chamber, (2) providing an actuator configured to create an angular movement, (3 ) mounting on the outside of the specified end of the compression chamber of the rotary disk having two holes located in different angular positions, so that one of the holes of the rotary disk is combined with the hole of one of the seats in the first m angular position, and the second openings of the rotary disc is aligned with a hole of the other of the seats in the second angular position different from the first angular position. The specified method further includes (4) attaching the rotary disk to the actuator to enable said disk to be rotated due to the indicated angular movement to positions in which one of the holes of the rotary disk is aligned with the corresponding hole of one of the saddles so that a fluid flow can pass through them media in or out of the compression chamber.

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate one or more embodiments and, together with the description, explain these embodiments. In the drawings

FIG. 1 is a schematic view of a conventional twin chamber reciprocating compressor;

FIG. 2A and 2B depict a conventional rotary actuator valve, respectively, in open and closed states;

FIG. 3 schematically depicts a piston compressor with a single chamber in accordance with an illustrative embodiment;

FIG. 4 shows a rotary disk of a rotary valve in accordance with an illustrative embodiment;

FIG. 5 depicts schematically a twin-chamber reciprocating compressor in accordance with an illustrative embodiment;

FIG. 6 is a schematic illustration of a dual chamber reciprocating compressor in accordance with an illustrative embodiment; and

FIG. 7 depicts a flow chart of a piston compressor retrofit method in accordance with an illustrative embodiment.

The following description of illustrative embodiments is given with reference to the accompanying drawings. The same reference numbers in different drawings denote the same or similar elements. The following detailed description does not limit the invention. The scope of legal protection of the invention is defined in the attached claims. A discussion of the following embodiments for simplicity is made using terminology and design related to reciprocating compressors used in the oil and gas industry. However, the embodiments discussed below are not limited to these compressors, as they can be used in other installations that require power, at a low cost and less footprint.

The reference in this description to “one embodiment” or “embodiment” means that a particular feature, structure or characteristic described in relation to one embodiment is included (a) in at least one embodiment of the invention. Thus, the appearance of the wording “in one embodiment” or “in an embodiment” at various places in the description does not necessarily refer to the same embodiment. In addition, specific features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

As described in relation to the prior art, one technical problem related to the use of actuating valves in reciprocating compressors is that an actuator capable of providing angular movement in a very short time (approximately 5 ms) is relatively cumbersome and relates to electrical equipment . Due to the flammability of the fluid in the oil and gas industry, the actuator must not be in contact with this fluid, and the drive movement must be transmitted to the movable part of the valve in contact with the fluid. The space required to install the actuator and gear for each valve may not be available in close proximity to the valves of the reciprocating compressor. Some of the embodiments described below use one actuator to control (i.e., open and close) two channels for flow to and from the compression chamber. In addition, in some embodiments, the same actuator provides control of all four flow channels to and from the compression chambers in a reciprocating compressor with a dual chamber.

In accordance with the illustrative embodiment shown in FIG. 3, a single-chamber reciprocating compressor 300 includes a compression chamber 310 for receiving fluid through a suction port 320, compressing a fluid, and then discharging it from a chamber 310 through an outlet 330. Which of the two fluid channels is open to the chamber 310 from the hole 320 or from the chamber 310 to the hole 330, depends on the location of the holes of the rotary disk 340, making a rotation due to the angular movement created by the actuator 350. The disk 340 is a switching (movable) element ntom rotary valve regulating where fluid extends - in the chamber 310 or out of it. The holes of the disk 340 are made so that they are aligned with the suction port 320 and the outlet port 330 in certain angular positions. A suction port 320 and an exhaust port 330 are formed at the end face 360 of the chamber 310 from the side of the piston head. The volume in which the disk 340 is located is separated from the environment by a cover 365.

Due to the reciprocating movement of the piston 370 along the axis 375, the compression of the fluid occurs cyclically with time correlation with the opening or closing of the holes 320 and 330 by means of a disk 340.

In FIG. 4 is a front view of a rotary disk 340 having a first hole 342 through which a fluid stream enters the compression chamber 310 when the first hole 342 is aligned with a suction hole 320. The disk 340 also has a second hole 344 through which a fluid stream exits the chamber 310 when the second hole 344 is aligned with the hole 330.

The angular movement of the disk 340 is transmitted from the actuator 350 through a gear transmission. Angular movement can be a continuous rotation (in one direction), or rotation with alternation (clockwise and counterclockwise). The actuator 350 is preferably located outside the working fluid to avoid the risk of explosion (provided that the fluids are possibly flammable). The gear train comprises a valve side shaft 380 extending through the cover 365. The gear 382 is attached to the end of the shaft 380 and is meshed with the disk 340 (i.e., the teeth 382A of the gear 382 are meshed with the teeth 340A of the disk 340) inside the volume filled with fluid between the disk 340 and the cover 365. The other gear 384 is attached to the other end of the shaft 380. One end of the shaft 390 from the side of the actuator is attached to the actuator 350, and the other end is attached to the gear 392 located bobbing in mesh with gear 384 (i.e., teeth 384A of gear 384 are engaged with teeth 392A of gear 392). The rod 380 may have collars 386 and bushings 388 located on both sides of the cover 365 to improve stability during operation.

In FIG. It is shown in FIG. 3 that the actuator 350 and the gear train are located closer to the suction port 320. However, in other embodiments, it may be located closer to the outlet 330, or elsewhere around the compression chamber 310. It should be understood that between the components shown in FIG. 3, or in other illustrative embodiments shown in the drawings, the relative dimensional relationship is not maintained.

In the oil and gas industry, a reciprocating compressor with a dual chamber (or double acting) is used more often than a reciprocating compressor with a single chamber (or single acting). FIG. 5 shows a reciprocating compressor 500 with a dual chamber in accordance with yet another illustrative embodiment. The compression of the fluid occurs due to the reciprocating movement of the piston 510 located inside the housing 520 between the end plate 530 from the side of the piston head and the end plate 540 from the side of the crank. The piston 510 divides the housing 520 into two compression chambers 522 and 524 operating in different phases, so that with a minimum value of the volume of the chamber 522, the volume of the chamber 524 has a maximum value and vice versa. The piston 510 moves back and forth due to the energy it receives, for example, from a crank through a slider (not shown) and piston rod 512.

Through the end plate 530 from the side of the piston head pass a suction hole 532 and an outlet 534 communicating with the compression chamber 522. Similarly, through the end plate 540 from the crank side, a suction port 542 and an outlet 544 communicating with the compression chamber 524 pass. Outside the housing 520, rotary disks 550 and 560 are located, respectively, at the end on the side of the head and the end on the side of the crank. The disks 550 and 560 are rotatable due to angular displacement perceived from actuators 570 and 580, respectively. Each of the disks 550 and 560 has a first opening, which allows the flow of fluid into the corresponding compression chamber 522 or 524, when the first the hole is aligned, respectively, with the suction hole 532 or 542. In addition, each of the discs 550 and 560 has a second hole, making it possible for the fluid flow to exit from the corresponding compression chamber 522 or 524, when yes, the second hole is aligned, respectively, with the outlet 534 or 544. The design of the discs 550 and 560 may be similar to the design of the disc 340 shown in FIG. 4. Some of the details of the end face facing the crank (ie, around the disk 560) are not shown so as not to obscure the details related to this issue.

Gears 575 and 585 are configured to transmit angular displacement, respectively, from actuators 570 and 580, respectively, to discs 550 and 560. Covers 555 and 565 separate the volume of fluid from the external environment. A detailed description of each of the components of the gears is not given, since these gears are similar to the gear described for the compressor 300 with a single chamber.

Although the reciprocating compressor 500 with a dual chamber is shown in FIG. 5 with rotary valves (formed by rotary disks) 550 and 560 located on both ends of the piston head and crank side, however, other embodiments may include a rotary valve on only one of these ends, as well as valves another type located at the other end of the compression chambers.

FIG. 6 illustrates a reciprocating piston compressor 600 with a dual chamber, comprising rotary valves located at the ends of both the piston head side and the crank side. The disks 550 and 560 of the compressor 600 drive the same actuator 590 instead of the two actuators 570 and 580 shown in FIG. 5. Since the components of compressor 600 are similar to those of compressor 500, a description is not given.

Existing piston compressors with automated valves can be upgraded using a rotary actuator (s). In FIG. 7 is a flowchart of a method 700 for upgrading a reciprocating compressor, initially comprising two automated valves located on the end plate of the compression chamber of said compressor. At step S710, method 700 includes removing the movable parts of the automated valves while keeping the seats of these valves in place, with each seat having an opening extending into the interior of the compression chamber. The suction valve seat can serve as a suction port, and the outlet valve seat can serve as an outlet.

The method 700 in step S720 further includes providing an actuator configured and connected to create angular movement, and in step S730, mounting an rotary disk having two holes in different angular positions from the outside of the compression chamber.

In step S740, method 700 also includes attaching a rotary disk to an actuator to enable rotation of the disk as a result of angular movement to positions in which one of the holes of the disk is aligned with the hole of one of the seats, making it possible for fluid to flow through them towards or out of the compression chamber.

Method 700 may further include mounting a gear train for transmitting angular displacement from an actuator to a rotary disk. The gear train can be made so that it passes through the piston compressor cover separating the volume filled with the fluid from the external environment where the actuator is located.

If the piston compressor to be upgraded is a piston compressor that contains two sequential compression chambers in the housing and initially contains two second automatic valves located at the end of the housing opposite the end on which the first two automatic valves are located, then the method 700 may further include the steps of: replacing two second automatic valves to the new rotary valve. Thus, the method 700 may include (1) removing the movable parts of the second two valves while keeping the seats of these valves in place, each seat having an opening extending into the inside of the second compression chamber, (2) mounting the opposite end of the new rotary a disk having two second holes in different angular positions, and (3) attaching a second rotary disk to the actuator with the possibility of rotation of this disk, due to angular movement, in positions in which one from the holes of the second rotary disk is combined, respectively, with one of the two second holes, making it possible for the fluid to flow through them to or from the second compression chamber.

The disclosed illustrative embodiments offer reciprocating compressors with at least one rotary valve and a method of modernizing existing piston compressors with at least one rotary valve in them. It should be understood that this description is not intended to limit the invention. On the contrary, it is understood that exemplary embodiments encompass variants, modifications, and their equivalents that are included in the spirit and scope of the invention as defined in the appended claims. In addition, in the detailed description of illustrative embodiments, numerous specific details are set forth in order to provide a thorough understanding of the claimed invention. However, one of skill in the art should understand that various embodiments may be practiced without the use of such specific details.

Although the features and elements of the illustrated illustrative embodiments are described in specific combinations, each feature or element may be used individually without other features and elements of these embodiments, or in various combinations with other features and elements discussed herein, or without them. .

The above description uses examples of the invention, which enable a specialist to put it into practice, including the implementation and use of any devices or systems, as well as the implementation of any related methods. The scope of legal protection of an invention is determined by its formula, while it may include other examples that will be encountered by specialists. It is understood that such examples fall within the scope of legal protection of the claims.

Claims (34)

1. A piston compressor comprising: a compression chamber having a volume for compressing a fluid entering the compression chamber through the suction port, wherein said medium is discharged from said compression chamber through an outlet after the compression process; compressor cover; an actuator configured to create angular displacement; and a rotary valve configured to sense said angular movement with a rod located on the valve side, the valve located on the valve side being able to pass through the compressor cover and control opening and closing of the suction port and outlet depending on the angular displacement wherein the rotary valve contains: a rotary disk, made with the possibility of rotation due to angular movement; a first opening permitting the flow of suction fluid into the compression chamber when the first opening is aligned with the suction opening, and a second hole allowing fluid to escape from the compression chamber when the second hole is aligned with the outlet, wherein the first end of the rod located on the side of the actuator is attached to the actuator, and the second end of the rod located on the side of the actuator is attached to the gear. 2. The piston compressor according to claim 1, wherein the gear train is located outside the compression chamber and is configured to transmit angular displacement from the actuator to the rotary disk of the rotary valve. 3. The piston compressor according to claim 2, wherein the gear train comprises: a rod located on the side of the actuator and attached to the actuator, and at least two gears, including a first gear attached to the specified shaft located on the side of the actuator, with the possibility of rotation with it, and a second gear, designed to transmit angular movement to the rotary disk of the rotary valve. 4. The piston compressor according to claim 3, wherein the gear train comprises a second gear wheel at one end of a shaft located on the valve side, and a third gear attached to the other end of the shaft located on the valve side and meshed with the first gear. 5. The piston compressor according to claim 4, in which the shaft located on the valve side has a first shoulder located between the cap and the second gear, and a second shoulder located between the cap and the third gear, and the gear further comprises a first sleeve located between the first shoulder and the cover, and a second sleeve located between the second shoulder and the cover. 6. The piston compressor according to claim 1, which is a reciprocating compressor containing two compression chambers, wherein the rotary valve is located at its end from the side of the piston head or at the end from the side of the crank, and said compression chamber is one of the two compression chambers. 7. The piston compressor according to claim 6, further comprising: a second rotary valve, configured to control the opening and closing of the suction port and the outlet of the second of the two compression chambers, depending on the angular movement transmitted to the second rotary disk configured to rotate due to the angular movement, and having: another first hole, allowing the flow of the suction fluid into the second of the two compression chambers when the other first hole is combined with the suction hole, and another second orifice allowing fluid to escape from the second of the two compression chambers when the other second orifice is aligned with the outlet. 8. The piston compressor according to claim 7, comprising: at least one gear transmission, configured to transmit angular displacement from the actuator to bring into rotation the rotary disk of at least one of these two rotary valves. 9. The reciprocating compressor according to claim 1, wherein the cover separates the external environment from the volume in which the rotary disk is located, wherein said volume is located between the cover and the bottom of the compression chamber. 10. The piston compressor according to claim 1, in which the rod located on the valve side connects the actuator with a rotary disk. 11. A method of upgrading a reciprocating compressor, initially containing two automated valves located on the end plate of the compression chamber of the reciprocating compressor, including: removal of the movable parts of the valves while maintaining the seats of these valves in place, with each seat having an opening extending into the interior of the compression chamber, providing an actuator configured to create angular movement, wherein the actuator is designed so that it is not in contact with a fluid compressed by the compressor, mounting outside the specified end of the compression chamber of the rotary disk having two holes located in different angular positions, so that one hole of the rotary disk is combined with the hole of one saddle in the first angular position, and the other hole of the rotary disk is combined with the hole of the other saddle in the second angular position, different from the first angular position, and attaching the rotary disk to the actuator through the compressor cover, allowing rotation of the indicated disk due to angular movement, while the rod located on the valve side is connected at one end to the rotary disk and connected to the actuator at its other end. 12. The method according to p. 11, in which the cover separates the external environment from the volume in which the rotary disk is located. 13. The method according to p. 11, in which a rod located on the side of the valve connects the actuator with a rotary disk.

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