The present invention relates to reciprocating compressors, and in particular to equipment for continuous regulation of the flow rate in the said compressors.
There are various possible methods of regulating the flow rate: devices external to the compressor which may be considered are on/off operation, variation of the speed of the motor driving the compressor, a by-pass between the delivery and inlet, and inlet throttling, while devices forming part of the compressor itself which may be considered are idle/load operation, backflow control and the introduction of an additional dead space which may be constant or variable.
Regulation by means of additional dead space is provided by adding a dead space to the cylinder to enable the opening of the pressure valves to be delayed, thus reducing the flow rate; it is possible to carry out either step regulation, by adding various dead spaces of different capacities, or continuous (stepless) regulation, by using an additional dead space of variable capacity, as indicated in U.S. Pat. No. 6,641,371.
Idle/load operation, which does not provide continuous regulation of the flow rate, is suitable when a storage reservoir is present in the system and a variation of the delivery pressure is acceptable; the pressure of the reservoir is controlled by a hysteresis regulator. Generally, the flow rate is regulated by actuators composed of pneumatic devices, which, by acting on a body (the pusher) present in each valve, enable the sealing element to be kept in a predetermined position (open), thus making the compressor idle (zero flow rate); when the said devices are inoperative, the compressor operates at maximum capacity.
The frequency of actuation of the pneumatic devices which operate the pushers of the inlet valves depends on the amplitude of the hysteresis, the volume of the reservoir and the maximum unbalance between the nominal flow rate and the minimum flow rate of the load; however, the said value must be limited to avoid excessive wear on the pneumatic devices.
This type of control of the flow rate of compressors causes a decrease of the global efficiency and of the power factor in the “idle operation” phase; furthermore, the heat generated in the “idle operation” phase is not dissipated, and thus increases the temperature of the sealing elements. Finally, the use of an actuator without position control, its limited response time and rise time, together with the presence of long pipes having limited cross sections and considerable dead space, and the absence of synchronization of the movement with the compressor shaft gives rise to a number of contacts at uncontrolled velocity between the sealing element and the pusher, which reduce the reliability of the valves, causing wear on the pusher and the breakage of the sealing element.
Backflow control is provided by delaying the closing of the inlet valve with respect to the closing point in the case of maximum flow rate. The gas which has entered the cylinder flows back into the inlet duct in a quantity proportional to the portion of the compression stroke during which the inlet valves are kept open.
The use of continuous regulation permits the use of storage reservoirs of limited capacity, since the pressure variations are practically absent. The actuation methods used up to the present time for controlling the position of the sealing element of the valves are of the pneumatic or oil hydraulic type.
Examples of some devices based on continuous backflow regulation are described in the documents U.S. Pat. Nos. 7,331,767 and 5,988,985. These devices use various actuation systems based on fluid which is supplied to a piston. Both systems require a panel for regulating the pressure of the fluid used for the actuation.
The object of the present invention is therefore to provide equipment for the continuous regulation of the flow rate in reciprocating compressors, by using essentially simple means which limit the wear of the valve components.
The present invention therefore proposes equipment for continuous regulation of the flow rate for a reciprocating compressor, provided with at least one compression chamber in which is slidably inserted a piston means movable with a reciprocating motion, at least one inlet valve for the fluid to be compressed and at least one outlet valve for the compressed fluid being provided in the said chamber, the said outlet valve being connected to a storage reservoir for the compressed fluid, and the said inlet valve being provided with translation means which can act on the obturator of the said valve, the said translation means being movable in a direction perpendicular to the plane of the said obturator, and interacting with actuator means which are movable in the said direction with a reciprocating motion by means of suitable operating means; the said operating means make it possible to control the velocity of displacement of the said actuator means in both directions of their movement; means for detecting the position of the said actuator means, means for detecting the position of the piston in the compression chamber and means for detecting the pressure in the reservoir are provided, the said detection means and the said operating means of the actuator means being connected to a central processing unit.
In a preferred embodiment, the operating means of the said actuator means are electromechanical, and in particular they comprise two solenoids. The actuator means comprise a rod provided in its central portion with a radially projecting magnetizable portion, the said portion interacting with the said solenoids and being placed in equilibrium between the solenoids by the use of suitable resilient loading means. One end of the rod is connected to the said translation means of the sealing element, while its opposite end interacts with means for detecting its position.
Further advantages and characteristics will be made clearer by the following detailed description of an embodiment of the present invention, provided, by way of example and without restrictive intent, with reference to the attached sheets of drawings, in which:
The rod 103 extending from the actuator 3 bears axially on the outwardly directed face of the said closing surface 522, this rod passing substantially through the whole length of the said actuator 3, and having, substantially in its central portion, the moving element 203, in the form of a disc of magnetizable material keyed to the said rod 103, the said moving element being positioned between two solenoids 303 and 403, and being movable in a reciprocating way over a given path. Resilient loading means 213 and 223, which interact with the flanges 113 and 123 respectively of the rod 103, are provided in the actuator 3.
The opposite end of the cylindrical body 803 of the actuator 3 comprises a cap 603 provided with a threaded axial hole 613, into which is inserted the block 503, which is also threaded; the said block has a cavity 513 facing towards the inside of the actuator, the spring 223 which interacts with the flange 123 of the rod 103 pressing into this cavity, and a cavity 543 facing the outside of the actuator 3, this cavity housing the plate 173 connected to the end 163 of the rod 103, which interacts with the sensor 42. The two cavities communicate by means of the channel 533, through which the end 163 of the rod 103 passes. The position of the block 503 can be fixed by means of the locking bolt 523.
The operation of the equipment according to the present invention will be made clear by the following text, with particular reference to the figures described above and to the graphs in
In the equipment according to the present invention, the solution is implemented by providing the sealing element translation means, in this case the pusher 502 of the valve 2 with its prongs 512 which, in a first position acts on the surface of the sealing element 302, with actuator means operated in such a way as to enable their velocity of displacement to be controlled in both directions of their movement, with markedly reduced reaction times. In a second position, the prongs 512 engage the sealing element, keeping it off of the valve seat and thus keeping the valve open. In this case, the operation is provided by means of the two solenoids 303 and 403 which cause the displacement of the moving element 203 which is fixed to the rod 103. The processing unit 40 detects the position of the piston 101 by means of the sensor 43 located on the shaft 20, and then coordinates the movement of the rod 103. As shown in the graph of
The moving part of the pneumatic actuator and consequently the pusher of the inlet valve have a very slow movement, equal to several compression cycles, and therefore a series of impacts occurs between the pusher and the valve obturator. The high transition velocity of the electromechanical actuator makes it possible to complete the whole of the compressor's loading cycle within a limited portion of the operating cycle, thus controlling the velocity of the impact of the sealing element against the valve seat, and avoiding the series of impacts between the pusher and the sealing element.
Thus the regulation of the flow rate of the compressor is achieved while the stress factors causing the deterioration of the sealing element 302 are kept to a minimum; this is because the contact between its surface and the prongs 512 of the pusher 502 always occurs at very low velocities, with a reasonably low degree of impact. Furthermore, the central processing unit always has a precise confirmation of the position of the rod 103, owing to the sensor 42, and the signal to the solenoids 303 and 403 can therefore be suitably regulated, by means of the control and monitoring probe 45. It should be noted that the position of the rod 103 of the actuator 3 can be regulated by means of the block 503, and similar the distance between the solenoids 303, 403 can also be selected conveniently according to the travel required to actuate the pusher 502.
With reference to the operation of a reciprocating compressor with step regulation of the “idle/load” type,
The moving part of the actuator starts its positioning not on the rising edge of the signal (D), but on the edge of the signal from the sensor 43 (C), in order to avoid a high contact force caused by the high internal pressure of the cylinder: in this situation, the inlet valve is already open, because the contact pressure due to the impact between the pusher and the sealing element is absent.
Similarly, during the return of the actuator rod, a phenomenon found in pneumatic actuators is avoided, owing to the limited return velocity: the moving part of the pneumatic actuator and consequently the pusher of the inlet valve have a very slow movement, equal to several compression cycles, and therefore a series of impacts occurs between the pusher and the sealing element of the valve. The high transition velocity of the electromechanical actuator makes it possible to complete the whole of the compressor's loading cycle within a limited portion of the operating cycle, thus controlling the speed of the impact of the sealing element against the valve seat, and avoiding the series of impacts between the pusher and the sealing element.
Number | Date | Country | Kind |
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GE2006A0067 | Jun 2006 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/056244 | 6/22/2007 | WO | 00 | 12/23/2008 |
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WO2008/000698 | 1/3/2008 | WO | A |
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