This is a 35 USC 371 U.S. National Phase of International Application No. PCT/US2013/035616, filed 8 Apr. 2013 and published in English as WO 2014/168604A1 on 16 Oct. 2014. The contents of the aforementioned application are incorporated by reference in their entirety.
This invention relates to a system and method to improve the energy-efficiency of conventional carbonaceous feedstock plug feeder systems. More particularly, the present invention concerns an arrangement which permits a synchronous process for the advancement, pressurization, and retraction of a plurality of co-acting piston cylinder assemblies which together may be used to apply necessary forces for the creation of one or more plugs of compressible material for feeding into a reactor.
The first piston cylinder assembly (04) is comprised of: a first hydraulic cylinder (24), a first hydraulic cylinder front cylinder space (26), a first hydraulic cylinder rear cylinder space (28), a first hydraulic cylinder front connection port (30), a first hydraulic cylinder rear connection port (32), a first piston rod (34), a first hydraulic cylinder piston (36), a first hydraulic cylinder flange (38), and a first piston ram (40).
The first piston ram (40) is partly accommodated and arranged to travel in a reciprocating manner inside the first cylinder (10) which has associated therewith a feedstock inlet (42), a first cylinder first flange (44), and a first cylinder second flange (46). The first hydraulic cylinder flange (38) is connected to the first cylinder first flange (44).
The second piston cylinder assembly (06) is comprised of: second hydraulic cylinder (48), a second hydraulic cylinder front cylinder space (50), a second hydraulic cylinder rear cylinder space (52), a second hydraulic cylinder front connection port (54), a second hydraulic cylinder rear connection port (56), a second piston rod (58), a second hydraulic cylinder piston (60), a second hydraulic cylinder flange (62), and a second piston ram (64).
The second piston ram (64) is partly accommodated and arranged to travel in a reciprocating manner inside the second cylinder (12) which has associated with it a second cylinder first flange (66), a second cylinder second flange (68), a second cylinder third flange (70), and a cylindrical second pipe branch opening (72). The second hydraulic cylinder flange (62) is connected to the second cylinder first flange (66).
The first cylinder second flange (46) is connected to the second cylinder third flange (70) so as to allow a carbonaceous feedstock to be transferred through the first cylinder (10) by the advancing motion of the first piston ram (40) and partially compressed into the second cylinder (12) through the cylindrical second pipe branch opening (72).
The third piston cylinder assembly (08) is comprised of: third hydraulic cylinder (74), a third hydraulic cylinder front cylinder space (76), a third hydraulic cylinder rear cylinder space (78), a third hydraulic cylinder front connection port (80), a third hydraulic cylinder rear connection port (82), a third piston rod (84), a third hydraulic cylinder piston (86), a third hydraulic cylinder flange (88), and a third piston ram (90).
The third piston ram (90) is partly accommodated and arranged to travel in a reciprocating manner inside the final, third cylinder (14) which has associated with it a third cylinder first flange (92), a third cylinder second flange (94), a third cylinder third flange (96), and a cylindrical third pipe branch opening (98). The third hydraulic cylinder flange (88) is connected to the third cylinder first flange (92).
The second cylinder second flange (68) is connected to the third cylinder third flange (96) so as to allow a carbonaceous feedstock to be transferred through the second cylinder (12) by the advancing motion of the second piston ram (64) and partially compressed into the final, third cylinder (14) through the cylindrical third pipe branch opening (98).
After loose carbonaceous feedstock is transferred to the final, third cylinder (14) from the advancing motion of the second piston ram (64), the feedstock is then advanced through the final, third cylinder (14) by the advancing motion of the third piston ram (90) where it is compressed to develop a plug (100) of defined length and pressure to form the seal between the pressurized thermochemical reactor (104) and the feedstock inlet (42), which may be exposed to the atmosphere.
As seen in
As plugs are successively formed they are transferred to a plug disintegrator assembly (18) which breaks up the formed plug for transference into the fluidized bed (102) of the pressurized thermochemical reactor (104) via a reactor feed screw assembly (22).
U.S. Pat. No. 7,964,004 shows an assembly which includes three single-acting pistons for use in a system of the sort seen in
In one aspect, the present invention is directed to a hydraulic circuit comprising:
a controller;
a primary hydraulic fluid source;
a platen configured to selectively move along a forward compression direction (310) and a rearward non-compression direction;
first and second ancillary piston cylinder assemblies, having respective first and second pistons operatively connected to the platen;
a third main piston cylinder assembly having a third piston operatively connected to the platen; and
wherein:
in a first mode of operation, hydraulic fluid is introduced under pressure into the first and second ancillary piston cylinder assemblies, thereby causing the first and second pistons to urge the platen in the forward compression direction, while the third piston passively travels in the forward compression direction;
in a second mode of operation, hydraulic fluid is introduced under pressure into the first and second ancillary piston cylinder assemblies and also into the third main piston cylinder assembly, thereby causing the first, second and third pistons to collectively urge the platen in the forward compression direction; and
in a third mode of operation, hydraulic fluid is introduced under pressure into at least the first and second ancillary piston cylinder assemblies, thereby causing at least the first and second pistons to urge the platen in the rearward non-compression direction
In a second aspect, the present invention is directed to a feeder apparatus for advancing a compressible material, comprising:
a first piston cylinder assembly having a feedstock inlet suitable for receiving a compressible material;
a second piston cylinder assembly configured to receive material from the first piston cylinder assembly;
a third cylinder having a third cylinder ram arranged to travel therein, the third cylinder configured to receive material from the second piston cylinder assembly; and
the hydraulic circuit according to claim 1; wherein:
the third cylinder ram is connected to the platen so as to travel therewith.
In a third aspect, the present invention is directed to a reactor comprising the aforementioned feeder apparatus, a plug disintegrator assembly and a reactor feed screw assembly, wherein: the third cylinder is connected to the reactor via the plug disintegrator assembly and the reactor feed screw assembly, to thereby provide a compressed plug of compressible material to the reactor.
For a better understanding of the present invention and to show how the same may be carried out in practice, reference will now be made to the accompanying drawings, in which:
The first ancillary piston cylinder assembly (140) is comprised of: a first ancillary hydraulic cylinder (142), a first ancillary hydraulic cylinder front cylinder space (144), a first ancillary hydraulic cylinder rear cylinder space (146), a first ancillary hydraulic cylinder front connection port (148), a first ancillary hydraulic cylinder rear connection port (151), a first ancillary hydraulic cylinder piston (154), and a first ancillary piston rod (152). The first ancillary piston rod (152) is connected to the platen (212).
Advancement and retraction of the piston (154) and rod (152) are with respect to the reference point created by the first ancillary hydraulic cylinder static end (160). The piston (154) defines ancillary front cylinder space (144) and ancillary rear cylinder space (146) in the first ancillary hydraulic cylinder (142). Each space contains hydraulic fluid.
The second ancillary piston cylinder assembly (164) is functionally identical to the first ancillary piston cylinder assembly (140) and is comprised of: a second ancillary hydraulic cylinder (166), a second ancillary hydraulic cylinder front cylinder space (168), a second ancillary hydraulic cylinder rear cylinder space (170), second ancillary hydraulic cylinder front connection port (172), a second ancillary hydraulic cylinder rear connection port (174), a second ancillary hydraulic cylinder piston (178), and a second ancillary piston rod (176). The second ancillary piston rod (176) is connected to the platen (212).
Advancement and retraction of the piston (178) and rod (176) are with respect to the reference point created by the second ancillary hydraulic cylinder static end (186). The piston (178) defines ancillary front cylinder space (168) and ancillary rear cylinder space (170) in the second ancillary hydraulic cylinder (166). Each space contains hydraulic fluid.
Piston rods (152) and (176) are connected to pistons (154) and (178), respectively, which are in sealing engagement with the walls of the cylinders (142) and (166), respectively. The system could be expanded to include any number of ancillary hydraulic cylinders, if such was required.
The primary third hydraulic cylinder assembly (189) is comprised of: a primary third hydraulic cylinder (190), a primary third hydraulic cylinder front cylinder space (192), a primary third hydraulic cylinder rear cylinder space (194), a primary third hydraulic cylinder front connection port (196), a primary third hydraulic cylinder rear connection port (198), a primary third hydraulic cylinder piston (202), and a primary third piston rod (201). The primary third piston rod (201) is connected to the platen (212).
The primary third piston rod (201) is connected to the primary third hydraulic cylinder piston (202) which is in sealing engagement with the walls of the primary third hydraulic cylinder (190). The piston (202) defines the front cylinder space (192) and the rear cylinder space (194) in the third cylinder (190). Each space contains hydraulic fluid.
At least one of the cylinders has a sensor that provides feedback signal to a distributed control system (DCS), programmable logic controller (PLC), or motion controller transmitting or indicating the exact position of the associated piston along its entire linear stroke (from start position, L0, to end the position, L2).
The sensor outputs a signal reflective of a position of third piston (202). This may be done by measuring the position of the primary ram (206), the position of the platen (212), the position of any of the piston rods (152, 176, 201), or the positions of any of the pistons (154, 178, 202). It is understood that measuring any one of these can provide information about the position of any of the others, since the primary ram, the platen, the piston rods and the pistons all move together.
In a preferred embodiment, the sensor comprises a linear transducer (193) having a first end attached to a fixed (non-moving) portion of one of the hydraulic cylinder assemblies (140, 164, 189) and a second end attached to a movable portion of said one of the hydraulic cylinder assemblies (140, 164, 189), or to the platen (212) or the primary ram (206). In a preferred embodiment, the linear transducer (193) is attached to the primary third hydraulic cylinder static end (208). The linear transducer (193) protrudes through the primary third hydraulic cylinder rear cylinder space (194) to be accommodated within an opening (191) deliberately ‘gun-drilled’ in the primary third piston rod (201) and primary third hydraulic cylinder piston (202), to precisely control and monitor the movement of the platen (212) and primary ram (206).
In an alternate embodiment, the sensor that is used for sensing and indication of the stroke position of the primary third piston rod (201), that is, indicating the amount of extension or the position of the piston rod (201) from a reference may be installed exterior to the hydraulic cylinder (142) (not shown) so it can be installed and removed without disassembly of the cylinder. In either embodiment, the single output by the linear transducer (193) reflects the position of third piston (202).
The hydraulic compression circuit (214) as depicted in
The ancillary cylinder rear valve (150) includes an ancillary cylinder rear supply port (150A), an ancillary cylinder rear drain port (150B), and an ancillary cylinder rear common port (150C).
The ancillary cylinder front valve (200) includes an ancillary cylinder front supply port (200A), an ancillary cylinder front drain port (200B), and an ancillary cylinder front common port (200C). A pump suction line (240) connects the primary tank (2000) with the hydraulic pump (238). A pump discharge line (236) connects the outlet of the hydraulic pump (238) with: the ancillary cylinder front supply port (200A) through the ancillary cylinder front supply line (232); the ancillary cylinder rear supply port (150A) through the ancillary cylinder rear supply line (230); and the primary third cylinder rear supply valve (300) through the primary third cylinder rear supply line (226). The hydraulic pump (238) may provide pressurized fluid to any of these three valves through their respective transfer lines.
The primary third hydraulic cylinder rear connection port (198) is in communication with the primary third cylinder rear supply line (226) where the open or closed position of the primary third cylinder rear supply valve (300) restricts the availability of the pressurized fluid transferred from the discharge of the hydraulic pump (238) to the primary third hydraulic cylinder rear cylinder space (194).
The primary third hydraulic cylinder rear connection port (198) is also in communication with the surge tank (1000) via a primary third cylinder rear surge line (224) with the primary third cylinder rear surge valve (350) interposed therebetween.
The primary third hydraulic cylinder front connection port (196) is in communication with the surge tank (1000) via a primary third cylinder front surge line (222) with the primary third cylinder front surge valve (400) interposed therebetween.
The primary third hydraulic cylinder front connection port (196) is also in communication with the primary tank (2000) via a primary third cylinder front drain line (220) with the primary third cylinder front drain valve (450) interposed therebetween.
Ancillary front cylinder space drain lines (252a, 252b) connect both the first ancillary hydraulic cylinder front connection port (148), and the second ancillary hydraulic cylinder front connection port (172), respectively, with the ancillary cylinder front common port (200C) of the ancillary cylinder front valve (200), via the shared ancillary front cylinder space drain line (252).
Ancillary rear cylinder space drain lines (248a, 248b) connect both the first ancillary hydraulic cylinder rear connection port (151), and the second ancillary hydraulic cylinder rear connection port (174), respectively, with the ancillary cylinder rear common port (150C) of the ancillary cylinder rear valve (150), via the shared ancillary rear cylinder space drain line (248).
As seen in the arrangement of
The ancillary cylinder front drain port (200B) of the ancillary cylinder front valve (200) is connected to the primary tank (2000) through an ancillary front cylinder space drain line (254).
The ancillary cylinder rear drain port (150B) of the ancillary cylinder rear valve (150) is connected to the primary tank (2000) through an ancillary rear cylinder space drain line (255).
Advancement Sequence Mode (1500)
Isolating the primary third hydraulic cylinder rear cylinder space (194) from the hydraulic pump (238) during the advancement sequence step (1500) has certain advantages related to the energy efficiency of the prior art feeding apparatus (02).
A high power consumption and unfavorable energy efficiency is associated with the third hydraulic cylinder (74) of the prior art feeding apparatus (02) since it is the largest of the three hydraulic cylinder assemblies and requires the most volume of hydraulic fluid for driving its piston.
The diameters of the first ancillary piston cylinder assembly (140) and the second ancillary piston cylinder assembly (164), specifically the pressure-receiving surface area of each of their pistons (154, 176) are of a lesser diameter than that of the primary third hydraulic cylinder piston (202).
Utilization of a platen (212) and two or more ancillary piston cylinder assemblies (140, 164) with diameters smaller than that of the primary third hydraulic cylinder assembly (189) reduces the volume of fluid required to advance the primary ram (206). This results in a more economical process for the compression of carbonaceous material into a plug of desired length and density.
In the advancement sequence mode (1500), hydraulic fluid is drawn from the primary tank (2000) and transferred through ancillary cylinder rear supply line (230), ports (150A, 150C) of ancillary cylinder rear valve (150), and ancillary rear cylinder space drain lines (248, 248a, 248b) into ancillary rear cylinder spaces (146, 170) of the first ancillary piston cylinder assembly (140) and second ancillary piston cylinder assembly (164).
Also in the advancement sequence step (1500), hydraulic fluid is displaced from the ancillary front cylinder spaces (144, 168) of the first ancillary piston cylinder assembly (140) and second ancillary piston cylinder assembly (164) and is returned to the primary tank (2000) through ancillary front cylinder space drain lines (252, 252a, 252b), ports (200C, 200B) of ancillary cylinder front valve (200) and ancillary front cylinder space drain line (254).
The hydraulic fluid advances ancillary pistons (154, 178) which in turn advances the motion of the platen (212) and primary ram (206) while also advancing the motion of the primary third piston rod (201) and primary third hydraulic cylinder piston (202).
Additionally, in the advancement sequence step (1500), the primary cylinder front and rear supply valves (300, 450) are closed, while the primary cylinder front and rear surge valves (350, 450) are open. This allow the primary third piston rod (201) and the primary third hydraulic cylinder piston (202) to advance while the primary third hydraulic cylinder front cylinder space (192) and primary third hydraulic cylinder rear cylinder space (194) are isolated from the discharge pressure of the hydraulic pump (238).
Hydraulic fluid displaced from the primary third hydraulic cylinder front cylinder space (192) is allowed to freely flow into the surge tank (1000) through primary third cylinder front surge line (222) and open front surge valve (400). In a similar vein, hydraulic fluid from the surge tank (1000) is allowed to freely flow into the primary third hydraulic cylinder rear cylinder space (194) through the primary third cylinder rear surge line (224) and open rear surge valve (350). Thus, by virtue of connection to the platen (212), the primary third piston rod (201) and the primary third hydraulic cylinder piston (202) go along for the ride, as the hydraulic fluid advances the ancillary pistons (154, 178).
Hydraulic fluid continues to be transferred to the ancillary rear cylinder spaces (146, 170) of the first ancillary piston cylinder assembly (140) and second ancillary piston cylinder assembly (164) until the linear transducer (193) indicates that a first predetermined set-point of the intermediate stroke length position (L1) has been reached. The output of the linear transducer (193) is provided to a controller (500). In response to the output from the linear transducer (193) indicating that the first predetermined set-point has been reached, the controller (500) is configured to control the various valves such that the system transitions from the advancement sequence mode (1500) to the pressurization sequence mode (1530).
Pressurization Sequence Mode (1530)
In the pressurization sequence mode (1530), hydraulic fluid is transferred to all the rear cylinder spaces (146, 170, 194) of the ancillary and primary piston cylinder assemblies (140, 164, 189) until the linear transducer (193) indicates that a second predetermined set-point of the maximum stroke length position (L2) has been reached. The output of the linear transducer (193) is provided to the aforementioned controller (500). In response to the output from the linear transducer (193) indicating that the second predetermined set-point has been reached, the controller (500) is configured to control the various valves such that the system transitions from the pressurization sequence mode (1530) to the retraction sequence mode (1560).
Retraction Sequence Mode (1560)
In the retraction sequence mode (1560), the primary cylinder front and rear supply valves (300, 450) are closed, and the primary cylinder front and rear surge valves (350, 400) are open, much like in the advancement sequence mode (1500). However, relative to their corresponding positions in the advancement sequence mode (1500), in the retraction sequence mode (1560), the positions of ancillary supply ports (150A, 200A) and the positions ancillary drain ports (150B, 200B) of the ancillary cylinder valves (150, 200) are reversed.
Hydraulic fluid is transferred from the hydraulic pump (238) through ancillary cylinder front supply line (232) and ports (200A, 200C) of ancillary cylinder front valve (200) into the ancillary front cylinder spaces (144, 168) of the first ancillary piston cylinder assembly (140) and second ancillary piston cylinder assembly (164).
Hydraulic fluid displaced from the primary third hydraulic cylinder rear cylinder space (194) is allowed to freely flow into the surge tank (1000) through rear surge line (224) and open rear surge valve (350). Accordingly, hydraulic fluid from the surge tank (1000) is allowed to freely flow into the primary third hydraulic cylinder front cylinder space (192) through front surge line (222) and open front surge valve (400).
Hydraulic fluid displaced from the ancillary rear cylinder spaces (146, 170) of the first ancillary piston cylinder assembly (140) and second ancillary piston cylinder assembly (164) is diverted back to the primary tank (2000) through ancillary cylinder rear drain lines (248, 248a, 248b), ports 150C and 150B of ancillary cylinder rear valve (150), and ancillary rear cylinder space drain line (255).
Hydraulic fluid entering the ancillary front cylinder spaces (144, 168) causes the first and second ancillary hydraulic cylinder pistons (154) and (178) to retract, thus pulling the platen (212). Due to motion of the platen (212), the primary ram (206), the primary third piston rod (201) and the primary third hydraulic cylinder piston (202) freely retract as well.
Hydraulic fluid is transferred to the ancillary front cylinder spaces (144,168) of the first ancillary piston cylinder assembly (140) and second ancillary piston cylinder assembly (164), thereby causing retraction of the primary third piston cylinder assembly (189), until the linear sensor transducer (193) indicates a predetermined third set-point of the stroke starting position (L0) has been reached. The output of the linear transducer (193) is provided to the aforementioned controller (500). In response to the output from the linear transducer (193) indicating that the third predetermined set-point has been reached, the controller (500) may be configured to control the various valves such that the system transitions from the retraction sequence mode (1560) to the advancement sequence mode (1500), to repeat the compression process.
Although the present invention has been described with reference to certain embodiments, it should be understood that various alterations and modifications could be made without departing from the spirit or scope of the invention as hereinafter claimed.
Filing Document | Filing Date | Country | Kind |
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PCT/US2013/035616 | 4/8/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/168604 | 10/16/2014 | WO | A |
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20160031177 A1 | Feb 2016 | US |