Title:
Direct acting hydraulic trip block
Document Type and Number:
United States Patent 7409965
Abstract:
A direct acting hydraulic voting trip block defines three separate paths between an inlet and an outlet port. Each path is intersected by a valve cylinder. Valve pistons in each valve cylinder are configured, in the activated position, to block two of thee different paths. As long as at least two of the pistons are in the activated position, communication between the inlet and outlet ports is prevented.
Inventors:
Blaser, Samuel (Altendort, CH)
Vogler, Heinz (Uetilburg, CH)
Vogler, Heinz (Uetilburg, CH)
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Sponsored by: Flash of Genius |
Application Number:
11/581799
Publication Date:
08/12/2008
Filing Date:
10/16/2006
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Referenced by:
Export Citation:
Assignee:
Elliott Company (Jeannette, PA, US)
Primary Class:
Other Classes:
137/884, 137/613
International Classes:
F01D21/18
Field of Search:
137/553, 137/884, 137/613, 137/554
US Patent References:
| 3429180 | OVERSPEED MONITOR TESTING APPARATUS | February, 1969 | Vind | |
| 3754565 | ANTI-THEFT OR USE DEVICE FOR SELF PROPELLED OR STATIONARY ENGINES | August, 1973 | Gennetten | 137/384.4 |
| 3834484 | ANTI-THEFT DEVICE FOR INTERNAL COMBUSTION ENGINES | September, 1974 | Sangster | 137/613 |
| 4001654 | Testable protective system | January, 1977 | Davis et al. | |
| 4215844 | Valve actuator system | August, 1980 | Bowen | |
| 4455614 | Gas turbine and steam turbine combined cycle electric power generating plant having a coordinated and hybridized control system and an improved factory based method for making and testing combined cycle and other power plants and control systems therefor | June, 1984 | Martz et al. | |
| 4524796 | Sliding-gate valve for use with abrasive materials | June, 1985 | Ayers et al. | 137/613 |
| 4621496 | Actuator control system | November, 1986 | Lamb | |
| 4637587 | Facility for the monitoring of physical quantities on systems | January, 1987 | Kühnlein | |
| 5143119 | Drive for a feed valve | September, 1992 | Plangger | |
| 5217199 | Connecting valve and hydraulic oil safety and power system in which the connecting valve is used | June, 1993 | Frey | |
| 5280807 | Supply circuit for a two-tube hydraulic system | January, 1994 | Frey et al. | |
| 5561976 | Redundant trip solenoid valve shut-off for gas turbine fuel system | October, 1996 | Chu et al. | |
| 5626070 | Control logic for a multiple use hydraulic system | May, 1997 | Sorbel | |
| 5665898 | Method and apparatus for testing solenoids in a safety system by bypassing the solenoid operated pilot valve | September, 1997 | Smith et al. | |
| 6155282 | Two out of three voting solenoid arrangement | December, 2000 | Zachary et al. | |
| 6435202 | Two out of three voting solenoid arrangement | August, 2002 | Zachary et al. | |
| 6478048 | Two out of three voting solenoid arrangement | November, 2002 | Hays | |
| 6722383 | Variable function voting solenoid-operated valve apparatus and testing method therefor | April, 2004 | Summers et al. | |
| 6862914 | Method of testing a variable function voting solenoid-operated valve apparatus | March, 2005 | Zachary et al. | |
| 6943540 | Multiple-channel solenoid current monitor | September, 2005 | Vincent et al. | |
| 7025326 | Hydraulic valve actuation methods and apparatus | April, 2006 | Lammert et al. | |
| 20030139837 | System and method for monitoring a control process in a process plant | July, 2003 | Marr | |
| 20050242310 | Control valve apparatus and pressure circuit | November, 2005 | Takiguchi et al. |
Foreign References:
| DE3040367 | May, 1982 | |||
| DE3432890 | January, 1986 | |||
| EP0433791 | June, 1991 | Actuator for a feeding valve. | ||
| EP0641919 | March, 1995 | Safety valve arrangement | ||
| JP11006402 | January, 1999 | EMERGENCY CONTROL DEVICE FOR TURBINE |
Primary Examiner:
Lee, Kevin L.
Attorney, Agent or Firm:
The Webb Law Firm
Claims:
The invention claimed is:
1. A direct acting hydraulic voting trip block comprising: a valve block having three valve cylinders therein; three valve pistons in the valve cylinders; three springs for biasing the valve pistons in non-activated position; three electric solenoid actuators for in response to a non-fault signal moving the piston against the bias of the springs into an activated position; said valve block defining three separate paths between an inlet port and an outlet port, each path intersecting the three valve cylinders; each valve piston being configured to, in the activated position, obstruct two of the three paths and each valve piston being uniquely configured to obstruct a different two of the three paths; whereby as long as at least two of the pistons are in the activated position communication between the inlet and outlet ports is prevented.
2. A direct acting hydraulic voting trip block according to claim 1, comprising three valve piston position monitors one associated with each valve piston whereby a solenoid can be commanded to deactivate and the response of the corresponding position monitor observed to determine the associated solenoid, valve piston, and position monitor are in good running order without allowing communication between the inlet and outlet ports.
3. A direct acting hydraulic voting trip block according to claim 1, wherein the three valve cylinders have parallel and spaced axes.
4. A direct acting hydraulic voting trip block according to claim 1 or 3, wherein the three paths between the inlet and outlet ports have portions intersecting the valve cylinders which have parallel and spaced axes.
5. A direct acting hydraulic voting trip block according to claim 4, wherein the axes of the valve cylinders and the paths between the inlet and outlet ports are perpendicular.
6. A direct acting hydraulic voting trip block according to claim 1, wherein the bias springs and solenoids are at the opposite axial ends of the valve cylinders.
7. A direct acting hydraulic voting trip block according to claim 1, wherein the solenoids are aligned on one face of the valve block.
8. A direct acting hydraulic voting trip block according to claim 1, wherein the inlet port is in communication with a normally pressurized control port.
9. A direct acting hydraulic voting trip block according to claim 1, wherein each piston extends axially between a solenoid actuator and a bias spring and has two enlarged diameter blocking sections for closing two paths when in the activated position and two smaller diameter unblocking section adjacent the blocking portion for opening the two paths and a third elongated unblocking section for unblocking the third path in either the activated or non-activated position.
1. A direct acting hydraulic voting trip block comprising: a valve block having three valve cylinders therein; three valve pistons in the valve cylinders; three springs for biasing the valve pistons in non-activated position; three electric solenoid actuators for in response to a non-fault signal moving the piston against the bias of the springs into an activated position; said valve block defining three separate paths between an inlet port and an outlet port, each path intersecting the three valve cylinders; each valve piston being configured to, in the activated position, obstruct two of the three paths and each valve piston being uniquely configured to obstruct a different two of the three paths; whereby as long as at least two of the pistons are in the activated position communication between the inlet and outlet ports is prevented.
2. A direct acting hydraulic voting trip block according to claim 1, comprising three valve piston position monitors one associated with each valve piston whereby a solenoid can be commanded to deactivate and the response of the corresponding position monitor observed to determine the associated solenoid, valve piston, and position monitor are in good running order without allowing communication between the inlet and outlet ports.
3. A direct acting hydraulic voting trip block according to claim 1, wherein the three valve cylinders have parallel and spaced axes.
4. A direct acting hydraulic voting trip block according to claim 1 or 3, wherein the three paths between the inlet and outlet ports have portions intersecting the valve cylinders which have parallel and spaced axes.
5. A direct acting hydraulic voting trip block according to claim 4, wherein the axes of the valve cylinders and the paths between the inlet and outlet ports are perpendicular.
6. A direct acting hydraulic voting trip block according to claim 1, wherein the bias springs and solenoids are at the opposite axial ends of the valve cylinders.
7. A direct acting hydraulic voting trip block according to claim 1, wherein the solenoids are aligned on one face of the valve block.
8. A direct acting hydraulic voting trip block according to claim 1, wherein the inlet port is in communication with a normally pressurized control port.
9. A direct acting hydraulic voting trip block according to claim 1, wherein each piston extends axially between a solenoid actuator and a bias spring and has two enlarged diameter blocking sections for closing two paths when in the activated position and two smaller diameter unblocking section adjacent the blocking portion for opening the two paths and a third elongated unblocking section for unblocking the third path in either the activated or non-activated position.
Description:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a direct action hydraulic trip block for steam turbines and other applications.
2. Description of Related Art
Apparatus for monitoring conditions and driving quick-closing valves by dumping control fluid wherein a majority determining switching logic is implemented are known, for example, from U.S. Pat. No. 4,637,587 entitled “Facility for the Monitoring of Physical Quantities on Systems.”
SUMMARY OF THE INVENTION
It is an object of this invention to provide a hydraulic majority voting logic valve system in a single valve block.
Briefly, according to this invention, there is provided a direct acting hydraulic voting trip block comprising a valve block having three valve cylinders therein, three valve pistons in the valve cylinders, three springs for biasing the valve pistons in non-activated position, and three electric solenoid actuators for, in response to a non-fault signal, moving the piston against the bias of the springs into an activated position. The valve block defines three separate paths between an inlet port and an outlet port. Each path intersects the three valve cylinders. Each valve piston is configured to, in the activated position, block two of the three paths. Each valve piston is configured to close a different two of the three paths. Thus, as long as at least two of the pistons are in the activated position, communication between the inlet and outlet ports is prevented.
According to a preferred embodiment, the voting trip block is provided with three valve piston position monitors, one associated with each valve piston. Thus, a solenoid can be commanded to deactivate and the response of the corresponding position monitor observed to determine the associated solenoid, valve piston, and position monitor are in good running order without allowing communication between the inlet and outlet ports.
According to a preferred embodiment, each piston extends axially between a solenoid actuator and a bias spring and has two enlarged diameter blocking sections for closing two paths when in the activated position and two smaller diameter unblocking sections adjacent the blocking portion for opening the two paths and a third elongated unblocking section for unblocking the third path in either the activated or non-activated position.
BRIEF DESCRIPTION OF THE DRAWING
Further features and other objects and advantages will become clear from the following detailed description made with reference to the drawing which is a section view of one embodiment of a hydraulic voting trip block according to this invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to the drawing, a direct acting hydraulic voting trip block comprises a valve block 10 having three valves 12 , 14 , 16 cylinders therein. Three valve pistons 18 , 20 , 22 are located in the valve cylinders. Three springs 24 , 26 , 28 bias the valve pistons in the non-activated position. Three electric solenoid actuators 30 , 32 , 34 are provided for moving the pistons against the bias of the springs into an activated position. Typically, the solenoid actuators move the piston into an activated position when receiving a non-fault condition signal. The valve block defines three separate paths 36 , 38 , 40 between an inlet port 42 and an outlet port 44 . Each path intersects the three valve cylinders. Each valve piston is configured to, in the activated position, block two of the three paths. Each valve piston is configured to close a different two of the three paths. Thus, as long as at least two of the pistons are in the activated position, communication between the inlet and outlet ports is prevented. Normally, the inlet port is in communication with a normally pressurized control port.
The voting trip block is provided with three valve piston position monitors 46 , 48 , 50 , one associated with each valve piston. Thus, a solenoid can be commanded to deactivate and the response of the corresponding position monitor observed to determine the associated solenoid, valve piston, and position monitor are in good running order without allowing communication between the inlet and outlet ports.
As shown in the drawing, each piston 18 , 20 , 22 extends axially between a solenoid actuator and a bias spring. Each piston has two enlarged diameter blocking sections 52 , 54 for closing two paths when in the activated position and two smaller diameter unblocking sections 56 , 58 adjacent the blocking portion for opening the two paths and a third elongated unblocking section 60 for unblocking the third path in either the activated or non-activated position.
As shown in the drawing of the preferred embodiment, the three valve cylinders have parallel and spaced axes. The three paths between the inlet and outlet ports have portions intersecting the valve cylinders which have parallel and spaced axes. The axes of the valve cylinders and the paths between the inlet and outlet ports are perpendicular. The bias springs and solenoids are at the opposite axial end of the valve cylinders. The solenoids are aligned on one face of the valve block.
Having thus defined our invention in the detail and particularity required by the Patent Laws, what is desired protected by Letters Patent is set forth in the following claims.