This is a U.S. national stage entry of International Patent Application No. PCT/DK2015/050012, filed on Jan. 16, 2015, which claims priority to Denmark Patent Application No. PA 2014 70022, filed on Jan. 17, 2014, the entire contents of all of which are fully incorporated herein by reference.
The present invention relates to a multiple purpose flow control arrangement for control of agent flows from an up-stream agent supply system to down-stream agent consuming fire protection system pipes.
The invention is typically applied for controls of water flows in fixed pipe systems for fire protection such as water mist systems, sprinkler systems, hydrant systems and foam systems etc.
It is known to apply valves for control of water flows. For sprinkler and water mist and foam systems the valves are often clapper style valves, where a force-controlled swing clapper controls the water inlet to dry nozzle pipes. This arrangement is called a deluge valve. The swing clapper arrangement is also applied for control of water back flow from wet pipe sprinkler and water mist systems back to the water supply system. This arrangement does usually not apply controlled force on the clapper, which causes the flow control arrangement design to differ significantly from that of deluge valves. A significant problem with the described arrangements is that the described technology causes the arrangements to have large and complex valve bodies which significantly differ for the two valve types. Valve bodies are therefore often cast and large, and the production of valves becomes inflexible to the casting of houses and available molds etc.
Another known arrangement for control of water flows is to control the water flow by controlling the opening inside a pipe body by turning a plate located inside the pipe body around its own center line. Arrangements applying this technology are often called butterfly valves. A problem with butterfly valves is that the valves often are difficult to seal. They are difficult to maintain, and the valve requires manual activation, or complex motor controlled activation to control.
Another known arrangement for control of water flows is to control the opening between a pipe-shaped opening and a plate being pushed horizontally into the opening. This arrangement is often being called a gate valve. A problem with gate valves is that they often require a spindle arrangement to push the plate into the pipe opening. This makes the valve houses become complex and large, where the valve houses often are cast causing inflexible productions, and also the valve to be difficult to maintain. As for butterfly valves the valve requires manual activation, or complex motor controlled activation to control.
Another known arrangement to control water flows is to control the opening in a pipe shaped cavity by turning a ball having a hole inside the pipe cavity, the arrangement is called ball valve. A problem with this arrangement is that it is complex to seal and that corrosion and debris over time have a tendency to cause the ball to be difficult to turn to control the flow. This makes ball valves be unsuitable for installations involving water and other corrosive media where the ball valve is not frequently activated.
Another known arrangement to control water flow is an arrangement having two chambers in two levels which are connected through an opening which may be closed with a plate which is attached to a spindle and/or is sealed with a diaphragm, and where the flow between the inlet and the outlet chamber is controlled by controlling the distance between the opening between the two chambers and the plate closing the opening. The control is often done manually through a spindle attached to the plate or by controlling the pressure inside the diaphragm attached to the plate. This arrangement is commonly called Globe valve. A variant of the globe valve is a globe hydrant valve where a spring applies a force on the plate closing the opening. The spring hereby causes a pressure loss over the valve controlling the outlet pressure of the valve. The valve is closed with the force from a spindle and activates when the spindle force on the plate is manually removed by turning the spindle. A problem with globe valves is that they require complicated housings and become physically large and heavy constructions; valve houses are therefore often cast, which requires molds and introduces errors such as cast porosities and other casting problems to the production of valves.
Another known arrangement to control water flow is an arrangement consisting of a pipe cavity having a polymeric balloon body located in the pipe cavity. The balloon swells up to reduce the opening between the pipe wall and the balloon surface when the internal pressure inside the balloon increases. The valve type is commonly called for Ball valve. This way Ball valves control water flows by controlling the internal water pressure inside the ball. A problem with ball valves is that the life time of the product depends on the life time of the polymeric ball, and that the valves need to be replaced from pipe systems to be maintained.
Another known arrangement to control water flows is an arrangement where a polymeric sleeve is located around a body located inside a pipe body, and where the ends of the sleeve are sealed to the pipe body. The arrangement is commonly called a sleeve valve. The sleeve valve controls the flow between inlet and outlet ports by controlling the pressure between the pipe surface and the outside surface of the sleeve. Problems with sleeve valves are that the life time of the product depends on the life time of the polymeric ball, and that the valves need to be replaced from pipe systems to be maintained.
It is desirable to overcome one or more of the above mentioned problems.
It is an object of the present invention to provide a multiple purpose flow control arrangement for control of agent flow from an up-stream agent supply system to down-stream agent consuming fire protection system pipes as mentioned in claim 1.
Hereby is achieved that the spool body forms a seal towards the seat, and the construction of the arrangement determines the agent flow. Additionally the end body may be dismounted and removed, such that the spool body may be removed from the pipe cavity through the opening.
Some embodiments of the invention concern a device for control of flow in pipe systems for fire protection, which comprises a housing having a pipe cavity with an opening in both ends and one or multiple openings in the pipe cavity wall. The one or multiple openings in the pipe cavity wall define at least one outlet port in the tubular pipe cavity wall. The opening in one end of the pipe cavity defines an inlet port; this end will also be referred to as the open end. The opening at the other end of the pipe cavity, opposite the open end, is closed by a dismountable end body. This end will also be referred to as the closed end as it defines neither an inlet nor an outlet port for the main flow. Nevertheless, in some embodiments, the end body may have one or multiple openings into the pipe cavity forming pilot flow lines for facilitating the flow control. The pipe cavity forms a cross section area reduction located between the open pipe cavity end and the openings in the pipe cavity wall, and where a spool body with larger cross section area than that of reduced pipe cavity in one or multiple locations, and smaller cross section area than that of the not reduced pipe cross section area is located inside the pipe cavity, and where the spool body rest on the end surface of the diameter reduction in the pipe cavity and seals to the pipe cavity wall in one or multiple locations between the opening or openings in the pipe cavity wall and the ended end of the pipe cavity. And where the spool body has one or multiple openings having two or multiple openings which hydraulically connects the pipe cavity having reduced cross section area with the pipe cavity volume which is located between the pipe cavity closed end and the sealing between the spool body and the pipe cavity wall.
In some embodiments, the housing may be formed by a tee-pipe.
The device operates in that the open pipe cavity end performs as an inlet port to the device and is connected to an agent supply system. Liquid flows from the supply port through the inlet port. The agent pressure presses the spool body back and against the closed end of the pipe cavity, and agent flows out through the outlet port opening in the pipe cavity wall. Agent does also flow through the openings and cavity in the body to exit from the opening in the pipe cavity closed end. When opening in the pipe cavity end is closed, the agent flowing through the spool body builds up an agent pressure between the spool body and the closed end of the pipe cavity. This applies a force on the spool body which pushes the spool body to rest on a recess in the pipe cavity wall which is caused from the reduction of the pipe cavity diameter. The pipe cavity having larger cross section area than that of the reduced pipe cavity diameter causes the force pushing the spool body towards the recess to be larger than the force pushing the body away from the recess, this recess forms a seat for the spool body, and the spool body seals against the seat of the recess in the pipe cavity inhibiting agent from flowing through the inlet port and out through the outlet port opening in the pipe cavity surface.
A variation of the above described device is characterized in that the pipe cavity reduction consists of a ring body. The ring body may be a pipe body which may be an insert into the pipe cavity of the housing. The ring body may stretch into the area of the pipe cavity where one or multiple openings are present.
The variation performs in that agent flowing through the displacement opening between the seat and the spool body can flow through a much larger outlet opening with the same body displacements. This causes less pressure losses and makes larger clearances between pipe cavity wall and body possible.
A second variation of the described device is characterized with a compressed spring located between the closed pipe cavity end and the spool body inside the pipe cavity to apply a spring force on the spool body pressing the spool body surface against the seat of the surface of the pipe cavity reduction.
The variation performs with that the spool body always rest at the seat, and that the spring load causes agent to flow through the spool body with a pressure similar to the spring force divided with the cross section area of the reduced pipe cavity reduction. This way the spring load reduces tendencies of agent to leak from openings in the pipe cavity wall when agent supply is switched on, and opening in the ended cavity wall is closed.
A third variation of the device is characterized with the housing consisting of an assembly of a Pipe Tee Fitting with standard pipe connections fitted, and the closed pipe cavity being ended with a flange. This variation allows the device to be constructed from available standard components, and makes it simple to install the device in pipe systems and to maintain and service the device.
A forth variant of the device is characterized by that the body inside the cylinder pipe cavity ends in a shaft portion which reaches into the pipe cavity diameter reduction, and where there is located a guide body inside the cylinder pipe at a location between its open end and the diameter reduction recess, a seat, where the body rests, and where the guide body is penetrated with one or multiple openings, allowing flow to pass the guide body, and where the shaft portion of the spool body penetrates one or multiple of the openings in the guide body.
The variation performs in that the spool body is guided to seat best possible on the valve seat reducing risks of leakages.
A fifth variation of the device is characterized by that one or more openings in the end body of the closed pipe end ends in a one or multiple devices which can be opened and closed manually or remotely.
The variation makes it possible to control the displacement of the body from the seat, and hereby to control pressure loss of agent flows, and to open and close for agent flows.
A sixth variation of the device is characterized by the pipe cavity reduction have a concave cone surface and that the spool body in the pipe cavity has a matching convex cone surface with a smaller angle than that in the pipe cavity reduction.
The variation performs in causing a graduate change in opening area to spool body displacement. To reduce tendencies to pressure circuits in pipe outlet and agent supply systems.
A seventh variation of the device is characterized by the closed pipe cavity end being closed with a end body having one or multiple openings into the pipe cavity which ends in a cavity which connects two cavities (chambers) in line around the same centerline, and where the one chamber are hydraulic connected to one or multiple openings in the pipe cavity wall, and where a pilot spool body, which has one or multiple cavities with openings are located in the line of cavities to have one or multiple of its openings located in each of the chambers, and where the pilot spool body section located in the chamber having hydraulic connection to opening in the pipe cavity wall has larger cross section area than the opening in the chamber which connects the chamber to the other end chamber in the line of cavities, and where the body reaches into the other end chamber in the cavity line where the body end has no opening to cavity in the body and is sealed to the chamber wall, and where a compressed spring supply an axial force on the body, and where the shaft portion length of the pilot spool body located in the two chambers are longer than the distance between the chambers, and where the cavity connecting the two chambers has a larger cross section area than that of the pilot spool body shaft portion connection the pilot spool body parts located in the two end chambers. And the opening from the second chamber into the cavity forms a bearing and/or a seal with the surface of the shaft portion.
The variation performs in that the opening in pipe cavity wall is connected to outlet pipe system. The variation performs with that the outlet pipe system is hydraulic connected to the line of cavities (chambers) located in the materials forming the end of the closed pipe cavity, and the body transport the agent pressure to the one side of the body piston in the spring chamber of the chamber cavity line. When the agent pressure in the pipe outlet system provide a force on the pilot spool body piston which is higher than that of the spring load, the pilot spool body moved towards the spring, and hereby reduces or closes the opening from the cavity which connects the opening in the ended pipe cavity end to the outlet pipe system, causing water pressure to build up between the body in the pipe cavity and the pipe cavity ending and the device to close or reduce the agent flow from the inlet port through the opening in the pipe cavity wall and to the outlet pipe system. When the agent pressure decrees the spring opens the opening and the body in the pipe cavity moves away from its seat allowing more agent to flow into the outlet pipe system. This way the variation allows the invention to perform pressure control in pipe outlet system without having to have connection to drain.
Embodiments of the invention will be described in the following with reference to the drawings wherein
The device performs with agent flows through the inlet port into one or more openings (11) in a portion of the spool body (9) and through the spool body to the closed pipe cavity volume between the dynamic spool body sealing (17) and the end body (15) of the pipe cavity (2), where the agent pressure apply a force on the body. Because the pipe cavity cross section area is larger than the seat hole area, the body is pressed against the seat (5), and agent can hereafter not flow through the inlet port (6) and out through the outlet port (3).
When one or multiple openings in the end body (15) is opened agent will flow from the pipe cavity volume between the spool body and the end body, this creates a reduced agent pressure and a reduced force on the back of the spool body, and the force on the front of the spool body will cause the spool body to travel towards the end body, which allows agent to flow through the inlet port and out through the outlet port.
From controlling opening in end body flow through the inlet port and out through the outlet port is controlled.
On
The end body (15) is attached to the flange (20) of the housing (1) with bolts and nuts (18,19). This makes it technically simple to service the device. When dismounting the end body (15) from the housing the spool body (9) with spool body seals (17) and gaskets can come out of the housing (1) to be services, with the device still being installed in the pipe work.
The open pipe cavity inlet port (6) is connected to up-stream agent supply system, and the outlet port (3) to the branched off cavity (3) connected to a down-stream pipe system. The spring (14) supply a force on the spool body (9), which holds the spool body seated against the seat (5) in the housing (1). When the agent supply system is activated agent will flow through the inlet port (6) into the pipe cavity volume between the inlet port (6) and the sealed seat and from here through the hydraulic connection cavity (21) to the pipe cavity volume between the spool body and the end body (15). Here the agent pressure provides a hydraulic force on the spool body (9) in the direction towards the seat (5), which is proportional to the pipe cavity cross section. This force together with the spring force is larger than the hydraulic force which the agent pressure in the pipe cavity reduction volume (4) applies on the spool body (9), and the spool body rests on the seat, preventing agent from passing the seat (5) to flow into the not reduced pipe cavity volume and from here through the outlet port into the branched off opening into the down-stream connected pipe system. When one or multiple openings in the flange end body (15) opens, the hydraulic pressure decreases in the pipe cavity volume between the spool body (9) and the flange end body (15). This causes the force equilibrium to change between the hydraulic force acting in the seat (5) area and the pipe cavity area of the spool body to change. And the spool body (9) will travel in direction towards the flange end body (15), compressing the spring (14) until a new force equilibrium occurs, and allowing agent to flow pass the inlet opening and out through the branched off outlet port (3) to enter the down-stream pipe work, which is connected to the branched off pipe connection.
The housing is flanged to the system pipes with an up-stream agent supply system pipe flange to the pipe flange on the open pipe cavity inlet port (6) and a down-stream nozzle system pipe flanged on the flange (20) connected to the outlet port (3) in the pipe cavity wall. In standby the force of the spring (14) pushes the spool body seat to rest on the seat (5) of the ring body (25), which is located in a distance (24) inside the area of the outlet port in the pipe cavity (2) wall. The agent supply is activated to apply agent pressure to the device. With openings closed in the end body (15) the agent flows through the open inlet port (6) into pipe cavity volume and through the openings in the guide body (8) to fill the pipe cavity volume between the inlet port and the seat (5). From this volume agent flows through a filter mesh openings (12) into the openings (11) in the spool body (9) and into the spool body cavity (10) and through the opening (26) into the pipe cavity volume (2) between the dynamic spool body seal (17) and the flange end body (15). The mesh can be a form of strainer or a filter. Here the spring (14) and the agent pressure provide a force which presses a seat surface on the spool body (9) against the seat s (5) on the ring body (25). The force of the spring and the hydraulic force acting in the volume which is limited by the spool body (9) and the flange body (15) is larger than the force from the agent supply acting on the seat (5) hole area, which causes the seat (5) and seat surface between the ring surface and the spool body to be tight. The spring load on the spool body helps keeping the seat (5) sealed when filling the volume between the spool body (9) and the flange end body (15) with closed openings with agent. The shaft portion (13) in the guide body (8) hole and the dynamic spool body seal (17) between the spool body (9) and the pipe cavity wall guides the spool body (9) to rest correctly on the seat (5) reducing agent leak between the spool body seat surface and the seat (5) of the ring body (25). The use of standard pipe components makes a highly flexible product, which is independent on house castings and casting molds. The seat (5) being displaced into the area of the outlet port, allows the device to have less friction loss with small spool body displacements. It should be noticed that the device functions also without the displaced seat and the guided spool body.
The example which
The device are installed in pipe work with flanged or other types of pipe connections, with the up-stream agent supply system connected to the inlet port (6), and the down-stream system connected to the branched off outlet opening with connection to outlet port (3) in the pipe cavity (2) wall. And the connection chamber (31) on the flanged on the end body (15) is hydraulically connected to the outlet cavity (23) of the device with a hydraulic connection line (29), with a two way stop valve (30). When agent supply is turned on to get access to the device, agent will flow through the inlet port (6) of the device, and into the pipe cavity (2) volume, which is sealed with the convex concave spool body (9) seat (5) where the spool body rests on the concave seat of the ring body (25), and which are hold in contact from the force of a spring (14). Agent flows through the strainer mesh (12) and into the openings (11) in the spool body (9) and into a cavity in the spool body and through opening (27) into the pipe cavity (2) volume between the spool body seal (17) to the pipe cavity wall and the flanged on the end body (15). A pre-set force which the adjustment device (43) sets on the pilot spring (42) in the control camber (33) applies force on the pilot spool body (34), which in the connection chamber (31) holds the enlarged end (37) of the pilot spool body (34) away from the opening (38) from the connection chamber (31) to the middle chamber (32). Agent flows from the pipe cavity (2) into the opening (36) from the pipe cavity to the connection chamber (31) and from here agent flows through the clearance between the pilot spool body shaft portion (34) and the Opening (38) between the connection chamber (31) and the middle chamber (32), into the connection chamber (31) and from here into the hydraulic connection line (29), where the stop valve (30) stops the agent from flowing further into the device outlet port and further into the down-stream system, and agent pressure similar to the agent supply pressure builds up in the pipe cavity (2) volume between the spool body seal (17) and the flange end body (15) with the connected above described connected agent filled volumes. The force acting on the back of the spool body (9) from the agent pressure acting on the pipe cavity (2) cross section diameter and the spring (14) is together higher than the force from agent pressure action on the seat (5) hole area on front of the spool body (9), which keeps the seat (5) sealed. When the stop valve (30) is opened, agent starts to flow from the pipe cavity (2) volume between the spool body seal (17) and the end body (15) via the hydraulic connection line (29) and the string of cavities (31) & (32) and the opening (36) in the end body (15) to the Down-Stream system. This agent flow makes the agent pressure decrease behind the spool body (9), and the force pushing the spool body (9) in forward direction becomes smaller than the force pushing the spool body (9) back in direction against the end body (15), and the spool body (9) travels away from the seat (5), and agent flows through the seat (5) and into the outlet port (3) opening in the pipe cavity wall and from here into the down-stream system where the agent flow builds up an agent pressure. This agent pressure is via the hydraulic connection line (29) and the open stop valve (30) connected to the connection chamber (31), and through the opening (35) in the pilot spool body feed into a control volume (44) in the control chamber (33), which are located between the opening (45) with seat (46) to the pilot spool shaft portion in the control chamber (33) to the middle chamber (32) and the piston seal (40) on the pilot spool body (34) in the control chamber. The Force Equilibrium on the pilot spool piston (39) in the control chamber between the force from the agent pressure and the force from the pilot spring (42) controls the size of the opening (38) between the middle chamber (32) and the connection chamber (31) from pulling and pushing the enlarged end (37) of the pilot spool body (34) closer to or further away from the opening (38), and this way controlling the flow from the pipe cavity (2) volume behind the spool body (9), and hereby the agent pressure closing the seat (5), and hereby the flow from agent supply to down-stream systems, and hereby the pressure build up in the down-stream system.
With the valve (49) in closed position the example performs as described for the example which
When the valve (49) is opened the agent drains from the pipe cavity (2) volume, which is located behind the spool body (9) end surface (C). It causes the hydraulic pressure acting on spool body surface area (C) to decrease, and the force from the agent pressure acting at the opposite end of the spool body (9) becomes able to forces the spool body (9) to travel away from the seat (5) and towards the end body (15), which makes the device to provide its maximum flow capacity to the agent supply pressure. And hereby provide a complete override of the pressure control performance as described for FIG. 4. When the valve (49) is reclosed, the override stops and the device return to perform its intended performances.
The example is installed in pipe work with agent supply pipe installed up-stream the open pipe cavity inlet port (6), and the agent consummating system inlet pipe installed down-stream the outlet port (3) opening to the pipe cavity (2). When the agent supply system is activated agent flows into the inlet port (6) and through openings in the guide body (8) and through the filter mesh (12) openings, and through one or more openings (11) and through the spool body (9) into the volume behind the spool body (9), where the force of the compressed pilot spring (57) holds the opening (50) closed with spring force on a seal body (52) acting on a seat surface (51). Agent leaks through an orifice (54) in the seal body (52) into a closed diaphragm chamber (55), where the agent builds up a static pressure which together with the pilot spring apply a force on the seat body (52) which keeps the opening in the end body closed, and the static agent pressure in the pipe cavity (2) volume acting on the full cross section area of the dynamic spool body seal (17) has a magnitude similar to that of the agent pressure on the inlet port (6), which acts on the spool body area similar to the opening area of the seat (5) surface. With the seat opening area being smaller than that of the cross section area of the pipe cavity, and the agent pressure being similar in front of the seat (5) area and that behind the dynamic spool body seal, the spool body seat against the seat (5) and there is no hydraulic connection between the supply system located up-stream the device and the agent consummation located down-stream the device. When the solenoid (66) becomes electrical energized, an magnetic field occurs, which magnetize the plug (64) end which faces the armature and the armature (60) end which faces the plug, with inverted magnetic poles, and a magnetic force between the two surfaces will pull the two surfaces towards each other against the force of the pilot spring (65). This removes the needle tip away from the opening (58) in the diaphragm chamber (55), and agent will flow from the diaphragm chamber into the cylinder volume (61) and from here through the drain connection (66) to drain. This creates a reduced agent pressure in the diaphragm chamber, and the agent pressure in the opening (50) acting on the seal body (52) provides a larger force than the force from the pilot spring and the agent pressure in the diaphragm chamber, which lifts the seal body (52) from the seat (51) and agent from the pipe cavity (2) volume behind the spool body (9) flows through the opening (50) in the end body (15) pass the seat surface (51) and the seal body (52) to drain via the drain connection (56) in the end body (15). This causes the agent pressure in the pipe cavity (2) behind the spool body (9) to drop and the higher agent supply pressure at the inlet port (6) will force the spool body (9) away from the seat (5) and agent will flow through the inlet port (6) pass the seat (5) and the spool body (9) and pass the outlet port (3) opening in the pipe cavity (2) into the down-stream agent consuming system. When electric power to the solenoid is turned off, the agent pressures re-build, and the device returns to its state before the solenoid was energized.
In an embodiment, the multiple purpose flow control arrangement for control of agent flows from up-stream agent supply system to down-stream agent consuming fire protection system pipes, which consists of a pipe housing having a pipe cavity with one or multiple openings in the pipe cavity wall making the device's outlet port, and an open end making the device's inlet port, and a closed end, and a seat surface with an opening making a reduced pipe cavity diameter, and in which a spool body is located, and where the spool body forms a seal to the seat, which is characterized by the closed end of the pipe cavity is closed with an end body, which design determines the agent flow control characteristics of the device, and where the fully assembled spool body may be removed from the pipe cavity through the opening the End Body closes when the End Body is dismounted the device.
In a further embodiment, the arrangement the spool body in its one end ends in a shaft portion having smaller diameter than the opening in the valve seat of the pipe cavity of the device housing, and where the shaft shaped ending of the spool body penetrates one or multiple opening in a guide body which is located in the pipe cavity of the devices housing between the open cavity end and the seat surface in the pipe cavity, and where the spool body in one or multiple locations between the opening in the pipe cavity wall of the devices housing and the end body ending the pipe cavity forms one or multiple dynamical seals to the device housing.
In a further embodiment, the spool body outer diameter is smaller than the diameter of the pipe cavity end of the device housing which is closed with a removable end body, and where the spool body in one or multiple locations has an outer diameter which are larger than the diameter of the opening in the seat surface of the diameter reduction seat in the pipe cavity of the devices housing.
In a further embodiment, a compressed spring being located between the end body which ends the pipe cavity of the devices housing and the spool body located in the pipe cavity of the devices housing, supplying a force which force the spool body to press against a seat surface located in the pipe cavity.
In a further embodiment, the devices housing consisting of an assembly of common pipe fittings, in the shape of Tee-fitting, and pipe fittings for pipe connections.
In a further embodiment, the spool body having a cavity with one or multiple openings to its outside surfaces, which when the spool body seals against the seat in the pipe cavity, is located in on or multiple locations up-stream the seat in the pipe cavity of the device housing and down-stream the dynamic seal between the spool body and the device house, and which together performs as an agents pilot supply line for the spool body location control, which is located inside the device housing.
In a further embodiment, the device housing being fitted with a pilot supply pipe connecting the pipe cavity volume between the device inlet and the spool body seat to the device housing to an opening into the pipe cavity volume between the spool body end and the end body attached to the device housing.
In a further embodiment, the inlets openings to pilot agent supply lines located upstream the spool body seat being protected with strainer or filters having openings which is less than the water ways of the control systems.
In a further embodiment, the device performing pressure control on agent flow to down-stream system by help of the device having an end body attached to end the pipe cavity, which contains one or multiple openings connecting the pipe cavity volume between the spool body and the end body to a cavity which connects two chambers located around the same axial center. And where the one chamber is connected to the outlet port of the device, and where an axial movable pilot spool body is located in the two chambers, and where the pilot spool body in the chamber which is connected to the device outlet port has larger diameter than that of the opening connecting the chamber to the opening into the pipe cavity of the device, and where the pilot spool body end in the other chamber forms a piston in in a cylinder, and where there is a connection through the pilot spool body connecting the chamber with connection to the device outlet port to a cavity located to a position between the pilot spool body piston shape and the connection from the other chamber, and where a compressed pilot spring is located in the cylinder chamber between the pilot spool body piston shape and a device to regulate the pilot spring compression.
In a further embodiment, the device having an end body fitted to end the pipe cavity volume, which is fitted with an override valve in the form of an integrated electrical operated device and, or a valve fitted to the end body, which when opened connects the pipe cavity volume located between the spool body and the end body to drain outside the device.
Number | Date | Country | Kind |
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2014 70022 | Jan 2014 | DK | national |
Filing Document | Filing Date | Country | Kind |
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PCT/DK2015/050012 | 1/16/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/106767 | 7/23/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2233649 | Stahl | Mar 1941 | A |
3860073 | Willms | Jan 1975 | A |
4070000 | Prescott | Jan 1978 | A |
4313466 | Adams | Feb 1982 | A |
4586533 | Estes | May 1986 | A |
5738332 | Perez Corbalan | Apr 1998 | A |
5954138 | Gabriel | Sep 1999 | A |
20030102137 | Bermes | Jun 2003 | A1 |
Number | Date | Country |
---|---|---|
85109329 | Aug 1987 | CN |
1102463 | May 1995 | CN |
1104918 | Apr 2003 | CN |
201368205 | Dec 2009 | CN |
102010029825 | Dec 2011 | DE |
0769644 | Apr 1997 | EP |
2428714 | Mar 2012 | EP |
Entry |
---|
Search Report from Denmark Application No. PA 2014 70022, dated Sep. 1, 2014, 4 pages. |
International Search Report from International Application No. PCT/DK2015/050012, dated Apr. 10, 2015, 4 pages. |
Written Opinion of the International Searching Authority from International Application No. PCT/DK2015/050012, dated Apr. 14, 2015, 4 pages. |
Chinese Patent Office Action for Application No. 201580004969.9 dated Apr. 2, 2018 (9 pages, Statement of Relevance Included). |
Number | Date | Country | |
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20160341319 A1 | Nov 2016 | US |