Patent Grant
11299878
The present invention relates generally to vacuum sewage transport systems for conveying sewage collected in a holding sump to a downstream collection vessel maintained under the influence of vacuum or subatmospheric pressure, and more specifically, to a vacuum sewage system with a sump breather apparatus.
Various vacuum sewage systems are known. Generally speaking, such systems are used to transport sewage and other waste liquids under vacuum or subatmospheric pressure from a source, such as a residential or commercial establishment, to a collection vessel. Examples of such systems are described in U.S. Pat. No. 4,179,371 issued to Foreman et al. and U.S. Pat. No. 5,570,715 issued to Featheringill et al.
In one embodiment of the present invention, a vacuum sewage system includes a sump pit for receiving sewage from a source of sewage, a valve pit, a valve located in the valve pit, a suction pipe having a first end connected to the valve and a second end extending into the sump pit, a transport pipe having a first end connected to the valve and a second end extending outside the valve pit, a sensor-controller, a first sensor pipe, a sump breather and a second sensor pipe. The sensor-controller selectively opens and closes the valve so as to permit sewage in the sump pit to travel from the sump pit, through the suction pipe to the discharge conduit. The first sensor pipe has a first end extending into the sump pit and a second end extending into the valve pit. The first sensor pipe communicates increased pressure to the sensor-controller as the level of sewage rises within the sump pit. The second sensor pipe has a first end extending into the sump pit and a second end extending into the valve pit. The second sensor pipe communicates pressure to the sump breather to move the sump breather from a first state to a second state to prevent sewage from entering the sensor-controller and valve.
In one embodiment, the first sensor pipe extends into the sump pit a greater distance than the second sensor pipe extends into the sump pit.
In another embodiment, the sump breather includes a housing, a first port for communicating atmospheric pressure from the sump pit to the housing and a second port for communicating atmospheric pressure from the housing to the sensor-controller. In one embodiment, the sump breather includes a diaphragm for selectively opening and closing the first port and the second port in response to increased sewage levels in the sump pit. In another embodiment of the invention, the sump breather includes a third port for communicating increased pressure from the second sensor pipe to the housing of the sump breather.
According to another embodiment of the invention, the diaphragm has a first side and a second side, the first port and the second port are positioned on the first side of the diaphragm and the third port communicates increased pressure to the sump breather housing on the second side of the diaphragm.
In certain embodiments, the system includes a spring for biasing the diaphragm away from the first and second ports.
In other embodiments of the invention, the system includes a switch for producing a signal indicating an abnormal state of operation of the vacuum sewage system. Certain embodiments of the invention include a spring cup located within the sump breather housing. The spring cup is moveable against the force of the spring in response to movement of the diaphragm. In other embodiments, movement of the diaphragm to seal the first port and the second port causes movement of the spring cup to activate the switch.
In other embodiments, the system includes a relief valve to prevent delayed operation of the sump breather. The relief valve prevents delayed operation of the sump breather by releasing excess pressure build up in the sump pit.
In one embodiment of the present invention, a vacuum sewage system includes a sump breather apparatus having a sensor pipe and a sump breather. The sump breather includes a housing having a first member and a second member, a first port communicating with the interior of the housing, the first port extending from the first member of the housing, a diaphragm located in the housing, the diaphragm having a first side and a second side, and a switch for producing a signal indicating an abnormal state of operation of the vacuum sewage system.
In one embodiment, the first port communicates with the interior of the housing on the first side of the diaphragm and the sump breather further includes second, third, fourth, fifth and sixth ports extending from the second member of the housing. The second, third, fourth, fifth and sixth ports communicate with the interior of the housing on the second side of the diaphragm.
According to another embodiment, the system further includes a spring that biases the diaphragm toward the first member of the housing.
In other embodiments, the diaphragm moves in response to pressure communicated to the interior of the housing toward the second member of the housing to seal the third, fourth, fifth and sixth ports.
In one embodiment, the system further includes a spring cup and movement of the diaphragm toward the second member of the housing causes the spring cup to activate the switch.
In one embodiment, the system further includes a relief valve to prevent delayed operation of the sump breather.
In certain embodiments, the vacuum sewage system includes a sump pit for receiving sewage from a source of sewage, a valve pit, a valve located in the valve pit, a suction pipe having a first end connected to the valve and a second end extending into the sump pit, a transport pipe having a first end connected to the valve and a second end extending outside the valve pit and a sensor-controller located in the valve pit, the sensor-controller selectively opens and closes the valve so as to permit sewage in the sump pit to travel from the sump pit, through the suction pipe to the discharge conduit. The sensor pipe communicates increased pressure in the sump pit to the sensor-controller to activate the sensor-controller. In one embodiment, the sensor pipe communicates increased pressure in the sump pit to the sump breather to activate the sump breather. In another embodiment, the sensor-controller is activated at a lower pressure than is the sump breather during normal operation of the sensor-controller.
Other features of the present invention will be apparent from the following description of embodiments of the invention and accompanying drawings.
Located above ground a distance away is a vacuum collection station containing a collection vessel 20 maintained at vacuum or subatmospheric pressure by means of vacuum pumps. Vacuum collection vessel 20 is operatively connected to sump pit 12 by means of a vacuum transport conduit 22. The vacuum transport conduit may be laid in a number of configurations. For example, it may be provided with “pockets” in which the sewage is collected so as to form a plug that entirely fills the cross-sectional bore of the conduit. The sewage plug is moved by means of differential pressure through the conduit in an integral condition. U.S. Pat. No. 3,115,148 issued to Liljendahl, and U.S. Pat. No. 3,730,884 issued to Burns et al. disclose such “plug-flow” systems. More preferably, the conduit portion leading to each pocket or low point is sloped such that the low point will not be filled with sewage upon completion of a sewage transport cycle, and an equalized vacuum or subatmospheric pressure condition is communicated instead throughout the conduit network. As taught by U.S. Pat. No. 4,179,371 issued to Foreman et al., a sewage/air mixture in such a “two-phase flow” system is swept along the conduit during a transport cycle.
A top panel 24 of sump pit 12 is connected to the sidewalls thereof. Positioned on top of the top panel 24 is valve pit 26, which is accessed at ground level by a manhole cover 28. Located within valve pit 26 is vacuum interface valve 30. Examples of interface valves may be found in U.S. Pat. No. 4,171,853 issued to Cleaver et al., and U.S. Pat. Nos. 5,078,174, 5,082,238 issued to Grooms et al, U.S. Pat. Nos. 5,259,427, 5,326,069 and 5,282,281. As shown generally in
Sensor-controller 66 is used to deliver a vacuum/subatmospheric or atmospheric pressure condition to upper housing 50 so to open or close interface valve 30 in response to the sewage level in sump pit 12. The structure of sensor-controller 66 is described more fully in U.S. Pat. No. 4,373,838 issued to Foreman et al. As shown in
To the other end of piston rod 94 is connected three-way valve seat 108 made from a plastic material. Flange 110 on valve seat 108 is positioned between elastomeric seals 112 and 114 which communicate vacuum/subatmospheric and atmospheric pressure from vacuum chamber 82 and atmospheric inlet port 102, respectively, to valve chamber 84.
Sensor-controller 66 is shown in the closed position in
Once the hydrostatic pressure communicated to chamber 78 rises to a predetermined level, diaphragm 86 is biased into contact with lever valve 90, which in turn is activated to open port 88 so that the vacuum/subatmospheric pressure in chamber 80 is replaced with the atmospheric pressure condition of sensor chamber 79 (
U.S. Pat. No. 4,691,731 issued to Grooms et al. describes another vacuum sewage system having a sump/valve pit structure 130, as shown in
Problems arise, however, if the vacuum/subatmospheric pressure condition within vacuum transport conduit 22 diminishes to a low vacuum condition. Referring to
Once the sewage level in sump pit 12 rises to a sufficient level, positive pressure therein pushes sewage through breather tube 142 to atmospheric inlet port 102 of sensor-controller 66. The atmospheric pressure in sensor valve chamber 79 will temporarily keep the sewage from entering it via atmospheric conduit 106. However, once lever valve 90 is opened when the sensor-controller valve is fired, atmospheric pressure leaks from sensor valve chamber 79 into chamber 80. Moreover, atmospheric pressure can leak from sensor valve chamber 79 through vacuum conduit 120, vacuum hose 98, and surge tank 100 into vacuum transport conduit 22. By reducing the atmospheric pressure condition in sensor valve chamber 79, sewage may now enter it and the rest of the sensor-controller chambers through the aforementioned paths to ensure that sensor-controller 66 cannot operate properly until it is manually drained by service personnel.
Thus, U.S. Pat. No. 4,691,731 also discloses a sump-vent valve which may be interposed within vacuum hose 98, and is closed by a low vacuum condition to prevent communication of the low vacuum to sensor-controller 66 which can cause atmospheric pressure in sensor valve chamber 79 to leak, and thereby compromise the sealed nature of chamber 79 that otherwise keeps sewage out of sensor-controller 66.
It has been found, however, that several problems can arise in operation of this system. First, the sump-vent valve is typically set to close at the correct time once a low vacuum pressure condition arises. For example, if 5 inches of vacuum is required to operate sensor-controller 66, and the sump-vent valve is set to close at 6 inches of vacuum, then the system works. However, if over time the sump-vent valve begins to close at 4½ inches of vacuum, then it is not activated soon enough as the vacuum pressure within the system 10 drops, and low vacuum can be communicated to sensor-controller 66 to allow sewage to enter it, despite the presence of the sump-vent valve.
Second, even if the sump-vent valve operates properly, once full vacuum is restored to the system, sensor-controller 66 will be activated to the open position in response to the elevated hydrostatic pressure condition in chamber 78. Some atmospheric pressure will be consumed in the process, which will cause sewage to be pulled through breather tube 142 into sensor-controller 66.
Third, breather tube 142 is connected to the top of sensor pipe 37 that extends through sump pit top 24. If the seal between sleeve 132 and top 24 fails, then atmospheric pressure can leak out of sump pit 12 into valve pit 26. This permits even more sewage to collect in sump pit 12 if the low vacuum condition that renders sensor-controller 66 and interface valve 30 inoperative by the sump-vented valve persists over an extended period of time. Once full vacuum is restored, and sensor-controller 66 is activated, enough atmospheric pressure can leak within sensor-controller 66 to draw sewage into it, as previously described.
Another problem arises if gravity line 14 is installed improperly or settles over time to create a dip therein. If the cross-sectional bore of the dipped portion becomes filled with sewage, then atmospheric pressure from gravity vent pipe 18 cannot be communicated to sump pit 12 to be passed to sensor-controller 66 and interface valve 30. This could prevent the sensor-controller and interface valve from operating properly. Furthermore, if hydrostatic pressure builds sufficiently in sump pit 12, then it, and not atmospheric pressure, can be communicated to atmospheric inlet port 102 of sensor-controller 66. Thus, hydrostatic pressure would be communicated to both ends of sensor-controller 66, and then to chambers 78 and 79, which would render sensor-controller 66 completely inoperative.
Second sensor pipe 300 is secured to sump pit top panel 24 by a sleeve and a collar 301 similar to those describe above in connection with
Sump breather 400 generally includes a housing having a first member 401 and a second member 402 connected by bolts or other fasteners F. Sump Breather 400 further includes a first port 403, a second port 404, a third port 405, a fourth port 406, a fifth port 407 and a sixth port 408. First port 403 extends from and may be integral with first member 401 of the housing of sump breather 400. Second port 404, third port 405, fourth port 406, fifth port 407 and sixth port 408 extend from and may be integral with second member 402 of the housing of sump breather 400.
As shown in
Sump breather 400 also includes a switch assembly 420 supported within second member 402 of the housing of sump breather 400. Switch assembly 420 includes a moveable switch element 422 and an electrical connector 424.
Sump breather apparatus 200 further includes a spring 430 and spring cup 431. Spring cup 431 includes a first member 432 and a second member 433. First member 432 includes a threaded protrusion or boss 434 which extends through opening 412 in diaphragm 410 and through an opening 435 in second member 433 of spring cup 431. First member 432 and second member 433 of spring cup 431 are secured together by engaging a nut or threaded retaining member 436 on threaded boss 434 of first member 432. Spring 430 is surrounds boss 434 and is captured between second member 433 of spring cup 431 and support structure 421. Spring 430 biases spring cup 431 and diaphragm 410 so as to position diaphragm 410 away from third port 405 and sixth port 408 as shown in
A first tube T1 connects first port 403 to second sensor pipe 300 and communicates pressure in sensor pipe 300 to first port 403. A second tube T2 connects second port 404 to first nozzle 302 of collar 301 and permits liquid to drain from sensor-controller 66, through sump breather 400, through first nozzle 302 and into sump pit 12 via the space between the exterior surface of sensor pipe 300 and the lower section of collar 301. A third tube T3 connects third port 405 to second nozzle 303 of collar 301 and supplies atmospheric pressure to sump breather 400 on one side of diaphragm 410. A fourth tube T4 is connected to fourth port 406 and a fifth tube 15 is connected to fifth port 407. Fourth tube T4 and fifth tube T5 are connected at their opposite ends to lower housing 48 and communicate atmospheric pressure to lower housing 48. A sixth tube T6 is connected to sixth port 408 and to the atmospheric inlet port 102 of sensor-controller 66. A seventh tube T7 is connected at one end to relief valve 500 and at the other end to tube T2.
When the amount of sewage in sump pit 12 is at normal levels for proper operation of the vacuum sewage system, the pressure in second sensor pipe 300 will be zero. This is because second sensor pipe 300 is shorter than sensor pipe 37 and, therefore, does not extend as far into sump pit 12 as does sensor pipe 37. Stated another way, sewage in sump pit 12 will reach the opening of sensor pipe 37 and increase the pressure therein before it reaches the opening of second sensor pipe 300 and increases the pressure therein.
When the sewage level in sump pit 12 becomes abnormally high, it will enter second sensor pipe 300 and communicate higher pressure through first port 403 to diaphragm 410. As the pressure continues to increase, diaphragm 410 and spring cup 431 will be pushed toward the right as shown in
When the operational problem is corrected, sensor-controller 66 will cycle and will reduce the sewage level in sump pit 12 to normal operational levels. This will in turn lower the pressure in second sensor pipe 300, which will cause diaphragm 410 to move away from third port 405, fourth port 406, fifth port 407 and sixth port 408 back to the position shown in
Note that relief valve 500 prevents delayed operation of sump breather 400 by releasing pressure build up in pit 12 that exceeds a specified level. Stated another way, if the pressure build up in pit 12 is such that it would prevent activation of sump breather 400, relief valve 500 will release the excess pressure in pit 12, thereby allowing activation of sump breather 400.
Although the present invention has been shown and described in detail, the same is for purposes of illustration only and should not be taken as a limitation on the invention. Numerous modifications can be made to the embodiments disclosed without departing from the scope of the invention.
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