The present invention relates to a device for flushing sewage systems so as to prevent the build up of deposits in the interior thereof. Sewer systems usually comprise a network of connected pipes linking buildings to a sewage treatment facility or waste outlet. The pipes carry human waste such as washing water, faeces, urine, laundry waste and other material which goes down drains such, as runoff rain water, which then needs to be disposed of safely and effectively. In some remote locations sewage is collected in septic tanks or cesspits and may be treated in situ or transported by a vehicle to a sewage treatment facility where it may be disposed of safely, but the pipes of these systems may still requiring cleaning.
In view of the nature of sewage, deposits such as fats, oils and greases accumulate on the interior of the pipes and other conduits in the sewer system, which is particulalry common in systems where the rate of sewage flow is low. Low flow may result from constant dry weather or periods of low waste being produced. The accumulation of such deposits can eventually lead to a complete or partial blockage that inhibits the flow of sewage through the system and ultimately leads to flooding or combined sewer overflow (CSO) discharges. Untreated sewage then becomes entrained in rivers and other watercourses and endangers the lives of life forms living therein and also humans bathing.
In order to minimise the risk of blockages, pipelines should be monitored and high risk areas cleaned periodically. Sewer pipes (also simply referred to as sewers) can be cleaned using pressurised water jetting systems, but these are known to damage the pipes and also pollute ambient air. Such procedures can also be costly.
It is an object of the present invention to provide a cleaning system which is self-sufficient and is operable without human intervention. It is a further object of the invention not to require inspection chamber covers to be opened during operation so as to avoid polluting the surrounding air. Moreover, it is an object of the invention not to damage the sewer system during operation and not to waste more water in the cleansing process which usually becomes entrained in the sewage and require treatment.
According to the present invention, there is provided a sewer flushing device for location in a sewage system, the device comprising
Preferably the housing comprises a frame and the gate is correspondingly sized and shaped to fit therein. Sewage systems comprise a network of conduits of various sizes and shapes according to their particular purpose and the usual and peak volume of sewage to flow therethrough. Thus, the size and shape of the frame may be selected to form an appropriate fit within the particular part of the sewage system in which it is to be located.
The gate may be mounted in the housing and arranged to pivot about a generally horizontal axis. This allows the gate to make full use of gravitational forces acting thereon, when moving between closed and open positions. Most preferably the generally horizontal axis is located approximately one third of the way up the gate from the bottom thereof.
Preferably deflectors may be provided on the gate and or the housing to deflect solid debris in the sewage away from the points where the gate is pivotally connected to the housing. Such deflectors may be mounted on the upstream side of the gate and the housing and have a generally tapered triangular profile with the narrow part upstream. Such deflectors aim to prevent solid matter from fouling the movement of the gate.
Many suitable arrangements are known for pivotally supporting gates and they may be suitable for the present invention, but in view of the adverse conditions in the sewage system it is preferable to include as few moving parts as possible. For instance, lugs extending generally horizontally from one of the gate and housing may be arranged to locate in openings provided on the other of the gate and housing. Most preferably such lugs are provided on the gate and the openings are provided on the housing.
The openings for receiving such lugs may comprise keyway slots formed in sidewalls of the housing. These are usually located so that the pivoting axis of the gate is generally horizontal. The keyway slots enable the gate to be securely supported on the housing, while permitting easy attachment and removal of the gate form the housing. In some circumstances, particularly during periods of heavy flow where no intermittent flushing is required or cold weather where there is a risk of the gate freezing onto the housing it may be preferable to temporarily remove the gate. Furthermore, many housings may be located at different points in the sewage system and one or more gate could be periodically moved from one housing to another to vary the position of flushing in the system. The keyway slots may take various forms; some may include several sections angled relative to each other while others may be generally linear. Some of the linear slots may be relatively short with an enlarged head while others may be relatively long with a uniform width. Many arrangements are possible so long as they allow the gate to be removed from the housing without requiring additional parts.
Seals may be provided on the housing. Against these the gate may bear when in its closed position so as to prevent or reduce sewage passing around the gate when in its closed position. The seals may also act as an abutment to limit the angular rotation of the gate when in its closed position. Furthermore, a specific abutment may be provided on the housing to support the gate in its open position and limit the angular rotation. Such an abutment may take a variety of forms, including, for example a bar extending between the sidewalls of the housing. Most preferably the abutment may be sufficiently narrow to avoid obstructing the flow of sewage.
Furthermore, seals may be provided on the gate so as to bear against the housing to inhibit the flow of sewage between the gate and the housing. In one arrangement, a seal is provided around a lower part of the gate so as to bear against the housing and seals are also provided on the housing and arranged to bear against upper parts of the gate. Preferably, elongate seals are provided on opposed sides of the housing and arranged to overlie part of the upstream face of the gate when in its closed position. The elongate seals may taper inwardly towards the lower part of the housing.
Preferably the housing and gate may each have a lower portion shaped to correspond to the sewage channel into which they are located. For example the sewage channel and the lower portion may both be curved and of a similar size so as to form a snug fit.
Preferably the sewer flushing device may be adapted to be located in an inspection chamber having a sewer inlet and a sewer outlet and a sewage flow channel therebetween. Such inspection chambers may be sufficiently large to enable a workman to access the conduit and which would therefore facilitate easy installation, maintenance and removal of the flushing device. Of course, the flushing device could be located in a sewage pipe when building the pipeline or possibly retrofitted.
Preferably a counterweight may be provided on the gate so as to bias the gate to its closed position. Most preferably the counterweight may have smooth contours so as to minimise turbulence as sewage flows thereby and also to reduce the likelihood of debris getting caught thereon. In one embodiment the counterweight is integral to the gate, but in an alternative embodiment the counterweight may be attached to the gate by suitable fastening means so as to facilitate removal therefrom. In some instances it may be preferable to attach a lighter or heavier counterweight to the gate so as to adjust the pre-determined level of sewage that must accumulate to cause the gate to move to its open position.
There may also be provided a locating device to assist in holding the housing in the required position. Such a device may comprise a sewer engaging portion adapted to locate in the sewer channel, and a housing connector adapted to connect to the housing.
Most preferably the sewer engaging portion is shaped to form a snug fit within a sewage inlet or outlet such as the inlets and outlets of the inspection chamber, thereby providing means by which the locating device and thus the flushing device may be secured in place. Additionally, the locating device may further comprise connecting means for fastening the locating device to parts of the chamber.
The housing connector may comprise at least one rigid protrusion adapted to extend into a lower part of the housing and overlie the base thereof, such that in use the base of the housing is lodged between the bottom of the sewer and the rigid protrusion. Most preferably the rigid protrusion may form a snug fit with the interior of the lower portion of the housing.
The sewage flushing system may also comprise baffles adapted to prevent sewage passing alongside the housing and bypassing the gate when in its closed position. For instance, a baffle may be mounted on opposed sides of the housing and connected to an adjacent wall so as to inhibit the flow of sewage and also serve to secure the flushing device in the required position.
One specific embodiment of the present invention will now be described in detail, with reference being made to the following drawings, in which,
Referring specifically to
Referring to
A keyway slot 35 is formed in each sidewall 25 of the housing 21 and arranged to receive a respective stud 33 extending from an adjacent edge 30 of the gate 21. Each keyway slot 35 comprises a large circular opening 36 and a narrow Z shaped opening 37 extending downwardly from the large opening. The large opening 36 of each keyway slot 35 is necessary to assist mounting the gate 22 in the housing 21, as the distance between the ends of the studs 33 is greater than the internal width of the housing 21. Fitting the gate 22 into the housing 21 requires the gate to be presented at an angle relative to the two sidewalls 25 so that one stud can be inserted into its respective large opening and then the angle of the gate relative to the sidewalls can be adjusted so as to locate the other stud into its respective large opening. The position of the studs 33 relative to the base 32 of the gate 22 must correspond to the position of the keyway slots 35 relative to the base 26 of the housing 21 for an effective seal to be created and the gate to fit sufficiently well in the housing 21. However, the height of the pivoting axis is proportional to the amount of sewage that must accumulate upstream of the flushing device to urge the gate 22 to its open position as shown in
A bar 40 extends between the two sidewalls 25 of the housing 21 at substantially the same height as the pivoting axis of the gate 22, but near the downstream face 28 so as to provide a surface against which the gate 22 bears when in its open position as shown in
Seals 41 project inwardly from the internal faces of the two sidewalls 25 so as to provide a sealing surface against which the gate bears when in its closed position. Each seal has a lower end located just above the pivoting axis of the gate 22, so as not to obstruct the movement of the gate from its closed position to its open position. Seals could also be provided for the lower portion of the gate but these might inhibit sewage flow, so are usually omitted.
A counterweight 43 is provided on the lower end of the gate 22, which, under the force of gravity biases the gate towards its closed position. The counterweight provided on the gate shown in
Referring now to
The middle section 53 of the housing locator 23 comprises a semicircular channel having an outer radius corresponding in size to the inner radius of the semicircular channel 14, so that the middle section may be located snugly in said channel.
The upstream end 54 is an extension of the middle section 53 in that it is a semicircular channel having an internal radius equal to that of the middle section so that the middle section 53 and second end 54 define a continuous interior. However, the external radius of the second end 54 is slightly smaller than that of the middle section 53, the difference in size being substantially equal to the wall thickness of the gate housing 21 such that an axial shoulder 59 is defined on an axial face of the middle section 53.
Thus, when the housing locator 23 is fitted in the manhole 10 a semi annular space is defined between the exterior of the second end 54 and the semicircular channel 14 in the floor 13. The gate housing 21 can then be positioned in the floor channel 14 behind the locator housing 23 and slid forward so that the base locates in the semi annular space, the rear face 28 of the housing abuts the should 59 and the upstream end 54 forms a liner sleeve over the internal face of the base 26, thereby holding the gate housing 21 firmly in position.
As shown in
In use, the gate 22 is biased to its closed position by the counterweight and sewage flowing down the sewer accumulates behind the gate housing 21 and baffles 65. When the height of accumulated sewage reaches a predetermined level the gate 22 will pivot to its open position (
In some instances it may be preferably to remove the gate 22 from the gate housing 21 or even remove the gate housing 21, particularly during periods of high sewage flow where there is a concern that the accumulation may cause flooding. Alternatively, flushing devices may be installed at various locations in the sewage system, but only some of those devices may be provided with gates so as to vary the level of cleansing at different locations in the system. To this end, the keyway slots 35 facilitate easy removal of the gate 22 from the gate housing 21 and the locator housing 23 facilitates easy removal of the gate housing 21 from the manhole 10.
Number | Date | Country | Kind |
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0809150.6 | May 2008 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2009/050463 | 5/5/2009 | WO | 00 | 2/14/2011 |