Method of cleaning the inlet to a thruster while in operation

Abstract

A method for the prevention or remediation of flooding waters in a geographic area using one or more thrusters to increase the velocity of a portion of the water in a channel draining the flooding waters away from the geographic area, mixing the portion of the accelerated waters back in to the remainder of the waters in the channel thereby increasing the average velocity of the waters in the drainage system and increasing the rate of removal of the flooding waters from the geographic area, the thrusters having the one or more inlets approximately at ninety degrees from the centerline of the thruster and cleaning the thruster inlets by reversing the flow through the thruster while the flooding waters are still passing the thruster.

Claims

1. A method for cleaning the inlet for one or more thrusters increasing the velocity of flowing waters in a channel in a first direction comprising using said one or more thrusters to draw a portion of said waters into one or more inlets of said one or more thrusters and increasing the velocity of said portion of said waters in a first direction within said one or more thrusters and sending said portion of said waters with said increased velocity out of one or more outlets, said one or more thrusters having a housing with a centerline, mixing said portion of said waters with said increased velocity back into the remainder of said waters to increase the average velocity of said waters in said first direction, and cleaning one or more of said one or more inlets of debris without slowing said flowing water in said channel by reversing the flow in said one or more thrusters in said first direction by drawing said portion of said waters into said one or more thrusters at proximately ninety degrees to said first direction and discharging said portion of said waters through said inlets at proximately ninety degrees from said first direction.

2. The invention of claim 1, further comprising said cleaning one or more of said one or more inlets of debris begins automatically.

3. The invention of claim 2, further comprising said cleaning of said inlet to said one or more thrusters when the suction pressure in said inlet is more than a predetermined value.

4. The invention of claim 2, further comprising said initiating of said cleaning of said one or more inlets to said one or more thrusters when the suction pressure in said one or more inlets is less than a predetermined value.

5. The invention of claim 1, further comprising cleaning one or more inlets to said one or more thrusters while said waters are in motion relative to said thruster.

6. The invention of claim 1, further comprising cleaning said one or more inlets of debris while said water outside of said housing in said one or more thruster is flowing proximately in said first direction.

7. The invention of claim 6, further comprising said cleaning occurs by providing a blocker within said housing to block a portion of the said one or more inlets of said one or more thrusters to allow unassisted flow outside said housing of said one or more thrusters to clean said one or more inlets which are blocked.

8. The invention of claim 7, further comprising moving said blocker to alternate the portions of said one or more inlets.

9. The invention of claim 8, further comprising rotating said blocker about a rotational axis or said centerline to alternate said portions of said one or more inlets.

10. The invention of claim 1, further comprising cleaning said one or more inlets of debris while said water in said one or more thrusters is flowing in a second direction which is proximately opposite said first direction.

11. The invention of claim 10, further comprising cleaning a portion of said one or more thrusters which is not said one or more inlets.

12. A method for the prevention or remediation of flooding waters in a geographic area comprising using one or more thrusters to draw a portion of said waters into one or more inlets to increase the velocity of said portion of said waters and send said portion of waters out of one or more outlets in a first direction, said one or more thrusters having a housing with a centerline, mixing said portion of said waters back in to the remainder of said waters in said geographic area increasing the average velocity of said waters in said geographic area in said first direction from an unassisted velocity to an assisted velocity thereby increasing the rate of removal of said waters from said geographic area, and cleaning one or more inlets to said one or more thrusters of debris without slowing said flowing water in said geographic area in said first direction by reversing the flow in said one or more thrusters by drawing a portion of said waters into said one or more thrusters at proximately ninety degrees to said first direction and discharging said portion of said waters through said one or more inlets at proximately ninety degrees from said first direction.

13. The invention of claim 12, further comprising receiving said portion of said waters proximately radially into said one or more thrusters.

14. The invention of claim 12, further comprising reversing the flow of said one or more thrusters to initiate said cleaning.

15. The invention of claim 14, further comprising said initiating cleaning of said one or more inlets to said one or more thrusters when the suction pressure in said one or mere inlets exceeds a predetermined value.

16. The invention of claim 14, further comprising directing a portion of said flow of said one or more thrusters proximately axially of said one or more thruster.

17. The invention of claim 14, further comprising cleaning a portion of said one or more thrusters which was not said one or more inlets.

18. The invention of claim 12, further comprising said cleaning occurs by providing a blocker within said housing to block a portion of the said one or more inlets of said one or more thrusters to allow unassisted flow outside said one or more thrusters to clean said one or more inlets which are blocked.

19. The invention of claim 18, further comprising moving said blocker to alternate the portions of said one or more inlets.

20. The invention of claim 18, further comprising rotating said blocker to alternate the portion of said one or more inlets.

21. A method for the prevention or remediation of flooding waters in a channel or geographic area comprising cleaning one or more inlets to said thrusters while said flooding waters are in motion relative to said one or more thrusters, using said one or more thrusters to increase the velocity of a portion of said flooding waters within said one or more thrusters and sending said portion of waters out of one or more outlets, said one or more thrusters having a housing with a centerline, mixing said portion of said flooding waters back into the remainder of said flooding waters in said channel or geographic area increasing the average velocity of said flooding waters in said channel or geographic area thereby increasing the rate of removal of said flooding waters from said channel or geographic area, and said thrusters having said one or more inlets proximately at ninety degrees from said centerline.

22. The invention of claim 21, further comprising reversing the flow of said one or more thrusters to initiate said cleaning.

23. The invention of claim 22, further comprising said cleaning of said inlet to said one or more thrusters when the suction pressure in said inlet is below a predetermined value.

24. The invention of claim 22, further comprising said initiating of said cleaning of said one or more inlets to said one or more thrusters when the suction pressure in said one or more inlets is more than a predetermined value.

25. The invention of claim 23, further comprising directing a portion of said reversed flow of said one or more thrusters proximately axially of said one or more thrusters.

26. The invention of claim 21, further comprising said cleaning occurs by providing a blocker to block a portion of the said one or more inlets of said one or more thrusters to allow unassisted flow outside said one or more thrusters to clean said one or more inlets which are blocked.

27. The invention of claim 26, further comprising moving said blocker to alternate the portions of said one or more inlets which are being cleaned.

28. The invention of claim 26, further comprising rotating said blocker to alternate the portion of said one or more inlets about said rotational axis or centerline which are being cleaned.

29. The invention of claim 22, further comprising cleaning a portion of said one or more thrusters which was not said one or more inlets.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a view of the general geographic area of Houston showing water flowing normally past downtown in Buffalo Bayou and by the University of Houston flowing in Brays Bayou, and finally in the bay system and into the Gulf of Mexico. The thruster packages of this invention are shown in place on Buffalo Bayou only.

(2) FIG. 2 is a view of the same general area in which the bayous are full and flooding has occurred both in the downtown area and in the University of Houston area. The thruster packages of this invention are shown in place, but not turned on.

(3) FIG. 3 is a view of the same general area with the flooding remedied by turning the thrusters on.

(4) FIG. 4 is a cross section of a waterway or other drainage channel with thrusters of the invention in place.

(5) FIG. 5 shows a perspective of thrusters of this invention as it would be when the flood waters are being jetted downstream.

(6) FIG. 6 shows a perspective of a thruster of this invention generally viewed from the downstream end while it is jetting.

(7) FIG. 7 shows an end view of a thruster of this invention from the downstream end while it is jetting.

(8) FIG. 8 shows a perspective of a thruster of this invention similar to FIG. 6 except from the upstream side and showing reversed flow through the thruster.

(9) FIG. 9 shows a perspective of a thruster of this invention similar to FIG. 8 except from the lower side and showing a lower check valve being opened by the flow.

(10) FIG. 10 shows a perspective of a thruster of this invention similar to FIG. 8 with the outer housing removed for clarity and the water flowing through in the jetting direction.

(11) FIG. 11 shows a perspective of a thruster of this invention similar to FIG. 10 with the outer housing removed for clarity and the water flowing through in the reversed cleaning direction.

DESCRIPTION OF THE PREFERRED EMBODIMENT

(12) Illustrative embodiments of the invention are described below. In the interest of clarity, not all features of an actual implementation are described in this specification. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort, even if complex and time-consuming, would be a routine undertaking for those of ordinary skill in the art having the benefit of this disclosure.

(13) How do we input power into water in open channels? Remote subsea vehicles, thrusters on great vessels and even propellers on large ships are means to put energy into water, to cause water to move in one direction, normally with the objective of moving the vessel in the opposite direction. Literally a propeller takes a small poundage of water and throws it to the rear of the ship. That energy of throwing the water to the rear of the ship causes an equal reaction in the opposite direction and provides force to move the ship forward. One can see the water speeding from the propeller at rear of a boat. Imagine that a giant propeller the size of a river is turning in a river, you can easily see that the water in the river will be accelerated.

(14) Now imagine that every one thousand feet along the Houston Ship Channel from downtown Houston to the start of the bay system into the Gulf of Mexico we put a water jet thruster package into the water. It is a distance of about 20 miles. That would be about 5 thruster packages per mile or about 100 thruster packages. Now assume in the normal flood situation, the waters are being carried away from downtown Houston, down the Houston Ship Channel, at approximately 3 miles per hour. The speed is a balance between the energy provided by the water and the frictional forces resisting it.

(15) Now assume that we have enough thrusters and we put enough power in each of the thrusters to increase the speed of the water to 6 miles per hour. If we literally increase the speed of the water in the Houston Ship Channel from 3 miles per hour to 6 miles per hour, we increase the flow rate from about 150 million cubic feet per hour to about 300 million cubic feet per hour and the flood disappears. The thrusters will take a small percentage of the flowing water into them and accelerate it out to a higher speed such as 30 miles per hour. When this accelerated water merges back into the flowing water, the average speed of all the water flowing will be increased.

(16) The better scenario isn't that we turn on the thrusters and cause the flood to go away, but when the rain comes we turn on the thrusters and the flood never happens in the first place.

(17) If the estimate of water at flood stage in Buffalo Bayou from Houston is a minimum of 36 feet deep, 300 feet wide at the surface, 228 feet wide at the bottom and the water flowing at the rate of 3 miles per hour, that would mean that a total of 1,003,622 cubic feet of water would be flowing, or 62,626,037,760 lbs. of water would be flowing. If the bayou slopes 24 in 20 miles, it drops 1.2 feet per mile or 3.6 feet in one hour, or 0.000682 feet per minute. The energy derived is 0.000682 feet times 62,626,037,760 lbs. or 42,699,571 feet-pounds per minute. This divided by 33,000 gives 1,294 horsepower.

(18) If the power required is a function of the square of the velocity, and the system method is only 50% efficient, then 1294*4/0.5=10352 horsepower. If we divide the 10352 horsepower by the 100 thruster stations, we get that each of the thruster stations would require a minimum of 103.5 horsepower.

(19) Referring now to FIG. 1, Buffalo Bayou 1 flows from west of Downtown Houston 2 thru a bay system into the Gulf of Mexico 3. White Oak Bayou 4 flows into Buffalo Bayou 1 at the confluence 5. Brays Bayou 6 flows by the University of Houston 7 and intersects Buffalo Bayou at 8.

(20) A multiplicity of thrusters 10-14 are shown in Buffalo Bayou 1, the lower end of Buffalo Bayou actually being the Houston Ship Channel 9. The thrusters 10-14 are shown above the water level in normal conditions in FIG. 1.

(21) Referring now to FIG. 2, generally in the area of the confluence 5 of Buffalo Bayou 1 and White Oak Bayou, major storms happened in the summer of 2001 and in 2017, causing more water to fall than Buffalo Bayou 1 could carry off to the Gulf of Mexico. As a direct result, a major flooding occurred generally in the area of the confluence of Buffalo Bayou and White Oak Bayou 5. Flooding 20 proceeded into downtown Houston 2 causing massive damage. Additionally, as Buffalo Bayou 1 was carrying as much water as it could carry, any rain falling onto the area of Brays Bayou 6 near the University of Houston had no means of flowing away, but simply collected. This resulted in major flooding in the area of the University of Houston, resulting in approximately $250 million dollars in damages.

(22) Referring now to FIG. 3, the thrusters of this invention have been turned on, causing the waters in Buffalo Bayou to flow faster. This results first in the flooding 20 in downtown Houston 2 being alleviated. Secondly, if also implemented, as the waters in Brays Bayou 6 now have someplace to flow, the flooding at the University of Houston 7 is eliminated. Although not shown on the figures, flooding also occurred along White Oak Bayou 4 which would not have happened if the methods of this invention had been applied.

(23) Referring now to FIG. 4, as taken along lines 4-4 of FIG. 5, a bayou or river 30 is shown with water 32 flowing at a normal level 34, flood level waters are shown at 36, and intermediate level of water is shown at 38. The intermediate level of water 38 is the maximum anticipated water level with this invention installed. A thruster system is shown at 40 with the thrusters 42 and 44 at a level above the normal flow of water at 34, but in the water below levels 36 and 38. A motor house is shown at 46, with power being conducted through shaft 48 to the thruster 42.

(24) The thruster 42 is effectively shown being mounted generally parallel to the center of the water way. In actual practice, benefits will be seen from having thrusters on opposite sides of the waterway and inclined rotated slightly toward the center of the waterway to optimize the addition of kinetic energy to the water in preference to added bank friction. Bottom of the bayou or river 30 is shown at 50 and the side is shown at 52. Revetments are shown at 54 which are generally one-foot cube concrete blocks interlaced with steel cable to reinforce the bank against erosion which still allowing green grass to grow. Alternately the sides of the waterway can be lined with concrete to prevent erosion.

(25) Referring now to FIG. 5, a perspective of a thruster of this invention as it would be when the flood waters are being jetted downstream without the water being shown.

(26) Referring now to FIG. 6 which is generally taken along lines 6-6 of FIG. 5, the thruster 42 is shown with outer housing 60 having a multiplicity of inlet holes 62 along the upstream, outlet check valve 64, and upstream dome 66. Arrows 70 and 72 illustrate water entering the outer housing 60 and arrow 74 illustrates water exiting outer housing 60 and being jetted downstream. In this case the flowing water is pushing the outlet check valve 64 open against gravity. When the flow 74 stops, outlet check valve 64 will close automatically.

(27) Referring now to FIG. 7, a view of the thruster 42 is seen from downstream generally along the lines 7-7 in FIG. 6. In addition to the parts shown in FIG. 5, a second flow arrow 80 is shown along with the impeller blades 82.

(28) Referring now to FIG. 8, a perspective of a thruster 42 is illustrated showing the upstream end and illustrating water being reversed to clean the inlets. Water is not entering from the bottom as indicated by arrow 90 and exits as indicated by arrows 92-98. Water being blown out of holes 62 as shown by arrows 92 and 94 will tend to release any debris which has collected on the side holes. Water being blown out of holes 100 as shown by arrows 96 and 98 will tend to lift anything off the dome 66 and cause it to float away. A very difficult item to deal with is a large tarp which is floating in the water and hits the upstream end, specifically wrapping around dome 66. Flow as shown by arrows 96 and 98 will cause a layer of water much like a liquid bearing to form over the dome, eliminating retaining friction and cause the tarp to slide off the dome. Holes 100 do not represent water inlets during normal operations as will be seen later.

(29) The decision to reverse the flow and clean the inlets can be made in a variety of ways. Some of the ways might be to monitor the suction pressure within chamber 126 and when it exceeds a desire value do a cleaning reversal, doing it at predetermined timed intervals, signaling the operation by remote control.

(30) Referring now to FIG. 9, a perspective of thruster 66 similar to FIG. 6 except from the lower side and from the outlet end. Lower check valve 110 is opened by the reverse flow allowing reverse circulation.

(31) Referring now to FIG. 10, a perspective of a thruster 42 is shown similar to FIG. 8 with the outer housing 60 removed for clarity. The flow arrows are shown similar to FIG. 6 in the normal operation mode. Lower check valve 110 is closed both by gravity and the flow and outlet check valve 64 is pushed open by the flow. Central motor or gearbox 120 is shown and a second set of impellers 122 is seen. Upstream check valve 124 is closed by gravity and by flow. It is closed against a mating plate with a hole (not shown) in the dome 66 by both gravity and the suction which will occur in chamber 126 during normal flow.

(32) Referring now to FIG. 11, a perspective of a thruster 42 is shown similar to FIG. 10 with the outer housing 60 removed for clarity. The flow arrows are shown similar to FIG. 8 when flow is reversed for cleaning. Lower check valve 110 is opened by the flow and outlet check valve 64 is closed by both suction and gravity. Upstream check valve 124 is opened by the flow. In this way the reversed flow is introduced to dome 66 as seen in FIG. 8 to introduce the fluid bearing on dome 100. Shaft 140 extends from motor or gearbox 120 which the impellers 82 and 122 rotate. Gear 142 is on the end of shaft 140 and engages planetary gear 144 which is mounted on blocker 146. Planetary gear 144 engages internal gear 148, which is stationary. This causes planetary gear 144 to rotate about the center of the housing 60 and similarly to rotate blocker 146 about the center of housing 60. Blocker 146 has edges 150-156 which closely fit or seal to the internal bore of housing 60, allowing blocker 146 to block the flow coming in a portion of the holes 62 in housing 60. This provides in normal operation for debris which might block a portion of the holes 62 to be released without having to reverse the flow. In this way continuous and intermittent cleaning of the inlets of thruster 42 are achieved.

(33) The particular thruster embodiment shown in the figures is a series of propellers mounted in a cylindrical housing. Any number of embodiments for a thruster can be utilized in this service, such as a single open propeller, gear pumps, or piston pumps.

(34) As the water level rises in the waterway, various means such as floats or pressure sensors can be utilized to automatically turn the engine on to drive the thruster until the water level drops satisfactorily. Additionally, remote or radio-controlled means can be easily utilized to start, stop, or regulate the speed of the thrusters.

(35) The particular embodiments disclosed above are illustrative only, as the invention may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. It is therefore evident that the particular embodiments disclosed above may be altered or modified and all such variations are considered within the scope and spirit of the invention. Accordingly, the protection sought herein is as set forth in the claims below.

NUMBERS IN SPECIFICATIONTRASH

(36) Buffalo Bayou 1 Downtown Houston 2 Gulf of Mexico 3 White Oak Bayou 4 confluence 5 Brays Bayou 6 the University of Houston 7 intersects Buffalo Bayou at 8 multiplicity of thrusters 10-14 Houston Ship Channel 9 Flooding 20 bayou or river 30 water 32 normal level 34 flood level waters 36 inter. level of water is shown at 38 thruster system is shown at 40 thrusters 42 and 44 motor house is shown at 46 shaft 48 Bottom 50 side is shown at 52 Revetments are shown at 54 outer housing 60 multiplicity of inlet holes 62 outlet check valve 64, and upstream dome 66 Arrows 70 and 72 arrow 74 second flow arrow 80 impeller blades 82 arrow 90 arrows 92-98 holes 100 arrows 96 and 98 dome 66 Holes 100 chamber 126 Lower check valve 110 motor or gearbox second set of impellers 122 Upstream check valve 124 chamber 126 Shaft 140 impellers 82 and 122 rotate Gear 142 planetary gear 144 blocker 146 internal gear 148 blocker 146 edges 150-156 internal bore