The present disclosure relates to the control of subterranean water. Particularly, the present disclosure relates to a sump pump with an emergency backup system for use in a structure having a basement floor located below ground level, which must be kept free of the ingress of subterranean water.
In structures, such as homes, having basements or cellars which extend below ground level, it is imperative that the ingress of water be prevented so that the basement space may remain usable. To that end, structures typically have footing drains leading to a sump or other similar collection basin, from which water is removed via a sump pump. It is a common practice in many areas of the United States to provide the sump in the floor of the basement.
A typical sump pump is an AC motor driven pump which operates using line power. Generally, a liquid level sensing device is provided to energize the pump motor when water level in the sump reaches a predetermined height and to deenergize the motor when the level has dropped to a safe level. Various types of sensing devices have been used for this purpose including sensors, float operated switches and pressure responsive switches.
The need for the sump pump is often greatest when storms occur. Unfortunately, the sump pump may not function when needed in an emergency because of a power failure or it may fail to operate because, for example, the level sensing device fails to operate. There are other factors that may result in the sump pump becoming inoperative, such as corrosion of certain pump parts, or clogging of the sump pump as a result of debris accumulating in the sump. In an attempt to solve the problems associated with the sump pump during those periods when pumping is necessary, a well-provided home also has a battery-operated emergency or backup pump, so that pumping can continue to avoid basement flooding.
Such battery or DC motor driven pumps are typically mounted in the sumps alongside the primary pumps, with the DC motor circuit being activated in response to a power line failure. Alarms have been provided for giving a warning if the battery voltage falls below a predetermined level. Unfortunately, these auxiliary DC systems have left much to be desired in preventing flooding due to AC motor driven pump failure. By way of example, since the battery operated pumps are rarely used, they sometimes are inoperative when their use is required. This may occur because the battery is incapable of supplying the power necessary to drive the pump. Although the static battery voltage may appear to be satisfactory, the initial current drain may reduce the battery voltage below the usable value.
Accordingly, the present disclosure provides a sump pump with an emergency backup system which overcomes certain difficulties with the prior art systems. The emergency backup system can be activated in response to power line failure, malfunctioning of the sump pump and/or the sump pump being overpowered by volume of water in the sump.
In accordance with one aspect of the present disclosure, a flood control system for use in a structure having a basement floor below ground level is provided. The flood control system comprises a sump, a main pump positioned in the sump, and a secondary pump positioned in the sum. The secondary pump is raised relative to the main pump to a predetermined elevation. The main pump is energized when a height of water within the sump is at a first level. The secondary pump is energized when a height of water within the sump reaches a second, higher level and is de-energized when a height of water within the sump drops to a third level. A cover is releasably mounted to the sump. The cover includes a first section for covering the main pump and a separate second section for covering the secondary pump. At least one of the first and second sections is hingedly mounted to the sump. A controller is operatively connected to the main pump and the secondary pump. The controller is responsive to water level within the sump to selectively energize at least one of the main pump and the secondary pump.
In accordance with another aspect of the present disclosure, a flood control system comprises a sump for gathering subterranean water for removal from the structure. An AC operated main pump and a DC operated secondary pump are positioned in the sump. An elevating member is located in the sump for raising a height of the secondary pump relative to the main pump. A cover is releasably mounted to the sump. The cover includes a first section for covering the main pump and a separate second section for covering the secondary pump. At least one of the first and second sections is hingedly mounted to the sump. A first discharge pipe is connected to an outlet of the main pump. A separate second discharge pipe is connected to an outlet of the secondary pump. The first and second discharge pipes extend through the cover and are configured to discharge to separate locations for preventing back pressure through the first and second discharge pipes.
In accordance with yet another aspect of the present disclosure, a flood control system comprises a sump, an AC operated main pump and a DC operated secondary pump. Each pump is positioned in the sump. The secondary pump is raised relative to said main pump to a predetermined elevation. The main pump is energized when a height of water within the sump is at a first level. The secondary pump being is energized when a height of water within the sump reaches a second, higher level and is de-energized when a height of water within the sump drops to a third level. A is shelf located in the sump for elevating the secondary pump in relation to the main pump. The shelf includes an opening configured to receive the main pump and a ring portion adjacent the opening for stopping a rotation of the shelf within the sump.
It should, of course, be understood that the description and drawings herein are merely illustrative and that various modifications and changes can be made in the structures disclosed without departing from the present disclosure. It will also be appreciated that the various identified components of the sump pump with an emergency backup system disclosed herein are merely terms of art that may vary from one manufacturer to another and should not be deemed to limit the present disclosure. All references to direction and position, unless otherwise indicated, refer to the orientation of the sump pump with an emergency backup system illustrated in the drawings and should not be construed as limiting the claims appended hereto.
Referring now to the drawings, wherein like numerals refer to like parts throughout the several views,
The main pump 104, which can be located on a floor 108 of the sump 102, is an AC motor driven pump employed in the sump to remove liquid, e.g., subterranean water, which may collect therein. For example, the basements of homes or commercial establishments may have such sumps to collect subterranean water for removal and thereby keep the basement dry. The main pump includes a housing 114 within which is the AC motor (not shown). A bottom portion of the housing can include a mesh screen. A discharge pipe 120 is connected to an outlet of the main pump 104 and extends to an appropriate location for discharge.
A first liquid level sensing device (not shown) can be provided to energize the main pump motor when water level in the sump 102 reaches a predetermined height and to de-energize the motor when the water level has dropped to a safe level. The first liquid level sensing device can be conventional and include sensors, float operated switches, pressure responsive switches and the like.
As indicated in the Background, the main pump 104 is subject to failure. For example, because the main pump is powered by the same alternating current employed for electrical power elsewhere in the home or commercial establishment, if a power failure occurs, the main pump 104 becomes inoperative. Since it is not uncommon for such a power failure to occur as a result of a storm, the main pump 104 may become inoperative just at the very time it is needed most. It should be appreciated that there are other factors that may result in the main pump becoming inoperative, such as corrosion of certain pump parts, or clogging of the main pump as a result of debris accumulating in the sump 102. Because the main pump may occasionally fail to operate, the secondary pump 106 is employed to remove water collected within the sump 102.
The secondary pump 106 includes a housing 130 for housing, for example, a twenty-four (24) volt electric or DC driven motor (not shown). A filter, such as a perforated cylindrical sleeve 132, can be attached to an upper portion of the housing for filtering water that flows into the secondary pump. A second liquid level sensing device (not shown) for operating the DC motor can be mounted within the filter for protecting same against damage and against fouling by debris. Similar to the first liquid sensing device, the second liquid sensing device can be conventional and can energize the secondary pump 106 when water level in the sump 102 reaches a predetermined height and de-energize the secondary pump when the level has dropped to a safe level. A separate discharge pipe 138 is connected to an outlet of the secondary pump 106 and extends to an appropriate location for discharge.
It should be noted that the separate discharge pipes 120 and 138 ensure effective operation of the main and secondary pumps 104, 106. Particularly, when two separate pumps send water into discharge lines which are connected to form a single overall discharge line, as is common in the art, the system may not achieve optimum results. Conditions can occur whereby one pump can cancel out the other, or one pump can overpower the other pump, thereby preventing the other pump from operating at full capacity. This can be due to differing pumping capacities or by backpressure created by bends in the single discharge line. Therefore, in the present disclosure, the separate discharge pipes 120, 138 are configured to discharge to separate locations or into a larger diameter discharge pipe (having a diameter at least equal to the combined diameters of the two smaller discharge pipes running from the main and secondary pumps 104 and 106) located outside of the sump 102. The two smaller pipes 120 and 138 would connect at different locations on the larger pipe.
In one embodiment, as illustrated in
Further, check valves 140, 142 can be located at the outlets of the main and secondary pumps 104, 106, respectively, for connecting the outlets to the discharge pipes 120, 138. The check valves prevent backflow into the pumps.
As shown in
With reference to
To better accommodate both the main pump 104, the secondary pump 106 and the shelf 150, an alternative embodiment of a sump 102′ is shown in
With reference again to
When the water level in the sump 102 rises to a first predetermined elevation and is sensed by the first liquid sensing device (not shown), the main pump 104 is energized via the controller 202 to pump water out of the sump through the discharge pipe 120. The main pump then remains energized for a predetermined time after the water level falls below the first elevation. If the main pump 104 fails to operate because of an interruption in AC power from the power line 200 via the AC power source 204 or because of a failure of the AC motor or another component of the main pump, or simply due to the volume of water in the sump 102, the water level in the sump will generally continue to rise. When the water level reaches a second predetermined elevation, the secondary pump 106 is activated. The secondary pump then remains energized for a predetermined time after the water level falls below the second predetermined elevation. Thus, the secondary pump 106 functions as a standby which can automatically set into operation to perform the pumping function normally performed by the main pump. If, on the other hand, the water level reaches the second elevation because the capacity of the main pump 104 is insufficient to handle the flow of water into the sump 102, then the two pumps can be operated simultaneously to prevent the water from over-flowing the sump.
As indicated above, it is only on infrequent occasions that the use of the secondary pump 106 will be required, but it is most important that the secondary pump function properly when its use is required. There are however, several reasons for failure of the secondary pump. For example, the motor of the secondary pump may be defective, the secondary pump itself may be defective or plugged or the DC power source (i.e., batteries 210, 211) may not provide sufficient power even though the voltage thereof during nonuse is at a satisfactory level. To prevent such failure, the controller 202 is configured to constantly monitor the output voltage of the DC power source. The controller can provide a warning if such voltage falls below a predetermined value. If the voltage falls, the controller can include means for charging the batteries from an AC power source, such as the AC power source 204 for the main pump or a separate AC power source. To further ensure the operation of the secondary pump 106 and sufficient output power of the batteries 210, 211, the controller 202 can switch to a test mode whereby the controller periodically activates the secondary pump for a set period of time. For example, the controller can cycle on the secondary pump 106 once a day for about eight (8) seconds. If the secondary pump functions properly, the controller returns the system 100 to normal operation. On the other hand, if the secondary pump fails to operate satisfactorily in the test mode, an alarm on the controller can be actuated to notify the user and the batteries 210, 211 can be recharged, if necessary. The disclosure herein is to a sump pump system which is simpler and more robust than the prior art. Also, less monitoring is necessary than in the known sump pump systems.
With reference to
While a particular sump design and lid design have been illustrated herein, it should be apparent to those of average skill in the art that the sump design and lid design can be changed while achieving the same objectives. It should also be appreciated that the sump pump with emergency backup system 100 can be a standalone system for removing subterranean water from a building or can be implemented into a home waterproofing system 300, schematically illustrated in
The waterproofing system 300 is used with a foundation wall 310 which is supported on a footer 312. A first, outside trench 314 is excavated to a shallow depth beneath the ground level next to the outside surface of the wall. On the outside surface of the wall 310, a waterproofing sealing membrane 316 is affixed to seal the wall. A layer of gravel 320 is placed in a trough formed in the membrane. A drain tile 322 for draining water is placed in the trough and is at least partially covered by the gravel. The gravel protects the tile 322 from dirt and allows water to flow therethrough to the tile. The trench may be back filled with a backfill 326 of earth. A second, inside trench 328 is formed adjacent an inside surface of the wall 310 next to the footer 312. A gravel bed 330 is laid and drain tile 332 is placed in the inside trench 328. The drain tiles 332 are also covered with gravel 330. A third trench 350 can be formed on the outside of the wall 310 adjacent footer 312. A gravel bed 352 is laid and drain tile 354 is placed in the trench. The tile 354 is covered with gravel 352.
The waterproofing system 300 of
With reference now to
Also, in this embodiment, separate power lines 410 and 412 are employed for the respective main pump 104′ and secondary pump 106′. Power line 410 is connected to a first AC power source 414 and power line 412 is connected to a second AC power source 416. The second AC power source can also provide electricity via a third line 418 to a battery charger 420. The battery charger can selectively charge a DC power source, such as two 12 volt batteries 422 and 424. The DC power source can be employed to run the motor of the emergency secondary pump 106′ via a line 426 when that becomes necessary. To this end, the battery charger 420 can also act to control the operation of the secondary pump via battery power. Thus, a simple, robust system is shown with a minimum of monitors or other complex electronics, which can be not only expensive but are subject to malfunctions.
It will be appreciated that various of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art. These are also intended to be encompassed by the following claims, and their equivalents.
This application claims priority from U.S. Provisional Patent Application Ser. No. 61/030,102, filed 20 Feb. 2008, the disclosure of which is incorporated herein by reference.
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Number | Date | Country | |
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20090208345 A1 | Aug 2009 | US |
Number | Date | Country | |
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61030102 | Feb 2008 | US |