US20040199989A1

US20040199989A1 - Toilet and urinal leak detection and warning system and method

Info

Publication number: US20040199989A1
Application number: US10/821,596
Authority: US
Inventors: Anthony Trolio
Original assignee: Individual
Current assignee: Individual
Priority date: 2003-04-11
Filing date: 2004-04-09
Publication date: 2004-10-14

Abstract

A toilet and urinal leak detection and warning system and method which detects water flow for a period of time outside a predetermined window. The invention includes a water flow detector, a timer and an audible alarm sound generator.

A flow of water past the water flow detector triggers the timer and in the event that the water is still running after a predetermined amount of time, a control signal is sent to the audible alarm generator and alarm will sound. The invention further includes reset logic to allow for either an automatic, or manual, reset of the alarm that will terminate the alarm state and return the device to a detection mode. The invention also may be configured to measure and react to relatively short flows of water signifying a slow loss of water not related to normal flushing activity.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

The Applicant claims the benefit of his provisional application No. 60/462,211 filed on Apr. 11, 2003.[0001]

BACKGROUND OF THE INVENTION

The present invention relates to a system for monitoring an operating toilet or urinal, in order to provide a user with a warning indication of a condition of failure, specifically the passing of water through the internal plumbing for a duration longer or shorter than planned, such that the user may undertake the necessary remedial actions.

Flush toilets are designed with a flush mechanism which is made up of a tank reservoir which when flushed release the water contained via gravity feed to force the waste through displacement to pass through the wastewater plumbing (soil or sewer line). The tank reservoir includes an apparatus which detects the water level in the tank. As the water level in the tank falls, a valve is opened to allow water from an outside source to enter the tank. If there are no leaks allowing the water to exit the tank in the absence of a flush cycle, the tank will eventually fill to a level to satisfy the water level detector, typically a float device, which will cause the water inlet valve to close.

Occasionally, a failure occurs to impede the process of filing the tank reservoir. Some examples of common failures are: the flush mechanism fails to reseat resulting in an opening allowing water to continue to flow from the tank reservoir to the toilet bowl after the flush cycle is complete; a leak between the toilet tank reservoir and the toilet bowl permitting water to escape the reservoir; a failure in the tank reservoir water level detector causing the water to continue to pass into the tank after the tank has reached a full level. Other failure modes include the short cycling of the toilet tank water valve which results from slow leaks somewhere in the mechanism. A leak in the system may allow the tank water level to reach a full level. However, occasional refreshing of the level will be required causing the refill cycle to be very short.

The current design of many millions of toilets will, under the conditions mentioned, continue to allow water to pass through the water inlet valve and through the tank reservoir until the condition repairs itself, or until it is noticed by someone who takes action to cause the continued water flow to cease. In some situations, a slow leak in the toilet reservoir may cause water inlet valve to recycle on a regular basis to keep the reservoir tank filled. In this failure mode, the water inlet valve will operate for a shorter period of time than normally would be associated to fill the tank when the tank is operating normally during a flush operation. Providing that an average toilet may pass up to two gallons of water per minute, a toilet which displays one or more of the aforementioned conditions may cause approximately 2500 to 3500 gallons of water to be wasted per day until the problem is detected and repaired.

In the case of urinals, a specially designed flush valve allows water to pass for a predetermined period of time. The water then rushes down the front face of the urinal through gravity feed to the bottom where it exits the drain. However, flush mechanisms are prone to stick in the open position allowing the water flow to continue well past the designed and intended duration.

SUMMARY OF THE INVENTION

One object of the present invention is to provide a running water detector and warning system which indicates the continuous flow of water into a toilet tank reservoir, or down the face of a urinal, and gives an alarm signal to the users such that they may undertake the necessary remedial actions. It is also an object of the present invention to provide a means to detect short cycling of a water inlet valve in a toilet tank reservoir to provide an alarm to the users that there is a leak in the system causing a shorter than normal flow of water into the reservoir to replenish water loss through the leak in the system.

The invention includes a means to detect a fluid flowing in a portion of a particular fixture, means to time the duration of the fluid flow, measurement of the fluid flow duration to compare to a predetermined preprogrammed duration, and means to enable an alarm to notify the user. As an alternative, the means for alarm can activate a solenoid driven fluid valve to shut off the fixture experiencing the problem if desired by the user. The method of determining that the plumbing fixture has a problem is disclosed which includes measurement of fluid flow to the fixture as being outside a predetermined normal operating window of fluid flow duration for normal fill operations.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a partial perspective view of a toilet with the leak detection and warning system apparatus of the present invention installed thereon. [0009]
FIG. 2 is a schematic view of a tubular-shaped water flow detector used with an embodiment of the present invention as depicted in FIG. 1. [0010]
FIG. 3 is a schematic view of a tubular-shaped water flow detector used with an embodiment of the present invention as depicted in FIG. 1 with an alternate circuit plan. [0011]
FIG. 4 is a partial cross sectional view of the water flow detector as depicted in FIG. 2 wherein the conductive members of the detector exist as surface contact points inside the tube. [0012]
FIG. 5 is a cross sectional view of the water flow detector as depicted in FIG. 2 wherein the conductive members of the detector pass completely through the inside of the tube. [0013]
FIG. 6 perspective view of a urinal with the leak detection and warning system apparatus of the present invention installed thereon. [0014]
FIG. 7 is a top plan view of a water flow detector in the form of a flat strip used with an embodiment of the present invention as depicted in FIG. 6. [0015]
FIG. 8 is a side view of a water flow detector of FIG. 7 wherein the strip-shaped water flow detector is essentially straight. [0016]
FIG. 9 is a side view of a water flow detector of FIG. 7 wherein the strip-shaped water flow detector is curved. [0017]
FIG. 10 is a circuit diagram for the electronic water flow detector, timer and alarm included in a preferred embodiment of the system of FIG. 1. [0018]
FIG. 11 is a block diagram showing the step by step process of the fluid flow detection method disclosed. [0019]
FIG. 12 is a block diagram illustrating an alternative configuration of the invention used to shut a fluid input valve to a fixture.[0020]

DETAILED DESCRIPTION OF THE INVENTION

In the following detailed description, like reference numerals will be used to refer to like or corresponding elements in the different figures of the drawings. The present invention couples a [0021] water flow detector 11 with a timer and alarm circuit 12 to detect a continuous and unintended water flow problem with a flush toilet or urinal. A preferred embodiment is disclosed in FIG. 1, showing the basic internal components of a typical toilet.
The [0022] water flow detector 11 is a device that detects a continued flow of water past or through it. As depicted in FIG. 2, this device is constructed of an insulating material 14 with a plurality of conductive members 13 mounted to the insulating material. In this particular embodiment depicted in FIG. 2, the insulating material is formed into the shape of a tube. The conductive members 13 are aligned and the device is mounted at the end of the inlet refill tube 16 such that when water flows into the tank of a toilet through the inlet refill tube 16, the incoming water passes over or through the detector 11. The water passing in contact with the conductive members 13 will cause them to be electrically connected by virtue of the conductivity of the water. Water existing across the conductive members 13 essentially act as a switch. One or more of the conductive members 13 are connected to a power source 18 or ground source 17. Thus, water that comes in contact with the conductive members 13 connected to each side of the detector circuit will cause the normally open circuit to be closed.
Turning to FIG. 4 and FIG. 5, one ordinarily skilled in the art can appreciate that the required [0023] conductive members 13 can take on various shapes provided that the passing water has adequate access to the surface of the conductive members. Accordingly, FIG. 4 depicts an embodiment of the present invention such that the conductive members 13 exist as surface contact points inside the tube shaped insulating material 14. In contrast, FIG. 5 depicts an embodiment of the present invention such that the conductive members 13 pass completely through the inside of the tube shaped insulating material 14.
Turning to FIG. 6, a depiction of a urinal with the leak detection and warning system apparatus of the present invention installed thereon is shown. The [0024] water flow detector 11 is mounted such that when water flows down the front wall 19 of the urinal, water flows over the detector 11. Accordingly, the insulating material 15 to be used on the front wall 19 of a urinal might best be served in the form of a straight flat strip as shown in FIG. 8 or slightly curved strip as shown in FIG. 9.
Turning now to FIG. 11, the sequence of events in the method disclosed shall be described in detail. First, it is necessary that [0025] fluid flow detection 30 occur. Measurement of the fluid flow is then timed to provide a duration of fluid flow 32. The usefulness of the method comes in comparing the measured duration 32 against a preestablished desirable flow duration range 34. The desirable flow duration window is measured usually in seconds and perhaps minutes. For a given fixture, the desirable range would be the normal operating parameters of the fixture as installed when considering the input fluid flow duration to refill the fixture or otherwise replenish the fluids consumed in the operation of the fixture. In establishing such a desired duration range 34, taken into account are such things as a short fluid flow run time which would indicate a partial refill because of a slow leak, or an over duration period indicating that the input valve or other mechanism to the fixture is stuck open or otherwise is not entirely completing its cycle causing the fixture to run in an on condition even though an overflow condition causing spillage may not exist. It can also be appreciated that in adjusting the desirable flow duration range 34, a certain amount of additional time on both ends of the desirable time range window is desirable to prevent false alarms because of slight differences occurring because of the aging fixtures, a drop or increase in inlet fluid pressure, or other normal changes in operating parameters that would cause a slight change in the range of normal operation in day to day use.
If the duration of [0026] fluid flow 32 falls outside the normal operating duration range 34, an alarm condition 36 exists. If an alarm condition 36 is tripped, an audible alarm 42 or other operation such as a command to close a fluid feed valve through a solenoid 40 can be the result. As an adjunct to the method, it can be appreciated that an external moisture condition 38 can also be used to enable the alarm condition range 36 to take desirable steps such as sounding an alarm or taking other action. External moisture conditions can include spillage of the fixture onto the floor or base of the fixture, or an overflow condition in the bowl of the fixture, all of which represent failures or conditions which may not be related to a stuck valve or other internal leak condition that would be measured by the duration of fluid flow 32.
FIG. 11 is a block diagram showing basic component configuration for an alternative preferred embodiment of the present invention. [0027] Fluid flow sensor 11 provides its output parameters to duration detection and alarm system 46 which can drive a solenoid fluid valve 34 to close the fixture until service can be provided. As described above, an external moisture sensor 48 can be used as an accessory to the present invention to provide similar action in the event there is not a problem measured by the duration of the fluid flow to the fixture, but rather a spillage condition such as a clogged drain or other failure which may cause water spillage over the fixture onto the floor base or other parts of the fixture that normally would remain dry.
FIG. 10 shows a schematic of a typical alarm circuit and timer circuit that is coupled to the [0028] water flow detector 11. The timer circuit is constructed of commercially available components such as the 555 timer, which is used as a monostable multivibrator, and in this mode is essentially a one shot timer. Using this device, a resistor and capacitor combination is selected to create a pulse duration. The pulse duration is set to approximately two times the intended water flow period as designed to run in the flush cycle. In the event water continues to be detected by the water flow detector for a duration as long or longer than the pulse duration set up in the timer, the timer will output a time-out pulse. In order to generate a stable signal from the timer, the output pulse is connected to a flip-flop and the data output of the flip-flop is directed to the alarm circuit. To trigger the alarm, the output of the timer circuit—which for example is set to a logical 1 (high state) if the alarm is triggered—is connected to the reset of the alarm circuit timer IC.
Using a [0029] 555 timer in an astable mode enables it to operate as an oscillator. In this fashion, the output is connected to a speaker to generate a buzz alarm tone of which the duration and tone emitted can be altered with the insertion of a capacitor connected within the positive side of the speaker connection. The 555 timer reset pin is connected to the output of the flip-flop such that when the flip-flop output is high, the alarm will sound.
In the automatic reset embodiment, the output of the water flow detector which is high when water flow is detected, is connected via an AND gate to the reset of the [0030] alarm circuit 555 chip. The output of the timer circuit flip-flop is the other input to the AND gate. Thus, when the timer circuit has timed out and water flow continues to be detected, the alarm will sound. When the water flow ceases to be detected, the alarm will cease to sound.
In the manual reset embodiment, a manual reset circuit contains a manual reset switch. Following the time-out, the alarm will sound whether water continues to flow or not. The reset switch is connected to ground on one side and to present or set pin of the flip-flop of the timer circuit. When pressed, the flip-flop is cleared and the signal to the alarm circuit goes low causing it to stop oscillating. Other timing circuits such as an oscillator and counter combination might be employed to measure the time period in which water runs. [0031]
The present invention may also be easily configured to react to undesirable intermittent water flow of the reservoir tank in certain instances of failure. Undesired intermittent water flow in a reservoir tank of a toilet may be caused by several different factors. Such factors include a leaky flap seal which occurs sometimes because of the seal's age or poor condition; an improperly adjusted float valve which controls the inlet valve allowing fresh water to pass into the tank; the inlet valve malfunctions for various reasons or small cracks in the tank which allow water to leak slowly out of the tank or between a faulty seal thereby requiring the inlet valve to operate intermittently to refresh the tank water level. [0032]
In such cases of intermittent flow, the inlet valve opens for only a short period of time to compensate for the loss of water not related to an actual flush operation. Because the duration of the flow is relatively short when compared to the duration of water flow related to a normal operating flush cycle, the present invention may employ a second timer circuit to detect such an occurrence. As can be appreciated by those skilled in the art, in such a situation the goal would be to detect that the duration of the water flow from the inlet valve into the tank is sufficiently less than what would be expected during a normal flush cycle. [0033]
A counter is added to count the number of times a “short flow” has occurred. Upon reaching a predetermined number of short flow occurrences, the counter would output a signal to which a latching operation would be associated. A latch circuit or other similar device would be connected to the alarm circuit in such a way to cause the alarm signal to activate and sound an alarm. In such a configuration, the present invention can provide an indication of a short flow run valve failure situation as described above allowing the owner to take appropriate action to repair the source of the problem. [0034]
In using the present invention in the immediately above described embodiment, a water flow circuit is configured to provide the measurement of the events described above. Upon sensing the water flow, a water flow detector circuit sets a latch which is operatively connected to an intermittent flow timer circuit. The intermittent flow timer circuit begins a timing event in each instance. If the water flow ends prior to the end of the timer sequence, a latch signal is set causing a pulse to be sent to the counter causing it to increment. It can be appreciated by one skilled in designing such incrementing counting circuits that a circuit can be designed to increment or decrement depending on the particular design preferred. If multiple occurrences of a short time sequence occurs, thereby causing the counter to overflow (or underflow) its preset alarm limit, a pulse is outputted from the counter to a latch circuit which is operatively connected to the alarm circuit. Accordingly, the alarm will sound notifying the owner of a short cycle valve operation. [0035]
It would be a simple matter to provide for a separate alarm circuit which could be employed such that the sound emitted in response to an intermittent flow condition might be different from the sound emitted in response to a continued water flow failure such as a stuck valve or the like. Alternatively, the pulse or signal sent to the alarm circuit from the counter circuit output latch could be used to alter the sound emitted from the alarm circuit. Those skilled in the art can once again accomplish such an end result in a number of ways such as using the state of the signal to set a flip-flop device which divides the pulses being sent to the speaker thus creating a different tone. In the event the intermittent timer reaches its timed out value, which would be the case in a normal flushing cycle, a pulse is sent to the counter clearing it and thereby allowing the entire counting cycle to begin once again. [0036]
An alternate embodiment of the disclosed invention contemplates connection of the output of the timer circuit, or the intermittent water flow detector or both, with a central alarm system as are commercially available. The central alarm system being a device designed to monitor a plurality of alarm types and take a prescribed or programmed action upon the event of detecting an alarm on one of the connected inputs. Such connection could be hardwired or via radio frequency. The same connection from the output of the timer circuit, or the intermittent water flow detector or both, could be made to a computer via a computer network interface or direct connection to a computer via one on the many interface methods available on standard computer systems. [0037]
While the main advantage of the present invention is to provide notification when the fixtures water feed system is running too long or too short than necessary to meet the design requirements of the fixture, other alarm systems can be integrated in parallel with the existing device to add usefulness to the end user. For example, while there are other overflow detection systems described in the prior art, none of such systems address the flow rate measurement issue taught in the instant application. It would be useful, however, to add to the present device accessories which allow for both the measurement of the condition described in this specification, as well as measurement of overflow conditions if the plumbing fixture is clogged and water begins to overflow from the bowl or other reservoir as is sometimes observed. Such additional alarm conditions can include water or moisture sensors placed on the floor underneath the fixture, or a water level alarm at the top of the rear reservoir of the toilet fixture or the bowl itself. In this fashion, the advantages of the present invention can be combined with more conventional moisture detection systems which only provide an alarm condition upon measuring moisture or water spillage where none normally would exist, during the proper operation of a fixture. Integration of the moisture sensor which would detect water levels or moisture conditions as described would be well known to those skilled in the art such that the integration of additional sensor inputs can be added to the alarm circuit to provide notification if an overflow condition exists. Such sensor could be placed on the floor behind or near the fixture. Other moisture sensors could be placed near the rim of a bowl or the reservoir tank of a fixture. [0038]
As an additional improvement or utility of the present invention, the alarm output generated by the detection of the period of time the water is flowing can be processed such as to drive a solenoid plumbing valve to shut off the water feed to the plumbing fixture which is leaking or for which the water feed is running too long. Aside from issuing an alarm condition to gain the attention of the homeowner, the output of the alarm can drive a solenoid valve so that water pressure to the fixture can be cut off automatically if desired. Such a solenoid driven valve is disclosed in prior art and is used for a variety of different plumbing fixtures to allow for valves to be opened or closed electrically without manual intervention. If a solenoid powered valve is utilized, it would require a separate power supply since the amount of current drawn by such solenoids is substantial enough to prevent them from being available to operate with small long-life batteries such as could be utilized in the alarm circuit disclosed. [0039]
In considering the alarm circuit disclosed in the present invention, it can also be appreciated that it may be convenient to provide a wireless alarm circuit whereby short range wireless components are utilized to allow the alarm output to be remotely located in another physical location rather than the plumbing fixture being monitored. For example, many wireless alarm devices exist for use in remote control, home alarm circuits, outdoor indicators or other devices commonly available to the public which would allow the alarm condition generated by the invention to be transmitted remotely, a short distance, to a receiver located in a more convenient location for the user of the device. Short range devices are used which are employed from anything such as baby monitors, garage door open condition indicators, mailbox mail delivery indicators and other simple consumer-type devices could easily be employed with the plumbing fixture to be communicated to another location in the building at the discretion of the user. Indeed, in a commercial installation such as an apartment rental, office building or the like, management of the premises may wish to have such an alarm condition communicated to them remotely via an internet connection or some other communication system possibly wired to a variety of similar detectors in a bank of plumbing fixtures such as may be found in a large building restroom or the like. [0040]
Although particular embodiments of the invention have been described and illustrated herein, it is recognized that modifications and variations may readily occur to those skilled in the art. It is intended that the claims presented herewith be interpreted to cover such modifications and equivalents. [0041]

Claims

What is claimed is:

1. A leak detection apparatus for use in plumbing fixtures and devices which include an inlet fluid valve for fluid flow to occur comprising:

a detector circuit to detect the flow of fluid,

a timer circuit operatively connected to said detector which detects that the fluid flow duration is outside of a predetermined duration, and

an alarm circuit operatively connected to said timer circuit which sounds an alarm in response to the timer circuit detection state.

2. The leak detection apparatus of claim 1 further including a valve operatively connected to the alarm circuit whereby the valve closes to cause fluid flow to the said plumbing fixture to cease upon detection of an alarm condition.

3. A leak detection apparatus for use in plumbing fixtures and devices which include an inlet fluid valve for fluid flow to occur comprising:

a detector circuit to detect the flow of a fluid,

a timer circuit operatively connected to said fluid flow detector which detects that the fluid flow duration is outside of a predetermined window of duration,

a valve operatively connected to said timer circuit which closes to cause the fluid flow to the device to cease in reaction to the state of the timer circuit.

4. The leak detection apparatus of claim 1 whereby further a moisture sensor is placed on or about the floor of the said plumbing fixture to detect the presence of fluid on such surface, wherein said-moisture sensor is operatively connected to the alarm's circuit to activate the alarm in the event that fluid is detected on the fixture support surface.

5. A method of limiting fluid overuse in a plumbing fixture comprising the steps of detecting the fixture's fluid flow duration during a operating cycle;

measuring the duration of said fluid flow;

comparing said fluid flow duration against a preestablished flow duration range; and

causing an alarm condition if said fluid flow duration is outside of the preestablished flow duration range.

6. The method of claim 5 above further including the step of activating a fluid valve to terminate the flow of fluid into the fixture upon an alarm condition.