METHODS, SYSTEMS, AND DEVICES FOR PROVIDING COMMUNICATIONS CAPABILITIES TO EQUIPMENT OF SWIMMING POOLS AND SPAS

Abstract

Communications capabilities are supplied to components of pool water recirculation systems, even if the components lack electrical power or supply wires. Capabilities may be furnished by wireless RF devices that connect to existing fittings or ports of the components, for example. The devices are configured to obtain desired information relating to the components (or the water within them) and transmit the information remotely for processing or consideration.

Claims

1. A method of controlling pool equipment of a water circulation system of a pool or spa, the method comprising: a. measuring a first pressure at a first location of water flowing along a water flow path of the water circulation system; b. measuring a second pressure at a second location of water flowing along the water flow path of the water circulation system; c. receiving additional non-pressure data about the water circulation system; d. evaluating the first pressure, the second pressure, and the additional non-pressure data to determine a characteristic of the water circulation system; and e. generating an output response based on the determined characteristic of the water circulation system, wherein the output response comprises transmitting a communication signal with the determined characteristic of the water circulation system to a device remote from the water circulation system.

2. The method of claim 1, wherein the characteristic of the water circulation system comprises a water flow rate.

3. The method of claim 1, wherein the characteristic of the water circulation system comprises energy usage.

4. The method of claim 1, wherein the communication signal comprises a light-based communication signal.

5. The method of claim 1, wherein the communication signal is a wireless communication signal.

6. The method of claim 1, wherein the communication signal further comprises information identifying the first location in the water circulation system, the second location in the water circulation system, or both the first location and the second location in the water circulation system.

7. The method of claim 1, wherein the communication signal further comprises self-identifying information about at least one piece of pool equipment.

8. The method of claim 1, wherein the non-pressure data comprises at least one of of water turbidity, a chemical characteristic of the water, a water temperature, a water flow rate, a number of on/off cycles, or a run time of the water circulation system.

9. The method of claim 1, wherein the characteristic of the water circulation system comprises a performance of a piece of pool equipment over time.

10. The method of claim 1, further comprising mechanically connecting a sensor to a piece of equipment lacking electrical power or supply wires, the sensor measuring the first pressure, the second pressure, or both the first pressure and the second pressure.

11. The method of claim 1, wherein the communication signal further comprises a suggested operational adjustment based on the determined characteristic of the water circulation system.

12. The method of claim 1, wherein generating the output response further comprises adjusting operation of a piece of equipment of the water circulation system based on the determined characteristic of the water circulation system.

13. A water circulation system of a pool or spa, the water circulation system comprising: a. at least one first sensor for measuring a first pressure at a first location of water flowing along a water flow path of the water circulation system and a second pressure at a second location of water flowing along the water flow path of the water circulation system; and b. at least one second sensor for measuring non-pressure data about the water circulation system, c. wherein the water circulation system is configured to: i. evaluate the first pressure, the second pressure, and the additional non-pressure data to determine a characteristic of the water circulation system, and ii. generate an output response based on the determined characteristic of the water circulation system, wherein the output response comprises at least a communication signal with the determined characteristic of the water circulation system to a device remote from the water circulation system.

14. The water circulation system of claim 12, further comprising at least one piece of equipment without electrical power or supply wires, wherein the at least one first sensor is mechanically connected to the at least one piece of equipment.

15. The water circulation system of claim 12, wherein the communication signal comprises a light-based communication signal.

16. The water circulation system of claim 12, wherein the communication signal comprises a wireless communication signal.

17. The water circulation system of claim 12, wherein the non-pressure data comprises at least one of water turbidity, a chemical characteristic of the water, a water temperature, a water flow rate, a number of on/off cycles, or a run time of the water circulation system.

18. The water circulation system of claim 12, wherein the communication signal further comprises a suggested operational adjustment based on the determined characteristic of the water circulation system.

19. The water circulation system of claim 12, wherein the at least one first sensor comprises a plurality of first sensors.

20. The water circulation system of claim 12, wherein the at least one first sensor comprises a transmitter for wireless communication.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] FIG. 1 is a perspective view of a pump useful as part of a pool water recirculation system with exemplary devices of the present invention connected to its drainage ports.

[0018] FIG. 2 is a perspective view of a portion of the pump, and a partly-exploded view of the exemplary devices, of FIG. 1.

[0019] FIG. 3 is a perspective view of a portion of a filter useful as part of a pool water recirculation system together with an exemplary device of the present invention incorporated into a filter-loading gauge.

[0020] FIG. 4 is a perspective view of the portion of the filter of FIG. 3 with the exemplary device of that figure connected thereto.

DETAILED DESCRIPTION

[0021] Depicted in FIGS. 1-2 is a pump P useful in a water-recirculation system. Pump P may be conventional, as the present invention is especially adapted for retrofitting existing components with communications capabilities. Pump P need not be conventional, however, as the present invention is not limited to use with existing products or even with pumps.

[0022] The conventional pump P of FIGS. 1-2 includes inlet 10 and outlet 14. Included within pump P may be such things as a strainer basket, an impeller, and a motor. In use, the motor turns the impeller, drawing water through inlet 10, the strainer basket, and the impeller before exiting via outlet 14. The water-flow path between inlet 10 and the impeller is typically called the “vacuum side” of pump P, whereas the path between the impeller and outlet 14 is frequently referred to as the “pressure side” of the pump P.

[0023] Conventionally, pump P includes drainage ports 18 and 22 on its “wet end.” Port 18 is present on the “vacuum side” of the pump P, whereas port 22 is in the “pressure side” path of water within the pump P. When pump P is not in use, port 18 may be used to drain water that has passed through inlet 10 and the strainer basket but not yet entered the impeller. By contrast, port 22 may be employed to drain water that has passed through the impeller but not yet exited outlet 14. Ports 18 and 22 traditionally are threaded so as to receive threaded plugs, with the plugs configured to seal the ports 18 and 22 (at least) when pump P is in use. For drainage, the plugs simply may be unscrewed so as to expose the ports 18 and 22.

[0024] As the strainer basket fills with debris, the vacuum pressure (i.e. the reduction in pressure below ambient) increases in the region between the strainer basket and the impeller. Hence, measuring vacuum pressure in this region as a function of time may be beneficial. Because port 18 already exists in this region, configuring a vacuum-pressure probe to fit in the port 18 likewise would be beneficial.

[0025] Similarly, obtaining pressure measurements over time on the “pressure side” of pump P may be advantageous. Together with the vacuum pressure measurements and, perhaps, other data (e.g. motor speed), various important characteristics of the water-recirculation system may be calculated, deduced, or otherwise determined. As (non-limiting) examples, system characteristics such as water-flow rate and energy usage could be determined.

[0026] Illustrated in FIGS. 1-2 are devices 26A and 26B consistent with the present invention. Devices 26A and 26B are configured to fit within ports 18 and 22, respectively, replacing conventional drain plugs. In the exemplary versions shown, therefore, devices 26A and 26B are threaded, may be used together with washers, gaskets, or o-rings 30 if desired to facilitate sealing of the ports 18 and 22, and have at least portions of their bodies positioned externally of pump P. Devices 26A and 26B need not be threaded or shaped, configured, or positioned as depicted, however, as will be apparent to persons skilled in the relevant art.

[0027] Unlike conventional drain plugs, devices 26A and 26B include sensors and, preferably, wireless RF transmitters. Alternatively, one or both of devices 26A and 26B could communicate via wire or other medium either remotely or one to the other or use other carrier means such as laser, ultrasonic, sonic, infrared, ultraviolet, or optics signals. In some cases either or both of devices 26A and 26B could include wireless or wired receivers as well.

[0028] In presently-preferred versions of the invention, devices 26A and 26B include pressure gauges so as to sense and measure pressures at ports 18 and 22. The gauges may be transducers so as to convert mechanical energy to electrical energy. Transmitters within devices 26A and 26B transmit the pressures, preferably doing so either continuously or periodically over a predetermined or determinable interval of time. Each of the gauges and transmitters may itself be conventional as long as it is capable of functioning adequately within device 26A or 26B. The devices 26A and 26B further may if desired be low-power digital devices including batteries or other power sources.

[0029] Devices 26A and 26B may be part of a network of devices, including similar devices deployed in fittings or ports of (or otherwise in connection with) other components of water-recirculation systems. If desired they may transmit (and, possibly, receive) wirelessly consistent with ZigBee, ZWave, or other common communications protocols. Preferably (although not necessarily), signals originating with one or both of devices 26A and 26B eventually are conveyed via the Internet for processing or consideration at a remote location. For example, information obtained using one or more of devices 26A and 26B could be forwarded to a smart phone, laptop, desktop, tablet computer, or other equipment of a homeowner or pool servicer for processing or consideration. Alternatively, the information may be conveyed directly (either wirelessly or via wire) to an on-board pump controller or other component.

[0030] If device 26A senses a rapid rise in vacuum (i.e. a rapid pressure decrease), for example, the strainer basket may be clogged with debris, inhibiting adequate water flow to the impeller. A decision to withdraw power from the motor of pump P may thus be made automatically or manually, remotely or nearby, based at least in part on information obtained from device 26A. Information from devices 26A and 26B additionally could be used to help determine flow rates of water through pump P as a function of time, energy usage of the pump P, and dynamic head of water to be pumped by pump P, etc., for conveyance to a homeowner, servicer, manufacturer, or otherwise via the Internet or otherwise.

[0031] As noted earlier, devices identical or similar to devices 26A or 26B may be used in connection with other pool or spa equipment. FIGS. 3-4 depict such usage in connection with filter F. The filter F may have port 34 into which conventionally a gauge is placed to indicate loading of the filter with debris over time. However, with the present invention, gauge 38 may include a transmitter as well as a debris-loading sensor. As with preferred versions of devices 26A and 26B, preferred embodiments of gauge 38 include low-powered devices with wireless RF transmitters configured for networking using any suitable communications protocol. Indeed, devices 26A and 26B and gauge 38 advantageously may form part of the same network when used in the same water-recirculation system. If any of devices 26A or 26B or gauge 38 includes a processor, information even may be conveyed among the devices and gauge themselves.

[0032] The foregoing is provided for purposes of illustrating, explaining, and describing embodiments of the present invention. Modifications and adaptations to these embodiments will be apparent to those skilled in the art and may be made without departing from the scope or spirit of the invention. For example, devices of the invention may sense information such as (but not limited to) temperature, flow, salinity, pH, ORP, FAC, turbidity, level, motion, gas trap characteristics, etc. Moreover, “pool,” “swimming pool,” and their plurals may include within their definitions spas and other water-containing vessels used for recreational or therapeutic bathing or swimming. The entire contents of the Uy and Stiles, Jr. patent applications are incorporated herein by this reference.