US20010047539A1

US20010047539A1 - Method and apparatus to either heat or cool a pool

Info

Publication number: US20010047539A1
Application number: US09/526,454
Authority: US
Inventors: John Lynn
Original assignee: Individual
Current assignee: Individual
Priority date: 2000-03-16
Filing date: 2000-03-16
Publication date: 2001-12-06
Also published as: US20010029625A1

Abstract

A method for adjusting the temperature of a swimming pool having a filter system and a waterfall, comprising running the filter system at times of the day such that heat transfer with ambient air is optimized by the action of swimming pool water falling through the ambient air, and further comprising positioning and substantially fixing the position of a movable surface below the water fall to help maximize the heat transfer with the ambient air. For pools without waterfalls, it is further disclosed to utilize a conduit from a submerged water return opening to the movable surface which could be a raft.

Description

BACKGROUND OF THE INVENTION FIELD OF THE INVENTION

The present invention relates to a method and an apparatus which is helpful in the cost efficient cooling and heating of swimming pools using ambient air temperature.

CROSS REFERENCE TO RELATED APPLICATIONS

Not applicable

BACKGROUND OF THE INVENTION

For many years there has been the problem of heating swimming pools during cool weather and cooling down swimming pools in hot climates during hot weather. The problem of heating swimming pools during cool weather can be addressed by any of a number of different well know methods such as passing the pool water through a pool heater (i.e., gas, propane or electric heat exchanger). This passing of the pool water through the heat exchanger normally occurs during the filtration process. The problems with this well known method of heating pool water are the upfront expense of the pool heater, the space requirements for the heater and perhaps most significantly, the very high energy cost of running the pool heater. An additional method of heating pool water is to use solar heat in the heat exchanger rather than fossil fuels or electricity. Examples of patents using solar heat exchangers are set forth in U.S. Pat. No. 4,261,332 entitled “Solar Heating Systems” and U.S. Pat. No. 4,256,087 entitled “Swimming Pool Heater”. These solar heat exchange systems have, inter alia, the disadvantages of high upfront costs and space requirements.

There have been fewer prior art inventions relating to cooling a swimming pool which is too warm. Nevertheless, this is a real problem in the summertime in hot climates. Often pools become so warm (above the 90+ degree Fahrenheit) that pool use is not as refreshing as in a cooler pool. U.S. Pat. No. 4,189,791 entitled “Swimming Pool Heating and Cooling System” describes a system using air pumps and temperature controllers to control the temperature of the pool using ambient air pumped into pipes located in the pool which act as a heat exchanger. Once again this invention has, inter alia, the problems high up front costs and space requirements. U.S. Pat. No. 3, 941,154 entitled “Swimming Pool Water Circulation System” describes a water circulation system which contains fountains at the water level which can be pointed into the air in order to cool the water being recirculated into the pool. The disadvantages of such a system are the upfront capital costs and the need to retrofit old pools.

What is needed is a simple method to cool or heat a pool. The method should be inexpensive to operate and require no retrofitting of the pool so that the upfront costs are minimized. All the prior art methods either are expensive to operate because of energy costs or expensive to install because of equipment needs or both.

SUMMARY OF THE INVENTION

Accordingly, it is the object of this invention to provide a low cost method and apparatus to help in adjusting the temperature of swimming pools.

In furtherance of the objects mentioned above, the present invention provides a method of cooling or heating a swimming pool using existing pool equipment and running the circulation system at times of the day which facilitate either heating or cooling of the pool. For example, running the circulation system at night to cool a pool during hot weather or alternatively running the circulation system during the hot part of the day to heat a pool which is too cool.

This optimized timing of running a pool filter system is simple. To cool the pool, run the filter system during the coolest part of the day (usually late at night). To heat a pool, run the filter system during the hottest part of the day (normally during the afternoon and early evening). Since pool filters must be run some minimum period of time each day in any event, this optimized timing does not have any additional costs. This method works best in pools which have waterfalls (e.g., from the pool spa into the main pool) or in pools which have some other way to have the water fall or run throught the ambient air (e.g., a fountain). The exposure of the pool water to the ambient air rather than being recirculated to the pool under the surface of the water greatly increases the heat exchange between the ambient air and the pool.

However, many pools do not have waterfalls, or if they do have a waterfall, the exposure of the pool water to the ambient air is not maximized because of the relatively limited time period the recirculated water is exposed to the ambient air during its fall into the pool. Accordingly, in a preferred embodiment of the invention an apparatus is provided which is a movable surface which is designed to let the recirculating pool water run over it while being exposed to the ambient air before running or dropping back into the pool. If the pool has only submerged water return openings, then a conduit can be used to channel the recirculated water onto the top of the movable surface and into the ambient air. By changing the size and shape of the movable surface (e.g., a raft) one can maximize the exposure of the recirculating pool water to the ambient air and accordingly maximize the heat transfer between the air and water. By having the movable surface irregularly shaped (e.g., tortuous paths caused by ripples, indentations, pebble shaped bumps, furrows, etc.) One can maximize the amount of time the recirculating water is on the movable surface and accordingly the heat transfer.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a top view of a movable surface situated under a spa waterfall. [0010]
FIG. 2 is a side view of a movable surface and a conduit which forces recirculated water out of a submerged return opening onto the top of the movable surface.[0011]

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 shows [0012] movable surface 11 situated underneath of waterfall 14. (A waterfall for the purpose of this disclosure is any recirculated water entering pool surface 13 from above pool surface 13.) In this embodiment, movable surface 11 has a specific gravity less than that of water (i.e., less dense than water) and is accordingly floating on pool surface 13. In other embodiments of the invention, just a section of movable surface 11 could be floating on pool surface 13 (e.g., a pontoon-like structure). There are many types of pool waterfalls but in the FIG. 1, waterfall 14 is caused by the recirculation of pool water into spa 20 which is at a higher elevation than pool surface 13 and accordingly during recirculation, water being recirculated into spa 20 falls back into pool surface 13 through waterfall 14 (caused by a low point in spa wall 23).
In order to maximize the heat transfer of the pool water falling through waterfall [0013] 14, movable surface 11 has been positioned and substantially fixed in position underneath waterfall 14 (movable surface 11 may move on the surface of the water, but should not float away). Therefore, instead of the recirculated pool water entering the pool immediately after dropping from the spa onto pool surface 13 it continues to be exposed to the ambient air because it falls upon movable surface 11 and is forced to run over its top surface which is exposed to ambient air. In a preferred embodiment of the invention, movable surface 11 has slightly raised side walls 17 which help channel the water from the end of moveable surface 11 situated underneath waterfall 14 to the opposite end of movable surface 11. This channelling of the water along the entire length of movable surface 11 to the discharge end 18 of movable surface 11 maximizes the time the water is on the movable surface 11 which also maximizes the heat exchange between the water and the ambient air.
This channelling of the recirculated pool water along the entire length of [0014] movable surface 11 could also be accomplished by having movable surface 11 slightly slanted downward away from the end of movable surface 11 under waterfall 14 and toward discharge end 18. Another method of assuring that water runs over the entire length of movable surface 11 could be accomplished by having channels or indentations on the upper surface of movable surface 11. Channels 15 near waterfall 14 could be designed to channel the water uniformity across the top of movable surface 11 by having channels 15 in a fan-like shape. The remainder of movable surface 11 could be formed to make a tortuous path (e.g., squiggly lines or a pebble-like contour) which maximizes the amount of time the recirculated pool water stays on movable surface 11. Alternatively, the upper surface of movable surface 11 could be flat or slightly slanted toward discharge end 18. Movable surface 11 in a preferred embodiment of the invention would double as a raft when not in use as a heat transfer surface. In cases where movable surface 11 has channels 15 or tortuous path 16 on the heat transfer side of the raft the opposing side could be smooth and usable as a raft by swimmers. This double-sided or dual purpose raft design would assure ultimate utility and ease of use. In this way, one would not even have to take raft out of the pool during use by swimmers since it doubles as a standard raft and can be used as either a normal flotation device for swimmers or as a heat exchanger.
In order to hold [0015] movable surface 11 in place under waterfall 14 it is necessary to have some manner of an attachment means of device. There are hundreds or thousands of different types of attachment devices well known in the art available to assure that movable surface 11 remains under waterfall 14 (e.g., straps, Velcro®, buckles, magnets, hooks, etc.). In addition, numerous movable surfaces 11 could be attached together to maximize surface area for heat transfer. However, in order to use movable surface 11 interchangeably as a raft for swimmers and in order to mimimize retrofitting of the pool wall or pool deck 21, one preferred embodiment would be to have strap or rope 27 detachably connected to movable surface 11 by means of detachable connection 25 and having the opposite end of rope or strap 27 connected to weight 22. Detachable connection 25 could be any of a number of different detachable connections such as Velcrot, snaps, buckes and so forth. In light of the water environment, Velco® may be a preferred attachment device. Using weight 22 positioned on pool deck 21 such that strap 27 is taunt against movable surface 11 which allows positioning of movable surface 11 essentially anywhere around the perimeter of a pool without any retrofitting of pool deck 21 or the pool walls. Also weight 22 does not have to be very heavy or bulky since there should not be significant lateral forces on movable surface 11 to displace it from underneath waterfall 14.
This preferred attachment method and device has the following two advantages: (1) The attachment device is easily detachable from [0016] movable surface 11 so that it can be alternatively used as a raft when not in use as heat transfer surface, and (2) since it relies on weight 22 to hold the movable surface 11 in place, it requires no retrofitting of pool deck 21 or the walls of the pool.
FIG. 2 sets forth an embodiment of the invention which is preferred when a swimming pool does not have a waterfall in which to place [0017] movable surface 11 underneath. Many pools do not have either waterfalls or spas. The water that is recirculated to the pool after filtering enters the pool through submerged water return openings below pool surface 13. In pool configurations where water return opening 33 is submerged there is a need for a way to get the recirculated water up above pool surface 13 so that it will be able to run over movable surface 11. A preferred method to get the recirculated water onto movable surface 11 is to use conduit 31 (as used herein, conduit 31 can be any kind of pipe or channel which changes the direction of the recirculated water exiting water return opening 33). One end of conduit 31 could abut against pool wall 21 and cover submerged return opening 33 at the end of return pipe 32. The recirculated water in return pipe 32 normally exits into the pool below pool surface 13 through return opening 33. However, because of the presence of conduit 31 and the pressure of the water in return pipe 32, the return water instead travels up through conduit 31 to exit onto movable surface 11. Once on movable surface 11 the water is subject to the heat exchange (either cooling or heating) caused by it's contact with the ambient air.
In a preferred embodiment, [0018] conduit 31 can be attached or detached very simply in order to maximize ease of use. This mobility allows the pool to be used safely without a permanent conduit or pipe protruding into it. In an experiment, conduit 31 consisted of two separate rigid 2″ UL-90° Std. Bend PVC Sch. 40 (issue no. X-33658) conduit from Cantex fitted together with a standard 2″ PVC coupling. When fitted together the two conduits formed “S” shaped pipe approximately 40″ long. One end of this “S” shaped pipe (conduit 31) was abutted against return opening 33 and the other end protruded above pool surface 13 and rested against an end of movable surface 11. The recirculating water pressure in the experiment was such that it exerted an outward pressure (away from pool wall 21) on conduit 31 which had to be counteracted. Counteracting such outward pressure was done by preventing movable surface 11 from moving away from pool wall 21. In the experiment, this was done by manually holding the raft (movable surface 11) in place. Movable surface 11 was about 18-20 inches from pool wall 21 and return opening 33 was about 16-18 inches below pool surface 13. Accordingly, the position of “S” pipe (conduit 31) was such that the water pressure from return opening 33 did not cause the “S” pipe to disengage from either pool wall 21 or movable surface 11. In short, conduit 11 was stuck in between pool wall 21 and movable surface 11 without any need for permanently anchoring conduit 31 to either movable surface 11 or pool wall 21.
Identical with the attachment means set forth in FIG. 1, [0019] movable surface 11 could also be prevented from moving away from pool wall 21 by using detachable strap or rope 27 connected to weight 22. (Unlike in FIG. 1, however, movable surface 11 would probably not abut against pool wall 21 because of the need to accomodate conduit 31.) The position of return opening 33 (i.e., depth below pool surface 13) could necessitate different configurations and/or lengths for conduit 31. One especially preferred method of addressing varying positions of return opening 33 and/or pressure of water exiting return opening 33 is to design conduit 31 so that its length may be easily varied. One method of easily varying the length of conduit 31 is to make conduit 31 “telescoping pipe” by means well known in the art. The varying length of conduit 31 also requires varying the length of rope or strap 27 so that the distance from movable surface 11 and pool wall 21 can be varied as well.
The present invention has been described above with reference to a preferred embodiment. However, those skilled in the art will recognize that changes and modifications may be made in the described embodiments without departing from the nature and scope of the present invention. Various changes and modifications to the embodiment herein chosen for purposes of illustration will readily occur to those skilled in the art. To the extent that such modifications and variatins do not depart from the spirit of the invention, they are intended to be included within the scope thereof which is assessed only by a fair interpretation of the following claims, enable those skilled int he art to understand and practice the same, the invention claimed is: [0020]

Claims

What I claim as my invention is:

1. A method for adjusting the temperature of a swimming pool having a filter system and a waterfall, comprising running the filter system at times of the day such that heat transfer with ambient air is optimized by the action of swimming pool water falling through the ambient air.

2. The method of

claim 1

, comprising positioning and substantially fixing the position of a movable surface below the waterfall to help maximize the heat transfer with the ambient air.

3. The method of

claim 2

, comprising floating the movable surface on the swimming pool.

4. The method of

claim 3

, wherein the moveable surface is a raft.

5. The method of

claim 4

, wherein the raft has an irregular surface designed to maximize the time the swimming pool water remains upon the raft and in contact with the ambient air.

6. The method of

claim 5

, wherein the raft is double sided and wherein one side is designed for use by swimmers and an opposing side is designed for maximum heat transfer.

7. A method for adjusting the temperature of a swimming pool having a surface, a filter system, a perimeter and a submerged water return opening comprising: (1) installing a conduit with a first end and a second end with the first end running from the submergerd water return opening and the second end exiting above the surface of the pool; and (2) positioning a movable surface underneath the second end of the conduit.

8. An apparatus for either heating or cooling a swimming pool having a waterfall and a filter system; comprising a movable surface which can be positioned and substantially fixed in position underneath of the waterfall such that it is possible to optimize heat transfer from ambient air by running the filter system at times of the day designed to either heat or cool recirculating water from the swimming pool.

9. The apparatus of

claim 8

, wherein the movable surface floats in the swimming pool.

10. The apparatus of

claim 9

, wherein the movable surface is a raft.

11. The apparatus of

claim 10

, wherein the raft has an irregular surface designed to optimize the heat transfer.

12. The apparatus of

claim 11

, wherein the raft is dual purpose and can be utilized as either a heat exchanger or a normal flotation device for swimmers.

13. The apparatus of

claim 9

, wherein the movable surface is attachable to other movable surfaces to maximize the surface area for the heat transfer.

14. An apparatus for either heating or cooling a swimming pool having a filter system and a submerged water return opening comprising; (1) a movable surface; and (2) a conduit designed to direct water from the submerged water return opening to the movable surface such that water runs over the movable surface and heat transfer occurs as it comes into contact with ambient air.

15. The apparatus of

claim 14

, wherein the movable surface floats in the swimming pool.

16. The aparatus of

claim 15

, wherein the movable surface is a raft.

17. The apparatus of

claim 16

18. The appartus of

claim 17

, wherein the raft doubles as both a heat exchanger and a normal flotation device for swimmers.

19. The apparatus of

claim 15

20. A method for adjusting the temperature of a swimming pool comprising:

running swimming pool water over a waterfall; and transferring energy between the swimming pool water and the ambient air by impacting the water onto a movable surface wherein the transfer of energy adjusts the pool temperature to a desired state.

21. The method of

claim 20

, wherein the desired state is to lower the temperature of the swimming pool water; the running step further comprising running the water when the ambient air temperature is lower than the swimming pool water temperature.

22. The method of

claim 20

, wherein the desired state is to raise the temperature of the swimming pool water; the running step further comprising running the water when the ambient air temperature is higher than the swimming pool water temperature.