This application claims priority to Australian Provisional Application No. 2013900156 filed Jan. 18, 2013, entitled “HEIGHT ADJUSTABLE CANOPY SYSTEM,” and to Australian Application No. 2013201035 filed Feb. 22, 2013, entitled “HEIGHT ADJUSTABLE CANOPY SYSTEM,” which claimed priority to AU 2013900156, the disclosures of which are incorporated fully by reference.
The present invention relates to canopies which can be used to cover or shelter a swimming pool.
Pool covers are required for outdoor swimming pools for a number of purposes when the pool is not in use. A pool cover is ideally required to cover the surface area of the pool to act as a barrier to prevent the ingress of debris, such as leaves, entering the pool in order to maintain the pool in a clean state. Furthermore, the cover acts to hinder or reduce the effects of water evaporation so as to maintain a reasonable volume of water within the pool.
Typical pool covers are formed of flat sheet material which extends across the surface of the pool. However, over time, debris falling on the cover tends to weigh down on the cover, causing the cover to bow under the weight. This bowing can cause the edges of the cover to expose the perimeters of the pool and negate the cover's effectiveness. Similarly, the bowing can cause the accumulated debris to gather in the centre of the cover which is not easily removed without removing the entire cover from the pool.
It is a primary object of the present invention to provide a multi-purpose swimming pool canopy system which can be employed as a useful pool cover.
According to a first aspect of the present invention there is provided a swimming pool canopy system, the system comprising:
a canopy frame sized so as to be capable of at least substantially covering the swimming pool;
a number of vertical support posts arranged around the swimming pool, wherein the base of each vertical support post is securely arranged in a respective subterranean cavity surrounding said swimming pool;
a number of electric motors, each electric motor arranged to drive an associated actuator arrangement engaging a corresponding one of said support posts, wherein each electric motor and associated actuator arrangement is attached to said canopy frame; and
a controller which controls each of said motors to drive the associated actuator arrangement, whereby the engagement of each associated actuator arrangement with each corresponding support post, causes the canopy frame to be raised or lowered between a maximum and minimum height above ground level.
The system according to the first aspect advantageously provides a fairly self-contained system which, aside from meeting the previously stated objective, facilitates ease of installation even when retrofitted to an existing swimming pool structure.
According to a further aspect of the present invention there is provided a swimming pool canopy system, the system comprising:
a canopy frame sized so as to be capable of at least substantially covering the swimming pool;
a number of vertical support posts arranged around the swimming pool, wherein the base of each vertical support post is securely arranged within a respective subterranean cavity surrounding said swimming pool;
a number of electric motors, each electric motor arranged to drive an associated actuator arrangement engaging a corresponding one of said support posts; and
a controller which controls each of said motors to drive the associated actuator arrangement, whereby the engagement of each associated actuator arrangement with each corresponding support post, causes the canopy frame to be raised or lowered between a maximum and minimum height above ground level;
wherein the system comprises a self-contained electrical power supply and electrical power circuitry, thereby removing any need to provide any connection to an external power source.
The system according to the second aspect provides advantages in being electrically self-contained. Consequently, in respect of installation, excavation to provide mains power supply is avoided and simplifies retrofitting to existing swimming pool structures.
Preferred embodiments of the invention will now be described with reference to the accompanying drawings, in which:
The present invention will be principally described with reference to particular illustrative examples. It will be understood that the principles of the present invention may be implemented using variations of features on the particular implementations illustrated and described.
In the context of the following description, a canopy system 10 is described which can be raised and lowered in height about an underlying swimming pool structure 12. In the fully raised height (see
A common feature of the following preferred embodiments is a canopy frame 16 formed of rigid interconnected members. The frame 16 can be formed of stainless steel, aluminium or other weather-durable materials. The frame 16 could have a pitched-roof structure, as illustrated, or conceivably be a flat platform. The frame 16 comprises cover material 18 which could be a variety of materials, comprising a canvass sheet material, PVC panels, or (especially in the case of a platform concept) wooden panels capable of providing a sturdy surface.
Referring to
In
The system 10 comprises a control box 22 affixed to the canopy frame 16. The control box 22 houses a power supply, typically a rechargeable battery, for powering the motor assemblies 20, and comprises a processor for sending and receiving control signals to/from the motors 20. Cables 24 for providing data and power between the controller 22 and the motors 20 is self-contained within the canopy system 10. Hence, in the case of installing the system 10, no external power supply is required, which simplifies the installation and means the need for additional cabling for mains supply, which would require disruptive excavation, is removed.
As shown, the canopy 14 could be provided with solar panels 26 which can recharge the rechargeable battery.
In
In this first embodiment, the posts 18 can be made removable when the canopy frame 16 is at the fully lowered position. As shown in
Each motor assembly 20 is enclosed in a motor housing 52, which is attached to the canopy frame 16, see
The motor 60 is a DC motor. The motor 60 shown can be between 100-130 W, having a worm drive and two-stage gear box with a gear ratio of 300:1. The motor 60 drives an actuator in the form of a cogged wheel 62. The cogged wheel 62 engages a slot 64 arranged along the height of the vertical support post 18. The slot 64 comprises a track with evenly spaced holes, in which the teeth of the cogged wheel 62 engage, see
As will be appreciated, controlling the direction of the motor 60 causes the cogged wheel 62 to turn and the engagement of the teeth with the track in the post 18 causes the canopy frame 16 to raise or lower, depending upon the direction in which the motor 60 is driven.
The motor assembly 22 is spring biased by a spring 70 so that the cogged wheel 62 is maintained in engagement with the post's track. A lever arrangement 72, in contact with the motor assembly 22 with abutting angled portions 74, allows the motor assembly 22 to be moved against the spring bias and cause the cogged wheel 62 to be manually disengaged from the post's track (see
In an alternative embodiment, the vertical posts 100 could be arranged as a number of telescopic members. Hence the raising and lowering of the canopy frame 16 is caused by the telescopic arrangement of the posts 100. Referring to
The system 10 can be designed to comprise a variety of additional features to improve safety aspects. As shown, the system 10 can comprise an anemometer 28 so that wind conditions can be monitored. The controller 22 can be programmed so that, when the anemometer 28 detects a wind condition in excess of a predetermined safe threshold, the controller 22 causes the motors 20 to drive the canopy frame 16 to the minimum height.
While the speed in which the motors 20 can raise or lower the canopy frame 16 is open to design choice, for safety reasons, it is preferred that, for at least during lowering, the speed is fairly slow and could take about a minute to go from full height to ground height.
In ideal embodiments, the controller 22 can respond to signals from a wireless remote control unit. In this regard, however, it may be prudent if, when lowering, that the control be manually entered adjacent the system 10 and, preferably, on the control box 22 itself. In this way, a user can be able to visually inspect the pool 12 to ensure that the pool 12 is clear of any persons before the canopy 14 is at its lowest height and fully covers the pool 12. In other words, ensuring that no-one is trapped under the lowered cover 14. In this regard, the controller 22 may be programmed so that, when remotely controlled, it lowers only to a select height (for example, 0.6 m above minimum height) and requires a manual entry on the control box 22 itself before lowering all the way to minimum height.
A further safety feature may be the detection of objects in the path of the lowering canopy frame 16. In this regard, each motor assembly 20 may be designed to detect progress of movement. In the case of any motor assembly 20 detecting movement being hindered, the controller 22 can stop all motors 20. Ideally, in this circumstance, the controller 22 would direct that all motors 20 reverse direction (for example by 0.2 m) and then stop, to allow any obstacles blocking the lowering of the canopy frame 16 to be removed.
A further feature may be the automatic lowering of the canopy frame 16 upon detecting that the pool 12 is not in use for a period of time. In this regard, the controller may be in communication with sensors associated with the pool, for example motion sensors and heat sensors, which can detect the presence of persons in the pool.
Number | Date | Country | Kind |
---|---|---|---|
2013900156 | Jan 2013 | AU | national |
2013201035 | Feb 2013 | AU | national |