20 Great Facts For Choosing Pool Cleaning Robots

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Top 10 Pool Cleaning Suggestions That Are Based On Specific Features Of The Pool
Inquiring deeper into the specifics of your pool is the most crucial decision in choosing the best robotic pool cleaner. It is important to match the capabilities of the robot to your pool. A robot is a costly investment. These are the important aspects to consider, as they could result in a less efficient cleaning process, damage to the pool or machine, and even buyer's regret. This complete guide lists the top 10 specs you should be aware of before buying a pool.
1. Primary Surface Material
It's the most important aspect. The surface of your swimming pool will determine what type and size of brushing mechanism that your robot will require to efficiently remove dirt without causing harm.
Concrete/Gunite/Plaster (including Pebble Tec & Quartz): These are rough, durable surfaces that often develop algae films. Robots with stiff, nylon-coated bristle brushes can be used to aggressively clean or scour surfaces order to eliminate biofilm and dirt.
Vinyl Liner: Vinyl is a relatively soft and flexible material that is easily punctured or scratched. Vinyl-based robots should have wheels without sharp edges and soft nonabrasive (normally vinyl or rubber) brushes. Using a cleaner with stiff brushes meant for concrete can cause premature wear or tear to the liner.
Fiberglass Fiberglass shells come with a smooth finish with an elastomer coating. They can also be damaged by abrasive substances. The best robots are those that have brushless rollers or brushes made of soft rubber. A robot that can clean more effectively with less power and on the surface that is smooth will often perform the task.

2. Pool Size and Complexity
The shape of your swimming pool determines directly the needed navigation intelligence and cable length.
Freeform or rectangular What is the best choice? A rectangular pool is most straightforward to keep in good condition. The majority of basic robots can handle it sufficiently. Kidney-shaped, freeform or L-shaped pools have curves and coves that could catch simpler robots, or be missed entirely. It is best to choose an advanced robot with navigation algorithms (gyroscopic and smart-sensing).
Ledges and Coves: The space that is a transition between the pool wall and the floor (the cove) is where the debris tends to accumulate. Check that the robot is designed to wash this curved surface. If your pool is large with flat ledges or sun shelves, (Baja shelf) Make sure that the robot is able climb on them and clean. Some models were created for walls and floors.

3. Dimensions of a Pool (Lengths widths, lengths, and maximum depths)
These measurements are not negotiable when choosing a model that has an adequate power cable.
Cable Length. The robot cable must be at least 60 feet. This is the norm for medium to large pools. The majority of pools have 60-foot cable. You should measure your pool to determine its longest length.
Depth Capability. Modern robotics are able to clean as deep as 8-10 ft. In the event that you have a deep end exceeding 10 feet (e.g. diving pool) It is important to determine what robots are able to clean. Infringing on this limit could cause damage to the motor of the pump, and may void your warranty.

4. Water Level and Tile/Coping Information:
The importance of cleaning is in the area of interface between pool structure and water.
Waterline Tile Cleaning The Waterline Tile Cleansing feature is an essential feature that robots with mid-to-high-end. You need a machine with exceptional waterline cleaning capabilities when there is a persistent buildup of dirt on your tiles, glass or even stone close to the waterline. It is usually a combination of a modified climbing pattern, and specially designed brushing at the highest point.
Type of coping: The substance which is used to cover the pool's wall (coping) could be composed of pavers, concrete stones, concrete, etc. If it has a sharp and strong overhang, it could possibly snag or damage the cable of the robot in time. This is important to remember when the routing of your cable.

5. There are a variety of elements and obstacles within the swimming pool.
It is easier to maintain a pool which is free of debris than one that is cluttered with dangers.
The main drains and vents must be flush with the surface of the pool. They should also be securely fastened. Vents that are older and protruding can trap small robots. The majority of floor water return vents do not pose any problems.
Steps, ladders, and Built-in Seating: These elements can disrupt the robot's pattern of cleaning. Ladders placed on the floor can hinder the robot. Steps and benches require a robot with sufficient power and traction to climb them and clean them. Simple random navigation robots can be unable to navigate these areas, whereas smarter models should handle them.
These large flat surfaces should be kept clean, since they are akin to steps. Make sure that the robot can efficiently traverse the horizontal surface.

6. Points of Entry and Exit (for Robot)
Think about the practicalities involved in getting the robot in and out of the water.
Physical Access: Are you required to lift the robot up a flight of steps, over a deck and then lower it down? The weight of the robot becomes an important factor. A 25-pounder robot is much more manageable on a week-to-week basis than a 40 pounder. A storage caddy is almost necessary in this situation.
There are robotics specifically designed for above-ground swimming pools. They're not as common, but they're still accessible. These machines are light, and aren't designed to climb walls. They're built specifically for the ground and lower parts of walls.

7. What kind of debris do you have?
What features you'll need depend on the main "job" that your robot will be required to complete.
If this is a serious issue, a solution to filtration is vital. The robot needs to be equipped with and able to use ultra-fine cartridges like pleated paper or very tight-woven mesh so that it can effectively filter out microscopic particles.
Leaves, Twigs, and Acorns: To handle larger debris, you'll need a robot that has a large debris canister or bag, a powerful suction pump and an intake system that isn't likely to clog. Some models have impellers designed to crush larger leaves in order to avoid clogging.

8. Location of the outlets and power sources
Robotic cleaners run on low-voltage DC power that is that is supplied by a transformer plug-in.
GFCI Outlet Mandatory For safety reasons, power supply cables must be plugged into an Interrupter Ground Fault Outlet (GFCI). This requirement is not negotiable. An electrician is required to install it if not already there.
Distance from Pool The transformer should be located at least 10 feet from the edge of the pool to protect it from rain and water splashes. Be sure that the cable has enough length to reach from this point to the farthest point in your pool.

9. Local Climate and the Storage Environment
The life expectancy of the robot is dependent on the way it is kept.
Storage outside of season Manufacturers explicitly warn against keeping robots underwater or under direct sunlight for prolonged periods. UV rays can damage cables and plastics. It is essential to have a cool, dry, shaded place (like sheds or garages) to store the cable and robot during non-use for extended periods of time.
In-Season Use: If regularly use the robot the storage caddy will allow you to keep it neatly beside the pool, without the cord becoming a mess on the deck.

10. Current Pool Circulation and Filtration:
The robot isn't independent however, it is a part in the pool ecosystem.
Complementary Function - Understand that the main function of the robot is to clean debris off surfaces and to remove any accumulation of dirt. It's not meant to replace your pool's primary circulation and filtration system, that is responsible for removing dissolving particles, distributing chemicals, and keeping algae out. The robot's purpose is to ease the burden on your primary filter.
Chemical Balance - Even a clean pool's surface may be infested with algae if the chemical balance is out of equilibrium. The robot can help maintain the cleanliness of your pool, but it will not replace proper sanitization, or water balance. View the top rated conseils pour le nettoyage de la piscine for more advice including cheap swimming pools, cleaning robot for pool, waterline pool, a swimming pool, swimming pool sweeper, swimming pool cleaning schedule, max pools, pool cleaners, in the swimming pool, robot for the pool and more.



Top 10 Tips To Improve The Efficiency Of Energy Used By Robotic Pool Cleaners
The efficiency of energy and energy sources of robotic cleaners are important to take into consideration when selecting one. They'll directly affect your operating costs over the long term, and also their environmental impact. In contrast to older suction or pressure side cleaners, which heavily rely on your pool's powerful main pump which is a massive energy hog, robotic cleaners have their own self-contained system. They operate in a separate manner, using their motors, which are low-voltage and high-efficiency. This is the fundamental source of their greatest advantage: enormous energy savings. Each robot is not in the same way. Inquiring into the specifics of their energy consumption, operational modes, and necessary infrastructure, you can select a model that maximizes performance while minimizing its draw on the electricity in your home, transforming the luxury of a convenience into a smart and cost-effective investment.
1. The Key Advantage: Independent Operation at Low Voltage.
The core concept is this. Robotic cleaners have their own motor and pump onboard, powered by a transformer connected to an ordinary GFCI plug. It typically operates on low-voltage DC (e.g., 24V 32V) that is more reliable and safer as compared to running a 1.5 to 2.5 HP main pool pump for several hours every day. This independence allows you to run the robot without having to run the energy-intensive main pump.

2. Watts Vs. Horsepower.
It is essential to comprehend how much you can save. A typical swimming pool's primary pump consumes between 1,500-2,500 watts of electricity per hour. A robotic pool cleaning system that is of top quality however, uses between $150 and 300 watts every hour. This is a reduction in energy usage of approximately 90 percent. The energy needed to power a robot over three hours is the same as running a number of lightbulbs in your home at the same time. This is in contrast to the main pump, which uses the same energy as an appliance.

3. What is the essential role of a DC power supply/transformer?
The black box that is between your outlet and the robot's cables is not just a power cord, it's an intelligent transformer. The transformer converts household 110/120V AC current into DC power that the robot is able to use. The safety of the robot as well as its performance depend on this part. It also houses the circuitry needed to regulate the programming cycle.

4. Smart Programming for Better Productivity.
The programming of the robot directly affects its energy consumption. It's efficient to be able to pick the appropriate cleaning cycles.
Quick Clean/Floors-Only Mode: In this mode the robot runs for shorter periods of time (e.g. around 1 hour), with the algorithm solely cleaning the floors. This mode consumes less energy than a full cycle.
Full Clean Mode Full Clean Mode: Standard 2.5 to 3 hours cycle to ensure thorough cleaning.
To ensure that you do not waste energy, you should only use the power that is needed to complete the task.

5. The Impact of Navigation on Energy Consumption.
The path of a robotic cleaner is closely linked to its power consumption. The navigation of a robot that is erratic and "bump-and turn" is not efficient. It could take at least four hours to clean the pool in a random manner, consuming more energy. A robot with systematic, gyroscopically-guided navigation cleans the pool in a methodical grid pattern, completing the job in a shorter, predictable timeframe (e.g., 2.5 hours), thereby using less total energy.

6. GFCI Outlet Placement and Requirement.
To ensure total security, you must connect the electrical supply of your robot into a Ground Fault Circuit Interrupter. They are usually found in the bathrooms and kitchens. A licensed electrician will need to install an GFCI before you are able to use the cleaner, if the pool isn't equipped with one. The transformer should be placed at least 10 feet away from the edge of the pool to shield it from water splash as well as the elements.

7. The length of the cable and the drop in voltage
The power that travels through the cable at low voltage could suffer a "voltage drop" when it is stretched over a long distance. Manufacturers set a limit to the length of cable (usually 50-60 feet). If you exceed this limit, it could cause the robot to be ineffective, move slowly or even have less capacity to climb. Make sure the cable of your robot is adequate to extend your pool's furthest distance from the outlet however, do not use extension cords, as they exacerbate voltage drops and can be a safety hazard.

8. Comparing Efficiency to other types of cleaners.
To truly justify the initial cost be aware of the things you're comparing it with.
Suction Side Cleaners: These depend on the pump that is used for. They require that you run the large pumps for 6-8 hour a day. This can result in heavy energy use.
Pressure-Side Cleaners : These cleaners use your main motor to create pressure. They also have another booster pump, which can add up to 1.5 HP.
It's cost-effective to purchase robotics due to their high efficiency.

9. Calculating Operating Costs
You can estimate how much it would cost to operate an automated. The formula to calculate costs is (Watts/1000 hours) x Electricity Cost ($ perkWh)
Example: A robot with 200 watts that is used for 3 hours three times per week in which electricity costs $0.15 per kWh.
(200W / 1000) = 0.2 kW. 0.2 kW x 9 hours/week equals 1.8 kWh. 1.8kWh * $0.15 = $0.27/week or $14/year.

10. Energy Efficiency as a metric of Quality
In general motors that are more sophisticated and efficient correlate with higher-quality products. A machine that is proficient in cleaning effectively in a shorter period of time and using less power demonstrates higher quality engineering, a superior navigation system and an efficient yet powerful pump system. Although a motor with a higher wattage might suggest greater power for climbing and suction, it's the combination of efficient cleaning in a short low-wattage time frame that defines real efficiency. A well-designed and well-designed model will pay off in your monthly bill for years. Check out the top swimming pool robot cleaner for blog tips including pool cleanliness, pools pro, smart swimming pool, robotic cleaners for above ground pools, swimming pool cleaning schedule, swimming pool service companies near me, robotic pool cleaner, swimming pool, swimming pools stores, pool automatic vacuum and more.