20 Definitive Reasons For Choosing Pool Cleaning Robots

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Top 10 Pool Cleaning Tips That Are Based On Specific Pool Characteristics
Examining the particulars of your pool's characteristics is the most critical aspect in deciding on the ideal robot pool cleaner. A robotic pool cleaner is an enormous investment. Its performance depends on how it's customized to your particular pool. If you don't pay attention to these factors, it could result in a poor cleaning, or even damage to the machine or your pool. It could also lead to the buyer to become frustrated. This complete guide will provide you with 10 most important specifications for your pool that you need to know before buying.
1. Primarily Surface Materials:
This is without doubt the most important aspect. The interior finish of the pool determines what type of brushing mechanism the robot will require to be able to scrub the pool efficiently and without causing damage to it.
Concrete/Gunite/Plaster (including Pebble Tec & Quartz): These are rough, durable surfaces that often develop algae films. Robots are required to clean and scour the surface using bristles that are rigid and coated with vinyl or nylon.
Vinyl Liner Vinyl is a soft, flexible and pliable material that is easily scratched or punctured. Robots made for vinyl should include wheels with no sharp edges and soft nonabrasive (normally rubber or vinyl) brushes. The liner can wear out prematurely or be torn if you use the right cleaner specifically for concrete.
Fiberglass: Fiberglass is a plastic shell that has a the smooth exterior of a gel-coated, smooth surface. Like vinyl, they can be scratched with abrasive materials. Robots with soft rubber brush systems or even roller systems without brushes are ideal. Smooth surfaces also allow robots to clean using less energy and with greater efficiency.

2. Shape and Complexity of the Pool:
The size and shape of your swimming pool determines the length and the type of cable needed.
Rectangular and. freeform: The most efficient method of cleaning a pool is by using the simple rectangle. It can be cleaned by the majority of basic robots that take randomly-routed paths. The curves in kidney-shaped pools, freeform pools, and L-shaped pools can cause robots get stuck or miss them completely. In these cases an automated robot with sophisticated algorithmic (gyroscopic) or intelligent sensing navigation will ensure the swimming pool is fully covered.
Transitions, Coves, and Ledges The transition point from the floor of the pool to the wall (the "cove") is an area where debris may accumulate. Make sure the design of the robot allows it to efficiently clean this curved area. Verify that your robot can remove the huge sun shelves, also known as ledges (Baja shelves) in your pool. Certain models are designed to clean floors and walls.

3. The dimensions of the pool (length, width and the maximum depth) are:
The above measurements are not to be negotiated when choosing the power cable.
Cable Length - The most common principle is that the cable of the robot must be at least as long as your pool's longest dimension (usually the length) with an additional couple of feet to route around the edge and to make sure the power source is in a position that is not too close to the pool's water. It's not uncommon for pools with a large or medium dimensions to have a cable that measures 60 feet. Before buying, you should measure the length of your pool.
Depth Capability The majority of modern robots are able to clean deeps of 8-10 feet without issue. But, if you've got an area that is deeper than 10 feet (e.g. an underwater pool) You must confirm the depth rating of the robot's maximum. Overextending it will strain the pump motor and invalidate the warranty.

4. The Level of Water and the Tile/Coping Details:
It is important to clean the space between the water and the structure of the pool.
Cleaning the waterline tiles is a function that's available on robots in the mid-range to high-end price range. If your tile, stone, or glass exhibits persistent scum at the waterline you should consider a robot that is advertised for its excellent waterline cleaning capabilities. It typically involves a different style of climbing as well as a brush action at its highest point.
The material used to cover the pool walls (coping) is either pavers or stones. If it has an overhang that is sharp or aggressive that could cause a cause damage to the robot's cable with time. This is important to remember when the routing of your cable.

5. In-Pool Obstacles & Features:
Cleaning a clear pool is easier than cleaning a pool with many hazards.
Main Drains/Vents: Make sure that the vents' covers are in line with the floor and are securely secured. Certain older drains with protruding edges could trap small robots. Water return vents on floors generally aren't an issue.
Steps with built-in seats, ladders and steps can interrupt a robot’s pattern of cleaning. Ladders that have legs on the floor can catch the robot. A robot needs to have enough strength and grip to be able to climb and clean the benches and steps. Simple, random navigation robots may stay clear of these areas, but better models will be able to handle them.
Benches and Swimouts: Similar to steps, these vast flat surfaces need to be cleaned. Check if the robot can effectively traverse a horizontal surface.

6. Points of Entry and Exit (for Robot)
Take into consideration the practicalities to get the robot into the water, and then out.
Physical Access. Do you have the robot that needs to be carried down a staircase, across an elevated platform, and finally brought up? If so the weight is a big factor. A robot weighing 25 pounds is easier to handle weekly than a 40-pounder. Storage caddy are almost necessary in this case.
Robots for above-ground swimming pools: Although less common, robots are available that are specifically made for above-ground pools. They are often lighter and built not to scale walls.

7. Debris Types and Volumes
The primary "job" you need the robot to complete will dictate its required features.
If this is the main concern for you, then the filtration system is crucial. It is crucial that your robot comes equipped with ultra-fine filters (pleated papers or meshes that are very fine dimension) and is able to use them effectively to capture tiny dust particles.
Leaves (including twigs) Acorns, leaves, and acorn twigs: In order to handle larger debris, you'll need an automated system that has a large bag or canister for debris and a pump that is powerful enough to get rid of the debris, and a filter that isn't blocked. Certain models with higher-end features include impellers specifically designed to macerate larger leaves to prevent the clogging.

8. The location of the source of power, as well as the type of outlet:
Robotic cleaners utilize low-voltage DC powered by a converter that connects to any outlet that is standard.
GFCI Outlet condition: The power source MUST be plugged directly into an GFCI Outlet for security. This is a must. You will need an electrician to install one should you not possess one.
Distance from Pool The goal is to ensure that the transformer is safe from water splashes and weather conditions, it must be placed at least 10 feet from the pool. Be sure that the cable will reach to the farthest point of your pool from this point.

9. Local Climate and the Storage Environment
The longevity of a robot is contingent on the way it is kept.
Storage in the off-season. Many manufacturers warn against storing your robot under direct sun or under water for long durations. UV rays cause the plastics and cables to degrade. When the robot isn't working for a prolonged period, it should be stored in a shady area, that is cool and dry (like garages).
In-Season Usage: If the robot is frequently used and the storage caddy is used frequently, it allows you to place it neatly next to the pool. This prevents the cord from becoming a mess on the deck.

10. Current pool filtering and circulation:
The eco-system of the pool is where the robot lives.
Additional function: Be aware that the robots' job is to clean up settled dirt and to clean the surface. It's not meant to replace your pool's primary filtration and circulation system, which is responsible for filtering dissolved particles, distributing chemicals, and preventing algae. The robot acts as a secondary cleaner that drastically reduces the strain on your primary filter.
Chemical Balance: A well-maintained surface may be prone to the growth of algae if the water chemical composition in your swimming pool isn't in balance. The robot can help maintain the cleanliness of your pool, but will not replace the need for proper sanitization. View the top rated consejos para limpiar la piscina for more recommendations including smart swimming pool, cleaner for swimming pool, in your pool, aiper pool, robotic pool cleaner, smart swimming pool, pool sweeper robot, any pool, discount swimming pools, in the swimming pool and more.



Top 10 Tips On The Power Supply And Energy Efficiency Of Robot Pool Cleaners
When you are evaluating robotic pool cleaners, knowing their energy efficiency and power supply is essential, since it directly affects your long-term operating costs as well as the environmental footprint and overall convenience. In contrast to older suction-side or pressure-side cleaners that rely on your pool's high-horsepower main pump--a significant energy hog--robotic cleaners are self-contained systems. They are powered by their own motor which is low voltage and efficient. The most significant benefit is their primary distinction that they are able to conserve energy. There are many robots that perform the same. If you study the information about their power consumption modes and requirements for infrastructure this will allow you to choose a model with maximum performance at a minimum cost.
1. The Key Advantage: Independent Low-Voltage Operation.
This is the basic idea. Robotic cleaners have its own motor and pump that are powered by a separate plug-in transformer. It usually runs on low voltage DC (e.g. 24V,32V) this means it is more secure and efficient than operating 1.5 to 2.5 HP pool pumps for several hours each day. This freedom lets you operate the robot without having to run the main pump.

2. Watts vs. Horsepower. Horsepower.
It is important to first comprehend the magnitude of the savings. The typical pump for a pool draws between 1500 to 2,500 watts an hour. In contrast, a high-quality robotic pool cleaner consumes between 150 and 300 Watts per hour during its cleaning cycle. This represents an energy reduction of around 90%. The energy needed to run a robotic device on 3 hours is the same as running a number of household lightbulbs at the same time. This is in contrast to the main pump, which uses energy like an appliance.

3. What is the critical function of DC power transformer or power supply?
The black box between your cable and your plug of your robot is not a simple power cord. It's actually an intelligent Transformer. It transforms the 110/120V AC power in your home to low voltage DC power, that can be utilized by robots. The quality of this part is crucial to the robot's efficiency and safety. It also includes the circuitry to control the program cycles.

4. Smart Programming to Improve Efficiency.
The robot's programming directly affects its energy consumption. A feature that increases efficiency is the capability to select particular cleaning cycles.
Quick Clean/Floors Only Mode: In this cycle, the robot is run for a shorter period of time (e.g. approximately 1 hour) and the algorithm solely cleaning the floors. This mode consumes less energy compared to the full cycle.
Full Clean mode: A standard cycle of 2.5 to 3 hours for thorough cleaning.
To avoid wasting energy, you should limit your use to as much power as is needed to complete the task.

5. The Impact of Navigation on Energy Consumption.
A robot's cleaning path is directly dependent on its energy consumption. A robot that uses random navigation (bump and turns) is inefficient. It could take hours to clean the entire pool. 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 Requirement and Placement.
The robot's power source MUST be plugged directly into a Ground Fault Circuit Interrupter Outlet (GFCI). These are the outlets commonly equipped with "Test", "Reset" and "Restart" buttons that are found in kitchens and bathrooms. A licensed electrician will need to install a GFCI before you can utilize the cleaner if your pool area doesn't have one. To safeguard the transformer from splashes and other elements it should be at least 10 feet away from the edges of the pool.

7. Cable Length and Voltage Drop
Over long distances the power that flows through the cable will suffer "voltage drop". Manufacturers set a limit to the length of cable (usually 50-60 feet). A cable that is too long could decrease the amount of power available to the robot. This can result in a reduced performance, slower movement and reduced capability to climb. The cable for the robot should be sufficient to extend all the way to the edge of your pool to the outlet. Don't use extension cables they can result in voltage drop and create the risk of injury to your family.

8. Comparing Efficiency to Other Cleaner Types
To ensure that the cost of the robot can be justified, it's important to be aware of the things you're comparing him to.
They rely on the main pump to supply suction. The cleaners will require that you run your large pump at least 6-8 hours a day, which results in very high energy costs.
Pressure-Side cleaners They are pressure side cleaners that utilize the main pump as well as an additional booster that adds an extra 1-1.5 HP.
The robot's independence makes it the most cost-effective choice in the long run.

9. Calculating operating costs
You can calculate the cost of operating your robot. The formula is (Watts/1000) (x hours), x Electricity Cost ($ per kWh), = Cost.
Example: A 200-watt machine used for 3 hours, three times per week in which electricity costs $0.15 per kWh.
(200W / 1000) = 0.2 kW. 0.2 kW multiplied by 9 hours per week equals 1.8 Kilowatts. 1.8 hours multiplied by $0.15 equals $0.27 per week, or around $14 annually.

10. Energy Efficiency as a Measure Of Quality
Generally, more advanced and effective motor technology goes hand in hand with a better product. A robot that's capable of cleaning thoroughly in less time and with less power demonstrates higher quality engineering, a superior navigation system, and an efficient yet strong pump system. The true measure of efficiency isn't about a high-wattage motor that can provide more capacity to climb or suction. It's about a mix of cleaning efficiency within a brief timeframe and low-wattage. It is advisable to purchase an appliance with a high efficiency rating. You'll save money on utility bills each month for a long time. View the best swimming pool robot cleaner for more info including swimming pool com, a swimming pool, cleaner for swimming pool, pool cleaner with hose, cleaner for swimming pool, swimming pool for swimming, robotic pool sweep, pool cleaner nearby, swimming pool sweeper, cleaner for swimming pool and more.