BE1027898B1 - CONTROL SYSTEM FOR POOLS - Google Patents

Abstract

This invention relates to a swimming pool control system composed of the combination of Wlan or Ethernet connected detectors, a specialized application and Wlan controlled devices. Via the WLAN detectors, a signal - which is for example related to the water quality or condition of the swimming pool equipment - is sent locally or via a remote sever, e.g. via a "cloud", to the specialized application, e.g. active on a mobile carrier such as cell phone or tablet. Typical signals are pH, Redox, temperature, water flow rate, water level and time. These different signals are then combined and interpreted by the specialized application, after which the software sends a binary signal to one or more control devices, which are also connected to the specialized application via Wlan. The Wlan control devices in turn control the swimming pool equipment such as filter pump, pH or Chlorine dosing pumps, UV lamps, heat pumps, electric heating, or automatic taps. In summary, the application therefore relates to a system for swimming pool control based on Internet Of Things (IOT).

Description

-1- BE2019/5948

CONTROL SYSTEM FOR POOLS

TECHNICAL FIELD OF THE INVENTION This invention relates to a swimming pool control system composed of the combination of Wlan or Ethernet connected detectors, a specialized application and Wlan controlled devices. Via the WLAN detectors, a signal — which is for example related to the water quality or condition of the swimming pool equipment — is sent locally or via a remote sever, e.g. via a “cloud”, to the specialized application, e.g. active on a mobile carrier such as cell phone or tablet. Typical signals are pH, Redox, temperature, water flow rate, water level and time. These different signals are then combined and interpreted by the specialized application, after which the software sends a binary signal to one or more control devices, which are also connected to the specialized application via Wlan. The Wlan control devices in turn control the swimming pool equipment such as filter pump, pH or Chlorine dosing pumps, UV lamps, heat pumps, electric heating, or automatic taps. In summary, the application therefore relates to a system for swimming pool control based on Internet Of Things (IOT).

BACKGROUND OF THE INVENTION The use of private swimming pools — propelled by the development of the economy, the decline in prices, the availability of very cheap swimming pools and global warming — is becoming increasingly popular.

Due to the direct impact of the pool water on the pool user, it is very important that the water quality and temperature are always guaranteed.

In many swimming pools, due to the financial inaccessibility of expensive control and regulation equipment, the water quality is manually verified and adjusted. This is not only time-consuming, but also prone to errors, as not all pool users have the necessary knowledge and resources to measure and control the water quality perfectly.

Modern swimming pools can be equipped with a number of electrical accessories, whether or not automatically operating, such as a filter pump, dosing pump for pH and Chlorine regulators, UV lamp, swimming pool lighting, automatic control valves for filter or solar heating or water level regulation, heat pump, electric heating, etc ... .

These devices often use built-in measurements and controls. For example, a filter pump can be controlled by a timer, whether or not built into the filter pump or with a smart WiFi plug and/or a built-in or external frequency controller. A pH and Chlorine dosing pump are controlled by a linked pH and Redox measurement, a heat pump by an internal flow detector and temperature measurement, a UV lamp by a timer, etc ... . All these devices work independently of each other, and the user or pool builder must be on site to get an overview of the pool's condition and the

22. BE2019/5948 pool water quality. Patents CN208949009 and CN110007703 disclose a control system in which the swimming pool equipment is controlled as a whole. The water quality parameters that are measured continuously are forwarded via a PLC to a cloud data server, where the PLC (programmable logic controller) — after interpreting the data — in turn controls the various devices. In this arrangement, the pool equipment is directly connected to the PLC via wiring. US2017/209339 describes a system in which various parts of a swimming pool installation, such as the heat pump, the filter pump, the swimming pool lighting, the swimming pool robot, and the like, are provided with a dedicated communication module, whereby each of these parts can be controlled via a hub or on-site control processor. are connected to each other and can communicate with a dedicated 'pool logic' software in order to enable a user to remotely monitor and control a swimming pool installation. Insofar as the system described in this last reference also allows wireless connections of the various components to the hub, it has the disadvantage that it only works with devices equipped with the dedicated communication module, which means that a retrofit of this system requires the installation. requires a hub or on-site control processor with one or more smart relays each equipped with a dedicated communication module to communicate with the dedicated pool logic software. As a result, these solutions can only be implemented by professionals. The present invention aims to greatly simplify the installation of such a pool control system.

SUMMARY OF THE INVENTION As already indicated above, the present invention relates to a swimming pool controller comprising a set of at least one Wlan connected detector, a specialized server application, hereinafter also referred to as 'server application', 'pool server application' or 'pool App cloud'. server' and one or more WLAN controlled devices; in particular one or more WLAN controlled plugs, relays or fuses; in particular one or more WLAN controlled plugs. In this invention, the various parameters of, for example, the swimming pool water, such as pH and temperature or of other parameters relating to the swimming pool, such as a position sensor of the roller deck or a flow sensor for the filtration, are measured via separate sensors, also referred to herein as detectors, each fitted with PCBs (Printed Circuit Board), hereinafter referred to as input PCBs. By way of example, pH and Redox of the pool water are measured via separate input PCBs. The pool water temperature (or temperatures), the presence or absence of flow, and the levels of the water and/or chemicals added to the pool water are also measured via separate or combined input PCBs.

_3- BE2019/5948 Characteristic of the system according to the invention is that each of these Input PCBs is provided with a Wlan connection for connecting each of the sensors / detectors with both the local network in which the swimming pool is located and with the internet.

Within the context of the present invention, a Wireless Local Area Network (Wlan) connection includes all possible wireless communication systems (eg.

Bluetooth, Wi-Fi, ZigBee, WAN, LoRa, LPWAN, LoRaWAN and the like) with which the detectors can ultimately be connected to the server application, whether or not via a node in a local network.

The measured input values are either directly via the local network or via a remote server eg a cloud server, sent as data input to a pool server application in which this data is stored and processed.

Based on preset parameters, this application will control devices (swimming pool related devices) which are also connected to the server application via Wlan.

So in addition to the aforementioned Wlan connected detectors, the system comprises one or more Wlan controlled devices.

In their simplest embodiment, these Wlan controlled devices comprise a Wlan controlled PCB controlled switch, hereinafter referred to as output PCB, such as a smart plug or smart relay or smart fuse.

Here too, a Wireless Local Area Network (Wlan) connection includes all possible wireless communication systems (e.g.

Bluetooth, Wi-Fi, ZigBee, WAN, LoRa, LPWAN, LoRaWAN and the like) with which the WLAN controlled devices can eventually be connected to the server application, whether or not via a node in a local network.

Through these output PCBs, the devices can communicate with and respond to switching instructions coming from the specialized server application.

In addition to the above-mentioned output PCBs, the WLAN-controlled devices in themselves can also optionally be additionally equipped with one or more detector(s) or sensor(s) with an Input PCB, such as a current measurement or temperature measurement.

Via these one or more WLAN-controlled devices, which are equipped with a Wlan-equipped PCB-controlled switch, you can then start and stop the various swimming pool devices.

For example, a heat pump can be started by means of a plug fitted with an output PCB if the temperature of the swimming pool water has dropped below the set value.

A client application, which for example operates on a mobile phone or tablet or a smart speaker, ensures, among other things, that the WLAN connection between the detectors, the pool server application, and the one or more WLAN controlled devices is realized.

In addition, the client application has the purpose of requesting data, transferring data or performing an action on the server, and is therefore provided with a user interface, more in particular a Graphical User Interface (GUI), to enable the end user, for example, to to request data about the pool control, to set desired parameters on the specialized server application, or to, for example,

_4- BE2019/5948 direct instructions to the WLAN controlled devices (Manual Override (MO)). The pool user can consult the current and historical input and output values via a carrier such as a mobile phone or tablet or a smart speaker, in combination with a specific client APP.

In a particular embodiment, the system according to the invention also comprises the use of adapted smart plugs or smart relays or smart fuses, in which the PCB provided with Wlan is pre-programmed to be able to connect directly to the specialized server application as an output PCB. The output PCB is therefore equipped with software that at least ensures that the plug, fuse or relay can be switched on and off (output function). Via these adapted smart plugs or relays or fuses, one can then start and stop the various swimming pool devices. For example, an acid pump can be started if the pH of the pool water has risen above the set value.

The specialized server application receives input values from the different detectors in the system and is able to combine different input values. For example, the chlorine pump can be started if the Redox is lower than the set value and the flow detection indicates that water is actually flowing through the pool pipes. The server application can also generate alarms via what's app, notifications or via any other medium, to the end user of the system.

BRIEF DESCRIPTION OF THE DRAWINGS With specific reference to the figures, it is emphasized that the details shown are by way of example only and for illustrative discussion of the various embodiments of the present invention. They are presented for the purpose of providing what is considered to be the most useful and direct description of the principles and conceptual aspects of the invention. In this regard, no attempt is made to show more structural details of the invention than is necessary for a fundamental understanding of the invention. The description taken in conjunction with the figures makes it clear to those skilled in the art how the various forms of the invention can be practiced.

Figure 1 shows a schematic representation of the relationship between measurements, server, carrier and control via plug or relay. The number of measurements and the number of controls is unlimited, which is indicated by the letters x and y. Outside of the control itself, the cloud server can receive specific user data and pool characteristics, which can be converted into "big data" which in turn

5, BE2019/5948 may lead to advice to the user.

DETAILED DESCRIPTION OF THE INVENTION The detailed examples described below give a good idea of the invention. However, the invention is not limited by these examples. Output PCBs such as a smart plug are known. These can be controlled by means of a corresponding application to switch a linked device on and off with a schedule on the basis of, for example, a timer. For example, it is possible with such a plug to switch a swimming pool filter pump on and off based on a timer function in the app. These existing smart plugs usually also allow you to consult a log file in which, for example, it is kept track of how many hours the plug has been active and what the power consumption has been. Although these are interesting metrics, such an existing smart plug is not capable of actively controlling the pool related devices in monitoring and automating the pool environment. It is therefore the objective of such existing output PCBs to make usable in realizing a swimming pool control by having them communicate with input PCBs which make measurements of parameters related to the swimming pool and the swimming pool environment.

In a first example, this can be done, for example, by supplementing the previous use of a smart plug in switching on and off with an input PCB linked to a Wlan connected detector such as a Wlan flow switch that will measure whether there is water flow in the swimming pool system. is or not. The result of this measurement (flow or not) is sent via Wlan to the pool App cloud server. As indicated above, the Swimming Pool server application will control the application devices, in this case the filter pump, based on preset parameters. In this specific example, the preset parameter can be the maximum length of a time interval within which the Wlan-flow switch detects no water flow, with the filter pump shutting down if this time interval is exceeded. The preset parameters can be included as factory settings in the Pool server application, with optional possibility to change them via a Client application. For example, via Client application, which preferably runs on a mobile phone, the option “flow protection” can be enabled to activate the preset parameters in the Pool server application. In a further embodiment, it is also possible to change the preset parameters in the server application, in this case by changing the length of the time interval. If no flow is detected, eg 3 minutes after starting the filter pump, the electrical current to the filter pump Wlan plug is sent via a signal from the swimming pool app cloud server to the filter pump Wlan plug. This configuration prevents the filter pump from running dry. On the

-6- BE2019/5948 the moment the electric power to the filter pump Wlan plug is interrupted, the server application will generate an alarm and the user will receive an alarm from the client app, for example via pop-up, SMS, email, what's app or via another medium.

In a second example, in addition to or independently of the previous example, the pH of the swimming pool water is measured by means of another input PCB via a Wlan connected detector, such as a Wlan pH electrode. Examples of such WLAN pH detectors are Blue Connect and OFI, which are connected to the local network via bluetooth and optional Wi-Fi extenders, or the Polish one, which uses a Low-power Wide-area network (LPWAN) for its wireless communication. By analogy with the above, the result of this pH measurement is sent as data input to the swimming pool App cloud server. In the context of automated swimming pool control, measuring the pH of the swimming pool water only makes sense if there is also an option to adjust the pH in an automated manner. In this example, the pH input PCB will therefore typically be coupled to a Wlan controlled acid pump. In its simplest embodiment, it consists of a peristaltic acid pump — which can pump sulfuric acid into the pool pipe - connected to a Wlan plug, hereinafter referred to as the acid pump Wlan plug. Also analogous to the foregoing, a preset pH value in the Pool server application will be used to enable or disable the Wlan controlled acid pump. Here too, it may concern preset factory settings that may or may not be activated and/or changed via the client application. One of the strengths of the system according to the present invention is the possibility to combine several input data by means of the Server application in controlling the WLAN controlled devices, whereby use is made of the connection between the various components. a client application . This not only makes multiple scenarios possible, it also gives the possibility to use input data that has nothing to do with the detector in itself, but by including them can have an impact on the durability and robustness of the entire pool control . For example, the pH measurement can be combined with the flow measurement by enabling the option “start peristaltic pump acid at pH greater than 7.4” in the client application on the mobile phone. As an additional condition, it is set that it is NOT allowed to operate if the flow meter indicates that no flow is detected. If a pH is detected greater than 7.4 AND the flow meter indicates that there is flow, then the peristaltic acid pump will receive electrical power from the acid pump Wlan plug. At pH 7.4 or less, or lack of flow, the electrical current to the acid pump Wlan plug is stopped via a signal from the pool app cloud server to the acid pump Wlan plug. In another scenario, it is possible, for example, whether or not independently of the flow measurement, to choose to have the acid regulation run proportionally. This is done by only switching on the acid pump Wlan plug 20-80% of the time. The closer the pH to 7.4, the smaller the % of

7- BE2019/5948 activation.

Here too, an embodiment can consist in that the preset parameters can be changed by the user by means of the Client application, for instance by setting a minimum and/or maximum pH value.

The moment this value is measured, the server application will generate an alarm and the user will receive an alarm from the client application via pop-up, SMS, email, what's app or via another medium.

In a third example, in addition to or independently of the previous examples, the Redox (RX) of the swimming pool water is measured via a Wlan connected RX electrode.

The result of this RX measurement is sent as data input via Wlan to the swimming pool App cloud server.

In the context of automated swimming pool control, measuring the redox values of the swimming pool water only makes sense if there is also an option to adjust the redox values in an automated manner.

In this example, the Redox input PCB will typically be coupled to a Wlan controlled chlorine pump.

In its simplest form, such a Wlan controlled chlorine pump is composed of a peristaltic pump of chlorine - which can pump sodium hypochlorite 15% into the pool pipe - connected to a Wlan plug, hereinafter referred to as the chlorine pump Wlan plug.

Also analogous to the foregoing, a preset redox value in the Pool server application will be used to switch the Wlan controlled chlorine pump on or off.

Again, this may concern factory presets that may or may not be activated and/or changed via the client application, and which may or may not be combined with other data input values.

In a possible embodiment of the system, which contains a Wlan connected Redox electrode and a Wlan controlled chlorine pump, the option “start peristaltic pump chlorine at RX smaller than 700” will be enabled via the client application on the mobile phone.

Optionally, an additional condition can be set that it may NOT operate if the flow meter indicates that no flow is detected.

If an RX is detected smaller than 700 AND the flow meter indicates that there is flow, the Pool server application will turn on the peristaltic chlorine pump by drawing electrical current from the chlorine pump Wlan plug.

At an RX value greater than 700 mV or if there is no flow, the electrical current to the chlorine pump Wlan plug is stopped via a signal from the pool app cloud server to the chlorine pump Wlan plug.

In another scenario, for example, whether or not independently of the flow measurement, it is possible to choose to have the chlorine regulation run proportionally.

This is done by only switching on the chlorine pump Wlan plug 20-80% of the time.

The closer the RX to 700 mV, the smaller the % of engagement.

Here too, an embodiment can consist in that the preset parameters can be changed by the user by means of the Client application, for example by setting a minimum and/or maximum RX value.

The moment this value is measured, the server application will generate an alarm and the user will receive an alarm from the client application via pop-up, SMS, email, what's app or via another medium.

-8- BE2019/5948 Since the simultaneous administration of acid and chlorine can lead to the formation of chlorine gas, this will be one of the preset parameters in a further embodiment of the server application, which prevents the simultaneous activation of the acid pump and the chlorine pump is going to be. In the proportional control of the chlorine and acid pump, this can be done, for example, by means of a timer function within which only one of the pumps can be active at a time. This ensures that acid and chlorine are never dosed at the same time. In a fourth example, in addition to or independently of the foregoing embodiments, a Wlan-connected level detector is placed in the acid and/or chlorine container. The result of these level measurement(s) is sent as input data via Wlan to the swimming pool App cloud server. Measuring the acid and/or chlorine level can in itself be an interesting fact to warn the user in time to replenish these products, but it gains added value in automating the pool control if it is used as additional input data in controlling the acid / chlorine pump respectively. An additional condition is indicated via the server application, whereby the acid Wlan plug and/or the chlorine Wlan plug may not allow electrical current to pass through to the acid pump and/or the chlorine pump respectively in case a low level is detected in the respective liquid containers. This additional condition can be enabled via the client application in the pool server application and will give the user a notification (alarm) regarding the low level by the client application via pop-up, SMS, email, what's app or via another medium. In addition, when a low liquid level is detected, the server application can adjust the proportional control of the Chlorine or Acid pump in order to dose as long as possible with the remainder.

In a fifth example, in addition to or independently of the previous examples, a swimming pool LED lamp is connected to a Wlan-connected plug as one of the Wlan controlled devices. In a particular embodiment, the LED lamp is chosen such that the color of the lamp can be selected by rapidly switching the electric current on-off. The moment the LED lamp is switched on via the client application on the GSM or Tablet, and the color is selected, the server application lamp Wlan plug will switch on and off as many times quickly as corresponds to the chosen color and program. . The lamp then remains on until the user switches off the lamp, whether or not via the client application. If there is a detector in the application that detects the position of the roller shutter (open/closed), it is possible to switch off the lamps in any case when the roller shutter is closed. In a sixth example, in addition to or independently of the preceding

-9- BE2019/5948 examples placed a WLAN connected level detection in the swimming pool itself. The result of this level measurement will be forwarded as data input via Wlan to the pool App cloud server. In the context of automated swimming pool control, measuring the level of the swimming pool water only makes sense if there is also an option to adjust the level in an automated manner or to intervene in the pool control. In this example, the water level input PCB will typically be coupled to a Wlan controlled water supply. Here too, the water level input data in the server application can be combined with the flow data, for example, with the additional pre-set condition that the filter pump Wlan plug does not allow electrical current to pass through to the filter pump, in case a low level is detected in the pool. In a seventh example, one or more WLAN-connected temperature probes are placed in addition to or independently of the previous examples. The temperature measurements can take place in the swimming pool pipe, or in the outside air in the direct swimming pool environment, e.g. freely in the sun, or in a weather station in the shade... The result of these temperature measurement(s) is sent as input data via Wlan to the pool App cloud server. In the Pool server application, these temperature measurement(s) can be used to control one or more WLAN controlled devices.

For example, the temperature measurement in winter can be used in the context of frost protection of the swimming pool installation. In this case, the WLAN controlled devices include, for example, the filter pump, whether or not in combination with a heat pump. A preset parameter in the Pool server application can be eg a measured outside temperature of at least 2°C.

When this temperature is reached, the Server application then switches on the filter pump Wlan plug and optionally also the Wlan controlled heat pump. The latter can, for example, be connected to a Wlan relay, a Wlan fuse, or a Wlan plug by means of a contactor, hereinafter referred to as the Wlan relay. By switching these relays, the contactor will allow current to flow. In this way, large power consumers are preferentially connected, optionally with a Wlan core current transformer for measuring the consumed electrical power. During the swimming season, the temperature measurement can be used to regulate the temperature of the swimming pool water, using the available heating installation(s) that are connected to the Swimming Pool server application via WLAN-connected devices (a WLAN relay, plug or fuse). In addition to the aforementioned heat pump, solar heating installations are also commonly used as swimming pool heating installation(s). In the case of a heat pump, this will be connected directly to the Wlan relay, with a solar heating system, this Wlan relay is connected to an automatic

_10- BE2019/5948 three-way valve or two-way valve connected to the swimming pool pipe. In each of these applications, a hysteresis of, for example, 1 or 2 degrees can be provided in the control of the relay or plug. In that case, the heating system will start up when the target temperature is -1 or 2 degrees, and switch off when the target temperature is reached. The target temperature can be set by the user through the client application. In the case of a heat pump, in addition to the temperature, the Server application will also take into account flow input data, whereby the heat pump may only be switched on if the Wlan flow measurement indicates that water is flowing through the heat pump.

In the case of a solar heating system, in addition to the temperature of the swimming pool water, the Server application will also take the temperature of the outside air into account, and the automatic three-way valve of a solar heating system can only be opened if the Wlan outdoor temperature measurement indicates that this temperature is example is at least 4 degrees higher than the pool water temperature. This tap can also be closed as soon as the outside air temperature drops below the pool water temperature.

In order to keep the energy consumption of the swimming pool installation under control, in a further embodiment the data input from said Wlan core current transformer can be used by the Server application to control the large power consumers. In addition to the heat pump, the filter pump is one of the major power consumers in a swimming pool installation. In a first embodiment, the server application can switch the filter pump Wlan plug on and off over a period of 24 hours in time blocks of at least 1 hour, wherein the filter pump has been running for at least 8 hours over this period of time. In an alternative embodiment, the filter pump is provided with a Wlan connected frequency converter used to control the filter pump. In that case, a Wlan frequency converter module sends a signal to a frequency converter, which then starts the pump in the rotating frequency set — via the GSM or tablet or smart speaker. For example, the pump can be switched to a low speed when the pool roller shutter is closed and to a higher speed when the pool roller shutter is open.

In an eighth example, in addition to or independently of the previous examples, the chlorine content of the swimming pool water is not measured via a Redox (RX) electrode, but via an amperometric chlorine probe coupled to an amperometric Wlan sensor, typical for swimming pool installations where no use is made of an electrolysis cell for generating chlorine. In the first place, the measured amperometric value is linked (calibrated) via the app to the chlorine content of swimming pool water with known

_11- BE2019/5948 chlorine content (1 to 1.5ppm). The result of this amperometric measurement and calibration is sent as data input via Wlan to the swimming pool App cloud server. In the context of automated swimming pool control, measuring the amperometric values of the swimming pool water only makes sense if there is also an option to adjust the chlorine values in an automated manner. In this example, the amperometric input PCB will typically be coupled to a Wlan controlled salt electrolysis device. In its simplest form, such a Wlan controlled salt electrolysis is composed of a standard salt electrolysis controller and an electrolysis cell - which will convert salt (NaCl) to sodium hypochlorite (NaClO) - connected to a Wlan plug, hereinafter called the salt electrolysis Wlan plug. Also analogous to the foregoing, a preset aperometric value in the Swimming Pool server application will be used to enable or disable the WLAN controlled salt electrolysis. Again, this may concern factory presets that may or may not be activated and/or changed via the client application, and which may or may not be combined with other data input values.

In a possible embodiment of the system, which contains a Wlan connected amperometric electrode and a Wlan controlled salt electrolysis, the option "Allow salt electrolysis to work at chlorine content less than 1.5ppm" will be enabled via the client application on the mobile phone. Optionally, an additional condition can be set that it may NOT operate if the flow meter indicates that no flow is detected. If a chlorine content of less than 1.5 ppm is measured AND the flow meter indicates that there is flow, the Pool server application will switch on the salt electrolysis device by running electrical current from the salt electrolysis Wlan plug. At a chlorine value greater than 1.5 ppm or if there is no flow, the electric current to the salt electrolysis Wlan plug is stopped via a signal from the pool app cloud server to the salt electrolysis Wlan plug. The moment this value is measured, the server application will generate an alarm and the user will receive an alarm from the client application via pop-up, SMS, email, what's app or via another medium.

While these examples have been clearly and specifically described, they are only examples and are not of a restrictive nature. All changes to these examples and this invention that are within the spirit of the invention are protected by this patent.

A variety of other devices, not mentioned in the above examples, can be controlled and/or monitored via this invention. This includes UV lamps, ozonators, electric heaters, booster pumps, flow meters and other devices not mentioned.

These examples show that the applications of this invention are almost limitless. The user can build a fully modular swimming pool measurement and control system. The use of Wlan sensors and Wlan plugs, relays or fuses plays an essential role in this

_12- BE2019/5948 the ease of use, production cost and installation cost. Because no wiring is required, all components can be manufactured fully automatically. The installation also requires no (Wlan plug) or few (Wlan relay or fuse) technical actions.

Through the data realized by this server application, the user can monitor and optimize the water quality, the condition of his equipment and the energy consumption of the pool. In addition to automated control, the input data from the server application can also be used in monitoring and possible calibration of the quality of the swimming pool water. For example, by placing the pH Wlan electrode in a calibration solution of pH 7.0, the user can check via the server application whether the pH measurement still corresponds to the calibration value. If the pH read on the client application on the mobile phone or tablet deviates from

7.0, the user can correct the pH reading to 7.0 via the pH calibration key. It should be clear that similar calibrations can be provided in the server application for the RX measurement or the measurement of the chlorine content. The pool builder or pool maintainer can check the condition of the pools of his customers via the application, remotely and without physically moving. In this way, both preventive and curative maintenance can be achieved quickly and efficiently. Through this invention, the pool equipment manufacturer and/or the pool application vendor gains access to a variety of pool data with the consent of the customer. With this data it is possible to advise the customer for the use and optimization of the use of his swimming pool. In this way, water quality and energy consumption of the swimming pool can be optimised, among other things. Given the pool equipment manufacturer and/or the pool application vendor, this advice may be of a geographical nature such as frost warning (if the pool data shows that the pool has not been winterized), increasing or decreasing the number of filtration hours depending on weather conditions. In summary, the invention relates to a swimming pool control system comprising: e One or more WLAN controlled devices; such as WLAN controlled plugs, relays or fuses; e At least one WLAN controlled sensor or measuring system; e A server application, in particular a cloud server application in which the data from the at least one Wlan controlled sensor or measuring system is collected, processed and the Wlan controlled devices are controlled; and e A client application, in particular for GSM or tablet and/or smart speaker with which a user can set up the connection between the one or more Wlan controlled devices, and the at least one Wlan controlled sensor, with the server application.

_13- BE2019/5948 In addition to the data from the at least one Wlan controlled sensor or measuring system, in one embodiment the server application in the swimming pool control system can also use data from a non-Wlan controlled measuring system, which forwards pool data or weather data to a cloud server or a PLC.

In the aforementioned embodiments, each of the sensors can be provided with its own PCB provided with a Wlan connection or several sensors can be combined on a shared PCB provided with a Wlan connection.

So in a special embodiment different measuring systems are combined on 1 PCB.

The sensors used in the control system according to the present invention are, for example, selected from: temperature measurements eg of swimming pool water before, after and between the heating or cooling appliances, outside air temperature in both sun and shade; pH measurement; Redox meeting; chlorine content; presence of flow; flow rate; level of liquid; used power of electrical appliances; total running time of electrical appliances; and such.

In addition to the sensors, not all devices are necessarily connected to the Server application via Wlan.

Thus, in a further embodiment, the pool control system also includes one or more devices that are connected directly — not via Wlan — to a device that forwards the data to the server application.

Claims (7)

- 14 - BE2019/5948 CONCLUSIONS 1. A swimming pool control system containing: e One or more WLAN controlled devices; such as WLAN controlled plugs, relays or fuses; e At least one WLAN controlled sensor or measuring system; e A server application, in particular a cloud server application in which the data from the at least one Wlan controlled sensor or measuring system is collected, processed and the Wlan controlled devices are controlled; and e A client application, in particular for GSM or tablet and/or smart speaker with which a user can set up the connection between the one or more Wlan controlled devices, and the at least one Wlan controlled sensor, with the server application, and whereby this one or more Wlan controlled devices and the at least one Wlan controlled sensor or measurement system are preferably provided with a PCB which is preprogrammed to be able to connect directly to the server application as an output PCB. A swimming pool control system according to claim 1, wherein in addition to the data from the at least one Wlan controlled sensor or measuring system, the server application in the swimming pool control system also uses data from a non-Wlan controlled measuring system, which transmits pool data or weather data to a cloud server or a PLC. A swimming pool control system according to the preceding claims, wherein each of the sensors is provided with its own PCB provided with a Wlan connection. A swimming pool control system according to the preceding claims wherein different measurement systems are combined on 1 PCB. A swimming pool control system according to the preceding claims wherein the sensors used in the control system according to the present invention are selected from: temperature measurements eg of swimming pool water before, after and between the heating or cooling appliances, outside air temperature in both sun and shade; pH measurement; Redox meeting; chlorine content; presence of flow; flow rate; level of liquid; used power of electrical appliances; total running time of electrical appliances; and such. A swimming pool control system according to the preceding claims, wherein not necessarily all devices are connected to the Server application via Wlan. _15- BE2019/5948 A swimming pool control system according to the preceding claims, wherein one or more devices are directly connected to a device that forwards the data to the server application.