GR20170100400A - Autonomous system for water leakage detection and water consumption control - Google Patents

Abstract

Novelty: a self-acting sensor meant for the mains water leakage detection and water consumption control is disclosed. Constitution: two parts: the mechanical part composed of a flowmeter and a solenoid and the electronic part composed of a programmer (the brain of the system) intended to program and control all operations; more precisely, the invented detection system is able to detect the continuous water flow or water volume beyond the preset time period and cut it off, or to close the water network after a precise quantity of water has passed at a precise time period and open it again according to the programmed presettings. All operational conditions and water consumption data are transmitted to the user via WiFi or GPRS. The autonomy of the system is ensured by a power condenser supplying power covering all operations. Embodiment: the invention finds application to all mains water supply networks.

Description

DESCRIPTION

Autonomous Leak Detection - Protection System and Water Consumption Control

The invention referred to is an energy autonomous system without an external power source consisting of an electronic, programmer, and two electromechanical parts, a pulse flowmeter and an electrovalve. The specialized control device is placed in water supply networks to protect the consumer from water leakage and its consequences (financial and material damage) but also to contribute to the saving and rational disposal of water (especially in areas with water shortages) of a valuable natural resource resource.

The existing systems do not provide a complete protection to the consumer with complex parameterization, water flow time, water volume in the unit of time, activation sensitivity and at the same time the possibility of water management by the provider. Also, non-energy independent systems cannot operate in areas without electricity, they are vulnerable and inactive in power outages which are a common phenomenon, eg in snowfalls, earthquakes.

The advantage of the invention is the energy autonomy that makes the system active in any location and under any conditions (remote non-electrified areas, power outages due to earthquakes, fires, etc.). Also a notable advantage for the described system is the range of leakage it detects as it starts from 1 1/h (the continuous drop of water). This means that the user is protected from minimal hidden leaks, which cause great damage over time (small leaks inside walls, from radiator fittings under wooden floors, built-in collectors, etc.). Finally, the biggest advantage is the complex parameterization for the detection of leaks, the continuous flow of water in a predetermined (by the user) period of time, the counting of a predetermined (by the user) volume of water in a specific period of time, the counting of a predetermined (by the provider) volume of water in a certain period of time For all large or small leaks, the consumer is informed via WiFi or GPRS network while at the same time the water supply is interrupted, similarly for all overconsumptions the provider is informed and the water supply is interrupted if these are prohibitive and harmful to the common good .

The system is placed in the central supply where there is either an analogue meter (old style) or a pulsed digital water meter. The difference to our system is that in the first case we will have to connect a pulse flowmeter which will give us a pulse for each water flow to activate the system. Apart from that, the operation is the same in both cases. An electric valve is connected to the water network which is electrically connected to our programmer (which is installed in the same or adjacent space) in order to receive the on-off commands. Our programmer is connected to the pulse flowmeter or digital meter and is activated when it receives a pulse from the water flow. The scheduler is programmed in terms of the time or volume of streaming allowed depending on the user's needs. When the system receives a pulse from the water flow, the countdown timer is activated and of course the water volume measurement begins. If the flow closes it means that we have normal operation, the timer resets and is ready to start a new measurement when some consumption is opened. If the flow continues beyond the predetermined time or volume of water, then the solenoid valve receives an order to close and the user is informed that the water supply has been interrupted with a message on his mobile phone or PC. Also, the ALARM light indicates that the water supply has been interrupted. The user, after realizing the problem, gives the RESET command remotely or on site and puts the system into operation according to the last programming. Power or water outages do not affect the system. Other programming supported by the system is through programming input and locked program and can be done by the operator. During this programming, the provider programs the allowed volume of water that a consumer is allowed to consume daily. Every time the water is turned on, the meter informs the programmer and the volume is counted, these counts are added up over the course of a day, and if the permitted consumption is exceeded, the network is interrupted and restarted in the new twenty-four hours. The consumer has of course been informed by message when 80% of the permitted consumption has been exceeded.

The operation of the system is as follows: we program in our programmer the time or volume of allowed continuous flow according to the needs of the user, for example 15 minutes per hour continuous flow or 200 liters of water. When the system receives a pulse from the water flow, the countdown timer is activated and of course the water volume measurement begins. If the flow closes it means that we have normal operation, the timer resets and is ready to start a new measurement when some consumption is opened. If the flow continues beyond 15 minutes or 200 liters then the solenoid valve receives an order to close and the user is informed that the water supply has been interrupted by a message on his mobile phone or PC. Also, the ALARM light indicates that the water supply has been interrupted. The user, after realizing the problem, gives the RESET command remotely or on site and puts the system into operation according to the last programming. Power or water outages do not affect the system. Other programming supported by the system is through programming input and locked program and can be done by the operator. During this programming, the provider programs the allowed volume of water that a consumer is allowed to consume daily, for example 5 m of water. Every time the water is turned on, the meter informs the programmer and the volume is counted, these counts are added up over the course of a day, and if the permitted consumption is exceeded, the network is interrupted and restarted in the new twenty-four hours. The consumer has of course been informed by message when 80% of the permitted consumption has been exceeded. As mentioned above, the system has multiple applications, i.e. it is installed at the initiative of the user in order to avoid the damage that can be caused by a large or small and long-term water leak. It can also be placed at the provider's initiative in sensitive areas where the phenomenon of water shortage occurs, especially in tourist areas during the summer months, so that a fair and rational management of water is carried out. Finally, it can be placed in cooperation between the two with mutual benefit

Claims (4)

1. Autonomous Detection - Leakage Protection and Water Consumption Control System which consists of a pulse flowmeter, an electric valve, a programmer-microprocessor and an electric accumulator that powers the whole system, characterized by the fact that the programmer is programmed a) in terms of the allowed time of continuous water flow b) in terms of the maximum allowed volume of water in continuous water flow and c) in terms of the maximum volume of daily consumption, exceeding the limits of each one individually or in combination signals a network interruption and reactivation after a command from the user in the cases a, b, of the provider in case c. 2. According to claim I and case c the programming is done by the provider via RS 232 port for the automatic restart of the system at a specified calendar time. 3. According to claim I, and 2, the user is informed electronically about the operating states in which the system occurs. 4. According to claims 1, 2 and 3 the user can program all the functions of the system remotely.