Patent Description:
The heating system heats the water and conveys it through the heating devices by means of which the heat of the water is transferred to the environment. The water is heated to a working temperature, by means of the heat generator placed in a heat exchange relationship with the hydraulic circuit, where a system for controlling the heat generator controls the activation, shutdown, and power adjustment of the heat generator, e.g., of a burner of a gas boiler or a compressor of a heat pump, as well as the activation, shutdown, and flow rate adjustment of a water circulation pump, for example for varying the flow of water conveyed through the hydraulic heating circuit.

The control system controls the operation of the heat generator and the circulation pump as a function of one or more temperature values selectable by a user and detected values of the ambient temperature in the environments to be heated and the temperature of the water in the hydraulic heating circuit. <CIT> describes a heating system according to the prior art and having features of the preamble of claim <NUM>. <CIT> and <CIT> describe systems of the prior art that represent a technological context for the invention.

One of the commonest problems in domestic heating systems is the presence of air bubbles in the hydraulic circuit, which results in:.

In these anomalous operating conditions, the heat generator, e.g., a gas boiler, initiates safety procedures aimed at protecting the reliability thereof over time, which can result in undesired temporary or permanent operating blocks.

For these reasons, during the installation and/or extraordinary maintenance of the heating system, it is necessary and known to thoroughly de-aerate the whole heating system and the heat generator in order to ensure the optimum operation thereof.

It is also known that after completely bleeding the heating system of air, a little air tends to go back to the hydraulic circuit over time (e.g., due to leaks), which is why it is necessary to repeat the de-aeration operation periodically.

It is known to bleed the heating system of air by means of:.

Typically, the de-aeration valves of the heating system are only opened by a skilled operator (technical service centers) and only during in-situ interventions, to avoid undesired side effects (which are difficult to manage for unskilled users) during the service life of the heating system.

Some known boilers also comprise an electronic control function for bleeding the air in both the local circuit of the boiler and the hydraulic circuit of the central heating system, which performs specific control sequences of controlling the circulation pump and a diverter valve for diverting the heat transfer fluid between the primary circuit of the boiler and the hydraulic heating circuit so as to carry the air bubbles of both circuits into the de-aerator.

This function is also generally manually activated by a skilled operator.

The air bleeding is typically carried out by skilled operators during installation or extraordinary maintenance and takes a long time, because there is no indicator of the presence of air and the only known clues for understanding whether the air has been completely bled are the circulation noises and operating anomalies of the boiler (e.g., overheating).

Similarly, the same problems arise for cooling systems and for heating and cooling systems with a hydraulic circuit.

Therefore, it is the object of the present invention to provide a method for verifying the presence of air in the heating and/or cooling system, having features such as to obviate at least some of the drawbacks of the prior art.

Within the scope of the main object, it is a particular object of the invention to provide a method which provides a more objective indicator of the presence of air in the central heating and/or cooling system.

These and other objects are achieved by a process according to claim <NUM>, and by a heating and/or cooling system according to claim <NUM>.

The dependent claims relate to advantageous and preferred embodiments.

According to one aspect of the invention, there is provided a method for detecting air in a heating or cooling system, in particular a domestic system, of the type comprising:.

Similarly, according to an aspect of the invention, a heating or cooling system (e.g., a boiler or a heat pump system), in particular a domestic system, comprises:.

By virtue of the correlation between the presence of air in the hydraulic circuit and the oscillation of the water flow rate, there is a more objective parameter for determining the presence of air in the hydraulic circuit. In fact, the greater the amount of air trapped inside the hydraulic circuit, the more the water flow speed and rate varies with the same (constant) operation of the circulation pump during the detection interval. In fact, the inventors have understood that the circulation vacuums produced by the air bubbles can be detected through a variation model of a signal linked to the water circulation.

The variation measurement of the flow rate or speed, detected directly or by means of the detection of flow parameters or related electrical parameters, provides an easily obtainable determination criterion, which is electronically processable and reliable.

Further advantageous aspects of the invention will become apparent from the following description of some embodiments thereof, given by way of non-limiting example, with reference to the accompanying drawings, in which:.

With reference to the figures, a heating or cooling system <NUM> (e.g., a gas boiler or a heat pump system), in particular a domestic system, comprises:.

According to an advantageous embodiment, the air detection module <NUM>, <NUM>' is configured so that, if during a first air detection step <NUM> of the air detection steps <NUM>,. n, with a first pumping speed of the circulation pump <NUM>, the calculated variation FlowRate_StdDev is lower than the variation threshold value Threshold_var, the air detection module <NUM>, <NUM>' performs a further subsequent air detection step <NUM>, with a further pumping speed of the circulation pump <NUM>, which is different from the first pumping speed.

In fact, as can be seen in <FIG> and <FIG>, which will be described in detail below, the calculated variation FlowRate_StdDev may differ significantly as a function of the flow speed. Therefore, performing the air detection process <NUM> by means of a plurality of air detection steps <NUM>,. n at different flow speeds of the circulation pump <NUM>, significantly increases the reliability and result precision thereof.

According to an embodiment, the air detection process <NUM> and the air detection module <NUM>, <NUM>' perform the first air detection step <NUM> with a first pumping speed and the subsequent air detection step(s) <NUM>,. n with pumping speeds decreasing from one air detection step <NUM>. n-<NUM> to the subsequent air detection step <NUM>. n (<FIG>), for example in the order of number of the air detection step <NUM>,. , <NUM>, the pumping speed is <NUM>%, <NUM>%, <NUM>%, <NUM>% of the maximum speed of pump <NUM>.

The pumping speed of the circulation pump <NUM> is preferably constant within the same air detection step <NUM>.

The duration of the detection interval is preferably constant, e.g., <NUM> seconds or in the range from <NUM> seconds to <NUM> seconds.

The number of values x detected and collected during the detection interval is preferably constant, e.g., <NUM> or in the range from <NUM> to <NUM>, detected with a detection frequency of <NUM> value/second, for example.

The variation threshold value Threshold_var is preferably different for different pumping speeds of the circulation pump <NUM>.

According to an embodiment, when determining the presence of air in the hydraulic circuit <NUM>, i.e., if the calculated variation FlowRate_StdDev is greater than the variation threshold value Threshold_var, the (reception of the) notification signal of air presence in the hydraulic circuit <NUM> can form the base for, or trigger subsequent method steps, e.g., one or more visual and/or acoustic notification steps and/or one or more anomaly control steps of the heat or cold generator <NUM> and/or the circulation pump <NUM>, and/or a safety shutdown step of the heat or cold generator <NUM> and the circulation pump <NUM>.

The visual and/or acoustic notification can occur by means of a user interface <NUM> of the electronic control system <NUM> of the heating or cooling system <NUM>, positioned directly on board the heat or cold generator <NUM> or externally thereto, for example, or by means of a further user interface <NUM>' of an air detection module <NUM>' outside the electronic control system <NUM> of the heating or cooling system <NUM>.

According to embodiments, the air detection module <NUM>, <NUM>' can be an electronic processing module <NUM> directly integrated into the electronic control system <NUM> of the heating or cooling system <NUM> or an electronic processing module <NUM>' outside the latter and temporarily or permanently connectable to the heating or cooling system <NUM> (signal and/or hydraulic and/or electrical connection) as a retrofitting accessory.

According to a further embodiment of the method and system <NUM>, in response to the notification signal of air presence an anomaly notification signal is transmitted (step F9), e.g., by cable or wirelessly (from the electronic control system <NUM> or the air detection module either integrated <NUM> or external <NUM>', for example) to a remote server <NUM> (cloud) which, in response to receiving the anomaly notification signal, performs a maintenance preparation procedure (step F10).

The maintenance preparation procedure F10 can comprise sending an electronic message, e.g., by telephone, SMS, email, etc., to the user or an administrator in charge of the heating or cooling system <NUM>.

According to an embodiment, the remote server <NUM>:.

According to an embodiment, the air detection module <NUM>, <NUM>' is configured to (and the air detection method comprises):.

Alternatively or additionally, the air detection module <NUM>, <NUM>' can be configured to (and the air detection method can comprise) performing the air detection process <NUM> automatically as a function of a predetermined starting criterion (or set of criteria).

The starting criterion or set of criteria (and/or the verification F8 thereof) can comprise:.

According to an embodiment, the parameter x indicative of the flow rate is obtained (e.g., from the air detection module <NUM>) by a flow rate signal provided by the circulation pump <NUM>. To this end, the circulation pump <NUM> can comprise a flow rate sensor <NUM> (flowmeter) or an indirect determination device <NUM> for the flow rate depending on electrical parameters (of the electric motor <NUM>) of the circulation pump <NUM>.

According to an embodiment, the parameter x indicative of the flow rate is obtained (e.g., from the air detection module <NUM>) by a signal of a flow rate sensor <NUM> (flowmeter) connected to the hydraulic circuit <NUM> outside the circulation pump <NUM>, e.g., inside or outside a housing <NUM> of the heat or cold generator <NUM>. Here, the parameter x indicative of the flow rate is the flow rate itself.

Alternatively, the parameter x indicative of the flow rate is obtained (e.g., from the air detection module <NUM>) by a prevalence signal generated by the circulation pump <NUM>, or by a signal of electric power (or electric current) absorbed by the electric motor <NUM> of the circulation pump <NUM> or by a signal of the number of revolutions or angular speed of the electric motor <NUM> of the circulation pump <NUM>.

According to a preferred embodiment, the calculation of the variation FlowRate_StdDev of the plurality of values x_t comprises calculating a standard deviation of the plurality of values x_t collected in the detection time interval, e.g., by means of the formula: <MAT> where: <MAT>.

According to an alternative embodiment, the calculation of the variation FlowRate_StdDev of the plurality of values x_t comprises calculating a relative standard deviation or variation coefficient.

According to a still further embodiment, the calculation of the variation FlowRate_StdDev of the plurality of values x_t comprises calculating an average value of the absolute differences between all values x of the plurality of values x_t and an average value of all values x of the plurality of values x_t.

According to a still further embodiment, the calculation of the variation FlowRate_StdDev of the plurality of values x_t comprises calculating an average value of the absolute differences between all values x of the plurality of values x_t and a central value (halfway between a maximum value and a minimum value) of all values x of the plurality of values x_t.

According to a still further embodiment, the calculation of the variation FlowRate_StdDev of the plurality of values x_t comprises calculating a degree of non-cyclicity or a degree of randomness of a sequence (in the order of time) of the values x of the plurality of values x_t. The greater the randomness, the greater the probability that the fluctuation is due to air in the system and not to cyclic pumping phenomena.

It should be noted that the name FlowRate_StdDev is an invented name which, despite the resemblance, does not necessarily indicate a standard deviation and does not necessarily refer to a flow rate, but to a parameter indicative or representative of the flow rate.

<FIG> shows the trend of the flow rate with respect to time: during alternate steps of the air detection <NUM> and de-aeration process of the system <NUM>, starting from a situation with a great amount of air in the system <NUM> and performing, for each air detection process <NUM>, a plurality of air detection steps <NUM>,. n, and, between two consecutive air detection processes <NUM>, respectively, a de-aeration step of the system <NUM>.

During each air detection process <NUM>, the pumping speed of pump <NUM> has been modulated at <NUM> different speeds, from MAX to MIN.

As can be seen in <FIG>, the presence of air in the hydraulic circuit <NUM> results in strong signal fluctuations which, however, are no longer present once the air has been eliminated.

The fluctuation measurement of the value x systematically depends on the amount of air in the water flow:.

In the first and second detection processes (cycles <NUM> and <NUM> from the left in <FIG>), the amount of air is very large and detectable at all speeds of pump <NUM>.

In the third detection process (cycle <NUM> in <FIG>), the amount of air is small and detectable only at the maximum speed of pump <NUM>.

In the fourth and fifth detection processes (cycles <NUM> and <NUM> in <FIG>), the amount of air is so small or completely absent that it is no longer detectable.

<FIG> shows the standard deviation (ordinate) of the flow rate at a constant pump speed (<NUM>% of the maximum speed) for each test cycle shown in <FIG>.

In particular, <FIG> shows that the standard deviation of the flow rate at a fixed pump speed (<NUM>%) increases as the air increases in the hydraulic circuit <NUM> (<NUM>st and <NUM>nd cycle in <FIG> and <FIG>) and decreases when the air is gradually eliminated (<NUM>rd, <NUM>th and <NUM>th cycles in <FIG> and <FIG>).

The samples of values acquired when performing the tests (<NUM> sample per second) are indicated on the axis of abscissas in <FIG>, taking into account a fixed number of <NUM> samples per detection interval.

The heating and/or cooling system <NUM> described so far can be installed at a house <NUM> or a general building. The water circulating in the hydraulic circuit <NUM> is brought to a desired working temperature (heated or cooled), by means of the heat and/or cold generator <NUM> placed in a heat exchange relationship with the hydraulic circuit <NUM>. The control system <NUM> of the heat and/or cold generator <NUM> (e.g., gas boiler or heat pump or geothermal generator) controls the activation, shutdown, and power adjustment of the heat and/or cold generator <NUM>, e.g., of a burner of a gas boiler or a compressor of a heat pump, as well as the activation, shutdown, and pumping speed adjustment of the circulation pump <NUM>.

The control system <NUM> controls the operation of the heat and/or cold generator <NUM> and the circulation pump <NUM> as a function of one or more temperature values selectable by a user by means of the user interface <NUM> or by means of an internal environment thermostat <NUM> with temperature selection function, as well as, possibly, as a function of values detected by one or more of an incoming water temperature sensor <NUM> at the inlet of the heat exchanger <NUM> of the heat and/or cold generator <NUM>, an outcoming water temperature sensor <NUM> at the exit of the heat exchanger <NUM> of the heat and/or cold generator <NUM>, an external ambient temperature sensor <NUM>, an internal ambient temperature sensor <NUM> (<FIG>).

Claim 1:
A heating or cooling system (<NUM>), in particular domestic, comprising:
a heat or cold generator (<NUM>) connectable in a heat exchange relationship to a hydraulic heating and/or cooling circuit (<NUM>),
a circulation pump (<NUM>), connectable to the hydraulic circuit (<NUM>), to convey a flow of water into the hydraulic circuit (<NUM>),
an electronic control system (<NUM>) in signal connection with the heat or cold generator (<NUM>) and with the circulation pump (<NUM>), to control the operation of the heat or cold generator (<NUM>) and the circulation pump (<NUM>),
characterized by comprising:
an air detection module (<NUM>, <NUM>') configured so as to perform an air detection process (<NUM>), comprising one or more air detection steps (<NUM>, ..., <NUM>.n), wherein:
- with the circulation pump (<NUM>) activated at a circulation speed, it detects a parameter (x) indicative of the flow rate of the water inside the hydraulic circuit (<NUM>),
- it collects a plurality of values (x_t) of the parameter (x) detected in a detection time interval,
- it calculates a variation (FlowRate_StdDev) of the plurality of values (x_t) collected in the detection time interval,
- it compares the calculated variation (FlowRate_StdDev) with a variation threshold value (Threshold_var) and:
if the calculated variation (FlowRate_StdDev) is greater than the variation threshold value (Threshold_var), it generates a notification signal of air presence in the hydraulic circuit (<NUM>), and
if the calculated variation (FlowRate_StdDev) is lower than the variation threshold value (Threshold_var), it does not generate the notification signal of air presence in the hydraulic circuit.