ITBO20130580A1 - SUCTION SYSTEM FOR AN INDUSTRIAL PLANT - Google Patents

Description

DESCRIPTION

SUCTION SYSTEM FOR AN INDUSTRIAL PLANT

The present invention relates to an aspiration system for an industrial plant, in particular an air handling system for operational purposes, i.e. not for mere ventilation.

Therefore, the present invention finds particular application in industry in general, in particular in those sectors in which it is necessary to provide for the removal of dust or fumes from the operating stations of the industrial plant, such as for example in chip removal processes, chemical plants , or other.

In the known art, such suction systems are known and used in various sectors, and they are all provided with a suction duct that extends from a first end, to which the suction means (an impeller or other) are associated, to a or more second ends, each provided with a suction mouth associated with a machine operating the plant.

Depending on the number of machines and their location, the duct can also be more than one and the suction means of different sizes. A valve or door is therefore associated with each mouth and is suitable for closing the opening in the event of a stoppage or malfunction of the respective operating station.

In order to drive the suction means, the known systems are provided with a control or processing unit associated with both the mouths and the suction means and configured to vary the power according to the pressure jump and the flow rate required by the current conditions. .

Note that the various components of the system are connected to each other both functionally and physically by means of wiring developed within the plant.

Clearly, this solution is more or less problematic depending on the size of the plant and the number of operating stations involved.

In other words, in extensive industrial plants with numerous operating machines, to which respective suction outlets are associated, the currently known solution is particularly expensive in terms of installation times and decidedly complicated from the logistical point of view. Moreover, the presence of cables inside the plant, which cannot always be adequately covered and insulated, reduces the reliability of the system itself as it increases the possibility of faults and damage.

Furthermore, it should be noted that the known suction systems present considerable difficulties in the control and efficiency of the suction.

In fact, these systems are sized to generate an air flow corresponding to the maximum requirements of the system, that is, during full operation of all the operating stations, a condition which, however, does not always materialize.

On the contrary, anyone who is used to the life of the plant knows that machine downtime, due to malfunctions or maintenance, are the order of the day, which often leads to poor efficiency of the suction system.

In fact, the control of the electric suction motor by means of an inverter often determines a constraint linked to the load curve to be satisfied, which is optimized for certain situations (e.g. steady operation) and not very efficient for others (e.g. few machines in operation. ).

The object of the present invention is to provide a suction system for industrial plants capable of overcoming the aforementioned drawbacks of the known art.

In particular, the object of the present invention is to provide a suction system for industrial plants that is easy to install and control.

Furthermore, it is an object of the present invention to provide a suction system for industrial plants that is reliable and has a lean layout and is easy to manage.

Moreover, the object of the present invention is also to make available a highly efficient and flexible suction system for industrial plants.

Said purposes are achieved by an aspiration system for an industrial plant provided with the characteristics of one or more of the subsequent claims, and in particular comprising an aspiration duct extending between an outlet mouth and one or more inlet openings, each associated with at least an operating station of an industrial plant, suction means associated with the outlet mouth of said duct and configured to generate a vacuum at said one or more inlet openings in order to perform a suction, sensor means associated with each inlet and configured to detect a pressure drop at said inlet and means for detecting the operating conditions of each operating station.

The system also comprises a processing unit operatively associated with the suction means, the sensor means and the detection means, arranged to receive from the sensor means and the detection means respective signals representative of the pressure drop and the operating conditions of each operating station. , programmed to calculate an operating condition of the suction means and configured to send a signal representative of the operating condition to the suction means.

According to the invention, the processing unit comprises a transceiver unit associated with transmission means for exchanging signals with them, a memory arranged to allocate data related to a plurality of operating curves of the suction means, a processing module connected to said transceiver unit and said memory is configured to vary the operating curve of the suction means as a function of a variation in the operating conditions of each operating station in order to define an operating condition of the suction means with low energy consumption.

In particular, the processing unit comprises a transceiver unit associated with said first and second wireless modules for exchanging signals with them, a memory designed to allocate data related to a plurality of operating curves of the suction means and a connected processing module to said transceiver unit and to said memory and configured to vary the operating curve of the suction means (or to select a more suitable operating curve) as a function of a variation in the operating conditions of each operating station (i.e. switching on or off) in order to define an operating condition of the low energy consumption suction means.

In other words, the processing unit (in particular the processing module) is programmed to modulate the load curve of the suction means (in particular the inverter) in order to optimize the energy consumption of the suction system, without compromising it. functionality.

Note that the operating curves of the suction means contained in the memory are load functions of the driving device, or of the inverter.

In other words, the operating curves are functions that correlate a value representative of the desired pressure jump with a value representative of the air flow to be managed.

In the preferred embodiment, the representative value of the pressure jump is defined by the inverter power supply voltage, while the representative value of the flow rate is defined by the frequency.

In this light, the memory has inside at least one first and a second operating curve, different from each other and optimized for a different flow rate value (ie frequency), ie for a different number of active operating stations.

The processing module is programmed to select, within said plurality allocated in the memory, the operating curve such that the suction means are able to generate the desired pressure jump with the required flow rate, minimizing its energy consumption.

According to another aspect of the invention, moreover, the system comprises means for transmitting signals, of the wireless type, provided with at least a first wireless module associated with the suction means and arranged to receive the signal representative of the operating condition calculated and sent by the processing unit and a second wireless module associated with the sensor means and configured to send to the processing unit the signal representing the pressure jump detected at each inlet.

Advantageously, in this way the detection of the operating conditions of the operating stations and the driving of the suction means takes place through the exchange of wireless signals with the processing unit, avoiding the installation and passage of long and cumbersome wiring inside. of the establishment.

Moreover, the absence of wiring considerably reduces the possibility of damage or breakage to the transmission system, making any failure of a single module immediately identifiable.

Each first and second wireless module therefore includes a transceiver group associated with the processing unit through a bidirectional (wireless) communication channel in order to exchange data with the processing unit itself.

It should be noted that, advantageously, the suction system according to the present invention is provided with at least two distinct wireless modules (first and second), each dedicated to treating respective types of input and output signals.

The first module is in fact dedicated to the driving of the suction means, and in particular to the transfer of the driving signal from the processing unit to the suction means and of the status signals (voltage and / or current and / or frequency) from the control means. suction to the processing unit. Therefore, the first module is arranged to receive from said suction means (equipped with an electric motor) one or more signals representative of the operating parameters of the electric motor and is configured to send to the electric motor itself (or to a driving device) a driving signal correlated to the operating condition calculated by the processing unit.

The second module is dedicated and associated with a respective inlet of the duct and is configured to receive a signal representative of the pressure jump from the pressure sensors and a signal representative of their position (i.e. the position of the movable partition) from valve means. , i.e. the opening / closing condition of the mouth.

Therefore, a second wireless transmission module is associated with each inlet port, which is responsible for exchanging data relating to the state of the mouth (pressure and position of the septum) with the processing unit. Note that the valve position is a parameter that is detected, and therefore sent by the second wireless module to the processing unit, which is set, and therefore sent by the processing unit to the second wireless module.

More precisely, the second wireless module is designed to receive from the valve means a signal representative of a detected position of the valve and configured to send to the valve means a signal representative of a valve position set by the processing unit.

Preferably, the second module is associated with both the respective input port and the corresponding operating station, to detect and send to the processing unit also a signal representative of the operating conditions of each operating station (start / stop and / or alarms).

More precisely, the second wireless module can also be associated with the aforementioned means for detecting the operating conditions of the operating station (ie its electrical panel).

It should be noted that, in some embodiments, the second wireless module is divided into two distinct modules, one associated with the inlet port to detect the pressure jump and drive the valve means, and the other associated with the operating station to send to the processing unit the aforementioned signal representative of the operating conditions of the operating station itself.

Preferably, the system also includes a third wireless module associated with an electrical panel of the industrial plant, configured to receive start / stop and / or system alarm signals from this general electrical panel and send them to the processing unit.

The aforesaid and other characteristics will become clearer from the exemplary and therefore non-limiting description of a preferred embodiment of the suction system for an industrial plant as illustrated in the attached figures, in which:

Figure 1 shows a schematic view of an aspiration system for an industrial plant according to the present invention;

- figures 2-5 schematically show some details of the suction system for an industrial plant of figure 1.

With reference to the attached figures, the number 1 indicates a suction system for an industrial plant "I" according to the present invention.

The term "industrial plant" in this text refers to a plant or a production or processing line equipped with one or more operating stations "S" (shown schematically) that require a suction action due to the generation of debris , dust, fumes, the release of chemical agents or other.

The industrial plant "I" is therefore equipped with its own general electrical panel "SB1" designed to power the plant (electrically) and equipped with emergency means (both manual and automatic) to allow the plant to stop in the event of a breakdown or in case of maintenance.

Furthermore, each operating station "S" is preferably equipped with its own specific electrical panel "SB2", also designed to power (electrically) the single operating station "S" and preferably equipped with emergency vehicles.

It should be noted that each operating station "S" is associated with means 23 for detecting the operating conditions of the operating station "S" itself, configured to detect its operating status (start / stop) and / or any alarms.

Said detection means 23 are preferably associated with the specific electrical panel "SB2" of the single operating station.

The suction system 1 according to the present invention is of the type capable of using air as an "operating means", or as a means of transporting the aforementioned debris, dust, fumes or the like.

In other words, the suction system 1 is not designed for the movement of air for ventilation or air conditioning purposes.

The suction system 1 therefore comprises a suction duct 2 extending between at least one outlet mouth 2a and one or more inlet openings 2b.

Each inlet 2b is associated with at least one respective operating station "S" of the industrial plant to allow the suction of the material.

In the illustrated embodiment, the duct 2 is provided with an outlet mouth 2a and a plurality of inlet openings 2b.

It should be noted that, preferably, the duct 2 is provided with a main pipe 3 (or manifold) and with a plurality of branches 4, each directed towards the respective operating station "S" (and therefore leading into the aforementioned inlet).

Therefore, preferably, the inlet openings 2b are arranged substantially in series with each other, each associated with the main pipe 3 through the respective branch 4.

The system 1 further comprises suction means 5 associated, preferably, with the outlet mouth 2a and configured to generate a depression in the duct such as to cause a suction effect (or suction) at each inlet mouth 2b.

Preferably, in correspondence with (or in proximity to) the outlet mouth 2a there is provided the presence of a filter 6 adapted to repair the suction means from the sucked material.

Furthermore, valve means 7 are preferably associated with each inlet mouth 2b, provided with at least one partition 7a (or wall) movable between an opening configuration, in which it allows the flow of material into the duct 2 through the respective inlet mouth. 2b, and a closure configuration, in which the opening of the mouth 2b is occluded (preferably in correspondence with a stationary state of the respective operating station "S").

Therefore, the valve means 7 are configured to allow the variation of the number of inlet ports 2b "active", ie open, according to the number of operating stations "S" actually in operation.

It should be noted that, in some embodiments, the valve means 7 are configured to allow positioning of the septum 7a also in intermediate positions between the opening and closing configurations, so as to vary and modulate the inlet section of the material in depending on the operating conditions of the respective operating station "S". In the preferred embodiment, the valve means 7 comprise a servomechanism (or actuator) 7b connected to the partition 7a to move it between the aforementioned opening and closing configurations.

Furthermore, means 7c for detecting the position of the septum 7a are preferably provided for detecting its position for control purposes.

Also associated with each inlet port 2b are sensor means 10 configured to detect a pressure drop at the respective inlet port 2b. Said sensor means 10 therefore comprise at least one pressure sensor for each inlet port 2b.

In the preferred embodiment, the pressure sensor is defined by is defined by a pressure detection sensor upstream of the valve and one downstream, so as to be able to detect the pressure jump at that point. If then it is positioned at the end of the line and therefore it is a suction mouth on the machine, the absolute pressure can be measured with respect to the external ambient pressure. Through this sensor and with the use of the laws of fluid dynamics it is possible to define the quantities involved, by defining the Reynolds number and the vortex state of the air motion to arrive at a fairly precise statistical determinative of the average speed of the air flow. at that point. Alternatively, the pressure sensor could also be of another nature. It should be noted that it could be installed upstream or downstream of the filter so as to be able to give a feedback data also relating to the clogging status of the filters, so that also on the basis of this data it is possible to have a considerable advantage in the regulation and therefore in the Suction efficiency especially in non-self-cleaning filters continuously.

As mentioned, suction means 5 are associated with the outlet 2a of the duct.

Said suction means 5 are, as mentioned, configured to generate a predetermined depression at each inlet mouth 2b.

In the preferred embodiment, the suction means comprise at least one impeller (not shown) and an actuator member 5a associated with the impeller to make it rotate.

Preferably, the actuator member 5a is of the electrical type. In other words, the actuator member 5a is preferably defined by an electric motor 8. The electric motor 8 is therefore associated with a driving device 9 configured to vary the operating parameters of the electric motor as a function of a driving signal. Therefore, the suction means 5 comprise a driving device 9 associated with the electric motor 8 to drive it.

In the preferred embodiment, the driving device 9 is defined by an inverter 9a.

In this regard, the suction system 1 comprises a processing unit 11 operatively associated with the suction means 5, the sensor means 10 and the detection means 23 (and possibly the detection means 7c) and configured to drive the suction means 5 ( and possibly the valve means 7) depending on the operating condition of the industrial plant "I".

More precisely, the processing unit 11 is arranged to receive from the sensor means 10 and from the detection means 23 respective signals representative of the pressure jump and of the operating conditions of each operating station "S" (i.e. operating regime and / or stop machine).

According to these signals representative of the pressure jump and the operating conditions of each operating station "S", the processing unit 11 is programmed to calculate an operating condition of the suction means 5.

More precisely, the processing unit 11 is programmed to calculate an operating point of the suction means 5 such that the same suction means 5 are capable of generating a sufficient (preferably optimal) depression to determine a suction condition at the inlet ports 2b active (ie the corresponding operating stations "S" are in operation).

The processing unit 11 is therefore configured to send a signal representative of said operating condition to the suction means 5 for driving it.

Preferably, moreover, the processing unit 11 is configured to drive the servomechanism 7b of the valve means 7 of each inlet port 2b as a function of the signals representative of the pressure jump received by the sensor means 10 and / or of the signals representative of the conditions operational of each operating station "S".

Advantageously, in this way, the processing unit 11 can independently control the closure of the septum 7a of an inlet 2b in correspondence with a non-functioning operating station "S".

According to the invention, the processing unit 11 is connected to the other elements of the suction system 1 by means of wireless transmission means 12.

These wireless transmission means 12 are therefore configured to put the processing unit 11 in communication at least with the suction means 5 and with the inlets 2b of the duct 2 by means of wireless communication channels.

In this regard, the wireless communication means 12 comprise at least a first wireless module 13 associated with the suction means 5 arranged to receive, from the processing unit 11, the aforementioned signal representative of the operating condition and at least a second wireless module 14 associated with the sensor means 10 and configured to send to the processing unit 11 the signal representing the pressure jump (at the respective outlet).

It should be noted that the wireless transmission means 12 comprise a second wireless module 14 associated with each inlet 2b of the duct 2.

Therefore, each first 13 and second wireless module 14 comprises a transceiver group 13a, 14a associated with the processing unit 11 (i.e. designed to communicate with it) through a bidirectional communication channel in order to exchange data with the processing unit 11 itself.

The first wireless module 13 is distinct from the second wireless module 14, in that they are designed to manage different signals.

In fact, the first wireless module 13 is dedicated to driving the suction means 5.

In particular, the first wireless module 13 is responsible for transferring the driving signal (of the suction means 5) from the processing unit 11 to the suction means 5 and of the status signals (voltage and / or current and / or frequency) from the suction means 5 to the processing unit 11 (ie in the reverse direction along the aforementioned bidirectional communication channel).

Therefore, the first wireless module 13 is arranged to receive from the suction means 5 (in particular from an electric motor 8) one or more signals representing the operating parameters of the electric motor 8 and to send (by means of the transceiver unit 13a) such one or more signals to the processing unit 11.

Furthermore, this first wireless module 13 is arranged to receive from the processing unit 11 (by means of the transceiver unit 13a) the signal representing the operating condition of the suction means 5 and configured to send to the suction means 5 themselves (i.e. to the electric motor 8) a driving signal correlated to said operating condition calculated by the processing unit.

More precisely, the first wireless module 13 is configured to send the driving signal to the driving device 9 of the electric motor 8 (or to the inverter 9a).

Therefore, the first wireless module 13 comprises an interface group 13b configured to exchange data (i.e. signals) with the suction means 5 and connected to the aforementioned transceiver group 13a (which is configured to exchange wireless signals with the processing unit 11).

Said interface assembly 13b is therefore provided with at least one input 15 connected to said electric motor 8 to receive one or more signals representative of the operating parameters of the same motor 8 and at least one output 16 connected to said driving device 9 (i.e. inverter 9a) to send said driving signal.

In the preferred embodiment, the interface group 13b of the first wireless module 13 comprises at least three inputs 15 suitable for receiving signals representing respectively the voltage, absorption and operating frequency of the electric motor 8.

The second wireless module 14 is, as already mentioned, dedicated and associated with a respective inlet 2b of the duct 2 and configured to receive from the sensor means 10 a signal representative of the pressure jump.

Preferably, the second wireless module 14 is also associated with the valve means 7 of the respective inlet port 2b and arranged to receive a signal representative of their condition (i.e. of the opening / closing position of the septum 7a).

In other words, a second wireless module 14 is associated with each inlet port 2b which is responsible for exchanging data relating to the state of the inlet port 2b (pressure jump and valve position) with the processing unit 11.

Moreover, in a preferred embodiment, this second wireless module 14 is arranged to receive from the processing unit 11 (by means of the transceiver unit 14a) a signal representative of a condition of the valve means 7 (i.e. of the position of the septum 7a) calculated by processing unit 11.

Note that the valve position is a parameter that is detected, and therefore sent by the second wireless module 14 to the processing unit 11, which is set, and therefore sent by the processing unit 11 to the second wireless module 14.

In fact, the second wireless module 14 is arranged to receive from the valve means 7 a signal representative of a detected position of the septum 7a and configured to send to the valve means 7 themselves (or to the servomechanism 7b) a signal representative of a position of the septum. 7a set (or calculated) by the processing unit 11.

In this regard, the second wireless module 14 comprises an interface assembly 14b configured to exchange data (ie signals) with the valve means 7 and with the sensor means 10.

This interface group 14b of the second wireless module 14 is therefore connected to the respective transceiver group 14a (which is configured to exchange wireless signals with the processing unit 11).

This interface assembly 14b of the second wireless module is therefore provided with at least two inputs 17 connected to the sensor means 10 and to the valve means 7 to receive signals representing the pressure jump and the position of the septum 7a, and with at least one output 18 connected to the servomechanism 7b of the valve means 7 to drive the septum 7a as a function of the signal received by the processing unit 11.

In the preferred embodiment, the second wireless module 14 is also connected to the operating station "S" of the respective input port 2b to receive a signal representative of the operating conditions of the operating station "S" itself.

More precisely, the interface group 14b of the second wireless module 14 comprises a third input designed to receive this signal to transmit it to the transceiver group 14a (and therefore to the processing unit 11).

In the illustrated embodiment, however, the presence of an auxiliary wireless module 24 associated with the specific electrical panel "SB2" (ie the detection means 23) of the operating station "S" and equipped with its own transceiver unit 18a is provided for transmit this signal representative of the operating conditions of the operating station "S" to the processing unit 11.

In other words, in this embodiment, the second wireless module 14 is divided into two distinct modules, that is the second true wireless module 14 and the auxiliary wireless module 18.

Preferably, the wireless transmission means 12 also comprise a third wireless module 19 associated with the general electrical panel "SB1" of the industrial plant "I", configured to receive start / stop and / or stop signals from this electrical panel "SB" system alarm and send them to the processing unit.

In detail, the third wireless module 19 is also provided with a transceiver unit 19a.

Furthermore, the third wireless module 19 also comprises its own interface group 19b connected to the transceiver group 19a.

The interface group 19b is connected to the general electrical panel "SB1" and arranged to receive from said electrical panel start / stop and / or alarm signals of the system and configured to send these signals to the transceiver group 19a, which exchanges said signals with the processing unit 11.

Therefore, the interface group 19b of the third wireless module 19 is provided with at least two inputs 20, associated with the general electrical panel "SB1" to receive a first signal representative of the stop or start of system 1 or system "I" and a second alarm signal, and at least one output to command the general electrical panel "SB1" to emit an alarm signal.

Advantageously, in this way, in the event of a fault or alarm it is sufficient for the operator to act on the general electrical panel "SB1" to obtain a complete shutdown of both the "I" system and the suction system 1.

Therefore, the processing unit 11 is programmed to manage or drive the suction means 5 (and the valve means 7) according to:

- the pressure jump at each inlet 2b detected by the sensor means 10;

- the operating conditions of each operating station "S" detected by the detection means;

- the ignition / shutdown conditions of the "I" system detected by the general electrical panel "SB1";

- a load curve of the driving device 9 of the electric motor 8. In other words,

Therefore, the processing unit comprises a transceiver group 11a associated with the first 13 and the second wireless module 14 to exchange signals with them.

This transceiver unit 11a is provided with a plurality of inputs designed to receive at least:

- said signal representing the pressure jump detected by the sensor means 10, by said second wireless module 14 and / or

- said signals representative of the operating parameters of the electric motor 8 from the first wireless module 13, and / or

- said signal representative of the operating condition of each operating station "S", of the second wireless module 14 or from auxiliary module 18, and / or

- said signal representative of the condition of the system "I" (start / stop / alarm) from the third wireless module 19.

Furthermore, this transceiver unit 11a is provided with a plurality of outputs, connected to the wireless modules 13, 14 and 19.

In particular, the issues are designed to transmit:

- a driving signal of the inverter 9a to the first wireless module 13, and / or - a signal representative of an inverter operating curve (as will be better explained below) to the first wireless module 13, and / or - a signal representative of the position of the septum 7a to the second wireless module.

Note that the operating curve (or load) of the driving device 9 (or inverter 9a) can be modulated, i.e. variable by the processing unit 11 according to the detected variables and the required performances (flow rate and pressure jump) .

Advantageously, using an inverter 9a as driving device 9 (with continuous feed back of the frequency Volt Ampere Herz status and general status of the machine through various secondary parameters), it is possible to obtain a new and customized working curve or set of points of work that returned to the inverter no longer as data of actual operation and status but as work positions can greatly expand the range of air flow with pressures suitable for the work required of the mechanical collection of pollutants by the air itself.

In this regard, the processing unit 11 comprises a memory 11c designed to allocate data related to a plurality of operating curves of the suction means 5 and a processing module 11b connected to the transceiver unit 11a and to the memory 11c.

This processing module 11b is configured to vary the operating curve of the suction means 5 as a function of a variation in the operating conditions of each operating station (i.e. switching on / off / failure) in order to define an operating condition of the suction means 5 a low energy consumption.

In particular, the operating curves of the suction means 5 contained in the memory (or calculated instantaneously by the processing module 11b) of the processing unit 11 each correspond to a load curve of the driving device 9 (or of the inverter 9a). correlated to a predetermined number of active operating stations.

In other words, if an operating curve (or load curve) optimized for these conditions corresponds to a maximum steady state condition (all active operating stations), in a partial steady state condition (only some active operating stations) this curve entails excessive energy consumption (and suction).

Therefore, the processing module 11b selects another operating curve more suitable for this condition (or, it calculates it instantly).

It should be noted that the operating curves of the suction means 5 (ie of the piloting device 9) are functions which correlate a value representative of the desired pressure jump as a function of a value representative of the air flow to be managed.

In the preferred embodiment, in which the driving device 9 is an inverter 9a, the operating curves correlate the power supply voltage of the inverter 9a with the frequency.

Therefore, the processing module 11b is programmed to select, within said plurality allocated in the memory 11c, the operating curve such that the suction means 5 are able to generate the desired pressure jump with the required flow rate, minimizing your energy consumption.

In practice, once a position of necessary flow has been commanded, with the use of frequency modulation, and the pressure value read from the sensors, the known value of the voltage will be modulated (as said before continuous feed back of the inverter to the PLC panel) to modulate it to obtain the desired pressures, if this does not lead to over-absorption of the system (this too can be deduced from the feed back in absorbed Amps) thus being able to establish a correct operating point.

In detail, the regulation of the air flow according to the known technology takes place through the use of the known HVAC or general ventilation curves, which are however designed for almost laminar or pseudolaminar motion and therefore for low or very low speeds in order to obtain regulation of air flows where the only concern is substantially the flow rate and not its prevalence.

On the other hand, since air is a mechanical means of transport for this project, for this to happen, the specification of the pressure is important.

Preferably, the processing unit 11 is programmed by setting some operating parameters, more preferably selected from the following list:

- maximum working frequency (then parameterized as 100%);

- minimum working frequency (then parameterized as 50%);

- project scope for each operating station "S";

- maximum project flow rate of plant "I";

- "anti-implosion" frequency variation, that is the value of the decrease in working frequency in which the opening of a safety valve is necessary;

- a correction parameter for the clogging of filter 6;

- a cleaning frequency parameter of duct 2;

- a duration parameter for cleaning the duct 2;

- a parameter related to the cost of energy;

- rated power of the suction means 5;

As already mentioned above, it is emphasized that the frequency is related to the air flow.

Therefore, the maximum frequency corresponds in logic to a value of the maximum design flow rate (greater than or equal to it).

Operationally, the processing module 11b is programmed to add the flow rate values assigned to the active operating stations "S" and to set the required flow parameter.

Furthermore, the processing module 11b is programmed to compare this value with the maximum design power.

If the value is below 50%, the processing unit 11 sets the minimum working frequency.

If this value is equal or greater, the processing unit 11 sets the maximum working frequency.

For each intermediate value, the processing unit 11 is programmed to proportionally calculate the frequency value starting from the maximum working frequency.

If the required flow rate exceeds the maximum design flow rate, the processing unit 11 is set to consider the flow rate as if it were the maximum design flow rate.

The value of the required flow rate must be corrected by the value of the differential pressure switch on a proportional basis, where the parameter entered gives 100% as a basis. If there is no input value or the values are higher than the set parameter, keep 100%, if instead you have the input data, the required pressure is decreased with a proportional value.

It is important to remember that inverter 9a does not activate when the "SB1" general electrical panel is started, but only processing unit 11 starts with it.

Inverter 9a is activated only when the first operating station "S" is started, and turns off when all operating stations "S" are switched off regardless of pressing the stop key on the main panel (ie if no operating station "S" works then the inverter 9a must be switched off).

The invention achieves the intended purposes and achieves important advantages. In fact, the suction system according to the present invention, being equipped with a processing unit capable of wirelessly communicating with the sensors and drives, is as simple to install as it is to manage.

In addition, the total absence of wiring inside the industrial plant, in addition to increasing the reliability of the data transmission means, reduces construction and installation costs for the manufacturer.

Moreover, the presence of dedicated wireless transmission modules for the various elements involved in the suction (suction means, valve means and electrical panels) makes it possible to make suction control highly efficient and easily manageable.

Claims (10)

CLAIMS 1. Suction system for an industrial plant, comprising: - a suction duct (2) extending between an outlet mouth (2a) and one or more inlet openings (2b), each associated with at least one operating station (S) of an industrial plant (I); - suction means (5) associated with the outlet mouth (2a) of said duct (2) and configured to generate a depression at said one or more inlet openings (2b) in order to perform a suction; - sensor means (10) associated with each inlet port (2b) and configured to detect a pressure jump at the inlet port (2b) itself; - means for detecting (23) the operating conditions of each operating station (S); - a processing unit (11): operatively associated with said suction means (5), with said sensor means (10) and with said detection means (23), arranged to receive from the sensor means (10) and from the detection means (23) respective signals representative of the pressure drop and of the operating conditions of each operating station (S); programmed to calculate an operating condition of the suction means (5) e configured to send to said suction means (5) a signal representative of said operating condition; - transmission means (12) of said signals between the processing unit (11) and said suction means (5), said sensor means (10) and said detection means (23), characterized in that said processing unit (11) comprises: - a transceiver unit (11a) associated with said transmission means (12) to exchange signals with them, - a memory (11c) arranged to allocate data correlated to a plurality of operating curves of the suction means (5); - a processing module (11b) connected to said transceiver unit (11a) and to said memory (11c) and configured to vary the operating curve of the suction means (5) according to a variation of the operating conditions of each operating station ( S) in order to define an operating condition of the low energy consumption suction means (5). 2. Suction system according to claim 1, characterized in that the suction means (5) comprise at least one impeller (5a), an electric motor (8) connected to said impeller (5a) to make it rotate and a driving device (9) of said electric motor (8); said operating curves of the suction means (5) contained in the memory (11c) of the processing unit (11) each corresponding to a load curve of said driving device (9) correlated to a predetermined number of operating stations (S ) active. 3. Suction system according to claim 1 or 2, characterized in that said operating curves of the suction means (5) are functions that correlate a value representative of the desired pressure jump as a function of a value representative of the flow rate air to manage. 4. Suction system according to claim 3, characterized in that said processing module (11b) is programmed to select, within said plurality allocated in the memory (11c), the operating curve such that the suction means (5) are able to generate the desired pressure jump with the required flow rate while minimizing their energy consumption. 5. Suction system according to any one of the preceding claims, comprising valve means (7) associated with each inlet mouth (2b) and provided with a septum (7a) selectively movable between an open position and a closed position. 6. Suction system according to any one of the preceding claims, characterized in that said transmission means (12) are of the wireless type and comprise: at least a first wireless module (12) associated with the suction means (5) designed to receive said signal representative of said operating condition from the processing unit (11); at least a second wireless module (14) associated with said sensor means (10) and configured to send said signal representative of the pressure jump to the processing unit (11). Suction system according to claim 6, wherein each first (13) and second wireless module (14) comprises a transceiver unit (13a, 14a) associated with said processing unit (11) through a bidirectional communication channel to the in order to exchange data with the processing unit (11) itself. 8. Suction system according to claim 6 or 7, wherein said suction means (5) comprise at least one impeller (5a), an electric motor (8) connected to said impeller (5a) to make it rotate and a device for driving (9) of said electric motor (8); said first wireless module (13) being provided with at least one interface unit (13b) connected to the transceiver unit (13a) and arranged to receive from said electric motor (8) one or more signals representing the operating parameters of the electric motor itself (8) and configured to send to the driving device (9) of the electric motor (8) a driving signal related to said operating condition calculated by the processing unit (11). 9. Suction system according to claim 8, characterized in that said second wireless module (14) is associated with the valve means (7) of the respective inlet (2b), arranged to receive a signal representative of the position of the septum ( 7a) and configured to send to said valve means (7) a signal representative of a position of said septum (7a) set by said processing unit (11). 10. Suction system according to any one of the preceding claims, in which the wireless transmission means (12) comprise a third wireless module (19) which can be associated with an electrical panel (SB1) of the industrial plant (I), designed to receive from said electrical panel (SB1) at least one signal representative of a status condition of the industrial plant (I) and / or of an alarm condition.