DE102016119735A1 - Method for determining and / or monitoring the efficiency of a compressed air system - Google Patents

Abstract

The invention relates to a method for determining and / or monitoring the efficiency of a compressed air system. The compressed air system has at least one compressor for generating compressed air and the method comprises at least the following method steps determining the load (t) and idle time (t) within a predefinable period of time (t) for the at least one compressor (2);

Description

The invention relates to a method for determining and / or monitoring the efficiency of a compressed air system. Compressed air systems are used in a variety of applications, for example in process and automation technology; For example, for cooling (here is exploited that a gas cools at a pressure drop), for the separation of nitrogen from the air, or as an energy source.

The compressed air system has at least one compressor for generating compressed air. The compressor presses in a compression process an existing intake volume V ₁ with an operating pressure p ₁ to a smaller volume V ₂ together, typically by means of an electrically driven motor, so that in the smaller volume V _2, an elevated pressure p ₂ prevails. In the context of this application rigid compressors and controllable or frequency-controlled compressors are provided; These are known in principle from the prior art. Frequency-controlled compressors are also referred to as "variable-speed-drive" compressors, or VSD compressors for short.

A rigid compressor is alternately in load and idle. For example, the rigid compressor is initially in the load run until the compressed air has reached a predetermined pressure; then the electric motor of the rigid compressor is turned off. The compressed air is optionally fed into a reservoir with higher pressure. As a result, any hysteresis effects can be compensated. The change between load or idle of the rigid compressor is controlled by a higher-level control unit.

In contrast, VSD compressors have a variable duty cycle, i. a VSD compressor may be idle, but may also be 20%, 40%, etc. in the load. By allowing the engine of a VSD compressor to be limited to a maximum required speed instead of periodically switching between load and idle, like a rigid compressor, VSD compressors typically have a lower average energy consumption than rigid compressors. Since they also cause lower energy costs, VSD compressors are in principle preferable, but are used less often than rigid compressors due to the initially higher purchase costs. Since the failure of a compressor can cause great damage, one or more redundant compressors are often used in safety-relevant aspects: if one of the compressors fails, the compressed air is supplied by a compressor redundant to the compressor.

Since the generation of compressed air is extremely energy-intensive, the increase in energy efficiency in compressed air systems is increasingly required, in particular in special guidelines for certification measures. Therefore, the safety-relevant aspects are faced with the requirement to continuously monitor and increase the energy efficiency of the compressed air system. When using redundant compressors, the potential for increasing energy efficiency is particularly great. It often happens that a compressed air system or the control and / or regulation of the compressed air system with respect to a particular application and / or system conditions (such as given, physically present conditions such as temperature, pressure, humidity, etc.) is designed , Not always will be made in any change in the specific application and / or conditions of use, an adaptation of the compressed air system or the control of the compressed air system. Also in this case there is great potential for increasing energy efficiency. Also, replacing a rigid compressor with a VSD compressor can often increase energy efficiency.

In order to monitor energy efficiency, additional measurements on or in the compressed air system are often necessary. This is not always desirable, on the one hand, because interventions in the compressed air system should be avoided, depending on the application, since a shutdown of a process plant is in principle associated with high costs. On the other hand, because every additional meter required for the measurement also consumes additional energy.

The invention is therefore based on the object of specifying a method with which the efficiency of the compressed air system, in particular the energy efficiency, as possible determined and / or monitored without interference with the compressed air system.

• - Ermittlung der Last- und Leerlaufzeit in einer vorgebbaren Zeitspanne für den mindestens einen Kompressor;
• - Bestimmung zumindest einer Diagnosegröße zur Beurteilung der Effizienz des Kompressors und/oder des Druckluftsystems in der vorgebbaren Zeitspanne, wobei die zumindest eine Diagnosegröße im Wesentlichen anhand der Last- und Leerlaufzeit des Kompressor/der Kompressoren in der vorgebbaren Zeitspanne bestimmt wird.

The object is achieved by a method for determining and / or monitoring the efficiency of a compressed air system, wherein the compressed air system has at least one compressor for generating compressed air, and wherein the method comprises at least the following method steps:

• - Determining the load and idle time in a predetermined period of time for the at least one compressor;
• Determining at least one diagnostic variable for assessing the efficiency of the compressor and / or the compressed air system in the predeterminable time span, wherein the at least one Diagnostic variable is determined essentially based on the load and idle time of the compressor / compressors in the predetermined period of time.

The compressed air system can also have more than one compressor, for example, two or more compressors- Since the compressor is either in the load or idle, the idle time results from the total operating time (or the predetermined period) minus the load time. Typically, commercial compressors are designed so that the operating and idle times are displayed directly and can therefore be read. It is of course also possible that the compressor only displays the load time. The idle time and the operating time is read from the count of the compressor or from the change in the count of the compressor within the predetermined period of time.

The predefinable time span is typically a time interval of at least one week. In the simplest case, the diagnostic variable is the load and idle time of the compressor / compressors themselves. Preferably, the load and idle times of all present in the compressed air system compressors are determined and taken into account in the determination of the diagnostic size for the compressed air system.

The diagnostic variable is always initially related to the predefinable period of time. For better comparability, if necessary, the load and idle times or the diagnostic variable determined therefrom are normalized to a time interval such as, for example, monthly and / or annual values.

In this way, in the method according to the invention, the efficiency is determined solely on the basis of the read load times or idle times, without the need for additional measurements in / on the compressed air system for assessing energy efficiency.

In one embodiment of the method, the diagnostic variable is additionally determined on the basis of stored and / or measured dependencies of the diagnostic variable on the load and / or idle time, and wherein the stored and / or measured dependencies result from the specific configuration of the compressor / compressors.

The stored dependencies on the load and / or idle time are, for example, the absorbed electrical power of the compressor or the compressed air system. The deposited dependencies depend on the specific design of the compressor or compressors such as the type of compressor. Typically, all technical data such as the capacity of the compressor in the load P _last and the power of the compressor in idle P are stored _empty in a data sheet. If the capacity of the compressor at idle P _{empty is} not specified, it is estimated as a fraction of P _last (eg 1/3 P _load ). The volume flow φ of the compressor or the delivered amount of compressed air per time during load is usually stored in such a data sheet. The volume flow φ depends on the pressure level eg 7bar; 7,5bar, etc. and is usually specified by the ISO1217 certification guideline.

For the purposes of this application, "data sheet" refers to the amount of all available compressor-specific technical data, which are published or provided, for example, by the manufacturer of the compressor. Of course, this data may also be available in another form, for example by being recorded in a database located on a server.

Alternatively, these dependencies can also be measured in addition or to increase the accuracy, for example before commissioning of the compressed air system, and then deposited in a higher-level unit.

In one embodiment of the method according to the invention, the diagnostic quantity is the electrical energy absorbed by the compressor (s) in the predeterminable period of time. The diagnostic quantity is therefore the total electrical energy E _ges recorded in the predefinable time span, ie in load and idle mode.

In the context of this application, "absorbed electrical energy / power" refers to the energy / power consumed by the compressor.

The diagnostic quantity may also be the electrical energy consumed in the load or idle by the compressor (s) during the predefined period of time. The power consumed by the compressor electrical energy in the power running E _load or idle E _empty is calculated from the stored specifications P _load and P _empty and the load and idle times t _load and t _empty substantially as follows: E _last = P _load * t _last or E _empty = P _empty * t _empty . The total energy absorbed by the compressor is then E _ges = E _last + E _empty .

The diagnosis variable may also be the amount of compressed air V delivered by the compressor (s) in the predefinable time period. This is calculated from the stored volume flow (or the amount of compressed air per time) φ in Load and load time determined as follows: V = φ * t _last

In a particularly advantageous embodiment of the method according to the invention, the diagnostic quantity is a specific characteristic number for assessing the energy efficiency of the compressor (s) within the predefinable time span. In determining the specific characteristic number, the quotient of the electrical energy absorbed by the compressor in the predefinable time period and the amount of compressed air supplied by the compressor is formed within the predefinable time span.

In forming the quotient E _ges / V, the amount of compressed air supplied by the compressor is set in relation to the total energy consumed by the compressor. The smaller the quotient, the more energy-efficient the compressor will be in the predefined time span. The characteristic K is, for example, proportional or antiproportional to the quotient, but can of course be any algebraic function (for example, an n-th degree polynomial) or else a transcendental function (for example, an exponential or logarithmic function) of the quotient. The specific characteristic number of the compressor is therefore a direct measure for assessing the energy efficiency of the respective compressor.

In one embodiment, the diagnostic quantity is the degree of utilization of the compressor (s) within the predetermined time span: in the event that the compressor is a rigid compressor, the quotient is determined when determining the degree of utilization of the fixed compressor the load time of the compressor in the predetermined period of time and the predetermined period of time formed.

In an advantageous embodiment, the diagnostic quantity is the degree of utilization of the compressor / compressors in the predeterminable time span: in the event that the compressor is a controllable compressor, the determination of the degree of utilization of the controllable compressor uses the in determines the average utilization that prevails over the predefined period of time. If the compressed air system also includes such a controllable compressor, which is controlled by a higher-level control unit, the utilization rate is calculated as the average utilization. In this embodiment, the diagnostic variable also provides an indication of the need for adaptation of the VSD control to regulate the controllable compressor.

In an advantageous embodiment, therefore, the diagnostic quantity is a characteristic number specific to the compressed air system for assessing the energy efficiency of the compressed air system, wherein the quotient of the electrical energy consumed by all the compressors in the predefinable time period and the amount of compressed air supplied by all compressors of the compressed air system is formed in the predetermined period of time.

A compressed air system typically includes not only a certain number of rigid or VSD compressors, but also other consumers called ancillary devices which additionally receive electrical energy. These include, for example, dryers, fans, pumps, filters and possibly heaters. Therefore, it is advantageous if the electrical energy absorbed by the entire compressed air system is determined and balanced.

In this embodiment, the specific code is therefore for the entire compressed air system. In a similar manner as the electrical energy absorbed by the compressors, the electrical energy consumed by the ancillary components is also determined on the basis of running and load times of the auxiliary units and stored dependencies.

Here, too, the following applies: When forming the quotient E _S / V, the amount of compressed air supplied by the compressed air system is set in relation to the total energy absorbed by the compressed air system. The characteristic K _{S of} the compressed air system is for example proportional or anti-proportional to the quotient, but can of course be any algebraic function (for example, an n-th degree polynomial) or else a transcendental function (for example, an exponential or logarithmic function) of the quotient. The characteristic number specific to the compressed air system is thus a direct measure of the energy efficiency of the respective compressed air system.

Depending on the embodiment of the method according to the invention, the specific parameters are available for all compressors as well as for the entire compressed air system.

In addition to the increase in energy efficiency can be done in the context of the method according to the invention on the basis of the systematic determination of the recorded from the compressor / compressors / compressed air system electrical energy and an assessment of the economics of the compressor / compressors / the compressed air system.

• - die Kosten zur Bereitstellung der von mindestens einem Kompressor aufgenommenen elektrischen Energie und/oder;
• - die Kosten zur Bereitstellung der von mindestens einem Kompressor aufgenommenen elektrischen Energie im Last- und/oder Leerlauf und/oder
• - die Kosten zur Bereitstellung der vom dem Druckluftsystem aufgenommenen elektrischen Energie.

In an advantageous development, the energy prices are therefore additionally determined. The diagnostic size is then

• the cost of providing the electrical energy consumed by at least one compressor and / or;
• - The cost of providing the recorded by at least one compressor electrical energy in the load and / or idle and / or
• - The cost of providing the electrical energy absorbed by the compressed air system.

In a particularly advantageous embodiment, the method can be executed by a user at least partially as an application program on a mobile terminal, the mobile terminal preferably being a laptop, a smartphone, a tablet computer, or data glasses. The application program advantageously requires little or no measures for installing the application program and is compatible with the most common operating systems of today's widespread mobile terminals (for example Apple iOS, Android, Windows 10 Mobile, Blackberry OS).

The inventive method uses a computer program which runs at least partially as an application program on a mobile terminal. In particular, it is provided in the context of the invention that the input of the load and operating times of the compressor / compressors are made in the computer program using the mobile terminal. It is also advantageous in this embodiment that, if appropriate, an indication or message concerning the at least one specific diagnostic variable takes place via the mobile terminal.

Of course, the computer program can also be partially executed on a non-mobile PC. In this embodiment, the computer program can also be partially executed on a remote from the compressed air system computer or possibly data center, for example, if calculations for determining the at least one diagnostic size require a reference to data sheets with respect to the compressors, which are not available on the mobile terminal , The communication of the computer program on the mobile terminal with the non-mobile PC can take place via a USB, HDMI, LAN, or a Bluetooth interface and / or via the Internet. The communication of the computer program on the mobile terminal and / or the non-mobile PC with the remote computer or possibly data center takes place via the Internet.

In this embodiment, the input of the load times of the compressor / compressors and the predeterminable period of time initially without an existing communication channel with the non-mobile PC, the remote computer or possibly computer center done, for example, if there is no Internet connection (ie in offline mode ). If further method steps require communication with the remote computer or, if appropriate, the data center, then, if appropriate, they can be executed at a later time, in the event that a communication channel such as, for example, an Internet connection then exists.

Of course, other, known from the prior art communication channels between the mobile terminal, the non-mobile PC and / or the remote computer or data center are possible.

In one embodiment of the method according to the invention, the time profile of the diagnostic variable is stored for at least one diagnostic variable.

In a further development of the method according to the invention, a further diagnostic variable is the temporal change of the diagnostic variable. For example, not only the specific characteristic number for the at least one compressor, but also the temporal change of the specific characteristic number is used as a diagnostic variable.

In one embodiment of the method according to the invention, the identification of the compressor and based on at least one mounted on the compressor optical code, wherein the optical code is preferably a QR code and / or a bar code. The QR code can be scanned with the mobile device, for example. In this way, with the application program in a simple manner the associated (for example, read) associated with the respective compressor deposited at the designated location.

The identification can also be based on the location of the compressor.

The identification can also be made on the basis of the type designation and / or the serial number of the compressor.

In a further embodiment of the inventors, the application program communicates with a database independent of the compressed air system on the basis of an Internet connection. At least one of the diagnostic variables is stored in the database and / or with one in the database stored setpoint value for the diagnostic variable is compared. Within the scope of this application, the setpoint is also the indication of an interval in which the diagnosis variable should be in the optimal case.

The database is assigned to a server, for example. In the database, on the one hand, the diagnostic size of the user is stored (for example, in a designated first section). On the other hand, setpoint values for the diagnostic quantity (for example, in a second section) are also present in the database which, if appropriate as a function of the application, contain knowledge formed from empirical values. The database may also include the aforementioned compressor-specific datasheets (for example, in a third section).

Also in this embodiment, the load and idle times are determined after entering the load time and the predefinable period of time (and possibly without an existing Internet connection) and the diagnostic size is stored in the database stored setpoints then takes place with an existing Internet connection, possibly at a later date.

The ideal degree of utilization of a compressor is dependent on the specific design of the compressed air system. Since the specific embodiment can typically be classified according to specific criteria such as the size of the compressed air system, field of application, etc., the comparison of the diagnostic variable with the empirical values stored in the database is particularly advantageous since the operator of the respective compressed air system no longer has his own Must build up experience knowledge. For example, a degree of utilization of a compressor of less than 70% is an indication of optimization approaches and potential savings.

Optionally, the actual load and / or idle power may differ from the specifications given by the manufacturer. This is due to the fact that compressors are designed by the manufacturers for worst-case scenarios under the safety-related aspects mentioned above, which are rarely achieved in actual applications. Therefore, the knowledge of the knowledge contained in the database may also include the actual load and / or idle power, optionally depending on the type of application and / or the particular conditions specific to the application.

Based on the diagnostic size and / or the comparison of at least one diagnostic variable with the stored setpoint, an inefficient utilization, control and / or control routine of the compressed air system is made visible.

• - eine Einsparung der von dem zumindest einen Kompressoren/von den Kompressoren und/oder von dem Druckluftsystem aufgenommenen elektrischen Energie im Falle einer Behebung von Leckagen,
• - eine Einsparung der von dem zumindest einen Kompressoren/von den Kompressoren und/oder von dem Druckluftsystem verursachten Kosten im Falle einer Behebung von Leckagen und/oder
• - ein Zeitpunkt für eine Überprüfung über das Vorliegen von Leckagen und/oder
• - ein Zeitpunkt für das Beheben von Leckagen ermittelt wird.

In a development of this embodiment, therefore, based on the at least one diagnostic variable and / or the comparison of at least one diagnostic variable with the stored nominal value

• a saving of the electrical energy received by the at least one compressor (s) from the compressors and / or by the compressed air system in the event of a leak being remedied,
• a saving on the costs caused by the at least one compressor (s) and / or by the compressed air system in the event of leakage repair and / or
• a time to check for the presence of leaks and / or
• - A time for correcting leaks is determined.

In this development, savings potentials are visualized and evaluated: the savings that result from a leakage measure (i.e., the systematic check for the presence of a leak and possibly the removal of a leak) are determined. These savings can then be compared with the costs associated with a leakage measure. Since the leakage measure may require flow measurement at a specific location in the compressed air system and interruption of a system fed by the compressed air system, this cost may well outweigh any savings from remedying a leak.

The method according to the invention makes it possible, on the basis of the systematic determination of the diagnostic variable (s), which is possibly compared with empirical knowledge stored in the database, in a simple manner and initially without additional measurements and / or interventions required for a leakage management To provide criteria.

• - aufgenommene elektrische Leistung von zumindest einem der Kompressoren im Last- und/oder Leerlauf
• - aufgenommene elektrische Leistung vom Druckluftsystem
• - Durchfluss, Druck, Temperatur, Feuchte

wobei die Messgröße bei der Bestimmung der Diagnosegröße berücksichtigt wird.In one development of the invention, at least one of the following measured variables is measured at at least one measuring point of the compressed air system:

• - recorded electrical power of at least one of the compressors in load and / or idle
• - Recorded electrical power from the compressed air system
• - Flow, pressure, temperature, humidity

wherein the measured variable is taken into account when determining the diagnostic quantity.

In this embodiment, the measured variable is taken into account when determining the diagnostic quantity. This allows a much more accurate and thus improved diagnostic size can be determined. The measurement at the measuring point can take place before commissioning (for example, power during load and / or idling) and / or during operation as an in-line measurement (for example flow, pressure, temperature).

• 1: Eine Ausgestaltung des erfindungsgemäßen Verfahrens
• 2: Eine Ausgestaltung eines Computerprogrammprodukts, welches das erfindungsgemäße Verfahren zumindest teilweise ausführt.

The invention will be explained in more detail with reference to the following figures, like reference numerals designate like features. It shows:

• 1 : An embodiment of the method according to the invention
• 2 : An embodiment of a computer program product which at least partially carries out the method according to the invention.

In 1 schematically an embodiment of the method according to the invention is shown, of course, alternative embodiments are possible as shown here. The compressed air system 1 includes in this embodiment a rigid compressor 2a , a VSD compressor 2 B , as well as a reservoir with compressed air 3 , in which there is a pressure p2. Furthermore, the compressed air system has a measuring device for measuring a measured variable 14 on. To the rigid compressor 2a is an optical code 9 appropriate. The identification of the compressor 2a can thus preferably by means of a mobile terminal 8th done, which is the optical code 9 scans. Alternatively, or for plausibility check (for example, based on GPS) the location 10 of the compressor 2a detected. The adjustable compressor 2 B is determined by its type designation 11 identified.

After identification of the compressor 2 is by a user 16 the idle time displayed on the compressor t _empty in the application program app entered. Together with the read operating time or the predefinable period of time t it then becomes of the application program app the load time t _last of the compressor 2 determines which then calculates the diagnostic size 4.

The load / idle time t _read; t _empty , the compressor 2a becomes a higher-level unit 15 such as a server connected to the Internet with a database 12 transfer. There are special dependencies in this 5 the diagnostic size 4 from the load time t _last deposited. The one from the compressor 2a absorbed electrical energy E _ges depends on the load time t _last for example, about the load power P _last which is usually indicated on a data sheet and in the database 12 is deposited. This can alternatively also be used as a measured variable 14 be measured. There is no internet connection 13 , the load / idle times t are _read; t _empty , first calculated in offline mode and the one used to calculate the diagnostic size 4 required data from the database 12 transferred at a later date. The diagnostic size 4 is determined and possibly additionally in the database 12 deposited or compared with stored there values.

Based on the diagnostic size 4 can then be the efficiency of the compressed air system 1 estimated. Exemplary is in to 2 the user interface of the application program app shown. Is for example that of the compressor 2 B absorbed energy at idle E _empty Too high, is the control routine for controlling the controllable VSD compressors 2 B Optimization. It can also directly the total idle hours t _empty in the predetermined period of time t and the associated idle costs are determined. This requires current energy prices 7 be known. These can be directly in the application program app be entered, or from the database 12 be taken, for example, by using data stored there with respect to the energy supplier of the compressed air system 1 the energy prices 7 be updated constantly.

When determining the specific ratio K for the compressor, the quotient between quotient of the electrical energy absorbed by the compressor E _ges in the specifiable t and that of the compressor 2a supplied amount of compressed air V in the predetermined period of time t educated.

The indication of the flow takes place, for example, in units of m ³ / hour, and the amount of compressed air V in m ³ . The specification of the compressed air quantity V the delivery volume should conform to ISO 1217. When specifying the volume, the volume is usually converted to standardized pressure and temperature conditions to compare volumes present at different pressures and temperatures (operating condition, operating volume). It is quite common in the art to do this to mark the actually inadmissible spelling of the unit "Nm ³ " for standard cubic meters.

The specific indicator K the rigid compressor 2a can directly with the specific Kennzahle K of the adjustable compressor 2 B be compared. Often the rigid compressor 2a used for a certain base load, and the adjustable compressor 2 B is switched on. A common reason for idling a rigid compressor 2a is also that the electric motor of a rigid compressor 2a typically performs only a certain number of on / off operations and then remains turned on for safety reasons. In combination with the energy costs for the rigid 2a and the controllable 2b compressor, this results from the diagnostic variables 4 an approach, whether a conversion of a rigid compressor 2a on a controllable compressor 2 B makes economic sense. Also a barter against a smaller (ie with a smaller pressure level) staring 2a or controllable compressor 2 B it may be suggested by means of the specific figure or the equipment of the compressors 2a , 2b with a higher-level control, since often every compressor 2a 2b only on a separate and from the other compressors 2a ; 2b has decoupled control.

The system characteristic K _{S is} calculated from the ratio of the total amount of compressed air V _s (ie the sum of the compressed air quantities V all compressors 2 ) and that of the entire compressed air system 1 absorbed energy E _s, ie all compressors 2 as well as the ancillaries we for example the dryer. This is the one of the compressed air system 1 supplied amount of compressed air V _s in relation to that of the compressed air system 1 absorbed total energy E _s set.

When determining the key figures K ; K _S may optionally contain continuously determined measured variables 14 Become involved, this will be the key figures K ; K _S according to more accurate. For example, a one-time or regular flow measurement can be carried out to measure the flow, the measurement result in the case of determining the code K ; K _S is used. Alternatively, by a in the compressed air system 1 existing, continuously measuring flowmeter the flow rate within the predefined time interval t be determined exactly. Also, the time change 41 the diagnostic size 4 be detected in the predetermined time interval and exceeding a setpoint 42 for display

The setpoints stored in the database 42 for the specific measure K for the compressor 2 and the key figure K _S for the compressed air system 1 indicate to the user if the metrics K ; K _S achieve critical values in terms of energy efficiency. For a typical plant size, the setpoint is 42 for the key figure K for the compressed air system 1 for example, 0.11 kWh / Nm ³ . At the same time as the setpoints 42 may be at limits. Is measure K for the compressed air system 1 greater than 0.12 kWh / Nm ³ , compressed air systems are considered mediocre and, from 0.14 kWh / Nm ^3, poorer in terms of energy efficiency. These setpoints 42 and / or limits are then, for example, depending on the size of the compressed air system 1 in the database 12 deposited.

For better comparability, the load and idle times t _las; t _empty , or the diagnostic size determined from this 4 if necessary extrapolated to certain time intervals such as monthly or annual values. Thus, a comparison of annual costs with the previous year's costs can be made; or the difference compared to the previous month. This will highlight the benefits of energy efficiency measures or the increase in leaks. In addition, the energy costs in relation to the standard cubic meters can be additionally determined.

The annual amount of compressed air V is calculated from the annualized / standardized diagnostic quantity of the compressed air quantity V in the predeterminable period of time, or else the quantities extrapolated to one year 14 ,

LIST OF REFERENCE NUMBERS

1

Compressed air system

2

compressor

2a

rigid compressor

2 B

adjustable compressor

3

compressed air

4

diagnosis variable

41

temporal change of 4

42

Setpoint for 4

5

dependencies

6

capacity utilization

7

energy prices

8th

mobile terminal

9

optical code

10

Location

11

Type designation / serial number

12

Database

13

Internet connection

14

measurand

15

parent unit

16

user

t

predefinable time span

t _last

Last time

t _empty

Idle Time

E _ges

from the compressor absorbed electrical energy in t

E _last

from the compressor absorbed electrical energy in t _last

E _empty

discharged by the compressor electrical energy in t _empty

P _last

Power in the load

P _empty

Power in the load

K

Key figure of the compressor

E _S

electrical energy absorbed by the compressed air system in t

K _S

Key figure of the compressed air system

V

Compressed air supplied by the compressor in t

V _s

compressed air supplied by the compressed air system in t

φ

Amount of compressed air per time

app

application program

Claims (17)

Method for determining and / or monitoring the efficiency of a compressed air system (1), wherein the compressed air system (1) has at least one compressor (2) for generating compressed air (3), and wherein the method comprises at least the following method steps: t _last) and idle time (t _empty) in a predefinable time period (t) for the at least one compressor (2); Determining at least one diagnostic variable (4) for assessing the efficiency of the compressor (s) (2) and / or the compressed air system (1) in the predeterminable time span, the at least one diagnostic variable (4) essentially being based on the load time (t _last ) and idle time (t _empty ) of the compressor (2) in the predetermined period of time (t) is determined. Method according to Claim 1 Wherein the diagnosis variable based on stored and / or measured dependencies (5) of the diagnosis variable (4) of the load (t _last) and / or idle time (t _empty) is determined, and wherein the stored and / or measured dependencies ( 5) by the specific design of the compressor (s) (2; ..). Method according to Claim 1 or 2 in which the diagnostic quantity (5) is the electrical energy (E _ges ) received by the compressor (s) (2) in the predefinable time period (t) and / or by the preselected time period (t) compressor / compressors (2) consumed electric energy (e _load; e _empty) in the load (t _last) or idle (t _empty) and / or - the predefinable time period (t) of the compressor / compressors (2 ) supplied amount of compressed air (V) is. Method according to at least one of Claims 1 - 3 in which the diagnostic quantity (4) is a characteristic number (K) specific to the compressor / compressor (2) for assessing the energy efficiency of the compressor (2) in the predeterminable period of time (t), wherein in determining the specific Characteristic number (K) of the quotient of the electrical energy absorbed by the compressor (E _ges ) in the predeterminable period of time (t) and the amount of compressed air (V) delivered by the compressor (2) is formed in the predeterminable period of time (t). Method according to at least one of Claims 1 - 4 in which the diagnostic quantity (4) is the capacity utilization rate (6) of the compressor (s) (2) in the predeterminable period of time (t), and in the event that the compressor (2) is a rigid compressor (2a) is, in the determination of the capacity level (6) of the rigid compressor (2a), the quotient of the load time (t _load) of the compressor (2) in the predefinable time period (t) and the predetermined period of time (t) formed becomes. Method according to at least one of Claims 1 - 5 in which the diagnostic quantity (4) is the capacity utilization rate (6) of the compressor (s) (2) in the predeterminable period of time (t), and in the event that the compressor (2) is a controllable compressor (2b) is determined in the determination of the degree of utilization (6) of the variable displacement compressor (2b) in the predetermined period (t) average utilization. Method according to at least one of Claims 1 - 6 , wherein the diagnostic quantity (4) is a characteristic number (K _S ) specific to the compressed air system (1) for assessing the energy efficiency of the compressed air system (1), and wherein the characteristic number (K _S ) specific to the compressed air system is determined. the quotient from the electrical energy (E _S ) taken up by all the compressors of the compressed air system (1) in the predefinable time span (t) and the compressed air quantity (V _S ) delivered by all compressors (2) of the compressed air system (1) in the predefinable time span (2) is formed. Method according to at least one of Claims 1 - 7 , wherein the diagnostic quantity (4) is a characteristic number (K _S ) specific to the compressed air system (1) for assessing the energy efficiency of the compressed air system (1), and wherein the characteristic number (K _S ) specific to the compressed air system is determined. the quotient of the electrical energy (E _S ) absorbed by the compressed air system (1) in the predefinable time span (t) and the compressed air quantity (V _S ) delivered by all compressors (2) of the compressed air system (1) within the predefinable time span (2) is formed. Method according to at least one of Claims 1 - 8th in which, in addition, the energy prices (7) are determined, and wherein the diagnostic quantity is the cost of providing the electrical energy (E _ges ) received by at least one compressor (2) and / or; _(Last E; E _empty) recorded the cost for providing the at least one compressor (2) electrical energy - in the load (t _last) and / or idle (t _empty) and / or - the cost of providing from the compressed air system (1) absorbed electrical energy (E _s ) acts. Method according to at least one of Claims 1 - 9 wherein the method by a user at least partially as an application program (App) on a mobile terminal (8) is executable, and wherein the mobile terminal (8) is preferably a laptop, a smartphone, a tablet computer, or a data glasses , Method according to at least one of Claims 1 - 10 , wherein for at least one diagnostic variable (4) the time course of the diagnostic variable (4) is stored. Method according to at least one of Claims 1 - 11 , wherein a further diagnostic variable (4) is the time change (41) of the diagnostic variable (4). Method according to at least one of Claims 1 - 12 in which the identification of the compressor (2) is based on - at least one optical code (9) attached to the compressor (2), the optical code (9) being preferably a QR code and / or a bar code, and / or - the location (10) of the compressor (2) and / or - the type designation / serial number (11) of the compressor (2). Method according to at least one of Claims 1 - 13 in which the application program (App) communicates with a database (12) independent of the compressed air system (1) by means of an Internet connection (13), and at least one of the diagnostic variables (4) is stored in the database (12) and / or with a in the database (12) stored setpoint (42) for the diagnostic size (4) is compared. Method according to Claim 14 , wherein for the case that the deviation of the at least one diagnostic variable (4) from the stored setpoint (42) is greater than a predefinable amount, a warning message is generated. Method according to at least one of Claims 1 - 15 , Based on the at least one diagnostic variable (4) and / or the comparison of at least one diagnostic variable (4) with the stored setpoint (42) - a saving of the at least one compressor / of the compressors (2) and / or of the compressed air system (1) consumed electrical energy (e _tot e _s) in case of a repair of leaks, - a saving of costs from the at least caused a compressor / from the compressors (2) and / or (1) of the compressed air system in the case of a leak is remedied; and / or - a leak check time point and / or - a leak recovery time point. Method according to at least one of Claims 1 - 16 Wherein at least one measuring point of the compressed air system (1) at least one of the following measured quantities (14) is measured - electric power absorbed by the compressor (2) in the load circuit (P _load) and / or idle (P _empty) - electric power absorbed by the compressed air system (1) - Flow, pressure, temperature, humidity and where the measurand (14) is taken into account when determining the diagnostic quantity (4).

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