BE1028672B1 - Method for managing a compressor - Google Patents

Abstract

According to one embodiment, the invention includes a computer implemented method (420) for managing a compressor (100) by a user through a user equipment (200), the compressor (100) configured to compress and deliver a gas, wherein the compressor (100) comprises a control unit (115) configured to manage the compressor (100), the compressor (100) further comprising a wireless interface unit (113) configured to wirelessly manage the compressor (100) (203), wherein, when the compressor (100) is connected to a pneumatic network (311) comprising one or more pneumatic consumers (300-302), the method further comprises the steps of: - detecting (401) when the one or more pneumatic consumers ( 300-302) be inactive for an inactive period of time; and - recording (402) a power consumption of the compressor (100) during the idle time period; and wherein a leakage (310) of the pneumatic network (311) is identified based on the energy consumption, and - reporting (409) the leakage (310) if identified.

Description

your BE2020/5690

METHOD FOR MANAGING A COMPRESSOR No EGG manne maenannaanrarantenvansanrrerma rar rare sa et et Technical field [011 The invention is situated in the field of compressors for compressing and supplying a gas to a pneumatic network, and more specifically in the management of such a compressor, Prior art It is known that compressors are used to compress gas in one or more stages. This compressed gas is supplied to one or more pneumatic consumers via a pneumatic network. 1031 It is further known that a multitude of parameters determine the choice of compressor. These parameters can be of a technical nature, such as, among others, the power, the pressure ratio and/or the start-up time. Other parameters can be economic parameters such as investment and/or maintenance costs, or even environmental requirements, such as energy efficiency and/or noise requirements during operation. Furthermore, the type of pneumatic consumers as well as the respective intended applications will influence the choice of compressor, Up to lock will also

2. BE2020/5690 the pneumatic network used influences the choice in terms of size and capacity, 1041 It is therefore clear that the choice of a compressor used and installed cps s a suitable location, such as in an industrial environment. is based on a unique combination of different parameters. As a result, every situation will be different and therefore also require a specific approach in terms of installation, operation requirements and maintenance.

1051 During operation, a number of preconditions can also change that influences the proper functioning of the compressor. Examples of this are changing the pneumatic consumers as well as the ambient temperature of both the room in which the compressor is installed and that of the connected pneumatic network. 168] In order to always ensure proper functioning of the compressor, an operator will try to manage and check the operating parameters Le. It is known that the operator has a control panel available on the compressor for this. 10717 However, several disadvantages can be identified. Firstly, the control panel can be limited. Lots of basic basic functions that allow the operator to perform only minor actions. {1981 Ten Lweede, even when a multiplicity of functions is available, this multiplicity creates a cluttered management system and a generally user-unfriendly operating panel. This is because the same keys are usually used for different functions, and/or because unique

Mi BE2020/5690 key combinations are used for private manipulations. Furthermore, abbreviations are used to visualize different parameters in order to visualize as much information as possible on the control panel. This means that the operator must not only be highly technical, but also have a thorough knowledge of how the different parameters can be displayed , controlled and/or controlled.

18 1893 Finally, for reasons of optimal location, a compressor is usually set up in a secluded room such as, for example, a technical room. Furthermore, the compressor is installed in this technical room in a place that is usually not easily accessible. This also causes nuisance for the operator because the operating panel is not easy to operate, 1101 Consequently, there is a need for a system and method to efficiently manage a compressor in order to respond quickly when changing boundary conditions adversely affect compressor operation.

Summary of the Invention It is an object of the present invention to provide a way to optimally and efficiently manage a compressor. This goal is achieved by providing a computer-implemented method for managing a compressor.

“4. BE2020/5690 by a user via a user device, the compressor being configured to compress and deliver a gas, the compressor comprising a control unit configured to manage the compressor, the compressor further comprising a wired coupling unit configured to control the compressor wirelessly wherein, when the compressor is connected to a pneumatic network comprising one or more pneumatic consumers, the method further comprises the steps of: = detecting when the one or more pneumatic consumers are inactive during an inactive period of time; and - recording an energy consumption of the compressor during the inactive time period; and wherein a leakage from the pneumatic network is identified based on the energy consumption, and - reporting the leakage if identified.

[123 The compressor is configured to compress or compress gas through, for example, one or more stages. The compressed or compressed gas can then be further supplied to pneumatic consumers via a pneumatic consumer network. Many connected pneumatic consumers then use the compressed gas for specific applications. Usually the consumers in other rooms are arranged in relation to the compressor, but it is clear this is not necessary. It is further clear that in a simple configuration a single pneumatic consumer can be present, whereby the compressor and consumer can be in close proximity.

25. BE2020/5690 pneumatic net is then a single pipe. It should further be understood that a pneumatic consumer can also include a connection coupling to the pneumatic consumer network. Since this connection coupling is suitable for connecting a consumer, this connection coupling in itself can be regarded as the consumer instead of any appliance connected thereto.

[LS] The compressor also includes a control unit. This control unit is configured to manage the compressor. Order Management means that a user can control, command, monitor, set and/or verify compressor operating parameters or states, or any other manipulation to affect the operation of the compressor. to run the compressor, 114] The control signal can be a simple on and off button, possibly combined with analog control panels. On the other hand, this can also be an extensive digital control panel, or possibly a combination of an analog and digital control. It should therefore be understood that the control unit allows an operation or management of the compressor as known in the art, {1151 furthermore the operating parameters of the compressor to be managed are, inter alia, the operational status of the compressor , a pressure of the gas, a pressure of a lubricant, a pressure of a refrigerant, a pressure ratio of the gas to an ambient pressure, a absorbed electric current, a speed, a temperature, a pressure drop, an electric voltage, a power, a humidity, a level, and/or a specification of the COMpræessor.

[161 When the compressor is driven by an electric motor, the absorbed electric current of this electric motor is an operating parameter. In this configuration, the electric motor is then regarded as part of the compressor. Furthermore, the electric voltage is also an operating parameter. 1471 In addition, a frequency converter can be used to drive the electric motor. The operating parameter can then be the input voltage and/or current of the frequency converter. [181 When the compressor compresses the gas by means of rotating compressor elements, such as for example a socket screw compressor, the rotational speed and/or the rotational speed of the rotating elements is also considered as an operating parameter. The compressor element can also work orbiting, as with a scroll compressor, or reciprocating, as with a piston compressor. this can also be the speed of the drive of the combustion engine. Furthermore, this can also be the speed of the electric motor when such a drive is used.

ils] The temperature is, for example, the ambient temperature, the temperature of the compressed gas, and/or the temperature of one or more components of the compressor. The temperature may further be a temperature of a coolant and/or lubricant.

7m BE2020/5690

[201] The power is, for example, the electrical or mechanical power consumed. The power may furthermore be the power consumption of the Érequency converter when Loepast. {1221 The humidity is, for example, the humidity of the environment of the compressor. 1221 The level is, for example, the oil level if it is an oil-lubricated compressor.

{1231 Zen specification is, for example, the year of construction and/or installation year of the compressor, a type, a serial number, a date of last service, a service interval, or any other data that the COMPTSSSor can specify and/or identify. E24] If available, an activity of one or more pneumatic consumers can also be included as a parameter. However, it should be understood that this is not a direct operating parameter of the compressor itself.

[25] The compressor further comprises a wireless coupling unit. This wireless coupling unit is configured to manage the compressor wirelessly, In other words, the wireless coupling unit allows to manage the operating parameters, that is, to control, modify, verify, control, monitor, and/or set, or any other manipulation that can affect the compressor's operation. The wireless management can be done by the wireless coupling unit controlling the control unit of the compressor, or by the wireless coupling unit managing the compressor automatically, i.e., taking over or possibly supplementing the functions of the control unit,

Be BE2020/5690

[28] The computer-implemented method includes functionalities to control, modify, or otherwise manage the one or more compressor operating parameters. The operator is operated by a user through a user device on which the computer-implemented method is implemented. Under user, therefore, administrator can be beaten. 1271 It should be understood that a pneumatic consumer can also imply a connection to the pneumatic consumer network. Since this connection coupling is suitable for connecting a consumer, this connection coupling can in itself be regarded as the consumer instead of any device connected thereto.

[281 The one or more pneumatic consumers may, for example, be equipped with a module such that it can be automatically detected when they are active/operational or inactive/non-operational.

[29] Alternatively, the inactive time period can be a recurring time period that is derived from a load profile of the compressor. The load profile is then analyzed and it is determined from this when the pneumatic consumers are not operational and thus do not take compressed gas from the pneumatic network, The analysis can be done, for example, by using artificial intelligence configured to perform such analysis.

1301 It is an advantage that the compressor can be managed or controlled wirelessly by an administrator or user. The wireless pairing unit therefore meets

Gs BE2020/5690 disadvantages listed above in the way in which compressors are managed according to the prior art. The administrator or user should therefore not be in the immediate vicinity of the compressor. This avoids dangerous situations, for example if other operational and/or running machines are in the vicinity of the compressor. 1311 Another advantage is that the management is not limited to the functionality of a possible control panel, but that the functionalities can be expanded. This extension is limited only by the user device specifications. However, these specifications are not tied to the compressor itself, to its location, and/or to boundary conditions such as, for example, temperature and humidity, allowing greater flexibility and more management options,

[32] According to an embodiment of the invention, the wireless interface unit is configured to manage the compressor wire locomotives via a wireless protocol. This protocol can be a specific tailor-made protocol, or for example known protocols such as Wi-Fi, bluetooth, Zigbee, Narrowband-IcT, LTE-CAT M, DASH7, or other communication protocols to communicate wirelessly, 1331 According to an embodiment of the invention the control unit includes a control unit configured to manage the compressor locally, [341 In other words, in addition to and alternatively or additionally, the compressor may also be managed via a control unit, This control unit, which is mounted on the compressor or

-10- BE2020/5690 connected directly and wired, can then include some basic functions, such as a compressor shutdown. An advantage is that the user or administrator can intervene if a potentially harmful situation occurs when the wireless connection is temporarily is unavailable. {351 According to a preferred embodiment, the inactive time period can also be detected by the user specifying start and/or stop conditions in which the pneumatic consumers are inactive. By this manner of detection, the user retains control over the computer-implemented method, thereby increasing the accuracy. 1361 The inactive period, whether recurring or not, is for example a period during the night, during the weekends, and/or during holiday periods. 1371 In addition, the energy consumption of the compressor is recorded during the inactive time period.

Because a compressor is usually set to maintain a predefined pressure in the pneumatic system, the compressor will, if necessary, have to increase the pressure when it falls below a certain limit. Such a situation will arise when the connections in the pneumatic just don't show ideal seals.

Furthermore, there may be an Iek or Leakage in the net.

Finally, the connected consumers themselves can be the cause of such a leak.

It should therefore be understood that a leak can be either a single leak, a sum of leakages, or a sum of poorly executed seals, or any other cause of a pressure drop in the pneumatic network.

-11- BE2020/5690 1381 Finally, the leakage is identified or determined on the basis of the registered energy consumption. In other words, because an energy consumption is registered during the inactive period, it can be determined whether a leakage is present in the pneumatic network. This identification can then be reported to the user, 1391 According to one embodiment, the computer-implemented method further comprises the steps of: - determining a weight of the leakage based on the energy consumption, the inactive time period, and/or the one or more pneumatic consumers; and — reporting the weight and/or energy consumption, 1401 The weight of the leakage expresses the significance or importance of the leakage. For example, if a small energy consumption is measured in relation to a long inactive period of time, the weight will be lower are compared to the opposite situation, i.e. high energy consumption measured during a short period of inactivity. Furthermore, the number of pneumatic consumers can also be taken into account, as well as the size and size of the pneumatic network.

[44] Subsequently, the weight, possibly together with the energy consumption, will be reported to the user. with the cost per kWh.

-417- BE2020/5690 1421 The user therefore gains insight into the possible need to take action in the event of a leakage, based on the weight, as well as what energy loss and associated financial costs are associated with this if no action is taken, [433 For example, reporting can be done automatically when a critical value for the balance and/or power consumption is exceeded. [441 According to a further aspect of the invention, there is provided a computer program product comprising computer executable instructions for carrying out the method in the most distant manner. aspect if this program is run on a computer.

[45] According to a third aspect of the invention, there is provided a computer readable storage medium containing the computer program product according to the second aspect.

[46] According to a fourth aspect of the invention, there is provided a user equipment configured to communicate wirelessly with one or more other devices characterized in that the user equipment is configured to manage a compressor according to the method of the first aspect. 1471 The user device is, for example, a device configured solely to manage the compressor Le. Further, according to one embodiment, the user device may comprise one of the group of a smartphone, a tablet, a computer, a laptop, or other device configured to communicate wirelessly with another device.

-13- BE2020/5690 (481 The user equipment may further, according to an embodiment of the invention, be configured to communicate with an external network.

[43] The external network is, for example, a local network, such as a corporate network, or the Internet. 159] The user equipment is thus a computer, whether mobile or not, and includes the computer-implemented method of managing the compressor Le. The computer-implemented methods can, for example, be downloaded and installed on the external network. Furthermore, updates can be performed by the manufacturer at specific times via the external network. This update can then increase the accuracy of the computer-implemented method to optimize the management of the compressor, 151] Alternatively, the user device can be a custom-built mobile device on which the computer-implemented method is implemented and as a set together with the compressor can be made available. Brief description of the drawings

[52] The invention will now be further described with reference to the drawings in which:

44. BE2020/5690 1531 Pig. 1 illustrates a compressor comprising a wireless interface unit configured to wirelessly manage the compressor according to an embodiment of the invention: 1541 FIG. 2 illustrates a COMpressor, a user device configured to wirelessly manage the compressor, and an external network according to an embodiment of the invention; there (551 Fig. 3 illustrates a compressor, a pneumatic network, and pneumatic consumers connected to the pneumatic network according to an embodiment of the invention: and 136] Fig. 4 illustrates schematically steps performed by a user device to manage a compressor according to an embodiment of the invention.

Description of Embodiments 157] FIG. 1 illustrates a compressor 100 according to an illustrative embodiment of the invention. The compressor 100 includes a control panel 111 for locally operating the compressor. The compressor 100 further includes an emergency button 112 and a storage or buffer tank 110 to store compressed gas. Thus, it should be understood that the illustrated compressor 100 is a compressor as known in the art. It should therefore be further understood that this illustration is in no way limiting, but that the compressor according to the invention may have a different design or construction, with other parts being present, or absent, such as a compressor without a local control panel 111 and/ or a storage vessel 110.

[58] The compressor 100 further includes a control unit 115. This control unit 115 is configured to manage the compressor 100. By managing it is meant that a user can control, control, monitor, set and/or verify operation parameters of the compressor 190 or states of the compressor 100, or any other manipulation to affect the operation of the compressor 100. The compressor 100 may then be further coupled to the control panel 111 such that the control unit 100 takes over the operation of the control panel 111 . Conversely, the control panel 111 may communicate the instructions received from a user, but the control unit 100 such the control unit 115 executes these instructions. The compressor 100 further according to the invention includes a wireless interface unit 113 configured to communicate 114 wirelessly with other devices. In fig. 2, such wireless communication is further illustrated. fig. 2 illustrates the compressor 100 of FIG. 1, with a user device 200 and an external network 201. The compressor 100 may then communicate 203 with the user equipment 210. Further, the compressor 100 may also communicate 204 with an external network 201, such as the Internet or a corporate network. The communication 204 then takes place, for example, via a router or other device suitable for communicating with an external network 201 Le 204. Furthermore, the user equipment 200 can also communicate with the external network 201 202. This allows the communication of the compressor 100 instead of from communicating directly with the eztern network 201 204, barley communicating 203 with the

-16- BE2020/5690 user device 200, which in turn communicates 202 with the external network 201. This allows the communication of the compressor 100 with the external network 201 to take place indirectly, [601 The compressor 100 is configured to use compressed or compressed gas Le supply to one or more users via a pneumatic net, This is further illustrated in Fig. 3, in which the schematic network 311 illustrates a pneumatic network. Various consumers 300-302 are connected to this 311. It should further be understood that also only one consumer 300 can be connected, the pneumatic network 311 then comprising only one single line. The pneumatic net 311 may be an extended net distributed at a company site. The compressor 100 will then be located at a different physical location than the various consumers 300-302, wherein the consumers 309-302 may also each be arranged at a different physical location relative to each other.

[Si] in the pneumatic net 311 there may be a leakage, illustrated by leakage 310, which can be detected by the computer-implemented method of the invention. The manner of this detection will be further illustrated with reference to Fig. 4.

1621 In fig. 4 again illustrates the user equipment 200 along with steps 401-409 that the computer implemented method 420 may perform to manage the compressor 100. These steps 401-409 may be performed simultaneously or separately. This depends, among other things, on the capabilities of the user device 200 and/or the preferences of the user who manages the compressor 100,

-17- BE2020/5690 {1631 To perform these steps 401-409, 203 the user equipment 200 communicates with the compressor 100 requesting and exchanging a set of operation parameters.

These operating parameters are, for example, an operational status of the compressor 120, a pressure of the gas, a pressure ratio of the gas to V. an ambient pressure, an electric current drawn, a flow rate in the pneumatic network 311, a speed, a temperature, a pressure drop, a voltage, a power, a humidity, a level, a specification of the compressor 100, and if available an activity of one or more pneumatic consumers 300-302. 1541 The communication 203 between the compressor 100 and the user device 200 may be via a secure or encrypted connection.

This can be done, for example, on the basis of a unique serial number of the compressor 100 together with a code given by the manufacturer of the compressor 100 to access the wireless link unit 113 in order to manage the compressor 100, {651 The operating parameters can be set in batch are requested, individually, or according to a certain restricted list according to a certain sequence of times.

In other words, not all operating parameters may be requested by the user device.

This is dependent on the next steps in the computer implemented method 420, and more specifically what analysis will be performed.

The operating parameters can also be queried at predetermined times or continuously monitored,

“18 BE2020/5690 [567 A first analysis is to identify a possible Leakage 310 in the pneumatic network 310. In a first step, it will be detected 401 whether the users 300-302 are inactive. This can be detected 401 through direct communication with the consumers 300-302, through an analysis of the load profile of the compressor 100, or manually sent by a user in the user device 200. During this inactive period, the energy consumption of the compressor 100 registered. Subsequently, a leakage is identified on the basis of mains energy consumption and reported 409 to the user. This reporting is then done on a display 410 of the user device 200, 167] In addition, a weight can also be assigned to the leakage 310 or determined 403. When the leakage 310 is critical, e.g. in terms of economic loss, the user will then have the determined 403 weight as well as energy consumption reported 409, 168] A second analysis is to determine a belt tension of a belt transmission when the compressor 100 has a liquid transmission. For this, the user equipment 200 makes a sound recording via its microphone 412. The user will then lightly strike the belt with an elongate object and measure its response 404. Subsequently, based on this response, the belt tension is determined 405. This belt tension is then reported 409 to the user on the display 410.

{1681 In the second analysis it will preferably also be determined 406 whether the belt tension can be tolerated, i.e. is within limits within which the belt transmission works optimally. This can be deduced because the

-19- BE2020/5690 user device 200 has specifications of the compressor 100 available or can request it via the operating parameters. This can then be further reported 409 to the user.

{1761 A third analysis is the detection 407 of an irregularity of the compressor 100, This can be done by analyzing the operating parameters of the compressor 100, When an anomaly occurs in one of the parameters, such as a Le high temperature, or if a drift over a period of time is determined, e.g. a level falling too quickly, an irregularity can be detected 407, this is then reported 409 to the user.

1711 Reporting 409 may further include reporting 409 of a service, reporting 409 of a spare parts list, or reporting 408 of a maintenance interval, each based on the detected 407 irregularity. external network 201 where information can be requested, e.g. from the compressor manufacturer

100.

1721 The computer implemented method 420 may further comprise consulting 408 documentation of the compressor 100. This documentation is, for example, an energy consumption of the compressor 100 over a period of time, measured for example over a month, an instruction and/or maintenance guide of the compressor 100, an identification of a distributor of the compressor 100, or any other documentation relevant to an administrator of the compressor 100. This documentation can be requested, for example, via the external network 201 so that this documentation does not have to be permanently saved on

-20- BE2020/5690 the user device 100. Another advantage is that this documentation can be updated if necessary by the manufacturer of the compressor 100 via the external network 201.

173] The present invention relates to a compressor in which operation and application can be reversed to generate a vacuum, such as in a vacuum pump. The operation is then the same as a compressor, where the application for the consumers is not on the discharge side, but on the suction side. In other words, it should be understood that the invention also relates to vacuum pumps, in which case operating parameters of the vacuum pump can be requested. It should be further understood that the present invention may also be applied to expanders or gas turbines, in which case operating parameters of the expander or gas turbine are requested. The present invention is by no means limited to the embodiments described by way of example and shown in the figures, but a compressor, user equipment and computer implemented method according to the invention can be implemented according to different variants without departing from the scope of the invention,

Claims (5)

-21- BE2020/5690 Conclusions 1.- Computer implemented method {420} for managing a compressor {100} by a user via a user device {200}, which compressor {100} is configured to compress and deliver a gas wherein the compressor (100) comprises a controller unit (115) configured to manage the compressor (100) wherein the compressor (100) further comprises a wireless interface unit (113) configured to manage the compressor {190} wirelessly {203} , wherein, when the compressor {100} is connected to a pneumatic network (311) comprising one or more pneumatic consumers {300-302}, the method further comprises the steps of: = detecting (401) when the one or more pneumatic consumers (300-302} being inactive during an inactive time period; and = recording (402) an energy consumption of the compressor {100} during the inactive time period; and wherein a check (310) of the pneumatic network (311) w is identified based on the power consumption, and = report (409) the leakage {310} if identified, Z. Computer-implemented method {420} according to claim 1, wherein the idle time period is a recurring time period derived from a load profile of the compressor (100). 27. BE2020/5690 The computer-implemented method (420) of claim 1, wherein the idle time period is detected by a start and/or stop time entered by the user. 4.- Computer-implemented method {420} according to any one of claims 1 to 3, the method further comprising the steps of! = determining (403) a weight of the leakage (310) based on the energy consumption, the idle time period, and/or the one or more pneumatic consumers (300-302); and = reporting (409%) of the weight and/or energy consumption, 9, A computer program product containing computer executable instructions to perform the method {420} according to any one of claims 1 to 4 if this program is executed on a computer, A computer readable storage medium containing the computer program product of claim 5. A compressor {100} configured to compress and deliver a gas comprising a control unit {115} configured to manage the CONPressor (100) according to the computer-implemented method according to any one of claims 1 to 4,