EP4004537A1

EP4004537A1 - System for producing a calibration solution

Info

Publication number: EP4004537A1
Application number: EP20771460.1A
Authority: EP
Inventors: Ivanka ATANASOVA-HÖHLEIN; Carolin Schütt
Original assignee: Siemens Energy Global GmbH and Co KG
Current assignee: Siemens Energy Global GmbH and Co KG
Priority date: 2019-09-11
Filing date: 2020-08-31
Publication date: 2022-06-01
Also published as: DE102019213820A1; WO2021047931A1

Abstract

The invention relates to a system (2) for producing a calibration solution (4) for the calibration of a gas chromatograph, having a liquid component (6) and at least one gaseous component (8), comprising a receiving device (10) for receiving the liquid component (6) and a multiplicity of different gaseous components (8), a first supply unit (12) for supplying a definable quantity of the liquid component (6) into the receiving device (10), a second supply unit (14) for supplying a definable quantity of a multiplicity of different gaseous components (8) into the receiving device (10), wherein the second supply unit (14) has a multiplicity of metering valves (16) for supplying the definable quantity of a multiplicity of different gaseous components (8).

Description

description

System for the preparation of a calibration solution

The present invention relates to a system and a method for producing a calibration solution, in particular for electrical insulating oils, for calibrating a gas chromatograph (laboratory or online device), having a liquid component and at least one gaseous component.

The reliable use of transformers is essential for the supply of electrical energy. To prevent unforeseen failures, the condition of transformers is regularly checked as part of maintenance work. One of the most important methods has been found to be the diagnosis of the insulating liquids used in the transformers, which can provide information about the chemical and electrical condition of the transformers. In particular, the so-called gas-in-oil analysis provides meaningful information about the current transformer status.

Such analyzes are usually carried out in gas chromatographs. For a meaningful analysis, however, prior calibration of the relevant measuring devices using appropriate calibration solutions is essential.

Methods and systems for producing such calibration solutions are known from the prior art and are described in IEC 60567, among others. However, the known methods for producing calibration solutions are very complex and error-prone, in particular because of their many individual manual steps. In addition, the known processes work with harmful mercury. In addition, the known methods and systems are only valid for the production of calibration solutions for mineral oil and not for other insulating liquids, such as natural and synthetic esters or silicone fluids are suitable.

It is therefore the object of the present invention to at least partially remedy the above-described disadvantages of known systems and methods for producing a calibration solution. In particular, it is the object of the present invention to provide a system and a method for producing a calibration solution which enables calibration solutions to be produced as precisely concentrated as possible in a simple, fast and inexpensive manner. In addition, the method according to the invention or the system according to the invention should be as versatile and user-friendly as possible.

The above object is achieved according to a first aspect of the invention by a system for producing a calibration solution according to claim 1 and according to a second aspect of the invention by a method for producing a calibration solution according to claim 14. Other features and details of the invention emerge from the subclaims , the description and the drawings. Features and details that have been described in connection with the system according to the invention naturally also apply in connection with the method according to the invention and vice versa, so that with regard to the disclosure of the individual aspects of the invention, reference is or can always be made to the individual aspects of the invention. The method according to the invention can therefore of course also be carried out with the system according to the invention.

The subject system for producing a calibration solution is preferably used to produce calibration solutions for electrical insulating oils, in particular for gas chromatographs. However, the system in question is also suitable for the production of other calibration solutions and also for other analysis devices. In the context of the invention, a liquid component is preferably one Standard conditions understood at least partially fluid component, in particular an oil. The liquid component can preferably be in the form of a transformer oil, in particular in the form of a mineral oil, a silicone oil or a synthetic, natural ester or the like. The gaseous components can preferably be in the form of substances that are gaseous under standard conditions, in particular in the form of high-purity gases, which are advantageously present with an analytical accuracy of at least 2.0, in particular at least 3.0. In particular, hydrogen, methane, ethane, ethylene, acetylene, propane, propylene, carbon monoxide, carbon dioxide, oxygen, nitrogen and / or methanol can be used as gases.

Within the scope of the invention it has been recognized that by means of an objective system for producing a calibration solution, in particular via the second supply unit embodied in the present invention with a plurality of metering valves for supplying a definable amount of a plurality of different gaseous components, calibration solutions for calibration can be precisely mixed in a particularly simple manner a gas chromatograph can be produced. In addition, the application of the present system means that the use of mercury which is hazardous to health can be dispensed with. In addition, calibration solutions for further insulating liquids in addition to mineral oil can be produced by means of the system or the process.

With regard to the possibility of a simple supply of the liquid and gaseous components to the

The receiving device can advantageously be provided according to the invention so that the receiving device is at least partially formed from an elastomer, for example a laminate reinforced elastomer, in particular at least partially from a rubber. An embodiment of the receiving device in the form of an elastomer enables a pressure equalization within the receiving device in a simple manner when adding the components, so that the addition of the components does not lead to a pressure increase within the receiving device and it is therefore not necessary to add the volume to be supplied beforehand via a syringe or the like before supplying a component remove. Compared to the method known from the prior art for the production of calibration solutions, the design of the receiving device in the form of an elastomer resistant to the insulating liquid and / or laminate-reinforced elastomer in particular eliminates the complicated and health-endangering step of mercury pressure compensation provided according to the prior art. In addition to an embodiment of the receiving device in the form of rubber or natural rubber, the receiving device can also be formed in the form of silicone rubber or vulcanizates or the like. With regard to a compact arrangement and a simple introduction of supply and discharge connections, the receiving device in question can advantageously be designed in the shape of a cuboid. Alternatively, other shapes, in particular spherical, oval or rectangular shapes, are also conceivable.

With regard to a robust and long-lasting design of the system in question and with regard to ensuring the production of a calibration solution that is as pure as possible, it can advantageously be provided that the receiving device is at least partially formed from a chemically resistant material, in particular has a chemically resistant coating. According to the invention, a chemically resistant material is understood to mean in particular a material with high chemical resistance to the preferably used liquid and gaseous components - that is, a material that is at best chemically inert to the preferably used substances. In terms of prevention of contamination, it is in addition, it is particularly advantageous if the receiving device in question is formed from an air-impermeable material.

In order to allow the liquid component to be conveyed or guided in a simple, fast and automated manner, it can be provided in particular that the first feed unit comprises a feed pump and a line system for conveying the liquid component into the receiving device. The delivery pump for delivering the liquid component is preferably designed in the form of a liquid pump, in particular in the form of an oil pump. To ensure a system that is as tight as possible, the line system can preferably be formed in the form of metal, in particular in the form of stainless steel lines, which can likewise advantageously be chemically resistant to the liquid component used. A line system made of metal is not only more stable and more resistant to chemical substances, but also generally more sealed to the environment than conventional hose systems or similar.

In order to enable the production of a particularly pure calibration solution, it can also advantageously be provided within the scope of the invention that the first feed unit has a vacuum pump and a line system for degassing the liquid component. The vacuum pump and the line system serve to effectively remove gases dissolved in the liquid component, which in the context of the invention should only be supplied in precisely defined quantities during the preparation of the calibration solution, so that it makes sense for the preparation of precisely concentrated calibration solutions, in advance all within to remove dissolved gases from the liquid component. To protect the vacuum pump from sucking off parts of the liquid component, collecting devices for collecting parts of the liquid component between the Vacuum pump and the storage location of the liquid component to be degassed can be provided.

In order to be able to continuously supply the liquid component, it is advantageously conceivable that a reservoir is provided for storing the liquid component, the reservoir preferably being connected to the feed pump and / or the vacuum pump via the line system. Such a connection makes it possible, in particular, to establish a continuous cycle of possible supply and degassing of the liquid component. In this case, the access to the feed pump should advantageously be arranged at the bottom of the reservoir and the access to the vacuum pump should be arranged at the cover of the reservoir in order to ensure that the vacuum pump only removes the gaseous substances from the liquid component and the feed pump only conveys the purified liquid component.

With regard to the most flexible handling of the receiving device while at the same time ensuring the production of a calibration solution that is as pure as possible, it can furthermore be provided according to the invention that a multi-way connecting unit is provided for connecting the receiving device to the first and / or second feed unit, the multi-way connecting unit preferably in the form a 3-way stopcock. A multi-way connection unit enables the receiving device to be easily separated without the calibration solution arranged inside the receiving device having to be exposed to the atmosphere after it has been mixed and thus its concentration being falsified. Such multi-way connection units can also be formed, for example, in the form of plastic taps or the like, which remain on the receiving device in the context of commercial distribution of the calibration solutions produced and can be sold together with it. Furthermore, it goes without saying that within the scope of greater flexibility, 4, 5 or more than 5-way connection units, in particular in the form of taps or the like, can be provided.

As part of the quick, simple and effective production of different calibration solutions, it can advantageously be provided according to the invention that the second feed unit has at least three, preferably at least five, in particular more than five metering valves for feeding the definable amount of a plurality of different gaseous components. In this case, different amounts of a gaseous component can preferably be introduced via the individual metering valves. The metering valves can preferably be in the form of gas metering valves. The quantities to be supplied can be regulated, for example, via the volumes, in particular the line diameter and / or the line length, or also via the time of introduction.

As part of a system that is as compact and low-maintenance as possible, the invention can also advantageously provide that the metering valves are connected to one another via a first and second fluid path, a first fluid path preferably for transferring the liquid component and the second fluid path for transferring a plurality of gaseous components is provided. The intended separation of the fluid paths, in particular, minimizes the cleaning effort and the number of necessary rinsing processes.

With a view to the most precisely controllable supply of a liquid and a plurality of gaseous components into an objective receiving device, it can advantageously be provided according to the invention that the metering valves have a coupling path for coupling the first and second fluid paths, the coupling path being designed in such a way that this an access between the first and second fluid paths in a closed state of FIG Metering valves closes and releases the metering valves in an open state. In this way, for example, the second fluid path can be completely protected from contamination with the liquid component by allowing access to the second fluid path via the coupling path only when a metering valve is opened, so that the gas is directed into part of the first fluid path for a definable period can be, which can then preferably be passed directly into the receiving device. By varying the opening time of the metering valve as well as the line cross-section and the length of the metering valve in question, the addition of a gas can be precisely controlled.

In the context of the most exact and preferably automated control of the supply of the gaseous components to the receiving device, it is conceivable in particular that the metering valves are in the form of pneumatically and / or electrically and / or magnetically operated valves.

In the context of a compact design of the system in question, which at the same time allows a simple and fast production of different calibration solutions, it can advantageously be provided according to the invention that a gas supply unit is provided for supplying a plurality of gaseous components, the gas supply unit having a plurality of supply and discharge lines , wherein the supply and discharge lines can preferably be connected to the second fluid path.

In the context of a particularly precise and in particular automatic or automatable production of calibration solutions, it can be provided in particular that a control unit is provided for automatic control of the gas supply unit and the metering valves in order to automatically and finely metered addition of a plurality of different gaseous components to the liquid Ensure component. Here, a control unit can be software-controlled, for example, and thus enable a clearly more precisely determinable opening duration of the metering valves, which advantageously correlates with the type and size and the pre-pressure of the gaseous components to be introduced. In the context of effective control of the system according to the invention, the individual system components can be connected to one another preferably via control lines or the like. In the context of a particularly flexible and easily integrated embodiment of the system in question, the individual components can also be connected to one another wirelessly or contactlessly via Bluetooth, WLAN, Zigbee or the like.

The invention also relates to a method for producing a calibration solution for calibrating a gas chromatograph. Here, the method according to the invention comprises the steps of supplying a defined amount of the liquid component into the receiving device by means of the first supply unit and supplying a defined amount of the plurality of different gaseous components into the receiving device by means of a second supply unit, the various gaseous components of the receiving device by means of the second feed unit can be fed in a defined amount via a plurality of metering valves. The method according to the invention thus has the same features as have already been described in detail with regard to the system according to the invention. The method according to the invention uses, in particular, a system according to the first aspect of the invention, as described in the system claims.

Before a liquid component is supplied by means of a first supply unit, the liquid component can preferably be degassed by means of the first supply unit, in particular by means of a vacuum pump integrated within the first supply unit and a correspondingly arranged line system. A dosage of the liquid and / or the at least one gaseous component can in particular be automated or automatic by means of a control unit or the like.

In order to completely dissolve the gaseous components present within the liquid component, the invention can also provide that after the liquid component and the various gaseous components have been fed in, the calibration solution is shaken, the calibration solution preferably being shaken for one to 24 hours. In this case, shaking can preferably take place in the receiving device in question, which for this purpose is preferably separated from the outside via shut-off valves and can be transferred to a suitable shaker.

In the context of the most exact possible preparation of different calibration solutions, the volume of a liquid component can preferably be determined by measuring the weight and converting the known density of the liquid component in question, so that the volume does not have to be measured and a risk of contamination is prevented. To be on the safe side, a sample can also be measured to verify the quality of the standard before using a calibration solution prepared according to the method in question.

Furthermore, it can be provided according to the invention that the subject method for producing a calibration solution takes place at constant temperature and at constant pressure, which allows the concentrations to be converted to standard conditions (20 ° C. and 101.3 kPa).

Further advantages, features and details of the invention emerge from the following description, in which exemplary embodiments of the invention are described in detail with reference to the drawings. Here, the features mentioned in the claims and in the description be essential to the invention individually or in any combination.

Show it:

1 shows a schematic representation of a system according to the invention for producing a calibration solution for calibrating a gas chromatograph according to a first exemplary embodiment,

2a shows a schematic representation of a second feed unit according to the invention for feeding a definable amount of a plurality of different gaseous components into the receiving device with completely closed metering valves,

FIG. 2b a schematic representation of the second feed unit according to the invention according to FIG. 2a with partially open metering valves,

3 shows a schematic representation of a method according to the invention for producing a calibration solution for calibrating a gas chromatograph according to a first exemplary embodiment.

1 shows a schematic representation of a system 2 according to the invention for producing a calibration solution 4 for calibrating a gas chromatograph, having a liquid component 6 and at least one gaseous component 8 according to a first exemplary embodiment.

The system 2 in question comprises a receiving device 10 for receiving the liquid component 6 and a plurality of different gaseous components 8, a first supply unit 12 for supplying a definable amount of the liquid component 6 into the receiving device 10 and a second supply unit 14 for Feeding a definable amount of a plurality of different gaseous components 8 into the receiving device 10, the second feed unit 14 having a plurality of metering valves 16 - not shown here - for feeding the definable amount of a plurality of different gaseous components 8.

With regard to the possibility of pressure equalization when the liquid component 6 or the at least one gaseous component 8 is supplied, the receiving device 10 is in the present case in the form of an elastomer, in particular made of rubber. To prevent contamination of the calibration solution 4 produced within the receiving device 10, the receiving device 10 is also formed from an air-impermeable and preferably chemically resistant material.

In the present case, the first feed unit 12 comprises a feed pump 18 and a line system 20 for conveying the liquid component 6 into the receiving device 10. The feed unit 12 also comprises a vacuum pump 18 ′ and a further line system 24 for degassing the liquid component 6.

To store the liquid component 6, a reservoir 27 is also provided, which is connected to the feed pump 18 via the line system 20 and to the vacuum pump 18 ′ via the line system 24. Such an arrangement is used to degas the liquid component 6, which is in the form of an insulating oil, preferably in the form of a mineral oil, a silicone oil or a synthetic ester, in that the gases dissolved within the liquid component 6 are discharged via the vacuum pump 18 '.

The liquid component 6 is meanwhile discharged via the feed pump 18 and made available again to the reservoir 27 within a circuit via the line system 20. During this transfer, the liquid Component 6 of the receiving device 10 are fed via shut-off valves 17. As can be seen, a large number of further shut-off valves 17 are arranged distributed over the system 2. With regard to the most flexible handling of the receiving device 10 while at the same time ensuring the production of a calibration solution 4 that is as pure as possible, the system 2 has a multi-way connection unit 34 for connecting the receiving device 10 to the first and / or second supply unit 12, 14, which is preferably in the form a 3-way cock or the like can be formed.

To protect the vacuum pump 18 'from sucking off parts of the liquid component 6, two collecting devices 22 for collecting residues of the liquid component 6 within the line system 24 are also provided between the reservoir 27 and the vacuum pump 18'.

FIG. 2a shows a schematic representation of a second feed unit 14 according to the invention for feeding a definable amount of a plurality of different gaseous components 8 into the receiving device 10 with completely closed metering valves 16a-16f.

The present six metering valves 16a-16f arranged next to one another are connected to one another via a first and second fluid path 26, 28, the first fluid path 26 being provided for transferring the liquid component 6 and the second fluid path 28 for transferring a plurality of gaseous components 8.

In the present case, the metering valves 16 can be in the form of pneumatically and / or electrically and / or magnetically operated valves.

A plurality of gaseous components 8 are added to the fluid path 28 via the gas supply unit 32 for supplying a plurality of gaseous components 8 added, which in the present case has a plurality of supply and discharge lines, via which various gases can be supplied to the fluid path 28.

In contrast to the fluid path 28 for transferring a plurality of gaseous components 8, the fluid path 26 leads to the transfer of the liquid component 6 via the feed pump 18 and the receiving device 10, so that a volume of the liquid component 6 arranged within the receiving device 10 is constantly within or along the Fluid path 26 can be circulated.

FIG. 2b shows a schematic representation of a second feed unit 14 according to the invention according to FIG. 2a with partially open metering valves 16.

Here, as shown in FIG. 2b, the valve 16e is open. As can be seen from the metering valve 16e, the valves 16a-16f have a coupling path 30 for coupling the first and second fluid paths 26, 28, which is designed in such a way that they provide access between the first and second fluid paths 26, 28 in a closed manner Closed state of the dosing valves 16 and released in the open state of the dosing valve 16e shown here, so that the gaseous component 8 introduced via the gas supply unit 32 can be introduced into the second fluid path 28 via the coupling path 30 of the dosing valve 16e and thus a new, third fluid path 29 for Transfer of a liquid component 6 mixed with a gaseous component 8 arises, via which the components 6, 8 are fed to the receiving device 10 and form the finished calibration solution 4.

3 shows a schematic representation of a method according to the invention for producing a calibration solution 4 for calibrating a gas chromatograph, having a liquid component 6 and at least one gaseous component 8. Here, the method according to the invention initially comprises a step of degassing 40 the liquid component 6 by means of a vacuum pump 18 ′ integrated within the first feed unit 12 and a correspondingly arranged line system 24, before a subsequent second step feed 42 a defined amount of the liquid component 6 in the receiving device 10 by means of the first supply unit 12 and, in the third step, supplying 44 of a defined amount of the plurality of different gaseous components 8 into the receiving device 10 by means of a second supply unit 14, the various gaseous components 8 being the

Receiving device 10 according to the method according to the invention can be fed in a defined quantity by means of the second feed unit 14 via a plurality of metering valves 16.

After supplying 42, 44 of the liquid component 6 and the various gaseous components 8, the receiving device 10 is then transferred 46 to a shaker and the calibration solution 4 is shaken 48, the calibration solution 4 preferably being shaken for one to 24 hours.

According to the invention, it can advantageously be provided that the method in question takes place at constant temperature and at constant pressure, so that the concentrations can be converted to standard conditions (20 ° C. and 101.3 kPa).

By means of the system 2 or the method for producing a calibration solution 4, it is possible in particular to be able to produce precisely mixed calibration solutions 4 for calibrating a gas chromatograph in a particularly simple, quick and user-friendly manner. In addition, by means of the system 2 or the The method in question, calibration solutions 4 for further insulating liquids in addition to mineral oil are produced.

Claims

1. System (2) for producing a calibration solution (4) for calibrating a gas chromatograph, having a liquid component (6) and at least one gaseous component (8), comprising:

- A receiving device (10) for receiving the liquid component (6) and a plurality of different gaseous components (8),

- A first feed unit (12) for feeding a definable amount of the liquid component (6) into the receiving device (10),

- A second feed unit (14) for feeding a definable amount of a plurality of different gaseous components (8) into the receiving device (10), characterized in that the second feed unit (14) has a plurality of metering valves (16) for feeding the definable amount of a Has a plurality of different gaseous components (8).

2. System (2) according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the receiving device (10) is at least partially formed from an elastomer, in particular at least partially from a rubber.

3. System (2) according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that the receiving device (10) is at least partially formed from a chemically resistant material, in particular has a chemically resistant coating.

4. System (2) according to one of the preceding claims, characterized in that that the first feed unit (12) comprises a feed pump (18) and a line system (20) for feeding the liquid component (6) into the receiving device (10).

5. System (2) according to one of the preceding claims, d a d u c h g e k e n n z e i c h n e t that the first feed unit (12) has a vacuum pump (18 ') and a line system (24) for degassing the liquid component (6).

6. System (2) according to one of the preceding claims, characterized in that a reservoir (27) for storing the liquid component (6) is provided, the reservoir (27) preferably via the line system (20) with the feed pump (18) and / or is connected to the vacuum pump (18 ') via the line system (24).

7. System (2) according to one of the preceding claims, characterized in that a multi-way connection unit (34) is provided for connecting the receiving device (10) to the first and / or second feed unit (12, 14), the multi-way connection unit (34 ) is preferably formed in the form of a three-way valve.

8. System (2) according to one of the preceding claims, characterized in that the second feed unit (14) has at least three metering valves (16), preferably at least five metering valves (16), in particular more than five metering valves (16), for supplying the definable amount has a plurality of different gaseous components (8).

9. System (2) according to any one of the preceding claims, characterized in that the metering valves (16) are connected to one another via a first and second fluid path (26, 28), wherein a first fluid path (26) is preferably provided for transferring the liquid component (6) and the second fluid path (28) for transferring a plurality of gaseous components (8).

10. System (2) according to one of the preceding claims, characterized in that the metering valves (16) have a coupling path (30) for coupling the first and second fluid paths (26, 28), the coupling path (30) being designed such that this closes an access between the first and second fluid path (26, 28) in a closed state of the metering valves (16) and releases it in an open state of the metering valves (16).

11. System (2) according to one of the preceding claims, d a d u c h g e k e n n z e i c h n e t that the metering valves (16) are in the form of pneumatically and / or electrically and / or magnetically operated valves.

12. System (2) according to one of the preceding claims, characterized in that a gas supply unit (32) is provided for supplying a plurality of gaseous components (8), the gas supply unit (32) having a plurality of supply and discharge lines, the Feed and discharge lines can preferably be connected to the second fluid path (28).

13. System (2) according to one of the preceding claims, characterized in that a control unit for automatically controlling the gas supply unit (32) and the metering valves (16) is provided in order to automatically and finely metered addition of a plurality of different gaseous components (8) to ensure the liquid component (10).

14. A method for producing a calibration solution (4) for calibrating a gas chromatograph, having a liquid component (6) and at least one gaseous component (8), comprising the steps:

- feeding (42) a defined amount of the liquid component (6) into the receiving device (10) by means of the first feeding unit (12),

- Feeding (44) a defined amount of the plurality of different gaseous components (8) into the receiving device (10) by means of a second supply unit (14), characterized in that the various gaseous components (8) of the receiving device (10) by means of the second supply unit (14) can be supplied in a defined quantity via a plurality of metering valves (16).

15. The method according to claim 14, characterized in that after feeding (42, 44) the liquid component (6) and the various gaseous components (8), the calibration solution (4) is shaken (48), the calibration solution (4) preferably shaken for 1 to 24 hours.