DE3730046A1 - Apparatus for determining the spontaneous ignition (autoignition, spontaneous inflammation) of organic liquids - Google Patents

Abstract

To improve, in an apparatus for determining the spontaneous ignition of organic liquids, in particular of oils, having a glass vessel, a metering device to introduce a particular amount of the liquid into the glass vessel, having a heating device to heat the glass vessel and having a temperature measuring facility to determine the respective temperature of the glass vessel, the observation of the liquid behaviour from introduction to ignition, it is proposed that the glass vessel is arranged in a flow channel through which a transparent and fluid heating medium flows, which medium is heated to a desired temperature in a heating device prior to entry into the flow channel, and that the wall of the flow channel comprises a transparent material.

Description

The invention relates to a device for determining the Autoignition of organic liquids, especially right of oils, with a glass jar, a dosing device for introducing a certain amount of the liquid into the Glass jar, with a heater for heating the glass jar and with a temperature measuring device for determining the respective temperature of the glass vessel.

It is known the self-ignition temperature of organi measuring liquids, especially oils, thereby sen that one with a small amount of liquid filled glass jar in an oven until it is heated until Self-ignition occurs. For the implementation of this loading standard conditions have been agreed (Stan  dard Test Method for Autoignition Temperature of Liquid Chemicals ASTM E 659-78 (re-approved 1984) in ANNUAL BOOK OF ASTM-STANDARDS, volume 05.03, pages 785 to 791 (1986)). In the known method, the glass vessel is in one all partly closed furnace heated, for example in one Sand bed. It is also possible to even out the Temperature on the surface of the glass jar with egg cover aluminum foil. To ignite the gas to be able to observe is in the known arrangement Mirror provided through the inside of the glass jar can be observed through the insertion opening. With this arrangement it is only possible to a very limited extent to closely monitor the processes inside the glass vessel ten, especially in that of the actual inflammation outgoing period. For the assessment of ignition and fire propagation behavior, however, it would be extremely important also the behavior of the liquid before the immediate to watch their inflammation.

It is an object of the invention, a generic Vorrich tion to improve such that on the one hand an improved Observation of the behavior of the liquid after the on fill in the glass jar and on the other hand a more accurate time It is possible to determine the course of the reaction in the glass vessel becomes.

This task is in a device of the beginning Written type solved according to the invention in that the Glass vessel is arranged in a flow channel a transparent and flowable heating medium flows through that before entering the flow channel in  a heater is heated to a desired temperature, and that the wall of the flow channel from a see-through material exists.

Surprisingly, it has been found that one such an arrangement that dips into the flow channel Glass vessel from the heat flowing through the flow channel medium is heated very evenly. Because that used Heating medium as well as the surrounding wall of the flow channel is transparent is an insight into the interior of the Liquid-absorbing glass jar possible; this can the behavior of this liquid from filling to ent ignition can be closely observed.

It is particularly advantageous if the glass vessel is spherical mig is formed and a cylindrical neck for on fill the liquid. The spherical training dung leads to an even flow around the glass vessel ßes by the heating medium, which is when flowing around creates the wall of the glass jar and this evenly warms up. Practical tests have shown that that the temperature deviations in the entire wall area of the Glass jar was below 1%.

It when the channel in cross section is particularly advantageous is cylindrical and if the glass vessel is centered in it is arranged. This essentially results in sym metric flow conditions in the flow channel, the ih on the other hand, a very even heating of the glass vessel guarantee.  

In a particularly preferred embodiment, it is provided see that the longitudinal axis of the flow channel is perpendicular is ordered.

The heating medium can be a liquid, especially before but it is partial if the heating medium is a gas, ins special air. It is particularly advantageous if an inert gas is used, which with the contents of the glass jar no undesirable reactions, so that one if the glass vessel breaks, the contents of the same is discharged with the flowing heating medium without undesirable reactions occur.

It can be provided that the heating medium the opening of the Flows around the glass vessel. This ensures that vapors or reaction products escaping from the glass vessel Heating medium are taken away and therefore not one disturbing accumulation.

In a preferred embodiment is in the area of impact the liquid in the glass vessel arranged a sensor that when Filling the liquid generates a start signal. This The sensor can be a thermocouple, for example, it can but other sensors are used that are based on the previous respond to the presence of the liquid, e.g. Semiconductor temperature sensor, a temperature-dependent measurement resistance or the like. The generated by this sensor te start signal can be used to determine the start of the experiment NEN, it can, for example, switch on a curve recorder ten, operate a camera or the like. Besides, can serve to mark the start of the experiment.  

Usually the river is poured into the glass vessel liquid collected on the bottom of the glass jar. It can but can be provided in a preferred embodiment, that in the glass jar below the fill opening and above a collecting tray for the liquid is ordered. This ensures that the ver vaporizing liquid with the gas inside the vessel mixes before the inflammation sets in. If you collect the rivers liquid at the bottom of the vessel, it can occur in individual cases come that the vapors generated by the liquid Displace air so that due to lack of mixing with egg Delayed autoignition occurs with an oxidizer.

The bowl can be made of glass or ceramic, in particular The stored cases can also ver metal shells be used, in particular made of a metal that Ver combustion reaction influenced catalytically. In this way catalytic interactions can also be checked.

It is particularly advantageous if the flow channel part a circuit for the heating medium.

To even out the temperature of the glass jar this on the floor with a good heat-conducting coating be provided, for example an aluminum layer. These does not obstruct the view of the inside of the glass jar or just a little.

Inside the glass jar are at a preferred off embodiment temperature sensors arranged, namely:  

• a) at the lowest point of the fluid intake area,
• b) at the edge of the liquid absorption area and
• c) above the liquid absorption area.

With these temperature sensors, the temperature profile in the liquid, at the edge of the liquid and above the Liquid throughout the period to self inflammation are monitored.

There is a particular advantage of the present invention in that through the transparent design of the Heizme diums and the surrounding channel wall outside the flow a high-speed camera can be arranged in the channel, which registers the course of the self-ignition reaction.

It is particularly advantageous if the metering device a channel protruding into the glass vessel, the ends just above the fluid intake area. There by ensuring that the liquid in the discharge area, which is usually in is on the order of a few microliters, in the form of a continuous drop in the liquid intake reached richly, without a fragmentation of this drop entry.

With other measurement methods, care can also be taken to ensure this be that the liquid when introduced into the glass vessel divides into a multitude of small droplets. At  for example, this can be done in that the feed channel is narrowed in the outlet area and the liquid under right relatively high pressure is injected quickly. It is observ attention was paid to that despite the smallest amounts of liquid this is broken up into a multitude of droplets without that a nebulization occurs.

The presence of the liquid in the form of a coherent the drop or in the form of a plurality of drops to changes in autoignition temperature so that these different examinations give a closer look can give conclusions about the overall behavior.

The following description of preferred embodiments the invention serves in connection with the drawing of the detailed explanation. Show it:

Fig. 1 is a schematic view of a test arrangement for determining the self-ignition of organic liquids with egg nem impact area of the liquid on the bottom of the glass vessel and

Fig. 2 is a schematic view of the glass vessel of Fig. 1 with an additional bowl for holding the liquid.

The device shown in the drawing comprises a spherical glass vessel 1 with a cylindrical neck 2 , which is held in the middle in a vertical glass tube 3 . The glass tube 3 is open at its lower and at its upper end, below the glass tube 3 is a hot air generator 4 , which heats air drawn in from the environment and blows centrally into the glass tube 3 from below, so that the hot air causes the glass vessel 1 flows around on all sides and is therefore evenly heated.

The entire arrangement is surrounded by a further glass jacket 5 .

A dosing device 6 for the liquid to be examined protrudes into the glass vessel 1 , for example a so-called microliter syringe, with which small amounts (for example 50 to 100 .mu.l) of the liquid to be examined can be introduced into the interior of the glass vessel 1 in a precisely metered manner.

Inside the glass vessel, a first thermocouple 7 is arranged on the bottom thereof, precisely below the outlet of the metering device 6 , so that liquid filled into the glass vessel from the metering device 6 strikes the thermocouple element 7 . Furthermore, a thermocouple 8 is arranged in the vicinity of the bottom of the glass vessel 1 so that when the liquid is filled in, it is located in the edge region of the liquid lake 9 forming on the bottom of the vessel.

Finally, another thermocouple 10 above the liquid lake 9 is preferably arranged in the middle of the glass vessel 1 .

All thermocouples are connected via signal lines 11 , 12 and 13 respectively to a measuring device 14 in which the temperature signals supplied by the thermocouples are registered. They can be recorded on a high-speed recorder 15 , which is connected via a control line 16 to the measuring device 14 .

To determine the autoignition of organic liquids, the glass vessel 1 is heated to a desired temperature by means of a hot air stream. The liquid to be examined is then introduced into the glass vessel 1 via the metering device 6 . The exact time of the filling lens results from a corresponding drop in temperature of the thermocouple 7 , so that the start of the experiment can be determined exactly. The corresponding start signal can, for example, switch on the high-speed recorder. All thermocouples together now determine the temperature behavior of the liquid in the center of the liquid lake 9 and at the edge of the same and also above the liquid in the vapor space of the glass vessel. This temperature courses can be recorded by means of the high-speed recorder 15 .

The optical phenomena, which are associated with the processes before the ignition and at the moment of ignition, can easily be followed by operators or a high-speed camera 17 arranged outside the glass jacket 5 , since the interior of the glass vessel is freely visible in spite of the heating device surrounding the glass vessel is.

In the embodiment shown in FIG. 2, which is largely of the same construction as that of FIG. 1, in contrast to the embodiment of FIG. 1, a receptacle 18 is arranged in the interior of the glass vessel 1 approximately halfway into which the receptacle is placed by means of the metering device 6 introduced liquid falls. The fact that the liquid speed does not hit the bottom of the glass vessel, but son on the receiving tray 18 , ensures that the evaporating liquid mixes with the surrounding atmosphere and does not push it aside. This mixing is necessary because the combustion of oxygen consumes the surrounding atmosphere. A displacement of the surrounding atmosphere can shift the ignition temperature.

While the receptacle 18 is usually made of glass or ceramic, in special embodiments it can consist of a metal which catalytically influences the inflammation reaction. In this way, catalytic effects of different metals can be investigated.

Corresponding thermocouples 7 , 8 and 10 are also provided in the embodiment of FIG. 2, which determine the temperature in the core of the liquid lake 9 , at the edge thereof and above the same, and feed the measuring device 14 .

Claims (19)

1. Device for determining the autoignition of organic liquids, in particular oils, with egg nem glass vessel, a metering device for introducing a certain amount of liquid into the glass vessel, with a heater for heating the glass vessel and with a temperature measuring device for determining the respective temperature of the glass vessel, characterized in that the glass vessel (1) is arranged in a flow channel (3) through which a transparent and flowable heating flowing medium in front of the entry into the Strö flow duct (3) in a heater (4) a desired temperature is heated, and that the wall of the flow channel ( 3 ) consists of a transparent material. 2. Device according to claim 1, characterized in that the glass vessel ( 1 ) is spherical and has a cylindrical neck ( 2 ) for filling the liquid speed. 3. Apparatus according to claim 1 or 2, characterized in that the channel ( 3 ) is circular cylindrical in cross section and the glass vessel ( 1 ) is arranged in the center. 4. Device according to one of the preceding claims, characterized in that the longitudinal axis of the flow channel ( 3 ) is arranged vertically. 5. Device according to one of the preceding claims, characterized in that the heating medium is a river liquidity. 6. Device according to one of claims 1 to 4, characterized characterized in that the heating medium is a gas. 7. The device according to claim 6, characterized in that the heating medium is air. 8. The device according to claim 6, characterized in that that the heating medium is an inert gas. 9. Device according to one of the preceding claims, characterized in that the heating medium flows around the opening of the glass vessel ( 1 ). 10. Device according to one of the preceding claims, characterized in that a sensor ( 7 ) is arranged in the impingement area of the liquid in the glass vessel ( 1 ), which generates a start signal when filling the liquid. 11. Device according to one of the preceding claims, characterized in that a collecting tray ( 18 ) for the liquid is arranged in the glass vessel ( 1 ) below the filling opening and above the bottom of the vessel. 12. The apparatus according to claim 11, characterized in that the collecting tray ( 18 ) consists of glass. 13. The apparatus according to claim 11, characterized in that the collecting tray ( 18 ) consists of ceramic. 14. The apparatus according to claim 11, characterized in that the collecting tray ( 18 ) consists of metal. 15. Device according to one of the preceding claims, characterized in that the flow channel ( 3 ) is part of a circuit for the heating medium. 16. Device according to one of the preceding claims, characterized in that the glass vessel ( 1 ) is provided on the bottom with a good heat-conducting coating. 17. Device according to one of the preceding claims, characterized in that in the interior of the glass vessel ( 1 ) temperature sensors ( 7, 8, 10 ) are arranged:

• a) at the lowest point of the liquid absorption area ( 9 ),
• b) at the edge of the liquid absorption area ( 9 ) and
• c) above the liquid absorption area ( 9 ).

18. Device according to one of the preceding claims, characterized in that the metering device ( 6 ) comprises a narrow channel projecting into the glass vessel ( 1 ) which ends just above the liquid intake area ( 9 ). 19. Device according to one of the preceding claims, characterized in that outside of the flow channel ( 3 ), a high-speed camera ( 17 ) is angeord net.