DE102014001783B4 - Device and method for the detection of local combustion in a silo - Google Patents

Abstract

Device for detecting and determining the spatial position of a local combustion (1) in a silo (2) for pourable, combustible substances (3), with at least one gas sensor (4) that detects the concentration of at least one combustion gas in a time-resolved manner at at least one measuring point (5) ), wherein at least two spatially separated measuring points (5) are provided within the pouring area, characterized in that the device is set up to determine the spatial position of the local combustion (1) from the time difference of the increase in the concentration of the at least one combustion gas at the determine at least two measuring points (5).

Description

The invention relates to a device and a method for the detection and determination of the spatial position of a local combustion in a silo for pourable, combustible materials with at least one gas sensor which detects the concentration of at least one combustion gas in a time-resolved manner at at least one measuring point, at least two spatially within the pouring area separate measuring points are provided.

Silos for pourable materials are increasingly being used to store flammable materials. In addition to the traditional storage of grain, for example, other flammable materials such as pellets or wood chips are also stored in such silos on a large scale. There have been various fires in the recent past as part of this storage. Extinguishing such fires has proven to be extremely difficult. Such fires have repeatedly destroyed the silos or entire silo systems. In the course of the extinguishing work, it has been shown that determining the position of the local combustion, for example the embers nest, within the silo as accurately as possible is at least a great advantage. On the basis of such information, on the one hand, targeted extinguishing measures can be taken, for example by local inert gas supply using lances. On the other hand, based on information about the location of the local combustion, the stored goods can be safely discharged until shortly before the source of the fire.

Local combustion is understood in the state of the art and in connection with the invention not only to be an exothermic oxidation, but any type of undesired temperature overshoot, e.g. local pyrolysis, which can be started by overheating caused by bacteria.

It is known from the prior art to monitor a silo filled with pourable, combustible substances for a fire by measuring the CO concentration in the head space of the silo and by issuing an alarm when a limit value is exceeded. The course of the concentration of the combustion gas, e.g. CO measured in the headspace, depends on various factors.

The main factors to be mentioned here are the outgassing rate of the fire itself, the outgassing rate from the non-burning material, the transport rate or speed of the gas through the bed above the source of the fire and a dilution of the fire gas by changing fresh air supply in the area of the head area.

Because the course of the concentration of the fire gas in the head space of the silo depends on such a large number of influencing factors, it is generally not possible to make a reliable statement about the spatial position of the local ones on the basis of a measurement of the fire gas concentration in the head space of the silo To hit combustion. Reliable statements about the stage of combustion and its size cannot be made on the basis of the measurements of fire gases in the head space of the silo known from the prior art for the reasons mentioned.

The DE 31 39 582 A1 describes a fire detection device for a silo, ionization fire detectors being arranged in flow channels. The flow channels are provided with several inlet openings.

The EP 2 674 197 A2 relates to a fire extinguishing system for a silo. Several carbon monoxide sensors can be provided, which report a fire when a limit value is exceeded.

In the GB 2 493 460 A a silo with a fire extinguishing system is described. Several carbon monoxide sensors can localize a fire.

The DE 195 36 582 A1 relates to a method for recording concentration profiles along a route.

On the basis of the prior art described above, the invention is based on the object of proposing a device or a method for detecting local combustion in a silo for pourable, combustible substances, the use or use of which ensures targeted and effective extinguishing measures.

According to a first teaching of the invention, the device according to the invention is characterized in that the device is set up to determine the spatial position of the local combustion from the time difference of the increase in the concentration of at least one combustion gas at the at least two measuring points.

The teaching according to the invention is based on the knowledge that combustion gases within a bed essentially spread via diffusion processes within the bed. Since the free-flowing materials are regularly packed tightly and gases, especially air, do not flow through them regularly, they spread Fire gases essentially unaffected by external effects via diffusion processes within the bed. Based on this knowledge, the arrangement according to the invention of at least two spatially separated measuring points within the pouring area makes it possible to determine the position of the local combustion in one dimension. This determination of the position in one dimension is sufficient, for example, if the expansion of the silo is significantly greater in the vertical direction than in the horizontal direction. In this case, the device according to the invention enables detection of the altitude of the local combustion. This combustion can then be combated, for example, by introducing inert gas lances through the outer shell of the silo at the appropriate height. Also, based on the specification of the

Altitude, the bulk material not yet captured by the local combustion is discharged.

In the arrangement according to the invention of two measuring points, the spatial position of the local combustion is determined from the time difference of the increase in the concentration of at least one combustion gas at both measuring points. The position of the local combustion in the connection direction of the two measuring points can then be determined via the time difference, assuming essentially identical diffusion ratios and at least approximately known diffusion speed of the combustion gas, by means of a simple rule of three.

If the diffusion speed is not known or is not known with sufficient accuracy, it can be determined to determine the position of the local combustion in the connecting direction of the measuring points by adding a third measuring point in the connecting direction of the two measuring points.

The basic principle is that additional unknown points, such as the diffusion speed or the dependence of the diffusion speed on the direction of propagation, can be determined by adding further measuring points.

The device according to the invention experiences a first advantageous embodiment in that at least four spatially separated measuring points are provided within the pouring area and that the connecting straight lines of the at least four measuring points span a three-dimensional body. Such an arrangement, in which the at least four measuring points are spatially separated from one another and neither all lie on a straight line or on one plane, enables a three-dimensional determination of the position of the local combustion even if the diffusion speed is not sufficiently known. This takes place, for example, on the assumption of a uniform diffusion through a triangulation known per se.

With this embodiment of the device according to the invention, a spatial localization of a combustion within a silo that is extended in the horizontal and vertical directions is made possible. This in turn ensures targeted control of the local combustion.

A further essential embodiment of the device according to the invention is ensured in that the at least one gas sensor is connected to at least one permeation pipe which is permeable at least over a partial length and which is laid within the pouring area.

Such a permeation tube is for example from the DE 24 31 907 A1 , the DE 197 21 081 C1 and the EP 0 692 706 A2 known. A permeation tube is a tube into which gases can penetrate along its length, in particular by diffusion. From time to time the gas column in the permeation tube is then transported, for example by a pump, to the gas sensor at a known speed, which then measures the gas concentrations in a time-resolved manner Gas sensor can be determined at different points on the permeation tube. If, for example, the gas column is transported past the gas sensor at a speed of 1 m / s, a measurement of the gas sensor after 5 seconds gives the gas concentration at a distance of 5 meters.

The time resolution of the measurement of the gas concentration required according to the invention takes place in that the gas column is guided past the gas sensor at certain time intervals. If, for example, the gas column is pumped past the gas sensor once every 5 minutes, the measuring point at a distance of 5 meters from the gas sensor can be recorded with a time resolution of 5 minutes. The achievable time resolutions are easily sufficient for the detection of local burns, since the burns in question develop only slowly. It should be noted here that the distance between the measurement periods is selected such that a diffusion equilibrium is at least essentially established.

The use of a permeation tube is initially particularly advantageous because it ensures that a relatively expensive gas sensor does not only have one, but several can measure measuring points lying along the permeation tube. On the other hand, permeation tubes used according to the invention are mechanically robust and can thus withstand the stress within the bed. At the same time, the permeation tubes used according to the invention can be produced inexpensively.

With a suitable laying of a permeation tube within the silo, four spatially separated measuring points can already be realized with one permeation tube, the connecting straight lines of the at least four measuring points spanning a three-dimensional body. This can be achieved, for example, by spiraling a permeation tube in the interior of a silo.

If at least three permeation pipes are laid inside the silo, there is great freedom when laying the permeation pipes, provided that at least four spatially separated measuring points are provided and the connecting straight lines of the at least four measuring points span a three-dimensional body.

The device according to the invention is particularly advantageous in that the at least one permeation tube is laid on the outer wall of the silo. By laying the permeation tube on the outer wall of the silo, the mechanical stress on the permeation tube by the bulk material is reduced.

The mechanical stress on the permeation tube is further reduced by the fact that the permeation tube is laid in the direction of pouring. As a result, stress on the permeation tube due to shear is largely avoided.

If a valve is provided at the end of the permeation tube facing away from the at least one gas sensor, this valve can be opened when the gas column is being transported through the permeation tube, as a result of which the gases within the bed are sucked out in the vicinity of the measuring points and thus influence the measuring environment , is avoided.

One embodiment is particularly advantageous in that the opening of the valve facing away from the permeation tube has a connection to the ambient air of the silo. As a result, the permeation tube is flushed with ambient air each time the gas column is transported, so that defined starting conditions are guaranteed for the following measurement cycle.

The accuracy and reproducibility of the measurements is further improved in that a connection to a test gas volume is provided at the end of the permeation tube facing away from the at least one gas sensor. The supply of a test gas to the end of the permeation tube ensures that the gas sensor can detect the end of the gas column being transported on the basis of the occurrence of the test gas. This enables a precise assignment of the time course of the gas column transported to the length of the permeation tube.

According to a second teaching of the invention, a method for the detection of a local combustion in a silo for pourable, combustible materials, in which the concentration of at least one combustion gas is detected with the aid of at least one gas sensor at at least one measuring point, is designed in such a way that the temporal combustion gas concentration curves be evaluated at at least two spatially separated measuring points. Regarding the advantages associated with the implementation of this second teaching of the invention, reference is made to the advantages described with regard to the first teaching of the invention.

The second teaching of the invention has an advantageous embodiment in that the temporal combustion gas concentration profiles are evaluated at at least four spatially separated measuring points and that a three-dimensional body is spanned by the connecting straight lines of four measuring points. With regard to the advantages associated with this embodiment, reference is also made to the advantages explained in connection with the first teaching of the invention.

The location of the local combustion within the bed is determined on the basis of the combustion gas concentration curves at at least two measuring points. As already explained, the evaluation of the combustion gas concentration profiles at at least two measuring points enables the position of the local combustion within the bed to be determined along the connecting straight line of the two measuring points.

The method according to the second teaching of the invention is particularly advantageous in that the temperature and / or intensity of the local combustion is determined on the basis of the combustion gas concentration profiles. In particular, if the fire gas concentration profiles of different fire gases are evaluated, conclusions can be drawn about the temperature and / or intensity of the local combustion. Depending on the temperature and / or intensity of the local combustion, the combustion gas concentration ratios change in a manner known per se. This can be done with the described embodiment of the second teaching of the invention for determining the characteristic of the local Combustion can be used in terms of temperature and / or intensity.

• 1a) schematisch ein Ausführungsbeispiel für eine in ein Silo eingebaute erfindungsgemäße Vorrichtung zur Detektion einer lokalen Verbrennung in einem Silo für schüttfähige, brennbare Stoffe,
• 1b) schematisch eine Aufsicht auf das Silo aus der sich die Positionierung der Permeationsrohre entlang des Umfangs des Silos ergibt,
• 2 schematisch eine Darstellung der Funktionsweise eines Ausführungsbeispiels für ein erfindungsgemäß verwendetes Permeationsrohr und
• 3 modellhaft einen Signalverlauf für das Messsignal eines die Konzentration eines Brandgases detektierenden, mit einem Permeationsrohr verbundenen Gassensors.

There are now a multitude of possibilities for designing and developing the device according to the invention and the method according to the invention for the detection of local combustion in a silo for pourable, combustible substances. Furthermore, an embodiment of the invention is explained in more detail in connection with the drawing. In the drawing shows

• 1a) schematically an embodiment of a device according to the invention installed in a silo for the detection of local combustion in a silo for pourable, combustible materials,
• 1b) schematically a plan view of the silo from which the positioning of the permeation tubes along the circumference of the silo results,
• 2 schematically shows the operation of an embodiment of a permeation tube used according to the invention and
• 3 model of a signal curve for the measurement signal of a gas sensor that detects the concentration of a combustion gas and is connected to a permeation tube.

The 1a) The drawing shows schematically an embodiment of an inventive device for detecting a local combustion 1 which in a silo 2 is installed. In the silo 2 there is a bed of flammable material 3 , In the exemplary embodiment shown schematically, the gas sensor detecting the concentration of at least one fire gas is temporally resolved at at least one measuring point 4 in the headspace of the silo 2 arranged. The exact arrangement is for the purpose of clear presentation in the 1a) not reproduced.

In the illustrated embodiment, a large number of measuring points are provided within the pouring area. In addition, the first teaching of the invention is initially in connection with the consideration of four measuring points 5 described. With these four measuring points 5 These are spatially separated measuring points, the dashed connecting lines of which span a three-dimensional body, which are therefore not all on a common straight line or a common plane.

From the time interval of the arrival of a fire gas, which is from the local combustion 1 goes out at the measuring points 5 can also be found when the rate of diffusion of the combustion gas within the bed of the combustible material is unknown 3 determine the spatial location of the local combustion.

At the in 1a) The illustrated embodiment is the only gas sensor 4 via three sensor valves 6 with one of the three permeation tubes 7 . 8th . 9 connected. The permeation tubes 7 . 8th . 9 indicate the maximum dumping height of the silo 2 range that is permeable to the fire gases to be detected. This is shown in dashed lines in the drawing. In the illustrated embodiment, the permeation tubes are 7 . 8th . 9 arranged on the outer wall of the silo. In order to ensure a further improved mechanical protection, the permeation tube can also be integrated in the outer wall. A necessary condition for this is that the permeation tube is connected to the gas volume of the silo even with this integration in the outer wall.

In the illustrated embodiment, the permeation tubes are 7 . 8th . 9 in the direction of dumping, here in the vertical direction along the outer wall of the silo 2 laid. At that of the gas sensor 4 opposite end of the permeation tubes 7 . 8th . 9 is an end valve 10 intended. The permeation tubes 7 . 8th . 9 opening of the end valve facing away 10 each has a connection to the ambient air of the silo. Is not shown in 1a) that at the end of the permeation tubes 7 . 8th . 9 before or after the end valve 10 a connection to a test gas volume is provided.

With the permeation tube open, for example 7 assigned, sensor valve 6 and end valve 10 will be in the permeation tube 7 located gas column via a gas pump 11 on the gas sensor 4 transported over.

In 1b) is a schematic view of the silo 2 shown, from which the positioning of the permeation tubes 7 . 8th . 9 along the perimeter of the silo 2 results.

In 2 the drawing is schematically one in a bed of wood pellets 3 introduced permeation tube 7 shown. In the exemplary embodiment shown, the permeation tube has diffusion openings 12 on, through which the gases from the bed of combustible matter 3 into the interior of the permeation tube 7 , as indicated by double arrows, can diffuse in.

Theoretically, each of the diffusion openings forms 12 one of the measuring points of the gas sensor 4 , since the gas volume assigned to the diffusion opening during the withdrawal via the gas pump indicated by an upward arrow 11 with the sensor valve open 6 is supplied to the gas sensor and can be assigned to the respective diffusion opening over the time interval of the gas detection.

If the diffusion openings become blocked 12 , it is possible to open them again by blowing them out. However, it should be noted that there is a falsification of the concentration distribution within the bed of the combustible substance in the course of blowing out 3 can come.

Through the use of permeation tubes 7 . 8th . 9 accumulation of condensate is also avoided. The gas sensor lying outside the bed 4 can be reached more easily for the purpose of replacement or maintenance, and gas sensors that consume the combustion gas can be used. Such gas sensors using the fire gas would have a clear and undefined influence on the result if they were used inside the bed.

After all, in 3 the temporal (t) combustion gas concentration curves represented by the gas sensor 5 in different measuring periods T ₁ . T ₂ . T ₃ be measured at the start of local combustion. A permeation tube is shown below the time axis to illustrate the relationship between the position of a measuring point and the measuring time.

In the measurement period T ₁ is a first increase in a fire gas concentration (c) at a measuring point 13 detected. The measuring point 13 is a point along the permeation tube 7 about the time interval from the start of pumping the gas column in the permeation tube 7 , so the time t ₁₃ , assigned.

Out 3 it can also be seen that the concentration of the combustion gas in the measurement period T ₂ at the measuring point 13 has increased in the measurement period T ₃ is the fire gas concentration at the measuring point 13 finally rose to a maximum. The broadening of the fire gas concentration profiles from T ₁ about T ₂ up to T ₃ results from the continued diffusion of the combustion gas not only towards the permeation tube but also parallel to the permeation tube.

Comparable combustion gas concentration profiles are delayed based on those from the permeation tubes 8th and 9 pumped out and over the gas sensor 4 guided gas columns determined. From the evaluation of at least four measuring points during different measuring periods T Certain gas concentration profiles, even with a horizontally and vertically extended bed of a combustible substance, the position of the local combustion within the bed can be determined if the diffusion rate of the combustion gases within the bed is unknown but approximately the same as the directions to the measuring points.

In 3 Finally, the concentration signal is shown, which is assigned to the test gas. This is the time for the gas column to be transported through the permeation tube 7 from which via an end valve 10 end of the permeation tube connected to the ambient air 7 to the gas sensor 4 assigned.

By evaluating the combustion gas concentration profiles within the permeation tubes used in the exemplary embodiment shown 7 . 8th . 9 in addition to the described determination of the location of the local combustion 1 also determine the outgassing rate and thus the intensity of the fire. If, for example, the course of the hydrogen concentration is also determined in addition to the fire gas CO, the stage of the fire, in particular the temperature of the embers, can also be determined, since a fire with a higher ember temperature imitates a higher proportion of hydrogen.

Claims (13)

Device for detecting and determining the spatial position of a local combustion (1) in a silo (2) for pourable, combustible substances (3), with at least one gas sensor (4) that detects the concentration of at least one combustion gas in a time-resolved manner at at least one measuring point (5) ), wherein at least two spatially separated measuring points (5) are provided within the pouring area, characterized in that the device is set up to determine the spatial position of the local combustion (1) from the time difference of the increase in the concentration of the at least one combustion gas at the determine at least two measuring points (5). Device after Claim 1 , characterized in that at least one third measuring point is provided, which is arranged in the connecting direction of the at least two measuring points (5) and the device is set up to determine the diffusion rate of the at least one combustion gas of the local combustion (1). Device after Claim 1 or 2 , characterized in that at least four spatially separated measuring points (5) are provided within the pouring area and that the connecting straight lines of the at least four measuring points (5) span a three-dimensional body. Device according to one of the Claims 1 to 3 , characterized in that the at least one gas sensor (4) with at least one permeable pipe (7, 8, 9) connected at least over a partial length and laid within the bulk area. Device after Claim 4 , characterized in that the at least one permeation tube (7, 8, 9) is laid on the outer wall of the silo (2). Device after Claim 4 or 5 , characterized in that the at least one permeation tube (7, 8, 9) is laid in the pouring direction. Device according to one of the Claims 4 to 6 , characterized in that a valve (10) is provided at the end of the permeation tube (7, 8, 9) facing away from the at least one gas sensor (4). Device after Claim 7 , characterized in that the opening of the valve (10) facing away from the permeation tube (7, 8, 9) has a connection to the ambient air of the silo (2). Device according to one of the Claims 4 to 8th , characterized in that a connection to a test gas volume is provided at the end of the at least one permeation tube (7, 8, 9) facing away from the at least one gas sensor (4). Method for the detection and determination of the spatial position of a local combustion in a silo for pourable, combustible substances, in which the concentration of at least one combustion gas is detected in a time-resolved manner with the help of at least one gas sensor at least one measuring point, the temporal combustion gas concentration profiles at at least two spatially separated measuring points are evaluated and the position of the local combustion within the bed is determined on the basis of the fire gas concentration curves at at least two measuring points, characterized in that the spatial position of the local combustion from the time difference of the increase in the concentration of the at least one fire gas at the at least two measuring points is determined. Procedure according to Claim 10 , wherein a third measuring point is provided, which is arranged in the connecting direction of the at least two measuring points and the diffusion rate of the at least one combustion gas of the local combustion is determined. Procedure according to Claim 10 or 11 , characterized in that the temporal fire gas concentration profiles are evaluated at at least four spatially separated measuring points and that a three-dimensional body is spanned by the connecting straight lines of four measuring points. Procedure according to one of the Claims 10 to 12 , characterized in that the temperature and / or intensity of the local combustion is determined on the basis of the combustion gas concentration curves.

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