NL8601697A - Determining combustible fraction in esp. fly-ash by weighing sample - in heated inert gas-filled oven, admitting oxygen for complete combustion, re-weighing, and computing fraction from wt. difference - Google Patents

Abstract

The method is intended for determining the combustible fraction of combustion residue, such as the carbon content in fly ash from coal combustion, by feeding taken samples into an oven (17) and causing their complete combustion each time determining from measurements the still combustible content initially present. Each sample is fed to a weighing (31) scale (18) arranged within an oven (17) containing an inert gas (CO2 fed via 28) and the weight is determined whilst the oven is at (constant 700-800 deg.C) temperature. Complete combustion is effected by admitting (27) oxygen and the sample weight is re-determined, the difference between the two weights being used to compute the percentage of combustibles initially present. The sample vol. fed to the scale pref. exceeds the vol. it can hold.

Description

*> NO 33905

Method and device for determining the content of carbon in the ash of a combustion device.

The invention relates to a method for determining the content of unburned components in the residue of a combustion device, such as determining the carbon content in the ash of a coal-processing device, in which an ash sample, such as fly ash, is taken each time, this sample is fed to an oven 10 and completely burned therein and measurements determine the percentage of unburnt components in the sample before it was burned.

This method is generally known and an example thereof can be found in the Netherlands Patent Application 8200425 laid open to public inspection.

According to this known method, the sample to be examined is completely burned with the aid of an excess of oxygen, after which the oxygen content and the content of the combustion gases are measured and the percentage of unburned carbon is determined on the basis of the measured values obtained. in the supplied sample.

The measurement of carbon in the ash, in particular in the fly ash of a furnace, is important in order to be able to quickly check whether combustion is proceeding correctly, because unburned carbon in the ash means loss of energy. Immediate correction of the combustion process requires a quick measurement, which can be repeated at high speed.

It is important for companies that process fly ash to know how high the percentage of unburned carbon is.

Accurate measurements are possible with the known method and device. However, the device is rather complicated and therefore quite expensive.

The object of the invention is to provide a method and device in which it is possible in a more simple manner to obtain reliable measuring results quickly with a device that is less expensive and requires less maintenance.

According to the invention, this object is primarily achieved in that the sample to be examined is fed to a scale, which is located in an oven in which there is an inert atmosphere, the weight of the sample quantity on the scale is determined in the inert atmosphere, while the furnace is at the right temperature, oxygen 40 is supplied to the furnace to burn all of the combustible components still present in the sample 8601697 2 *!> *, the weight of the burnt sample is then determined again and from the difference between the two weight measurements, the percentage of initially present unburnt components is calculated.

The invention thus essentially rests on the very simple principle by determining the weight of carbon, i.e. still combustible components, in a sample before and after combustion.

With each sampling, and thus with every measurement, only the start-10 values and the end values of the weight count. The initial values may vary. Critical when applying the principle according to the invention is not the amount of the sample which is supplied to the oven for each measurement, but the composition of the sample and the conditions under which the combustion of the incompletely burnt components in the sample takes place. For this it is important that the initial measurement takes place in an inert atmosphere and that the oven has a constant temperature. After the initial weight of the sample has been determined, the furnace is supplied with so much oxygen that the inert atmosphere is changed to an extent that allows complete combustion of the unburnt components of the sample to take place. The time at which this complete combustion has taken place can be determined empirically by setting a certain period of time in which the oxygen is supplied or by determining that this final weight no longer changes in a series of measurements of the final weight, for example twenty measurements.

Fly ash tends to spray. When a sample is supplied to the scale, part of the sample quantity will end up outside the scale in the oven. Would the sample quantity be less than the quantity that the scale can contain or. be as large as the amount that can be placed on the scale, there is a danger that by placing the quantity of fly ash on the scale or depositing the quantity of fly ash, so much fly ash ends up in the oven outside the scale that no sample quantity remains on the scale, which is representative in composition of the sample to be examined. To avoid this, it is therefore proposed according to the invention that the volume of the sample be larger than the volume that can be taken up by the dish.

The surplus ends up in the oven and will also burn when oxygen is supplied and later discharged as ash via the discharge together with the completely burnt sample. However, the use of a sample volume of 40 me, which is larger than the scale can contain, provides a greater certainty with respect to the homogeneous composition of the sample to be examined on the scale.

The device known from the aforementioned Dutch patent application 8200425 uses an oven in the form of a heated fall pipe in which the sample burns during the vertical movement of the sample through the oven, for examining the sample 5.

The device for carrying out the method according to the invention can now consist of a dosing device, which has an airtight closed connection with an oven, in which there is a scale which can tilt about a horizontal axis, which supports on a weighing device, and that means are present for tilting the tray from the horizontal position to an emptying position and back, which furnace further comprises an inert gas supply and an oxygen supply 15 as well as a closable discharge. Essential for the device according to the invention is the tilting scale, which can be remotely controlled in some way, for example with the aid of magnets or a push rod mechanism. Furthermore, the completely closed system, i.e. a system, which can be kept completely filled with an inert gas from the dosing device up to and including the discharge, so that the sample can reach the scales unaffected and only then be further burned by supplying oxygen.

A constructionally simple construction can be obtained if, according to the invention, the device is designed in such a way that the connection from the dosing device to the oven has a pipe piece, which opens just above the scale, which supports the scale directly on a weighing device placed under the oven via a shielded feedthrough placed under the shell through the bottom of the furnace, which feedthrough also guides the operating rod to effect the tilting movement of the shell, which feedthrough extends through an oven bottom which slopes towards the closable drain.

The operating mechanism for tilting the shell can be formed by a rod which extends vertically through the shielded lead-through and which can be moved upwards by a magnet and then tilt the shell. This bowl can have such a position of its center of gravity relative to the axis of rotation that the bowl automatically tilts back into the horizontal position after emptying and after retracting the operating rod. The use of a return spring is really also possible. This feed-through should guide the support of the 40 scale on the weighing device without friction and this becomes 5301 69? 4 obtained by a tubular passage to a weighing device placed under the oven in a closed cabinet, which also contains the inert atmosphere, such as the CO2, which is supplied to the oven. If oxygen is supplied to the furnace for combustion of the sample, this oxygen cannot enter the throughput filled with CO2, respectively. cabinet with weighing device. Placement of the feedthrough above the weighing device and below the scale provides reasonable assurance that no sample dust will enter the feedthrough and the cabinet below. If this does take place, the risk is nevertheless small that oxygen will also end up in the passage, since the oxygen will mainly be used up for the combustion of the sample quantity present on the scale and for the combustion of the substances that have ended up next to the scale and on the sloping ground resp. components of the sample located in the drain. If all this does take place, then only combustion takes place, which does not affect the measurement. It is of course also possible to clean the transit periodically.

According to the invention, it is preferable if between the metering device and the furnace supply pipe there is an inclined pipe, which is coupled to a vibrating device and the slope of which is such that the sample entering it is only removable when the downcomer becomes vibrated. brought.

It has already been noted that when supplying the sample to the dish it is desirable that as little as possible of the sample is sprayed. Should the sample now be dropped directly on the dish from the dosing device via a downcomer, this would result in a result in strong spraying of the sample. The inclined and vibratable pipe now prevents this. The monster falls to the bottom of this sloping pipe and remains there. If it is now made to vibrate, a very gradual discharge of the sample to the dish is possible.

Fly ash tends to stick in the metering device. It is therefore preferable that a vertically extending hose is located between the inclined pipe and the metering device and a squeeze valve can engage this hose 35 and the metering device has means for discharging the sample quantity taken and supplying it to the hose. The hose preferably consists of silicone rubber, since fly ash adheres poorly there. With the pinch valve the hose can now be closed and the sample quantity then discharged into the hose, in particular and preferably through a spray nozzle from which an 8601 697 5 CO2 "jet emerges. If the pinch valve is then opened, the sample falls into the inclined vibrating pipe. The scale is then supplied in steps.

The invention will now be further elucidated with reference to the drawing, in which the device according to the invention is schematically shown in cross-section.

The device shown in the drawing consists of a box 1 with a feed pipe 2 for the shaft to be examined at the top, which pipe opens into the dosing device 3, which is provided with a slide 4, which can be reciprocated with the aid of the cylinder 5. and which has a chamber 6 for receiving a quantity of fly ash.

At 7 there is a closable pipe section for feeding a standard sample or comparison sample.

The slide 4 can be moved from the position in which the chamber 6 is located under the pipe 2 to the shown position in which the chamber 6 is situated above a vertical hose 8, which is mounted on a zigzag-shaped pipe 10 by means of a hose clamp 9 with a sloping portion 11. This pipe is mounted in a frame 12, which is coupled to the vibrating device 13.

The hose 8 consists of silicone rubber and can be closed by means of the pinch device 14 with operating device 15, with the aid of which the two pressure members of the pinch device face each other, respectively. can be moved away from each other.

The housing 3 of the slide 4 can be provided above the hose 8 with an opening for the supply of CO2 to the chamber 6.

A sample, which comes out of the chamber 6 via the hose and released by the clamp 14 into the inclined part 11 of the pipe 10, remains therein. This pipe 10 has a discharge spout 16 which protrudes through the top wall of the oven 17. When the pipe 10 is vibrated with the vibrator 13, the sample contained in the inclined pipe section 11 will pass through the spout 16 on a scale 18 tiltable about a horizontal axis 19 and in the shape of an inverted truncated cone. The oven 17 is located in an insulated housing 20 and is heatable by means of a heating coil 21.

35 The oven has a constant temperature of 700 i 800 ° C.

The oven further has an inclined bottom 22, which connects to a discharge pipe 23, which is provided with a hinged valve 24 with operating cylinder 25 and which opens into the shaft space 26

At 27 there is a connection for the supply of O2 to 40 the entire system and at 28 there is a connection for the supply of CO2 · 8oö16S7 6

A pipe 29 protrudes through the sloping bottom 22, which rests on a cabinet part 30 in which the weighing device 31 is located. On this weighing device there is a console 32 from which a vertical rod or support arm 32 runs up through the tube 29, which support arm 32 carries the shell 18.

An electromagnet 33 is further mounted in the box 30, which is coupled to a vertically movable rod 34, the end of which is located just below the shell 18. When this rod 34 is moved upwards with the aid of the electromagnet, the scale 18 tilts about the hinge 19. Since the rod 34 may not influence the measurement results, it has no connection to the scale. The tray should therefore have reset means which return the tray from the tilted position to the horizontal position. This can be achieved by the correct location of the center of gravity of the shell relative to the pivot axis 19 or by a spring (not shown) located between a point of the shell and the supporting arm 32.

The amount of ash that is supplied to the tray by means of the metering device and the inclined pipe is greater than the amount that the tray can carry. For example, the amount is 4 to 20 grams while the scale only takes up 2 grams.

Supply takes place while the furnace and its supply and discharge are filled with an inert gas, such as 002. Then oxygen is supplied sufficient to at least completely burn the ashes on the dish, after which the weight on the dish is determined again.

The results of the measurement can be made analogously or digitally visible in a manner known per se and, if necessary, recorded with known equipment.

With the device according to the invention, a measurement can be taken every three to six minutes.

80S 1697

Claims (7)

1. Method for determining the content of unburnt components In the residue of a combustion device, such as determining the carbon content in the ash of a coal-processing device, in which an ash sample, such as fly ash, is taken each time, this sample is fed to an oven and completely incinerated therein and measurements determine the percentage of unburnt constituents in the sample before it was incinerated, characterized in that the sample to be Examined is fed to a balance located in a furnace in which there is an inert atmosphere, the weight of the sample amount on the scale is determined in the inert atmosphere while the furnace is at temperature, oxygen is supplied to the furnace to burn all the flammable components still present in the sample, the the weight of the burnt sample is then re-determined and from the difference between the two weight measurements the percentage of initially present unburnt components is calculated. Method according to claim 1, characterized in that the volume of the sample fed to the dish is greater than the volume that can be taken up by the dish. Device for carrying out the method according to claim 25. or 2, consisting of a dosing device, which has an airtight closed connection with an oven, in which there is a scale tiltable about a horizontal axis, which supports on a weighing device, and that means are provided for tilting the tray from the horizontal position to an emptying position and back, which furnace is further provided with an inert gas supply and an oxygen supply as well as a closable discharge. Device according to claim 3, characterized in that the connection from the dosing device to the oven has a pipe piece, which opens just above the tray, which supports the tray directly on a weighing device placed under the oven via a tray placed below the tray. shielded feedthrough through the bottom of the furnace, which feedthrough also guides the actuating rod to effect the tilting movement of the shell, which feedthrough passes through an oven bottom, which slopes in the direction of the closable drain. 86016S7 5. Device according to claim 3 or 4, characterized in that between the dosing device and the furnace supply pipe there is an inclined pipe, which is coupled to a vibrating device and the slope of which is such that the sample entering it can only be removed therefrom. when the downcomer is vibrated. 6. Device as claimed in claim 3, 4 or 5, characterized in that a vertically extending hose is located between the inclined pipe and the dosing device and a squeezing valve can engage on this hose and the dosing device has means for discharging the genomes therefrom sample quantity and supply to the hose. Device as claimed in claim 6, characterized in that said supply means consist of a CO2 blowing nozzle. 8601687