EP0495172A2 - Dosing apparatus - Google Patents

Abstract

The invention relates to an apparatus for dosing viscous dusts, in particular fibrous wood-grinding dusts for dust furnaces with an intermediate storage container for receiving the dust charged, with an adjustable conveying device at the lower end of the intermediate storage container for the dosed removal of the dust from the intermediate storage container into a dust extraction line which is acted upon by compressed air and leads to the burner, and with a compensating line between the chute of the conveying device and the head end of the intermediate storage container for removal of leak air which has escaped from the dust extraction line into the device. The invention envisages that the conveying device is mounted with a hopperless intermediate storage container on a gravimetric measuring device for the dust removed, that the outlet of the conveying device opens into a chute forming a part of the compensating line and the dust removed passes from there via a second conveying device, which serves for explosionproof disconnection, into the dust conveying line, and that the cross-sectional area of the compensating line is dimensioned in such a manner that the rate of fall of the dust carried along with the leak air is greater than the flow rate of the leak air in the compensating line. The invention makes it possible to produce a dosing apparatus for viscous dusts for unsupervised continuous operation with an internal continuously operating leak air/dust separation and recycling. <IMAGE>

Description

The invention relates to a device for dosing difficult-flowing dusts, in particular fibrous and possibly pollutant-laden wood grinding dusts for dust-firing systems, with an intermediate storage container for receiving the added dust, with a controllable conveying device at the lower end of the intermediate storage container for dosed discharge of the dust from the intermediate storage container into a Compressed air operated, dust conveyor line leading to the burner, and with a compensating line between the discharge of the conveyor device and the head end of the intermediate storage container for the removal of leaked air escaping from the dust delivery line into the device.

Such a device manufactured and sold by the applicant is known (magazine "Energie", volume 37, issue 6/85). In this known device, designed for operation with wood and lignite dust, an upper cellular wheel sluice arranged directly under a dust bunker ensures the periodic filling of the intermediate storage container. The switching on and off of the upper rotary valve is controlled by two level sensors arranged one above the other. A second rotary valve, which is arranged under the intermediate storage container and which continuously delivers, takes over the fuel metering and its introduction into the dust delivery line operated with compressed air as well as the explosion-proof decoupling of the intermediate storage container and dust delivery line. Leakage air inevitably escapes from the dust delivery line via the lower rotary valve in the intermediate storage container. In order to eliminate this leakage air, a pressure equalization line is provided between the dust delivery line and the upper end of the intermediate storage container. The metering in this known device is carried out volumetrically via the speed of the lower rotary valve.

Wood abrasive dusts, in particular the fibrous dusts from MDF board production (MDF = medium-density fiber), which are increasingly increasing, are compared to mineral fuel dusts, e.g. made of hard coal or lignite, much more difficult to dose. The flow properties and the reaction to changes in the external boundary conditions depend very much on the average grain size or fiber length, the bulk density, the moisture content, the cohesion behavior and the compressibility of the dust to be metered. Further boundary conditions that make the dosing process more difficult are, on the one hand, compliance with the explosion regulations and, on the other hand, the fact that the dosing material has to be metered into a dust delivery line under excess pressure (up to 1 bar). The associated problem of the existing leakage air laden with dust is particularly important when it comes to polluted dusts, or when dosing takes place in closed rooms and improper leakage air discharge creates dust deposits that pose an increased risk of explosion.

The known device with volumetric metering does not allow exact burner control when using the fibrous wood sanding dust mentioned, because the fluctuations in the dust quality (such as changing the bulk density) cannot be detected with this type of metering. Furthermore, there is the disadvantage in the known device that, due to the decreasing cross-sectional area of the intermediate storage container, bridging occurs relatively easily, as a result of which the metering is completely interrupted, which immediately leads to Ceasefire leads and can have considerable consequences for the operation of the downstream system. Furthermore, the pressure equalization line has a relatively thin cross-section, so that it quickly becomes clogged with dust and thereby prevents pressure equalization. The result is a leakage air flow through the rotary valve which, in an uncontrolled manner, makes its way from below through the dust in the intermediate storage container. Depending on the filling level of the intermediate storage container, this creates more or less large air bubbles in the intermediate storage dust, which disintegrate again at irregular intervals or escape further upwards. This leads to different filling of the individual chambers of the cellular wheel sluice, which hinders even dosing. Even the introduction of dust into the dust conveying line is difficult because the fibrous dusts tend to agglomerate.

The invention has for its object to provide a device of the type mentioned, which enables a precise metering of heavy-flowing fibrous dusts designed for unattended continuous operation, and in which a largely dust-free leakage air discharge takes place.

The object is achieved according to the invention in that the conveying device with a funnel-less intermediate storage container is mounted on a gravimetric measuring device for the discharged dust, that the outlet of the conveying device opens into a chute forming part of the compensating line and the discharged dust from there via a second explosion device serving for explosion-proof decoupling gets into the dust conveying line, and that the cross-sectional area of the compensating line is dimensioned such that the sinking speed of the dust carried with the leakage air is greater than the flow rate of the leakage air in the compensating line.

The exact, uniform gravimetric fuel metering ensures optimal control of the combustion process. The fact that the intermediate storage container is funnel-free, ie does not taper in its cross section, prevents the dust from bridging. Dust carried by the leakage air sinks downwards due to the dimensions of the compensating line and does not get into the exhaust air.

Differential dosing scales are known which allow the gravimetric mass determination of normal, free-flowing bulk materials, but which do not meet the requirements placed on a dust-fired dosing device intended for continuous operation, especially not when it is a question of exacting , explosion-proof dosing of pollutant-laden, hard-flowing wood sanding dust into a compressed air-operated delivery line.

The cross section of the intermediate storage container preferably increases from the filling head to the conveying device, which further reduces the risk of bridging.

In a further embodiment of the invention, the upper end of the equalization line opens into the filling head above the dust application, a fine dust filter provided with an outlet opening for the leakage air being arranged at the upper end of the filling head such that it can be emptied into the intermediate storage container. As a result, the remaining dust components still contained in the leakage air are retained and returned to the intermediate storage container, so that a largely cleaned leakage air is released into the atmosphere.

It is advantageous if means for equalizing the dust discharge are arranged at the outlet of the conveying device, which preferably consist of rotating shearing knives and counteract an agglomeration of the fibrous fuel dust.

The invention is explained in more detail below with reference to an exemplary embodiment of a metering device shown in the drawing.

The intermediate storage container 1 of the dosing device is loaded from above in a vertical or - as shown - in a lateral direction through a filling shaft 15 at certain time intervals with the aid of a filling element (not shown) (e.g. screw conveyor, bucket elevator or the like). The intermediate storage container is fixedly mounted on the screw box of a speed-adjustable precision metering screw 2, and its cross section increases from top to bottom, i.e. it does not have the usual, conically narrowing funnel at the lower end, so that the dust is practically prevented from bridging. The intermediate storage container 1 and the dosing screw 2 form the central unit of the dosing device. The discharge of the dosing screw is evened out with regard to the fibrous fuel dusts that tend to agglomerate with the aid of rotating shear knives 16 and enters the chute 21, which forms the lower part of a compensating line 3 and on which there is a cellular wheel sluice 4 which holds the dust in conveyed a dust conveying line 17 which is operated in the direction of arrow 18 with compressed air and which transports the mixture of compressed air and dust in the direction of arrow 19 to the burner (not shown). The cellular wheel sluice 4 is used for explosion-proof decoupling from the dust delivery line 17 and the intermediate storage container 1.

The cellular wheel sluice 4 rotates at a relatively high speed in order to ensure in each case that the largest possible amount of dust discharged from the dosing screw 2 gets into the pressurized delivery line 17. The leakage air which forcibly escapes through the rotary valve and the chute 21 into the compensating line 3 is discharged upwards through the line 3, which is designed as a large-sized riser pipe as an extension of the chute. The cross-sectional area of the chute and the riser pipe is dimensioned such that the sinking speed of the dust entrained in the leakage air is greater than the flow rate of the leakage air. This has the advantage that a considerable part of the amount of dust contained in the leakage air can be separated by sedimentation in the riser pipe and at the same time is returned to the rotary valve 4 below.

The residual dust remaining in the leakage air reaches the filling head 6 through the likewise large-area cross connection attached to the upper end of the riser pipe, on which a fine dust filter 7 with an outlet opening 20 for the leakage air is arranged at the top. This dust filter is automatically cleaned when a certain degree of contamination is reached by compressed air introduced in the direction of arrow 5. The arrangement of the dust filter on top of the filling head 6 ensures that the amounts of dust cleaned off the filter get directly back into the metering process. This concept has the advantage of an integrated, internal, continuously operating leakage air dust separation and recirculation, so that a separate leakage air dust separation with intermediate storage in additional collecting containers is not necessary.

In order to be able to carry out the dosing by means of gravimetric dust mass measurement, the precision dosing screw 2, including the intermediate storage container 1 firmly connected to it, is mounted on a solid base plate 8, on the underside of which a tip bearing 9 directed through the center of gravity of the unit consisting of dosing screw and intermediate storage container is attached. This is carried out in such a way that the weight force of the metering central unit, which is absorbed in the tip, is introduced directly vertically into a load cell 10. This measures the weight loss per unit of time and regulates the speed of the metering screw so that the weight loss corresponds to a predetermined target value. Lateral supports with play 11 in the upper area of the intermediate storage container 1 ensure that the unit consisting of the metering screw and intermediate storage container is stably supported in the predetermined vertical position without any significant weight forces being able to be transmitted. The dosing screw outlet is gravimetrically decoupled from the chute 21 as well as the intermediate storage container 1 from the filling head 6, so that there is no direct contact and no weight forces can be transmitted here either. Sealing against dust leakage of the decoupled areas is ensured by bellows 12 and 13 which are highly flexible in the vertical direction.

All components contained in the dosing device, including all electrical control and regulation elements (e.g. contactless level monitoring 14, gravimetric measuring device) are accommodated in a compact steel frame, so that the entire device is available as a largely mobile, universally usable compact dosing system.

Claims (5)

Device for dosing difficult-flowing dusts, in particular fibrous and possibly contaminated wood sanding dusts for dust-firing systems, with an intermediate storage container for receiving the added dust, with a controllable conveying device at the lower end of the intermediate storage container for dosed discharge of the dust from the intermediate storage container into a pressurized air Burner-carrying dust conveying line, and with a compensating line between the discharge of the conveying device and the head end of the intermediate storage container for discharging leakage air escaping into the device from the dust conveying line, characterized in that the conveying device (2) with a funnel-less intermediate storage container on a gravimetric measuring device (10) is stored for the removed dust that the outlet of the conveyor (2) in a part of the compensating line (3) forming Fallsc hacht (21) opens and the discharged dust from there via a second explosion-proof decoupling device (4) into the dust delivery line (17), and that the cross-sectional area of the compensating line (3) is dimensioned so that the rate of descent with the leakage air entrained dust is greater than the flow rate of the leakage air in the compensating line (3). Device according to claim 1, characterized in that the cross section of the intermediate storage container (1) increases from the filling head (6) to the conveying device (2). Apparatus according to claim 1 or 2, characterized in that the upper end of the compensating line (3) opens into the filling head (6) above the dust application (15), and that at the upper end of the filling head (6) one with an outlet opening (20) for the leakage air provided fine dust filter (7) is arranged so that it can be emptied into the intermediate storage container (1). Device according to one of the preceding claims, characterized in that means (16) for equalizing the dust discharge are arranged at the outlet of the conveying device. Device according to claim 4, characterized in that the means (16) consist of rotating shearing knives.

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