DE2326011A1 - DEVICE FOR TRANSPORTING MATERIALS TOWABLE WITH A FLUID - Google Patents

Description

DIPL.-ING. HANS W. GROENING DIPL.-CHEM. DR. ALFRED SCHÖN

FATENTAfTWJLl-TE

S / C 20-26

Crown Zellerbaeh Corporation, San Francisco, California / USA

Device for transporting items that can be entrained with a fluid materials

The invention relates to a device for transporting materials that can be carried along with a fluid "

Material in the form of individual particles, such as, for example Wood chips, sand, grains, or other materials entrained by a fluid, are often passed through pipes in the Way that this material was transported by a towing fluid Is entrained, for example air, the material with the fluid using suction fans, blowers or the like is moved rapidly from a zone at the inlet end of the tube to a remote outlet zone. It is often necessary to provide bends or corners in the transport tube so that the material from a first flow or Flow path is diverted to a second flow path extending in a different direction. Are bends or There are corners in a pipeline, then problems arise

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because the fast moving material tends to hit the surface as it tries to get around the corner, which forms the outer radius of the corner, so that erosion of the pipe surface and damage to the dragged Material as a result of such an impact.

Devices are known with the aid of which the erosion problem caused by the impact can be reduced of particles on the surfaces forming the corner. Known devices are for example in U.S. Patent Nos. 584,968 and 3,149,885; DT 584,852 and 598,363; and British Patent 731,646 and 11,590. In these patents suggest an auxiliary fluid the bend or corner to make it easier for the material to change direction. However, it has been so far never proposed the use of a device to measure the speed of the dragging fluid along the Surface is increased, which leads in the downstream direction of the inner radius of the corner, compared to the velocity of the entrainment fluid along the surface of the outer radius of the corner.

According to a feature of the invention, a device is provided which forms flow paths for material entrained by a fluid, the material flowing in and with the entrained fluid along a first flow path, undergoes a change in direction at one corner and then flowing along a second flow path which extends in a direction different from the direction of the first flow path. A device, such as a Coandadüse is mounted near the corner to the flow rate of Mitschleppfluids the surface longitudinally in a Abstromrichtwng _s which is a continuation of the inner radius of the corner is to increase, and longitudinally as compared to the Abstromfließgeschwindigkeit the Surface in the second flow path, which is a continuation of the outer radius of the corner.

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Another feature of the invention can be seen in the fact that the entrainment properties of Coanda nozzles are used to remove part of the entrainment fluid from the first flow path, to slow down the particles before they reach the corner, whereupon this removed entrainment fluid re-enters the second flow path is introduced.

Another feature of the invention is the provision of Pulling devices for pulling off or removing auxiliary dragging fluid from the flow path at a downstream point for its introduction as well as for reintroduction of this withdrawn Fluids in the system.

The invention is explained in more detail with reference to the accompanying drawings;

Show it:

Fig. 1 is a side section through a device according to a Embodiment of the invention.

Fig. 2 is a section along the line 2-2 of Fig. 1,

Fig. 3 A side section through a device which has a, represents another embodiment of the invention.

Fig. 4 is a schematic section illustrating the dimension and flow rates under specific Working conditions of a device according to the invention appear.

As already discussed the phenomenon of the "Coanda effect" this effect will first be explained in more detail. This phenomenon has been known for many years and is an example in U.S. Patent 2,052,869. This effect can be seen as the tendency of a fluid flowing out of a slot exiting under pressure, can be described to adhere to a surface in the form of an elongated lip of the slot and following this surface with the lip receding from the flow axis of the fluid as it exits the slot. on

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in this way a zone of reduced pressure is created in the area of the slot so that air or other entrainment Material that is in the zone is carried along and flows with the fluid attached to the elongated lip. A Coanda nozzle can therefore be defined as a device which takes advantage of this phenomenon.

As is apparent from FIGS. 1 and 2, there is the device shown from a device which forms a first flow path, which in the direction indicated by the arrows by one Corner 12 leads to a second flow path 14 which extends in a different direction than the first flow path.

Before the corner 12, the first flow path 10 has one generally rectangular cross-section. The flow path is through the bottom wall 16, the top wall 18 and the opposite Side walls 20 and 22 are formed. After corner 12, the second flow path is also generally rectangular Cross section and is formed by the bottom wall 24, the top wall and the opposing side walls 28 and 30.

The top wall 18 has a portion 32 that is upward diverges in a direction leading to the corner, creating an enlarged zone in the corner which is a Coanda nozzle 34 having a curved top surface 36 extending between opposing side walls 20 and 22 extends, capable of receiving. The Coanda nozzle provides a device for increasing the flow rate of the entrained fluid Details are discussed below. This nozzle has a chamber 38 for receiving fluid, such as Air, under pressure from a compressor or pump 40, with a conduit 42 leading to the chamber. Lips 44 and 46 form a slot 48 which leads out of the chamber 38. The lip 46 deviates from the flow axis of the 'fluid that exits the slot, back and forms an adhesive surface 50 for this fluid, so that a mode of action according to the above described Coanda effect is possible.

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The lower surface 52 of the nozzle 34 is flat. The nozzle is so arranged in the enlarged Ecksone that the surface 52 illustrates an upper interface for particulate material which is substantially along a straight line is dragged along in the first flow path 10. The upper curved surface 36 of the nozzle 34 provides a lower one The interface for a secondary path 54, which is in communication with the first flow path 10 through an opening 56. A sieve extends across the opening to this secondary path 54. The mesh size of the screen is chosen such that in the form of Individual particles present material is prevented from getting into this secondary flow path, while the entrainment fluid passes through the sieve.

The lower surface 52 of the nozzle 34 is inclined in such a manner that the cross-sectional area of the first flow path 10 decreases in a downstream direction from a location near the upstream end 60 of the nozzle surface towards the downstream end 62 of the nozzle surface 52. This reduction in the cross-sectional area of the flow path is therefore expedient _t since it is ensured in this way that the entrained fluid. has a sufficiently high speed when it flows through this point with a reduced area, so as to ensure entrainment of the particles su, taking into account the fact that part of the entrained fluid has been drawn off via the secondary path 54.

The wall 26 which forms an interface of the second flow path presents a first surface portion 64 which extends in a direction which intersects the first flow path downstream in continuation of the outer radius of the corner between the first and second flow paths. The wall 24, which forms another boundary surface of the second flow path 14, represents a wide surface section S6 which extends downstream in the right direction to the corner 12 in continuation of the inner radius of the corner.

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The FlieflhaftoberfläGhe 15 of the nozzle 34 is positioned such that a curtain of _e Mitschleppfluid which moves at high speed, is aligned in a direction which extends across the flow path of the entrained material along 'of the first flow path 10th The curtain is directed towards the surface 66. This high velocity curtain follows the surface 66 so that the velocity of the entrainment fluid flowing in a downstream direction along the second surface 66 is significantly increased compared to the flow velocity prevailing in the downstream direction along the first surface 64. This increased speed along the surface 66 results in a rapid deflecting effect on the entrained material. It has been found that the impact of the entrained material against the surface 64 is significantly reduced, so that the erosion of that surface is reduced a direction away from the outer surface 64, exerts a drag effect, and on the other hand carries the material in a direction away from the wall 64, thereby keeping direct impact of the material against the surface 66 to a minimum.

The method of operation of the device described can be seen with reference to FIG. 4 and in connection with the following description explain in more detail. An apparatus as shown in Fig. 4 is used. This device has the following Dimensions:

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"A" - 76 - 7 - mm 2326011 dimension "B" 82 mm (width of the wall 18) dimension "C" - 381 mm dimension "D" - 711 mm dimension "E" - 102 mm dimension II Tp Il 82 mm dimension ¹¹ G " 57 mm dimension "H" 54 mm dimension Il J.I - 102 mm dimension "K" 76 mm dimension "L" 82 mm (width of wall 26) dimension "M" 51 mm dimension

₂ Air is supplied to chamber 38 at a pressure of 0.35 kg / cm (5.0 psig). The width (distance between lips 44 and 46) of slot 48 is 1.3 mm (0.050 inches). A pitot tube is inserted through narrow openings in the walls at various points in the system to determine the velocity profiles of the air moving through the various parts of the system. The speeds (in feet per minute) are given in FIG.

If air emerges from the slot 48 (cf. FIG. 4), then it adheres to the surface 15 and follows this with a noticeable one Speed due to the aforementioned Coanda effect. This air curtain is directed downstream along surface 66 so that the flow velocity is approximately 3 mm (1/8 inch) from surface 66 about 6 mm (1/4 inch) downstream from corner 12 about 1080 m (3600 feet) per minute in an outflow direction is »If the conditions described above are observed, there is no flow at a point approximately 3 mm (1/8 inch) above the surface 64 directly opposite the point at which the 1080 meters per minute have been measured. Rather, as can be seen from the drawing, a backflow is determined, namely nit, one Speed along surface 64 of approximately 390 meters (1300 feet) per minute in an upstream direction.

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4, when air exits slot 48 at a high velocity, a zone of reduced pressure is created at the location of the slot which causes a significant volume of air to be entrained into the system through inlet 6 8 causes. When approximately 1.70 standard cubic feet per minute (SCFM) of air is supplied to the chamber 38, the supplied air flow is approximately 6.23 standard m / minute (220 SCFM) in the first flow path 1o in Upstream of opening 56, 4.2 4 standard m / minute (150 SCFM) in secondary path 54, 1.98 standard m / minute (70 SCFM) in flow path 10 downstream of opening 56 and 7.92 standard m ³ / minute (280 SCFM) in the second flow path 14. the side walls of the system consist of a rigid and transparent plastic, so that the amount of the direct impingement of material from the flow path 10 can be visually observed against the surface 64th If wood chips are fed to the inlet and entrained by entrained air, then the chips quickly pass the corner, where they only hit the surface 6 4 to a small extent. It is of course often convenient to use a further section of pipe, both upstream and downstream of the system represented by FIG. In these cases it is advisable to provide sources from which entrainment fluid is fed into the system, in addition to the Coanda nozzle which is located in the corner.

As for the fourth for the pressures under which the fluid is the Chamber 38 is fed, as well as with regard to the values of the width of the slot 48, it should be noted that these values are within a wide range can be selected, these values depending, for example, on the size of the tubes in the System as well as the speed with which the dragged material is transported through the system target. The width of the slot 48 is preferably between 0.025 and 3.810 mm (0.001 and 0.150 inches). The cross-sectional area of the slot opening should preferably be about 0.1 to 10.0% of the cross-sectional area in the conduit between the corner 12 and the downstream end 62 of the nozzle. The prints

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of the fluids supplied to the chamber 38 can .between 0.07 and 28.1 atmospheres (1 and 400 psig). For one For a given slot width, an increase in the pressure of the fluid supplied to the slot has an increase in speed of the fluid as it emerges from the slot and as it moves over the adhesive surface 50 increases the speed imparted to the material being carried along.

It should be noted that additional fluid is added to the system through nozzle 34 (FIG. 1). In order to avoid the need to enlarge the pipes in the downstream direction to the nozzle, in particular if further, relatively long pipe sections in the downstream direction to the corner are used, it is expedient to use the auxiliary drag fluid which is removed through the nozzle 34 from the system in Downstream is fed to the corner, remove. To accomplish this removal of air, a vent chamber 70 may be provided in the second flow path 14 downstream of the corner 12. This venting chamber can lead to an outlet 74 through a valve 72. Optionally, the outlet 74 may be connected to an inlet tube 76 which led to a compressor or to a pump 40 so that the withdrawn fluid may be continuously recirculated through the system.

According to the embodiment represented by FIG. 3, forms a pipe 80 provides a first flow path 82 for entrained material. The material passes around the corner 84 in a flow path 86, the is formed by a tube 88. A first downstream surface section 90 in the second flow path extends in a direction continuing the first flow path downstream of the outer radius of corner 84 intersects while a second downstream surface portion 92 extends downstream extends to the corner in continuation of the inner radius of the corner 84. The surface portion 92 forms a fluid adhesive surface for fluid emerging from the slot 94 in the Coanda nozzle 96. The fluid is from the pump or the compressor 9 8 via the chamber 100 is supplied.

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It should be noted that the velocity of the fluid moving downstream along surface 92 is substantially greater than the velocity of the fluid moving moved along surface 90 in a downstream direction. Which caused as a result of this high speed movement Dragging along the surface 92 causes the dragged material to quickly get past the corner and follows the second flow path 86.

Since a zone of reduced pressure is created in the portion of the slot, this zone "seeks" more fluid to drag along * - It is therefore useful to have an opening 102 through the outer bend of surface 90 to provide a source of this additional fluid. This opening 102 should be in communication with the atmosphere or optionally, as can be seen from FIG. 3, in connection with a ventilation chamber 104 in the downstream direction to this corner via an auxiliary conduit 106 upright to recirculate removed fluid. As can be seen from Fig. 3, A further vent line 1Ö8 with a valve 110 can be provided. If necessary, this vent line 108 can be connected to an inlet 112 to a compressor 98 stand.

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Claims (13)

Claims 1. Device for transporting and deflecting a material entrained by a dragging fluid from a first flow path around a corner into a second flow path extending in a direction that is different from the direction of the first flow path, characterized by devices (16, 18, 20, 22, 80) having a first flow path (10, 82) form, means (24, 26, 28, 30, 88) defining a second flow path (14, 86), wherein a first A downstream surface portion (64) is provided which extends in a direction which intersects the first downstream flow path in continuation of the outer radius of the corner (12), the means forming the second flow path having a second downstream surface portion (66) which intersects extends in the downstream direction to the corner (12) in continuation of the inner radius of the corner, and a device for increasing the flow rate of the entrained fluid in a downstream direction along the second distance surface area compared to the flow velocity along the first downstream surface. 2. Apparatus according to claim 1, characterized in that the device for increasing the flow rate of the entrainment luids along the second outflow surface (66) from a Nozzle (34, 96) consists of a chamber (38, 100) for receiving fluid under pressure, a pump (40, 98) for supplying Fluid into the chamber, means (44, 46) having an exit port Form (48), which leads out of the chamber, and a fluid adhesive surface (50, 92), which are arranged in this way is that the fluid adhering to it is directed in a downstream direction along the second downstream surface portion (66) will have. 309851/0363 3. Apparatus according to claim 2, characterized in that the fluid adhesive surface (50, 92) which leads away from the slot (48, 94), spaced from the second downstream surface portion (66) and positioned such that a Fluid curtain directed over the flow path of the entrained material which is transported along the first flow path (10, 82) will. 4. Apparatus according to claim 2, characterized in that the adhesive surface (92) is part of the second downstream surface section forms. 5. Apparatus according to claim 2, characterized in that a device (70, 104) is provided for removing dragging fluid which is fed to the material flow path from the chamber (38, 100) at a location below the corner. 6. Apparatus according to claim 5, characterized in that the device (70, 104) is in communication with the pump (40, 98), so that the withdrawn fluid is recirculated through the chamber. 7. Apparatus according to claim 4, characterized in that an opening (102) through the first downstream surface section (90) is provided, which allows an entry of fluid through this opening towards a zone of reduced pressure, which generated by the fluid exiting the slot (94). 8. Apparatus according to claim 7, characterized in that an auxiliary line (106) is provided, which the opening (1O2) with a zone downstream of the first downstream surface portion connects, causing a removal and a renewed dragging of the dragging fluid that is below the corner flows, is effected. 309851/0363 9. Device for transporting a fluid that can be dragged along Material in a drag fluid from a first flow path around a corner into a second flow path that turns into extending in a direction different from the direction of the first flow path is different, characterized by surface portions which form first and second flow paths for the material, a Nozzle inside the corner to remove entrainment fluid from the entrained material that has passed through the first flow path flows, as well as for reintroducing the removed entrainment fluid into the second flow path, wherein the nozzle has a chamber for Receipt of fluid under pressure and a pump for supplying fluid into the chamber, wherein a slot is also provided which emerges from the chamber, and wherein a fluid adhesive surface is furthermore provided which leads away from the slot, wherein the fluid adhesive surface is arranged such that they drag fluid that comes out of the slot over the first Flow path directs in a direction which leads in the downstream direction of the second flow path. 10. Apparatus according to claim 9, characterized in that the nozzle has surface portions which form interfaces for the first flow path, with a path for the entrainment fluid is provided that is removed from the first flow path. 11. The device according to claim 10, characterized in that a grid is provided which paves the way for the removed dragging fluid separates from the first flow path. 12. Device for transporting a fluid that can be dragged along Material in a drag fluid characterized by a flow path for the material, a device along the flow path for adding auxiliary drag fluid to the material that is transported along the flow path, as well as a removal device in the downstream direction to the auxiliary fluid supply device as well as in the upstream direction to the point at which the Material is withdrawn from the flow path, wherein the removal device can be operated in such a way that auxiliary entrainment luid is removed from the transported material. 309851/0363 13. Apparatus according to claim 12, characterized in that the removal device is connected to the supply device for the auxiliary fluid, so that the withdrawn fluid can be recirculated along the flow path. 309851/0363