US3144202A - Stabilizing devices for generating and guiding potential whirls - Google Patents

Stabilizing devices for generating and guiding potential whirls Download PDF

Info

Publication number
US3144202A
US3144202A US100999A US10099961A US3144202A US 3144202 A US3144202 A US 3144202A US 100999 A US100999 A US 100999A US 10099961 A US10099961 A US 10099961A US 3144202 A US3144202 A US 3144202A
Authority
US
United States
Prior art keywords
whirl
potential
guiding
trough
diffuser
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US100999A
Inventor
Helmbold Theodor
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Application granted granted Critical
Publication of US3144202A publication Critical patent/US3144202A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04DNON-POSITIVE-DISPLACEMENT PUMPS
    • F04D17/00Radial-flow pumps, e.g. centrifugal pumps; Helico-centrifugal pumps
    • F04D17/02Radial-flow pumps, e.g. centrifugal pumps; Helico-centrifugal pumps having non-centrifugal stages, e.g. centripetal
    • F04D17/04Radial-flow pumps, e.g. centrifugal pumps; Helico-centrifugal pumps having non-centrifugal stages, e.g. centripetal of transverse-flow type

Definitions

  • the present invention relates to stabilizing devices for the development and control of whirling masses of a supplied medium which are known as potential whirls or vortices such as roller-shaped or ring-shaped potential whirls.
  • Such potential whirls are suitable as means for bending a fluid stream, as, for example, in transverse flow type blowers, diffusers, valves, flue gas chimneys, whirls at the rear of motor cars, or liquid streams.
  • trough-shaped guiding bodies have been used to generate and guide such potential whirls as disclosed, for example, in said copending application.
  • the shape of the trough-shaped guiding bodies correspond to the shape of the guided potential whirl.
  • Such trough-shaped guiding act to hold the potential whirl substantially in place within the transverse blower rotor in opposition to the influence exerted on the whirl by rotation of the rotor.
  • an air cushion is developed between the whirl and the trough-shaped body.
  • This air cushion interferes with the proper and accurate guidance of the whirl and makes it noisy with the result that the efficiency of the transverse flow type blower is reduced.
  • This air cushion is formed by eddies along the inwardly directed surface of the trough-shaped guiding body which tend to push the whirl or vortex away from the guiding body to thereby make the whirl unsteady. This unsteadiness of the whirl contributes to noise and impairs the efficiency of the blower.
  • the object of this invention is to avoid the foregoing problems and disadvantages.
  • This is accomplished in accordance with the present invention by providing a special trough-shaped body or stabilizing device for guiding the potential whirl.
  • This special trough-shaped body has a passage extending from the interior of the trough with respect to the turning direction of the whirl and the rear part of the body is arranged so that it does not touch the whirl.
  • the passage extending from the interior of the troughshaped body connects an interior part of the troughshaped body with a predetermined exterior region of the body.
  • the interior part and the exterior region connected together by the passage are arranged such that the pressure, within the exterior region, is lower than the pressure within the interior part.
  • the medium forming the whirl as, for example, air is drawn in small quantities from the interior part of the trough to the exterior region, within which the whirl is turning off the trough.
  • the medium may be picked up by the fluid stream moving toice wards the whirl and is supplied again to the exterior part of the whirl.
  • the passage provided at a trough-shaped guiding body is slot-shaped and is arranged to extend either over the whole length of the trough-shaped guiding body or only over parts of the body.
  • the passage can also be formed by a series of bores.
  • partial disks are provided for at the trough-shaped guiding body and are arranged to extend approximately normal to the rotational axis of the potential whirl. These partial disks divide a long potential whirl into several short whirls such that each short whirl no longer has any disturbing effect.
  • the partial disks preferably correspond in their form and size to the cross section of the guided potential whirl and are rotatably supported.
  • a set of double outer end disks is provided for. These double end disks. essentially consist of two disks arranged at a small distance from each other and substantially normal to the rotational axis of the whirl.
  • these double end disks have an effect similar to a labyrinth packing so as to prevent the potential whirl from drawing additional masses of the medium to its core.
  • the inner end disks directly limit the length of the potential whirl and preferably correspond in form and size to the transverse cross section of the guided potential whirl.
  • the outer end disks are larger than the inner disk and may be formed by the housing parts of the apparatus to which the disk assembly is applied, such as a transverse flow type blower, diffuser, flue gas chimney or the like.
  • Diffusers facilitate the transmutation of velocity head into a static pressure head. This is accomplished providing for a gradually increasing cross section of flow area extending away from the inlet opening of the diffuser. By this construction, velocity of the medium entering through the inlet is retarded. As a result, the static pressure of the medium is increased.
  • the magnitude to which the diameter of known diffusers can be enlarged is limited since the medium will not flow along the wall of the diifuser and the stream of the medium consequently will not fill the exit of the diffuser if the flare of the enlarging flow area is made too great. It is usually desirable to construct diffusers with an enlargement or flare angle that is greater than 15".
  • the stabilizing device of the invention to a diffuser.
  • the trough-shaped guiding bodies are arranged for generating and stabilizing one or several potential whirls lying in a plane normal to the flow direction and parallel to the wall of the diffuser.
  • the apparatus producing the potential whirls according to the invention is arranged within the interior of the diffuser and effectuates an increased dispersion of the fluid stream passing through the diffuser to thereby insure that the medium fills the passage of the difiuser.
  • the present invention enables diffusers to be constructed with wider enlargement or flare angles and appreciably shorter length without diminishing the efliciency of the diffuser.
  • the slot hereinbefore referred to, which is formed within the guiding body in an axial direction to the guided potential Whirl, extends over the entire length of the guiding body or over a part of the body.
  • the slot an essentially strip-shaped adjustably arranged body is provided for.
  • the diffuser partial disks are provided for which support the whirl in an axial direction. These disks are arranged approximately normal to the rotational axis of the potential whirl and essentially correspond in shape and size to the cross section of the whirl. These disks also may be rotatably mounted.
  • the cross section of the fluid stream in the diffuser according to the invention is normally circular, but, alternatively, it may be of any other shape.
  • two or more trough-shaped guiding bodies may be arranged within the diffuser such that they are positioned one behind the other with regard to the direction of fluid flow through the diffuser.
  • the trough-shaped guiding bodies preferably are formed by the wall of the diffuser.
  • FIGURE 1 is a transverse sectional view of a transverse flow type blower rotor taken along lines 11 of FIGURE 2 and illustrating a vortex guiding and stabilizing device according to one embodiment of the present invention
  • FIGURE 2 is a side elevational view of the blower shown in FIGURE 1 with the blower rotor partially broken away to illustrate the side elevation of the vortex guiding and stabilizing device shown in FIGURE 1;
  • FIGURE 3 shows a plotted graph of results of the device according to the invention when used in a transverse flow type blower
  • FIGURES 4 and 4a show an embodiment of diffuser according to the present invention, equipped with means for guiding a potential whirl in one line
  • FIGURE 5 shows another embodiment of diffuser according to the present invention.
  • a trough-shaped guiding body 1 constructed in accordance with the principles of the present invention is shown to be mounted within a transverse flow type blower unit 20 (FIGURE 1) having a peripherally bladed rotor 22 mounted for rotation about a shaft axis 24.
  • Rotor 22 is positioned between and in the region of a fluid inlet channel 26 and a fluid outlet channel 28.
  • Channels 26 and 28 are separated from each other by a partition 30 disposed externally adjacent to rotor 22.
  • Channel 26 and 28 are suitable delimited at their sides opposite from partition 30 by means of a housing wall 32.
  • rotation of rotor 22 in a predetermined direction draws fluid from inlet channel 26.
  • the fluid stream passing from inlet channel 26 passes transversely through rotor 22, as indicated by the arrows and is propelled into outlet channel 28.
  • the trough-shaped guiding body 1 produces and holds the vortex in its proper position within rotor 22 and constitutes an improvement of the guiding body disclosed in said 00- pending application.
  • the guiding body to accomplish its purpose, is mounted within rotor 22 radially between the shaft axis 24 and partition 30 and adjacent to partition 30 in the region where the vortex is to be formed and positioned.
  • Arranged on the trough shaped guiding body 1 are at least a pair of axiallyspaced apart parallel partial disks 4 corresponding in- At opposite ends: of the body 1 a pair of parallel outer end disks 6 are; mounted on body 1 such that disks 4 extend axially be-- tween disks 6.
  • disks 6 are larger than the:
  • tial disks 4 divide the guided potential whirl into several shorter whirls.
  • body 1 axially spaced apart parallel double inner end disks 5 are mounted between disks 4 and 6.
  • disks 5 are mounted on body 1 closely adjacent to disks 6.
  • the inner end disks 5 essentially correspond in shape and size to the cross section of the guided potential whirl.
  • the outer end disks 6 are largerthan the inner disks 5 which are about the same size as: disks 4.
  • Each of the slots 2 extend between adjacently disposed disks 4 and 5 such that one disk 5 is positioned at one end of the slot and one disk 4 is positioned at the opposite end of the slot.
  • blower 20 In operation of blower 20, the whirl or vortex formed on guiding body 1 is guided and held in position by body 1. As mentioned previously, an air cushion formed by small eddies tends to develop on guiding body '1 between the radially inwardly directed surface thereof and the vortex guided thereby.
  • the air cushion is continuously removed by slits 2 to maintain body 1 substantially free of disturbing air eddies which otherwise would tend to make the guiding vortex unsteady.
  • FIGURE 3 shows a series diagrammatically plotted curves representing the supply intensity with respect to the extension of the blower in the direction of the rotational axis of the potential whirl.
  • the guiding body 1 functions to generate and guide the potential whirl for the blower and is positioned within the blower rotor.
  • the abscissa 7 of the graph shown in FIGURE 3 represents the lateral extension of a blower incorporating guiding body 1.
  • the ordinate axis 8 represents .the supply in tensity depending on the lateral position.
  • the plotted curve 9 is for a trough-shaped guiding body 1 without partial disks and without slots according to the invention. Curve 9 clearly shows that at the sides of the blower there is an essentially lower supply intensity than in the middle region.
  • the curve 10 represents a trough-shaped guiding body 1 which is provided with the slots 2 extending from the interior of the trough to the exterior part of the guiding body in the direction of the whirl movement.
  • the air cushions are sucked from the interior of the trough through the slots so that an accurate guidance of the potential whirl is eifectuated within the troughshaped guiding body.
  • the influence of drawing air from the interior of the body 1 by means of slots 2 is clearly shown by curve 10 in comparison to curve 9 in that the intensity of medium supply is appreciably improved throughout both sides of the blower.
  • the curve 11 is for a trough-shaped guiding body 1 equipped with slots 2 arranged according to the invention, and with partial end disks.
  • Curve 11 shows an appreciable improvement of supply intensity over a very wide range.
  • the improved supply intensity results from the arrangement of the end disks 6 which allows the potential whirl to suck only small quantities of separate air.
  • the partial disks 4 prevent a deformation of the whirl when the Whirl becomes relatively long.
  • FIGURES 4 and 5 illustrate diffusers which conventionally convert the velocity head of a flowing medium into pressure head.
  • these diffusers act on a fluid stream having given velocity and pressure heads to increase the pressure head While reducing the velocity head.
  • a diffuser 12 is shown to have an inlet 13.
  • the air stream enters inlet 13 for passage through the diffuser.
  • Diffuser 12 comprises trough-shaped guiding body 1b arranged near the inlet 13 of diffuser 12 and functioning to guide a potential whirl indicated at 20.
  • whirl which is essentially a vortex or turbulence
  • This whirl or vortex spreads the fluid stream passing through difluser 12, causing it to uniformly diverge and increase in cross-section without producing objectionable currents.
  • whirl 20 is located adjacent to inlet 13.
  • objectionable eddy currents tend to develop on guiding body 1b.
  • These eddy currents are continuously removed by a slot 2b.
  • Slot 2b extending from the inner part of the trough in the movement direction of the potential whirl, is provided in a portion 14 of body 1b.
  • the trough-shaped guiding body 1b is formed by the interior wall surfaces of the diffuser. The provision of slot 2b stabilizes whirl 20, thus enabling it to act on the fluid stream passing through diffuser 12 without tearing the boundary layers of the stream.
  • FIGURE 5 shows a diffuser 15.
  • the air stream enters difluser 15 through an inlet 16.
  • two trough-shaped guiding bodies 10 and 1a arranged in the flow direction one behind the other.
  • the annular whirls or vortices formed on guiding bodies 10 and 1a are respectively indicated at 22 and 24.
  • Both guiding bodies are provided with slots 2a formed in bodies 140, 14a.
  • the trough-shaped guiding bodies 111 and 1a are formed by the interior wall surfaces of the diffuser.
  • vortex guide means in said transfer device for guiding and stabilizing the position of said potential whirl to control the direction of said fluid stream through said device, said vortex guide means comprising a body having a concave inner surface for supporting and guiding said potential whirl, said concave surface corresponding in size and shape to a substantial portion of the periphery of said Whirl and located adjacent thereto, and fluid passage means providing at least one uninterrupted fluid passage in said body extending from the region of said inner concave surface to the rearward part of said body with regard to the flow direction of the potential whirl supported thereby, said passage means being operable in co-operation with said whirl and the fluid flow through the device to produce a suction effect for continuously removing fluid boundary layers forming between said whirl and said surface.
  • said vortex guide means comprises at least one disk shaped member mounted on said guide body intermediate the oppositely facing ends thereof facing axially with respect to the rotational axis of said potential whirl, said diskshaped member projecting from said surface into the region of said potential whirl supported thereby in substantially perpendicular relationship to said rotational axis to axially divide said potential Whirl into at least two segments.
  • said vortex guide means comprises double outer end disk shaped elements mounted at opposite ends of said body and axially delimiting said potential whirl, said elements extending substantially normal to the axial flow direction of said whirl.
  • said 3 8 transfer device comprises a diffuser having a diffuser Wall said vortex guiding means being disposed Within said formed in P y Said yrotor radially between the rotational axis thereof and 8.
  • said said partition transfer device comprises a transverse flow type blower having an inlet and outlet, a rotor disposed transversely 5 References Ci i h fil f hi patent between said inlet and outlet and being rotatable to convey a fluid in a stream from said inlet to said outlet, FOREIGN PATENTS and a partition separating said inlet from said outlet, 225,767 Australia Dec. 4, 1959

Landscapes

  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Structures Of Non-Positive Displacement Pumps (AREA)

Description

Aug. 11, 1964 'r. HELMBOLD 3,144,202
STABILIZING DEVICES FOR GENERATING AND GUIDING POTENTIAL WHIRLS Filed April 5, 1961 2 Sheets-Sheet 1 30 I NVENTOR f1 5 Theodor Helmbold ATTORNEY 5 Aug. 11, 1964 Filed April 5, 1961 T. HELMBOLD STABILIZING DEVICES FOR GENERATING AND GUIDING POTENTIAL WHIRLS 2 Sheets-Sheet 2 INVENTOR. 4 "1@/4 United States Patent 3,144,202 STABILIZING DEVICES FUR GENERATTN G AND GUIDING POTENTIAL WHEELS Theodor Helmhold, Hedwigstrasse 4, Munich, Germany Filed Apr. 5, 1961, Ser. No. 100,999 Claims priority, application Germany Nov. 19, 196i) 8 Ciaims. (Cl. 230-125) The present invention relates to stabilizing devices for the development and control of whirling masses of a supplied medium which are known as potential whirls or vortices such as roller-shaped or ring-shaped potential whirls.
This is a continuation-in-part of my copending application Serial No. 96,953, filed March 30, 1961, and entitled Transverse Flow Type Blowers.
Such potential whirls are suitable as means for bending a fluid stream, as, for example, in transverse flow type blowers, diffusers, valves, flue gas chimneys, whirls at the rear of motor cars, or liquid streams.
It has been previously suggested to utilize potential whirls for influencing flowing media. In transverse flow type blowers, trough-shaped guiding bodies have been used to generate and guide such potential whirls as disclosed, for example, in said copending application. As disclosed in said copending application, the shape of the trough-shaped guiding bodies correspond to the shape of the guided potential whirl. Such trough-shaped guiding act to hold the potential whirl substantially in place within the transverse blower rotor in opposition to the influence exerted on the whirl by rotation of the rotor. As a result of the influence of the guiding body on the whirl, an air cushion is developed between the whirl and the trough-shaped body. This air cushion interferes with the proper and accurate guidance of the whirl and makes it noisy with the result that the efficiency of the transverse flow type blower is reduced. This air cushion is formed by eddies along the inwardly directed surface of the trough-shaped guiding body which tend to push the whirl or vortex away from the guiding body to thereby make the whirl unsteady. This unsteadiness of the whirl contributes to noise and impairs the efficiency of the blower.
The object of this invention is to avoid the foregoing problems and disadvantages. This is accomplished in accordance with the present invention by providing a special trough-shaped body or stabilizing device for guiding the potential whirl. This special trough-shaped body has a passage extending from the interior of the trough with respect to the turning direction of the whirl and the rear part of the body is arranged so that it does not touch the whirl.
The passage extending from the interior of the troughshaped body connects an interior part of the troughshaped body with a predetermined exterior region of the body. The interior part and the exterior region connected together by the passage are arranged such that the pressure, within the exterior region, is lower than the pressure within the interior part. As a consequence, the medium forming the whirl, as, for example, air is drawn in small quantities from the interior part of the trough to the exterior region, within which the whirl is turning off the trough. By transferring the medium to the exterior side of the trough-shaped body, the medium may be picked up by the fluid stream moving toice wards the whirl and is supplied again to the exterior part of the whirl. By evacuating the whirl forming medium from the interior of the trough which is guiding the whirl, no accumulation of the whirl generating medium is allowed to develop to lift the whirl off the guiding trough. In this manner the potential whirl is settled in its movement and position within the guiding body.
According to a feature of the invention the passage provided at a trough-shaped guiding body is slot-shaped and is arranged to extend either over the whole length of the trough-shaped guiding body or only over parts of the body.
The passage can also be formed by a series of bores.
Those guided potential whirls which have a comparatively long length in comparison to their diameter tend to increase their rotational diameter to a certain degree and consequently become shorter. In order to prevent the unfavorable effect which such a condition has on the efliciency of the potential whirl, partial disks are provided for at the trough-shaped guiding body and are arranged to extend approximately normal to the rotational axis of the potential whirl. These partial disks divide a long potential whirl into several short whirls such that each short whirl no longer has any disturbing effect. The partial disks preferably correspond in their form and size to the cross section of the guided potential whirl and are rotatably supported.
Since the static pressure near the core of a potential whirl is less than the static pressure nearer to the exterior of the whirl, the whirl tends to suck in additional medium in an axial direction with the result that its mass is increased. As a consequence, the favorable influence which the whirl has on the fluid stream is diminished. In order to avoid this increase in mass of the potential whirl, a set of double outer end disks is provided for. These double end disks. essentially consist of two disks arranged at a small distance from each other and substantially normal to the rotational axis of the whirl. In accordance with the present invention, these double end disks have an effect similar to a labyrinth packing so as to prevent the potential whirl from drawing additional masses of the medium to its core. The inner end disks directly limit the length of the potential whirl and preferably correspond in form and size to the transverse cross section of the guided potential whirl. The outer end disks are larger than the inner disk and may be formed by the housing parts of the apparatus to which the disk assembly is applied, such as a transverse flow type blower, diffuser, flue gas chimney or the like.
By applying the stabilizer device according to the invention to transverse flow type blowers, less noise and increased flow over the whole width of the blower is attained.
Diffusers facilitate the transmutation of velocity head into a static pressure head. This is accomplished providing for a gradually increasing cross section of flow area extending away from the inlet opening of the diffuser. By this construction, velocity of the medium entering through the inlet is retarded. As a result, the static pressure of the medium is increased. In practice, the magnitude to which the diameter of known diffusers can be enlarged is limited since the medium will not flow along the wall of the diifuser and the stream of the medium consequently will not fill the exit of the diffuser if the flare of the enlarging flow area is made too great. It is usually desirable to construct diffusers with an enlargement or flare angle that is greater than 15". In order to minimize the slope of the flare to thereby insure that the fluid stream passing through the diffuser fills the exit thereof and at the same time to provide for an enlargement flare that is greater than 15 it has been the practice in the past to increase the length of the diffuser. Diffusers which are relatively long, however, cannot be used advantageously in certain applications.
This foregoing difficulty is overcome by applying the stabilizing device of the invention, to a diffuser. The trough-shaped guiding bodies are arranged for generating and stabilizing one or several potential whirls lying in a plane normal to the flow direction and parallel to the wall of the diffuser.
The apparatus producing the potential whirls according to the invention, is arranged within the interior of the diffuser and effectuates an increased dispersion of the fluid stream passing through the diffuser to thereby insure that the medium fills the passage of the difiuser. As a consequence, the present invention enables diffusers to be constructed with wider enlargement or flare angles and appreciably shorter length without diminishing the efliciency of the diffuser.
In applying the guide body to a diffuser, the slot, hereinbefore referred to, which is formed within the guiding body in an axial direction to the guided potential Whirl, extends over the entire length of the guiding body or over a part of the body. In forming the slot an essentially strip-shaped adjustably arranged body is provided for.
In order to divide the potential whirl extending over the circumference of the diffuser partial disks are provided for which support the whirl in an axial direction. These disks are arranged approximately normal to the rotational axis of the potential whirl and essentially correspond in shape and size to the cross section of the whirl. These disks also may be rotatably mounted.
The cross section of the fluid stream in the diffuser according to the invention is normally circular, but, alternatively, it may be of any other shape.
In diffusers constructed for greater velocity gradients two or more trough-shaped guiding bodies may be arranged within the diffuser such that they are positioned one behind the other with regard to the direction of fluid flow through the diffuser.
The trough-shaped guiding bodies preferably are formed by the wall of the diffuser.
The present invention will now be described with reference to the accompanying drawings, in which:
FIGURE 1 is a transverse sectional view of a transverse flow type blower rotor taken along lines 11 of FIGURE 2 and illustrating a vortex guiding and stabilizing device according to one embodiment of the present invention;
FIGURE 2 is a side elevational view of the blower shown in FIGURE 1 with the blower rotor partially broken away to illustrate the side elevation of the vortex guiding and stabilizing device shown in FIGURE 1;
FIGURE 3 shows a plotted graph of results of the device according to the invention when used in a transverse flow type blower;
FIGURES 4 and 4a show an embodiment of diffuser according to the present invention, equipped with means for guiding a potential whirl in one line, and FIGURE 5 shows another embodiment of diffuser according to the present invention.
Referring now to the drawings and more particularly to FIGURES 1 and 2 a trough-shaped guiding body 1 constructed in accordance with the principles of the present invention is shown to be mounted within a transverse flow type blower unit 20 (FIGURE 1) having a peripherally bladed rotor 22 mounted for rotation about a shaft axis 24. Rotor 22 is positioned between and in the region of a fluid inlet channel 26 and a fluid outlet channel 28. Channels 26 and 28 are separated from each other by a partition 30 disposed externally adjacent to rotor 22. Channel 26 and 28 are suitable delimited at their sides opposite from partition 30 by means of a housing wall 32.
The foregoing blower construction is disclosed in said copending application to which reference is made in the event a more detailed description is required for an understanding of the present invention.
As disclosed in said copending application, rotation of rotor 22 in a predetermined direction draws fluid from inlet channel 26. The fluid stream passing from inlet channel 26 passes transversely through rotor 22, as indicated by the arrows and is propelled into outlet channel 28.
As disclosed in said copending application, when rotor 22 is rotated, a vortex or potential whirl is formed within rotor 22 radially between partition 30 and shaft 24. It will be appreciated that this potential whirl thus formed, exerts a guiding influence on the fluid stream passing through rotor 22 in that the whirl will divert or bend the stream downwardly (as viewed from FIGURE 1) and somewhat towards itself.
According to the present invention, the trough-shaped guiding body 1 produces and holds the vortex in its proper position within rotor 22 and constitutes an improvement of the guiding body disclosed in said 00- pending application. As shown, the guiding body, to accomplish its purpose, is mounted within rotor 22 radially between the shaft axis 24 and partition 30 and adjacent to partition 30 in the region where the vortex is to be formed and positioned. Arranged on the trough shaped guiding body 1 are at least a pair of axiallyspaced apart parallel partial disks 4 corresponding in- At opposite ends: of the body 1 a pair of parallel outer end disks 6 are; mounted on body 1 such that disks 4 extend axially be-- tween disks 6. As shown, disks 6 are larger than the:
shape to the guided potential whirl.
partial disks 4.
direction of the whirl movement.
tial disks 4 divide the guided potential whirl into several shorter whirls. At the ends of the trough-shaped guiding: body 1 axially spaced apart parallel double inner end disks 5 are mounted between disks 4 and 6. As shownin FIGURE 2, disks 5 are mounted on body 1 closely adjacent to disks 6. The inner end disks 5 essentially correspond in shape and size to the cross section of the guided potential whirl. The outer end disks 6 are largerthan the inner disks 5 which are about the same size as: disks 4. Each of the slots 2 extend between adjacently disposed disks 4 and 5 such that one disk 5 is positioned at one end of the slot and one disk 4 is positioned at the opposite end of the slot.
In operation of blower 20, the whirl or vortex formed on guiding body 1 is guided and held in position by body 1. As mentioned previously, an air cushion formed by small eddies tends to develop on guiding body '1 between the radially inwardly directed surface thereof and the vortex guided thereby.
With the provision of slits 2, however, in the rearward edge of guiding body 1 with respect to the flow direction of the vortex as shown, a suction effect is established to continuously draw oflf fluid medium adjacent to the inwardly directed surface of body 1.
Thus, the air cushion is continuously removed by slits 2 to maintain body 1 substantially free of disturbing air eddies which otherwise would tend to make the guiding vortex unsteady.
FIGURE 3 shows a series diagrammatically plotted curves representing the supply intensity with respect to the extension of the blower in the direction of the rotational axis of the potential whirl. The guiding body 1 functions to generate and guide the potential whirl for the blower and is positioned within the blower rotor. The abscissa 7 of the graph shown in FIGURE 3 represents the lateral extension of a blower incorporating guiding body 1. The ordinate axis 8 represents .the supply in tensity depending on the lateral position. The plotted curve 9 is for a trough-shaped guiding body 1 without partial disks and without slots according to the invention. Curve 9 clearly shows that at the sides of the blower there is an essentially lower supply intensity than in the middle region. This effect is caused by the fact that the guided potential whirl in the interior of the blower rotor is sucking additional air into its core at its ends. Thus, the mass of the potential whirl is increased and, as a consequence, the favorable influence which the whirl has on the fluid flow through the blower is correspondingly diminished. In addition, the guiding of the whirl within the trough of the guiding body is interrupted by air cushions which are produced as a result of the influence of the whirl by the guiding body.
With continued reference to FIGURE 3, the curve 10 represents a trough-shaped guiding body 1 which is provided with the slots 2 extending from the interior of the trough to the exterior part of the guiding body in the direction of the whirl movement. With this slot construction, the air cushions are sucked from the interior of the trough through the slots so that an accurate guidance of the potential whirl is eifectuated within the troughshaped guiding body. The influence of drawing air from the interior of the body 1 by means of slots 2 is clearly shown by curve 10 in comparison to curve 9 in that the intensity of medium supply is appreciably improved throughout both sides of the blower.
With continued reference to FIGURE 3, the curve 11 is for a trough-shaped guiding body 1 equipped with slots 2 arranged according to the invention, and with partial end disks. Curve 11 shows an appreciable improvement of supply intensity over a very wide range. The improved supply intensity results from the arrangement of the end disks 6 which allows the potential whirl to suck only small quantities of separate air. Furthermore, the partial disks 4 prevent a deformation of the whirl when the Whirl becomes relatively long.
FIGURES 4 and 5 illustrate diffusers which conventionally convert the velocity head of a flowing medium into pressure head. Thus, these diffusers act on a fluid stream having given velocity and pressure heads to increase the pressure head While reducing the velocity head.
In FIGURES 4 and 4a a diffuser 12 is shown to have an inlet 13. The air stream enters inlet 13 for passage through the diffuser. Diffuser 12 comprises trough-shaped guiding body 1b arranged near the inlet 13 of diffuser 12 and functioning to guide a potential whirl indicated at 20. Owing to the path of the fluid stream flowing through diffuser 12 and to the construction of body 16, it is clear that whirl (which is essentially a vortex or turbulence) is of annular shape surrounding the fluid stream. This whirl or vortex 20, owing to the circular direction of movement of fluid therein, spreads the fluid stream passing through difluser 12, causing it to uniformly diverge and increase in cross-section without producing objectionable currents. As noted from FIG- URE 4, whirl 20 is located adjacent to inlet 13. As explained in connection with the embodiment of FIG- URES 1 and 2, objectionable eddy currents tend to develop on guiding body 1b. These eddy currents are continuously removed by a slot 2b. Slot 2b, extending from the inner part of the trough in the movement direction of the potential whirl, is provided in a portion 14 of body 1b. As shown, the trough-shaped guiding body 1b is formed by the interior wall surfaces of the diffuser. The provision of slot 2b stabilizes whirl 20, thus enabling it to act on the fluid stream passing through diffuser 12 without tearing the boundary layers of the stream.
FIGURE 5 shows a diffuser 15. The air stream enters difluser 15 through an inlet 16. According to the invention there are provided two trough-shaped guiding bodies 10 and 1a arranged in the flow direction one behind the other. The annular whirls or vortices formed on guiding bodies 10 and 1a are respectively indicated at 22 and 24. Both guiding bodies are provided with slots 2a formed in bodies 140, 14a. As shown, the trough-shaped guiding bodies 111 and 1a are formed by the interior wall surfaces of the diffuser.
The invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.
What is claimed and desired to be secured by United States Letters Patent is:
1. In combination with a fluid transfer device for conducting a fluid stream from one region to another, and having means for producing a potential whirl entirely within the device, vortex guide means in said transfer device for guiding and stabilizing the position of said potential whirl to control the direction of said fluid stream through said device, said vortex guide means comprising a body having a concave inner surface for supporting and guiding said potential whirl, said concave surface corresponding in size and shape to a substantial portion of the periphery of said Whirl and located adjacent thereto, and fluid passage means providing at least one uninterrupted fluid passage in said body extending from the region of said inner concave surface to the rearward part of said body with regard to the flow direction of the potential whirl supported thereby, said passage means being operable in co-operation with said whirl and the fluid flow through the device to produce a suction effect for continuously removing fluid boundary layers forming between said whirl and said surface.
2. The combination defined in claim 1 wherein said vortex guide means comprises at least one disk shaped member mounted on said guide body intermediate the oppositely facing ends thereof facing axially with respect to the rotational axis of said potential whirl, said diskshaped member projecting from said surface into the region of said potential whirl supported thereby in substantially perpendicular relationship to said rotational axis to axially divide said potential Whirl into at least two segments.
3. The combination according to claim 1 wherein said passage means is formed by a series of bores.
4. The combination according to claim 2 wherein said disk shaped member corresponds in shape and size to the cross section of the potential whirl.
5. The combination defined in claim 4 wherein said vortex guide means comprises double outer end disk shaped elements mounted at opposite ends of said body and axially delimiting said potential whirl, said elements extending substantially normal to the axial flow direction of said whirl.
6. The combination defined in claim 5 wherein said elements are formed larger than said disk shaped member.
7. The combination defined in claim 1 wherein said 3 8 transfer device comprises a diffuser having a diffuser Wall said vortex guiding means being disposed Within said formed in P y Said yrotor radially between the rotational axis thereof and 8. The combination defined in claim 1 wherein said said partition transfer device comprises a transverse flow type blower having an inlet and outlet, a rotor disposed transversely 5 References Ci i h fil f hi patent between said inlet and outlet and being rotatable to convey a fluid in a stream from said inlet to said outlet, FOREIGN PATENTS and a partition separating said inlet from said outlet, 225,767 Australia Dec. 4, 1959

Claims (1)

1. IN COMBINATION WITH A FLUID TRANSFER DEVICE FOR CONDUCTING A FLUID STREAM FROM ONE REGION TO ANOTHER, AND HAVING MEANS FOR PRODUCING A POTENTIAL WHIRL ENTIRELY WITHIN THE DEVICE, VORTEX GUIDE MEANS IN SAID TRANSFER DEVICE FOR GUIDING AND STABILIZING THE POSITION OF SAID POTENTIAL WHIRL TO CONTROL THE DIRECTION OF SAID FLUID STREAM THROUGH SAID DEVICE, SAID VORTEX GUIDE MEANS COMPRISING A BODY HAVING A CONCAVE INNER SURFACE FOR SUPPORTING AND GUIDING SAID POTENTIAL WHIRL, SAID CONCAVE SURFACE CORRESPONDING IN SIZE AND SHAPE TO A SUBSTANTIAL PORTION OF THE PERIPHERY OF SAID WHIRL AND LOCATED ADJA-
US100999A 1960-11-19 1961-04-05 Stabilizing devices for generating and guiding potential whirls Expired - Lifetime US3144202A (en)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
DE3144202X 1960-11-19

Publications (1)

Publication Number Publication Date
US3144202A true US3144202A (en) 1964-08-11

Family

ID=8087736

Family Applications (1)

Application Number Title Priority Date Filing Date
US100999A Expired - Lifetime US3144202A (en) 1960-11-19 1961-04-05 Stabilizing devices for generating and guiding potential whirls

Country Status (1)

Country Link
US (1) US3144202A (en)

Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS5142101A (en) * 1974-10-07 1976-04-09 Mitsubishi Heavy Ind Ltd DEIFUYUUZAA
JPS5297401A (en) * 1975-12-27 1977-08-16 Klein Schanzlin & Becker Ag Means for minimizing cavitation wear
US4328661A (en) * 1980-09-12 1982-05-11 Duffers Associates, Inc. Cross flow rotary mower having an axial expansion section
JPS58175208U (en) * 1982-05-18 1983-11-24 三菱重工業株式会社 pressure recovery device
US4497445A (en) * 1980-03-10 1985-02-05 Rolls-Royce Limited Diffusion apparatus
US5632142A (en) * 1995-02-15 1997-05-27 Surette; Robert G. Stationary gas turbine power system and related method
US20130022444A1 (en) * 2011-07-19 2013-01-24 Sudhakar Neeli Low pressure turbine exhaust diffuser with turbulators
US8425188B2 (en) 2011-06-30 2013-04-23 Pratt & Whitney Canada Corp. Diffuser pipe and assembly for gas turbine engine
US9874223B2 (en) 2013-06-17 2018-01-23 Pratt & Whitney Canada Corp. Diffuser pipe for a gas turbine engine and method for manufacturing same

Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS5142101A (en) * 1974-10-07 1976-04-09 Mitsubishi Heavy Ind Ltd DEIFUYUUZAA
JPS5297401A (en) * 1975-12-27 1977-08-16 Klein Schanzlin & Becker Ag Means for minimizing cavitation wear
US4497445A (en) * 1980-03-10 1985-02-05 Rolls-Royce Limited Diffusion apparatus
US4328661A (en) * 1980-09-12 1982-05-11 Duffers Associates, Inc. Cross flow rotary mower having an axial expansion section
JPS58175208U (en) * 1982-05-18 1983-11-24 三菱重工業株式会社 pressure recovery device
US5632142A (en) * 1995-02-15 1997-05-27 Surette; Robert G. Stationary gas turbine power system and related method
US8425188B2 (en) 2011-06-30 2013-04-23 Pratt & Whitney Canada Corp. Diffuser pipe and assembly for gas turbine engine
US20130022444A1 (en) * 2011-07-19 2013-01-24 Sudhakar Neeli Low pressure turbine exhaust diffuser with turbulators
US9874223B2 (en) 2013-06-17 2018-01-23 Pratt & Whitney Canada Corp. Diffuser pipe for a gas turbine engine and method for manufacturing same

Similar Documents

Publication Publication Date Title
US4566852A (en) Axial fan arrangement
KR0180555B1 (en) Vacuum cleaner
US5551841A (en) Axial-flow fan
EP0413406B1 (en) A method for forming a zone surrounded by an air-stream
US3334807A (en) Fan
US3312386A (en) Fan
EP0772007B1 (en) Jet fan
US3275223A (en) Fluid moving means
US3144202A (en) Stabilizing devices for generating and guiding potential whirls
US2847156A (en) Fan assembly
US2991927A (en) Apparatus for moving fluids
US3221983A (en) Centrifugal fan
US3433403A (en) Fan inlet shroud
CZ290391B6 (en) Inlet funnel-like part for centrifugal fans
KR0180742B1 (en) Vacuum cleaner having an impeller and diffuser
US3198423A (en) Helicoid fan
JPS63219825A (en) Exhauster for gas turbine consisting of jet diffuser
JP2001115997A (en) Multi-blade fan
US1787655A (en) Apparatus and method of controlling fans
US3295750A (en) Cross flow machine
US3437262A (en) Cross-flow fluid machines
US2253066A (en) Fan
JP4592908B2 (en) Fan seal structure
US3026787A (en) Induction air distributors
JPH06249194A (en) Electric blower