EP0622112A1

EP0622112A1 - An agitator blade

Info

Publication number: EP0622112A1
Application number: EP94106477A
Authority: EP
Inventors: Yasuo Noda; Hideo Noda; Takaya Inoue
Original assignee: Kansai Chemical Engineering Co Ltd
Current assignee: Kansai Chemical Engineering Co Ltd
Priority date: 1993-04-30
Filing date: 1994-04-26
Publication date: 1994-11-02
Anticipated expiration: 2014-04-26
Also published as: EP0622112B1; JPH078776A; DE69423122T2; DE69423122D1

Abstract

An agitator blade (2) comprises a plurality of local agitators (22) mounted on a mounting frame (21), which in turn is secured to an agitator shaft (12). The agitator shaft (12) is rotated by a motor (13) to drive the local agitators (22) to mix the fluid thoroughly. When applied for agitation and mixing processes, the agitator blade (2) of this invention can realize a high degree of mixing easily and reliably in a short period of time and with a small driving power. Further, the construction of this agitator blade (2) is simple.

Description

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to an agitator blade and more particularly to an agitator blade which is capable of mixing fluids efficiently and reliably.

Description of the Prior Art

Among widely used agitator blades are turbine blades, oar blades, marine blades and ribbon blades. When these conventional agitator blades are used for agitating and mixing within small equipment or tanks, a high degree of mixing close to 1 can be reached in a relatively short time without trouble with a single agitator blade.
When such agitator blades are used in large-scale tanks in plants, however, the use of only one agitator blade may result in an unexpected dead space being formed in the tanks, taking a protracted length of time to mix fluids at a sufficiently high degree of mixing. Even after many hours of mixing operation, it is often not possible to achieve a high degree of mixing that is easily realized for small-scale equipment and tanks.
One possible way to cope with such a situation is by increasing the number of agitator blades. There is, however, a limit on the number of agitator blades that can be used in the tank. Even if the number of agitator blades is increased to as many as is allowed in the tank, the degree of mixing does not increase in proportion to an increase in the number of agitator blades. The additional agitator blades on the other hand require additional driving power, significantly increasing the operation cost.
After having conducted research on ways to eliminate aforementioned drawbacks experienced with the conventional agitator blades, the inventors of this invention have developed an agitator blade which is simple in construction and can achieve a high degree of mixing easily and reliably and with a minimum amount of driving power, and which comprises a plurality of local agitators for simultaneous agitation at multiple locations.

SUMMARY OF THE INVENTION

The present invention concerns an agitator blade in which local agitators are mounted to a mounting frame secured to an agitator shaft.
In this invention, the local agitators themselves are not directly driven and require no driving power. The only member that is driven is the agitator shaft. There are no structural limitations except for the following requirement. That is, as the agitator shaft is driven, the mounting frame on which the local agitators are mounted is rotated about the agitator shaft to let fluid to be mixed pass through the local agitators, locally agitating the fluid in the tank. Such local agitators may be used as a flow mixer.
The flow mixer, as explained in "Kagaku Kogaku Binran (or Chemical Engineering Handbook)" compiled by Kagaku Kogaku Kyokai (Chemical Engineers Association) and published by Maruzen Kabushiki Kaisha in 1988, page 567, is a device that makes use of a kinetic energy of fluid flow in mixing the fluid and which is installed in a flow passage of the fluid being transported.
According to the representative aspects of this invention, examples of the local agitator include: a cylinder incorporating one or more twisted plates; a pipe; a cylinder incorporating one or more orifice plates; a cylinder incorporating a plurality of bent plates, which are disposed in an alternately inverted relationship with one another so that the facing bent peripheral sides of the adjacent bent plates cross each other; a cylinder incorporating a plurality of flat plates, which are stacked on their peripheral sides so that the facing peripheral sides of the adjacent flat plates cross each other; a cylinder incorporating a sponge-like material; and a cylinder incorporating one or more net-like sheets so disposed as to cross the axis of the cylinder.
The twisted plate may be twisted either in a positive or forward direction (i.e. clockwise as seen from the front end of the twisted plate) or in a reverse direction (i.e. counterclockwise as seen from the front end of the twisted plate). The twist angle of the twisted plate (an angle between one end and the other end of the twisted plate) may be set anywhere in the range of 90 to 180 degrees. When a plurality of twisted plates are employed, they are arranged in series end-to-end, with their axes substantially aligned along the axis of the cylinder (the cylinder axis passing through the opposite openings of the cylinder).
The pipe may be a square cylinder or a circular cylinder, and formed as a straight pipe, curved pipe with a large curvature, or a reducing pipe.
There is no restriction on the number of holes formed in the orifice plate. One hole or two or more holes may be provided.
The bent plate may be formed by bending a square or rectangular plate at least once along a distinct bending line at near the center, or by curving the plate at least once by bringing the opposite peripheral sides toward each other to cause the central portion of the plate between the opposing peripheral sides to form a vertex.
The plurality of bent plates, which are disposed in an alternately inverted relationship with one another so that the facing bent peripheral sides of the adjacent bent plates cross each other, are installed in a rectangular parallelepiped- or a cube-shaped cylinder that circumscribes them. The plurality of bent plates are arranged side by side in the cylinder with their axes (virtually perpendicular to the bending lines or vertices) extending substantially parallel to the axis of the cylinder. As a result, the bending lines or vertices of the bent plates are placed in contact with the upper and lower internal surfaces, alternately, of the cylinder that circumscribes the bent plates.
The bent plates may have their facing peripheral sides in contact or spaced from each other.
The flat plates incorporated in the cylinder may include, for example, plates curved with a small curvature and corrugated plates with small pitches in addition to flat plates. Normally, the flat plates are virtually square or rectangular.
The plurality of flat plates are so disposed that their facing peripheral sides cross each other. The flat plates are installed inside a cylinder that inscribes them.
The flat plates may be placed in contact with each other at their facing peripheral sides or spaced from each other.
The sponge material loaded in the cylinder need only be a porous material through which fluids can pass from one opening of the cylinder to the other. For example, it may be a wire net rolled in a cylinder, a wire net folded several times into a square pillar, a metallic sponge, or a sintered metal.
Among preferable examples of the net sheets installed in the cylinder are a wire net, a plastic net and a lamination of these wires.
Inside the cylinder of the local agitator, there is formed a complex fluid passage by the twisted plates, bent plates, orifice plates, flat plates, sponge material and wire sheets.
The inner surface of the cylinder of the local agitator and the surface of the twisted plates, orifice plates, bent plates and flat plates may be either smooth or rough, or may be formed with small depressions and projections in such patterns as waves, dots or small circles.
The cylinder of the local agitator may take an arbitrary shape as long as it ensures that fluids to be mixed can pass through the cylinder. For example, the transverse cross section of the cylinder (a cross section perpendicular to the axis of the cylinder that normally corresponds to the shape of the opening) may take a polygonal shape such as a triangle, quadrangle, pentagon and hexagon, or a circular shape such as a circle, oval and ellipse, depending on the shape, number and arrangement of the orifice plates, twisted plates, bent plates and flat plates installed in the cylinder. The transverse cross section of the cylinder is preferably a circle when accommodating the twisted plates. In accommodating the bent plates and flat plates, a square or rectangular transverse cross section is preferred. The cylinder of the local agitator may be formed either as a straight pipe or a curved pipe with a small curvature.
One or more such local agitators are mounted on a mounting frame. The mounting frame may be formed as a flat plate member, a curved plate member, a square rod member, a round rod member, a shape steel member, and a structure using these members.
The size and number of the local agitators to be mounted on the mounting frame are determined according to the kind and property of fluids to be mixed, the size and shape of the tank, and the target degree of mixing.
A single mounting frame may be mounted with a plurality of local agitators.
The plurality of local agitators mounted on one or more mounting frames may employ the same construction or differing constructions.
When a plurality of local agitators are to be mounted on a single plate-like mounting frame, they are normally arranged in a lattice or checkered pattern although other arrangements are also possible. The size of the mounting frame itself is determined according to the number of local agitators to be mounted.
The local agitators are installed on the mounting frame in such a way as to allow the fluid to pass therethrough from one opening to the other during the operation.
The local agitator, which accommodates a plurality of bent plates or flat plates in the cylinder, is mounted on the mounting frame in such a way that the boundary plane on which the facing peripheral sides of the adjacent bent plates or flat plates lie and cross each other can be at any angle, from parallel to perpendicular, with respect to the rotating plane of the agitator blade.
The direction of the local agitator (i.e. the direction of axis passing through the opposing openings of the cylinder, or the direction of axis of the reducing pipe) on its rotating plane is set anywhere between the tangent direction and the radial direction of a circle whose radius is the distance from the center of the rotating plane to the local agitator, according to the viscosity of the fluid to be mixed and the agitation speed, so as to obtain as high a degree of fluid mixing as possible. The angle between the axis of the local agitator and its rotating plane is also determined arbitrarily.
Rear side of a leading end of a local agitator against rotating direction may be cut off in order to have the leading end inclined. So is a plurality of local agitators arranged in parallel, which are slightly apart or connected.
The local agitator is preferably constructed such that its direction on the rotating plane (horizontal or lateral direction) and on a plane perpendicular to the rotating plane (vertical direction) can be changed freely. This may be realized, for example, by rotatably mounting the local agitator to the mounting frame with a screw or other means.
It is also possible to automatically control the direction of the local agitator according to the viscosity of the fluid to be mixed and the agitation speed to realize a high mixing degree, as by detecting the fluid resistance to which the local agitator or the mounting frame is subjected.
Although its excellent function can be utilized to its fullest extent when applied to the agitation of fluids in a large-scale tank, the agitator blade of this invention can also be used for agitation in small tanks.
Normally one or more agitator blades of this invention are installed in the tank. A plurality of agitator blades may be secured either to the same agitator shaft or separate shafts.
A gas supplied into the tank forms bubbles, which are broken into smaller bubbles increasing the contact surface area with the fluid.
The agitator blade of this invention is suitably applied for the mixing between different liquids, between liquid and solid, between liquid and gas, between different gases, between liquid, solid and gas.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a vertical cross section of an agitation tank in which the agitator blade of this invention is installed;
Figure 2 is a plan view of the agitator blade of this invention installed in the agitation tank of Figure 1;
Figure 3 is a vertical cross section of another embodiment of the agitation tank in which the agitator blade of this invention is installed;
Figure 4 is a plan view of another embodiment of the agitator blade of this invention installed in the agitation tank of Figure 3;
Figures 5 and 6 are a side view and a vertical cross section, respectively, of a local agitator which incorporates two twisted plates that are twisted in a positive or forward direction at a twist angle of 90 degrees;
Figures 7 and 8 are a side view and a vertical cross section, respectively, of a local agitator as a reducing pipe;
Figures 9 and 10 are a side view and a vertical cross section, respectively, of a local agitator incorporating two orifice pipes;
Figures 11 and 12 are a side view and a vertical cross section, respectively, of a local agitator incorporating two twisted plates that are twisted in opposite directions at a twist angle of 180 degrees, the vertical cross section showing only the cylinder in vertical cross section with the two twisted plates shown in side view;
Figures 13 through 16 show one embodiment of the agitator blade of this invention, Figure 13 representing a perspective view of the agitator blade, Figure 14 a horizontal cross section of the local agitator used in the agitator blade, Figure 15 a front view of the local agitator with a side wall of the cylinder body removed, and Figure 16 a perspective view of bent plates built into the local agitator;
Figure 17 is a perspective view of the bent plates incorporated in the local agitator which are curved;
Figures 18 and 19 illustrate a local agitator incorporating three bent plates that are each bent five times, Figure 18 representing a horizontal cross section of the local agitator and Figure 19 representing a front view of the local agitator with a side wall of the square cylinder removed;
Figures 20 through 23 show an agitator blade equipped with a local agitator incorporating two flat plates, Figure 20 representing a partly cutaway perspective view of the agitator blade having a laterally rotatable local agitator, Figure 21 a vertical cross section of the local agitator, Figure 22 a plan view of the local agitator with the upper surface of the square cylinder removed, and Figure 23 a partly cutaway perspective view of the agitator blade having a vertically rotatable local agitator;
Figure 24 is a perspective view of an agitator blade having two local agitators mounted on a single mounting frame;
Figure 25 is a partly cutaway perspective view of a local agitator incorporating in its cylinder body a wire net rolled in a cylinder;
Figure 26 is a partly cutaway perspective view of a local agitator incorporating in its cylinder body a plurality of disk-shaped nets crossing the axis of the cylinder body; and
Figures 27 and 28 show a plan view and a slant view, respectively, of a plurality of local agitators and outer leading ends are cut in order to have leading end inclined.

DETAILED DESCRIPTION OF EMBODIMENTS

The present invention will be described in detail in conjunction with embodiments shown in the accompanying drawings. It is noted, however, that the invention is not limited to these embodiments alone.
In Figure 1 and Figure 3, an agitator shaft 12 passes through the center of a top wall of a tank body 11 of an agitation tank 1 and is connected at the upper end with a motor 13. An agitator blade 2 of this invention is secured to that part of the agitator shaft 12 contained in the tank.
The agitator blade 2 used in the agitation tank 1, as shown in Figure 1 and Figure 2, has one flat plate as a mounting frame 21 fixed to the agitator shaft 12. The mounting frame 21, which is divided in two by the agitator shaft 12, has each of its halves mounted with 78 local agitators 22 arranged in 13 rows of six local agitators each, forming a lattice pattern in which they are positioned at almost equal intervals. Further, below the lowermost row there is provided another row of 3 local agitators close to the rotating axis, bringing the total to 81. These local agitators 22 incorporate twisted plates.
The local agitators 22 are all mounted almost perpendicular to the flat plate as the mounting frame 21 and directed tangent to the circumferences of circles whose radii are defined as distances from the center of the agitator shaft 12 to the local agitators 22.
The agitation tank shown in Figure 3 may be suitably applied, for example, as a culture tank and a fermentation tank.
The agitator blade 2 used in the agitation tank 1 of Figure 3 has two pairs of mounting frames 21 formed of flat plates and secured to the agitator shaft 12 through support rods 20, as shown in Figure 3 and Figure 4. These flat-plate mounting frames 21 are placed on one and the same vertical plane (a plane including the agitator shaft axis). Each of the mounting frames 21 is mounted with four local agitators 22, which are arranged in two rows, each of two agitators, forming a lattice pattern in which they are positioned at almost equal intervals. These local agitators 22 incorporate twisted plates. The lower end of the agitator shaft 12 is supported by a bearing 14. An air supply pipe 15 is passed through the bottom wall of the agitation tank body 11 and connected to a sparger 16 at the bottom of the tank body. Air discharged from the sparger 16 rises as bubbles through the liquid to reach the agitator blade 2 where they are broken down by the local agitators into smaller bubbles improving the contact of air with the liquid.
The local agitators 22 are mounted almost perpendicular to the flat plate of the mounting frame 21 and directed tangent to circumferences of circles whose radii are defined as the distances from the center of the agitator shaft 12 to the respective local agitators.
The local agitator 3 shown in Figure 5 and Figure 6 have two twisted plates 32, 33 installed inside a cylinder body 31 with their peripheries in contact with the inner circumferential surface of the cylinder body 31.
The twisted plate 32 is made by twisting a rectangular plate--whose shorter peripheral side and longer peripheral side are substantially equal to the inner diameter and one-half the length, respectively, of the cylinder body 31--in a positive or forward direction so that the short peripheral side 321 at one end and the short peripheral side 322 at the other end are nearly at right angles. The twisted plate 33 is also formed in the similar way. These twisted plates 32, 33 are installed inside the cylinder body 31 with the facing short peripheral sides 322, 331 set approximately 90 degrees from each other, with the axes of the two twisted plates virtually aligned, and with the two twisted plates arranged in series, end-to-end, in the direction of axis of the local agitator's cylinder body 31 and inscribed in the inner circumferential surface of the cylinder body 31. These twisted plates 32, 33 form a complex flow path in the cylinder body 31 of the local agitator 3.
As the agitator shaft is rotated to drive the local agitators, the fluids to be mixed are drawn from one opening of the cylinder body 31 (for example, left-side opening in Figure 6) into the cylinder body 31, in which they are forced to pass through a complex flow path before being discharged from the other opening.
A local agitator 4 shown in Figure 7 and Figure 8 are a reducing pipe, a frustoconical hollow cylinder whose circumferential wall is slightly curved inward. The agitator blade equipped with such local agitators 4 is rotated in a direction such that a larger opening 41 moves in front of the smaller one, forcing the fluids in the tank to pass through the hollow portion of the local agitator 4 from the larger opening 41 toward the smaller opening 42.
A local agitator 5 shown in Figure 9 and Figure 10 have two orifice plates 52, 53 parallelly disposed inside the cylinder body 51 with the orifice plates in contact with the inner circumferential surface of the cylinder body. These orifice plates 52, 53 have circular holes 54, 55 formed at their centers.
The fluids to be mixed are forced into the cylinder body 51 from one opening (for example, a left-side opening in Figure 10), pass through the holes 54, 55 at the centers of the orifice plates 52, 53 and are discharged from the other opening of the cylinder body 51.
A local agitator 6 shown in Figure 11 and Figure 12 have twisted plates 62, 63 inscribed in the cylinder body 61. These twisted plates are arranged in series along the axis of the cylinder body 61 and in contact, end-to-end, with each other, with the facing short peripheral sides 622, 631 set at approximately 90 degrees from each other. The two twisted plates 62, 63 are essentially similar to those used in the local agitator 3 of Figure 5 except that they are twisted in opposite directions at the twist angle of 180 degrees.
An agitator blade 7 shown in Figures 13 through 16 have four local agitators 72 mounted one on each of four support rods 71, which are spaced 90 degrees apart and secured to the agitator shaft 12.
The local agitator 72 has two bent plates 722, 723 installed in a rectangular cylinder 721 whose opening is rectangular. The bent plates 722, 723 are formed by bending rectangular flat plates along bending lines 7221, 7231. These two bent plates 722, 723 have their facing peripheral sides 7222, 7232 in contact with each other and are disposed in an inverted relationship with each other. They are installed in the rectangular cylinder 721 so that the cylinder 721 circumscribes them. The two bent plates 722, 723 are placed side by side with their axes virtually parallel to the axis of the rectangular cylinder 721.
As a result, when these bent plates are installed inside the rectangular cylinder, the bending line 7221 of one bending plate 722 and the bending line 7231 of the other bending plate 723 come into contact with the inner surfaces of the bottom wall and the top wall of the rectangular cylinder 721.
These bent plates 722, 723 form a complex flow passage inside the rectangular cylinder 721 of the local agitator.
The local agitator 72 is mounted on the support rod 71 in such a manner that a boundary plane 724 containing the facing peripheral sides 7222, 7232 of the adjacent two bent plates 722, 723 installed inside the local agitator is perpendicular to the rotating plane of the agitator blade 7, to which the local agitator 72 is mounted.
A bolt secured vertically to the top outer surface of the rectangular cylinder 721 is passed through a hole in the support rod 71 (bolt and hole are not shown) and fastened with a butterfly nut so that the local agitator 72 is rotatable with respect to the support rod 71.
As shown in Figures 13 through 16, the local agitator 72 are radially arranged to face the agitator shaft 12.
As the local agitators 72 are driven by rotating the agitator shaft 12, the fluids to be mixed are forced into the rectangular cylinder 721 from one opening, flow through a complicated passage formed in the cylinder 721 and then are forced out from the other opening of the cylinder 721.
A bent plate 81 shown in Figure 17 is curved to cause the opposite short peripheral sides 811, 812 of a rectangular plate to come near each other with the central portion raised as a vertex 813. Another bent plate 82 is also curved in the similar manner. These two bent plates 81 and 82 are disposed side by side in an inverted relationship so that their vertices 813 and 823 project in opposite directions. These bent plates are placed inside the rectangular cylinder with their facing long peripheral sides 814 abd 824 in contact.
A bent plate 91 shown in Figure 18 and Figure 19 are formed of a rectangular plate bent along bending lines 911, 912, 913, 914, 915. A second bent plate 92 is also a rectangular plate bent along bending lines 921, 922, 923, 924, 925. The third bent plate 93 is also a rectangular plate, which is likewise bent along bending lines 931, 932, 933, 934 and 935. In other respects, these three bent plates are essentially the same as those shown in Figures 13 through 16.
A local agitator 101 shown in Figures 20 through 23 contain two rectangular plates 1011 and 1012. The rectangular plates are stacked on their long peripheral sides so that they cross each other at an angle with their long peripheral sides 10111, 10121 in contact at the central portion. They are installed in a rectangular cylinder 1013 so that the cylinder circumscribes them. A boundary plane 1014 containing the long peripheral sides 10111, 10121 is parallel to the rotating plane of the local agitator. In other respects, this local agitator 101 is essentially similar to that shown in Figures 13 through 16.
A local agitator shown in Figure 20 has a support rod 102 secured to the top of the rectangular cylinder 1013 with a thumbscrew, about which the local agitator can be pivoted laterally in either direction.
In a local agitator shown in Figure 23, a support rod 103 is secured to the side of the rectangular cylinder 1013 with a thumbscrew, about which the local agitator can be rotated in a vertical plane.
An agitator blade shown in Figure 24 has two local agitators 72, similar to the ones shown in Figures 13 through 16, mounted to both sides of a rectangular-plate mounting frame 21 secured perpendicularly to the support rod 20, with the local agitators staggered in height.
A local agitator shown in Figure 25 has a wire net 112 rolled in a cylinder and installed inside its cylinder body 111.
A local agitator shown in Figure 26 incorporates in its cylinder body 121 a plurality of disk-shaped nets 122 so disposed as to cross the axis of the cylinder body.
In Figures 27 and 28, four pairs each of two local agitators 132, 133 are secured in a radical direction with 90° angle each around a central hole 1311 at the periphery of and on the both sides of a support plate 131 of a disk shape. A pair of local agitators 132, 133 is connected each other in parallel against rotation direction.
The local agitators 132, 133 are made of square cylinders 1323, 1333 wherein a pair of two bent plates 1321, 1322 and a pair of bent plates 1331, 1332, reversely directed each other, are put in. Rear side of a leading end of the local agitator against rotating direction is cut off in order to have the leading end inclined and to have outer opening sweeped back. 134 is a boss mounted around the hole 1311 for the agitator shaft 12.
The agitator blade of this invention offers the following advantages. That is, when applied for agitation and mixing processes, the agitator blade of this invention can realize a high degree of mixing easily and reliably in a short period of time and with a small driving power. Further, the construction of this agitator blade is simple.

Claims

An agitator blade comprising:
an agitator shaft;
a mounting frame secured to the agitator shaft: and
one or more local agitators mounted to the mounting frame.
An agitator blade according to claim 1, wherein the local agitator is used as a flow mixer.
An agitator blade according to claim 1 or 2, wherein the local agitator is a cylinder incorporating one or more twisted plates.
An agitator blade according to claim 1 or 2, wherein the local agitator is a pipe.
An agitator blade according to claim 1 or 2, wherein the local agitator is a cylinder incorporating one or more orifice plates.
An agitator blade according to claim 1 or 2, wherein the local agitator is a cylinder incorporating a plurality of bent plates, which are disposed in an alternately inverted relationship with one another so that the facing bent peripheral sides of the adjacent bent plates cross each other.
An agitator blade according to claim 1 or 2, wherein the local agitator is a cylinder incorporating a plurality of flat plates, which are stacked on the peripheral sides thereof so that the facing peripheral sides of the adjacent flat plates cross each other.
An agitator blade according to claim 1 or 2, wherien the local agitator is a cylinder incorporating a sponge-like material.
An agitator blade according to claim 1 or 2, wherein the local agitator is a cylinder incorporating one or more net-like sheets so disposed as to cross the axis of the cylinder.
An agitator blade according to any one of claim 1 through 9, wherein the local agitator is rotatably supported on the mounting frame.
A method for agitating and mixing fluids by rotating one or more agitator blades in the fluids around one or more agitator shafts, said agitator blades having one or more local agitators mounted on one or more mounting frames fixed to one or more agitator shafts.