US3137481A - Mixing device - Google Patents

Description

June 16, 1964 P. A. MaCLEAN MIXING DEVICE 2 Sheets-Sheet l Original Filed April 16, 1958 INVENTOR. F//L/ 4 Mal/w June 16, 1964 P. A. MacLEAN MIXING DEVICE 2 Sheets-Sheet 2 Original Filed April 16, 1958 JNVENTOR.

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United States Patent() 3 Claims. (Cl. 259-97) The present invention relates to an improved mixing and stirring device, adapted to mix and homogenize liquids in a receptacle and more particularly to eliminate swirling and centrifugal churning action of the liquid being mixed, against the walls of the said receptacle.

This application is a continuation of my copending application, Serial No. 728,864, filed April 16, 1958 now abandoned.

Mixing devices for liquids, such as the conventional kitchen appliance, are usually of the egg'beater type. Such a device comprises a motor, a shaft and a mixing paddle or churning device affixed to this shaft, the said device being adapted to mix liquids in a large mixing bowl. Such a bowl must be large enough to allow for the centrifugal churning action of the mixer, and also must be of a certain minimum sturdiness, such as that of the conventional Vheavy molded glass or stainless steel kitchen mixing bowl, for example. That is, a fragile container, such as thin glassware would obviously be inadequate and would quickly break under the pressure of churning action and/or accidental Contact with the rotating impeller. Where the liquid is retained in an elongated receptacle such as a test tube or flask, a great saving in time and a far more efficient mixing action could take place if the mixer were adapted to be inserted directly into such an elongated receptacle. For example, in laboratory work where a high degree of accuracy is desired, a loss in liquid would occur if liquids are transferred from test tubes to mixing bowl and back again to test tubes.

This is unavoidable under existing devices. Moreover,

the conventional mixer could not be used where the liquid level was within a short distance of the top portion of the receptacle, as the liquid would quickly overflow and be spilled in thecourse of the mixing action.

Brielly stated, this invention provides an easily cleaned liquid mixing device of simple construction wherein mixing is carried out within a confined chamber.

Itis, therefore, a special object of the present invention to provide an improved mixing device for liquids retained in elongated fragile receptacles such as test tubes or the like. Y

It is a further object of the present invention to provide mixing means for liquids that eliminate to a great extent swirling and churning effects due to centrifugal force being exerted on said liquids.

Yet a further object of the present invention is to'` provide mixing means for liquids wherein minimum vibration is imparted to the surrounding receptacle.

A particular advantage of this invention is the provision of completely protected moving parts. n

Still a further object of the present invention is to provide mixing means for liquids stored in receptacles of various shapes and sizes whereby access is readily made to said receptacles. l

A particular advantage of the present invention is that it permits of thorough and convenient cleaning 'of the mixer. This feature is of major importance for laboratory application.

These and other objects and advantages of the present invention will be apparent from the following description and accompanying drawing, and the claims appended thereto. n

In ,the drawing: t FIG. 1 is a cross-sectional of the present invention.

FIG. 2 is aplan view along line 2 2 of FIG. l (with receptacle 46jremoved).

View in elevation of Va device FIG. V3u is a longitudinal cross-section of an embodif mentof a device of the present invention, employing an alternative impeller Vmeans and a flexible shaft drive means.

V FIG. 4 is an exploded view, partly broken away, showing an alternative embodiment of the present invention.

FIG. 5 shows in elevation and partially broken away the invention shown in FIG. 4 as employed in a resin kettle.

Referring now more particularly to the drawing, there is shown in FIG. l a device of the present invention charv acterized generally by thevnumeral 10.. Tube 12 in the embodiment here illustrated is shown Aas an elongated member of relatively narrow diameter, adapted to be inserted in vessels such as test tubes, beakers or flasks.

However, it will be understood that this configurationV is not critical and that the length and diameter of this this tube defines a flow passage from inlet opening 16 to outlet opening 18. A wall portion 20 is disposed transversely approximate to opening 18 .of this tube, the

` wall thus being adapted to act as a deflection surface. A

serve as flow straightening means.

second tube Y22 is formed coaxially about tube,12 and extends longitudinally to enclose a portion of the upper section of tube 12. Tube 22 extends axially forward of tube 12, and abuts wall20 to dene an inverted cupmember. The abutting edge of tube 22 istightly sealed to wall surface 20 by threaded engagement, where registering threadsare formed on the inner edge of tube 22, and the rim of wall 20, by soldering, or by simple force fit.

The space between the inner wall of tube 22 and the adjacent confronting outer wall of tube 12 defines a second flow passage 32 formed concentrically about tube 12,

through which, in operation, liquid will pass opposite in direction to flow through passage 14. The outlet of this second flow passage is defined by the openingY 24 oftube 22.

It will be noted from FIG. 1 that tube 12 is spaced a fixed distance from the inner wall 28 of tube 22. This requisite spacing is maintained by baille members 26 interposed between inner wall-28 of tube 22 and outer wall Y 30 of tube 12. Baffie members 26 are rigidly soldered to a ring 23, giving the inner tube 12 the requisite rigidity relatively little blockage to the said second ow passage while acting to prevent swirling of therliquid being acted upon.

Liquid is drawn into ow passage 14 by means of motor 38 which rotates shaft 40, upon which is mounted impeller 42, disposed proximate to the opening 16 of tube 12. Shaft 40 is positioned coaxially in tubef12, passing f through an aperture formed in wall 20. Inroperation, tube 12 is introduced into receptacle 46 containing liquid 48. Upon rotation of shaft 40 by motor 38, impeller 42 draws liquid up into flow passage 14 with considerable velocity. impeller 42 is shrouded by the walls of tube 12; therefore, there is little or no centrifugal thrust exerted against receptacle 46. Hence, there is no spill or overflow. The liquid drawn through ow passage 14 thrusts against wall Patented June 16, 1964 It should be particularly noted, however,` that surface and is then deected into second ow passage 32. It is then returned to receptacle 46 by the force of the liquid column forced up through ow passage 14. In the return direction, the liquid iows downwardly over the outer wall of tube 12 in iiow passage 32. While flowing through llow passage 32, the liquid has imparted to it a straightening action by the action of baiiie members 26. Thus all turbulence and swirling motion taking place in the region of wall 20 is largely eliminated, and the liquid descends downward into receptacle 46 owing with relative smoothness over the outer wall of tube l2. VThe liquid continuously re-enters receptacle 46, as the mixing cycle is continued. Thus, the llow of liquid in the device of the present invention is almost entirely in an upward and downward direction, with little or no lateral component of motion.

In order to completely disassemble the apparatus for cleaning, collar 2S is unscrewed from tube 22 thus permitting the removal of tube 12, vanes 26 and ring 23 as a unit. Collar 31 is then unscrewed from the end of tube 13. This permits flanged polyiiuoroethylene split bushing 33 to be removed together with impeller 42 and shaft 40. It will be noted that shaft 4t) is provided with a reduced portion over which the split bushing 33 is positioned. A force t split washer 35 limits the downward thrust of shaft in response to the action of impeller 42 during operation. The end of shaft 40 is keyed into the motor shaft by any of the conventional coupling arrangements.

FIG. l also illustrates another important feature of the present invention, namely, that it isnot necessary to immerse tube 12 to a maximum depth within the receptacle for the device to function adequately. Thus, the present device can be employed with relatively shallow receptacles and still function eliiciently to stir and mix liquids retained therein, whereas conventional mixing devices would be entirely inoperative under such a situation. It should also be noted that the receptacle can be full almost to the top and mixing will still be possible utilizing the present device, without danger of spill.

As shown in FIG. 3, an alternate method of supporting tube 12 in spaced relationship to wall 20 and outer tube 22 is to fasten the upper portion of tube 12 against the surface of wall Ztl by a soldering or brazing operation. Alternatively, the tubes 12 and 22 and wall 24) may be integrally formed by conventional metal working techniques such as by casting. In this embodiment, apertures 36 are formed in the upper portion of tube 12', serving as outlet ports for flow passage 14 and providing an access to the second flow passage 32. In this embodiment, bafe members 26 likewise serve as in the dual role of support and anti-swirl element.

It will be noted that whereas the embodiment of FIG. l provides but little resistance to the liow of liquid at the top of tube 12', the embodiments of FIGS. 3 and 4 employ a number of orices 36 and 64, respectively, so that liquid is expelled therethrough under pressure resulting in en- Y hanced mixing action.

As shown in FIG. 3, an alternate form of impeller unit is provided which comprises a spiral configuration Sil formed upon shaft 40', this spiral extending through a considerable portion of the length of tube 12'. This imparts an improved impeller action. The shaft 40 is maintained in position by split bushing 47 which is, in turn, locked in by clamping nut 43.

Shown in FIGS. 4 and 5 is yet another embodiment of the present invention, illustrating improved shaft supporting means and improved positioning of the baille members. A unitary structure 51 is provided, which comprises a torque tube 52 having a number of baffle members 54 extending radially outward along most of the length of this tube. At one end of tube 52, there is formed a collar portion S6 and a threaded neck portion S8. In assembling the unit, shaft 40 is positioned in sleeve 52 being mounted on bearings similar to that shown in FIG. 1. Impellel' 42 is Securely attached to the terminal portion of shaft 4G. Outer tube 22 is furnished with an internally threaded portion which registers with externally threaded neck portion 5S. Prongs 27 of vanes 54 iit into registering apertures in sleeve 52. A terminal portion 31 of vanes 54 t into registering slots of collar 56. This arrangement permits rapid assembly, disrnounting and cleaning or" the vanes. Inner tube 12 and collar S7 are an integral assembly which is slipped over the vane portion of sleeve 52 and is clamped against seat S9 by neck portion 5S. Varies 54 register tightly with the inner wall of tube 12', and tube 12' is provided with apertures 64 which serve as outlet ports whereby liquid entering tube 12 under impeller action can be forced into the flow passage defined by the area between 22 and 12', as explained previously. Collar 56a is threadably secured to the lower end of tube 52. The construction and function of collar 56a are the same as collar 31 which was described hereinabove with respect to FIG. 1. That is, unscrewing collar 56a will permit the removal of shaft 40 and impeller i2 for cleaning thereof.

It should be noted that the basic principle illustrated in the above three embodiments of the present invention is that of internal mixing, namely, that the entire mixing action takes place inside the device, not in the receptacle. The mixing action commenced by the impeller is continued by the impact of liquid particles against the walls of the flow passages and against the walls of the vanes, which promotes very effective mixing action during the entire period the liquid is traveling through the device.

It should be particularly noted that vanes structure 54 of the embodiment positioned within the inner tube as shown in FIG. 4 provides very eiiicient means for eliminating centrifugal swirling action. Therefore, this embodiment is particularly adapted for use with fragile receptacles, such as test tubes. Another feature of this embodiment is the great ease of assembling and dismantling the tube sections, whereby tube 12' and 22' can readily be removed for purposes of cleaning.

As shown in FIG. 1, the mixer structure of the present invention is secured rigidly to the motor rotating the shaft, by means of bolts or similar connecting members 66. For greater flexibility, connecting members 66 may be removed and motor coupling 68, shown here as rigidly coupled to shaft' 40, may be coupled to an intermediate length of ilexible shafting 78, whereby the device of the present invention can be used, for example, for mixing of the contents of a large number of racked test tubes, the flexible shaft portion providing maximum mobility in this application while the motor is maintained in a viixed position. In FIG. 3, motor 38' is shown coupled to shaft 40 by flexible shaft 78. Handle 79 provides a convenient means for holding the mixer.

An important advantage of this device is that it may readily be litted through small orifices. This lends to it utility as a mixer for resin reaction kettles.

Heretofore mixers for such devices were of limited capabilities as performance was often secondary to abilityto plug 84 ts into the neck of the reaction vessel 80. The

unit of this invention may be made suliiciently small to fit through the neck` opening of a typical reaction kettle chemically resistant plastics, as shown heretobefore, for seals and the like, it is also contemplated that the invention may be embodied in mixers formed from glass, plastics or other metals besides stainless steel. For example, a glass mixer would have utility in certain biological and bacteriological processes where the ability to sterilize the mixer would be of extreme importance. On the other hand, it is contemplated to produce the body structure disclosed as a one-piece injection molding of a lthermoplastic resin such as polystyrene or nylon for applications wherein it may be desirable to dispose of the mixer because of contamination as may result from radiological applications.

The method of forming the unit will be dependent on the material chosen. The device is well adapted to molding, casting or other well known fabrication techniques.

There has thus been provided in accordance with the present invention a compact, highly efficient device, relatively simple in construction and ease of manufacture, adapted to mix liquids with minimum risk of damage to fragile receptacles, and minimum risk of spill and overflow due to centrifugal or swirling action during the mixing process. Various changes and modifications in the present device can be made by those skilled in the art without, however, departing from the scope and spirit of this invention.

What is claimed is:

l. A device for mixing liquids in a receptacle comprising:

a torque tube having an outer wall;

a second tube open at each end having an inner wall opposite said torque tube outer wall and concentric to said torque tube, to define a lirst flow passage therebetween said first ow passage being characterized by a substantially larger intake cross sectional area than outlet cross sectional area whereby liquids are discharged under pressure;

a wall portion disposed transversely to said second tube,

proximate to one end thereof;

a third tube disposed coaxially about and enclosing at least part of said second tube and extending axially forward of said second tube to abut said transverse wall in sealed relationship thereto, the volume bctween the inner wall of said third tube and the confronting outer wall of said second tube defining a second flow passage concentric about said rst ow passage and communicating therewith proximate to said Wall portion; a rotatable shaft axially disposed in said torque tube; bale members radially aligned with respect to said shaft, said baille members extending between said inner wall of said third tube and said outer wall of said second tube; impeller means carried by said shaft whereby rotation of said shaft, when said first tube is introduced into said liquid, will force a portion of said liquid through said lirst ow passage and, in turn, through said second W passage so as to return said liquid to said receptacle; and a bushing characterized by a low coefficient of friction interposed between said shaft and said torque tube. 2. The mixing device of claim 1 including axially movable collar means to exert pressure on said bushing for deforming said bushing so as to seal the opening between said shaft and said torque tube so as to prevent said liquid from entering therein.

3. The device of claim l, wherein said bushing is provided with a flange adapted to extend over the edge of said tube and means to clamp said ange to said tube.

References Cited in the file of this patent UNITED STATES PATENTS 1,194,355 Bunnell Aug. 15, 1916 1,891,122 Urch Dec. 13, 1932 1,933,346 Schwentker Oct. 31, 1933 2,662,042 Dougherty Dec. 8, 1953 2,736,536 Banowitz Feb. 28, 1956 FOREIGN PATENTS 338,440 Great Britain Nov. 20, 1930

Claims (1)

1. A DEVICE FOR MIXING LIQUIDS IN A RECEPTACLE COMPRISING: A TORQUE TUBE HAVING AN OUTER WALL; A SECOND TUBE OPEN AT EACH END HAVING AN INNER WALL OPPOSITE SAID TORQUE TUBE OUTER WALL AND CONCENTRIC TO SAID TORQUE TUBE, TO DEFINE A FIRST FLOW PASSAGE THEREBETWEEN SAID FIRST FLOW PASSAGE BEING CHARACTERIZED BY A SUBSTANTIALLY LARGER INTAKE CROSS SECTIONAL AREA THAN OUTLET CROSS SECTIONAL AREA WHEREBY LIQUIDS ARE DISCHARGED UNDER PRESSURE; A WALL PORTION DISPOSED TRANSVERSELY TO SAID SECOND TUBE, PROXIMATE TO ONE END THEREOF; A THIRD TUBE DISPOSED COAXIALLY ABOUT AND ENCLOSING AT LEAST PART OF SAID SECOND TUBE AND EXTENDING AXIALLY FORWARD OF SAID SECOND TUBE TO ABUT SAID TRANSVERSE WALL IN SEALED RELATIONSHIP THERETO, THE VOLUME BETWEEN THE INNER WALL OF SAID THIRD TUBE AND THE CONFRONTING OUTER WALL OF SAID SECOND TUBE DEFINING A SECOND FLOW PASSAGE CONCENTRIC ABOUT SAID FIRST FLOW PASSAGE AND COMMUNICATING THEREWITH PROXIMATE TO SAID WALL PORTION; A ROTATABLE SHAFT AXIALLY DISPOSED IN SAID TORQUE TUBE; BAFFLE MEMBERS RADIALLY ALIGNED WITH RESPECT TO SAID SHAFT, SAID BAFFLE MEMBERS EXTENDING BETWEEN SAID INNER WALL OF SAID THIRD TUBE AND SAID OUTER WALL OF SAID SECOND TUBE; IMPELLER MEANS CARRIED BY SAID SHAFT WHEREBY ROTATION OF SAID SHAFT, WHEN SAID FIRST TUBE IS INTRODUCED INTO SAID LIQUID, WILL FORCE A PORTION OF SAID LIQUID THROUGH SAID FIRST FLOW PASSAGE AND, IN TURN, THROUGH SAID SECOND FLOW PASSAGE SO AS TO RETURN SAID LIQUID TO SAID RECEPTACLE; AND A BUSHING CHARACTERIZED BY A LOW COEFFICIENT OF FRICTION INTERPOSED BETWEEN SAID SHAFT AND SAID TORQUE TUBE.

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