SE439735B - MIXERS FOR DIFFERENT FLOWS IN A PIPE IN WHICH FASTLY ORGANIZED ELEMENT IS PROVIDED TO FIGURE AT LEAST TWO SCREWED FLOOR CHANNELS - Google Patents

Description

7803226-5 curvatures and are attached to the pipe wall. U.S. Pat 3,794,300 discloses a line mixer with a shaft, which extends longitudinally through a conduit and which shows a plurality of vane-like mixing elements, which are screwed formally laid around the shaft and attach to it.

Although these known devices have largely performed their work on acceptable way, they have shown some disadvantages. Because each mixing steps in these devices have been manufactured continuously sheet material, the rotational movement of the liquid in each mixture step has been fixed for each step. Furthermore, mixed the steps of the known devices have not been easy to adjust for change in the flow pattern and different flow conditions. Therefore have different mixer devices were needed for different flow conditions. Although these devices have generally been effective in mixing under laminar flow conditions, however, they do not End ~ these devices have usually been of very durable been so effective under turbulent flow conditions. natural and not easy to disassemble for cleaning. It is also often desirable to inject liquids into a line or to take samples of the liquid in the line. Thus, a need has arisen for an liquid injection and sampling system, which can be easily combined with a line mixer for interaction with the mixing PIOCGSSGI! .

Briefly, the present invention provides a line mixer of the kind mentioned above with the features specified in claim 1.

In particular, a line mixer has been provided for mixing a single liquid with at least one other substance. The mixer includes a pipeline, the cavity of which surrounds a central axis and in which a rod extends along the conduit and the central axis.

The mixer also comprises a plurality of stationary mixing stages, which extend in series along the central axis, with each mixing steps delimit a plurality of helical channels in the tubular the cavity of the wire. Each mixing step comprises a plurality special segments (which form the above-mentioned channel delimiting parts), which extend in series along the central axis. The mixer further comprises a device for adjusting both the angular position as the axial position of each segment relative to the adjacent 7803226-5 sanding segment along the axis. The line mixer is assembled through attaching a holding device to one end of the rod, after which a plurality of mixing elements are slidably arranged on the rod, each after each mixer element is shifted to the desired angular position and axial position along the rod. A stop is attached to the other end of the bar end to keep mixer elements clamped between the stop and the fastening device. The rod and mixer elements are then arranged in the lead and attached to it to prevent relative axial movement between them. The fastening device can be used either for spraying of liquid in the line or sampling of liquid in the cord. The fastening device comprises a stand with an outside and a cavity with an inside. The stand comprises at least one opening which extends radially from the inside to the outside.

A tube part extends through the opening into the cavity of the stand and the pipe part is releasably attached to the frame so that the pipe part diella position is adjustable.

As can be seen from the following, the line mixer according to the invention can easily adapted for both laminar and turbulent herring, and easily assembled and disassembled for cleaning and adjustment ning. Furthermore, the line mixer according to the invention is so designed that the number of flow channels can be varied. The device is both and can be easily combined with a liquid injector and a sampling device. simple in construction and cheap to manufacture, device.

Advantages and features of the invention will become apparent from the following descriptions. exemplary embodiments of the invention with reference to the accompanying drawings, in which Fig. 1 is a side view, partly in longitudinal section, of a line mixer according to the invention, Fig. 2 is an end view of a portion of the line mixer of Fig. 1; Fig. 3 shows an end view of a mixing element, Fig. 4 shows the mixing element in Fig. 3 from the opposite end, Fig. 5 shows a partially enlarged side view of the mixing element in Fig. 3, Fig. 6 shows a side view of a spacer element, Fig. 7 shows in partial longitudinal section a side view of a second embodiment form of the invention, .up n¿§? ' ~ i ' gßvß 4 'Vf Ah___ _ .. __ _ _, ~ .I -_-_.-____._...._._ __... _- _._.- .. ...___ __ ___ .. Å _ ADQ 7803226-5 Fig. 7A shows a schematic end view along the section A-A in Fig. 7, Fig. 7B shows a schematic end view along the line B-B in Fig. 7, Fig. 8 shows an end view of an injection and sampling device fluid in the line, Fig. 8A shows an end view in partial cross section along the lines 8A - 8A in Fig. 8, Fig. 9 shows an end view in partial cross section of a second embodiment in the form of a liquid injection and sampling device in the cord, Fig. 9A shows a cross section of the device of Fig. 9 along the line 9A - 9A, Fig. 10 shows a third embodiment of an injection and sampling device for liquid in the line and Fig. 10A shows a cross section of the device of Fig. 10 along the line. jen l0A - 10A.

With reference to Figures 1-5 of the drawing, a suitable embodiment embodiment of the line mixer according to the invention is described in detail. Fig. 1 shows a line mixer 20 comprising a hollow pipeline 22 arranged around a central axis 24. They lead the intended substances are added in a section of the line current around line 22 in a known manner. A rod or shaft 26 extends along the central axis 24 of the conduit 22. On the rod 26 is provided with a plurality of mixing steps 28, 30, 32, etc., which in series extend along the rod in the conduit 22. In six such mixing stages are shown. However, it should be clear that in each particular case the number of step of the properties of the substances to be mixed, the desired the flow, the desired pressure drop through the mixer and the the cost of operation. Each mixer step defines a plurality of screw formed channels through the pipeline 22. These screw channels stretch along the entire length of each mixing step. One of the special The distinctive features of the invention are that each mixing step involves comprises a plurality of special segments or mixing elements 34.

Each segment or mixer element 34 has the shape of a propeller and includes, as shown in Figures 3 and 4, a hub 36 and a multi-member speech blades 38, which extend radially outward from the hub 36. Each blade is helically twisted. The pitch angle of each blade 38 in relation to the central axis 24 is indicated in Fig. 5 as the angle b. The angle of inclination of the tip 38 of the blade towards the central 77803226-5 in The difference between IN axis 24, Fig. 5 is designated as angle c. these two angles (b - c) are the angle of rotation of each blade. Fig. 5, the angle b is shown as 150 and the angle c as 450, sa that the angle of rotation b - c is equal to 300. The tip angle c is the pitch of each mixer step (ie the axial distance) is correct for which a channel rotates through 3600) and in conjunction with diameter determines the hub angle of the blade b. Depending on the the mixture to be mixed and the desired pressure drop across the the entire length of the conductor 20, the tip angle c can generally vary from 3o ° to eo °. length per segment determines the number of segments 34 in each mixer stage For a given acute angle c and a given axial the rotation given to the liquid during the passage through the mixer increased. In the embodiment shown in Fig. 1 there are seven segments, which cause 1800 rotation for each screw channel within each mixer. darsteg. The axial length of the segments 34 determines the degree of variability of alternative flow patterns within the mixer 20 and therefore the axial length of the segments 34 can be selected corresponding manner. Although the axial length of the segments 34 has shown equally, it is clear that it is within the scope of the finding to include segments with different axial lengths in the same mixer. In the embodiment of Fig. 1, the axial distance between leaves of adjacent segments as small as possible to eliminate In the embodiment it is axial The lower cross-flows between the channels. the distance between the blades suitably less than the blade thickness. the radial dimension of the blades 38 is so large that each blade 38 is pipes or almost touches the inside of the pipeline 22. Any game is desirable between the tip of the blade 38 and the wall of the conduit 22 for to allow the entire mixer structure to be pulled out of the line ')') 1.:., as will be described in more detail later. Yet another particular feature of the invention is that each segment 34 further comprises a device for adjusting both angular the position and the axial position of the segment in relation to the adjacent segments along the rod 26. The adjusters include 36 and a direction sensor at the axial ends of the hubs to a predetermined, fixed angular relationship between adjacent hub admit true hub. As most clearly shown in Figs. 3, 4 and 5 include these direction sensors a plurality of linear projections or ridges 40, which project axially from the ends of the hub 36, with radial direction from the hole in the hub surrounding the rod 26 and distributed with L ', V ,, ï_ kwwn.- _} .. u ..- ~ 7803226-5 the same angular distance from each other around one end of the hub 36.

Suitably the number of committees is thirty in number with twelve degrees angular displacement, although a greater or lesser number of projections may be arranged depending on the desired accuracy of the alignment ning. Correspondingly, a plurality of linear grooves or grooves 42 received at the opposite axial end of the hub 36, which extends radially outward from the hole in the hub around the rod 26, and which are distributed uniformly around the end of the hub 36. The grooves 42 are distributed in the same way as the committees 40, i.e. with l2 ° difference nad. Since in assembling the mixer 20 the hub 36 is in sliding contact with the rod 26, it is obvious that then adjacent hubs are arranged next to each other, the projections 40 will grip in the grooves 42 and thus prevent relative rotation between adjacent true segment. Those skilled in the art will recognize that other devices for that prevent rotation between adjacent segments may be provided.

For example. each hub 36 may comprise a set of screws, which extend radially into the hub to engage the rod 26 and prevent axial or angular movement between the hub 36 and the rod 26.

Thus, a plurality of segments can be arranged axially and at an angle against the rod 26 to define a plurality of helical channels, which turn in a first direction, e.g. as shown in step 28. Similarly, a second stationary mixer can step 30 may be arranged axially adjacent to the first mixing stage 28 to define a plurality of screw channels which rotate in a second direction, which is opposite the first angular rotation.

Suitably the leading edges of the blades in the first mixing stage 30 are so arranged to divide the screw channels in the mixer stage 28.

This generally gives the best division of the flow and therefore the best mixture of the substances flowing through line 22. Similarly, the subsequent mixing steps generally give a reversal of the direction of rotation in the screw channels and also divides the screw for the previous mixer steps. It should be noted, however, that it is within the scope of the invention to arrange the various mixing steps and the segments in any appropriate manner. Thus, several mixers steps are arranged axially next to each other without reversing the flow the direction and the angle of intersection between the axially adjacent darsteg can be varied. As mentioned above, the number of mixer steps in the mixer 20 is also varied according to different desired currents. mixing and blending properties. 7803226-5 Although the mixer segments 34 have been shown with three blades and thus created three screw channels in the conduit 22, it is within the scope of the invention frame to vary the number of blades 38 according to the mixing ratio countries, which it is desired to prevail in the mixer 20. For the most from two to four blades should be sufficient to achieve the desired flow and mixing in the In the embodiment shown in Fig. 1, it has three blades used.

The mixer 20 further comprises a fastening device 44, which in longitudinal section is shown in Fig. 1 and in an end view in Fig. 2. The fitting comprises a fastening part or retaining ring 46 with an outer ring 48, an inner hub 50 and a plurality of rails 52, which extend radially outward from the hub 50 to the ring 48. The rails 52 are preferably of the same number as the number of leaves in the first mixer. segment and suitably aligned with the leading edges of these leaves.

Although the line mixer according to the invention is suitable for mixing liquids flowing through it in either direction are FAST fi n0fdHi fl Qen 44 suitably arranged at the inlet of the mixer, so that the flow in Fig. 1 would be from right to left.

The pipeline 22 includes flanges 54 at both ends for allow the line mixer 20 to be connected to adjacent ends of the cord. The ring 48 is intended to be clamped between the flange 54 and the flange on an adjacent portion of the conduit. Inside of the hub 50 is threaded as well as the end portion 56 of the rod 26. A nut 58 is threaded on the end portion 56 of the rod 26 and the hub 50 on the mounting part 46 to prevent axial movement between them. The opposite the ends of the rod 26 are externally threaded to receive the hold 60, which hold the mixer steps pressed against the fasteners 44 and thus prevent axial movement of the mixer stages within pipeline 22. The fasteners suitably comprise a pair of nuts 62 and 64 and a lock washer 66, which are screwed onto the threads the end portions 68 of the rod 26, to hold the mixer steps fixed pressed against the fasteners 44. In a typical line mixer of it shown type in Fig. 1, the mixer components may be made of a number of different materials, the most important selection criterion sufficient strength and rigidity, and that each particular material rial does not react with the mixed substances. A suitable one material is stainless steel. In addition, the mixer segments 34 are suitable. 7803226-5 designed by casting to further cheapen manufacturing. The diameter of the pipeline 22 generally varies from roughly 5 cm to about 30 cm. Pipeline 22 length generally corresponds to about ten times the diameter of the wire.

The line mixer 20 according to the invention is intended for use at all kinds of flow conditions, ie. laminar and tour- bulent. straight, parallel paths in layers.

In laminar flow, the flow particles move along The order of magnitude of the the speed of sand layers is different. The viscosity of the liquid dominates and prevents any tendency of the flow to reach turbulent terms. holes about noise in all directions, making determination impossible In turbulent flow, the particles flow in the flow of the motion of individual particles.

Reynolds speech for a line mixer at a particular liquid can calculated to determine if the flow is laminar or turbulent.

Reynolds numbers are defined as: R: En E zu R = Reynolds number, V = average speed, d = wire diameter, p = mass density of the liquid, / u = absolute viscosity.

Since Reynolds' numbers are less than 2000, the flow is generally laminar.

Since Reynolds' number in mixer 20 is greater than 2000, the flow in generally turbulent.

The embodiment in Fig. 1 of the line mixer is generally that prefer for laminar flow. In the embodiment of Fig. 1 is adjacent hub angular position and axial position so adjusted, that the distance between the blades in adjacent segments is the smallest possible to achieve the best mixture in laminar flow in liquid through line 22. Distinctive screw channels are present in each mixer stages and no cross-flow is allowed between these channels.

Accordingly, the mixing is effected by rotating the liquid in 78Û3226 ~ 5 channel and by periodically dividing the flow at each new one mixer step. On the other hand, the angular and axial positions of the hubs can be in relation to adjacent hubs are adjusted to accommodate significant play between the leaves in adjacent segments to achieve the best mixing turbulent flow in the liquid through line 22.

Both the angular and the axial displacement can be achieved e.g. by using adjusting screws on each hub and changing However a suitable shape for axial displacement is shown in Fig. 6 and includes utilizes a plurality of spacers 70. the elements can be of any desired axial extent and their relative positions on the rod as mentioned above.

Di:; ans- divided as desired between adjacent hubs in a mixer stage for to create games between adjacent segment sheets. Each remote element 70 is arranged in slidable engagement with the rod 26 and contains grasp directional sensors on the axial ends to maintain a fixed angular relationship between adjacent hubs. Directional donors include committees 72 and 74, which are identical to the the bulkheads 40 and the grooves 42 on the hub 36.

A suitable embodiment is intended to mix turbulent flow conditions as shown in Figs. 7, 7A and 7B. Fig. 7 shows a first mixer stage 80 and a second mixer stage 82. genes 80 and 82 distinguish such mixer steps as shown in Fig. 1.

Blandarste- The first mixer stage 80 comprises two segments 34c and 34d of a similar kind to segment 34 in Fig. 1, both of which include leaves, which are twisted in a first direction. However, the segment 34 and 34d are angularly offset so that they form considerable play 84 between adjacent leaves. Games 84 are particularly noticeable in Fig. 7B, which schematically shows the relative angle position of the seg- ment 34: and 34d. step 80 can be compared with the angular position of the segments 34a and The angular position of segments 34c and 34d in the 34b in the mixer stage immediately upstream of the mixer stage 80 through comparison with Fig. 7A. From Fig. 7A it is clear that nothing angular clearance is present between adjacent segments 34a and 34b.

The size of the games 84 can be adjusted to achieve the best mix.

However, the adjustability of the games 84 is limited by the pitch of the direction sensors 40 and 42. Using the 12 ° directional the sensors in Fig. 3 and Fig. 4, the winches 84 can be adjusted in increments of 12 °. 7803226-5 10 The second mixer stage 82 comprises segments 34 with blades twisted in the opposite direction to those in the mixer stage 80. The segments 34 in the mixing stage 82 is correspondingly angularly offset in the displacement holding together to form play 84 between the leaves. The relatively short screw channels, which are delimited by the mixer steps 80 and 82 thus allow a considerable cross-flow between the channels 80, so that steps 80 and 82 exert a chopping action in the flow. This chopping effect is highly desirable during turbulence. low flow conditions to provide satisfactory mixing ning. It is within the scope of the invention to either increase or decrease the number of segments in steps 80 and 82 depending on the substances, which to be mixed. Of course, the number of turbulents also depends on this or chopping step 80 or 82 in a given mixer also on those substances to be mixed. It is thus obvious that thanks the variability of the possible segment combinations in management 22, the line mixer 20 according to the invention can be built for to provide the best flow conditions for each type of substance, such as to be mixed. Yet another feature of the invention relates to the ease with which the mixer according to the invention can be assembled and disassembled.

For assembly of the mixer according to the invention, the device 44 at the end 56 of the rod 26. This is achieved by screwing the part 58 against the inner part of the hub 50 and the end 56 of the rod 26. A plurality of mixing elements or segments 34 are used. then slidably arranged on the rod 26. If any segment is to be separated from adjacent segments, spacer elements 70 are arranged in sliding contact with the rod 26. Each segment 34 is then arranged in desired angular position and axial position on the rod 26. Since the desired the number of elements has been added to the rod, fasteners are placed 60 at the end 68 of the rod 26 to hold the various elements clamps between the fastening device 60 and the holding device 44. This is accomplished by displacing the lock washer 66 toward it the last element on the rod and by screwing on the nuts 62 and 64 at the end of the rod 26 68. However, it should be noted that the order of the steps described so far may to some extent change race. For example. the mixer elements can be applied to the rod first and the device 44 and the abutment 60 are then supplied. Or also the abutment may first engage the end 68 of the rod 26, before the fastening device 44 is supplied. 7803226-5 ll The rod 26 with mixing elements arranged thereon is then placed in management 22. As previously mentioned, there is enough play between the tips of the blades 38 and the inside of the conduit 22 to allow provide that the entire device is inserted into the conduit 22. Rod 26 with the mixer elements arranged thereon are then fastened in the line 22 to prevent relative axial displacement between mixer devices and this is conveniently accomplished by the fastening device 44 is arranged to abut against one end of the conduit. one and attachment to it. In this case, the fastening device 44 is clamped between the flange 54 on the conduit 22 and the flange on an adjacent one part of the line.

The line mixer according to the invention can further be combined with a device for injecting liquid into the liquid line and for sampling of liquid in the line. A first such device 100 for injection and sampling is similar in structure to the attachment the part 46 in Fig. 1 and is intended to be used as a fastening part as Fig. 1 shows. The device 100 includes a stand such as an outer ring 102. The ring 102 has an outer cylindrical surface 104 and an internal cavity defining an internal cylindrical surface 106, which is intended to be arranged around the central one the shaft 24. A hub 108 is also arranged around the central shaft and attached to one end of the rod 26. A plurality of rails 110 are attach to hub 108 and inside 106 of ring 102. Rails ll0 extends radially outward from the hub 108 and divides the cavity in the ring 102 in a plurality of flow channels. As mentioned in connection with the fastening ring 46 in Fig. 1, these flow channels lie in line with the screw channels in the first mixer stage 28, so that they forms a continuation of the screw channels. In the ring 102 there is a device for placing each flow channel in communication with a point outside the outside 104 of the ring 102. As FIG. 8 and 8A show this connecting link comprises a plurality of openings 112 in the ring 102, which extend radially outward from the inside 106 to the outside 104. a threaded portion 114 for securing a conduit to the opening 112 for the supply or removal of liquid from flow channels The portion of the opening 112 closest to the surface 104 suitably includes na. Conveniently, there is an opening 112 for each flow channel, though a larger or smaller number can be used as desired.

Figs. 9 and 9A show a second embodiment of the device for ,., _ fTj l Q fifl. 6 “_ ...- yjsæaßödt ' "la ;; »- fl ~ ' 7803226-5 12 spraying and sampling according to the invention. The embodiment in Figs. 9 and 9A is identical in each respect to that in Fig. 8 and 8A with the exception that the injection and test device recess 120 in Figs. 9 and 9A further includes a plurality pipe sections 122 extending through each of the openings 112 into the flow channels. Each tube member 122 is suitably soluble attached to the ring 102 by means of a conventional press fit 124, so that the radial position of each pipe section 122 is adjustable. The end of each pipe section extending into the flow channel is closed, preferably by means of a plug 126. However, each tube part 122 an opening 128 next to the part to allow injection and sampling of liquid in a direction parallel to the flow in the channel. For injection of liquid into the flow channel should the opening 128 will generally be provided on the downstream side of the pipe. part 122. For sampling of liquid in the flow channel, the part can 122 is rotated 1800, so that the opening 128 is arranged on the upstream the side of the part 122. The part 122 can also be used as a printing giver.

Figs. 10 and 10A show a third embodiment of the device for injection and sampling of liquid according to the invention. An- the arrangement 130 is identical to the devices shown in Figs. 8 and 9. with the exception that a tubular member 132 extends through each of the openings 112 into each of the flow channels.

As with the embodiment of Fig. 9, the pipe members 132 are releasable attached to the ring 102 by means of the press fit 124, so that it The dial position of each of the pipe members 132 is variable. Emeller- time, the pipe members 132 differ from the pipe members 122 in that end on each pipe section 132, which extends into the flow passage, is open to allow spraying and sampling of liquid in a direction, which is perpendicular to the flow direction in the channel.

The pipe part 132 can also be used as a pressure sensor. It should be that although each of the injection and test devices Figures 8, 9, 10 are shown with identical flow connections. it is within the scope of the invention to utilize each combination nation of the three different flow connections on one and the same ring 102.

It thus appears that the line mixer according to the invention is easily variable for use in either laminar or turbulent 7803226-5 13 flow conditions. This is because the special mixers the elements of the line mixer according to the invention can be combined set and arranged to form many different mixing paths.

By simple use of elements which have more or fewer leaves, In addition, the number of flow channels can be varied in the line mixer. daren. The mixer is relatively simple to build and inexpensive to manufacture. The components of the mixer are easy to assemble and disassemble for cleaning and relocation, which further increases operating economy. Finally, there is a device for liquid injection. and sampling, which is easily compatible with the line mixer for interaction with the mixing process. , fl _..___..._ f, _ fifl f _ W ~ _ ~ _-._ fi wtaaww., _ 'Vf ~

Claims (10)

7803226-5 lä Patent claim Mixer for different flows in a line, in which fixed elements are arranged to form at least two helical flow channels, the line (22) successively containing at least two mixer stages (28, 30, 32) with from one stage to the next step reversed screw direction, characterized in that each mixing step is built up in succession on a central axis (26) in the conduit (22) arranged, mutually equal screw blade elements (34), whose blades (38) with angular displacement adapted to the pitch towards adjacent screw blade elements (34) form relatively smooth, helical partitions between the helical flow channels. Mixer according to claim 1, characterized in that the screw blade elements (34) are rotatable on the shaft (26). Mixer according to Claims 1 to 2, characterized in that the screw blade elements (34) are slidable along the shaft (26). Mixer according to claims 1 - 3, characterized in that the screw blade elements (34) comprise a hub (36). A mixer according to claim 4, characterized in that the hub (36) on the axial end surfaces has radially directed axes (40) and grooves (42) for engaging in adjustable angular positions against adjacent hubs (36). Mixer according to claim 5, characterized in that the device comprises bladeless hubs according to claim 5 as a spacer between the screw blade elements (34). Mixer according to Claims 1 to 6, characterized in that the partitions formed by means of the screw blade elements (34) in each mixer stage comprise a screw angle of 3 to 3 °. Mixer according to one of Claims 1 to 7, characterized in that each flow channel in a mixing stage is divided symmetrically by the adjacent edge of the blade (38) in adjacent mixing stages. Mixer according to one of Claims 1 to 8, characterized in that the shaft (26) can be fastened at one end centrally in a retaining ring (46), against which the screw blade elements (34) of the mixer steps are fixed by means of fastening means (62 , 64, 66, 58) at the ends of the shaft (26), and that the retaining ring (46) is sealingly connectable to the conduit (20). Mixer according to one of Claims 1 to 9, characterized in that the number of screw blade elements (34) in adjacent mixer stages is different. Poon o. Aa zf;