JP2019112853A - Air lift device - Google Patents

Abstract

To improve recovery efficiency of an object to be recovered.SOLUTION: An air lift device 1 comprises: a riser tube 2; an aeration portion 3; an air supply portion supplying compressed air 5; a flange portion 6 provided at an outer periphery of a lower end side opening 2a of the riser tube 2; a separator connected to an upper end side opening of the riser tube 2; and a recovery portion recovering an object to be recovered. In the aeration portion 3, air injecting pipes 15 with a posture along a radial direction from an axial center position of the riser tube 2 are attached to a plurality of positions in a circumferential direction of a peripheral wall of the riser tube 2. Passages 17a, 17b corresponding to the upper limit value of a set particle size range of the object to be recovered are included between air injecting pipes 15 adjacent to a center portion of the riser tube 2 in a circumferential direction. When the air lift device 1 is used, water flow toward the lower end side opening 2a of the riser tube 2 is formed in a gap 23 between a water bottom 13 and the flange portion 6, and the object to be recovered 11 is sucked from the lower end side opening 2a into the riser tube 2 together with the water flow.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an air lift device for recovering an object located at the bottom of the water through a riser pipe to near the water surface and recovering it.

  As one of the pumping pumps, an air lift pump is known that pumps by pumping compressed air into a riser pipe.

  There is also known an apparatus of a type that utilizes a pumping function by an air lift pump in order to raise sediment such as sediment and sludge deposited on the bottom of the water to near the water surface. A bubble jet air lift pump has been conventionally proposed as one of such devices.

  This is configured to include a riser pipe (air lift riser) extending up and down, a conical skirt provided on the bottom of the riser pipe, and a plurality of bubble jet generators provided on the skirt. Each bubble jet generator has a function of causing water mixed with air bubbles to be jetted obliquely inward and downward inside the skirt (see, for example, Patent Document 1).

  The bubble jet type air lift pump having such a configuration generates a swirling flow inside the skirt by the jet flow ejected from each bubble jet generating device, and sediments such as soil and sludge accumulated on the water bottom by this swirling flow are generated. While being rolled up, it can be stirred and mixed with water inside the skirt. Furthermore, inside the skirt, the air bubbles in the center can be coalesced by centrifugal force and can be raised as large bubbles. Therefore, the bubble jet type air lift pump can generate the action of the air lift pump in the riser pipe, and can lift the mixture of sediment and water rolled up as described above through the riser pipe. It is assumed.

JP, 2005-291171, A

  However, the bubble jet type air lift pump disclosed in Patent Document 1 generates a swirling flow inside a skirt provided at the bottom of the riser pipe in order to wind up sediment on the bottom of the water.

  Therefore, even if the bubble jet air lift pump is effective for recovery of sediments such as earth and sand and sludge existing at the bottom of the water, objects of larger particle size, for example, particle diameter of several tens of millimeters to one hundred It is not suitable for the task of recovering objects from the bottom of the water, such as gravels and debris that have a particle size of millimeter or larger.

  That is, when a swirling flow is generated inside the skirt, a centrifugal force acts on an object moving on the swirling flow. At this time, the magnitude of the centrifugal force acting on the object depends on the magnitude of the inertial mass of the object.

  Therefore, even if the particle size is large, such as earth and sand or sludge, the centrifugal force acting in the swirling flow does not increase so much according to the smallness of its inertial mass, so the swirling flow exists It is also easily transported by the flow of water from within the skirt towards the riser pipe.

  On the other hand, objects such as weirs and debris that have a particle size of a few tens of millimeters to a few hundred millimeters or more have a larger inertial mass, and so are in the swirling flow occurring in the skirt In this case, it is easy to move in the outer circumferential direction by receiving a larger centrifugal force. At this time, since the skirt is shaped to expand downward, when an object such as a weir or rubble of the above-described particle diameter moves in the circumferential direction in the skirt, the skirt is inclined downward along the slope of the peripheral wall of the skirt. It will be sent to. For this reason, it is difficult for an object such as soot or rubble of the above-mentioned particle size to reach the riser pipe above the skirt, and hence the phenomenon of being fed upward through the riser pipe is difficult to occur.

  Therefore, the present invention provides an airlift device capable of improving the efficiency of pulling up to near the water surface and recovering an object that is sunk in the bottom of the water and is an object to be recovered in the set particle size range. It is something to try.

  MEANS FOR SOLVING THE PROBLEMS In order to solve the above-mentioned problems, the present invention solves the above problems, a riser pipe, an aeration unit provided near the lower end of the riser pipe, an air supply unit connected to the aeration unit to supply compressed air, A flange portion provided on an outer periphery of a lower end side opening of the riser pipe; a separator connected to the upper end side opening of the riser pipe to separate air from the mixed fluid discharged from the upper end side opening; And a recovery unit for recovering an object to be recovered which is discharged together with water from the separator, and the aeration unit is circumferentially provided on a peripheral wall near the lower end of the riser pipe. The object to be recovered is provided with a plurality of air jet pipes which are arranged at intervals in the direction and one end side in the longitudinal direction is fixed to the peripheral wall of the riser pipe, and between the plurality of air jet pipes Upper limit of particle size range set for Allowance which is set than to the airlift device including the formed constitute a large passage.

  The air aeration unit may have a configuration in which the plurality of air ejection pipes are disposed circumferentially spaced apart on the peripheral wall near the lower end of the riser pipe in a posture extending radially from the axial center position of the riser pipe. Good.

  The air aeration portion is a central portion of the riser pipe, and a portion located inside the projecting end portions of the air ejection pipes, and the air ejection arranged adjacent to the circumferential direction in the vicinity of the outer periphery of the riser pipe The passages may be provided between the tubes.

  The separator may be of cyclone type.

  The separator may have an air outlet, and a bag filter may be connected downstream of the air outlet of the separator.

  The separator may have an air outlet, and the upstream end of the exhaust cylinder may be connected to the air outlet of the separator, and the downstream end of the exhaust cylinder may be oriented toward the water surface. Good.

  According to the air lift device of the present invention, it is possible to improve the efficiency of pulling up to near the water surface and recovering an object that is sunk to the bottom of the water and that is to be recovered in the set particle size range.

It is a schematic side view which shows 1st Embodiment of an air lift apparatus. It is a figure which expands and shows the aeration part in the air lift apparatus of FIG. It is a figure which shows another example of arrangement | positioning of the air ejection pipe | tube in an aeration part. It is a figure which expands and shows the separator in the air lift apparatus of FIG. It is a figure which shows the 1st application example of 1st Embodiment. It is a figure which shows the 2nd application example of 1st Embodiment. It is a schematic side view which shows 2nd Embodiment of an air lift apparatus. It is a schematic side view which shows 3rd Embodiment of an air lift apparatus.

  Hereinafter, the air lift device of the present invention will be described with reference to the drawings.

First Embodiment
FIG. 1 is a partially cut schematic side view showing a first embodiment of the air lift device. FIG. 2 is an enlarged view of the aeration part in the air lift device, and FIG. 2 (a) is a cut side view, and FIG. 2 (b) is a view on arrow AA in FIG. 2 (a). . FIGS. 3 (a) and 3 (b) are views corresponding to FIG. 2 (b) showing another configuration example of the aeration unit. FIG. 4 is a cutaway side view showing the separation part in the air lift device in an enlarged manner.

  The air lift device of the present embodiment is shown by reference numeral 1 in FIG. 1, and is connected to the riser pipe 2, the aeration unit 3 provided near the lower end of the riser pipe 2, and the aeration unit 3, It is connected to the air supply part 4 which supplies the compressed air 5 to the part 3, the flange part 6 provided on the outer periphery of the lower end side opening 2a of the riser pipe 2, and the upper end side opening 2b of the riser pipe 2 A separator 8 for separating the air 5a from the mixed fluid 7 discharged from 2b, and an object to be recovered 11 provided downstream of the outlet 9 of the separator 8 and discharged together with the water 10 from the outlet 9 of the separator 8 And a recovery unit 12 configured to recover the

  The upper end side opening 2b of the riser pipe 2 is positioned above the water surface 14 by a set dimension when the lower end side opening 2a is disposed near the water bottom 13 where the object 11 to be recovered is sunk. Thus, the vertical dimension of the riser pipe 2 is set.

  For example, when the air lift device 1 of the present embodiment is used for recovering the object 11 to be recovered from the water bottom 13 whose water depth is about several meters to several tens of meters, the vertical dimension of the riser pipe 2 is a target. The water depth of the work area is set to a size obtained by adding an additional dimension set to about 1 meter to 2 meters. Of course, this additional dimension may be changed as appropriate in consideration of the type and size of the separator 8 and the like.

  In the present embodiment, the riser pipe 2 is a pipe having a circular cross-sectional shape as shown in FIG. 2 (b). Further, in the present embodiment, as shown in FIG. 1, the riser pipe 2 is a pipe having a constant diameter (inner diameter) over the entire length.

  By the way, in the air lift device 1 of the present embodiment, the particle size range of the object to be recovered 11 which is desired to be recovered is set from the lower limit value X to the upper limit value Y. The lower limit value X is set, for example, to several tens of millimeters, and the upper limit value Y is set, for example, to about one hundred millimeters. The numerical values of the lower limit value X and the upper limit value Y are merely examples, and it goes without saying that one or both of them may be set to different numerical values. Therefore, the upper limit value Y may be a set value larger than one hundred millimeters. For convenience of explanation, the particle size range set for the recovery target object 11 desired to be recovered is hereinafter simply referred to as the particle size range.

  By the way, the air lift apparatus 1 of this embodiment pulls up the collection | recovery object object 11 from water bottom to near water surface using the effect | action of the air lift pump which arises in riser pipe 2 so that it may mention later. Therefore, the particle diameter of the recoverable object 11 that can be recovered is limited in relation to the cross-sectional shape and cross-sectional area of the flow path of the riser pipe 2 and the density and shape of the object 11 to be recovered. Therefore, the upper limit value Y of the particle size range may be set by finding conditions that can be recovered by a preliminary test or numerical calculation. According to the test model of the air lift device 1 of the present embodiment, the inventor of the present invention is an object such as rubble having a particle diameter of about 100 mm under the condition that the inner diameter of the riser pipe 2 is about 200 mm and the lift is several meters. It has been confirmed that it is possible to pull up through the riser pipe 2.

  The riser pipe 2 is required to have a function of passing the object to be recovered 11 having a particle diameter of the upper limit value Y of the particle diameter range from the lower end side opening 2a to the upper end side opening 2b. From this point of view, the inner diameter of the riser pipe 2 is preferably at least twice the size of the upper limit value Y of the particle diameter range. In addition, this condition is a preferable setting example of the inner diameter of the riser pipe 2, and the inner diameter of the riser pipe 2 is not limited to a size twice or more of the upper limit value Y of the particle size range.

  Furthermore, in the present embodiment, as shown in FIG. 1, the upper end side of the riser pipe 2 is bent in the lateral direction, and the upper end side opening 2 b is in the lateral direction. In the riser pipe 2, in order to guide the mixed fluid 7 flowing in the riser pipe 2 to the upper end side opening 2 b more reliably, the laterally bent portion on the upper end side extends horizontally or the upper end side It is preferable to be configured to be slightly inclined downward toward the opening 2 b.

  In addition, the riser pipe 2 is not limited to the structure by which the laterally bent part in an upper end side becomes a horizontal direction or inclines a little downward toward the upper end side opening 2b. Furthermore, if the upper end side opening 2b can be connected to the separator 8, the riser pipe 2 has a shape other than the illustrated shape, for example, a shape in which the upper end side is curved with a larger curvature and the upper end side opening 2b becomes horizontal. Of course it is good.

  As shown in FIGS. 2 (a) and 2 (b), the aeration unit 3 is provided with a plurality of air ejection pipes 15 provided at circumferentially spaced intervals on the peripheral wall near the lower end of the riser pipe 2, and air supply A header 16 is provided to disperse and supply the compressed air 5 supplied from the unit 4 to the air jet pipes 15.

  Each air ejection pipe | tube 15 is made into the attitude | position which follows the radial direction centering on the axial center position O of the riser pipe | tube 2 as shown in FIG.2 (b). Each air jet pipe 15 is attached to the peripheral wall of the riser pipe 2 so as to penetrate in the inside and outside directions, with one end side in the longitudinal direction positioned on the outer peripheral side. Therefore, one end side in the longitudinal direction of each air jet pipe 15 is fixed to the peripheral wall of the riser pipe 2, and cantilever support is performed in which the other end side in the longitudinal direction becomes a free end.

  Furthermore, the aeration unit 3 is set such that the longitudinal dimension and the circumferential arrangement of each air ejection tube 15 satisfy the following two conditions.

  The first condition is that the upper end value Y of the particle size range is located inside the other end portions of the respective air ejection pipes 15 disposed so as to protrude in the axial center direction of the riser pipe 2 at the central portion of the riser pipe 2 It is a condition that a passage 17a is formed as indicated by a dot-and-dash line having a large diameter by the set margin.

  The second condition is a passage indicated by a two-dot chain line having the same diameter as the passage 17a between the air ejection tubes 15 disposed adjacent to each other in the circumferential direction near the outer periphery of the riser pipe 2 The condition is that 17b is formed.

  By satisfying these two conditions, in the aeration unit 3, the collection target object 11 having a particle diameter equal to or less than the upper limit value Y of the particle diameter range can easily pass the aeration unit 3 through the passage 17a and the passage 17b. Can. Therefore, in the air lift device 1 of the present embodiment, the recovery target object 11 having a particle diameter equal to or less than the upper limit value Y of the particle diameter range is allowed to pass through the aeration portion 3 upward and enter into the riser pipe 2 Can.

  On the other hand, in the aeration unit 3, an object having a particle diameter larger than the upper limit value Y of the particle diameter range is inhibited from passing through the passage 17a or the passage 17b due to the presence of each air jet pipe 15. Therefore, the air lift device 1 of the present embodiment can suppress an object having a particle diameter larger than the upper limit value Y of the particle diameter range from entering the riser pipe 2 through the aeration portion 3.

  Therefore, in the air lift device 1 of the present embodiment, each air ejection pipe 15 of the aeration unit 3 functions as a screen for selectively allowing the object 11 to be recovered to approach the riser pipe 2.

  FIG. 2 (b) shows the aeration section 3 satisfying the first and second conditions described above for the case where the ratio of the inner diameter of the riser pipe 2 to the upper limit value Y of the particle size range is about 4 to 1. Shows a configuration example of

  In the present configuration example, the air ejection pipes 15 are provided on the circumferential wall of the riser pipe 2 at eight points at intervals of 45 degrees in the circumferential direction.

  Thus, the passages 17 b are formed at eight circumferential locations between the air jet tubes 15 adjacent to each other in the circumferential direction, in the vicinity of the outer periphery of the riser tube 2.

  Among the air ejection pipes 15, the four air ejection pipes 15 arranged at intervals of 90 degrees in the circumferential direction, which are up and down and left and right in the figure, have length dimensions such that the other end in the longitudinal direction approaches the passage 17a. It is set.

  The length dimension of the remaining four air jet pipes 15 is set to about half of that of the four air jet pipes 15.

  The aeration part 3 of this configuration example is provided with the air ejection pipes 15 having different length dimensions, alternately in the circumferential direction, so that it is closer to the inner periphery than the other end of the short air ejection pipe 15 in the longitudinal direction and circumferentially A passage 17c shown by a two-dot chain line having the same diameter as the passage 17b is further formed at a position between the long air jet tubes 15 arranged adjacent to each other in the direction.

  Therefore, the aeration unit 3 of the present configuration example includes the passage 17c in addition to the passage 17a and the passage 17b, so the aeration target object 11 having a particle diameter equal to or less than the upper limit value Y of the particle diameter range is aerated. The portion 3 can be passed smoothly from below to the riser pipe 2 more smoothly.

  In the configuration similar to that of FIG. 2 (b), the aeration unit 3 is replaced with the configuration having four short air ejection pipes 15, and all eight air ejection pipes 15 have the other end in the longitudinal direction. It is good also as composition set up in the length dimension which a part approaches passage 17a. In the aeration unit 3 of this configuration, the passage 17c is not formed, but the passage 17a and the passage 17b are formed, so it is apparent that the screen function by each air ejection pipe 15 of the aeration unit 3 described above can be obtained is there.

  Further, FIG. 2 (b) shows a configuration example of the aeration part 3 in the case where the ratio of the inner diameter of the riser pipe 2 to the upper limit value Y of the particle size range is about 4: 1. For example, in the case of about 8 to 3 and in the case of about 2 to 1 of the ratio of the inner diameter of the particle diameter to the upper limit value Y of the particle diameter range, the configuration examples shown in FIG. do it. In FIGS. 3 (a) and 3 (b), the same components as in FIG. 2 (b) are assigned the same reference numerals.

  FIG. 3 (a) shows the air diffuser 3 satisfying the first and second conditions described above for the case where the ratio of the inner diameter of the riser pipe 2 to the upper limit value Y of the particle size range is about 8 to 3. Shows a configuration example of Therefore, in FIG. 3A, the relative dimensions of the passage 17a and the passage 17b with respect to the riser pipe 2 set corresponding to the upper limit value Y of the particle size range are different from those in FIG. 2B. .

  In the present configuration example, the air ejection pipes 15 are provided on the circumferential wall of the riser pipe 2 at four points at intervals of 90 degrees in the circumferential direction. Each air jet pipe 15 is set to have a length dimension in which the other end in the longitudinal direction is in proximity to the passage 17 a as indicated by a dot-and-dash line set at the center of the riser pipe 2.

  Thus, in the circumferential direction around the outer periphery of the riser pipe 2, passages 17 b indicated by two-dot chain lines are formed at four places in the circumferential direction between the air jet pipes 15 arranged adjacent to each other in the circumferential direction.

  FIG. 3 (b) shows the aeration section 3 satisfying the first and second conditions described above when the ratio of the inner diameter of the riser pipe 2 to the upper limit value Y of the particle size range is about 2 to 1. Shows a configuration example of Therefore, in FIG. 3B, the relative dimensions of the passage 17a and the passage 17b with respect to the riser pipe 2 set corresponding to the upper limit value Y of the particle diameter range are different from those in FIG. 2B. .

  In the present configuration example, the air ejection pipes 15 are provided on the circumferential wall of the riser pipe 2 at three points at intervals of 120 degrees in the circumferential direction. Each air jet pipe 15 is set to have a length dimension in which the other end in the longitudinal direction is in proximity to the passage 17 a as indicated by a dot-and-dash line set at the center of the riser pipe 2.

  As a result, a passage 17 b as shown by a two-dot chain line is formed between the air jet pipes 15 adjacent to each other in the circumferential direction in the vicinity of the outer periphery of the riser pipe 2.

  The screen function by each air jet pipe 15 can be obtained also by the aeration unit 3 of each configuration example of FIG. 3A and FIG. 3B.

  Each air ejection pipe 15 is closed at the other end, and as shown in FIG. 2A, the air nozzles 18 face downward at a plurality of locations in the longitudinal direction of each air ejection pipe 15. It is provided.

  The header 16 is disposed on the outer peripheral surface of the riser pipe 2 so as to cover a longitudinal end of each air ejection pipe 15 in a bowl-like member extending along the outer peripheral surface of the riser pipe 2 over the entire circumferential direction. It is supposed to be attached.

  The header 16 is provided with an air inlet 19 at one point in the circumferential direction.

  The air supply unit 4 includes an air line 20 having one end connected to the air inlet 19 of the header 16 and a supply source 21 of the compressed air 5 connected to the other end of the air line 20. . A compressor or a compressed air tank may be used as the supply source 21.

  Furthermore, the air line 20 is configured to include a solenoid valve 22 that can be opened and closed by remote control. In addition, what is necessary is just to make the riser pipe 2 hold | maintain the air line 20 in the riser pipe 2 via the holding tool which is not shown in figure at the time of use of the air lift apparatus 1 of this embodiment.

  Thus, when the solenoid valve 22 is opened, the air supply unit 4 supplies the compressed air 5 guided from the supply source 21 through the air line 20 to the air inlet 19 of the header 16 in the aeration unit 3. it can.

  The compressed air 5 supplied to the header 16 is dispersed in the circumferential direction in the header 16 and then flows into each air jet pipe 15 from one end. Therefore, in the aeration unit 3, the compressed air 5 is jetted downward from the air nozzles 18 of the air jet tubes 15.

  At this time, as shown in FIG. 1, if the lower end side opening 2a of the riser pipe 2 is disposed in the vicinity of the water bottom 13, the air is jetted downward from the air nozzle 18 of each air jet pipe 15. The compressed air 5 generates air bubbles. Since the air bubbles rise in the riser pipe 2 in which the air jet pipes 15 are disposed, the rise of the air bubbles causes the action of the air lift pump in the riser pipe 2.

  Therefore, in the riser pipe 2, suction of the water 10 from the lower end side opening 2a is started. Therefore, when the object to be recovered 11 present in the vicinity of the lower end side opening 2a of the riser pipe 2 gets on the flow of water 10 sucked from the lower end side opening 2a of the riser pipe 2, from the lower end side opening 2a, As described above, it passes between the air jet pipes 15 of the aeration unit 3 and is sucked into the riser pipe 2. Therefore, in the riser pipe 2, a phenomenon occurs in which the mixed fluid 7 including the water 10 sucked from the lower end opening 2a, the air bubble, and the object to be recovered 11 is sent toward the upper end opening 2b.

  On the other hand, the air supply unit 4 stops the supply of the compressed air 5 to the aeration unit 3 when the solenoid valve 22 is closed.

  Thereby, in the aeration unit 3, the ejection of the compressed air 5 from the air nozzle 18 of each air ejection pipe 15 is stopped, so the generation of air bubbles is stopped. Therefore, in the riser pipe 2, since the rise of air bubbles is not performed, the action of the air lift pump is stopped.

  The flange portion 6 is an annular plate attached to the outer peripheral surface on the lower end side of the riser pipe 2 as shown in FIG. 2A, and spreads with a dimension set on the outer peripheral side centering on the lower end side opening 2a. It is configured to have a downward surface. In the present embodiment, the bottom plate of the header 16 is configured to double as the flange portion 6.

  Note that the downward surface of the flange portion 6 is in the direction orthogonal to the axial center direction of the riser pipe 2 as shown in FIG. It is preferable to use a flat surface. In addition, the downward surface of the flange portion 6 is a surface (frustum surface) vertically inclined within an angle range of 30 degrees or less from the direction orthogonal to the axial center direction of the riser pipe 2 from the center side to the outer peripheral side It may be Furthermore, the downward surface of the flange portion 6 may be provided with asperities such as, for example, circumferentially arrayed concave portions extending in the radial direction centering on the lower end side opening 2a.

  Thereby, in the air lift device 1 of the present embodiment, when the lower end side opening 2a of the riser pipe 2 is disposed in the vicinity of the water bottom 13, the flange portion 6 and a portion of the water bottom 13 located below the flange portion 6 A gap 23 can be formed between the lower end side opening 2 a of the riser pipe 2 and the outer periphery along the water bottom 13.

  When the suction of the water 10 from the lower end side opening 2a of the riser pipe 2 as described above is performed in the state where the gap 23 is formed, the water 23 along the water bottom 13 goes from the outer peripheral side to the central side Flow is formed.

  Here, as a comparative example to the present embodiment, a configuration will be considered in which the riser pipe 2 similar to the present embodiment does not have a flange portion on the outer periphery of the lower end side opening 2a. In this configuration, when the water 10 is suctioned from the lower end side opening 2a of the riser pipe 2, the water 10 is supplied from above as well as the outer peripheral side to a position near the outer peripheral side of the lower end side opening 2a. For this reason, the flow of the water 10 in the direction along the water bottom 13 generated around the lower end side opening 2a is not so strong, and the generation region is also limited to the vicinity of the lower end side opening 2a.

  On the other hand, since the riser pipe 2 in this embodiment is provided with the flange part 6, water 10 does not flow in from the upper part with respect to the outer peripheral side vicinity position of the lower end side opening 2a. Therefore, in the gap 23 between the flange portion 6 and the water bottom 13, when the water 10 is sucked from the lower end side opening 2a of the riser pipe 2, the flow of the water 10 toward the lower end side opening 2a along the water bottom 13 Can be generated as a strong flow compared to

  For this reason, the air lift device 1 of the present embodiment, when the water 10 is sucked from the lower end opening 2a of the riser pipe 2, the recovery target object 11 sunk in the water bottom 13 along the water bottom 13 to the lower end opening 2a. It can be moved to the lower end side opening 2a by the flow of the strong water 10 which goes, and therefore, the efficiency of sucking the collection object 11 into the riser pipe 2 from the lower end side opening 2a can be improved.

  The separator 8 is a cyclone type separator 8 in this embodiment.

  As shown in FIG. 4, the separator 8 penetrates the central portion of the cylindrical wall 24 extending vertically, the ceiling wall 25 closing the upper end side of the outer cylinder 24, and the central portion of the ceiling wall 25. An inner cylinder 26 concentrically disposed at the center of the cylinder 24 is provided.

  The outer cylinder 24 has an opening at one circumferential position on the upper end side, and the upper end side opening 2 b of the riser pipe 2 is communicably connected to this opening from the direction along the tangent of the outer cylinder 24. In FIG. 4, the structure of the connection part of the upper end side opening 2b of the riser pipe 2 with respect to the outer cylinder 24 is simplified and shown for convenience of illustration.

  In the separator 8, the opening on the lower end side of the outer cylinder 24 is an outlet 9 of the water 10 containing the object to be recovered 11, and the opening on the upper end side of the inner cylinder 26 is an air outlet 27.

  Thereby, in the separator 8, when the mixed fluid 7 including the water 10, the air bubbles and the object 11 to be recovered which is guided through the riser pipe 2 and discharged from the upper end side opening 2 b flows into the outer cylinder 24, the outer cylinder A swirling flow of the fluid mixture 7 is formed along the inner peripheral surface of the surface 24.

  In the swirling flow of the mixed fluid 7, the bubbles contained in the mixed fluid 7 are collected at the axial center position of the outer cylinder 24 according to the density difference with the water 10 and the collection target object 11, and the collection target object It is efficiently separated from the water 10 containing 11. Thereafter, the water 10 containing the object to be recovered 11 is discharged downward through the outlet 9 by its own weight. On the other hand, the air bubbles collected at the axial center position of the outer cylinder 24 combine to form a solid of air 5a and enter the inner cylinder 26 from the lower end side and are discharged from the air outlet 27 at the upper end side of the inner cylinder 26 .

  In the present embodiment, the separator 8 arranges the lower end side opening 2a of the riser pipe 2 in the vicinity of the water bottom 13 where the object 11 to be recovered is sunk as shown in FIG. In the use state, the vertical dimension of the outer cylinder 24 is set such that the portion near the lower end of the outer cylinder 24 is submerged and the outlet 9 is disposed below the water surface.

  The reason why the outlet 9 of the separator 8 is disposed in the water when the air lift device 1 of this embodiment is used as described above is as follows.

  That is, the mixed fluid 7 flowing into the separator 8 from the upper end side opening 2 b of the riser pipe 2 contains fine solids such as sand and sludge that have sunk in the water bottom 13 like the object 11 to be recovered. Have In addition, when the water 10 containing the object 11 to be collected falls to the water surface 14, splashes occur. Thus, the droplets may contain fine solids that have sunk in the bottom of the water 13.

  Therefore, by arranging the outlet 9 in the water, the separator 8 in the present embodiment scatters into the surrounding environment in a state in which the fine solid substance sunk in the water bottom 13 is included in the spray, or the spray itself is It is possible to suppress scattering to the surrounding environment.

  The air outlet 27 of the separator 8 is preferably connected to the upstream end of an exhaust cylinder 28 whose downstream end is disposed in a posture facing the water surface 14 as shown in FIG. 1. According to this configuration, the air 5 a discharged from the air outlet 27 of the separator 8 is discharged from the downstream end of the exhaust cylinder 28 as a flow toward the water surface 14 after passing through the exhaust cylinder 28. Therefore, in the configuration provided with the exhaust cylinder 28, the air 5a discharged from the air outlet 27 of the separator 8 includes droplets generated in the outer cylinder 24 and the fine solid matter sunk in the water bottom 13 as described above. Even if the droplets containing these are entrained, they can be sprayed on the surface of the water 14 on the flow of the air 5a. Thus, according to the configuration provided with the exhaust cylinder 28, the droplets themselves contained in the air 5 a discharged from the air outlet 27 of the separator 8 and the fine solids contained in the droplets are trapped at the water surface 14. It is possible to reduce the emission to the surrounding environment.

  In the present embodiment, the recovery unit 12 is a bowl-like container having an opening 29 on the upper end side and a side and a bottom portion formed of a member having a hole such as a wire mesh or a perforated plate. The holes provided in the side part and the bottom part are set such that the opening area and the opening shape of each hole can not pass through the object 11 to be collected which is the lower limit value X of the particle size range. In addition, only one of the side part and the bottom part of the recovery unit 12 may be a member having a hole through which the water 10 passes.

  Further, the recovery unit 12 has an opening 29 on the upper end side set to a size surrounding the outlet 9 of the separator 8, and a float 30 is attached to the outer periphery of the opening 29. Thereby, as shown in FIG. 1, the recovery unit 12 can be disposed in the vicinity of the water surface 14 by the buoyancy of the float 30 in a state where the opening 29 is disposed so as to surround the outlet 9 of the separator 8 It is.

  In this state, the recovery unit 12 can receive the water 10 including the recovery target object 11 discharged from the outlet 9 of the separator 8 inside the recovery unit 12. Furthermore, the recovery unit 12 can discharge the water 10 to the outside through the holes provided in the side and the bottom, and can carry the flow of the water 10 through the holes provided in the side and the bottom so that the particle size range It is possible to discharge an object which is not a collection target smaller than the lower limit value X of.

  Therefore, the recovery unit 12 can selectively collect the recovery target object 11 from the water 10 including the recovery target object 11 discharged from the outlet 9 of the separator 8.

  The air lift device 1 of this embodiment is lifted by a transport device such as an overhead crane or another type of crane to change the position at the time of use and the position at which the recovery target object 11 in the water bottom 13 is collected. It is preferable to provide the hanging part 31 in the location located in the upper end side of the whole apparatus so that it can do. Although FIG. 1 exemplifies a configuration in which the hanging portion 31 is provided on the upper end side of the riser pipe 2 and the upper end side of the exhaust cylinder 28, the arrangement and the number of the portions having the hanging portion 31 are of course not limited thereto. It is.

  In the case of using the air lift device 1 according to the present embodiment having the above configuration, the air lift according to the present embodiment is arranged such that the lower end side opening 2a of the riser pipe 2 is disposed near the water bottom 13 where the object 11 to be recovered is sunk. Positioning of device 1 is performed. At this time, the recovery unit 12 is disposed at a position corresponding to the outlet 9 of the separator 8.

  Further, the air supply unit 4 starts supply of the compressed air 5 from the supply source 21 to the air line 20 in a state where the electromagnetic valve 22 is closed.

  Next, the air lift device 1 of the present embodiment opens the electromagnetic valve 22 of the air supply unit 4 when actually starting the recovery operation of the recovery target object 11.

  Thus, the air supply unit 4 starts the supply of the compressed air 5 to the aeration unit 3.

  Therefore, in the aeration unit 3, the compressed air 5 is jetted downward from each air nozzle 18 of each air jet pipe 15, and a bubble is generated by the jetted compressed air 5.

  The air bubbles generated in the aeration unit 3 rise in the riser pipe 2, so the action of the air lift pump occurs in the riser pipe 2.

  Therefore, in the riser pipe 2, since suction of the water 10 from the lower end opening 2 a is started, the particle diameter from the lower limit X to the upper limit Y of the particle size range existing in the vicinity of the lower end opening 2 a is The to-be-collected object 11 to be collected passes between the air jet pipes 15 of the aeration unit 3 and is sucked into the riser pipe 2.

  Therefore, in the riser pipe 2, the mixed fluid 7 including the water 10, the air bubbles, and the object to be recovered 11 is sent toward the upper end side opening 2 b disposed above the water surface 14.

  The mixed fluid 7 sent to the upper end side opening 2 b of the riser pipe 2 is separated from the air 5 a forming bubbles in the separator 8, and then the water 10 and the object to be recovered 11 are collected from the outlet 9. Sent to

  In the recovery unit 12, the water 10 and an object not to be recovered smaller than the lower limit value X of the particle size range are discharged to the outside through the holes provided in the side and the bottom. Therefore, the air lift device 1 of the present embodiment can collect the collection target object 11 having the particle size from the lower limit value X to the upper limit value Y of the particle size range in the collection unit 12.

  Thereafter, the air lift device 1 of the present embodiment moves the position of the lower end side opening 2a of the riser pipe 2 to a position where a new recovery target object 11 is sunk in the vicinity of the water bottom 13 as necessary. The work of pulling up the target object 11 from the water bottom 13 and collecting it in the recovery unit 12 may be continued.

  The air lift device 1 of the present embodiment operates to close the solenoid valve 22 of the air supply unit 4 when stopping or ending the recovery operation of the recovery target object 11.

  After that, in the air lift device 1 of the present embodiment, the object to be recovered 11 repaired by the recovery unit 12 may be withdrawn from the water surface 14 together with the recovery unit 12 and recovered. Along with the withdrawal of the recovery unit 12 from the water surface 14, the recovery target object 11 collected by the recovery unit 12 is recovered in a state where the water 10 is cut.

  As described above, according to the air lift device 1 of the present embodiment, the particle diameter in the set particle diameter range, for example, from the lower limit X set to several tens of millimeters to the upper limit Y set to about 100 millimeters The to-be-recovered object 11 having a particle diameter of 10% can be withdrawn from the bottom 13 and recovered.

  Furthermore, in the air lift device 1 of the present embodiment, the flow of the water 10 toward the lower end side opening 2 a along the water bottom 13 is generated at the gap 23 between the flange portion 6 provided near the lower end of the riser pipe 2 and the water bottom 13. Can. For this reason, the air lift device 1 of the present embodiment can move the recovery target object 11 sunk in the water bottom 13 to the lower end side opening 2a on the flow of the water 10, and the riser from the lower end side opening 2a The efficiency with which the object to be recovered 11 is sucked into the pipe 2 can be improved.

  Moreover, the air lift device 1 of the present embodiment does not generate the swirling flow as generated in the device disclosed in Patent Document 1 on the lower end side of the riser pipe 2.

  Therefore, the air lift device 1 of the present embodiment can improve the efficiency of pulling up the collection target object 11 sunk in the water bottom 13 to the vicinity of the water surface 14 and collecting it.

  Furthermore, in the air lift device 1 of the present embodiment, each air ejection pipe 15 in the aeration unit 3 suppresses that an object having a particle diameter larger than the upper limit value Y of the set particle diameter range is drawn into the riser pipe 2 Also functions as a screen. Therefore, air lift device 1 of this embodiment can prevent clogging of riser pipe 2 by the object of unexpected particle diameter.

  In the air lift device 1 of the present embodiment, the shape and the particles of the object 11 to be collected sucked into the riser pipe 2 as each air jet pipe 15 of the aeration unit 3 has the function as the screen as described above. Depending on the diameter, it may be considered that the air jet pipe 15 is somewhat caught.

  However, the air lift device 1 of the present embodiment has a configuration in which each air ejection pipe 15 is supported in a cantilever manner, and the end portion of each air ejection pipe 15 arranged near the axial center of the riser pipe 2 becomes a free end. There is. Therefore, in each air ejection pipe 15, if the object to be collected 11 slides along the air ejection pipe 15 to the free end side and passes by the free end, the catching of the object 11 to be collected with the air ejection pipe 15 is easily eliminated. Be done. Furthermore, when the force received from the object 11 to be collected becomes large, each air ejection pipe 15 can generate a deflection in which the free end side is displaced.

  Therefore, in the air lift device 1 of the present embodiment, even if the recovery target object 11 sucked into the riser pipe 2 is caught on the air ejection pipe 15, the recovery target object 11 is along the air ejection pipe 15 and the free end By moving in the direction or by bending the air ejection tube 15, it is possible to release the catching of the object 11 to be collected.

  Each air jet pipe 15 jets compressed air 5 downward from each air nozzle 18 provided at a plurality of locations in the longitudinal direction. Therefore, when the object to be recovered 11 sucked from the lower end side opening 2 a of the riser pipe 2 approaches the air jet pipe 15 from below, the object 11 to be recovered is compressed by the compressed air 5 jetted from each air nozzle 18 The impetus to hit the air jet pipe 15 can be reduced. Thus, the air lift device 1 of the present embodiment can suppress damage to the air jet pipe 15 caused by the recovery target object 11 sucked into the riser pipe 2 hitting the air jet pipe 15.

First Application Example of First Embodiment
FIG. 5 shows a first application example of the first embodiment, and FIG. 5 (a) is a cutaway side view of a portion near the lower end of a riser pipe provided with a flange portion of another configuration example, FIG. ) Is a cutaway side view of a portion near the lower end of a riser pipe with a flange portion of yet another configuration example.

  5 (a) and 5 (b), the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted.

  In the first embodiment, the bottom plate of the header 16 is configured to double as the flange portion 6, but the flange portion may be configured as shown in FIG. 5 (a) or as shown in FIG. 5 (b).

  In the configuration shown in FIG. 5A, an annular plate member 32 projecting to the outer peripheral side is attached to a position near the lower end of the outer peripheral surface of the header 16 having the same configuration as the first embodiment. A combination of 32 and the bottom plate of the header 16 forms a flange 6a.

  The header 16 supplies the compressed air 5 supplied from the air supply unit 4 (see FIG. 1) to each of the air ejection pipes 15 in a distributed manner, and is necessary to obtain the distributed supply function of the compressed air 5. The dimensions to be determined are determined. Therefore, providing the header 16 excessively larger than the required size leads to an increase in the material and cost required for manufacturing the header 16.

  On the other hand, in the flange portion 6 a shown in FIG. 5A, the diameter dimension of the flange portion 6 a can be easily enlarged without enlarging the header 16.

  The flange portion 6 b shown in FIG. 5B is configured such that an annular plate member separate from the header 16 is attached to the outer peripheral surface of the riser pipe 2 at a position near the lower end.

  In the configuration employing this flange portion 6b, the header 16 is not related to the formation of the flange portion 6b. Therefore, if the header 16 can distribute and supply the compressed air 5 supplied from the air supply unit 4 to one end portion of each air ejection pipe 15 attached to the riser pipe 2, a bowl-like member is used. Any configuration other than the configuration attached to the outer peripheral surface of the riser pipe 2 may be adopted.

  Therefore, when the flange portion 6 b of FIG. 5B is adopted, it is possible to increase the degree of freedom of the shape and the configuration of the header 16.

Second Application Example of First Embodiment
FIG. 6 shows a second application example of the first embodiment, and FIG. 6 (a) is a cutaway plan view showing another configuration example of the aeration part, and FIG. 6 (b) is a view shown in FIG. It is a BB directional arrow view of.

  6 (a) and 6 (b), the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted.

  Here, the case of enlarging the diameter of the riser pipe 2 is considered. In the case of enlarging the diameter of the riser pipe 2, it is necessary to increase the amount of compressed air 5 to be ejected from the aeration unit 3.

  In the said 1st Embodiment, the aeration part 3 showed the structure provided with the air nozzle 18 in each air ejection pipe | tube 15. As shown in FIG. Therefore, in order to increase the amount of the compressed air 5 ejected from the air nozzle 18 provided in each air ejection pipe 15 in the aeration unit 3 in the first embodiment, the diameter of each air ejection pipe 15 is increased. You will need to

  By the way, each air ejection pipe 15 of the aeration unit 3 also has a function as a screen for selectively allowing the object to be collected 11 (see FIG. 1) to enter the riser pipe 2. From the viewpoint of the function as the screen, the thickening of the air jet pipes 15 leads to the narrowing of the passages 17a, 17b and 17c through which the object 11 to be collected passes. Furthermore, the bending of the air jet pipe 15 makes it difficult to obtain the function of releasing the object 11 to be recovered from as the air jet pipe 15 becomes thicker.

  Therefore, as shown in FIGS. 6 (a) and 6 (b), the aeration unit 3 in the present application example has air in the side wall of the riser pipe 2 in addition to the same configuration as the aeration unit 3 in the first embodiment. A nozzle 18 a is provided, and the air nozzle 18 a is connected in communication with the header 16.

  FIG. 6A shows, as an example, a configuration in which the air nozzle 18a is provided at each position between the air jet pipes 15 adjacent in the circumferential direction. The air nozzle 18 a is a riser pipe according to the difference between the amount of compressed air 5 desired to be jetted in the riser pipe 2 and the amount of compressed air 5 jettable from the air nozzle 18 of each air jet pipe 15. Of course, the number and arrangement of the air nozzles 18a provided on the side wall of 2 may be set other than that illustrated.

  When adopting the aeration unit 3 in the present application having the above configuration, in addition to the air nozzle 18 of each air ejection pipe 15, the compressed air 5 is also ejected from the air nozzle 18a of the side wall of the riser pipe 2. Can. Therefore, the aeration unit 3 of this application example can increase the ejection amount of the compressed air 5 while suppressing an increase in the thickness of each air ejection tube 15. Therefore, the aeration part 3 of this application example can be made into the aeration part 3 suitable when expanding the diameter of the riser pipe 2.

  Of course, the aeration unit 3 in this application example may be applied to the first application example of the first embodiment shown in FIGS. 5 (a) and 5 (b).

Second Embodiment
FIG. 7 is a schematic side view showing a second embodiment of the air lift device.

  In FIG. 7, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted.

  The air lift device 1 of this embodiment has the same configuration as that of the first embodiment except that the air exhaust 27 is connected to the downstream side of the air outlet 27 of the separator 8 instead of the air outlet 27 of the separator 8 ( The bag filter 33 is connected to the downstream side of FIG. 4).

  An attraction fan 34 is connected to the downstream side of the exhaust port of the bag filter 33.

  The air lift device 1 according to the present embodiment having the above-described configuration conducts dust collection processing by guiding the air 5a discharged from the air outlet 27 of the separator 8 to the bag filter 33 by the operation of the induction fan 34. it can.

  Therefore, even if the air 5a discharged from the air outlet 27 of the separator 8 contains droplets generated in the outer cylinder 24 and the droplets contain fine solid matter sunk in the water bottom 13, the fine particles Solid substances are collected by the bag filter 33.

  Therefore, the air lift device 1 of the present embodiment, when the fine solid substance sunk in the water bottom 13 contains environmental pollutants such as radioactive substances and chemical substances to be prevented from being released into the environment, the environmental pollutants Can be more reliably prevented from being dissipated to the surrounding environment.

  Of course, any one or both of the first application example and the second application example of the first embodiment may be applied to the air lift device 1 of the present embodiment.

Third Embodiment
FIG. 8 is a cut side view showing another example of a separator as a third embodiment of the air lift device.

  In addition, the structure of the air lift apparatus 1 of this embodiment is the same as that of 1st Embodiment shown to FIGS. 1-3 (a) (b) except a separator. Further, in FIG. 8, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted.

  As shown in FIG. 8, the separator 8a in the air lift device 1 of the present embodiment includes a cylindrical container 35 extending vertically, and the opening provided on the side wall of the container 35 is the upper end side opening 2b of the riser pipe 2. Have a connected configuration.

  The container 35 is set such that the cross-sectional area of the flow passage through which the mixed fluid 7 flowing into the container 35 flows is larger than the flow passage cross-sectional area of the riser pipe 2. Thereby, the container 35 decelerates the flow velocity of the mixed fluid 7 flowing into the container 35, and in the mixed fluid 7, the water 10 and the recovery target object 11 fall by their own weight while the bubbles move upward. Is supposed to occur.

  The separator 8a in the present embodiment, as shown in FIG. 8, as a means for enhancing the effect of the deceleration of the mixed fluid 7 in the above-mentioned container 35, for example, a plate-like decelerating member 36 in the container 35. , In a configuration in which the mixed fluid 7 flowing into the container 35 collides.

  Since the flow of the mixed fluid 7 collides with the decelerating member 36 when the mixed fluid 7 flows into the container 35, the separator 8a having such a configuration can reduce the flow momentum of the mixed fluid 7 more efficiently. .

  Of course, the speed reducing member 36 may have a shape, an arrangement, and a number other than that shown in FIG. 8 as long as it can reduce the momentum of the flow of the mixed fluid 7 flowing into the container 35. .

  Further, in the action of the air lift pump generated in the riser pipe 2, when the mixed fluid 7 is discharged from the upper end side opening 2b of the riser pipe 2, the discharge of the water 10 containing the recovery object 11 and the discharge of air bubbles alternate. To be done. Therefore, when discharge of the water 10 containing the collection object 11 is intermittently performed from the upper end side opening 2 b of the riser pipe 2, the speed reducing member 36 may repeatedly receive the impact. Therefore, in order to prevent the separator 8a from swinging even when such an impact repeatedly acts on the reduction member 36, it is advantageous for the weight of the separator 8a to be large.

  In the separator 8a, the opening on the lower end side of the container 35 is an outlet 9 of the water 10 containing the object to be recovered 11, and an air outlet 27 is provided at the top of the container 35.

  The separator 8a may have a configuration in which an exhaust stack 28 similar to that of the first embodiment is connected downstream of the air outlet 27. However, a configuration in which a bag filter 33 is connected as in the second embodiment It may be

  The air lift device 1 of the present embodiment provided with the separator 8a configured as described above can be used in the same manner as the air lift device 1 of the first embodiment to obtain the same effect.

  In the air lift device 1 of the present embodiment, either or both of the flanges 6a and 6b in the first application example of the first embodiment and the aeration section 3 of the second application example may be applied. Of course.

  Furthermore, the present invention is not limited to the above embodiments and application examples.

  The shapes and dimensions of the components of the air lift device 1 of the present disclosure shown in FIGS. 1 and 7 and the dimensional ratio of the components are for convenience of illustration, and the shapes and dimensions of the actual components, It does not reflect the dimensional ratio of components.

  Although the riser pipe 2 illustrated the pipe provided with the circular cross-sectional shape, cross-sectional shapes other than circular, such as square shape, may be sufficient.

  Further, in the riser pipe 2, in consideration of the fact that the size of the air bubble in the mixed fluid 7 increases with the decrease in water pressure, the riser pipe 2 is disconnected at the upper end side opening 2 b than the lower end side opening 2 a It may be a tube whose cross-sectional shape or cross-sectional area changes midway in the longitudinal direction so as to increase the area.

  The separators 8, 8a receive the mixed fluid 7 discharged from the upper end side opening 2b of the riser pipe 2 and can separate the water 10 containing the object to be recovered 11 and the air 5a, as shown in FIG. A separation system or type of separator other than that shown in FIG. 8 may be employed.

  If the collection | recovery part 12 can selectively collect the collection | recovery object object 11 from the mixture of the water 10 discharged | emitted from the exit 9 of the separators 8 and 8a, and the collection | recovery object object 11, arbitrary except the above-mentioned A recovery unit 12 of a type may be employed.

  Of course, various changes can be made without departing from the scope of the present invention.

2 riser pipe 2a lower end side opening 2b upper end side opening 3 aeration part 4 air supply part 5 compressed air 5a air 6, 6a, 6b flange part 7 mixed fluid 8, 8a separator 9 outlet 10 water 11 collection object 12 collection part 14 Water surface 15 Air ejection pipe 17a, 17b, 17c Passage 27 Air outlet 28 Exhaust stack 33 Bag filter Y Upper limit value

Claims (6)

Riser pipe,
A diffuser provided near the lower end of the riser pipe,
An air supply unit connected to the aeration unit to supply compressed air;
A flange portion provided on the outer periphery of the lower end side opening of the riser pipe;
A separator connected to the upper end side opening of the riser pipe to separate air from the mixed fluid discharged from the upper end side opening;
And a recovery unit provided downstream of the outlet of the separator for recovering an object to be recovered which is discharged together with water from the separator.
Furthermore, the aeration part is disposed circumferentially at a circumferential wall near the lower end of the riser pipe, and includes a plurality of air jet pipes whose one end side in the longitudinal direction is fixed to the peripheral wall of the riser pipe
Between the plurality of air ejection pipes, a large passage is formed by an allowance set more than the upper limit value of the particle size range set for the object to be collected desired to be collected,
An air lift device characterized by The aeration unit is disposed at intervals in a circumferential direction on a peripheral wall near the lower end of the riser pipe, in a posture extending in a radial direction from an axial center position of the riser pipe. An airlift device as described. The air aeration portion is a central portion of the riser pipe, and a portion located inside the projecting end portions of the air ejection pipes, and the air ejection arranged adjacent to the circumferential direction in the vicinity of the outer periphery of the riser pipe The air lift device according to claim 2, wherein the passage is provided between the tubes. The air lift device according to any one of claims 1 to 3, wherein the separator is a cyclone type. The separator comprises an air outlet,
The air lift device according to any one of claims 1 to 4, wherein a bag filter is connected downstream of the air outlet of the separator. The separator comprises an air outlet,
An upstream end of an exhaust stack is connected to the air outlet of the separator;
The air lift device according to any one of claims 1 to 4, wherein a downstream end of the exhaust stack is in a posture facing a water surface.

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