JP3797644B2 - How to squirt liquid - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for ejecting liquid, and more particularly, to a method for ejecting liquid for ejecting liquid in a tank toward a heat transfer surface of a heating / cooling device or an inner peripheral surface of a tank peripheral wall. .
[0002]
[Prior art, problems to be solved by the invention]
In fermentation and culture, fermented liquor and culture broth have a large foaming property, and often foam significantly by stirring during work, thereby reducing workability. An antifoaming agent such as silicon is added in order to prevent such foaming and to eliminate the foam once generated. However, the addition of this antifoaming agent is not only expensive, but since the antifoaming agent itself is a foreign substance, there is a risk of adversely affecting fermentation, culture, etc., and it is mixed as an impurity in the product. Therefore, it takes time and effort to remove the product from the product, and it is mixed with waste liquid and interferes with the waste liquid treatment work.Therefore, the addition of an antifoaming agent is an undesirable means and should be avoided as much as possible. It is regarded as a means not to be.
[0003]
Also, by rotating the disk in the foam layer on the liquid surface, and rotating the truncated cone-shaped hollow cylinder with the large-diameter lower opening facing the foam layer on the liquid surface, etc. Attempts have been made to eliminate bubbles by crushing bubbles with shearing force. However, such a means not only requires a great deal of power, but also has the disadvantage that the bubbles are only fragmented and often not defoamed in the end.
[0004]
Further, the inner peripheral surface of the peripheral wall of the stirring tank is contaminated by microbial cells and solid raw materials and products attached to the inner peripheral surface, thereby reducing the reaction yield and heat transfer of the peripheral wall of the stirring tank. Often reduces the coefficient. In such a case, in order to drop such deposits from the inner peripheral surface of the stirring tank, it is substantially impossible to clean the inner peripheral surface of the peripheral wall of the stirring tank without stopping the operation in the stirring tank. Is impossible.
[0005]
In addition, as a heating / cooling device for the liquid in the stirring tank, for example, when the jacket and the snake tube and the multi-tube bundle are provided in the outer peripheral surface of the peripheral wall of the stirring tank and the stirring tank, respectively, the liquid in the stirring tank However, for example, it decreases due to evaporation or the like, and the liquid level in the agitation tank decreases with the passage of time, and the heat transfer area of these heating / cooling devices cannot often be used effectively.
[0006]
In order to increase and recover the reduced heat transfer area, the liquid remaining in the tank is circulated by means of supplying a new liquid into the tank to raise the liquid level or using a pump installed outside the tank. There is a method of spraying on the inner peripheral surface of the peripheral wall of the tank. In the former, the supply of new liquid into the tank causes a sudden change in the composition of the liquid in the tank, and the operating conditions need to be changed in response to such a change. Also, there are drawbacks such as changes in product quality. In the latter case, a pump and a pipe for circulating the residual liquid are necessary, and there are drawbacks that the residual liquid remains in the tank and the pipe after the operation is stopped. Therefore, these are means that cannot be adopted in reality. Thus, no means to be put into practical use has yet been found to eliminate the disadvantage that this heat transfer area cannot be used effectively.
[0007]
Furthermore, in order to evaporate the liquid in the agitation tank, a heating means is immersed in the liquid or attached to the outside of the peripheral wall of the agitation tank and heated with or without agitation of the liquid. There is a method of evaporating from the liquid surface, but in this method, the heat of the space on the liquid surface heated by the heating means is not effectively used, and the heating of the liquid is limited to the contact area with the heating means, The heat of the means is not used effectively, and there is a disadvantage that the liquid evaporation rate is slow. Furthermore, it is preferable that two types of liquids can be efficiently mixed with an apparatus having a simple structure.
[0008]
In the conventional defoaming by stirring, contamination of the inner peripheral surface of the peripheral wall of the stirring tank and the surface of the heating / cooling device, reduction of the heat transfer area, and mixing of liquids and suspensions having different specific gravity Defects such as low mixing ratios can be overcome only by mechanical stirring, eliminating bubbles efficiently and reliably, cleaning the inner peripheral surface of the peripheral wall of the stirring tank and the surface of the heating / cooling device, In order to prevent a decrease in the inner peripheral surface of the peripheral wall of the stirring tank and the heat transfer area of the heating / stirring device and to mix liquids and suspensions having different specific gravities efficiently, the stirring blade and the stirring method have been intensively studied. As a result of repeating the soot, an invention relating to a stirring blade and a stirring method was reached and a patent application was filed (Japanese Patent Laid-Open No. 6-335627).
[0009]
In the stirring blade of the prior application, one or a plurality of liquid feeds such as a tube body, a bowl-like body and a plate body are preferably fixed obliquely on a fixture attached to the stirring shaft. A stirring blade having an upper opening and a lower opening at both ends. As a result, the present inventors have continued and studied to solve the above-mentioned problems, and as a result, discovered the following problems in the invention relating to the above-mentioned patent application, and further studied to solve the problems. Stacked firewood. That is, in the above-mentioned prior application, the liquid feeding is preferably inclined with the upper end closer to the stirring shaft than the lower end, or the lower end is brought closer to the stirring shaft than the upper end and is slanted. The direction of the blade was not specified, and the inclination angle was fixed and not variable. Therefore, to change the purpose and conditions of use of the stirring blade, the use of the stirring blade was stopped. Thus, the size of the tilt angle had to be changed by taking the stirring blade out of the tank.
[0010]
In addition, since the pipe body to be fed is usually brought into contact with a highly corrosive liquid, the surface thereof is made of, for example, polytetrafluoroethylene in order to complete its corrosion resistance. Such a synthetic resin and a material having high corrosion resistance such as glass and ceramics are coated or lined. Thus, although the technology in this coating or lining has been greatly improved in recent years, there is still a risk of pinholes, and therefore the coating or lining is caused by the risk of pinholes. The certainty of the corrosion resistance of the pipe is difficult to guarantee.
[0011]
In order to increase the certainty of the corrosion resistance of this pipe body, prior to the use of this pipe body, a coating layer or a lining layer of this pipe body (these layers may be collectively referred to as a lining layer hereinafter). It is necessary to inspect not only the outer peripheral surface of this tubular body but also the inner peripheral surface for the presence or absence of pinholes in However, it is extremely difficult to inspect the presence of a pinhole on the inner peripheral surface of the tube, and even if a pinhole is found, it is difficult to repair the pinhole.
Since it is easy to inspect the presence of pinholes in the lining layer and the like, and therefore it is easy to repair the pinholes, it is preferable to use a bowl-like body as the liquid feed.
[0012]
Further, in the specification of the prior patent application, it is described that when the rod is used as the liquid to be fed, the liquid simply rises up the rod and is discharged from the upper opening. The mounting surface and mounting direction of the rod-shaped body are not described at all.
[0013]
However, for example, when the liquid discharged from the upper opening of the bowl is sprayed on the foam layer on the liquid surface to defoam, the inner peripheral surface of the tank peripheral wall is cleaned by spraying it on the inner peripheral surface of the tank peripheral wall. When spraying on the heat transfer surface to secure the heat transfer area and / or for cleaning and spraying on the liquid surface space to evaporate, etc. Needless to say, it is preferable that the distance and amount of liquid to be ejected (hereinafter referred to as ejection distance and ejection amount, respectively) are large.
[0014]
  In order to increase the ejection distance and the ejection amount of the ejected liquid, the present inventors can increase the direction of inclination of the rod-shaped body, the size of the inclination angle, and the direction of directing the concave surface,That is,The present invention has been reached based on the knowledge that the choice of the deflection angle size must be selected.
[0015]
[Means for Solving the Problems]
  The present inventionA stirring shaft and a bowl-shaped body fixed to the shaft are provided in the container, and the bowl-shaped body is rotated around the stirring shaft while the lower end of the bowl-shaped body is positioned in the liquid in the container. The liquid is ejected from the upper end of the body into the container, collides with the wall of the container, and / or is sprayed into the container.Clean inner surface or heat transfer surfaceHold in a wet state, and / orSecure the heat transfer area of the liquidAbovePlightthe body'sMake the concave face the rotation axis or the rotation direction of the rod-shaped bodyIn addition, three points arbitrarily selected in the order of precedence according to the rotation direction in the opening of the bowl or the cross section of the bowl in the plane of rotation A , B and C And the rotation axis on the same plane as the opening or cross section of the rod-shaped body D And if these points A , B and C And D (1) B ~ D Distance between ≧ C ~ D And (2) line segment AB And line segment BD The eggplant ABD And line segments BC Made with the line segment BD CBD Θ ₁ And θ ₂ Then θ ₁ And θ ₂ Each of the points B When the rod is rotated clockwise around the center, a positive sign is attached. On the other hand, when the rod is rotated counterclockwise, a negative sign is attached. D −75 ° ≦ θ ₁ ≦ 110 ° and −75 ° ≦ θ ₂ ≦ 110 °, and the rod-shaped body is the axis of rotation D −110 ° ≦ θ when rotated counterclockwise around the center ₁ ≦ 75 ° and −110 ° ≦ θ ₂ ≦ 75 °Is the method.
[0016]
In the method of ejecting the liquid of the present invention, the ejected liquid ejected from the upper opening at the upper end of the rod-like body is used, for example, for cleaning the inner peripheral surface of the container peripheral wall, securing the heat transfer area and / or cleaning. However, it is also used for defoaming the foam layer on the surface of the liquid and evaporating the liquid in the space above the liquid. Unless otherwise specified in the present invention, “upper” and “lower” are defined as “position close to the liquid bottom” and “position far from the liquid bottom”, respectively.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
There is no particular limitation on the shape and material of the fixture as long as it is for attaching one or more bowls to the stirring shaft. The fixture can be a rod-shaped body, a square member, a steel plate and a plate-shaped body with holes (hereinafter also referred to as a perforated plate-shaped body), or a plate-shaped body that is not perforated (hereinafter referred to as a non-perforated plate-shaped body). And so on). These unperforated plate and perforated plate are preferably attached to a stirring shaft so that fluid resistance does not become excessive when rotating in a liquid.
[0018]
These rod-shaped body, square bar, section steel, perforated plate-shaped body, and non-perforated plate-shaped body are respectively positioned on the radius or the diameter of the rotation plane. Further, these rod-shaped body, square bar, shaped steel, perforated plate, perforated plate-shaped body and non-perforated plate-shaped body may be one, but may be plural, and in the case of plural, usually, You may arrange | position on the same rotation plane, and may arrange | position on a mutually different rotation plane.
One or more hooks are attached to one fixture.
[0019]
The number of hooks attached to one fixture, the mounting position of one hook when one hook is attached to one fixture, and a plurality of hooks per fixture When the rod-like body is attached, the interval between the rod-like bodies and the attachment position are the viscosity of the liquid, the thickness of the rod-like body, the diameter of the container itself, the angle between the stirring shaft and the rod-like body, and the upper end of the rod-like body. The liquid is appropriately selected according to the use of the liquid ejected from the upper opening of the liquid (hereinafter sometimes referred to as the ejected liquid) and the kind of the liquid to be mixed.
[0020]
The rod-shaped body is usually made of a metal such as iron and stainless steel, and its surface is coated or lined with a synthetic resin such as polytetrafluoroethylene and a material having high corrosion resistance such as glass and ceramic. Although preferable, it may be made of a corrosion-resistant material such as plastic and metal having a high corrosion resistance and glass and ceramic.
[0021]
The rod-shaped body is a hollow body such as a cylindrical body or a rectangular tube body, and a part of the peripheral wall is notched in the longitudinal direction (this opening may be referred to as an upper surface opening hereinafter). The cross section of the middle part (same as the cross section perpendicular to the long axis) and the upper and lower ends (hereinafter also referred to as the upper opening and the lower opening, respectively). There is no particular limitation on the shape of each of the following (which may be simply referred to as an opening), and the shape may be either a symmetrical shape or an asymmetric shape (hereinafter also referred to as a symmetrical shape or an asymmetric shape, respectively). However, the former is preferable for practical use. The inner peripheral surface of the peripheral wall of the rod-shaped body is hereinafter referred to as the concave surface of the rod-shaped body.
[0022]
Typical examples of symmetrical shapes are circles with some arcs missing (hereinafter also referred to as missing circles), semicircles, semilong circles, semielliptical circles, U shapes, V shapes and trapezoids. A square, a rectangle, a regular octagon, a straight line connecting the first and fifth vertices, and a half of the deformed pentagon and a straight line connecting the midpoints of the first and fifth sides of the regular octagon. Polygons such as deformed hexagons and shapes that are rounded at the apex angle of these polygons and / or bent outward with a small curvature (hereinafter sometimes referred to as “substantial polygons”) Can be mentioned.
[0023]
As a typical example of the asymmetric shape, there is a shape in which one circumference or side of an end corresponding to the two peripheral edges of the above-mentioned symmetrical shape (hereinafter also referred to as an open end) is extended (these symmetrical shapes and The asymmetric shape is sometimes referred to as the open shape below). In addition, an equilateral mountain-shaped steel, an H-shaped steel, and a square or rectangular C-shaped steel having a cross-sectional shape of a square or a rectangle can be used as a bowl-shaped body. Of these, C-shaped steel is preferred. The equilateral angle steel is a bowl-shaped body having a V-shaped opening whose apex angle is a right angle and whose two sides are substantially equal to each other.
[0024]
Each of the H-shaped steels is a bowl-shaped body having a square or rectangular opening lacking one side. A C-shaped steel having a square cross-sectional shape is a bowl-shaped body having a square opening lacking a part of one side, and a C-shaped steel having a circular cross-sectional shape is a bowl-shaped body having an opening at the circumferential portion of the defect. Is done. Furthermore, it is preferable that the upper surface opening edge is rounded or bulged into a cylindrical shape prior to coating or lining, as in a coating or lining known per se.
[0025]
The shapes and sizes of the upper opening and the lower opening of the bowl-like body may be the same as each other or different from each other. The area of the upper opening is preferably smaller than the area of the lower opening. The opening area of each of the upper opening and the lower opening of the rod-shaped body is defined as an area where the liquid can pass through the concave surface of the rod-shaped body.
[0026]
The opening area of each of the upper and lower openings of the rod-shaped body is a straight line connecting these shapes and the ends of the openings when the shapes of the upper and lower openings are symmetrical open shapes. If the shape of each of the upper opening and the lower opening is an asymmetrical open shape, the shape, its extension end and the other opening end are connected. It is an area of an asymmetric closed shape surrounded by a straight line or an area of a symmetrical closed shape surrounded by a straight line connecting both ends of these shapes and excluding the extension.
[0027]
There is no particular restriction on the shape of the side surface of the bowl (hereinafter also referred to as the side shape), but usually a straight line, a curved line curved with a small curvature so as to bulge upward or downward, and The straight line and the upper end and / or the lower end of the curve are formed in an S-shape further extended in the horizontal direction. The curve is preferably a parabola. In particular, a straight line is preferable because it is easy to create a rod-like body. Further, in order to increase the injection distance and / or the injection amount, a curved line that is bent downward and bulged is preferable, and a parabola that is bent downward and bulged is particularly preferable.
[0028]
The shape seen from the front (hereinafter sometimes referred to as the front shape) is not particularly limited, but it is usually bent in a straight line with a small curvature in the horizontal direction (the direction parallel to the plane of rotation of the rod-like body). The curved line and the straight line and the upper end and / or the lower end of the curved line have an S-shape that is further extended in the lateral direction.
[0029]
In addition, the shape seen from above or below (hereinafter sometimes referred to as a planar shape) is not particularly limited as in the case of the side shape and the front shape, and the rotation direction of the rod-like body with a straight line and a small curvature or The curved line and the straight line and the upper end and / or the lower end of the curved line that are bent in the counter-rotating direction are further formed into an S shape that is extended in the lateral direction toward the circumference. preferable. The length of the hook-shaped body is not particularly limited, and the lengths of the plurality of hook-shaped bodies attached to the fixture may be the same or different from each other.
[0030]
Cover the entire upper opening of the rod-shaped body with a perforated plate and a net having a large number of holes in order to eject liquid from the upper opening of the rod-shaped body as a mist, as a fine droplet or a trickle. And it is preferable. The perforated plate may have a large number of holes formed regularly or irregularly, and the shape and number of the holes are not particularly limited. Typical examples of the hole shape include a circle, an ellipse, a square, and a rectangle.
[0031]
Further, the bowl-shaped body may have its upper opening closed with a plate body with a gap along the inner peripheral surface of the bowl-shaped body. Further, the upper surface opening of the bowl-shaped body can be attached and detached, and can be closed with an opaque or transparent lid. Furthermore, in order to rapidly change the direction of the liquid ejected from the upper opening of the bowl, a reflector can be provided separately from the upper opening.
[0032]
Further, the rod-shaped body does not prevent the liquid from being twisted as long as the liquid can be raised or rotated around its long axis. In this case, the angle at which the rod-shaped body is twisted or rotated is appropriately selected depending on the opening shape and the inclination angle of the rod-shaped body, the viscosity of the liquid in the container, the rotational speed of the rod-shaped body, and the like. .
[0033]
In the latter case, the hook-like body can be rotatably mounted on the fixture. In this case, the rod-shaped body can be fixed after being directed to an arbitrary deflection angle, or can be automatically rotated according to the rotation speed of the rod-shaped body. In this case, the bowl-like body is rotatably mounted on the stirring shaft.
[0034]
The rod-like body may be attached to the fixture such that its long axis coincides with the radial direction of the rotation plane corresponding to the attachment direction of the fixture, and is eccentric in a direction different from the radial direction. And may be mounted.
When the rod-shaped body is mounted eccentrically, the long axis of the rod-shaped body may be parallel to the radial direction on the rotation plane corresponding to the mounting direction of the fixture, or may be inclined. May be. In addition, the plurality of hooks attached obliquely may have their lower ends crossed with each other in the vicinity of the stirring axis.
[0035]
Further, the concave surface of the bowl-like body is attached to the agitation shaft via a fixture with the concave surface facing the rotation axis (the same as the center of the agitation shaft) or the rotation direction. The degree of the direction of the concave surface of the rod-shaped body with respect to the rotation axis is indicated by the magnitude of the deflection angle. The deflection angle is defined in the same way as the deflection angle in dynamics. Three points arbitrarily selected in the preceding order according to the rotation direction in the opening of the rod-like body or the cross-section of the rod-like body in the plane of rotation are A, B, and C, respectively, on the same plane as the opening or the cross-section of the rod-like body When the rotation axis is D, these points A, B, C, and D satisfy the following conditions. That is, (1) the distance between B and D ≧ the distance between C and D, and (2) the ABD formed by the line segment AB and the line segment BD, and the fist formed by the line segment BC and the line segment BD. Each CBD is θ₁And θ₂Then θ₁And θ₂Each of these is marked with a positive sign (+) when the rod-shaped body is rotated clockwise around the point B (clockwise), while it is rotated counterclockwise (counterclockwise). In this case, a negative sign (−) is attached, and in the case where the rod-like body is rotated in the clockwise direction around the rotation axis D, −75 ° ≦ θ₁≦ 110 ° and −75 ° ≦ θ₂When ≦ 110 °, and when the rod-like body is rotated counterclockwise about the rotation axis D, −110 ° ≦ θ₁≦ 75 ° and −110 ° ≦ θ₂≦ 75 °. The magnitude of the deflection angle is (θ₁+ Θ₂) / 2. Therefore, θ₁And θ₂Are equal to each other, the deflection angle is zero.
[0036]
The magnitude of the deflection angle is appropriately selected within the above range depending on the shape and opening shape of the rod-like body itself, the opening area ratio between the upper opening and the lower opening, the use of the jet liquid, and the like. When attaching the bowl-shaped body to the fixture, the fixture must not prevent the liquid from rising in the concave surface of the bowl-shaped body.
[0037]
The rod-like body is fixed to the fixture with a predetermined inclination angle, or is attached to the fixture so that the inclination angle can be adjusted arbitrarily, the latter being preferred. This adhering can be performed by conventional methods such as fitting, welding, and adhesion. The inclination angle is defined as an angle formed by the long axis of the bowl and the rotation plane.
[0038]
Accordingly, the saddle-like body has an inclination angle larger than 0 ° to 90 ° and the lower opening is made closer to the rotating shaft than the upper opening or the lower opening from the rotating shaft. The distances to the upper opening and the upper opening are equal to each other, but the former is preferable in practice. In the latter case, it is preferable to close the lower opening of the bowl. Also in this case, the liquid in the liquid immersion portion of the rod is raised in the rod. The angle of inclination of the rod-shaped body is the shape and opening shape of the rod-shaped body itself, the ratio of the opening area between the upper opening and the lower opening, the type of liquid, the rotational speed of the rod-shaped body, and the desired ejection distance of the ejected liquid The amount is appropriately selected according to the amount of jetting and the use of the jetting liquid. Usually, about 15 ° to 80 ° is preferable.
[0039]
In order to attach the rod-shaped body to the stirring shaft so that the inclination angle can be adjusted, for example, the lower end of the rod-shaped body is hinged to the stirring shaft, and the vertical direction (the same applies to the axial direction of the stirring shaft). What is necessary is just to mount | wear so that the upper opening of a bowl-shaped body can be moved along the radius of a rotating plane by a moving means or a horizontal direction (direction parallel to a rotating plane) moving means. In the above description, the movement of the upper opening of the bowl-like body by the vertical movement means and the movement by the horizontal movement means may be referred to as a vertical method and a horizontal method, respectively.
[0040]
Furthermore, the hook-shaped body may be bendable and / or stretchable. In order to make the bowl-like body bendable, for example, the bowl-like body may be made of a flexible material, or a plurality of bowl-like bodies (divided into a plurality of divisions about its long axis) A rod-like body may be referred to as a piece below) and may be connected with a joint material. Further, in order to make the rod-like body extendable and retractable, for example, a plurality of rod pieces are slidably connected to each other.
[0041]
When a plurality of the hooks are fixed to the fixture, the plurality of hooks may be independent from each other or may be integrated with each other. For example, the edge part with respect to the tank surrounding wall of the flat structure provided in the stirring axis | shaft can be bent in a rotating shaft direction, and can be made into a bowl-shaped body. As a representative example of the bowl-shaped body integrated with the fixture as described above, for example, a plate body that is a flat plate structure is used as the fixture, and the opposite side portions that are not horizontal of the plate body that is the fixture are, Folded along the side substantially parallel to the side, or folded along the side by folding the lower apex, and the rod-like body is located at the edge of the opposite side of the plate that is not horizontal. A curved plate that is connected by striking the upper opening side edge, or bent outwardly with a small curvature or a triangular or quadrangular plate at an arbitrary angle to the edge of the opposite side of the plate that is not horizontal Examples thereof include a rod-like body formed by bonding bodies.
[0042]
In this case, the plate body, which is a flat plate structure used as a fixture, is usually preferably a triangular plate and a rectangular flat plate such as an inverted trapezoid, a rectangle, and a square. Does not interfere with the plate. In the bowl-shaped body formed in this manner, the shapes of the upper opening and the lower opening are asymmetrical shapes. The plate body used as a fixture acts as a stirring blade. It is preferable that a hole can be formed in the plate so that the fluid resistance in the plate does not become excessive, so that the fluid resistance can be reduced.
[0043]
The fixture to which the rod-like body is attached is fixed to the stirring shaft or is slidably mounted, and the lower-side opening of the rod-like body is submerged below the liquid surface, and the upper opening is exposed from the liquid surface. By rotating the stirrer shaft and rotating the rod-like body, the liquid in the liquid immersion part of the rod-like body is raised in the rod-like body by centrifugal force and ejected from the upper opening. At the same time, the liquid is agitated at a portion below the liquid surface of the rod-shaped body. Further, it is possible to perforate an arbitrary intermediate portion of the portion corresponding to the liquid flow path in the rod-like body, and to eject the liquid from this hole. Furthermore, an ejection pipe can be provided outside the drilled hole toward the circumference of the plane of rotation. A nozzle, a net, a perforated plate, and the like can be provided at the tip of the ejection pipe.
[0044]
The rod-shaped body used in the present invention is fixed to the stirring shaft by a fixture, or is slidably mounted. The fixing means is not particularly limited, and may be any one of, for example, fitting, screwing, welding, and adhesion.
[0045]
In the case of fixing, a plurality of fixtures can be attached to the stirring shaft in the longitudinal direction of one or the stirring shaft. In the latter case, the lower opening of the upper bowl and the upper opening of the lower bowl preferably overlap each other in the major axis direction of the stirring shaft. Furthermore, a plurality of attachments can be attached to the same rotational plane.
[0046]
In addition, in order to slidably mount, for example, a groove or protrusion or a protrusion is provided on the surface of the stirring shaft along the long axis, and the groove or protrusion on the surface of the stirring shaft is provided on the fixture. Alternatively, it is possible to provide protrusions or protrusions or grooves that can be fitted and slid with the protrusions.
[0047]
Furthermore, the fixture slidably attached to the stirring shaft can be moved automatically or manually. For example, a float can be placed on the fixture and floated on the liquid level, and can be automatically moved in response to the vertical movement of the liquid level in the tank, or by remote operation from outside the tank It can be moved up and down and stopped at a predetermined position. It is also possible to manually move the fixture up and down by suspending the fixture with a wire connected to the outside of the tank and tensioning or relaxing the wire outside the tank.
[0048]
The float can also be used as a fixture. Further, it is preferable that the float has a shape and a structure such that the fluid resistance does not become excessive during stirring. In the method of ejecting the liquid of the present invention, the liquid immersion portion of the rod-shaped body acts as a stirring blade, and together with the rod-shaped body, for example, a turbine blade, a propeller, a pitched flat blade, a flat blade disk turbine, a flat blade Other stirring blades such as a curved blade, a fiddler blade, and a bull margin blade may be provided. The fixture itself also acts as a stirring blade.
[0049]
In the method of ejecting the liquid of the present invention, the size of the rod-shaped body is not particularly limited. For example, a small-scale laboratory vessel used in a flask or a large tank in a factory production apparatus It can be of any size, such as a large scale used inside. In the flask, it is preferable that the rod-shaped body has an inclination angle adjustable by a vertical method.
[0050]
The erupted liquid ejected from the upper opening of the rod-like body is used for various applications as follows. That is, for example, (a) the inner peripheral surface of the tank peripheral wall is washed by spraying on the inner peripheral surface of the tank peripheral wall. (B) When the liquid level in the tank is lowered, in the tank where the jacket is provided on the outer peripheral surface of the tank peripheral wall, the inner peripheral surface of the tank peripheral wall, which is a heat transfer surface, and a snake tube and a multi-tube bundle are provided in the tank. In a tank, the heat transfer surface is sprayed on each surface such as a snake tube and a multi-tube bundle to secure a heat transfer area and / or clean. At the same time, (c) spraying on the foam layer on the liquid level to defoam and (d) spraying it on the space above the liquid level to evaporate the liquid. Can also be used.
[0051]
When the ejected liquid is used for defoaming at the liquid level and for evaporating the liquid in the space above the liquid level, one or more bowls are provided in one fixture in the radial direction of the plane of rotation. The inclination angle is selected according to the rotational speed of the rod-shaped body (circumferential speed in the plane of rotation) so that the ejected liquid can be ejected high. Note that the direction of the liquid ejected from the upper opening can be rapidly changed onto the liquid surface by the reflector provided apart from the upper opening of the bowl-shaped body.
[0052]
In addition, it is preferable to attach a plurality of hooks to one fixture so that the spray liquid is evenly dispersed in the tank. In addition, when using it for defoaming on the liquid surface, it is preferable that the hooks attached to the fixtures are attached so that their trajectories do not overlap with each other in the fixtures on the diameter.
[0053]
When using the erupted liquid to clean the inner peripheral surface of the tank peripheral wall and / or to secure the heat transfer area of the tank peripheral wall, which is used as the heat transfer surface, the tip is attached to one fixture at its tip. It is only necessary to provide a single bowl-shaped body with the upper opening of the body being brought close to the inner peripheral surface within the ejection distance of the ejection liquid.
[0054]
In addition, when used for securing and / or cleaning the heat transfer surface of the heat transfer surface of a heating / cooling device such as a serpentine tube or a multi-tube bundle provided in the tank, It is only necessary to provide one bowl-like body with the upper opening being brought close to the heat transfer surface within the ejection distance of the ejection liquid.
[0055]
The bowl-shaped body integrated with the plate-like fixture that is a flat plate structure fixed to the stirring shaft has a large stirring action when the plate itself as the fixture is rotated. It is preferable because mixing of the two liquids is performed efficiently. The two liquids mixed with each other include liquids having different specific gravities and suspensions having different solid contents.
[0056]
In the method of ejecting the liquid of the present invention, the rotational speed of the rod-shaped body can be appropriately selected depending on the type of liquid, the shape and thickness of the rod-shaped body, the use of the ejected liquid, the type of liquid to be mixed, and the like.
[0057]
【Example】
The cage used in the present invention will be described more specifically with reference to the examples shown in the drawings. However, the present invention is not limited to these examples. These drawings are schematic diagrams for illustrating the principle of the present invention, and the relative sizes and the like are not accurately represented.
[0058]
FIG. 1 shows a plurality of bowl-shaped bodies that are fixedly attached to a stirring shaft by a fixture. In FIG. 1, a is a plan view, and b is a cross-sectional view taken along the line BB of the bowl-shaped body shown in a. However, in a, the agitation shaft shows the end face of the transverse part. The rod-like body 1 is fixedly attached to the stirring shaft 3 by a fixture 2 and attached.
[0059]
The rod-shaped body 1 has a semicircular shape in the cross section of each of the middle part and the upper opening and the lower opening, and is a shape in which a cylinder is vertically cut along a plane including the center of the bottom surface (long axis including the center of the bottom surface). This is equivalent to cutting in the direction below. This cut surface is an upper surface opening. The inner peripheral surface of the peripheral wall of the bowl-shaped body is a concave surface of the bowl-shaped body. Further, the upper portion of the rod-like body 1 is extended almost horizontally toward the circumference. The fixture 2 is a plate 22,..., 22 fixed radially to the central ring 21 at a central angle of 90 °, and a holder 23 for holding the bowl 1 is provided at the tip thereof. . Thus, the stirring shaft 3 is inserted into the center ring 21, and the fixture 2 is fixed to the stirring shaft 3.
[0060]
The plate 22 is an elongated trapezoidal flat plate whose tip is inclined, and its surface is parallel to the major axis direction of the stirring shaft. The holder 23 is a cylinder having an inner peripheral radius equal to the outer peripheral radius of the bowl-shaped body 1. The bowl-like body 1 is inserted into and secured to the holder 23 of the fixture 2, and the lower opening 11 is made closer to the stirring shaft 3 than the upper opening 12, and the concave surface and the upper surface opening are made to face the stirring shaft. Thus, the holder 23 of the fixture 2 does not prevent the liquid from rising in the concave surface. Therefore, the inclination angle of the rod-shaped body is about 60 °.
[0061]
The rod-like body 1 has its lower opening 11 submerged below the liquid surface, the upper opening 12 is exposed from the liquid surface, and the stirring shaft 3 is rotated to rotate. The liquid in the liquid immersion part is raised in the concave surface toward the upper opening 12 of the rod-like body 1 and is ejected from the upper opening 12 together with the liquid under the liquid surface of the rod-like body. Is stirred.
[0062]
FIG. 2 shows a typical example of a rod-shaped body. In FIG. 2, a, b, and c are a side view, a front view, and a perspective view, respectively, seen from an obliquely upward direction (in the direction of the arrow in a). The bowl-shaped body 1 shown in FIG. 2 has a substantially vertically long bottomless semi-cylindrical hollow truncated cone shape, and the cross-sectional shape of each of the middle part and the lower opening 11 and the upper opening 12 is a semicircle. It is circumferential. Further, the side surface has a straight middle portion, and the lower end and the upper end are extended almost horizontally in the center direction and the circumferential direction of the rotation plane, respectively, so as to have a vertically long S-shape as a whole.
[0063]
FIG. 3 shows another example of a bowl-shaped body. In FIG. 3, a and b are a side view and a front view as seen from diagonally above (in the direction of the arrow in a) of the bowl-shaped body, respectively. The rod-shaped body 1 shown in FIG. 3 has a substantially vertically long bottomless semi-cylindrical cylindrical shape, and the cross-sectional shape of each of the middle portion and the lower opening 11 and the upper opening 12 is semicircular. Is. Further, the side surface shape is a parabolic shape that is bulged downward with a small curvature.
[0064]
FIG. 4 shows the shape of the cross section at the opening of the bowl, which are all symmetrical. The same applies to the cross-sectional shape of the intermediate portion. A is a semicircle, B is a semi-ellipse that is bisected by the major axis, C is a U-shape, D is a V-shape with an obtuse angle, and E is an inverted trapezoid (upper base-short side-and lower base- Trapezoids with long sides-below and above, respectively), F is a rectangle, G is a modified pentagon divided by a straight line connecting the first and fifth vertices of a regular octagon, and h is a regular octagon It is a deformed hexagon divided into two equal parts by straight lines connecting the midpoints of the first side and the fifth side.
[0065]
Ri, Nu, Le, and O indicate the cross-sectional shapes of equilateral mountain-shaped steel, a C-shaped steel having a rectangular cross-sectional shape, a C-shaped steel having a circular cross-sectional shape, and an H-shaped steel. ing. Thus, in these rod-shaped bodies, the space between the open ends 13 and 14 is an open edge 15, and the opening area is a shape surrounded by the peripheral surface of these rod-shaped bodies and the open edge 15. It is an area.
[0066]
FIG. 5 shows the cross-sectional shape at the opening of the bowl, all of which are asymmetrical. The same applies to the cross-sectional shape of the intermediate portion. These asymmetric shapes are shapes in which the circumference or side of one open end in the symmetrical shape shown in FIG. 4 is extended, and “a” to “h” in FIG. 5 correspond to “a” to “h” in FIG. To do.
[0067]
That is, for example, FIG. 5A has a shape in which the semicircular opening end 14 of FIG. 4A is extended up to the extension end 16 in the tangential direction at the opening end 14. Further, FIG. 5D has a shape in which the modified pentagonal opening end 14 of FIG. 4T is extended upward and the side of the opening end 14 is extended to the extension portion end 16 as it is. In addition, in FIG. 5, “wa” and “ka” respectively correspond to “a” and “ri”, and indicate the cross-sectional shapes of the bowl-shaped body in which the upper opening edge is bulged in a columnar shape.
[0068]
Therefore, the opening edge 17 is between the opening end 13 and the extension end 16 in these rod-shaped bodies. Further, the opening area is the area surrounded by the symmetrical shape of the peripheral surface of the bowl-shaped body and the opening end 15 to the asymmetrical peripheral surface of the bowl-shaped body and the area surrounded by the upper surface opening end 17. It is.
[0069]
FIG. 6 shows the upper opening of the rod-shaped body covered with the perforated plate. That is, the perforated plate 4 covering the semicircular upper opening 12 of the bowl 1 shown in FIG. 6A is a semicircular shape corresponding to the upper opening 12, and has a plurality of circular small holes 41,. 41 are drilled irregularly. Further, the perforated plate 4 covering the substantially rectangular upper opening 12 in which the two apex angles of the rod-shaped body 1 shown in FIG. 6B are rounded, the apex angle corresponding to the upper opening 12 is rounded. Further, a plurality of elongated rectangular holes 42,..., 42 are regularly formed with their long axes parallel to each other.
[0070]
FIG. 7 shows the upper opening of the bowl-shaped body covered with a plate with a gap along the inner peripheral surface of the upper opening. That is, in FIG. 7A, the upper opening 12 of the bowl-shaped body 1 is semicircular, and the shape of the plate body 5 has a long axis having a length equal to the semicircular diameter of the upper opening 12 of the bowl-shaped body 1. The shape of the gap 18 is a crescent shape. 7B, the upper opening 12 of the bowl 1 has a substantially rectangular shape with two apex angles rounded, and the shape of the plate 5 has the long side of the upper opening 12 of the bowl 1. Is a rectangle whose short side is equal to the length of the long side of the rectangular shape, and whose short side is shorter than the length of the short side of the rectangular shape of the upper opening 12 of the rod-shaped body 1, and the shape of the gap 18 is two pieces. It is an elongated, substantially rectangular shape with rounded apex angles.
[0071]
FIG. 8 shows a bowl-like body provided with a reflection plate spaced from the upper opening. In FIG. 8, a is a plan view of this bowl-shaped body, and b is a cross-sectional view of the bowl-shaped BB section indicated by a. That is, a rectangular reflector 6 is provided perpendicularly to the major axis direction of the bowl 1 so as to be separated from the upper opening 12 of the bowl 1. Thus, the reflector 6 is attached to the holder 23 for attaching the bowl 1 to the fixture 2 via the connecting rod 61.
[0072]
The deflection angle will be described with reference to FIG. That is, the three points arbitrarily selected in the order of precedence according to the rotation direction in the opening of the rod-shaped body 1 or the section of the rod-shaped body 1 in the plane of rotation are A, B, and C, respectively. If the rotation axis on the same plane (the center of the stirring axis is the same below) is D, these points A, B, C, and D satisfy the following conditions. That is, (1) a distance between B and D ≧ a distance between C and D, and (2) an angle ABD formed by the line segment AB and the line segment BD and an angle formed by the line segment BC and the line segment BD. Each CBD is θ₁And θ₂Then θ₁And θ₂Each of these is marked with a positive sign (+) when the rod-shaped body is rotated clockwise around the point B (clockwise), while it is rotated counterclockwise (counterclockwise). In this case, a negative sign (−) is attached, and in the case where the rod-like body is rotated in the clockwise direction around the rotation axis D, −75 ° ≦ θ₁≦ 110 ° and −75 ° ≦ θ₂When ≦ 110 °, and when the rod-like body is rotated counterclockwise about the rotation axis D, −110 ° ≦ θ₁≦ 75 ° and −110 ° ≦ θ₂≦ 75 °. The magnitude of the deflection angle is (θ₁+ Θ₂) / 2. Therefore, θ₁And θ₂Are equal to each other, the deflection angle is zero.
[0073]
FIG. 10 is a perspective view of a bowl-like body that is rotatably mounted on the stirring shaft. That is, the lower opening 11 of the bowl 1 is provided with a lower support 113 connecting the opening ends 111 and 112, and the upper support connecting the opening ends 121 and 122 also to the upper opening 12. 123 is provided. A round bar is fixed to the lower support 113 and the upper support 123 in the center of the lower support 113 and the upper support 123 as a lower support bar 114 and an upper support bar 124, respectively.
[0074]
A lower fixture 221 and an upper fixture 222 are fixed to the stirring shaft 3 in a radial direction perpendicular to the stirring shaft 3. Thus, both the lower fixture 221 and the upper fixture 222 are elongated rectangular plates, and the length of the lower fixture 221 is shorter than the length of the upper fixture 222. Further, the interval between the lower fixture 221 and the upper fixture 222 is equal to the length parallel to the stirring shaft 3 of the slanted rod-like body 1 (length of the saddle-like body × sin inclination angle). The lower fixture 221 and the upper fixture 222 are respectively provided with circular holes 2211 and 2221 at the distal ends.
[0075]
The lower support bar 114 and the upper support bar 124 of the bowl 1 are inserted through the circular hole 2211 of the lower fixture 221 and the circular hole 2221 of the upper fixture 222, respectively. A butterfly screw 125 is screwed onto the upper support rod 124 in contact with the upper surface of the upper fixture 222. The rod-shaped body 1 is automatically rotated according to the rotation speed when the rod-shaped body is rotated around the stirring shaft.
[0076]
On the other hand, the rod-like body 1 can be fixed after being turned to a desired deflection angle. This fixing is achieved by screwing a nut onto the upper support rod 124 and tightening the upper fixture 222 with this nut and the aforementioned butterfly screw 125 and / or screwing two nuts onto the lower support rod 114. Then, it is performed by clamping the lower attachment 221 with these nuts.
[0077]
FIG. 11 shows a bowl-shaped body whose inclination angle can be adjusted by a vertical method. In FIG. 11, a, b, c and d are a perspective view, a plan view, a front view and a side view, respectively. However, in b, the agitation shaft shows the cross-section end face. That is, the lower end of the bowl-like body 7 is fixed to the stirring shaft 3 by the hinge plate 71, while the upper end is connected to the sliding ring 31 via the connecting rod 72. The sliding ring 31 is slidably mounted on the stirring shaft 3. The sliding ring 31 is provided with a butterfly screw 311 for fixing at an arbitrary position. The connecting rod 72 and the sliding ring 31 are vertical movement means.
[0078]
Therefore, the size of the inclination angle of the bowl-like body 7 can be adjusted by moving the sliding ring 31 along the stirring shaft 3 in the direction perpendicular to the rotation plane. When the inclination angle of the bowl-shaped body 7 reaches a predetermined size, the sliding ring 31 is fixed to the stirring shaft 3 by the thumbscrew 311.
[0079]
FIG. 12 shows a bowl-shaped body whose inclination angle can be adjusted by the lateral method. In FIG. 12, a, b, c and d are a perspective view, a plan view, a front view and a side view, respectively. However, in b, the agitation shaft shows the cross-section end face. That is, the lower end portion of the bowl-like body 7 is fixed to the stirring shaft 3 by the hinge plate 71, while the upper end portion is connected to the rotating ring 32 via the connecting rod 73. The rotating ring 32 is supported by the rotating shaft 321 so as to rotate in the vertical direction in parallel with the stirring shaft 3. Further, a hole 322 through which the connecting rod 73 is inserted is formed in the central portion of the rotating ring 32 along the long axis thereof. Further, the rotating ring 32 is provided with a butterfly screw 323 for fixing the connecting rod 73. A connecting rod 73 is inserted into the hole 322 of the rotating ring 32. The connecting rod 73 and the rotating ring 32 are lateral movement means.
[0080]
Thus, the rod-like body 7 has a large inclination angle by moving the connecting rod 73 inserted through the hole 322 of the rotating ring 32 substantially along the plane of rotation of the rod-like body 7. Can be adjusted. When the inclination angle of the bowl-shaped body 7 reaches a desired size, the connecting rod 73 is fixed to the stirring shaft 3 via the rotating ring 32 by the butterfly screw 323.
[0081]
FIG. 13 shows a bowl-shaped body that can be bent. In FIG. 13, a is a folded bowl and b to d are stretched bowls, a and b are side views, and c and d are bowls indicated by b, respectively. It is the top view and front view of these. Moreover, e thru | or g show an intermediate piece, and e, f, and g are a perspective view, a side view, and a rear view, respectively.
[0082]
That is, the saddle-like body 8 is composed of three pieces of the lower piece 81, the intermediate piece 82 and the upper piece 83 in order from the lower end. Thus, the lower flange 81, the intermediate flange 82, and the upper flange 83 are all semicircular shapes having substantially the same transverse shape. However, the intermediate collar 82 and the upper collar 83 are bulged so that the lower ends of the intermediate collar 82 and the upper collar 83 can be fitted into the upper ends of the lower collar 81 and the intermediate collar 82, respectively. . Further, the lower end piece 81 and the intermediate end piece 82 each have a quadrant as viewed from the side.
[0083]
The center of this quadrant is in the vicinity of the upper surface opening of each of the lower flange 81 and the intermediate flange 82. Knock pins 812, 812 and 822, 822 are respectively screwed to the center of the quadrant. Knock pin holes 823, 823, 833, and 833 through which the above-mentioned knock pins 812, 812, 822, and 822 are inserted are formed in the vicinity of the upper surface opening at the lower ends of the intermediate collar 82 and the upper collar 83, respectively. In this rod-shaped body 8, the knock pins 812, 822 and the knock pin holes 823, 833 are joint materials.
[0084]
Insert the upper end of the lower flange 81 into the bulging portion 821 at the lower end of the intermediate flange 82 and insert the knock pins 812, 812 of the lower flange 81 into the knock pin holes 823, 823 of the intermediate flange 82 to connect the lower flange 81 and the intermediate flange The piece 82 is connected, and in the same manner, the intermediate piece 82 and the upper piece 83 are connected, so that one piece 8 is formed. By moving the upper end of the rod-shaped body 8 along the stirring axis, the rod-shaped body can be arbitrarily bent or stretched.
[0085]
FIG. 14 shows a bowl-shaped body that can be expanded and contracted. In FIG. 14, a and b indicate stretched rods, and c and d indicate shrunken rods. Moreover, both a and c are side views, and b and d are both plan views.
That is, the bowl-shaped body 9 is composed of three pieces of a piece of a lower piece 91, an intermediate piece 92, and an upper piece 93 in order from the lower end. Accordingly, the lower flange 91, the intermediate flange 92, and the upper flange 93 are sequentially narrowed, and the transverse shape is a semicircular shape substantially similar to each other. In the intermediate collar 92, knock pins 921, 921 and 922, 922 are respectively screwed in the vicinity of the upper surface opening on the outer side of the lower end and the inner side of the upper end. The lower flange 91 and the upper flange 93 have elongated slots 912, 912 and 932, 932 in parallel with the peripheral edge of the upper surface opening at positions corresponding to the knock pins 921, 921 and 922, 922 in the vicinity of the upper surface opening, except for both end edges. It has been drilled.
[0086]
The intermediate piece 92 is housed in the lower piece 91, and the knock pins 921, 921 of the intermediate piece 92 are inserted into the grooves 912, 912 of the lower piece, respectively, so that the lower piece 91 and the intermediate piece 92 are connected in the same manner. Thus, the intermediate hook 92 and the lower hook 93 are connected to each other, so that one hook-like body 9 is formed. The rod-shaped body 9 can be expanded and contracted by moving the tip of the rod-shaped body 9 along the long axis of the rod-shaped body and sliding the rod pieces together.
[0087]
FIGS. 15 to 18 show two opposing saddle-like bodies integrated with a plate body which is a flat plate-like structure which is a fixture. In FIG. 15, a and b are a front view and a plan view, respectively. However, in b, the agitation shaft shows the cross-section end face. That is, the inverted trapezoidal plate 10 that is a flat structure is attached to the stirring shaft 3, and the hypotenuse of the inverted trapezoidal plate 10 is bent in parallel with the hypotenuse to form the bowl 101. Yes. A hook-like body 102 is formed on the opposite side in the same manner.
[0088]
Each of the shapes of the lower openings 1011 and 1021 and the upper openings 1012 and 1022 of the rod-like bodies 101 and 102 is an asymmetric shape in which the apex is rounded and one side thereof is a long V shape. Thus, the flat plate portion 103 that is not bent in the inverted trapezoidal plate body 10 is used as a fixture, and also acts as a stirring blade. Three flat holes 1031,..., 1031 are perforated in the flat plate portion 103 to reduce the fluid resistance. Each of these hooks 101 and 102 corresponds to a hook attached to the fixture without being decentered, and the deflection angle thereof is about 35 °.
[0089]
In FIG. 16, a is a front view, and b is a cross-sectional view taken along the line BB of the bowl-shaped body indicated by a. That is, the inverted trapezoidal plate 10 that is a flat structure is attached to the stirring shaft 3, and the hypotenuse of the inverted trapezoidal plate 10 is bent in an arc parallel to the hypotenuse to form the bowl 101. I'm hurt. A hook-like body 102 is similarly formed on the opposite side. The shapes of the lower openings 1011 and 1021 and the upper openings 1012 and 1022 of the rod-like bodies 101 and 102 are almost semicircular and are asymmetrical shapes with one end of the circumference extended.
[0090]
Therefore, the flat plate portion 103 which is not bent in the inverted trapezoidal plate body 10 is used as a fixture, and also acts as a stirring blade. The flat plate portion 103 is formed with an inverted trapezoidal hole 1031 substantially similar to the shape of the plate body 10 to reduce the fluid resistance. Each of these hooks 101 and 102 corresponds to a hook that has a long axis parallel to the surface of the flat plate portion 103 and is eccentric to be attached to the fixture, and each deflection angle is about 22. It is set to 5 °.
[0091]
In FIG. 17, a is a perspective view and b is a plan view. However, in b, the agitation shaft shows the cross-section end face. That is, a rectangular plate 10 that is a flat plate structure is attached to the stirring shaft 3, and the non-horizontal side of the rectangular plate 10 includes a trapezoidal bent portion that includes the apex angle of the lower portion of the plate 10. A saddle-like body 101 is formed by folding 104 and bending it along the side. In the center of the bent portion 104, a triangular hole 1041 having three sides parallel to the three sides other than the upper bottom of the bent portion 104 is formed. A saddle-like body 102 is similarly formed on the opposite side. Each of the shapes of the lower openings 1011 and 1021 and the upper openings 1012 and 1022 of the rod-shaped bodies 101 and 102 corresponds to an asymmetric shape in which the apex angle is rounded and one side thereof is a long V shape.
[0092]
Thus, the flat plate portion 103 that is not bent in the rectangular plate 10 is used as a fixture, and also acts as a stirring blade. The flat plate portion 103 is formed with an inverted trapezoidal hole 1031 substantially similar to the shape of the flat plate portion 103 to reduce the fluid resistance. Each of the hooks 101 and 102 corresponds to a hook that is eccentric and attached to the fixture, and the deflection angle of each of the hooks is approximately 52.5 °.
[0093]
In FIG. 18, a is a perspective view and b is a plan view. However, in b, the agitation shaft shows the cross-section end face. That is, a deformed inverted trapezoidal plate 10 having a trapezoidal hypotenuse that is a flat plate structure bent outward is attached to the stirring shaft 3, and the edge of the hypotenuse of the deformed inverted trapezoidal plate 10 is A rectangular plate body 105 bent from a folding line 1051 according to the hypotenuse of the modified inverted trapezoidal shape is collided and connected to form a bowl-shaped body 101.
[0094]
A saddle-like body 102 is similarly formed on the opposite side. Each of the shapes of the lower openings 1011 and 1021 and the upper openings 1012 and 1022 of the rod-like bodies 101 and 102 is an asymmetrical shape having a vertical angle of a right angle and a long V-shape. Therefore, the flat plate portion 103 that is not bent in the deformed inverted trapezoidal plate body 10 is used as a fixture, and also acts as a stirring blade. The flat plate portion 103 is formed with an inverted trapezoidal hole 1031 to reduce the fluid resistance. Each of these hooks 101 and 102 corresponds to a hook attached to the fixture without being eccentric, and the deflection angle thereof is about 45 °.
[0095]
Two opposing bowl-shaped bodies 101, 102 integrated with the plate body 10 which is a flat plate structure shown in each of FIGS. 15 to 18 have their lower openings 1011 and 1021 below the liquid level. Then, the upper openings 1012 and 1022 are exposed from the liquid surface, and the liquid is ejected from the upper openings 1012 and 1022 into the space above the liquid surface by rotating around the stirring shaft 3, while the rod-like body 101,102 are immersed in the liquid, the lower opening 1011,1021 and the upper opening 1012,1022 are opened in the lower layer liquid and the upper layer liquid, respectively, and the lower layer liquid is opened at the upper part of the rod-shaped body by rotating around the stirring shaft The two liquids in the agitation tank can be agitated and mixed by being ejected from 1012, 1022 and agitating the liquid by means of a plate-like fixture. In the liquid ejection device shown in each of FIGS. 15 to 18, the rod-like bodies 101 and 102 are preceded and the flat plate portion 103 is moved backward and rotated (clockwise in the drawing).
[0096]
FIG. 19 and FIG. 20 each show a bowl-like body attached eccentrically. In FIG. 19, a and b are a plan view and a front view, respectively. However, in a, the agitation shaft shows the end face of the transverse part. c is a cross-sectional view taken along the line CC of the liquid ejection device shown in b. That is, in FIG. 19, the two bowl-shaped bodies 1,1 have an agitation shaft 3 by means of a fixture 24 which is an elongated rectangular plate at the top and a fixture 25 which is a trapezoidal plate at the bottom. At a tilt angle of about 20 °, the lower opening is mounted closer to the stirring shaft 3 than the upper opening. The fixtures 24 and 25 are on substantially the same diameter as each other.
[0097]
The bowl-like body 1 has a V-shaped apex angle of each of the upper opening 11 and the lower opening 12, one side is fixed to the fixtures 24 and 25, and the tip of the other side is It is swollen. The two hooks 1, 1 are fixed to the opposite surfaces of the fixtures 24, 25, and the long axes of the hooks 1, 1 are on the plane of rotation corresponding to the mounting direction of the fixtures. Is eccentric with respect to the stirring shaft 3. Further, the deflection angle of each of the rod-like bodies 1 and 1 is about 45 °. The hooks 1 and 1 are rotated so as to precede the fixtures 24 and 25 (clockwise in the drawing).
[0098]
20, a and b are a plan view and a front view (from the direction of arrow B in a), respectively. However, in a, the agitation shaft shows the end face of the transverse part. That is, the fixtures 2 and 2, which are rods having a rectangular cross section, are positioned on the same diameter on the rotation plane and fixed to the stirring shaft 3. The lengths of the fixtures 2, 2 are substantially equal to each other. C-shaped steel with a rectangular cross-section is a rod-shaped body 1, 1 with the top opening on the inside, the top at the tip of the fixture 2, 2 and the bottom at the opposite side of the stirring shaft 3 The long axis of each of the rod-like bodies 1 and 1 is relative to the radius on the rotation plane corresponding to the mounting direction of the fixture. The lower openings 11 and 11 of the bowls 1 and 1 are eccentric with respect to the stirring shaft 3.
[0099]
The deflection angle of these rods 1 and 1 is substantially 0 °. Further, the lower opening 11 is made closer to the stirring shaft 3 than the upper opening 12, and the slanted body 1 has an inclination angle of about 40 °. The rod-shaped body 1 is preferably rotated with the lower opening 11 leading and the upper opening 12 following (clockwise in the drawing), but may be rotated in the opposite direction.
[0100]
FIG. 21 and FIG. 22 each show a bowl-shaped body perforated in an arbitrary intermediate portion of a portion corresponding to a liquid flow path. In FIG. 21, a and b are a front view and a side view, respectively, of a punched rod-shaped body. In the bowl-shaped body 1 shown in FIG. 21, a ridgeline 107 formed at a connection portion between the peripheral walls 106 and 106 is used as a liquid flow path, and a hole 1071 is formed in the ridgeline 107. FIG. 22 is a perspective view of a perforated bowl-shaped body. In the bowl-shaped body 7 shown in FIG. 22, a hole 74 is formed in an intermediate portion of the outer peripheral wall, and an ejection pipe 741 is provided outside the hole 74 toward the circumference of the rotation plane.
[0101]
FIG. 23 is a vertical cross-sectional view of a stirring tank having a bowl-like body mounted therein. That is, except that two sets of fixtures 2 and 2 are used to attach the bowl 1 to the stirring shaft 3, the bowl like the one shown in FIG. It is attached to. Thus, the upper end of the stirring shaft 3 is connected to an electric motor M on the upper bottom plate of the stirring tank T. A jacket J is disposed on the peripheral wall of the stirring tank T and the outer periphery of the bottom plate. Note that the bowl 1 has a length from the bottom of the stirring tank T to the top of the jacket J.
[0102]
The lower opening 11 of the bowl 1 is submerged below the liquid level L in the stirring tank T, while the upper opening 12 is exposed to the space above the liquid level L in the stirring tank. Thus, this bowl-shaped body rotates the stirring shaft 3 by driving the electric motor M on the upper bottom plate of the stirring tank T, and the liquid in the stirring tank T is moved to the lower part of the bowl-shaped body 1 by being rotated. From the opening 11 through the rod-like body 1, it is ejected as an ejected liquid from the upper opening 12, and the ejected liquid is dispersed in the space on the inner peripheral surface of the peripheral wall of the stirring tank T and / or the liquid surface L. It is done. Further, the portion below the liquid level L of the bowl 1 and the fixtures 2 and 2 below the liquid level L act as stirring blades.
[0103]
FIG. 24 is a vertical cross-sectional view of a flask having a rod-like body mounted therein.
That is, the size of the inclination angle can be adjusted by the same vertical method as shown in FIG. 11 except that the butterfly screw 311 is omitted and the stopper 34 is fixed to the lower portion of the stirring shaft 3. A body 7 is attached to the center of the flask F.
[0104]
Then, from the outside of the flask F, the sliding ring 31 is slid upward on the surface of the stirring shaft 3 to increase the inclination angle of the rod 7 and the upper end of the rod 7 is brought close to the stirring shaft 3. The rod-like body 7 is constricted and inserted through the mouth of the flask F, and then the sliding ring 31 is opened and lowered along the stirring shaft 3 until it comes into contact with the stopper 34 to reduce the inclination angle to a predetermined size. Say it. The stopper 34 can be omitted. In this case, the inclination angle of the rod-like bodies 1, 1 has a magnitude corresponding to the rotational speed and / or the length of the connecting rod 72.
[0105]
FIG. 25 shows a bowl-like body that is slidably mounted on the stirring shaft by means of an attachment that also serves as a float. In FIG. 25, a is a plan view of this bowl-shaped body, b is a cross-sectional view of the bowl-shaped section taken along the line B-B shown in a, and c is a hook of the bowl-shaped body to the attachment that also serves as a float. It is an expansion perspective view of an attachment part. That is, the floats are a small-diameter float 26 and a large-diameter float 27 that are both annular and have a substantially square cross-section and are positioned concentrically with each other on the same plane of rotation. Two sets of two rods 1, 1 arranged on the same diameter across the stirring shaft 3 are attached to the floats 26 and 27 with a central angle of 90 ° between the rods. It has been. This set of bowls is long and the other set is short. Thus, the cages 1, 1 are attached to the floats 26 and 27 by holders 19,. The floats 26 and 27 are connected to the central ring 28 at the center by support rods 29 and 29. The central angle between the support rods 29 and 29 is a right angle.
[0106]
A protrusion 281 is provided on the inner peripheral surface of the center ring 28. On the other hand, the stirrer shaft 3 is provided with a groove 33 on its outer peripheral surface along its long axis. The stirrer 26 and 27 are slidably mounted on the stirrer shaft 3 by inserting the stirrer shaft 3 into the center ring 28 and fitting the protrusion 281 of the center ring 28 into the groove 33 of the stirrer shaft 3. Is done. The liquid ejecting device is always floated on the liquid level, and the liquid is continuously ejected from the upper opening 12 of the rod-shaped body 1 without any change regardless of the change in the height of the liquid level.
[0107]
FIG. 26 shows a plurality of hooks attached to one fixture. In FIG. 26, a and b are a plan view and a front view, respectively. That is, the fixtures 2 and 2 have the same length and are positioned on the same diameter with the stirring shaft 3 interposed therebetween. Two hooks 1,1 are attached to one (left side as viewed in the drawing), and three hooks 1,1,1 are attached to the other (right side as viewed in the drawing). It has been. The inclination angles of these rod-shaped bodies are equal to each other, and both are set to about 75 °. Thus, the distances from the stirring shaft 3 to the rods 1 are all different. When the rods 1,..., 1 are rotated around the stirring shaft 3, five rods are used. Circumferences that are trajectories of the shapes do not overlap each other.
[0108]
【The invention's effect】
According to the method of ejecting the liquid of the present invention, it is possible to eject the liquid at a large ejection distance and ejection amount simply by rotating the stirring shaft, and the ejected liquid causes the inner peripheral surface of the tank peripheral wall to be ejected. Cleaning, securing of the heat transfer area and cleaning of the heat transfer surface are facilitated, and together with these, it can be used for defoaming the foam layer and evaporating the liquid on the liquid surface and mixing the two liquids.
[Brief description of the drawings]
FIG. 1 shows a plurality of bowl-like bodies in which each bowl-like body is fixedly attached to a stirring shaft by a fixture.
FIG. 2 shows an example of a bowl-shaped body.
FIG. 3 shows another example of a bowl-shaped body.
FIG. 4 shows a symmetrical cross-sectional shape in the opening of a bowl-shaped body.
FIG. 5 shows an asymmetric cross-sectional shape in the opening of the bowl-shaped body.
FIG. 6 shows an upper opening of a bowl-shaped body covered with a perforated plate.
FIG. 7 shows an upper opening of a bowl-shaped body covered with a plate body with a gap along the inner peripheral surface of the upper opening.
FIG. 8 shows a bowl-like body provided with a reflection plate spaced apart from the upper opening.
FIG. 9 is a drawing for explaining a deflection angle of a bowl-shaped body.
FIG. 10 is a perspective view of a bowl-like body that is rotatably mounted on a stirring shaft.
FIG. 11 shows a rod-shaped body whose inclination angle can be adjusted by a vertical method.
FIG. 12 shows a bowl-shaped body whose inclination angle can be adjusted by a lateral method.
FIG. 13 shows a bowl-shaped body that can be bent.
FIG. 14 shows a bowl-shaped body that is made to be extendable and contractible.
FIG. 15 shows two opposing rod-shaped bodies integrated with a plate body that is a flat structure.
FIG. 16 shows two opposing rod-shaped bodies integrated with a plate body that is a flat structure.
FIG. 17 shows two opposing rod-shaped bodies integrated with a plate body that is a flat structure.
FIG. 18 shows two opposing rod-shaped bodies integrated with a plate body that is a flat structure.
FIG. 19 shows a bowl attached eccentrically.
FIG. 20 shows a bowl mounted eccentrically.
FIG. 21 shows a rod-shaped body perforated in an arbitrary intermediate portion of a portion corresponding to a liquid flow path.
FIG. 22 shows a rod-shaped body perforated in an arbitrary intermediate portion of a portion corresponding to a liquid flow path.
FIG. 23 is a longitudinal sectional view of a stirring tank having a bowl-like body mounted therein.
FIG. 24 is a longitudinal sectional view of a flask in which a rod-like body is mounted.
FIG. 25 shows a bowl-like body that is slidably mounted on the stirring shaft by means of an attachment that also serves as a float.
FIG. 26 shows a plurality of hooks attached to one fixture.
[Explanation of symbols]
1 rod
11 Bottom opening
111 Open end
112 Open end
113 Lower support
114 Lower support rod
12 Top opening
121 Open end
122 Open end
123 Upper support
124 Upper support rod
125 butterfly screw
13 Open end
14 Open end
15 Open edge
16 Extension end
17 Open edge
18 gap
19 Holder
2 Fitting
21 Central ring
22 Plate
221 Lower fitting
2211 hole
222 Upper fitting
2221 hole
23 Holder
24 Fixture
25 Fixture
26 Float
27 Float
28 Central ring
281
29 Support rod
3 Stirring shaft
31 Slide ring
311 butterfly screw
32 Rotating ring
321 Rotating axis
322 holes
323 Butterfly Screw
33 groove
34 Stopper
4 perforated plate
41 small hole
42 holes
5 plate
6 Reflector
61 Contact
7 Rod
71 Butterfly board
72 Linkage
73 Connecting rod
74 holes
741 Blowout pipe
8 Rod
81 Lower piece
812 dowel pin
82 Middle piece
821 bulge
822 knock pin
823 knock pin hole
83 Upper piece
831 bulge
833 knock pin hole
9 Rod
91 Lower strip
912 slot
92 Intermediate
921 Knock pin
922 knock pin
93 Upper piece
932 slot
10 plate
101 rod
1011 Bottom opening
1012 Top opening
102 rod
1021 Bottom opening
1022 Top opening
103 Flat part
1031 hole
104 Folding part
1041 hole
105 plate
1051 folding line
106 perimeter wall
107 Ridge line
1071 hole
F Flask
J jacket
L level
M motor
T stirring tank

Claims (3)

A method of spraying a liquid in a container, cleaning an inner peripheral surface or a heat transfer surface of a peripheral wall of the container, and / or ensuring a heat transfer area of the liquid, the container having a stirring shaft and at least 1 And has a lower opening that is supported by the stirring shaft so that the lower opening is closer to the stirring shaft than the upper opening, and the lower opening sinks the lower opening in the liquid. The upper opening is exposed above the liquid level, and the concave surface is made to face the rotation direction of the rotating shaft or the rod-like body, the magnitude of the deflection angle indicating the degree of the concave surface direction is selected, and the stirring shaft raised by rotating the liquid around in the gutter body, jetting liquid from the upper opening of the gutter-like bodies, characterized in that allowed to increase the ejection distance and ejection quantity of ejected liquid from the upper opening of the gutter-like bodies How to squeeze.   2. The method according to claim 1, wherein the end of the flat structure provided on the stirring shaft facing the container peripheral wall is bent in the direction of the stirring shaft to form a bowl-shaped body.   The method of Claim 1 which attached the bowl-shaped body to the side surface of the flat structure provided in the stirring shaft.

Images