KR0171654B1 - Method and apparatus for feeding liquid into tank without foaming and tank equipped therewith - Google Patents

Abstract

OBJECT Provides a tank having a liquid supply device capable of supplying a large amount of liquid quickly and suitable for supplying a high viscosity liquid without requiring expensive equipment or a special device.

The constituent tank 1 is provided with the liquid supply apparatus 2 inside.

The anti-foaming mechanism is composed of a liquid guide member 3 having a descending slope, a blocking member 4 on an upward wall, and a flow path forming member on a downward wall as a material having a thin thickness as a whole.

The liquid guide member 3 has the upper center of the tank 1 as the vertex c, and extends inclined downward slowly just before the tank inner peripheral wall surface 1A. The plate-shaped blocking member 4 extends upward from the cutout end of the liquid guide member 3, and the wall flow path forming member 5 extends downward from the lower end of the liquid guide member.

The liquid supply device 2 is fixed to be movable horizontally to a mounting stay installed on the tank inner circumferential wall surface 1A via a mounting portion having a long circular mounting hole, and an annular support member 10 protrudes below the tank inner circumferential wall surface. have.

Description

A method for supplying a liquid to a tank without forming bubbles, a device used therein, and a tank provided with the device.

1 is a perspective view showing a temporary embodiment of a liquid supply apparatus according to the present invention.

2 is a plan view of a tank having the liquid supply device shown in FIG.

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a plan view of a tank having a liquid supply different from that of FIG.

5 is a plan view of a tank having a liquid supply device different from FIGS. 2 and 4;

FIG. 6 is a cross-sectional view taken along the line A-A in the case of having a cross section different from that of FIG. 2 in a tank including a liquid supply device having the top view shown in FIGS.

FIG. 7 is a cross-sectional view along the line A-A having a cross section different from FIGS. 2 and 6. FIG.

8 is a cross-sectional view taken along the line A-A having a cross section different from those in FIGS.

9 is a cross-sectional view taken along the line A-A having a cross section different from those in FIGS.

10 is a cross-sectional view along the line A-A having a cross section different from the second, six, seven, eight, and nine degrees.

11 is a cross-sectional view taken along the line A-A having a cross section different from the second, six, seven, eight, nine, and ten degrees.

12 is a cross-sectional view taken along the line A-A having a cross section different from the second, six, seven, eight, nine, ten, eleven.

* Explanation of symbols for the main parts of the drawings

1: Tank 1A: Tank inner peripheral wall

2: liquid supply device 3.3 ': liquid guide member

4.4 ': Blocking member 5.5': Channel forming member

6A, 6B: Mounting hole 7A, 7B: Mounting hole

8A, 8B: Mounting stay 9A, 9B: Mounting bolt

10: round bar support member 11: liquid

The present invention relates to a method for supplying a liquid without forming bubbles, an apparatus used therein, and a tank provided with the apparatus.

Some liquids are reluctant to generate bubbles such as coating liquids, detergents or foods.

In order to prevent bubbles from being generated when these liquids are put in the tank, for example: ① Slowly add the liquid slowly along the wall of the tank. ② Install the liquid supply pipe in the tank, fill the pipe with liquid (with air removed) and put it directly into the liquid in the tank. ③ After the liquid is put into the tank, the generated bubbles are removed with a defoaming device. Such means are known.

However, the means of (1) has the drawback that it takes too long when a large amount of liquid is put in a tank.

Further, the means of (2) not only takes time to fill the liquid in the liquid supply pipe, but also has a drawback that a back pressure facility such as a pressure for putting the liquid into the tank is required. The means (3) need not only expensive equipment called degassing apparatus, but also tanks cannot be used during degassing, and defoaming is difficult and time consuming when high viscosity liquids are added.

Other proposals for defoaming by using ultrasonic waves or centrifugal force, etc., but these have the drawback that excessive cost is required to install the equipment.

In order to solve the above-mentioned problem, Unexamined-Japanese-Patent No. 2-19808 has proposed the apparatus which provides a barrier in the liquid drop part in a tank at the time of supplying liquid to a tank, and prevents the bubble at the time of liquid drop. The above apparatus can supply a large amount of liquid rapidly, but since the liquid after passing through the barrier becomes turbulent and is supplied to the tank, not only some bubbles occur in the liquid after passing through the barrier, but also bubbles in the liquid supplied to the barrier. It is also difficult to remove it, so it cannot be said to be a satisfactory anti-foaming liquid supply device.

[0003] In Japanese Patent Application Laid-Open No. 1-379876, a liquid supply apparatus is provided in which a liquid guide member having a curved upper surface is deposited so as to be deposited in the liquid in a tank, and a liquid supply pipe is disposed above the guide member. In this device, it is possible to prevent foaming due to the scattering of the supply liquid, but since the liquid flowing down the liquid guide member is in turbulent flow, bubbles are not only generated at a high flow rate, but also it is impossible to remove bubbles in the supplied liquid. Therefore, it cannot be said that it is a satisfactory bubble preventing liquid supply device.

The present invention eliminates the above-mentioned drawbacks, does not require expensive equipment or special equipment, and can supply a large amount of liquid quickly without foaming, and also supplies a high viscosity liquid even when a low viscosity liquid is supplied. It is an object of the present invention to provide a liquid supplying method suitable for use at the time, an apparatus used therein, and a tank provided with the apparatus.

As a result of intensive studies to achieve the above object, the present invention finds that bubbles are not formed when the liquid is supplied to the tank in a laminar flow state, and the present invention is completed based on the results. That is, according to the invention, in the method of supplying a liquid to the tank, the tank inner circumference is provided by supplying the liquid to an upper portion of the descending slope extending near the tank inner circumferential wall surface and causing the liquid to flow along the descending slope. A liquid supply method is provided for the purpose of flowing a team between a wall surface and a flow path forming member disposed while forming a gap along the inner circumferential wall in a laminar flow state.

Further, according to the present invention, the liquid guide member having a lowered slope extending from a predetermined height position at the center of the tank to the vicinity of the inner circumferential wall surface of the tank, and a flow path forming member extending downward from the lower end of the liquid guide member. And a liquid supply device characterized in that it is configured as such.

According to the present invention, the liquid guide member includes a cutout portion and a blocking member extending upward from an end portion of the cutout portion, and at the same time, the gap between the flow path forming member and the tank inner circumferential wall is adjustable. There is provided a liquid supply apparatus mounted to a support via a member.

Further, there is provided the liquid supply apparatus, characterized in that the average inclination angle of the liquid guide portion is 5-10 °, and the portion is formed in a conical shape or in a bulging upward shape.

Further, in the tank provided with the liquid supply device, a tank is provided, wherein a support member is provided on the lower end face of the flow path forming member of the liquid supply device so as to perturb, so that the support member is preferably a round bar. .

In the apparatus according to Claims 2 and 3, the supply liquid flows slowly without generating liquid droplets dispersed above the liquid guide member having the inclined slope, and the gap formed in the flow path forming member and the tank inner circumferential wall, etc., flows in the laminar flow state to the tank Since it is accommodated inside, it is possible to accommodate a large amount of liquid into the tank smoothly in a short time without the formation of bubbles without requiring special devices or facilities such as a defoaming device or a back pressure device.

In the apparatus according to claim 4, the gap between the flow path forming member and the tank inner peripheral wall can be easily adjusted, so that the gap is set to an optimum value corresponding to the viscosity, quantity, or the like of the liquid to be accommodated. Therefore, it is possible to effectively supply a large amount of liquid in a short time.

In the apparatus according to claim 5, no bubbles are generated on the liquid guide member when the liquid flow rate is excessively slow, and bubbles are not generated even when the liquid flow rate is too fast. It is possible to receive liquid into the tank without generating it.

In the apparatus of Claims 6 and 7, the liquid supplied to the liquid guide member flows down the member phase evenly, respectively, to reach the gap, and the amount of liquid that flows down by the formation place of the gap is not significantly changed. Since there are no angles or protrusions on the surface of the liquid guide member, bubbles do not occur on the liquid guide member even when the liquid supply speed is increased, so that the liquid can be accommodated in the tank smoothly.

Since the tank of Claim 8 is equipped with the said liquid supply apparatus, it is a tank which can supply a large amount of liquid quickly, without forming a bubble.

Since the tank according to claim 9 has a support member which is in a perturbable contact with the liquid supply device, it is possible not only to support the liquid supply device without trouble but also to easily move the liquid supply device for adjusting the gap. It's a tank.

In the tank according to claim 10, since the support member on the round bar contacts the lower part of the liquid supply device in smooth line contact, the device is moved horizontally to support the weight of the liquid supply device and to adjust the gap clearance. Since it is also used as a guide, the slide gap can be adjusted smoothly without contacting the liquid even in a narrow tank by simply sliding it without lifting the liquid supply device.

EMBODIMENT OF THE INVENTION Hereinafter, although one Example of this invention is described in detail based on drawing, this invention is not limited by this Example.

1 is a perspective view showing an example of a liquid supply apparatus of the present invention, and FIG. 2 is a plan view showing an example of a tank provided with a liquid supply apparatus. 3 shows sectional drawing which cut | disconnected FIG. 2 with the A-A line | wire.

The tank 1 of this embodiment is a liquid storage tank and has a liquid supply device 2 therein. The liquid supply device 2 comprises a liquid guide member 3 composed of a semi-conical inclined portion, a blocking member 4 composed of a plate vertical wall portion, and a vertical wall portion having a semicircular horizontal cross section, as shown in FIG. It is comprised as the flow path forming member 5. The liquid supply device 2 is a device having a liquid guide member 3 having a cutout of 180 ° in plane angle. That is, when the liquid guide member 3 covers the entire tank upper surface, no cutout exists, and when half of the tank upper surface is covered by the member, the cutout portion having a plane angle of 180 ° is present. Therefore, when only 150 degrees of the tank upper surface as the planar angle is covered with the liquid guide member 3, a cutout of 210 degrees exists as the planar angle.

It is preferable that the liquid supply device 2 is formed as a lightweight, inexpensive, strong, thin thickness material, and as a suitable material for forming the device, a synthetic resin plate which does not react with the liquid to be supplied and does not dissolve in the liquid. , Metal plates or various laminated boards are preferable.

The liquid guide member 3 of this embodiment is a liquid guide member of a type in which the conical surface is divided in two in the longitudinal direction, and as shown in FIGS. 1 and 3, the upper center of the tank 1 is referred to as the vertex c. The lower end portion is gently inclined downward and extends to the vicinity of the tank inner circumferential wall surface 1A. The downward inclination angle a is set to 5-10 degrees. When a is less than 5 °, liquid droplets are generated on the liquid guide member 3, and when liquid flows into the droplets, air is mixed to easily generate bubbles. In addition, when a exceeds 10 °, bubbles are also easily generated because the flow velocity of the liquid flowing along the liquid guide member 3 is too fast.

From the lower end part 3c of the liquid guide member 3, the flow path forming member 5 which consists of a semicircle of a horizontal cross section and extends downward is provided. The boundary between the liquid guide member 3 and the flow path forming member 5 is such that angles or projections are not formed so that the flowing liquid becomes turbulent and bubbles are not formed. That is, this portion is formed to have a round shape so that the liquid flows smoothly.

The gap between the flow path forming member 5 and the tank inner circumferential wall surface 1A is an important part for making the flowing fluid into the laminar flow state, and if the gap gap t is too wide, the liquid flows into the laminar flow state. If the gap t is too narrow, it is difficult to flow a large amount of liquid rapidly. Therefore, it is preferable to set the clearance gap t to an optimal value in view of the viscosity and specific gravity of the liquid flowing down.

When the high viscosity liquid flows down, the gap is set to 5 to 20 mm, preferably 8 to 12 mm, and when the low viscosity liquid flows down, the gap is 3 to 15 mm, preferably 5 to 8 mm. It is good to do. In addition, if the length of the gap gap portion (length shown in FIG. 3) is too short, it is difficult to bring the liquid flowing down into the laminar flow state. Therefore, when the high viscosity liquid flows down, the length of the gap gap portion is 30 mm or more, preferably Is 50 mm or more, and when the low-viscosity liquid flows down, the length is preferably 50 mm or more, preferably 80 mm or more. In addition, when the gap between the lower end of the gap and the tank bottom is too long, bubbles are likely to occur, so the length of this part is preferably as short as possible.

From the end parts 3a and 3b of the cutout part of the liquid guide member 3, the plate-shaped blocking member 4 extends upwards. The blocking member 4 is a member which prevents the liquid supplied on the liquid guide member 3 from falling from the cutout to the tank, and prevents the liquid from overflowing or splashing into the droplets. Doing. In addition, the mounting portions 6A and 6B extend in the horizontal direction from both upper ends of the blocking member 4, and the mounting portions 6A and 6B have long circular mounting holes 7A, respectively ( 7B) is formed.

On the other hand, in the upper part of the inner peripheral wall surface 1A of the tank 1, as shown from FIG. 2 and FIG. 3, the mounting stays 8A and 8B for attaching the liquid supply apparatus 2 are provided, In the mounting stays 8A and 8B, screw holes (not shown) corresponding to the mounting bolts 9A and 9B are formed. Then, the mounting bolts 9A and 9B are loosened and the liquid supply device 2 is moved so that the clearance gap t becomes a desired value. Then, when the mounting bolts 9A and 9B are fastened, the clearance gap t It is possible to adjust).

At a position corresponding to the center of the lower end portion of the flow path forming member 5, a round bar-like support member 10 protrudes from the lower portion of the tank inner peripheral wall surface 1A in the horizontal direction, which supports the liquid supply device 2. At the same time, it is used as a guide when the liquid supply device 2 is moved. In addition, 11 in a figure shows the accommodated liquid.

The operation of the above embodiment will be described below.

Before supplying the liquid, the mounting bolts 9A and 9B are loosened to adjust the horizontal position of the liquid supply device 2 (the position in the left and right directions in FIG. 2), and accordingly, the tank inner peripheral wall surface 1A. After adjusting the clearance gap t with the flow path forming member 5 to an appropriate value, the mounting bolts 9A and 9B are fastened. At the time of adjusting the gap, the lower end portion of the flow path forming member 5 under the liquid supply device 2 is in direct contact with the annular support member 10 protruding from the tank inner peripheral wall surface 1A. Therefore, the support member 10 supports the weight of the liquid supply device 2 and acts as a guide in the case of moving the device in the horizontal direction for gap formation without lifting the liquid supply device 2. By simply sliding, it is possible to perform a minute adjustment without touching the liquid in a narrow tank. When the rod is used for the supporting member 10, the surface contact or the edge contact causes slipper operation to be worse than that of the round rod, which makes it more difficult to adjust the gap.

After adjustment of the clearance gap t, the liquid to be accommodated is supplied near the apex c of the liquid guide member 3 of the liquid supply device 2. At this time, it is possible to employ a conventionally known means as the liquid supply means. The supplied liquid flows downward along the inclined surface of the liquid guide member 3, but at this time, since the liquid guide member 3 is formed in a semi-conical shape, the supplied liquid does not concentrate on a part of the member 3. Since it is suitably dispersed in the circumferential direction, and furthermore, the inclination angle a of the member 3 is set to 5-10 °, no droplet is formed on the liquid guide member 3 and an appropriate flow rate is achieved. Will flow downward. Therefore, there is no mixing of air due to concentration of the supplied liquid or mixing of air due to the generation of liquid droplets, thereby preventing the generation of bubbles.

Further, the liquid that has flowed down to the lower end of the liquid guide member flows into the tank between the flow path forming member 5 and the tank inner peripheral wall surface 1A stably in a laminar flow state.

The liquid flowing down on the liquid guide member 3 flows down from the lower end of the member 3 to the gap gap, but dissipates more than half of the bubbles contained in the liquid flowing down when changing the direction. It is possible. The liquid, which contains almost no bubbles, flows down to fill the gap and becomes laminar at this point. Therefore, even if bubbles are included in the supplied liquid, bubbles are hardly contained in the liquid contained in the tank 1.

Further, since the plate-shaped blocking member 4 is provided in the liquid supply device 2, the side opposite to the installation portion of the liquid supply device 2 in FIG. 1 when the supply liquid collides with the liquid guide member 3 is provided. Since the liquid into the furnace is not scattered, bubbles are also prevented from being generated due to the scattering of the liquid, so that the generation of bubbles can be prevented very effectively.

As mentioned above, although demonstrated based on one Example of this invention, this invention is not limited to the said Example, A various deformation | transformation and a change are possible. For example, the container shape may be an octagonal cylinder shape or a hexagonal cylinder shape, and the liquid guide member may form an X-shaped curved surface upward.

Modifications will be described below.

4 and 5 are plan views corresponding to FIG. 2, and the cutouts provided in the liquid guide member 3 of the liquid supply device 2, as shown in the drawing, have a plane angle B of 180 degrees. Less than (FIG. 4) or 180 degrees or more (FIG. 5) may be sufficient.

The plane angle B of the cutout portion is preferably 120-240 °, preferably 160-210 °.

6 to 12 are cross-sectional views corresponding to FIG. 3, and in FIGS. 6, 8, 10, and 12, the liquid guide member 3 'is formed to have an upward curved surface. That is, the liquid guide member is formed so that the liquid flows smoothly, and may be any shape. However, since bubbles are generated when the liquid flow velocity is high when projections or angles are present on the surface of the member, the surface is preferably smooth to the extent that foaming can be prevented.

7, 8, 11, and 12, the blocking member 4 'is formed in an inclined shape different from the blocking member described in the above embodiment.

Such a blocking member may not be formed as a plate-shaped vertical wall portion, or may be inclined, curved, or wrinkled if the supplied liquid is formed so as not to overflow or scatter.

Claim 9 is also in to 12 also has a flow path forming member (5 ') inclined, that because of the gap the gap formed between the member and the tank inner wall surface (1A) to t ₂ in the upper portion, the lower the narrower than t ₂ t ₁ . Thus, although the flow path forming member may be inclined, it is necessary to satisfy the requirements for forming the laminar flow state described above, and if a portion having a gap gap in the above range is provided in the length, t ₂ is larger than the gap gap. It may be wide. However, t ₁ needs to be in the range of the gap.

As described above, the planar state of the tank can be configured in any shape such as hexagonal or octagonal as well as circular shape. Since the liquid guide member 3 is formed so as to have the clearance gap even when the tank is formed in any shape, when the conical liquid guide member 3 is used when a tank other than a circular shape is used, the lower end thereof is used. The height of is different depending on the place. However, if the downward inclination angle a of the liquid guide member 3 uses a liquid guide member having a slightly different surface according to the place, it is possible to equalize the heights of the lower end portions, respectively. In addition, even if the height of the lower end of the liquid guide member is slightly different, there is no particular problem, and it is possible to allow a large amount of liquid to flow down without foaming.

According to the present invention, it is possible to provide a tank having a liquid supply device which can supply a large amount of liquid quickly without requiring expensive equipment or a special device, and is also suitable for supplying high viscosity liquids. In addition, by adopting a configuration for fixing the liquid supply apparatus so as to be movable in the horizontal direction, it is possible to easily adjust the clearance gap between the flow path forming member and the tank inner circumferential wall surface. Liquid supply is possible.

In addition, since the supporting member contacts the lower part of the liquid supply apparatus by smooth line contact by providing a round bar-like support member at the lower part of the inner wall of the tank, it is possible to support the weight of the liquid supply apparatus and to adjust the gap gap at the same time. When the device is moved, it also acts as a guide in the horizontal direction, and simply slides the device without lifting the device, so that minute adjustments can be made smoothly without touching the liquid even in a narrow tank.

The tank provided with the liquid supply apparatus of this invention can be used suitably as a coating tank for apply | coating a photosensitizer and a heat sensitive agent as an attendant method. Moreover, it is possible to use suitably as a tank for magnetic liquid coating in the tank for antirust coating by the immersion method. In addition, it is possible to use suitably for the application | coating tank or adhesive paste coating tank which uses the viscosity liquid of 0.4-500 poise aqueous or oily liquid as a coating agent, or the storage tank of liquid medicine, food, etc.

Claims (11)

In the method of supplying the liquid 11 to the tank 1, the tip is supplied with the liquid to the upper portion of the descending slope extending near the tank inner circumferential wall surface 1A, and the liquid flows along the descending slope. And flowing a gap between the tank inner circumferential wall surface (1A) and a flow path forming member (5) disposed with a gap along the inner circumferential wall surface (1A) in a laminar flow state. A liquid guide member 3 having a descending slope extending near the tank inner circumferential wall surface 1A, with the predetermined height position at the center of the tank 1 as the vertex C, and the lower end of the liquid guide member 3. And a flow passage forming member (5) extending downward from the liquid supply apparatus. The liquid supply apparatus according to claim 2, wherein the liquid guide member (3) has a cutout portion and a blocking member (4) extending upwardly from an end of the cutout portion. 4. A liquid supply apparatus according to claim 3, wherein a blocking member (4) is attached to the support so that the clearance gap between the flow path forming member (5) and the tank inner peripheral wall surface (1A) is adjustable. The liquid supply apparatus according to any one of claims 2 to 4, wherein the average inclination angle of the liquid guide member (3) is 5-10 degrees. The liquid supply device according to any one of claims 2 to 4, wherein the liquid guide member (3) is formed in a conical shape. The liquid supply apparatus according to any one of claims 2 to 4, wherein the liquid guide member (3 ') is formed in a curved shape which bulges upward. Tank provided with the liquid supply apparatus 2 in any one of Claims 2-4. The tank according to claim 8, wherein a support member (10) for perturbating contact with the lower end face of the flow path forming member (5) of the liquid supply device (2) is provided. 10. The tank according to claim 9, wherein the support member (10) is formed in a round bar shape. A method of supplying a liquid to a tank, wherein the liquid is supplied to the upper part of the descending slope having an average inclination angle of 5-10 °, and the liquid is supplied into the tank by causing the liquid to flow along the slope.