JPH04131131A - Stationary mixer - Google Patents

Abstract

PURPOSE:To provide a spiral blade in a state not almost forming a gap with respect to the inner peripheral surface of a hole by forming the spiral blade inserted in a circular hole by connecting a plurality of blade pieces having a specific shape and a specific dimension. CONSTITUTION:The spiral blade 2 inserted in the hole 1a having a diameter D of a mixer main body 1 having a length dimension L has a twist angle of 180 deg. over the range from the inlet part of the main body 1 to the outlet part thereof. The spiral blade 3 inserted in the state crossing the spiral blade 2 at a right angle has the same shape as the spiral blade 2 and each of the spiral blades 2, 3 is formed by continuously connecting six blade pieces 4 each having a diameter D and divided length (l) by welding or adhesion. The shape and dimension of each of the blade pieces 4 is determined using a specific formula. By this method, the spiral blades 2, 3 can be provided in a state not almost providing a gap with respect to the inner peripheral surface of the hole 1a of the mixer main body 1.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a static mixer for mixing fluids.

(Prior art) Generally, a static mixer has one unit in the mixer body, or
It is formed by drilling a plurality of circular holes and inserting spiral blades into the chain holes. As a static mixer with such a configuration, for example, Japanese Patent Publication No. 5336182, Japanese Patent Publication No. 55
It is described in JP-A-22135 and the like. If the diameter of the spiral blade is small (approximately 100 mm or less)
The mixer is manufactured by twisting and bending a thin plate at a predetermined angle (60° to 180°) and cutting its outer peripheral surface with a lathe or the like to a size that allows it to be inserted into a hole in the mixer main body. In addition, if the diameter is large (approximately 100 mm or more),
Manufactured by casting.

(Problem to be solved by the invention) In the former case when manufacturing the above-mentioned spiral blade, the length dimension (L) is set to L/D≧1 with respect to the diameter dimension (D) due to the twisting of the plate material. It is necessary to set it to .5. Further, bending occurs during twisting and bending cannot be done smoothly if the plate thickness is small. For these reasons, there was a problem in that there were restrictions on forming spiral blades by twisting a single plate, and only blades with a diameter (D) of about 100 mm or less could be manufactured. In the latter case, it is necessary to manufacture a wooden mold, and as the diameter increases, the wall thickness also increases, and the weight of the mixer as a whole increases. Therefore, it is necessary to make the member supporting the mixer sturdy and to have a large installation space. Furthermore, iron and stainless steel castings can only be produced with a high carbon content, and special steels such as Hastelloy cannot be produced.

(Means for Solving the Problems) In order to solve the above-mentioned problems, the static mixer of the present invention is a static mixer in which a spiral blade is inserted into a circular hole in the mixer body. The spiral blade is formed by connecting a plurality of blade pieces.

In addition, the diameter dimension (D) of the blade pieces forming the spiral blade is determined from the relationship between a) degree of mixing and pressure loss.

(Example) The relationship between the length (L) and diameter (D) of the spiral blade (L/D) based on the degree of mixing of the fluid and the size of the installation location.
Determine.

c) Determine the number of blade pieces to be divided (n>) and the divided length dimension (Il>) from the length dimension (L).

2) Draw a line (CC') with the same dimension as the diameter (D>) on the board or paper pattern that forms the wing piece, at the center point C of the word line.
D/2), draw a vertical line with the same size as the division length dimension (β) to find the point (A).

e) Radial dimension of the blade piece (D/2) centered on the meaning of the word (A)
) to draw an arc.

) Here, the spiral blade with radius dimension (D/2) is divided into a plurality of blade pieces (n, ), and the side length (b') when viewed in plan is calculated using the following formula (1) Find it by

b'= (2Xs f nθ' xD/2) ”・
・(1) θ'=θ/ 2 n θ: Twisting angle from the inlet to the outlet of the helical blade (°) B' Twisting angle of the two blade pieces (°) D: Diameter dimension of the helical blade (mm ) g) Based on the side length (b'), calculate the side length b> on the cylinder as the side length when the blade piece is viewed from the side using the following formula (2). Then, centering on the point (C) of the arc in item (e), draw an arc with side length b>, and find the point (B) that is the intersection.

b = J positive 7 lower = 17 ... (2
) The side length (b) and radius dimension (
D2・'2) and each point (A, ), (B), (C),
A circular arc (
Find f).

W) Each of the above points (A), (B), (C), (C(B')
, each line segment connecting (A) (AB) (BC), (CC')
, (C'B'), and (B'A) to cut the board or paper pattern that will form the blade piece.

J) Fold the plate material cut into the above shape so that line segment (AB) and line segment (AB') are on the same plane with the height of (12), and line segment (AC) and line segment (ACl) valley fold,
Alternatively, it can be made by folding it into a mountain and folding it in a straight line on the same plane.

Each dimension is determined and manufactured in this order.

Furthermore, the arc (f) along the inner circumferential surface of the hole of the mixer body in item g) for forming the above-mentioned blade pieces is defined as a line segment ( Point (d, ) that is the intersection on the extended line of AB) or line segment (BC)
Draw an arc of diameter (D) from point (B) or point (C) on the center line of , and draw an arc of diameter (D) from the point (B) or point (C) with the intersection of the lines (d> as the center point). This can be approximated by drawing an arc where the two intersect.

(Function) The static mixer of the present invention has a spiral blade formed by connecting a plurality of blade pieces, and is free from constraints such as the diameter dimension, the relationship between the diameter dimension and the length dimension, the twisting angle, the material, etc. This is something I tried not to do.

(Example) The configuration of one example of the static mixer of the present invention will be described based on the drawings.

Reference numeral 1 denotes a mixer main body, in which a hole 1a having a diameter (D) is bored. 2 is a spiral blade inserted into the chain hole 1a,
The length dimension <L) has a twist angle of 180° from the inlet to the outlet.

Reference numeral 3 denotes a spiral blade which is connected and inserted perpendicularly to the spiral blade 2, and has the same shape as the spiral blade 2. Details of the spiral blade 2.3 are shown in FIGS. 3 to 4.
As shown in the figure, the diameter dimension < D) and the divided length dimension (
Continuously welding six blade pieces 4 made of I-ri, or
They are connected by adhesive or the like. And the blade piece 4
The shape is as shown in FIGS. 5 to 7, and each dimension is determined in the following order.

First, the diameter dimension (D) is set to 695 from the relationship between mixing degree and pressure loss.
mm, the length of the blade (L>1032) nm based on the mixing degree of the fluid and the size of the installation location, and the number (n) of the blade pieces 4 from the length (L) and workability, etc. The divided length dimension (ρ) is determined to be 172 mrn.

Here, as shown in Fig. 8, a circle with a diameter (D) of 695 mm is drawn when the spiral blade is viewed from above, and this is divided into six blade pieces with side length (b' ) is calculated using the following formula.

b' = (2xsin θ'
5/2) = 1.79.9 mm Next, as shown in Fig. 10, on the board or paper pattern forming the blade piece 4, draw a line (CC') of 695 mm, which is the same dimension as the diameter dimension (D>). ), draw a vertical line of 172 mm, which is the same as the dividing length dimension (2), at the center point of the word line to find the point (A). Then, draw the blade piece 4 with the chain point (A) as the center. 347, which is the radius dimension (D/2) of
, 5mm, and based on the above-mentioned side length (b') of 179.9mm, the side length on the cylinder as shown in Figure 9 when viewed from the side. The side length (b) is determined by the following formula.

b= b'''-1 ffi: 172mm b= 179.92+1722 =248.9mm When the side length (b) is calculated using the above calculation, the 10th
Draw an arc of 248.9 mm, which is the side length dimension (b), centering on point (C) in the figure, and point (B) that is the intersection point.
).

When cutting the circumferential surface of the spiral blade 2.3 or the contact surface at the hole 1a of the mixer main body 1, the short axis dimension (D) is 695 mm and the long axis dimension (100 mm) as shown in FIG. "!L') has an elliptical shape of 1244.2 mm. Therefore, the side length (b) mentioned above is 248°9 mm, the radius dimension (D/2) is 347.5 mm, and each point (A) The short axis dimension (D) connecting , (B) and (C) is 695 mm and the long axis dimension (n hundred]) 1
The mixer body 1 is made from an oval shape of 244.2 mm.
Find the arc (f) along the inner peripheral surface of the hole 1a.

And each of the above points (A), (B), (C), (C')
, (B'), each line segment (AB) (BC), (
The board material or paper pattern that will form the blade piece 4 is cut along the lines CC'), (C'B'), and (B'A). If the spiral blades 2.3 of the plate material cut into the above-mentioned shape are cut out of stones, then line segment (AB) and line segment (AB') or (ρ
) and fold it so that it is on the same plane as the height of the line segment (AC
), the line segment (AC') is folded into a valley, and the blade piece 4 is formed by folding the line segment (AC') into a straight line on the same plane. When the spiral blade 2.3 is twisted to the right, the line segment (AB) and the line segment (AB') are bent so that they are on the same plane at the height of (I), and the line segment (AC> is bent in a valley. , the line segment (AC') is bent into a mountain shape and bent so that they are in a straight line on the same plane.When six of these blade pieces 4 are manufactured, they are welded as shown in Figures 3 and 4. Connect by gluing, riveting, screwing, etc.

Another embodiment of manufacturing the blade piece 4 forming the spiral blade of the present invention will be described based on FIG. 12 of the drawing.

The drawing is made in the same way as the developed view of the blade piece 4 in FIG. 10 above, and the arc (f) along the inner peripheral surface of the hole in the mixer body is
Point (d) which is the intersection point on the extension of line segment (A, B) on the center point of line segment (BC), or point (B) or point (C) on the center line of line segment (BC). ) from the diameter dimension (D
It can be determined approximately by drawing a circular arc >, and then drawing an arc where points (B) and (C) intersect, with point (d), which is the intersection of the lines, as the center point.

The blade pieces 4 obtained by this method are connected to form a spiral blade 2.
．． 3 was able to obtain a product with a shape almost the same as that of the spiral blade 2.3 obtained in the first example.

(Effects of the Invention) The static mixer of the present invention is a static mixer in which a spiral blade is inserted into a circular hole in a mixer main body, in which the spiral blade is connected to a plurality of blade pieces. Since it is formed by the above, it is possible to easily obtain a static mixer with spiral blades inserted therein, which is not limited by the diameter, the relationship between the diameter and length, the twisting angle, the material, etc.

The static mixer according to claim 1, wherein the blade pieces forming the spiral blade are manufactured by determining each dimension in the following order.

b) Determine the diameter dimension (D) from the relationship between mixing degree and pressure loss.

(1) The relationship between the length (L) and diameter (D) of the spiral blade is determined from the mixing degree of the fluid and the size of the installation location (1, /D).
Determine.

c) Determine the number of divided blade pieces (n) and the divided length (fl) from the length dimension (L).

2) Draw a line (CC') of the same size as the diameter (D) on the board or paper pattern forming the wing piece, and draw the center point of the word line (
D/2), draw a vertical line with the same size as the division length dimension (P) to find the point (A).

e) Radial dimension of the blade piece (D/2) centered on the chain point (A)
) to draw an arc.

) Here, the spiral blade with radius dimension (D/2) is divided into a plurality of (n) blade pieces, and the side length when viewed in plan is (
b') is determined by the following formula (1).

1)'= (2XS i nθ'xD/2 )-= (
1) θ'=θ/'2n θ: Twisting angle from the inlet to the outlet of the helical blade (°) θ' Twisting angle of the two blade pieces (°) D = Diameter of the helical blade (mm) Based on the side length (b'), the side length (b) on the cylinder is determined by the following formula (2) as the side length when the blade piece is viewed from the side. Then, draw an arc with the side length (b) centering on the point (C) of the arc in item e), and find the point (B) that is the intersection.

b=, E7 device F...(2) And,
Centering on point (C) of the arc in term e), the side length (
Draw the arc of b) and find its intersection point (B).

h) Side length (b) and radius dimension (D
/2 >, each point (A), (B), (C), the short axis dimension (D) and the long axis dimension (, 1 tear; T1) from the elliptical shape of the mixer main body 1. An arc along the inner peripheral surface of the hole 1a<
Find f).

W) Each of the above points (A), (B), <C), (C') (θ
′), (A), each line segment (AB), (BC>, (CC
), (C'B'), and (θ'A).

N) Fold the plate material cut into the above shape so that line segment (AB) and line segment (AB') are on the same plane with the height of (2), and line segment (AC) and line segment (AC' ) are valley-folded or mountain-folded and folded so that they are in a straight line on the same plane.

By determining each dimension and manufacturing in this order, it is possible to obtain a static mixer in which the spiral blades are inserted into the inner peripheral surface of the hole of the mixer main body with almost no gap.

Furthermore, the arc (f) along the inner circumferential surface of the hole of the mixer body in item g) for forming the above-mentioned blade pieces is defined as a line segment ( The diameter dimension (
Draw an arc of D>, and draw an arc that intersects points (B) and (C) with the intersection point (d) of the lines as the center point to approximately obtain the work. It can be done quickly.

[Brief explanation of the drawing]

FIG. 1 is a schematic front view showing one embodiment of the static mixer of the present invention. FIG. 2 is a z-z cross-sectional view in FIG. 1. FIG. 3 is a schematic front view showing one embodiment of the spiral blade constituting the static mixer of the present invention. FIG. 4 is a schematic side view of FIG. 3. FIG. 5 is a schematic front view showing one embodiment of a blade piece forming a spiral blade. FIG. 6 is a schematic side view of FIG. 5. FIG. 7 is a schematic plan view of FIG. 5. FIG. 8 is a schematic plan view of a spiral blade divided into a plurality of blade pieces. FIG. 9 is a schematic diagram showing divided blade pieces of a spiral blade on a cylinder. FIG. 10 is a developed view showing one embodiment of a blade piece forming a spiral blade of the present invention. FIG. 11 is a schematic view showing the cross-sectional shape of the surface of the spiral blade that comes into contact with the inner peripheral surface of the hole in the mixer body. FIG. 12 is a developed view showing another embodiment of the blade piece forming the spiral blade of the present invention. 1: Mixer body, 4: Blade piece, 2゜: Spiral blade,

Claims (1)

[Claims] 1) In a static mixer in which a spiral blade is inserted into a circular hole in a mixer main body, the spiral blade is formed by connecting a plurality of blade pieces. Characteristic static mixer. 2) The static mixer according to claim 1, wherein the blade pieces forming the spiral blade are manufactured by determining each dimension in the following order. b) Determine the diameter dimension (D) from the relationship between mixing degree and pressure loss. b) Determine the relationship (L/D) between the length dimension (L) and diameter dimension (D) of the spiral blade from the mixing degree of the fluid and the size of the installation location. c) Determine the number of blade pieces to be divided (n) and the divided length dimension (l) from the length dimension (L). d) Draw a line (CC') with the same dimension as the diameter (D) on the board or paper pattern forming the blade piece, and mark the center point of the line (CC').
D/2), draw a vertical line with the same size as the division length dimension (l) to find the point (A). e) The radius dimension of the blade piece (D/2) centered on the point (A)
) to draw an arc. F) Here, the spiral blade with radius dimension (D/2) is divided into a plurality of (n) blade pieces, and the side length (b
') is determined by the following formula (1). b'=(2×sinθ'×D/2)...(1)θ'
= θ/2n θ: Twisting angle (°) from the inlet to the exit of the helical blade θ′: Twisting angle of the blade piece (°) D: Diameter dimension of the helical blade (mm) G) Length of the side ( Based on b'), calculate the side length (b) on the cylinder as the side length when the blade piece is viewed from the side using the following formula (2), and then calculate the point (e) of the arc in term e). Draw an arc with the side length (b) centered on C), and find the point (B) that is its intersection. b=√b'^2+l^2...(2) H) Side length (b) and radius dimension (D
/2), each point (A), (B), (C), and the short axis dimension (
D) and the long axis dimension (√D^2+L^2), an arc (f
). li) Each of the above points (A), (B), (C), (C'), (
Each line segment (AB), (BC), (C
Cut the wing piece or paper pattern along C'), (C'B'), and (B'A). N) Fold the plate material cut into the above shape so that line segment (AB) and line segment (AB') are on the same plane at the height of (l), and then cut line segment (AC) and line segment (AC' ) are valley-folded or mountain-folded and folded so that they are in a straight line on the same plane. 3) The stationary device according to claim 2, characterized in that the blade piece of the spiral blade is formed by approximately determining an arc (f) along the inner peripheral surface of the hole 1a of the mixer main body 1 as described below. mold mixer. n) Point (d) which is the intersection on the extension of line segment (AB) on the center point of line segment (BC), or point (B) or point (C) on the center line of line segment (BC). ) from the diameter dimension (D)
This is determined by drawing a circular arc, and using the intersection point (d) on the line as the center point, draw an arc where points (B) and (C) intersect.