JPS63232828A - Agitaing device - Google Patents

Abstract

PURPOSE:To enlarge the effective volume rate of an agitating device for e.g. viscous materials fixing paddles to revolving shafts with a distance between each paddle and fixing scrapers having the length corresponding to the above- mentioned distance to the top part of the paddles. CONSTITUTION:The material to be agitated is introduced from an inlet in a vessel 11 and is agitated by the agitating action caused by the movement of paddles 21-26, 31-36 and scrapers 41-46, 51-56 due to the driving revolution of the revolving shaft 12, 13 and is discharged from an outlet. In this case, as the volume occupied by the revolving shafts 12, 13 and the scraper 41-46, 51-56 is small and the paddles 21-26, 31-36 are fixed with a certain distance between, the effective volume rate in the vessel 11 is largely increased in comparison with the ordinary self-cleaning type agitating device.

Description

Detailed Description of the Invention <Industrial Application> The present invention relates to a stirring device for stirring and mixing substances such as high viscosity fluids, slurry-like substances, powders, etc. It is suitable for use as a desolvent device, a demonomer device, or a mixer for various raw materials in the food industry.

<Prior Art> In the chemical industry and the food industry, stirring devices are often used to mix and react substances such as high viscosity fluids, slurry substances, and powders. In order to process such substances, it is often desirable to have an apparatus that has high mixing performance, high heat transfer performance, and a function that prevents the formation of deposits, that is, a self-cleaning function.

For this reason, agitation devices having a self-cleaning function have been proposed for treating particularly strongly adhesive substances. Here, there are generally the following two types of self-cleaning methods. The first method is to install two or more rotating shafts and move the stirring bodies attached to them relative to each other and the stirring body and the inner wall of the container while maintaining a slight clearance, thereby mechanically removing the deposits. This method attempts to completely prevent generation. Also,
The second method takes into account the flow state of the material to be handled and attempts to suppress the formation of adhering substances through the shearing action of the fluid itself. However, in recent years, product quality has become more stringent in the chemical industry, and the properties of substances handled have become more diverse, so the second method described above is insufficient to prevent adhesion. In many cases, the demand for devices according to the first method is increasing.

The first method of preventing the formation of deposits by mechanical scraping has conventionally been a device in which multi-shaft screws are engaged, and a device by Todd, D., B. et al., Chea, Eay, Progr. , Vat, 65°P, 84 (1969), in which paddles with a spindle-shaped cross section (convex lens-shaped cross section) are engaged,
A multi-shaft stirring device in which paddles with pseudo-triangular cross sections are engaged is known.

<Problems to be Solved by the Invention> However, in conventional devices of this type, the volume occupied by the agitating body, such as a threaded screw installed in a container, a spindle-shaped paddle, or a paddle with a condensed triangular cross section, is too large. There was a problem in that the effective volume of the container excluding it was limited to a few percent to 60%. As a result, the total volume of the stirring device has to be large relative to the amount of material to be treated, which increases costs and makes it difficult to apply in practice.In particular, the residence time required for treatment is long. In this case, the total volume of the device for processing light becomes enormous, which is a fatal drawback in terms of device cost.

The present invention solves these problems in conventional stirring devices, and aims to provide a stirring device that can increase the effective volume ratio without impairing the mechanical self-cleaning function. There is.

Means for Solving the Problems> A stirring device according to the present invention that solves the above problems includes a plurality of rotating shafts arranged in a container and driven to rotate synchronously, and each of the rotating shafts. A stirring device comprising a plurality of paddles that are fixed to and perform a stirring action, wherein the paddles are attached to the rotating shaft at intervals in the axial direction, and the paddles are attached to the tips of the paddles at intervals approximately corresponding to the intervals. The invention is characterized in that a scraper having a length is attached parallel to the rotation axis.

Action> The paddle and scraper move within the container due to the drive rotation of the rotating shaft, and the substance to be stirred in the container is stirred and mixed. Since the paddles are spaced apart and the scraper is only provided at the tip of the paddle, they occupy a small volume within the container, thus increasing the effective volume fraction. Further, by the movement of the paddle and scraper, adjacent objects move relatively close to each other, and each part inside the container is self-cleaned.

Embodiment Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a longitudinal sectional view of a stirring device according to an embodiment of the present invention, and FIG. 2 is a sectional view taken along line n-4 in FIG. As shown in FIGS. 1 and 2, there are two rotating shafts 12.
13 are supported in parallel with each other, and each rotating shaft 12
13 are rotated in synchronization with each other in the same rotational direction and at the same rotational speed as indicated by arrows in the figure, by a drive source (not shown).

The inner wall of this container 11 has a cocoon-shaped cross section in the form of two cylindrical walls 111, 112 connected to each other, each centered on a rotation axis 12, 13.

Moreover, the rotating shafts 12 and 13 are round shafts 121° and 131°, respectively.
and a shaft cover 122,1 having an artificial bait angle cross section on its outer periphery.
32 (see Figure 2).

A plurality of paddles 21 are mounted on the rotating shaft 12 at predetermined intervals.
, 22, 23, 24, 25, and 26 are fixed. Each of the paddles 21 to 26 is formed into a thick inner plate having a spindle-shaped cross section with a bulge in the center and pointed ends.
- 26 are attached to the rotating shaft 12 along a plane orthogonal thereto, and the adjacent paddles 21 - 26 aligned in the axial direction of the rotating shaft 12 are out of phase by 90 degrees around the axis. ing. Further, each tip of these paddles 21 to 26 is arranged so that it can face the circular WJ wall 111 of the container 11 or the corresponding paddles 31 to 36 described later with a slight clearance depending on the rotational angular position thereof. Dimensions are selected.

On the other hand, a plurality of paddles 31, 32, 33, 34°35.36 having a spindle-shaped cross section are similarly fixed to the rotating shaft 13. Each paddle 31-36 is the paddle 21-36, respectively.
The paddles 26 are located at the same axial position as the paddles 21 to 26, and are attached to the rotating shaft 13 with a phase shift of 90 degrees with respect to the corresponding paddles 21 to 26, respectively. In addition, each paddle 31
36 can face the cylindrical wall 112 of the container 11 or the corresponding paddles 21 to 26 with a slight clearance depending on their rotational angular position.

Furthermore, scrapers 41 to 46 having pseudo-triangular cross sections corresponding to the cross-sectional shape of the tip portions are attached to the tip portions of the paddles 21 to 26 and 31 to 36, respectively.
．． It is fixed parallel to 13. Each scraper 41-4
6. The tip surfaces of 51 to 56 are adjacent to the paddles 21 to 26,
31 to 36 are warmer in the axial direction and are opposed to each other with a clearance in between. Each step--Pa 41-46, 51-5
6 has a similar configuration, so I will use paddle 23 as a representative.
To explain in detail, there are a total of 4 on both sides of the paddle 23.
Scrapers 43 are attached, and the tips of the paddles 23 on both sides can be opposed closely to the sides of the paddles 32 and 34, respectively. The tip twill line of each scraper 43 is located on the same line as the corresponding tip of the scraper 43, so that the tip of each scraper 43 is aligned with the rotation axis 12.
Depending on the rotational angular position of the shaft cover 132, which has a surface that is continuous with the cylindrical wall 111 of the volume vBll or the paddle 33, with a slight clearance therebetween. Also, the second
As shown in the figure, scrapers 52 and 54 attached to adjacent paddles 32 and 34 are inserted into each other between the scraper 43 and the shaft cover 122 as they rotate. The dimensions are selected so that the surface of the scraper 43 on the shaft center side and the circumferential surface of the scrapers 52 and 54 on the shaft center side are close to each other with a slight clearance.

In such a stirring device, the substance to be stirred is put into the ill from an inlet (not shown), and the paddles 21 to 26, 31 to 36 and the scrapers 41 to 46, 51 to 56 are driven and rotated by the rotating shafts 12 and 13. The liquid is stirred for a moment by the stirring action caused by the movement of the liquid, and then taken out from an outlet (not shown).

Here, as can be seen from the sectional view of FIG. 2, the rotating shaft 12.
13 and the scrapers 41 to 46 and 51 to 56 are small, and the paddles 21 to 26 and 31 to 36 are also installed at intervals, so the effective volume ratio in the container 11 can be reduced to a level similar to that of the conventional self-cleaning method. This can be significantly increased compared to other stirring devices. Incidentally, in the illustrated example, the effective volume is 70% to 75% of the total volume. Note that the effective volume ratio can be further increased by widening the mounting intervals of the paddles 21 to 26 and 31 to 36 and increasing the lengths of the scrapers 41 to 46 and 51 to 56 accordingly.

On the other hand, at the same time as the stirring action described above, each part inside the container 11 is self-cleaned by the cleaning action described below. That is, the inner wall of the container 11 has paddles 21-26, 31-3.
6 and the tip twill portions of the scrapers 41 to 46 and 51 to 56 are moved close to each other for cleaning. Further, the curved surfaces of the paddles 21 to 26 and the paddles 31 to 36 are cleaned by moving their tips close to each other. Furthermore, paddle 21~
The planar side surfaces of 26.31 to 36 and the tip surfaces of the scrapers 51 to 56.41 to 46 facing them, respectively, are cleaned by moving close to each other. For example, the planar side surface of the paddle 22 is the scraper 51.
53, and the opposing surfaces thereof are mutually cleaned. In addition, scrapers 41 to 4
6. The lunar surfaces of 51 to 56 are mutually scraped by scrapers 41 to 46,
When the comrades 51 to 56 move their tips and turns close to each other, they are cleaned together. Therefore, the rotation axis 1
2. Paddle 21~26°31~36 by x3 rotation,
The relative movement of the scrapers 41-46, 51-56 allows all surfaces within the container 11 to be completely cleaned.

Although two rotating shafts are provided in the above-described embodiment, the present invention is not limited to two, and it is also possible to provide three or more.

<Effects of the Invention> As described above with reference to one embodiment, according to the present invention, it is possible to increase the effective volume ratio of the stirring device without impairing the self-cleaning function. becomes possible.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of a stirring device according to an embodiment of the present invention, and FIG. 2 is a sectional view taken along line II-I in FIG. In the drawing, 11 is a container, 12.13 is a rotating shaft, 21-26.31-36 are paddles, 41-46.51-56 are scrapers.

Claims (1)

[Claims] In a stirring device comprising a plurality of rotating shafts arranged in a container and driven to rotate synchronously, and a plurality of paddles fixed to each of the rotating shafts and performing a stirring action, the paddles are arranged in an axial direction. A stirring device, characterized in that the scraper is attached to the rotating shaft with a spacing of .about.25 mm apart, and a scraper having a length approximately corresponding to the spacing is attached to the tip of the paddle in parallel with the rotating shaft.