JPS60153931A - Apparatus having mixing, kneading, stirring and crushing functions - Google Patents

Abstract

PURPOSE:To enable mixing and stirring, by mounting a rotary magnetic field generation apparatus surrounding the outer periphery of a main body container so as to turn a part thereof to the bottom part of said container and mounting a rotor, which receives the attracting action to the inside surface and the bottom surface of the main body container by said apparatus, in said container. CONSTITUTION:Primary magnetic flux generated from a rotary magnetic field generation apparatus 2 pierces the wall of a main body container 1 and intersects the inner cylinder 10 of a primary rotor 3 to generate secondary magnetic flux. By the mutual action of these primary and secondary magnetic fluxes, the primary rotor 3 generates right-handed rotary force around phi2 and receives right-handed rotation force around phi1 while is attracted to the inside surface and the bottom surface of the main body container 1 by a rotary magnetic field. A secondary rotor 4 is also attracted to the inside surface and bottom surface of the main body container 1 by the rotary magnetic field.

Description

[Detailed description of the invention] ? f body same 1. , or small i'+tl'.'Lll
Processing of mixing, kneading, stirring, and pulverizing relatively soft substances 1. Mechanical equipment with several sets;
In particular, it relates to a new device for power transmission mechanisms.

Conventionally, in the equipment of this building, a stirring rod was inserted into the main container containing the object to be treated, and a motor etc. was connected to this stirring rod through a mechanical coupling. −
: Ichibushiya is a type of chopstick that processes objects using tangential driving force. The present invention implements such processing using the following method:
The object of the present invention is to provide a device which allows the operation to be carried out without physical connection.

Preferred embodiments of the present invention will be described in detail below as illustrated in the accompanying drawings.

FIG. 7 is a central vertical sectional view showing the basic concept of the device of the present invention, and FIG.

This device' consists of a main body into which the object to be processed is inserted, and a rotating drive source installed to surround it.
It is composed of a pot field generator ll#'1, and primary and secondary rotors 3 and 3 placed in the main body.

The main body container is a circle + W body with 1 hole in γ, and when inverted, it has a small permeability, high electrical resistance, and is as robust as possible, such as SUS JCI'l,
, 307.

Materials such as ceramics, hard rubber, and synthetic resins are selected. Preferably,
It is preferable that there is a coating 5 on the inside 1011 of the main body container and on the inner bottom surface of the container, which is made of a ceramic material having heat dissipation and heat insulating properties.

Of course, this coating S should also have a low magnetic permeability and a high market resistance H'd.

If you feel safe, an output gate 6 is provided at the bottom of the main unit. However, in this case, the upper surface of υ [output gate B is also coated +i1. and its inner surface must form an angle of -1.14 mm with the inner side of the main container.

Ω placed within the main body without any real connection
The two cylinders, namely the primary rotor 3 and the secondary rotor, are also coated on their outer circumferential surfaces and at least on the outer surface. It is preferable to use the same inversion conditions and preferably the same inversion as the coating S of the present 1 Hontani ware.
Between 4 and 4 → to urinate the power, coating 7, g
It is better to use the surface to some extent or form a small groove for engagement in one direction.

Regarding the relationship between the inner diameter of the main body container and the outer diameter of the primary and secondary rotors 3, the outer diameter of the primary rotor 3 is equal to or slightly larger than that of the secondary rotor, and It has been experimentally found that a method in which the outer diameter and the outer diameter of the secondary rotor are somewhat smaller than the inner diameter of the main vessel l is good.

The rotating magnetic field generator is based on the same principle as Nishinomiya's 4-tatami'r (,, Tsukiniku's stator, and its A1+'i i is almost the same. Therefore, By changing the phase and frequency of the flow, it is possible to change the direction and speed of the generated rotating magnetic field.'This rotating magnetic field generator λ extends partially under the main container. , the primary rotor 3 is placed in the main container/
It acts to attract the inner full surface and inner bottom surface of the

In addition, this time, 1st year, 1st generation generator, the 7th year of the school year.
The height I'11 of the line is set lower than the height []2 of the center line of the -order rotor 3 when the bottom is in contact with the bottom of the main body container. This prevents the negative force from acting on the primary rotor 3 due to the deviation of the center line and pulling the primary rotor 3 back into the electromagnetic center of the rotating magnetic field generator, preventing the secondary rotor 3 from being lifted up by the object. can do.

The primary rotor 3, which acts as a rotor, will be explained below, corresponding to the rotating magnetic field generator λ, which acts as a stator of the motive force on the induction 1.

FIG. 3 is a view showing an example of the primary rotor 3 at the central edge 1. has a hollow structure in which the I-shape and the bottom are solidly layered with each other, and the outer periphery and one side thereof are coated with a coating 7.
The second part has a shaving pad with a 11-piece structure.

Outer 11) 9 and the following text are made of the same material as the main container /, i.e., have low magnetic permeability and electrical resistance.
It is made up of 446 parts. The middle Hio and the subsequent middle bottom have a low electrical conductivity and are good electrical conductors.
For example, copper, aluminum, etc. are formed in Toga. The cylinder// and the bottom portion following it are made of a material with a high magnetic flux of 1 (strong 1+n), such as iron.

Depending on the thickness ratio (or mass ratio) and material of the middle cylinder/0 and the inner cylinder//, the force with which the -order rotor 3 rotates and revolves and the force with which it is pulled toward the main body container/side change. . For example, the thickness of i;l+)/l (or #:I
) is too large, the next rotor 3 will receive a large attraction force from the rotating magnetic field generator, and the second rotor 3 will not rotate or
Unable to call and revolve, it tumbles 7 yaws.

On the other hand, if the thickness (or quality) of the inner cylinder is made too small, the force that extends the primary magnetic flux generated by the rotating magnetic field generator will be weakened, and therefore the inside When the number of primary magnetic fluxes that intersect with θ decreases and the rotation and revolution forces of the primary rotor 3 become uniform, the -order rotor 3 is
The inner aspect and inner jii! The ability to attract people to the bottom becomes weaker. Furthermore, if the weight (or mass) of the middle 10 is reduced, the rotational and revolving forces will be reduced.

7 to 6 show the second rotor 11M of the primary rotor 3.
! evening! 1, which has a greater rotational force and improved efficiency than the one shown in Figure 3. FIG. 9 is a plan view of the primary rotor 3, FIG. 85 is a front view, and FIG. 6 is a central sectional view 1fji.

This -order rotor 3 has an imaginary number conductor barfuge in the electromagnetic core /3 stacked around the tl/J1 shaft /2, and has a total IAI:
l K In is inserted or IP is installed, and both of these ψ1h; are connected by an end ring/S, and a φ plate with a small magnetic permeability is installed. Besides those I1. (I5- and 1 are provided with a coating 7. This is provided with a suitable upper stop plate 11/7.

In the case of rotor 3, the number of conductor bars and '(' .

It should be noted that this -order rotor J does not have the rotor upper shaft of the squirrel-cage J type IIW machine:・i? and the same (l' of η
It has i7j dragon, but in addition, 'Una:' [j: Kiwakai, Iku's setting ten, mu sentence as is) I4 is used as 'una'.
lJj 11 Gon Rod 1 - The suction force of the raw neck λ is too large, so it generally rotates. 1r in this Ib11i Shio U! ,,The mass of the single conductor bar/da is increased and the mass of the electromagnetic core/3 is decreased to obtain the optimum rotational force. In the structure of this second embodiment 1fl, the electromagnetic core /3 corresponds to the inner cylinder // and the bottom part of the first embodiment, and the conductor bar puffer and the end ring 15
corresponds to the middle cylinder IO and the following intermediate 1-hole part.

FIG. 7 is a view of one central edge showing the structure of the secondary rotor. Secondary rotor q rr1 A coating g is applied to the outer surface of the main body cylinder/g and the main body bottom plate/9. i have been Moreover, one upper space is closed with a suitable lid. Main body cylinder/g and main body bottom plate/
q is formed of high transmittance, for example, the hem. These thicknesses are also set to appropriate values, since if rq is exceeded, the suction force will become excessive, causing problems.

Next, the operation of this device will be explained with reference to the third figure. In FIG. 3, the direction of the rotating magnetic field of the rotating magnetic field generator is clockwise as indicated by the arrow -◯.

The primary magnetic flux generated by the rotating magnetic field generator passes through the wall of the main rotor, intersects with the middle cylinder 10 (or conductor bar and end ring) of the primary rotor 3, and crosses the center cylinder 10 of the primary rotor 3 (or the conductor bar and end ring).
Generate magnetic flux. The primary rotor 3 generates a clockwise rotational force (autorotation force) about φ2 due to the force action of the -order and secondary 11?1 bundles. Since the inner surface and 1 meal are drawn to 1 go, a clockwise rotation centering on φ1 is worn. Here, i:'f) / / of the -order rotor and the light-emitting core 1/1 ('electromagnetic core/3) are transparent, a
By increasing the straight weight of one arrow, the center cylinder 10 (conductor bar 7)
It acts to intersect with the ring and end ring/S.

In the secondary phase 11ii, the particles are also absorbed by the rotating magnetic field on the inner surface of the main container and IJ.

- primary and secondary rotor 3, outer circumference 1d mutually appropriate l
,,'j+, , Since the d force is 1j, the -order rotor 3 turns 1117 times, and only (from the field) the -device 1 causes the main body ``valley stagnation/111] and 11: (and When it rotates and revolves while touching, the secondary screw q also rotates counterclockwise around φ, so that it rolls on the inner 11! At this time, if the target object 2/ placed in the main container/ is at the position shown in the figure, for example, it will rotate clockwise from that position in the direction shown by the arrow. Try to exercise.

The rotation speed of the primary rotor 3 is much higher than its revolution speed, and therefore the secondary rotor q also has a higher rotation speed. For this reason, the object inside the main container l:
2/ receives a large amount of acting force from the rotation of the primary and secondary rotors 3, and becomes a flow in that direction.

Even if the direction of the rotating magnetic field of the rotating magnetic field generator is reversed, the object 2/ will be processed by the same action of the I element. When this rotating magnetic field is switched, the -order rotor 3 rotates as shown in Fig. 3,
The direction of revolution is reversed. During this 11M period, the secondary rotor 3 remains stationary at approximately the position shown in the figure, and the primary rotor 3 operates to revolve to 1ilQ, which is opposite to the position shown in the figure of the secondary rotor 3.
At this time as well, the object 2/ is subjected to the effects of mixing, crossing, arranging, or pulverizing.

Therefore, the rotating magnetic field generator λ changes the direction of the rotating magnetic field at appropriate intervals to adjust the size of the inside of the main container;
An elephant! / is due to the force 11 moving within the main container, which is subjected to the action of being caught between one rotor and the rotor and the main container throughout the vessel,
Effective mixing and other processes are further promoted.

Hereinafter, the present invention has been described in detail with reference to two practical examples thereof; however, it is not limited to these specific examples, and the scope of the present invention is How many mass transformations have occurred within the city? The force is 4″11′F!.For example, the -arrow and secondary rotor are each of medium-sized structure, but
[Processing] You can put an appropriate length of lancer inside considering the L-claw sweat of the house, or you can lay it out in the middle.

Figure q shows a simple explanation of TFI 70. Figure 87 is a longitudinal cross-sectional view of the device of the present invention at about 7j at medium heat.
P,-! The figure is the same f':l'j I4noi but Figure 3 (
The center of the d-th rotor is 1' center 1.
A vague sectional view, Figure 1 is a plan view of the primary rotor, Figure 5 is a front view of the same, Figure 5 is the same front view, Figure 2 is the same front view. FIG. 7 is a center longitudinal 14' fT view showing an example of the secondary rotor, and FIG. 8' is a diagram for explaining the operation of the apparatus of the present invention.

/...Main container, λ...Rotating IIH field generator, 3...
-Secondary rotor, Y...Secondary rotor, S...Coating,
B...I non-lit gate, 7, g...coating, W...outer cylinder, 10...middle 14), //, /2...inner cylinder, /
3...'Tun Mikoa, /ll...→1 Mokuno Q-115
・・End ring, /Otsu・・Bottom protection plate, /7・・Top stop plate, 1g・・Body cylinder, /?・・Body bottom plate, −〇・
・Arrow, Cor/・Object.

Figure 4 Figure 7 Figure 6 Procedural amendment (voluntary) March 1, 1980 Director-General of the Patent Office Kazuo Wakasugi 1, Indication of case Patent Application No. 9427 of 1982 2, Title of invention Mixing, kneading , a device 3 having stirring and crushing functions;
Person making the amendment Relationship to the case Applicant Name Gousai Seisakusho 4 Co., Ltd. Agent Address: 519 Hiyo Park Building, Yurakucho-chome 8-1-1, Chiyoda-ku, Tokyo 100 (Tel: 213-)
0686) 5. Subject of Supplement: Detailed Description of the Invention in 1 of the Specification, 4X.

1

Claims (1)

[Claims] / A slurry to be mixed, kneaded, stirred or pulverized
a hollow cylindrical bottom-handed main body container with low magnetic flux and high electrical resistance in which an object is placed; a rotating magnetic field generator formed by wrapping the outer periphery and a part of the main container around the bottom thereof; and the rotating magnetic field generator 6. The primary rotor of the cylindrical prisoner, which is subjected to the suction, rotation, and revolution effects on the side and bottom surfaces of the MiJ main body container, and this secondary rotor are placed in each Fail approved main body container without mutual mechanical connection. The contact friction with the rotor (a cylindrical secondary body with magnetic permeability that rotates and revolves due to the force) Rotation-
Mixing, kneading,
A device with stirring and crushing functions. The height of the electromagnetic center line of the rotating magnetic field generator is set to -
8. The device according to claim 7, wherein the device is set above the height of the next rotor and below the line. 3. The above-mentioned -order rotor is connected to the outer cylinder and outer bottom of the abrasive pile fluid with low magnetic permeability and high air permeability, and the middle cylinder and intermediate bottom of the gas giant conductor with low permeability (city at a rate of 1 m), The device according to claim 1, characterized in that the device is composed of a cylinder and an inner bottom portion, each of which is fixed to each other with four holes. The apparatus according to claim 1, characterized in that the conductor bar is inserted in the axial direction over the entire circumference and short-circuited at both ends by an end ring. Claim 1, the apparatus listed in IA9C, characterized in that the rotor is made of iron. B. At least the inner one-law surface and the inner curved surface of the main body container and at least the outer circumferential surfaces of the secondary and secondary rotors. and the outer bottom surface thereof are coated with a material having low magnetic permeability, high electrical resistance, wear resistance, and heat insulation properties. 7. The device lamp according to claim 6, characterized in that the coating is made of ceramic. The apparatus according to claim 1, characterized in that the sum of the outer diameter of the secondary rotor and the inner diameter of the MiJ main body is slightly smaller than the inner diameter of the MiJ main body. 9) jI - Outside of the secondary rotor The device i''+' according to claim g, characterized in that the diameter is the same as or slightly larger than the outer diameter of the secondary rotor i%iJ.