RU2319432C1 - Mixer - Google Patents

Abstract

FIELD: household facilities, in particular, beverage mixing devices.

SUBSTANCE: mixer has mixing chamber, circular source of rotating magnetic fields, and ferromagnetic bodies. Mixing chamber is formed as cup. Circular source of rotating magnetic field is formed as solenoid coli disposed on outer surface of dielectric cup. Ferromagnetic bodies are formed as turbines having offset center of mass and covered with plastic. Turbines are positioned between bottom and protrusions fixed in parallel with bottom, within cup. Two turbine position sensors are disposed on cup outer surface, at the level of protrusions and bottom.

EFFECT: provision for mixing of difficult-to-flow liquids, and enhanced reliability in operation of mixer.

5 dwg

Description

The invention relates to household appliances, namely, devices for mixing drinks.

A known mixer containing a drive with a set of working bodies, including a frame whisk with two vertical uprights, and a device for mounting the working bodies to the drive shaft (Application of Germany No. 2156789, MKI A47J 43/08, publ. 1978).

A disadvantage of the known device is its high complexity, low reliability.

A known mixer containing a drive with a set of working bodies, including a frame whisk with two vertical racks, and a device for attaching working bodies to the drive shaft. In this case, the mixer is equipped with an additional working element containing vertical racks on which an annular element with a cylindrical protrusion on the inner side of the ring is mounted, the annular element having notches and the protrusion having teeth (AS USSR No. 1007647, MKI A47J 43/04 Publ. 1983, BI No. 12).

A disadvantage of the known device is its high complexity, low reliability.

The closest in technical essence to the proposed invention is a continuous mixer, consisting of a mixing chamber made of non-magnetic material placed inside an annular source of rotating magnetic fields with ferromagnetic bodies introduced into it, inlet and outlet pipes. The source of rotating magnetic fields is made in the form of three-phase alternating current electromagnets sequentially placed along the mixing chamber, creating a magnetic field in the adjacent zones of the chamber with the opposite direction of rotation (see AS USSR No. 423489 BI No. 14, 1974).

A disadvantage of the known design is the inability to mix non-flowing liquids and the inability to use in laboratory conditions.

The basis of the invention is the task of providing the possibility of mixing non-flowing liquids, as well as improving the reliability of the mixer in operation.

The problem is solved due to the fact that in a mixer containing a mixing chamber of non-magnetic materials, an annular source of rotating magnetic fields and ferromagnetic bodies, according to the invention, the mixing chamber is made in the form of a glass, the annular source of rotating magnetic fields is made in the form of a solenoid coil mounted on the outer side of the glass, and the ferromagnetic bodies are made in the form of a turbine, covered with plastic, located between the bottom of the glass and the protrusions mounted in the glass, two additionally installed turbine position sensors, one at the bottom of the glass, the other at the protrusions.

The invention has significant differences, since there are no known solutions with features that distinguish this solution from the prototype.

Figure 1 - General view of the mixer,

figure 2 is a cross section of a General view of the mixer (the turbine is not cut),

figure 3 is a view along arrow A,

figure 4 is a view along arrow B,

figure 5 is a cross-section of the turbine.

The mixer consists of a cup 1, a coil of a solenoid 2 mounted on the outside of the cup, a turbine 3 located at the bottom of the cup. The turbine 3 is made of a ferromagnet coated with a material that is neutral to miscible liquids, such as a food grade polymer. In the upper part of the glass, parallel to its bottom, protrusions 4 are installed. Two position sensors of the turbine 5 are mounted on the outer surface of the glass 1 at the level of the protrusions and the bottom.

The turbine 3 is designed so that it has an offset center of gravity, which provides a constant orientation of the turbine 3 relative to the bottom of the cup 1, or the diameter of the turbine 3 approaches the inner diameter of the cup 1, as a result of which the turbine 3 can have a “sliding” fit relative to the inner hole of the cup 1 .

The protrusions 4 are designed to limit the stroke of the turbine and provide free pouring of mixed liquids from the glass 1.

The mixer works as follows.

Mixed liquids are poured into a glass 1. At this time, the turbine 3 is at the bottom of the cup 1. In this position, the sensor 5 is closed and when voltage is applied to the winding of the solenoid 2, an electromagnetic force arises in the interior of the cup 1, the turbine 3 begins to rise up. When the turbine 3 reaches the position of the upper sensor 5, the electric circuit supplying the coil of the solenoid 2 opens. Under the influence of its own gravity, the turbine 3 sinks to the bottom of the cup 1. At this time, thanks to the sensor 5, the electric circuit supplying the solenoid 2 is again closed at the bottom of the cup 1, and the turbine 3 begins to rise up. The process is repeated. In this case, when raising and lowering the turbine 3 rotates. The rotation is carried out due to the passage of laminar flows of mixed liquids through the blades of the turbine 3. All this leads to intensive mixing of the liquids. After mixing, the power to the winding 2 is turned off and the mixed liquid is poured out of the glass 1. In this case, the turbine 3 is delayed in the glass 1 by the protrusions 4.

In order that the ferromagnet of the turbine 3 does not come into contact with the mixed liquids, it is covered with a film of a material that is neutral to the mixed liquids, for example, food grade polymer.

The turbine 3 can be performed, for example, in this way.

At the ferromagnetic circle, petals are made along the ring, as shown in Fig. 4. A load in the form of a cylinder is installed in the center of the ferromagnetic circle, which provides a displaced center of mass of the turbine 3. A ring of dielectric can be made along the perimeter of the ferromagnetic disk, which will serve as a guide when the turbine moves up and down.

The protrusions 4 can be made of a polymer inert to the mixed liquids and have an outer diameter, the size of which ensures a fixed (“pull-in”) fit in relation to the size of the opening of the cup 1. This ratio of the diameters of the outer of the protrusions 4 and the inner of the cup 1 allows you to remove from the glass 1, the tabs 4 and the turbine 3, if necessary.

As position sensors 5, for example, reed switches can be used.

A prototype of the inventive mixer was made, which was successfully tested. The inventive device can be used for mixing explosive liquids, such as hydrochloric and sulfuric acids, in laboratory conditions.

Claims (1)

A mixer containing a mixing chamber, an annular source of rotating magnetic fields and ferromagnetic bodies, characterized in that the mixing chamber is made in the form of a glass, an annular source of rotating magnetic fields is made in the form of a solenoid coil placed on the outer surface of the dielectric glass, and ferromagnetic bodies are made in the form turbines with a displaced center of mass, covered with plastic and located between the bottom and protrusions, mounted parallel to the bottom inside the cup, while two turbine position sensors are installed Lena on the outer surface of cup at the bottom and protrusions.

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