KR101106919B1 - Mixer - Google Patents

Abstract

PURPOSE: A mixer is provided to increase grinding areas and grinding numbers per rotation by varying the speed ratio of each blade and to increase stirring effect by implementing a grinding operation during a stirring process. CONSTITUTION: An electric power part is prepared. A driving part implements revolution and rotation based on a bear box(122) composed of planetary gears(126, 128) and a center gear(124). A mixing part(130) is arranged at the lower side of the driving part. A first blade(214) implements revolution and rotation in the mixing part based on a first driving shaft(212) and stirs target materials. A second blade(224) implements revolution and rotation in the mixing part based on a second driving shaft and stirs the target materials. The rotation traces of the first blade and the second blade are partially overlapped.

Description

Blender {mixer}

The present invention relates to a mixer, and more particularly, to a mixer that can enhance the stirring effect by performing grinding as well as stirring the stirring target material.

In general, a mixer, and a planetary mixer, among them, performs a function of stirring and mixing the high-viscosity material mainly in a kneaded state, and is also referred to as a rotating revolving screw mixer.

Such a mixer is provided with a plurality of blades for rotating and rotating in a predetermined container to mix the target material in the container through a dispersion and stirring action. At this time, the target material is moved left and right by the rotating blade as well as the dispersion and stirring action by the convection movement of the target material up and down along the shape of the twisted blade.

By the way, there is a lack of the effect of uniformly mixing the target material in the high viscosity to semi-solid dough only by the dispersion and stirring action by the blade. In particular, agglomeration often occurs in mixed powders in which large particles and small particles are mixed, and thus, it may be impossible to obtain a satisfactory mixing effect only by simple stirring in evenly mixing these target materials.

Therefore, there is a need for a mixer capable of preventing the aggregation of the target material and increasing the mixing effect, as well as grinding and grinding as well as grinding the target material.

Embodiments of the present invention to provide a mixer that can enhance the stirring effect by performing grinding as well as stirring the stirring target material.

In addition, it is to provide a mixer that can increase the number of grinding and grinding area per unit rotation by varying the speed ratio of each blade.

In addition, it is not only the grinding is performed between the blades, but also to provide a mixer that can be grinding between the blade and the inner wall of the container.

In addition, the stirring is performed under a reduced pressure in a vacuum state to provide a mixer that can further increase the stirring effect of the stirring target material.

According to one aspect of the invention, the drive unit for implementing the orbital movement and the rotational movement by the power unit, a gear box consisting of a planetary gear and a solar gear provided therein receiving a driving force from the power unit, and the lower portion of the drive unit It is provided, the mixing unit is accommodated by the mixing unit, the first drive shaft connected to the drive unit by the rotating and revolving inside the mixing unit by stirring the stirring target material, the center except for the wing end of the first hollow portion Rotating and revolving inside the mixing unit by a blade and a second drive shaft connected to the drive unit to agitate the agitating target material, and the blade including the central body surface and the wing end all the second blade consisting of one body Includes, the rotational trajectory of the first blade and the second blade partially overlap, the first blade and the second blade Is located between the body surfaces of the blade end and the second blade of the first blade mixer is characterized in that the grinding (grinding) and pressing the stirred substances may be provided as the rotation.

In addition, the rotation ratio of the first blade and the second blade may be configured to be 2: 1.

In addition, the rotation direction of the first blade and the second blade may be configured to be made in the opposite direction to each other.

In addition, when the first blade and the second blade is rotated, the distance between the both ends of the first blade and the body surface of the second blade closest may be made of 3mm ~ 10mm.

In addition, a revolving axis of the first blade and the second blade revolves may be configured to be eccentric from the center of the mixing portion.

In addition, an interval between the outermost end of the first blade that rotates and orbits and the inner wall of the mixing unit may be 3 mm to 10 mm.

In addition, when the stirring object is stirred, the inside of the driving unit and the inside of the mixing unit may be decompressed in a vacuum state.

The mixer according to the embodiments of the present invention may enhance the stirring effect by performing grinding as well as stirring the stirring target material.

In addition, by varying the speed ratio of each blade, the number of grinding and the grinding area per unit rotation can be increased.

In addition, the grinding may be performed not only between the blades, but also between the blades and the container inner wall.

In addition, the stirring is performed under reduced pressure in a vacuum state to further increase the stirring effect of the stirring target material.

1 is a front view of a blender according to an embodiment of the present invention.
2 is a longitudinal sectional view of the mixer according to the embodiment of the present invention.
3 is a block diagram showing a first blade configuration of a mixer according to an embodiment of the present invention.
Figure 4 is a block diagram showing a second blade configuration of the mixer according to an embodiment of the present invention.
5 is a plan view showing a state in which the first blade and the second blade of the mixer according to an embodiment of the present invention rotates.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosure may be made thorough and complete, and to fully convey the spirit of the present invention to those skilled in the art. Like numbers refer to like elements throughout.

1 is a front view of a mixer according to an embodiment of the present invention, Figure 2 is a longitudinal sectional view of the mixer according to an embodiment of the present invention, Figure 3 is a first blade configuration of the mixer according to an embodiment of the present invention It is a block diagram showing the. 4 is a block diagram showing a second blade configuration of the mixer according to an embodiment of the present invention, Figure 5 is a state in which the first blade and the second blade of the mixer according to an embodiment of the present invention rotates It is a plan view.

1 to 5, the mixer 100 according to an embodiment of the present invention is largely, the power unit, the planetary gears (126, 128) and the sun gear provided therein by receiving the driving force from the power unit A driving unit 120 for implementing an orbital motion and a rotating motion by the gear box 122 formed of a 124, a mixing unit 130 provided below the driving unit 120, and containing a stirring target material; The first blade formed by the first drive shaft 212 connected to the drive unit 120 rotates and revolves inside the mixing unit 130 to agitate the agitating target material and the hollow portion 216 has a center except for the wing end. 214 and a second drive shaft 222 connected to the driving unit 120 rotates and revolves inside the mixing unit 130 to agitate the stirring target material, and a blade including a central body surface and a wing end. Includes a second blade 224, all made up of one body It can be done over.

The power unit includes a drive motor 112 for generating a driving force and a reducer 114 for reducing the power generated from the drive motor 112 to a driving unit 120 at a predetermined ratio, and the drive motor ( 112 and the reducer 114 may be installed above the mixer 100.

The drive unit 120 including the gearbox 122 including the planetary gears 126 and 128 and the sun gear 124 is provided below the power unit. The driving unit 120 receives a driving force from the power unit and transfers the driving force to the first blade 214 and the second blade 224.

In the present embodiment, since the blade is composed of two first blades 214 and second blades 224, the first planetary body is connected to the sun gear 124 and the first blade 214 in the gearbox 122. The second planetary gear 128 connected to the gear 126 and the second blade 224 is provided, respectively, and the rotation and the revolving movement of the first blade 214 and the second blade 224 are achieved by these configurations. Is implemented.

That is, as the revolving part 202 including the gear box 122 rotates in the driving part 120, the first blade 214 and the second blade 224 revolve along a predetermined trajectory, and the As the first planetary gear 126 engaged with the sun gear 124 rotates, the first blade 214 rotates while the first drive shaft 212 connected to the first planetary gear 126 rotates. As the second planetary gear 128 engaged with the first planetary gear 126 rotates, the second drive shaft 222 connected to the second planetary gear 128 rotates, so that the second blade 224 is rotated. Rotate

The configuration of the gears in the gearbox 122 may be configured in various ways depending on the number of blades, rotation and idle ratio.

The mixing unit 130 in which the stirring target material is accommodated and stirred is installed below the driving unit 120. The stirring target material may be an ink, a paint, a ceramic, a medicine, a food, an electronic material, and various other industrial materials.

The mixing unit 130 is coupled to the lower container 134 and the upper container 136 to form a predetermined space therein, the stirring target material is accommodated in the predetermined space, the first blade 214 and the second The blade 224 is stirred as it rotates and revolves.

Here, the lower container 134 is provided to be moved up and down by the cylinder 132, when the lower container 134 is located in the lower state, the upper container 136 and the lower container 134 is separated When the lower container 134 is moved to the upper and combined with the lower end of the upper container 136, the interior is sealed. As described above, the lower container 134 and the upper container 136 may be coupled to each other to perform stirring of the stirring target material in a sealed state.

At this time, the first blade 214 and the second blade 224 for performing the stirring of the stirring target material performs the rotation and revolving movement in the state located in the mixing unit 130.

Specifically, the first blade 214 is rotated and revolved in the mixing unit 130 by the first drive shaft 212 connected to the first planetary gear 126 in the drive unit 120 to the stirring target material Stir.

Here, the first blade 214 is made of a spiral twisted shape, the hollow portion 216 is formed in the center is formed in the form of a body only toward the border, mainly moving the stirring material to the left and right, of course twist Along the shape of the first blade 214, the stirring target material is convectively moved up and down to disperse and stir.

On the other hand, the second blade 224 is rotated and revolved in the mixing unit 130 by the second drive shaft 222 connected to the second planetary gear 128 in the drive unit 120 to the stirring target material Stir.

Here, the second blade 224 is made of a spiral twisted shape, unlike the first blade 214, all of the blade is made of one body. The twisted direction of the second blade 224 may be opposite to the twisted direction of the first blade 214.

The second blade 224 also performs the stirring degree action of the stirring target material according to the rotational movement, but close to the wing end of the first blade 214 performs a grinding (grinding) action on the stirring target material. Will perform.

Specifically, the rotational trajectories of the first blade 214 and the second blade 224 partially overlap each other, and the rotation ratios of the first blade 214 and the second blade 224 and the respective curvatures and twisted angles are different from each other. By adjusting, the first blade 214 and the second blade 224 pass by in close proximity to each other without colliding with each other.

In particular, as the first blade 214 and the second blade 224 rotates, grinding of the stirring target material between both wing ends of the first blade 214 and the body surface of the second blade 224 ( grinding) action.

That is, while both ends of the wing of the first blade 214 having the hollow portion 216 rotates, the body surface of the second blade 224 is passed in close proximity, whereby the stirring material is pressed to grind. Can be done.

As described above, the mixer 100 according to an embodiment of the present invention has an advantage of preventing aggregation of the stirring target material and increasing the stirring effect by performing grinding as well as stirring the stirring target material.

At this time, it is preferable that the rotation ratio of the first blade 214 and the second blade 224 is 2: 1, which is the first planetary gear 126 and the second planetary gear 128 as shown in FIG. Can be configured by adjusting the diameter and gear ratio. In particular, considering the revolution, the rotational speed of the first blade 214, the rotational speed of the second blade 224 and the number of revolutions are preferably configured to achieve a ratio of 6: 3: 2.

Thus, when the rotation ratio of the first blade 214 and the second blade 224 is 2: 1, when the first blade 214 is rotated once, both ends of the first blade 214 are respectively rotated by the second blade ( 224) Two grinding operations are performed while passing through one side of the body surface. In addition, when the first blade 214 further rotates one more time, both ends of the first blade 214 pass through the other side of the body surface of the second blade 224, respectively, and perform two grinding operations.

That is, when the second blade 224 is rotated by one reference to the second blade 224, a total of four grinding operations are performed. Therefore, since a relatively large number of grinding operations can be performed by only one rotation of the second blade 224, the number of grinding and the grinding area per unit rotation can be increased, and ultimately, the stirring efficiency can be improved.

At this time, as shown in Figure 5, the rotation direction of the first blade 214 and the second blade may be made in the opposite direction, when the first blade 214 and the second blade 224 is rotated The distance between the both ends of the first blade 214 and the body surface of the second blade 224 to be closest to each other is preferably configured to be short as about 3mm ~ 10mm.

Meanwhile, as illustrated in FIGS. 2 and 5, a revolving axis of the first blade 214 and the second blade 224 may be eccentric from the center of the mixing unit 130.

In particular, it is preferable to position the revolving shaft such that both ends of the first blade 214 pass near the inner wall of the mixing unit 130 while the first blade 214 rotates.

In this configuration, the first blade 214 may not only perform grinding based on the body surface of the second blade 224, but also grind the stirring target material based on the inner wall of the mixing unit 130. This can increase the grinding area and the grinding efficiency of the target material.

Specifically, the distance between the outermost end of the first blade 214 that rotates and orbits and the inner wall of the mixing unit 130 is closest to each other in the same manner as that of the body surface of the second blade 224 that is 3 mm to 10 mm. It is preferable to configure it as short as possible.

On the other hand, the mixer 100 according to an embodiment of the present invention may be configured to decompress the inside of the drive unit 120 and the mixing unit 130 in a vacuum state when the stirring target material is stirred.

By maintaining the inside of the mixing unit 130 in a vacuum state, there is an advantage that can eliminate the air resistance during stirring and increase the stirring effect. At this time, it is preferable that the inside of the driving unit 120 is also reduced in a vacuum state to match the pressure state.

Of course, it is possible to determine whether or not to apply a vacuum state according to the type and properties of the stirring target material, the vacuum state can be applied separately or simultaneously applied to the inside of the mixing unit 130 and the drive unit 120, and vacuum It is also possible to stir without pressure reduction.

1 to 5, the operation of the mixer 100 according to an embodiment of the present invention configured as described above will be described.

First, the stirring target material is introduced into the mixing unit 130, and then the upper container 136 and the lower container 134 of the mixing unit 130 are combined to seal the inside of the mixing unit 130. In this case, the inside of the mixing unit 130 and the inside of the driving unit 120 may be decompressed by a vacuum pump (not shown) and maintained in a vacuum state.

The driving force generated in the driving motor 112 is decelerated at a predetermined ratio by the speed reducer 114 and transmitted to the driving unit 120. In the driving unit 120, an idle unit 202 including the gear box 122 is provided. As it rotates, the first blade 214 and the second blade 224 revolve along a certain trajectory.

At the same time, as the first planetary gear 126 engaged with the sun gear 124 rotates, the first drive shaft 212 connected to the first planetary gear 126 rotates so that the first blade 214 is rotated. The second blade 224 rotates while the second drive shaft 222 connected to the second planetary gear 128 rotates as the second planetary gear 128 rotates while being engaged with the first planetary gear 126. Rotates.

As described above, stirring and stirring of the target material are performed according to the rotation and orbital motions of the first blade 214 and the second blade 224. At the same time, when both ends of the wings of the first blade 214 rotate, While passing through the body surface of the blade 224 in close proximity, the stirring material is pressed to perform a grinding action.

At this time, since the rotation ratio of the first blade 214 and the second blade 224 is 2: 1, when the first blade 214 rotates once, both ends of the first blade 214 are respectively second The blade 224 performs two grinding operations while passing through one side of the body surface, and when the second blade 224 rotates once based on the second blade 224, a total of four grinding operations are performed.

In addition, since the revolving axis of the first blade 214 and the second blade 224 is eccentric from the center of the mixing unit 130, the first blade 214 is the inner wall of the mixing unit 130 It can also play a role of grinding the stirring target material.

In performing the grinding as described above, the distance between the both ends of the first blade 214 and the body surface of the second blade 224 closest to each other is composed of about 3mm ~ 10mm, the maximum of the first blade 214 An interval between the outer end and the inner wall of the mixing unit 130 closest to each other is maintained at about 3 mm to 10 mm to increase grinding efficiency.

The mixer 100 according to the embodiment of the present invention configured as described above performs grinding as well as stirring of the stirring target material under a reduced pressure in a vacuum state, and grinding is not performed only between the blades, but also between the blade and the inner wall of the container. Grinding can be done.

Furthermore, by varying the speed ratio of each blade, the number of grinding and the grinding area per unit rotation is increased, and the agitation effect can be further increased because grinding is performed as if grinding the target material to prevent aggregation of the target material.

Although the above has been described with reference to an embodiment of the present invention, those skilled in the art may variously modify and change the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You can do it. It is therefore to be understood that the modified embodiments are included in the technical scope of the present invention if they basically include elements of the claims of the present invention.

100: blender 112: drive motor
114: reducer 120: drive part
122: gearbox 124: sun gear
126: first planetary gear 128: second planetary gear
130: mixing unit 132: cylinder
134: lower container 136: upper container
202: idle portion 212: first drive shaft
214: first blade 216: hollow part
222: second drive shaft 224: second blade

Claims (7)

Power unit;
A drive unit configured to receive a driving force from the power unit to implement an orbital motion and a rotational motion by a gearbox including a planetary gear and a sun gear provided therein;
A mixing unit provided below the driving unit to accommodate a stirring target material;
A first blade which rotates and revolves inside the mixing unit by a first drive shaft connected to the driving unit to agitate the agitating target material, and has a central portion excluding a wing end in a hollow portion; And
And a second blade formed of a single body including a central body surface and a blade end, by stirring and rotating the inside of the mixing unit by a second drive shaft connected to the driving unit to rotate the stirring target material. ,
The rotation paths of the first blade and the second blade partially overlap each other, and as the first blade and the second blade rotate, the stirring target material is disposed between both wing ends of the first blade and the body surface of the second blade. A blender characterized by crushing and grinding. The method of claim 1,
The rotation ratio of the first blade and the second blade is a mixer, characterized in that 2: 1. The method of claim 2,
Mixer, characterized in that the rotational direction of the first blade and the second blade is opposite to each other. The method of claim 1,
When the first blade and the second blade is rotated, the distance between the two ends of the first blade and the body surface of the second blade closest to the mixer, characterized in that 3mm ~ 10mm. The method of claim 1,
The revolution shaft which the said 1st blade and the 2nd blade revolves is eccentric from the center of the said mixing part. The method of claim 5,
And a distance between the outermost end of the rotating and revolving first blade and the inner wall of the mixing part closest to each other is 3 mm to 10 mm. The method of claim 1,
The mixer and the mixer, characterized in that the inside of the drive unit and the mixing unit is reduced in a vacuum state when the stirring target material.

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