KR101520179B1 - Twin mixer - Google Patents

Abstract

A twin mixer device is disclosed. A mixer liner provided inside the housing of the present invention; A pair of first and second shafts coupled by arms such that a plurality of blades are coupled by arms and installed parallel to the interior of the mixer liner and capable of transmitting power to each other; And a drive unit having a drive motor and a speed reducer provided at one side of the housing to drive the first shaft, wherein the blades are arranged in a first direction toward a center line of the first shaft or the second shaft, Wherein the second region is formed so as to be narrower than the first region, the end portion of the second region is formed in an arc shape, and a straight line portion perpendicular to the center line is polygonal as a whole, Wherein each of the rectilinear sections is connected to each other by sloping surfaces and is formed in an asymmetric shape on both sides of a first reference line perpendicular to the center line, And protrusions are formed on one side. According to the present invention, by forming the blades asymmetrically, not only the mixing of the raw materials such as concrete can be performed efficiently, but also the effect of obtaining the slump value without mixing in the concrete can be provided do.

Description

Twin mixer device {TWIN MIXER}

The present invention relates to a twin mixer apparatus, and more particularly, to an intelligent twin mixer apparatus capable of efficiently mixing and extracting an amperage value applied to a driving unit during mixing to obtain a slump value based on the extracted amperage value.

In general, the twin mixer device is used to homogeneously mix a plurality of viscous compounding elements and is essentially used in the process of homogenizing the mixture in the final step of commercialization.

The main application fields of such a twin mixer device are the construction field and the chemical field and are used in various industrial fields.

On the other hand, the twin mixer device used for the verification of the concrete pavement is simple because the test equipment is simple and the price is low. Therefore, it is pointed out that the problem of the mixing method and the result of the combination are different from the conditions of the site, Despite the disadvantages of not being able to take into account the mechanical performance of the package of the present invention, it has been widely used without any modification.

The twin mixer device described above is a kind of mechanical stirrer, which is composed of a blending part composed of a pair of shafts in which an arm having a blade is coupled, and a driving part for driving the shaft with a speed reducer.

Various twin mixer devices are disclosed. As an example, Korean Utility Model No. 20-2009-11964 (published on November 25, 2009) discloses a twin shaft mixer. 1, a twin-shaft mixer having such a structure is provided with a checker foot 5 for checking the internal state of mixing with the mixer frame and an inspection window 22 of the upper cover 21, The hollow shaft worm reducer 4 is mounted on the two shafts 15 to which the main body arm and the tip are connected and the balance between the mixer torque arm lever 18 and the reducer torque arm 6 is aligned and fixed, And is configured to be secured with a rubber coupling 8 to transmit power to the motor 1 pulley 2 and the worm reducer pulley 3 belt.

However, the conventional twin mixer device has the following problems.

First, after completing the mixing of the concrete, there is a problem that the slump value must be obtained through a separate slump test. That is, the twin mixer device according to the prior art has a disadvantage of merely performing the function of mixing.

Second, as shown in FIG. 1, adjacent mixer tips provided on both shafts are spaced apart from each other, and the shape of the mixer tips is formed into a triangle shape, so that the mixing of concrete is not efficiently performed.

Korean Utility Model No. 20-2009-11964 (Published on November 25, 2009)

It is an object of the present invention to provide a twin mixer device capable of obtaining a slump value without any special test at the time of mixing concrete and efficiently mixing the raw materials.

The object is achieved by a mixer liner provided inside a housing according to the present invention; A pair of first and second shafts coupled by arms such that a plurality of blades are coupled by arms and installed parallel to the interior of the mixer liner and capable of transmitting power to each other; And a drive unit having a drive motor and a speed reducer provided at one side of the housing to drive the first shaft, wherein the blades are arranged in a first direction toward a center line of the first shaft or the second shaft, Wherein the second region is formed so as to be narrower than the first region, the end portion of the second region is formed in an arc shape, and a straight line portion perpendicular to the center line is polygonal as a whole, Wherein each of the rectilinear sections is connected to each other by sloping surfaces and is formed in an asymmetric shape on both sides of a first reference line perpendicular to the center line, And a protrusion is formed on one side of the twin mixer.

Wherein the blades are disposed at an angle of 40 degrees with respect to the center line, each of the blades is arranged in a radial manner while maintaining 90 degrees with respect to the center line, The protrusions of the blades installed in the first shaft and the protrusions of the blades installed in the second shaft may be arranged to face each other.

The blade located on the longitudinal wall side of the mixer liner is formed such that a third region facing the wall is formed in a straight line parallel to the wall and a fourth region located on the opposite side is formed in a semi-trapezoidal shape And may be formed to be wider and wider toward the widthwise wall of the mixer liner.

Wherein the driving unit includes a slump value detecting device, wherein the slump value detecting device comprises: a detecting unit for detecting a load value applied to a driving shaft of the driving motor based on a change in current supplied to the driving motor; A microcomputer for calculating a slump value of a compounded product by comparing a load value of the drive shaft detected by the detection unit with a slump reference value stored in a memory; And an output unit for displaying a slump value calculated from the microcomputer on a screen display unit and outputting a slump value to a printer.

According to the present invention, by forming the blades asymmetrically, not only the mixing of the raw materials such as concrete can be performed efficiently, but also the effect of obtaining the slump value without mixing in the concrete can be provided do.

1 is a view showing a conventional twin mixer.
2 is a schematic plan sectional view showing a twin mixer apparatus according to the present invention.
3 is a schematic front view showing the twin mixer apparatus shown in Fig.
4 is a schematic block diagram for explaining an apparatus for detecting a slump value of a twin mixer apparatus according to the present invention.
5 to 9 are graphs showing test results of a mixture blended with the twin mixer apparatus according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions are not described in order to simplify the gist of the present invention.

3 is a schematic front view showing the twin mixer apparatus shown in FIG. 2, and FIG. 4 is a cross-sectional view of the twin mixer according to the present invention. FIG. Fig. 2 is a schematic block diagram for explaining a slump value detecting device of the apparatus; Fig.

2 to 4, the twin mixer apparatus according to the present invention includes a mixer liner 22 provided inside a housing 20, and a plurality of blades 50, And a pair of first and second shafts 40A and 40B connected by gears G so as to be able to transmit power to each other and to be installed in parallel by the bearings while maintaining a gap in the interior of the mixer liner 22, And a driving unit 70 having a driving motor 70 and a speed reducer 72 provided at one side of the housing 20 to drive the first shaft 40A.

The blades 50 are formed so that the first region 52 toward the center line C1 is formed to be narrower with respect to the center line C1 of the first shaft 40A or the second shaft 40B, The region 54 is formed to be wider than the first region 52. The end portion 54A of the second region 54 is formed in an arc shape and a rectilinear portion 56 perpendicular to the center line C1 is formed in the first region 52 and the second region 54 The linear portions 56 are connected to each other by the inclined surfaces 58 and are formed asymmetrically with respect to the first reference line C2 perpendicular to the center line C1 And a protruding portion 54B is formed on one side of the second region 54.

That is, as shown in FIG. 2, the blade 50 according to the present invention has an asymmetric structure biased to one side with respect to the first reference line C2, and has a polygonal shape by straight lines and curved lines.

The shape of the blade 50 is coupled to the other end of the arm 60 coupled to the shafts 40A and 40B with bolts or the like.

On the other hand, when the blade 50 is engaged with the respective shafts 40A and 40B, the second reference line C3 of the surface of the blade 50, with respect to the center line C1, Is set at an angle (A) of 40 degrees. Each of the blades 50 is radially arranged while maintaining 90 degrees with respect to the center line C1, but arranged in a spiral shape maintaining an equal interval.

That is, each of the blades 50 is disposed at a 40-degree angle (A) with respect to the center line C1 and radially arranged while maintaining 90 degrees at regular intervals in the longitudinal direction of the shafts 40A and 40B , And arranged in a spiral manner.

At this time, the projections 54B of the blades 50 installed on the first shaft 40A and the projections 54B of the blades 50 installed on the second shaft 40B should be arranged to face each other.

Such an installation structure is intended to efficiently mix the raw materials.

On the other hand, in the blade 50A positioned on the longitudinal wall 22A of the mixer liner 22, the third region 55 on the side facing the wall 22A is formed in a straight line parallel to the wall 22A, The fourth region 57 on the opposite side is protruded in a trapezoidal shape with reference to the third reference line C3 and is formed to be widened as it extends toward the widthwise wall 22B of the mixer liner 22. [ This is so that the blade 50A located on the side of the longitudinal wall 22A has an asymmetrical shape offset to one side like the other blade 50 and in particular the blade 50A located on the side of the longitudinal wall 22A, So as to rotate without interfering with the wall 22A, and to efficiently move and compound the compound moved toward the wall 22A.

On the other hand, the driving unit 70 is provided with a slump value detecting device 80, and the slump value detecting device 80 detects the slump value of the driving motor 72 by the load value applied to the driving shaft 76 of the driving motor 72 A detection unit 82 for detecting a load value of the drive shaft 76 detected from the detection unit 82 based on a change in the supplied current (ampere), and a comparison unit 80 for comparing the load value of the drive shaft 76 detected by the detection unit 82 with the slump reference value stored in the memory 84 A microcomputer 86 for calculating a slump value and an output section 88 for displaying the slump value calculated by the microcomputer 86 on the screen display section 88B and outputting the slump value to the printer 88A .

The operation of the present invention configured as above will be described.

When the driving motor 72 is driven after the raw material to be mixed is injected into the mixer liner 22, the speed reducer 74 connected to the driving motor 72 drives the first shaft 40A, The second shaft 40B connected to the second shaft 40B is driven. At this time, the first shaft 40A and the second shaft 40B rotate in opposite directions to each other.

The respective blades 50 and 50A provided on the first shaft 40A and the respective blades 50 and 50A provided on the second shaft 40B are separated from the projected portion 54B and the fourth region 57 Since the blades 50 and 50A are formed asymmetrically, the blending of the raw materials can be smoothly performed.

That is, the blades 50 and 50A provided on the first shaft 40A and the blades 50 and 50A provided on the second shaft 40B feed raw materials in the mixer liner 22 While the blades 50 and 50A of the shafts 40A and 40B are blended by the blades 50 and 50A of the shafts 40A and 40B, the blades 50 and 50A are arranged in a helical shape and move in opposite directions with respect to the longitudinal direction of the shafts 40A and 40B So that the mixing can be efficiently performed.

Further, by smoothly flowing the raw materials through the asymmetrically formed blades 50 and 50A, the blending of the raw materials can be performed efficiently and completely.

On the other hand, when the rotations of the shafts 40A and 40B are performed, the load value applied to the drive shaft 76 of the drive motor 72 is determined based on the change of the current (ampere value) supplied to the drive motor 72 ).

That is, the current supplied to the drive motor 72 increases when the load on the drive shaft 76 is large, and the current decreases when the load takes a relatively small amount. The detection unit 82 senses a change in the current supplied to the drive motor 72 and detects it as a load value.

The load value detected by the detector 82 is received by the microcomputer 86 and compared with the slump reference value previously stored in the memory 84 to calculate the slump value of the compounded mixture.

The slump value thus calculated is displayed on the screen display section 88A by the output section 88 and output to the printer 88B.

Therefore, a separate measuring operation for measuring the slump value of the compounded compound is not required.

In the accompanying drawings, as shown in FIG. 5, the graph of the 25-18-80 mixture is loaded at the topmost position. The test time was 60 ~ 80sec. The graph of the 25-18-120 mixture is in the middle position, and the graph is formed at the bottom of 25-18-150.

In the accompanying drawings, as shown in FIG. 6, the graph of the 25-24-80 mixture is located at the top. It can be shown that the load of mixed aggregate is the highest. 25-24-120 The graph of the mixture shows that the middle 25-24-150 mixture is located at the bottom. The blend ratio of the mixed contents shows that the amount of cement is increased and the amount of sand is increased as the ratio is 150.

In the accompanying figures, as shown in FIG. 7, the graph of the 25-30-80 mixture is located at the top. It can be shown that the load of mixed aggregate is the highest. 25-24-120 The graph of the mixture shows that the 25-30-150 mixture is in the middle and the mixture is at the bottom. The mixing ratio of mixed contents shows that the amount of cement is increased and the amount of sand is increased as the ratio is 150.

In the accompanying drawings, as shown in FIG. 8, the graph of the 25-40-150 mixture is located at the top. It can be shown that the load of mixed aggregate is the highest. 25-24-120 The graph of the mixture shows that the 25-40-180 mixture in the middle is located at the bottom. The blending ratio of the mixed contents shows that the amount of cement is increased and the amount of sand is increasing as the distance is increased to 180 °.

In the accompanying drawings, as shown in Fig. 9, the graph of the 25-50-150 mixture is located at the top. It can be shown that the load of mixed aggregate is the highest. 25-50-180 The mixture is seen at the bottom. When the mixing ratio of the mixed contents is examined, it is seen that the amount of cement increases and the amount of sand increases with the increase of the mixing ratio to 180.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have. Accordingly, it should be understood that such modifications or alterations should not be understood individually from the technical spirit and viewpoint of the present invention, and that modified embodiments fall within the scope of the claims of the present invention.

20: housing 22: mixer liner
22A, 22B: wall 40A: first shaft
40B: second shaft 50, 50A: blade
52: first region 54: second region
54A: end portion 54B:
55: third region 56: straight line portion
57: fourth region 58: inclined surface
60: arm 70:
72: drive motor 74: speed reducer
76: drive shaft 80: slump value detecting device
82: Detection unit 84: Memory
86: Microcomputer 88: Output section
88A: Screen display part 88B: Printer

Claims (4)

A mixer liner provided inside the housing; A pair of first and second shafts coupled by arms such that a plurality of blades are coupled by arms and installed parallel to the interior of the mixer liner and capable of transmitting power to each other; And a drive unit having a drive motor and a speed reducer provided at one side of the housing to drive the first shaft,
The blades,
The first region facing the center line is formed narrower with respect to the center line of the first shaft or the second shaft and the second region extending in the opposite direction is formed wider than the first region, Wherein a straight line portion perpendicular to the center line is formed parallel to both the first region and the second region so as to form a polygon as a whole, each of the straight portions is connected by inclined surfaces, Wherein the first region and the second region are formed asymmetrically with respect to a first reference line perpendicular to the first region and a protrusion is formed on one side of the second region,
Wherein the blades are disposed at an angle of 40 degrees with respect to the center line, each of the blades is arranged in a radial manner while maintaining 90 degrees with respect to the center line, The protrusions of the blades installed in the first shaft and the protrusions of the blades installed in the second shaft are disposed so as to face each other,
The blades located on the longitudinal wall side of the mixer liner,
A third region facing the wall is formed in a straight line parallel to the wall and a fourth region in the opposite direction is protruded in a trapezoidal shape with reference to a first reference line, And is formed so as to become wider and wider,
The driving unit includes:
A slump value detecting device includes a detecting unit for detecting a load value applied to a driving shaft of the driving motor based on a change in a current supplied to the driving motor; A microcomputer for calculating a slump value of a compounded product by comparing a load value of the drive shaft detected by the detection unit with a slump reference value stored in a memory; And an output unit for displaying a slump value calculated by the microcomputer on a screen display unit and outputting a slump value to a printer.
Twin mixer device.
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