KR20230155578A - Impeller assembly and mixing device - Google Patents

Abstract

This application discloses an impeller assembly and mixing device, and relates to the field of solid and liquid mixing facility technology, including an impeller structure and a housing structure, where the impeller structure includes a main body, and a plurality of curved blades are installed on the surface of the main body. The blade angle at any flow surface of the curved blade first decreases from the inlet to the outlet and then increases, a first baffle is installed at the lower part of the main body, the housing structure includes a second baffle, and 1 A first guide groove is provided in the baffle, and a second guide groove is provided in the second baffle. The fluid flows in from the inlet at the top of the main body, flows along the surface of the main body, and flows through the outlet at the bottom of the main body, the first guide. It flows out through the groove and the second guide groove, and the center line of the first guide groove is deflected in the direction opposite to the rotation direction of the impeller structure, and the center line of the second guide groove is deflected in the direction of rotation of the impeller structure. This application solves the problems of unstable transmission, high vibration and noise, and low operating efficiency.

Description

Impeller assembly and mixing device

This application relates to the field of solid and liquid mixing equipment technology, and in particular to impeller assemblies and mixing devices.

<Cross-reference to related applications>

This application claims priority of the Chinese patent application, application number 202111190681.9, filed with the State Intellectual Property Office of China on October 13, 2021, and titled “Impeller Assembly and Mixing Device,” the entire disclosure of which is included in this application. incorporated by reference.

In related technology, no special design has been carried out for the wing shape of the inner blade and the fluid flow passage, so the blade's action on the fluid is limited, and the multi-layer baffle generates a large resistance to the movement of the fluid, making delivery difficult. Therefore, it is necessary to accelerate and discharge the fluid using the action of the material discharge blade outside the baffle.

However, due to the forced acceleration and discharge of the material discharge blade against the fluid, the pressure wave in the delivery chamber is large, causing pulsation in the delivery flow amount, generating large noise and vibration, and reducing the operating efficiency of the dispersing device.

This application provides an impeller assembly and mixing device to solve the problems existing in the existing technology described above, and when the viscosity of the solid and liquid mixture is large, the delivery is unstable, which tends to occur when using a centrifugal delivery type dispersion device, The purpose is to solve the problems of high vibration noise and low operating efficiency.

In order to realize the above-mentioned object, this application provides the following technical solution.

The present application includes a relatively rotating impeller structure and a housing structure, the impeller structure includes a main body, a plurality of curved blades are installed on the surface of the main body along the circumferential direction of the main body, and a lower portion of the main body. At least one layer of first baffles is provided, the first baffles are installed on the outside of each of the rear curved blades, the housing structure includes at least one layer of second baffles, and the second baffle is the first baffle. It is located inside and/or outside the baffle, and the first baffle is provided with a plurality of first guide grooves, and the second baffle is provided with a plurality of second guide grooves, so that fluid flows in from the inlet at the top of the main body. , flows along the surface of the main body and flows out through an outlet at the bottom of the main body, the first guide groove, and the second guide groove, and the center line of the first guide groove is in a direction opposite to the rotation direction of the impeller structure. and the center line of the second guide groove is deflected in the rotation direction of the impeller structure.

Optionally, the size of the main body gradually increases from the top of the main body toward the bottom of the main body, and the surface of the main body is curved.

Optionally, the blade angle in any flow plane of the curved blade is first gradually decreased from the inlet to the outlet and then gradually increased, and the blade angle is between the tangent of the curved blade surface arc and the axial plane of the impeller structure. It is a narrow angle.

Optionally, the angle of the blade angle at the inlet location is 20 - 80° and the angle of the blade angle at the outlet location is 0 - 30°.

Optionally, the included angle between the center line of the first guide groove and the radial reflection of the body center axis is 15-50°.

Optionally, the included angle between the center line of the second guide groove and the radial reflection of the body center axis is 35-80°.

The present application further provides a mixing device including the impeller assembly.

This application achieves the following technical effects compared to existing technologies.

The curved blade adopted in this application can realize excellent coupling with the flow of fluid when rotating, so that the curved blade installed in the main body acts on the fluid more efficiently, and in particular, through simulation calculations, in any flow surface of the curved blade. The blade angle is designed to first decrease from the inlet to the outlet and then increase, so that the curved blade acts on the fluid more efficiently. On the other hand, a first guide groove is provided in the first baffle, and a second guide groove is provided in the second baffle. By providing a guide groove, it was found that the power loss when fluid passes through the first baffle and the second baffle is reduced through the direction of the first guide groove and the second guide groove. After the fluid is dispersed through the dispersion area between the first baffle and the second baffle, it still has sufficient power and can be discharged in the manner of centrifugation, so that there is no need to further increase the material discharge blade acting on the fluid, and the material By reducing interference with the fluid in the discharge area as much as possible, the fluid pressure in the material discharge area can be kept uniform and stable, the fluid can be discharged at a stable flow speed, and vibration and noise caused by pulsation have been eliminated.

In order to more clearly explain the embodiments of the present application or the technical solutions of the existing technology, the accompanying drawings required in the following embodiments will be briefly described, and the accompanying drawings described below are only some embodiments of the present application and are in the present technical field. It is obvious to a person skilled in the art that other attached drawings can be obtained based on these attached drawings under the premise that no creative labor is required.
1 is a schematic diagram of the impeller assembly of the present application.
Figure 2 is a cross-sectional view taken along line AA of Figure 1.
Figure 3 is a local enlarged view of position I in Figure 2.
Figure 4 is a schematic diagram of the impeller structure of the present application.
Figure 5 is a schematic diagram of the housing structure of the present application.

Hereinafter, the technical solutions of the embodiments of the present application will be clearly and completely explained in conjunction with the accompanying drawings in the embodiments of the present application, and the described embodiments are only some embodiments of the present application and are not all embodiments. Based on the embodiments of this application, all other embodiments that can be obtained by a person skilled in the art without creative labor fall within the scope of the claims of this application.

This application provides an impeller assembly and mixing device to solve the problems existing in the existing technology described above, and when the viscosity of the solid and liquid mixture is large, the delivery is unstable, which tends to occur when using a centrifugal delivery type dispersion device, The purpose is to solve the problems of high vibration noise and low operating efficiency.

In order to make the above-described objects, features, and advantages of the present application easier to understand, the present application will be described in detail below in conjunction with the accompanying drawings and specific embodiments.

Example 1

1 to 5, this embodiment provides an impeller assembly 100, including a relatively rotating impeller structure 1 and a housing structure 2, wherein the impeller structure 1 has a main body ( 3), and a plurality of curved blades 4 are installed on the surface of the main body 3 along the circumferential direction of the main body 3, and at least one layer of first baffle 5 is provided on the lower part of the main body 3. ) is installed, the first baffle 5 is installed on the outside of each curved blade 4, the housing structure 2 includes at least one layer of the second baffle 6, and the second baffle 6 ) is located inside and/or outside the first baffle 5, and in this embodiment, second baffles 6 on both inner and outer sides are installed in the housing structure 2, respectively, and the first baffle 5 ), the second baffle 6 is nested and snap-joined to the outside of the first baffle 5, and the first baffle 5 is provided with a plurality of first guides along the circumferential direction. A groove (7) is provided, and the first guide grooves (7) are uniformly distributed in the first baffle (5), and the second baffles (6) on both inner and outer sides are provided with a plurality of second guides along the circumferential direction. A groove (8) is provided, and the second guide groove (8) is uniformly distributed on the second baffle (6), and the cross-sectional shapes of the first guide groove (7) and the second guide groove (8) are It is similar to a diamond shape, and is provided while the deflections of the first guide groove (7) and the second guide groove (8) intersect, and is located at the top of the main body (3) of the impeller structure (1) of the impeller assembly (100). A fluid inlet is provided, and a fluid outlet is provided at the bottom of the main body 3 of the impeller structure 1, so that the fluid flows in from the inlet at the top of the main body 3 and flows along the surface of the main body 3. and sequentially flows out through the outlet at the bottom of the main body 3, the second guide groove 8 on the inside, the first guide groove 7, and the second guide groove 8 on the outside, and the first The center line of the guide groove (7) is deflected in the direction opposite to the rotation direction of the impeller structure (1), and the center line of the second guide groove (8) is deflected in the direction of rotation of the impeller structure (1).

In this embodiment, based on the arrangement direction in FIG. 2, the impeller structure 1 rotates in the instantaneous hand direction about the axis of the main body 3.

In this embodiment, the size of the main body 3 gradually increases from the upper part of the main body 3 toward the lower part of the main body 3, the main body 3 forms a truncated cone shape, and the surface of the main body 3 is curved. am. The meridional flow passage line from the inlet to the outlet of the main body 3 is an arcuate curve similar to an inwardly curved circular arc.

In this embodiment, the blade angle in any flow surface of the curved blade 4 first gradually decreases from the inlet to the outlet and then gradually increases, and the blade angle is the tangent of the surface arc of the curved blade 4 and the impeller structure. It is an included angle of the axial plane of (1) and takes a positive value.

In this embodiment, the gap between the curved blade 4 and the housing changes continuously and smoothly from the inlet to the outlet.

In this embodiment, the blade angle at the inlet position is 20 - 80°, the blade angle at the outlet position is 0 - 30°, and the minimum blade angle is 0 - 30°. The angle distribution of the blade angle is related to the pneumatic load distribution of the rear curved blade (4), and based on the fluid simulation results among the rear curved blades (4), the angle distribution of the blade angle is adjusted to ensure that the fluid flow is excellent with the rear curved blade (4). By realizing the coupling, it is ensured that the curved blade 4 acts efficiently on the fluid.

In this embodiment, the included angle (i.e. β ₂ ) between the center line of the first guide groove 7 and the radial reflection of the central axis of the main body 3 is 15 - 50°. The included angles (i.e. β ₁ and β ₃ ) between the center line of the second guide groove 8 and the radial reflection of the central axis of the main body 3 are 35 - 80°. Specifically, referring to FIG. 3, β ₁ is the angle between the center line L1 and the radial line R1 of the inner second guide groove 8, and β ₂ is the center line of the first guide groove 7 ( It is the angle between L2) and the radial line (R2), and β ₃ is the angle between the center line (L3) of the outer second guide groove (8) and the radial line (R3). The radial line R1, R2, and R3 are all lines along the radial direction starting from the central axis of the main body 3. The intersection of the center line L1 and the radial line R1 of the second guide groove 8 of the second baffle 6 of the inner layer is located on the circumference of the inner wall of the second baffle 6 of the inner layer, and the first The intersection point of the center line (L2) and the radial line (R2) of the guide groove (7) is located on the circumference of the inner wall of the first baffle (5), and the second guide groove of the second baffle (6) of the outer layer ( 8), the intersection point of the center line L3 and the radial line R3 is located on the circumference of the inner wall of the second baffle 6 of the outer layer.

The rotation direction of the impeller assembly 100 is as shown by the arrow in FIG. 3, and in this embodiment, the fluid load distribution of the curved blade 4 is controlled by adjusting the blade angle on the one hand, and the curved blade is controlled through the blade angle distribution. (4) rotates to realize excellent coupling with the flow of fluid, so that the curved blade (4) installed on the main body (3) acts on the fluid more efficiently, and on the other hand, the first baffle (5) A first guide groove (7) is provided in the second baffle (6), and a second guide groove (8) is provided in the second baffle (6), so that the fluid flows through the directions of the first guide groove (7) and the second guide groove (8). Reduces power loss when passing through the first baffle (5) and the second baffle (6). Specifically, the second baffle 6 fixed to the housing structure 2 is static, and the center line of the second guide groove 8 is deflected in the rotation direction of the impeller structure 1, thereby causing the fluid to change direction significantly. Ensure that the second guide groove (8) can be passed smoothly without any changes. The first baffle (5) fixed to the impeller structure (1) rotates together according to the impeller structure (1), so that the remaining portion except the first guide groove (7) is regarded as an extension of the curved blade (4), The first guide groove 7 is also considered to have a curved structure, which is more advantageous in acting on the fluid.

After the fluid is dispersed in the dispersion area between the first baffle (5) and the second baffle (6), it still has sufficient power and can be discharged in a centrifugal manner to the outside of the outermost second baffle (6). There is no need to further increase the material discharge blade acting on the fluid, which reduces the interference with the fluid in the material discharge area as much as possible, ensures that the fluid pressure in the material discharge area is maintained uniform and stable, and ensures that the fluid has a stable flow speed. It can be transmitted to, and vibration and noise caused by pulsation have been eliminated.

Example 2

This embodiment provides a mixing device including the impeller assembly 100 of Example 1.

In this specification, the principles and embodiments of the present application have been described through specific examples, and the description of the above embodiments is for understanding the method and core idea of the present application, and at the same time, for those skilled in the art, the present application Based on the idea, both the specific embodiment and the scope of application can be changed. In light of the above, the contents of this specification should not be construed as limiting the present application.

100: Impeller assembly 1: Impeller structure
2: Housing structure 3: Main body
4: Rear curved blade 5: First baffle
6: 2nd baffle 7: 1st guide groove
8: Second guide groove

Claims (7)

As an impeller assembly,
It includes a relatively rotating impeller structure and a housing structure, wherein the impeller structure includes a main body, a plurality of curved blades are installed on the surface of the main body along the circumferential direction of the main body, and at least one layer is located on the lower part of the main body. A first baffle is installed, the first baffle is installed on the outside of each of the curved blades, the housing structure includes at least one layer of a second baffle, and the second baffle is on the inside of the first baffle. and/or located on the outside, a plurality of first guide grooves are provided in the first baffle, and a plurality of second guide grooves are provided in the second baffle, so that fluid flows in from the inlet at the top of the main body, flows along the surface of the body and flows out through an outlet at the bottom of the main body, the first guide groove, and the second guide groove, and the center line of the first guide groove is biased in a direction opposite to the rotation direction of the impeller structure. , Impeller assembly, characterized in that the center line of the second guide groove is biased in the rotation direction of the impeller structure. According to paragraph 1,
An impeller assembly, wherein the size of the main body gradually increases from the upper part of the main body to the lower part of the main body, and the surface of the main body is curved. According to paragraph 1,
The blade angle in any flow surface of the curved blade first gradually decreases from the inlet to the outlet and then gradually increases, and the blade angle is an included angle between the tangent of the arc of the curved blade surface and the axial plane of the impeller structure. Featured impeller assembly. According to paragraph 3,
An impeller assembly, characterized in that the angle of the blade angle at the inlet position is 20 - 80°, and the angle of the blade angle at the outlet position is 0 - 30°. According to paragraph 1,
An impeller assembly, characterized in that the included angle between the center line of the first guide groove and the radial reflection of the central axis of the main body is 15-50°. According to paragraph 1,
An impeller assembly, characterized in that the included angle between the center line of the second guide groove and the radial reflection of the central axis of the main body is 35 - 80°. A mixing device comprising an impeller assembly according to any one of claims 1 to 6.