CN220635229U - Feeding device for powder cleaning machine - Google Patents

Abstract

The utility model provides a feeding device for a powder cleaning machine, which relates to the technical field of powder cleaning machines and comprises a shell assembly and a vibrating mechanism, wherein a feeding part which is connected in a sleeved mode is arranged on the inner side of the shell assembly, the vibrating mechanism is arranged on the outer side of the feeding part, the vibrating mechanism comprises a fixed block, a vibrating cabin, a driving wheel set, a separation frame, a vibrating motor, a central shaft and an eccentric wheel set, and the fixed block is arranged on the outer side of the feeding part; the utility model mainly utilizes the vibrating mechanism to generate vibrating force, so that the sieve plate can primarily sieve the injected raw materials, and the driving motor on the motor base outputs power to drive the output end to drive the rotating shaft, the spline shaft sleeve and the lower connecting shaft to coaxially rotate, so that the raw materials can be thrown onto the convex wall at the inner side of the jacket cabin under the mutual matching of the round platform cabin and the jet port to achieve the effect of crushing, thereby facilitating the subsequent deep processing of the powder cleaning machine and obviously improving the processing quality and efficiency.

Description

Feeding device for powder cleaning machine

Technical Field

The utility model relates to the technical field of powder cleaning machines, in particular to a feeding device for a powder cleaning machine.

Background

The machine for separating pure and purer endosperm particles from ground material in pulverizer is composed of one screen body with two layers of screen surfaces or two screens body with two or three layers of screen surfaces, air channel and air chamber, and features that each layer of screen surface is made up of four screens with different meshes, and the screen body is supported by four rubber springs and driven by eccentric vibration motor.

When the existing feeding device is used, raw materials are generally placed into the inner side of a powder cleaning machine and are deeply processed by the powder cleaning machine so as to achieve the effect of purification, as disclosed in application number CN202122222509.9, the feeding device for the powder cleaning machine relates to the technical field of powder cleaning machines and comprises a main frame, a first motor is arranged in the main frame, a first conical gear is sleeved on the surface of an output end of the first motor, a shaft lever is inserted into the inner side of the main frame through a bearing, and second conical teeth are sleeved on the surface of the shaft lever at equal intervals; however, in the above-mentioned technology, although the quantitative conveying effect is provided, the material is directly injected into the powder cleaning machine, so that it is difficult to improve the quality and efficiency of the material, and therefore, the present utility model proposes a feeding device for the powder cleaning machine to solve the problems in the prior art.

Disclosure of Invention

According to the feeding device for the powder cleaning machine, after vibration force is generated by the vibration mechanism, the sieve plate can primarily screen injected raw materials, and the driving motor on the motor base outputs power to drive the output end to drive the rotating shaft, the spline shaft sleeve and the lower connecting shaft to coaxially rotate, so that the raw materials can be thrown onto the protruding wall at the inner side of the sleeve cabin under the mutual matching of the round platform cabin and the injection port to achieve the crushing effect, and the subsequent deep processing of the powder cleaning machine is facilitated, and the processing quality and efficiency are obviously improved.

In order to achieve the purpose of the utility model, the utility model is realized by the following technical scheme: the feeding device for the powder cleaning machine comprises a shell assembly and a vibrating mechanism, wherein a feeding part which is connected in a sleeved mode is arranged on the inner side of the shell assembly, and the vibrating mechanism is arranged on the outer side of the feeding part;

the vibration mechanism comprises a fixed block, a vibration cabin, a driving wheel group, a separation frame, a vibration motor, a central shaft and an eccentric wheel group, wherein the fixed block is arranged on the outer side of the feeding component, one end of the fixed block is provided with the vibration cabin, the outer end of the vibration cabin is provided with the driving wheel group, the input end of the driving wheel group penetrates through the separation frame and is connected with the vibration motor, the central shaft is arranged in the vibration cabin, and the eccentric wheel group is arranged on the outer side of the central shaft.

As a preferred implementation mode of the utility model, a plurality of groups of eccentric wheel groups are distributed in parallel by the central axis of the central shaft, and the eccentric wheel groups are in a fan-shaped structure.

As a preferred embodiment of the utility model, the shell assembly comprises a bottom connecting rod, side frames, a sleeve cabin, a protruding wall, an assembling disc, a central sleeve and a bearing sleeve, wherein the side frames are arranged above two ends of the bottom connecting rod, the sleeve cabin is arranged on the upper inner side of the side frames, and the protruding wall distributed in an annular mode is arranged on the inner side of the sleeve cabin.

As a preferred embodiment of the utility model, a bolt-assembled assembly disk is arranged above the cabin, a center sleeve is arranged on the inner side of the assembly disk, and a bearing sleeve is arranged below the center sleeve.

As a preferred embodiment of the utility model, the feeding component comprises a fixed pipe, an upper cabin body, a side pipe, a feeding hole, a motor base, a driving motor, a rotating shaft, a spline shaft sleeve, a sieve plate, a lower connecting shaft, a round platform cabin and a jet hole, wherein the fixed pipe is arranged on the top side of the central sleeve, the upper cabin body is arranged above the fixed pipe, one side of the upper cabin body is connected with the side pipe for installing the feeding hole in a sleeved mode, and the top side of the upper cabin body is provided with the motor base for installing the driving motor.

As a preferred embodiment of the present utility model, the output end of the driving motor is connected with a rotating shaft through the motor base, a spline shaft sleeve is arranged below the rotating shaft, a screen plate is arranged at the outer side of the spline shaft sleeve, a lower connecting shaft is connected with the spline shaft sleeve through the screen plate, a round platform cabin is arranged below the lower connecting shaft, and a jet port is arranged at the outer side of the round platform cabin.

The beneficial effects of the utility model are as follows:

the utility model mainly utilizes the vibrating mechanism to generate vibrating force, so that the sieve plate can primarily sieve the injected raw materials, and the driving motor on the motor base outputs power to drive the output end to drive the rotating shaft, the spline shaft sleeve and the lower connecting shaft to coaxially rotate, so that the raw materials can be thrown onto the convex wall at the inner side of the jacket cabin under the mutual matching of the round platform cabin and the jet port to achieve the effect of crushing, thereby facilitating the subsequent deep processing of the powder cleaning machine and obviously improving the processing quality and efficiency.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic bottom perspective view of the present utility model;

FIG. 3 is a schematic perspective view of a jacket assembly according to the present utility model;

FIG. 4 is a schematic perspective view of a feed member of the present utility model;

fig. 5 is a schematic structural view of a vibration mechanism according to the present utility model.

Wherein: 1. a housing assembly; 101. a bottom link; 102. a side frame; 103. a cabin; 104. a raised wall; 105. a mounting plate; 106. a central sleeve; 107. a bearing sleeve; 2. a feed member; 201. a fixed tube; 202. an upper cabin body; 203. a side pipe; 204. a feed inlet; 205. a motor base; 206. a driving motor; 207. a rotation shaft; 208. a spline shaft sleeve; 209. a sieve plate; 2010. a lower connecting shaft; 2011. round platform cabin; 2012. a jet port; 3. a vibration mechanism; 301. a fixed block; 302. a vibration cabin; 303. a driving wheel group; 304. a partition frame; 305. a vibration motor; 306. a central shaft; 307. an eccentric wheel set.

Detailed Description

The present utility model will be further described in detail with reference to the following examples, which are only for the purpose of illustrating the utility model and are not to be construed as limiting the scope of the utility model.

According to fig. 1-5, this embodiment provides a feeding device for a powder cleaning machine, which comprises a casing assembly 1 and a vibration mechanism 3, wherein a feeding part 2 connected in a sleeved manner is arranged on the inner side of the casing assembly 1, and the vibration mechanism 3 is arranged on the outer side of the feeding part 2;

the vibration mechanism 3 comprises a fixed block 301, a vibration cabin 302, a driving wheel group 303, a separation frame 304, a vibration motor 305, a central shaft 306 and an eccentric wheel group 307, wherein the fixed block 301 is arranged on the outer side of the feeding component 2, one end of the fixed block 301 is provided with the vibration cabin 302, the outer end of the vibration cabin 302 is provided with the driving wheel group 303, the input end of the driving wheel group 303 penetrates through the separation frame 304 and is connected with the vibration motor 305, the central shaft 306 is arranged in the vibration cabin 302, and the eccentric wheel group 307 is arranged on the outer side of the central shaft 306.

The eccentric wheel sets 307 are arranged in parallel with the central axis of the central shaft 306, and the eccentric wheel sets 307 are in a fan-shaped structure.

In this embodiment, when the blanking is needed, the output power of the vibration motor 305 is started to drive the output end of the vibration motor 305 to run through the output end of the vibration motor 305, so that the output end of the vibration motor 305 runs and then drives the driving wheel set 303 at the inner side of the separation frame 304 to output and drive, and the central shaft 306 in the vibration cabin 302 is driven to rotate through the output and drive of the driving wheel set 303, so that the central shaft 306 drives the eccentric wheel sets 307 in parallel distribution to rotate after rotating to generate vibration force.

The casing assembly 1 comprises a bottom connecting rod 101, side frames 102, a sleeve 103, a protruding wall 104, a mounting plate 105, a central sleeve 106 and a bearing sleeve 107, wherein the side frames 102 are arranged above two ends of the bottom connecting rod 101, the sleeve 103 is arranged on the upper inner side of the side frames 102, and the protruding wall 104 distributed in an annular mode is arranged on the inner side of the sleeve 103.

In this embodiment, first, the upper bottom connecting rod 101 is placed at the feeding position, and the side frames 102 are installed at two ends of the bottom connecting rod 101, so that the capsule 103 is placed above the feeding position, and the protruding wall 104 is disposed at the inner side of the capsule 103, so that the impacted raw materials can be effectively crushed initially.

A bolt-fitted fitting disk 105 is provided above the nacelle 103, and a center bushing 106 is provided on the inner side of the fitting disk 105, and a bearing bushing 107 is provided below the center bushing 106.

In this embodiment, after the installation of the capsule 103 is completed, an assembly disc 105 is disposed on the top side of the capsule 103, the central sleeve 106 is sealed and sleeved by the assembly disc 105, and a bearing sleeve 107 is installed below the central sleeve 106 to connect the circular truncated cone 2011 and the injection port 2012 in a bearing manner so as to facilitate rotation.

The feeding component 2 comprises a fixed pipe 201, an upper cabin 202, a side pipe 203, a feeding port 204, a motor base 205, a driving motor 206, a rotating shaft 207, a spline shaft sleeve 208, a screen plate 209, a lower connecting shaft 2010, a round platform cabin 2011 and a jet port 2012, wherein the fixed pipe 201 is arranged on the top side of the central sleeve 106, the upper cabin 202 is arranged above the fixed pipe 201, one side of the upper cabin 202 is sleeved with the side pipe 203 for installing the feeding port 204, and the top side of the upper cabin 202 is provided with the motor base 205 for installing the driving motor 206.

In this embodiment, after the central shaft 306 and the eccentric wheel set 307 rotate to generate vibration force, raw materials to be input are input into the side pipe 203 through the feed inlet 204 above one end of the side pipe 203, are input into the upper cabin 202 through the introduction of the side pipe 203 under the action of the vibration force, and fall onto the screen plate 209 below the fixed pipe 201 after entering into the upper cabin 202, so that the screened raw materials enter into the round platform cabin 2011 below the screen plate 209 under the interaction of the vibration force and the screen plate 209.

The output of driving motor 206 runs through motor base 205 and is connected with rotation axis 207, and the below of rotation axis 207 is provided with spline shaft sleeve 208, and the outside side of spline shaft sleeve 208 is provided with screen 209, and spline shaft sleeve 208 runs through screen 209 and is connected with lower connecting axle 2010, and the below of lower connecting axle 2010 is provided with round platform cabin 2011, and the outside side of round platform cabin 2011 is provided with jet 2012.

In this embodiment, the driving motor 206 is used to output power to drive the driving motor 206 to operate, the driving motor 206 is used to drive the rotation shaft 207 to rotate after the driving motor 206 is operated, so that the lower connecting shaft 2010 below the screen plate 209 rotates at a high speed after the rotation shaft 207 and the spline shaft sleeve 208 are matched with each other, the round platform cabin 2011 is driven to rotate at a high speed by the high speed rotation of the lower connecting shaft 2010, and thus the round platform cabin 2011 is used to make materials discharged from the device through the injection port 2012 after rotating, and the protruding wall 104 on the inner side of the impact sleeve cabin 103 is impacted to achieve the effect of preliminary crushing so as to facilitate the subsequent deep processing.

The working principle of the feeding device for the powder cleaning machine is as follows: firstly, an upper bottom connecting rod 101 is placed at a feeding position, a side frame 102 is installed at two ends of the bottom connecting rod 101, a cabin 103 is placed above the feeding position, as a convex wall 104 is arranged on the inner side of the cabin 103, the impacted raw materials can be effectively crushed initially, after the cabin 103 is installed, an assembly disc 105 is arranged on the top side of the cabin 103, a central sleeve 106 is sleeved and sealed through the assembly disc 105, a bearing sleeve 107 is installed below the central sleeve 106 to connect a round cabin 2011 with a jet 2012 in a bearing manner, so that the rotation is facilitated, when the blanking is needed, a vibrating motor 305 is started to output power to drive the output end of the vibrating motor 305 to operate through the output end of the vibrating motor 305, a driving wheel set 303 on the inner side of a partition frame 304 is driven to output and drive after the output end of the vibrating motor 305 operates, the central shaft 306 in the vibration cabin 302 is driven to rotate through the output transmission of the driving wheel group 303, so that the central shaft 306 rotates to drive a plurality of groups of eccentric wheel groups 307 which are distributed in parallel to rotate to generate vibration force, after the central shaft 306 and the eccentric wheel groups 307 rotate to generate vibration force, raw materials to be input are input into the side pipe 203 through the feed inlet 204 above one end of the side pipe 203, are input into the upper cabin 202 through the introduction of the side pipe 203 under the action of vibration force, fall onto the screen plate 209 below the fixed pipe 201 after entering into the upper cabin 202, are enabled to enter into the round platform cabin 2011 below the screen plate 209 under the interaction of the vibration force and the screen plate 209, then the output power of the driving motor 206 is used to drive the output end of the driving motor 206 to operate, the output end of the driving motor 206 is enabled to drive the rotation shaft 207 to rotate after the output end of the driving motor 206 operates, like this through the mutually supporting of rotation axis 207 and spline axle sleeve 208 back for lower connecting axle 2010 of sieve 209 below carries out high-speed rotation, drives round platform cabin 2011 high-speed rotation through the high-speed rotation of lower connecting axle 2010, and round platform cabin 2011 makes the material pass through jet 2012 discharge equipment like this after rotatory, strikes the protruding wall 104 of cover cabin 103 inboard side in order to reach preliminary broken effect, in order to carry out the depth processing subsequently.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a feeding device for powder cleaning machine, includes cover shell subassembly (1) and vibration mechanism (3), its characterized in that: the inner side of the shell assembly (1) is provided with a feeding component (2) which is connected in a sleeved mode, and the outer side of the feeding component (2) is provided with a vibrating mechanism (3);

the vibrating mechanism (3) comprises a fixed block (301), a vibrating cabin (302), a driving wheel group (303), a separation frame (304), a vibrating motor (305), a central shaft (306) and an eccentric wheel group (307), wherein the fixed block (301) is arranged on the outer side of the feeding part (2), one end of the fixed block (301) is provided with the vibrating cabin (302), the outer end of the vibrating cabin (302) is provided with the driving wheel group (303), the input end of the driving wheel group (303) penetrates through the separation frame (304) and is connected with the vibrating motor (305), the central shaft (306) is arranged inside the vibrating cabin (302), and the eccentric wheel group (307) is arranged on the outer side of the central shaft (306).

2. The feeding device for a powder cleaning machine according to claim 1, wherein: the eccentric wheel sets (307) are distributed in parallel by the central axis of the central shaft (306), and the eccentric wheel sets (307) are of a fan-shaped structure.

3. The feeding device for a powder cleaning machine according to claim 1, wherein: the shell assembly (1) comprises a bottom connecting rod (101), side frames (102), a sleeve cabin (103), protruding walls (104), an assembly disc (105), a center sleeve (106) and bearing sleeves (107), wherein the side frames (102) are arranged above two ends of the bottom connecting rod (101), the sleeve cabin (103) is arranged on the inner side of the side frames (102), and the protruding walls (104) distributed in an annular mode are arranged on the inner side of the sleeve cabin (103).

4. A feeding device for a powder cleaning machine according to claim 3, characterized in that: an assembling disc (105) assembled by bolts is arranged above the sleeve cabin (103), a center sleeve (106) is arranged on the inner side of the assembling disc (105), and a bearing sleeve (107) is arranged below the center sleeve (106).

5. A feeding device for a powder cleaning machine according to claim 3, characterized in that: the feeding component (2) comprises a fixed pipe (201), an upper cabin body (202), a side pipe (203), a feeding port (204), a motor base (205), a driving motor (206), a rotating shaft (207), a spline shaft sleeve (208), a sieve plate (209), a lower connecting shaft (2010), a round platform cabin (2011) and a jet port (2012), wherein the fixed pipe (201) is arranged on the top side of the central sleeve (106), the upper cabin body (202) is arranged above the fixed pipe (201), the side pipe (203) for installing the feeding port (204) is connected to one side of the upper cabin body (202) in a sleeved mode, and the motor base (205) for installing the driving motor (206) is arranged on the top side of the upper cabin body (202).

6. The feeding device for a powder cleaning machine according to claim 5, wherein: the output of driving motor (206) runs through motor base (205) is connected with rotation axis (207), just the below of rotation axis (207) is provided with spline shaft (208), the outside side of spline shaft (208) is provided with sieve (209), spline shaft (208) run through sieve (209) are connected with lower connecting axle (2010), just the below of lower connecting axle (2010) is provided with round platform cabin (2011), the outside side of round platform cabin (2011) is provided with jet (2012).