CN219839191U - Novel anti-blocking vacuum feeding machine - Google Patents

Abstract

The utility model discloses a novel anti-blocking vacuum feeding machine, which comprises a feeding machine shell, a discharging pipe, a supporting column, a sealing cover, a vacuum pump, a vibrating conveying filter ring structure, a vibrating feeding conveying pipe structure and a storage box, wherein the discharging pipe is connected to the middle position of the bottom end of the feeding machine shell in a threaded manner; support columns are fixed on the periphery of the bottom end of the shell of the feeding machine through bolts respectively; the upper end bolt of the feeding machine shell is fixedly provided with a sealing cover. The feeding machine shell, the discharging pipe, the first fixing ring, the elastic fixing piece, the second fixing ring, the hanging plate, the vibrator, the fixed vibration rod and the first spring column are mutually matched, so that the fixed vibration rod and the first spring column are driven to vibrate in the feeding machine shell through the vibrator in the using process, and material agglomeration or material adhesion on the inner wall of the feeding machine shell in the feeding process is prevented.

Description

Novel anti-blocking vacuum feeding machine

Technical Field

The utility model belongs to the technical field of material conveying equipment, and particularly relates to a novel anti-blocking vacuum feeding machine.

Background

The vacuum feeder is also called as a vacuum conveyor, and is dust-free closed pipeline conveying equipment for conveying particles or powdery materials by means of vacuum suction, gas in a pipeline is formed to flow by utilizing the air pressure difference of vacuum in an environment space, the powdery materials are driven to move, and accordingly powder conveying is completed.

Disclosure of Invention

The technical problems to be solved by the utility model are as follows: the utility model provides a novel prevent stifled vacuum feeder through setting up inside vibrations mediation mechanism at the in-process of material loading, conveniently prevents material caking or material adhesion at the device inner wall at the in-process of material loading, influences the in-process of material loading efficiency and sets up the inside vibration mechanism of inlet pipe at the in-process of material loading, conveniently improves the purpose of material conveying speed at the in-process of material loading.

In order to solve the technical problems, the utility model adopts the following technical scheme: the novel anti-blocking vacuum feeding machine comprises a feeding machine shell, wherein a discharging pipe is connected to the middle position of the bottom end of the feeding machine shell in a threaded manner; support columns are fixed on the periphery of the bottom end of the shell of the feeding machine through bolts respectively; the upper end bolt of the feeding machine shell is fixedly provided with a sealing cover; the right side of the upper end of the sealing cover is fixedly provided with a vacuum pump by bolts, and is characterized in that a vibration conveying filter ring structure is fixed in the middle position inside the shell of the feeding machine; the right lower part of the shell of the feeding machine is provided with a vibration feeding conveying pipe structure; the outer wall of the bottom end of the vibratile feeding conveying pipe structure is provided with a storage box.

Preferably, the vibration conveying filter ring structure comprises a first fixed ring, and elastic fixing sheets are respectively fixed on the upper parts of the inner walls of the first fixed ring through bolts; a second fixing ring is fixed at the middle position of the bottom of the inner wall of the first fixing ring by using an extension screw; a hanging plate is fixed between the elastic fixing plates through bolts; a vibrator is fixed at the middle position of the bottom end of the suspension plate through bolts; a fixed vibrating rod is fixed at the middle position of the bottom end of the vibrator through bolts; the first spring column is connected between the fixed vibration rods in a threaded manner.

Preferably, the vibratable feeding conveying pipe structure comprises an inverted L-shaped feeding pipe, and a second spring column is fixed on the right side of the top end of the inner wall of the inverted L-shaped feeding pipe through bolts; a third spring column is fixed on the upper part of the right inner wall of the inverted L-shaped feeding pipe through bolts; a longitudinal vibration rod penetrates through the middle position inside the right side of the inverted L-shaped feeding pipe; the middle position inside the upper end of the inverted L-shaped feeding pipe transversely penetrates through the transverse vibrating rod.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, the shell of the feeding machine, the discharging pipe, the first fixing ring, the elastic fixing piece, the second fixing ring, the hanging plate, the vibrator, the fixed vibration rod and the first spring column are mutually matched, so that the fixed vibration rod and the first spring column are driven to vibrate in the shell of the feeding machine through the vibrator in the using process, and material agglomeration or material adhesion on the inner wall of the shell of the feeding machine in the feeding process is prevented.

According to the utility model, the arrangement of the inverted L-shaped feeding pipe, the second spring column, the third spring column, the longitudinal vibration rod and the transverse vibration rod in a mutually matched manner is beneficial to preventing caking of materials on the inner wall of the inverted L-shaped feeding pipe in the feeding process by arranging the longitudinal vibration rod and the transverse vibration rod in the inverted L-shaped feeding pipe in the feeding process, so that the purpose of improving the conveying speed of the materials is achieved.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a schematic structural view of the shakable delivery filter ring structure of the present utility model.

Fig. 3 is a schematic structural view of a shakable feed conveyor pipe structure according to the present utility model.

In fig. 1 to 3:

1. a feeder housing; 2. a discharge pipe; 3. a support column; 4. sealing cover; 5. a vacuum pump; 6. a vibratable delivery filter ring structure; 61. a first fixing ring; 62. an elastic fixing piece; 63. a second fixing ring; 64. a hanging plate; 65. a vibrator; 66. fixing a vibration rod; 67. a first spring post; 7. a vibratable feed delivery pipe structure; 71. an inverted L-shaped feed tube; 72. a second spring post; 73. a third spring post; 74. a longitudinal vibration rod; 75. a transverse vibrating rod; 8. a storage box.

Detailed Description

The utility model is described in detail below with reference to the attached drawing figures:

as shown in fig. 1 and fig. 2, the novel anti-blocking vacuum feeding machine comprises a feeding machine shell 1, a discharging pipe 2, a supporting column 3, a sealing cover 4, a vacuum pump 5, a vibrating conveying filter ring structure 6, a vibrating feeding conveying pipe structure 7 and a storage box 8, wherein the discharging pipe 2 is in threaded connection with the middle position of the bottom end of the feeding machine shell 1; the periphery of the bottom end of the feeding machine shell 1 is fixedly provided with support columns 3 through bolts respectively; the upper end of the feeding machine shell 1 is fixedly provided with a sealing cover 4 through bolts; the right side of the upper end of the sealing cover 4 is fixedly provided with a vacuum pump 5 through bolts; a vibration conveying filter ring structure 6 is fixed in the middle position inside the feeding machine shell 1; the lower part of the right side of the feeding machine shell 1 is provided with a vibratable feeding conveying pipe structure 7; the outer wall of the bottom end of the vibratable feeding conveying pipe structure 7 is provided with a storage box 8; the vibration conveying filter ring structure 6 comprises a first fixed ring 61, an elastic fixing piece 62, a second fixed ring 63, a hanging plate 64, a vibrator 65, a fixed vibration rod 66 and a first spring column 67, wherein the upper part of the inner wall of the first fixed ring 61 is respectively and fixedly provided with the elastic fixing piece 62 through bolts; a second fixing ring 63 is fixed at the middle position of the bottom of the inner wall of the first fixing ring 61 by using an extension screw; a hanging plate 64 is fixed between the elastic fixing plates 62 through bolts; a vibrator 65 is fixed at the middle position of the bottom end of the suspension plate 64 through bolts; a fixed vibration rod 66 is fixed at the middle position of the bottom end of the vibrator 65 through bolts; a first spring column 67 is connected between the fixed vibration rods 66 in a threaded manner; when the feeding machine is used, the feeding machine shell 1 is fixed at a proper position, an external power supply and external control equipment are connected through an external lead, and the external pipeline is used for connection between the equipment, when feeding is performed, the vacuum pump 5 is controlled to start working, so that the inside of the feeding machine shell 1 is vacuumized, then materials enter the inside of the feeding machine shell 1, the materials are output through the discharging pipe 2, the vibrator 65 is controlled to start working in the process of outputting the materials, the fixed vibration rod 66 and the first spring column 67 are driven to vibrate in the inside of the materials, then the feeding work is realized, and the materials are smashed and prevented from being blocked through the vibration of the protrusions arranged on the outer wall of the fixed vibration rod 66 in the vibration process.

In this embodiment, referring to fig. 3, the vibratable feeding pipe structure 7 includes an inverted L-shaped feeding pipe 71, a second spring post 72, a third spring post 73, a longitudinal vibration rod 74 and a transverse vibration rod 75, where the second spring post 72 is bolted to the right side of the top end of the inner wall of the inverted L-shaped feeding pipe 71; a third spring column 73 is fixed on the upper part of the right inner wall of the inverted L-shaped feeding pipe 71 through bolts; a longitudinal vibration rod 74 penetrates through the middle position inside the right side of the inverted L-shaped feeding pipe 71; a transverse vibration rod 75 transversely penetrates through the middle position in the upper end of the inverted L-shaped feeding pipe 71; meanwhile, in the feeding process, the second spring column 72 and the third spring column 73 are respectively arranged at the top end of the longitudinal vibration rod 74 and the right end of the transverse vibration rod 75 in the process of sucking materials through the inverted-L-shaped feeding pipe 71, the longitudinal vibration rod 74 and the transverse vibration rod 75 are driven to vibrate through power generated during material movement, the phenomenon that the inverted-L-shaped feeding pipe 71 is blocked in the feeding process is prevented, and therefore vacuum feeding work is completed.

In this embodiment, specifically, the support columns 3 are three and are arranged in a triangle shape; the connecting pipe arranged at the left end of the vacuum pump 5 penetrates through the middle position of the inside of the sealing cover 4 and is communicated with the inside of the feeding machine shell 1; the sealing ring is arranged at the joint of the feeding machine shell 1 and the sealing cover 4.

In this embodiment, specifically, the vibrator 65 slides through the inner middle position of the second fixing ring 63; the elastic fixing piece 62 is a cuboid stainless steel sheet with elasticity; the fixed vibrating rod 66 is a cylindrical stainless steel rod with a convex outer wall.

In this embodiment, specifically, the first fixing ring 61 is fixed in a middle position of the inner wall of the feeder housing 1 by bolts; the fixed vibration rod 66 and the first spring column 67 penetrate through the middle position inside the bottom end of the feeder casing 1; the vibrator 65 is arranged at an inner middle position of the feeder housing 1.

In this embodiment, specifically, the second spring post 72 is screwed to the outer wall of the upper end of the longitudinal vibration rod 74; the third spring post 73 is connected to the outer wall of the right end of the transverse vibration rod 75 in a threaded manner; the right end of the transverse vibration rod 75 penetrates through the upper end inner middle position of the longitudinal vibration rod 74.

In this embodiment, specifically, the left end of the inverted L-shaped feeding pipe 71 is screwed to the lower right side of the feeder housing 1 and is disposed in communication with the lower right side; the lower end of the inverted L-shaped feeding pipe 71 is inserted into the left side of the middle position inside the storage box 8.

In the utility model, when the feeding machine is used, the feeding machine shell 1 is fixed at a proper position, an external power supply and external control equipment are connected by using an external lead, and equipment is connected by using an external pipeline, when feeding is performed, the vacuum pump 5 is controlled to start working, so that the inside of the feeding machine shell 1 is vacuumized, then materials enter the inside of the feeding machine shell 1, and the discharging pipe 2 is used for carrying out material output working, in the process of outputting materials, the vibrator 65 is controlled to start working, the fixed vibration rod 66 and the first spring column 67 are driven to vibrate the inside of the materials, then feeding working is realized, the materials are vibrated by the protrusions arranged on the outer wall of the fixed vibration rod 66 in the process of vibrating, the materials are crushed to prevent blockage, and meanwhile, in the process of feeding the materials is performed by the inverted L-shaped feeding pipe 71, the top end of the longitudinal vibration rod 74 and the right end of the transverse vibration rod 75 are respectively provided with the second spring column 72 and the third spring column 73, and the longitudinal vibration rod 74 and the transverse vibration rod 75 are pushed by power generated when the materials move, so that the phenomenon of blocking the feeding pipe 71 in the process of feeding is prevented from being in the process of pouring L-shaped.

By using the technical scheme of the utility model or under the inspired by the technical scheme of the utility model, a similar technical scheme is designed by a person skilled in the art, so that the technical effects are achieved, and the technical effects fall into the protection scope of the utility model.

Claims (5)

1. The novel anti-blocking vacuum feeding machine comprises a feeding machine shell (1), wherein a discharging pipe (2) is connected with the middle position of the bottom end of the feeding machine shell (1) in a threaded manner; support columns (3) are fixed on the periphery of the bottom end of the feeding machine shell (1) through bolts respectively; the upper end bolt of the feeding machine shell (1) is fixedly provided with a sealing cover (4); a vacuum pump (5) is fixed on the right side bolt of the upper end of the sealing cover (4); the novel anti-blocking vacuum feeder is characterized in that a vibration conveying filter ring structure (6) is fixed in the middle position inside a feeder shell (1); the lower part of the right side of the feeding machine shell (1) is provided with a vibration feeding conveying pipe structure (7); the outer wall of the bottom end of the vibratable feeding conveying pipe structure (7) is provided with a storage box (8).

2. The novel anti-blocking vacuum feeding machine according to claim 1, wherein the vibratable conveying filter ring structure (6) comprises a first fixing ring (61), and elastic fixing sheets (62) are respectively and fixedly arranged on the upper part of the inner wall of the first fixing ring (61) in a bolt manner; a second fixing ring (63) is fixed at the middle position of the bottom of the inner wall of the first fixing ring (61) by using an extension screw; a hanging plate (64) is fixed between the elastic fixing plates (62) through bolts; a vibrator (65) is fixed at the middle position of the bottom end of the suspension plate (64) through bolts; a fixed vibrating rod (66) is fixed at the middle position of the bottom end of the vibrator (65) through bolts; a first spring column (67) is connected between the fixed vibrating rods (66) in a threaded mode.

3. The novel anti-blocking vacuum feeding machine according to claim 1, wherein the vibratable feeding conveying pipe structure (7) comprises an inverted-L-shaped feeding pipe (71), and a second spring column (72) is fixed on the right side of the top end of the inner wall of the inverted-L-shaped feeding pipe (71) through bolts; a third spring column (73) is fixed on the upper part of the right inner wall of the inverted L-shaped feeding pipe (71) through bolts; a longitudinal vibration rod (74) penetrates through the middle position inside the right side of the inverted L-shaped feeding pipe (71); the middle position inside the upper end of the inverted L-shaped feeding pipe (71) is transversely penetrated by a transverse vibration rod (75).

4. The novel anti-blocking vacuum feeding machine according to claim 2, wherein the first fixing ring (61) is fixed at the middle position of the inner wall of the feeding machine shell (1) through bolts; the fixed vibration rod (66) and the first spring column (67) penetrate through the middle position inside the bottom end of the feeding machine shell (1); the vibrator (65) is arranged at the middle position inside the upper casing (1).

5. A novel anti-blocking vacuum feeding machine as claimed in claim 3, wherein the left end of the inverted-L-shaped feeding pipe (71) is connected with the lower right side of the feeding machine shell (1) in a threaded manner and is communicated with the lower right side of the feeding machine shell; the lower end of the inverted L-shaped feeding pipe (71) is inserted into the left side of the middle position inside the storage box (8).