CN220072401U - Multistage separating mechanism for calcium oxide - Google Patents

Abstract

The utility model provides a multistage separation mechanism for calcium oxide. Including the separator box, a plurality of discharge gates have been seted up to separator box top fixedly connected with feeder hopper, a plurality of spouts have all been provided with the stock guide in the discharge gate, be provided with a plurality of spouts in the separator box, the equal fixedly connected with spring in both ends of spout, be provided with the filter screen in the spout, separator box internal rotation is connected with the pivot, fixedly connected with vibrating mass in the pivot, one side fixedly connected with baffle that the filter screen is close to the pivot, the outer end fixedly connected with drive wheel of pivot, be provided with the drive belt on the drive wheel, one of them pivot outer end is provided with the motor, separator box inboard bottom is provided with the fine material case. The utility model has the advantages that: the calcium oxide flows downwards along the inclined plane of the filter screen in the vibration process of the filter screen, flows out of the separation box from the corresponding discharge port, is convenient to receive and achieves the purpose of multistage separation, and is convenient and quick to use.

Description

Multistage separating mechanism for calcium oxide

Technical Field

The utility model relates to the technical field of separation mechanisms, in particular to a multi-stage separation mechanism for calcium oxide.

Background

Calcium oxide, which is an inorganic compound, has a chemical formula of CaO, is commonly known as quicklime, is a common building material, and can also be used as a raw material for industrial production.

The purity of the desired calcium oxide varies depending on the application, and therefore, the calcium oxide needs to be sieved. Most of the existing separating mechanisms for calcium oxide can not take out screened calcium oxide quickly and can not perform multi-stage screening well, so that the method is inconvenient to provide the calcium oxide raw materials meeting the requirements quickly according to different purposes. For this purpose, a multistage separation mechanism for calcium oxide is proposed for improvement.

Disclosure of Invention

The object of the present utility model is to solve at least one of the technical drawbacks.

Therefore, an object of the present utility model is to provide a multi-stage separation mechanism for calcium oxide, which solves the problems mentioned in the background art and overcomes the shortcomings in the prior art.

In order to achieve the above purpose, an embodiment of an aspect of the present utility model provides a multi-stage separation mechanism for calcium oxide, which comprises a separation box, wherein a feeding hopper is fixedly connected to the top of the separation box, a plurality of discharge ports are formed in two sides of the separation box, guide plates are arranged in the discharge ports, a plurality of sliding grooves are arranged in the separation box, springs are fixedly connected to two ends of the sliding grooves, a filter screen is arranged in the sliding grooves, a rotating shaft is rotatably connected to the separation box, a vibrating block is fixedly connected to the rotating shaft, a baffle is fixedly connected to one side of the filter screen, which is close to the rotating shaft, a driving wheel is fixedly connected to the outer end of the rotating shaft, a driving belt is arranged on the driving wheel, a motor is arranged at the outer end of one rotating shaft, and a polishing box is arranged at the bottom of the inner side of the separation box.

By any of the above schemes, preferably, the discharge ports are elongated holes and are arranged adjacently up and down.

By any of the above schemes, preferably, the guide plate is arranged at the bottom of the discharge hole and extends downwards and outwards from the inside of the discharge hole in an inclined manner, and the bottom of the separation box is provided with a box door.

The technical scheme is adopted: the separation box is used for providing working space for the separation structure and providing support for the separation structure so as to ensure the stable work of the separation structure. The feed hopper is used for injecting the calcium oxide raw material to be separated into the separation box. The discharge gate is used for supplying the calcium oxide outflow from the separator box after the screening to the staff carries out the receipts material. The long strip-shaped discharge hole is matched with the filter screen in width, so that calcium oxide on the whole filter screen can smoothly flow out of the discharge hole. The guide plate is used for guiding the calcium oxide raw material, and is convenient for the staff to receive the calcium oxide raw material. The box door position at the bottom of the separating box corresponds to the position of the concentrate box, so that a worker can conveniently take out the concentrate box.

By any of the above schemes, it is preferable that the number of the sliding grooves is consistent with the number of the discharging holes, and the sliding grooves are obliquely arranged in the separation box.

In any of the above schemes, it is preferable that the number of the filter screens is identical to that of the sliding grooves, and the filter screens are sequentially arranged from top to bottom according to the pore size.

The technical scheme is adopted: the chute is used for the filter screen to move in, the height of the chute is slightly larger than the thickness of the filter screen frame, and the length of the chute is longer than the length of the filter screen frame, so that the filter screen can move in all directions locally up, down, left and right. The chute is obliquely arranged, namely the filter screen is obliquely arranged, and the filter screen is obliquely arranged, so that the calcium oxide can flow on the filter screen conveniently. The multiple filter screens can carry out multistage separation work on the calcium oxide raw material, and the filter screens are arranged in sequence from top to bottom according to the pore size, so that the calcium oxide raw material with thicker grain diameter can be reserved on the filter screens with corresponding grain diameters and flow out from corresponding discharge holes. The calcium oxide with smaller particle size can continue to fall until being intercepted by the filter screen or falling into the concentrate box.

By any of the above schemes, preferably, both ends of the filter screen are fixedly connected with the springs, and the rotating shaft is rotatably connected with the separating box through the bearings.

It is preferable in any of the above-described aspects that the vibrating masses have a plurality of masses on each rotating shaft and are uniformly arranged around the rotating shaft.

The technical scheme is adopted: the two ends of the filter screen are connected with the springs, so that the filter screen can be supported by the springs and can be restored as soon as possible by the elasticity of the springs after moving. The pivot is used for installing the vibrating mass to drive the vibrating mass and rotate, the vibrating mass can drive the filter screen vibrations with the baffle cooperation, thereby realizes the purpose of dynamic screening, also can assist ejection of compact work. When the filter screen is used, the motor is started, the motor drives the rotating shaft to rotate through the driving wheel and the driving belt, the rotating shaft drives each filter screen to vibrate through the vibrating block and the baffle, the calcium oxide raw material to be separated is poured into the feeding hopper, falls into the separating box through the feeding hopper and is screened layer by the filter screen, after the calcium oxide raw material is intercepted by the filter screen, the calcium oxide raw material flows downwards along the inclined plane of the filter screen in the vibration process of the filter screen, flows out of the separating box from the corresponding discharge port, and is received at the discharge port. After the separation work is finished, the box door is opened, the fine material box is taken out, and the calcium oxide raw material with the finest grain diameter is collected.

Compared with the prior art, the utility model has the following advantages and beneficial effects:

1. this multistage separating mechanism that calcium oxide was used, through seting up a plurality of discharge gates in the both sides of separator box, the cooperation sets up the stock guide, the spout, a spring, the filter screen, pivot and vibrating piece and baffle, starter motor, the motor passes through the drive wheel, the drive belt drives the pivot and rotates, the pivot drives each filter screen through vibrating piece and baffle and vibrates, will wait to separate the calcium oxide raw materials and pour into the feeder hopper, the calcium oxide raw materials falls into the separator box through the feeder hopper, and by the filter screen screening layer upon layer, after it is intercepted by the filter screen, flow downwards along its inclined plane in the vibration process of filter screen, and flow out the separator box from the discharge gate that corresponds, connect the material at the discharge gate can. Receive the material convenient and realized multistage separation's purpose, convenient to use is swift.

2. This multistage separating mechanism that calcium oxide was used through setting up spout, spring, filter screen, pivot, vibrating mass, baffle, cooperation drive wheel, drive belt and motor, starts the motor, and the motor passes through a series of transmission structure and drives the filter screen and shake about in the spout, has realized the purpose of dynamic screening, and the screening effect is better.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic view of a first view structure according to the present utility model;

FIG. 2 is a schematic view of a second view angle structure according to the present utility model;

FIG. 3 is a schematic view of the present utility model in cross-section;

fig. 4 is a schematic view of the structure of the inside of the separator of the present utility model.

In the figure: 1-separating box, 2-feeding hopper, 3-discharge port, 4-stock guide, 5-box door, 6-chute, 7-spring, 8-filter screen, 9-spindle, 10-vibrating block, 11-baffle, 12-driving wheel, 13-driving belt, 14-motor, 15-fine material box.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present utility model and should not be construed as limiting the utility model.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

As shown in fig. 1-4, the utility model comprises a separation box 1, wherein the top of the separation box 1 is fixedly connected with a feed hopper 2, two sides of the separation box 1 are provided with a plurality of discharge ports 3, the discharge ports 3 are internally provided with guide plates 4, the separation box 1 is internally provided with a plurality of sliding grooves 6, two ends of each sliding groove 6 are fixedly connected with springs 7, a filter screen 8 is arranged in each sliding groove 6, the separation box 1 is rotationally connected with a rotating shaft 9, the rotating shaft 9 is fixedly connected with a vibrating block 10, one side, close to the rotating shaft 9, of the filter screen 8 is fixedly connected with a baffle 11, the outer end of the rotating shaft 9 is fixedly connected with a driving wheel 12, a driving belt 13 is arranged on the driving wheel 12, the outer end of one rotating shaft 9 is provided with a motor 14, and the inner bottom of the separation box 1 is provided with a polishing box 15.

Example 1: the discharge holes 3 are strip-shaped holes and are arranged adjacently up and down. The guide plate 4 is arranged at the bottom of the discharge hole 3 and extends downwards and outwards from the inside of the discharge hole 3 in an inclined manner, and the bottom of the separation box 1 is provided with a box door 5. The separating box 1 is used for providing a working space for the separating structure and providing support for the separating structure so as to ensure the stable work of the separating structure. The feed hopper 2 is used for injecting the calcium oxide raw material to be separated into the separation box 1. The discharge port 3 is used for the screened calcium oxide to flow out of the separation box 1 so as to be convenient for the staff to receive materials. The long strip-shaped discharge hole 3 is matched with the filter screen 8 in width, so that calcium oxide on the whole filter screen 8 can smoothly flow out from the discharge hole 3. The guide plate 4 is used for guiding the calcium oxide raw material, so that the worker can conveniently receive the calcium oxide raw material. The position of the box door 5 at the bottom of the separation box 1 corresponds to the position of the essence box 15, so that the staff can conveniently take out the essence box 15.

Example 2: the number of the sliding grooves 6 is consistent with that of the discharging holes 3, and the sliding grooves 6 are obliquely arranged in the separation box 1. The number of the filter screens 8 is consistent with that of the sliding grooves 6, and the filter screens 8 are sequentially arranged from top to bottom according to the pore size. The chute 6 is used for the filter screen 8 to move therein, the height of the chute is slightly larger than the thickness of the frame of the filter screen 8, and the length of the chute is longer than the length of the frame of the filter screen 8, so that the filter screen 8 can locally move in all directions up and down and left and right. The chute 6 is obliquely arranged, namely the filter screen 8 is obliquely arranged, and the obliquely arranged filter screen 8 can facilitate the original flow of the calcium oxide thereon. The multiple filter screens 8 can perform multistage separation on the calcium oxide raw materials, and the filter screens 8 are arranged in sequence from top to bottom according to the pore sizes, so that the calcium oxide raw materials with thicker particle sizes can be left on the filter screens 8 with corresponding particle sizes and flow out from the corresponding discharge holes 3. The finer size calcium oxide will continue to fall until it is caught by the screen 8 or falls into the head box 15.

Example 3: both ends of the filter screen 8 are fixedly connected with the springs 7, and the rotating shaft 9 is rotatably connected with the separation box 1 through a bearing. The vibrating blocks 10 are provided with a plurality of blocks on each rotating shaft 9 and are uniformly arranged around the rotating shafts 9. Both ends of the filter screen 8 are connected with the springs 7, so that the filter screen can be supported by the springs 7 and can be restored as soon as possible by the elasticity of the springs 7 after moving. The rotating shaft 9 is used for installing the vibrating block 10 and driving the vibrating block 10 to rotate, and the vibrating block 10 and the baffle 11 are matched to drive the filter screen 8 to vibrate, so that the purpose of dynamic screening is realized, and the discharging work can be assisted. When the separating box is used, the motor 14 is started, the motor 14 drives the rotary shaft 9 to rotate through the driving wheel 12 and the driving belt 13, the rotary shaft 9 drives each filter screen 8 to vibrate through the vibrating block 10 and the baffle 11, the calcium oxide raw material to be separated is poured into the feed hopper 2, falls into the separating box 1 through the feed hopper 2 and is screened layer by the filter screens 8, after the calcium oxide raw material is intercepted by the filter screens 8, the calcium oxide raw material flows downwards along the inclined planes of the filter screens 8 in the vibration process of the filter screens 8, flows out of the separating box 1 from the corresponding discharge holes 3, and is received at the discharge holes 3. After the separation work is completed, the box door 5 is opened, the essential box 15 is taken out, and the calcium oxide raw material with the finest grain size is collected.

The working principle of the utility model is as follows:

s1, starting a motor 14, wherein the motor 14 drives a rotating shaft 9 to rotate through a driving wheel 12 and a driving belt 13, and the rotating shaft 9 drives each filter screen 8 to vibrate through a vibrating block 10 and a baffle 11;

s2, pouring the calcium oxide raw material to be separated into a feed hopper 2, enabling the calcium oxide raw material to fall into a separation box 1 through the feed hopper 2, screening the calcium oxide raw material layer by a filter screen 8, enabling the calcium oxide raw material to flow downwards along an inclined plane of the filter screen 8 in the vibration process of the filter screen 8 after the calcium oxide raw material is intercepted by the filter screen 8, enabling the calcium oxide raw material to flow out of the separation box 1 from a corresponding discharge port 3, and receiving the calcium oxide raw material at the discharge port 3;

and S3, after the separation work is completed, opening the box door 5, taking out the fine material box 15, and collecting the calcium oxide raw material with the finest grain size.

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

1. this multistage separating mechanism that calcium oxide was used, through seting up a plurality of discharge gates 3 in the both sides of separator box 1, the cooperation sets up stock guide 4, spout 6, spring 7, filter screen 8, pivot 9 and vibrating piece 10 and baffle 11, starter motor 14, motor 14 passes through drive wheel 12, drive belt 13 drives pivot 9 and rotates, pivot 9 drives each filter screen 8 through vibrating piece 10 and baffle 11 and vibrates, will wait to separate the calcium oxide raw materials and pour hopper 2, the calcium oxide raw materials falls into separator box 1 through feeder hopper 2, and by filter screen 8 screening layer upon layer, after it is intercepted by filter screen 8, flow downwards along its inclined plane in the vibration process of filter screen 8, and flow out separator box 1 from corresponding discharge gate 3, connect the material at discharge gate 3 can. Receive the material convenient and realized multistage separation's purpose, convenient to use is swift.

2. This multistage separating mechanism that calcium oxide was used through setting up spout 6, spring 7, filter screen 8, pivot 9, vibrating piece 10, baffle 11, cooperates drive wheel 12, drive belt 13 and motor 14, starts motor 14, and motor 14 passes through a series of transmission structure and drives filter screen 8 and shake about in spout 6 from top to bottom, has realized the purpose of dynamic screening, and the screening effect is better.

Claims (7)

1. A multistage separation mechanism for calcium oxide, comprising a separation box (1); the separating box is characterized in that the top of the separating box (1) is fixedly connected with a feeding hopper (2), a plurality of discharging holes (3) are formed in two sides of the separating box (1), guide plates (4) are arranged in the discharging holes (3), a plurality of sliding grooves (6) are formed in the separating box (1), springs (7) are fixedly connected to the two ends of the sliding grooves (6), a filter screen (8) is arranged in the sliding grooves (6), a rotating shaft (9) is rotationally connected to the separating box (1), a vibrating block (10) is fixedly connected to the rotating shaft (9), a baffle (11) is fixedly connected to one side, close to the rotating shaft (9), of the filter screen (8), a driving wheel (12) is fixedly connected to the outer end of the rotating shaft (9), a driving belt (13) is arranged on the driving wheel (12), a motor (14) is arranged at the outer end of one rotating shaft (9), and a fine material box (15) is arranged at the bottom of the inner side of the separating box (1).

2. A multi-stage separation mechanism for calcium oxide as claimed in claim 1, wherein: the discharge holes (3) are strip-shaped holes and are arranged adjacently up and down.

3. A multi-stage separation mechanism for calcium oxide as claimed in claim 2, wherein: the material guide plate (4) is arranged at the bottom of the discharge hole (3) and extends downwards and outwards from the inside of the discharge hole (3) in an inclined manner, and the bottom of the separation box (1) is provided with a box door (5).

4. A multi-stage separation mechanism for calcium oxide as claimed in claim 3, wherein: the number of the sliding grooves (6) is consistent with that of the discharge holes (3), and the sliding grooves (6) are obliquely arranged in the separation box (1).

5. A multi-stage separation mechanism for calcium oxide as claimed in claim 4, wherein: the number of the filter screens (8) is consistent with that of the sliding grooves (6), and the filter screens (8) are sequentially arranged from top to bottom according to the pore size.

6. A multi-stage separation mechanism for calcium oxide as claimed in claim 5, wherein: both ends of the filter screen (8) are fixedly connected with the springs (7), and the rotating shaft (9) is rotationally connected with the separation box (1) through a bearing.

7. A multi-stage separation mechanism for calcium oxide as claimed in claim 6, wherein: the vibrating blocks (10) are arranged on each rotating shaft (9) uniformly around the rotating shafts (9).