CN221288155U - Ore soil powdering equipment - Google Patents

Abstract

The utility model discloses ore soil pulverizing equipment, which comprises a protection cavity, a crushing wheel and a discharge hole, wherein the crushing wheel comprises a left central shaft, a right central shaft, an inner wheel and an outer wheel which are fixedly connected with the central shaft respectively, one end of the central shaft is provided with a driving device for driving the central shaft to rotate, a feeding channel is arranged above the protection cavity and used for guiding ore soil into a rotating wheel, the ore soil rotates along with the rotation of the crushing wheel, the inner wheel and the outer wheel rotate in different directions, and the ore soil is ground by layer-by-layer impact on the ore soil until the ore soil is thrown out from the discharge hole. The device is through mutually supporting of feed channel, break pulley, bin outlet and drive arrangement, more convenient high-efficient with the ore deposit soil of major diameter become the powder of minor diameter.

Description

Ore soil powdering equipment

Technical Field

The utility model relates to the technical field of ore soil grinding equipment, in particular to ore soil pulverizing equipment.

Background

The ceramic pug is a basic raw material in the industries of construction, ceramics and the like, has wide application range in China for years, can be used as a raw material of products such as bowls, cups, dishes, toilets, squatting pans and the like, and is prepared by the steps of raw material excavation and crushing, screening, iron removal, pug conveying, mud dehydration and the like.

In the existing ceramic pug production process, for sand stone ore soil crushing, a crusher is often used, and is mainly completed by mutually matching and rolling a rotary roller and a grinding stone plate. Although the crusher can feed in a large scale, the diameter of the entered sand and ore soil blocks is limited, and the crushing effect is common.

Disclosure of Invention

Aiming at the prior art, the utility model aims to provide ore soil pulverizing equipment which can grind large-diameter ore soil and has the advantages of high efficiency, good effect and low manufacturing cost.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

The utility model provides a powder equipment is made to ore deposit, includes the protection chamber, the protection chamber is enclosed by half arc panel, left side board, right side board and closes and form, its characterized in that, left side board with set up the break-up wheel between the right side board, the break-up wheel includes outer wheel and interior wheel, the outer wheel rotates with the first center pin that inserts the left side board perpendicularly and is connected, interior wheel rotates with the second center pin that inserts the right side board perpendicularly and is connected, the outer wheel with leave the side space between the interior wheel, the one end of center pin all is provided with the drive arrangement who is used for driving center pin pivoted, feed channel has been seted up to the protection chamber, feed channel is arranged in with ore deposit direction break-up wheel, the outer wheel with interior wheel towards different direction high-speed rotation, get into the major diameter ore deposit in the break-up wheel rotates thereupon as well, realizes striking, crushing to ore deposit, until throwing out from the bin outlet.

Through adopting above-mentioned technical scheme, drive arrangement drive center pin high-speed rotation, if the center pin rotates, then outer wheel and interior wheel that is connected with the center pin rotation also can rotate thereupon, external ore deposit soil pours into the feed channel into, under the guide effect of feed channel, ore deposit soil gets into the protection chamber, because leave the side space between outer wheel and the interior wheel, because outer wheel and interior wheel are rotatory along with the center pin at this moment, and outer wheel and interior wheel rotate towards opposite direction, so ore deposit soil shuttles through from the side, smash ore deposit soil through the friction, the striking of outer wheel, interior wheel, discharge from the bin outlet at last. The process of crushing the large-diameter ore soil into small-diameter powder is completed, and the device has small occupied space and low energy consumption and is suitable for crushing the large-diameter ore soil.

Further, the driving device is a motor.

Further, the outer wheel comprises a plurality of equally spaced cuboids and circular rings fixedly connected to two ends of the cuboids, the circular rings are close to the left side plate and are first solid circular rings, first through holes for allowing a first central shaft to pass through are formed in the first solid circular rings, the inner wheel comprises a plurality of equally spaced cuboids and circular rings fixedly connected to two ends of the cuboids, the circular rings are close to the right side plate and are second solid circular rings, and second through holes for allowing a second central shaft to pass through are formed in the second solid circular rings.

Through adopting above-mentioned technical scheme, described the structure of outer wheel and interior wheel, outer wheel and interior wheel all are by a plurality of equidistant cuboid, and one end rigid coupling ring, one end rigid coupling solid ring are constituteed, and the center pin rotates with outer wheel, interior wheel through passing the through-hole on the solid ring to be connected. The adoption of a plurality of equally spaced cuboids is favorable for more uniformly receiving ore soil from a feeding channel, and the diameter of the outer wheel is larger than that of the inner wheel, so that larger gaps are reserved on the side surface of the outer wheel for the ore soil to penetrate and carboxylic. By the aid of the structural design, after ore soil enters the protection cavity, powder with small diameter can be finally obtained through friction and collision of one layer of the ore soil and the other layer of ore soil under high-speed rotation of the outer wheel and the inner wheel.

Further, a third wheel is fixedly connected to the outer wheel, the third wheel comprises a plurality of equally-spaced cuboids and a ring fixedly connected to one end of the cuboid, the ring faces the second solid ring, the inner wheel is sleeved with the third wheel, the diameter of the third wheel is smaller than that of the inner wheel, and the diameter of the inner wheel is smaller than that of the outer wheel.

By adopting the technical scheme, the diameter of the third wheel is smaller than that of the inner wheel, and the diameter of the inner wheel is smaller than that of the outer wheel, so that large-batch large-diameter ore soil has enough space to shuttle. The third wheel is fixedly connected with the outer wheel, the inner wheel is sleeved on the third wheel, the motor drives the first central shaft to rotate, the outer wheel also rotates along with the first central shaft, the outer wheel is fixedly connected with the third wheel, the third wheel also rotates along with the third wheel, and similarly, the motor drives the second central shaft to rotate, and the inner wheel also rotates along with the second central shaft. The outer wheel and the third wheel rotate in the same direction, the inner wheel rotates in the opposite direction, the outer wheel, the third wheel and the inner wheel are all composed of a plurality of equally spaced cuboids, ore soil falling into the outer wheel, the third wheel and the inner wheel are impacted by 4 layers in sequence, and finally the ore soil flows into the conveying equipment from the discharge hole, and the large-diameter ore soil is crushed into fine powder.

Further, the feeding channel comprises a feeding groove, the notch of the feeding groove faces upwards, the notch of the feeding groove is larger than the bottom of the feeding groove, and the bottom of the feeding groove is provided with a feeding hole.

Through adopting above-mentioned technical scheme, the setting of feed chute for when the user pours the ore deposit into the feed channel, from great feed chute notch entering, from the feed inlet entering into the protection chamber again. Therefore, when the ore soil enters, the ore soil is not easy to scatter outside, and the ore soil enters more conveniently.

Further, an inclined plane is arranged between the notch of the feeding chute and the feeding hole.

Through adopting above-mentioned technical scheme, the setting on inclined plane makes the ore deposit soil can be more smoothly follow the notch flow direction feed inlet of feed chute, and then enters into in the feed channel.

Furthermore, the inside of the protection cavity is fixedly connected with a wear-resisting block.

Through adopting above-mentioned technical scheme, when the device normal operating, the protection chamber can avoid the ore deposit that pours into to splash everywhere, pollutes the environment, and at break wheel pivoted in-process, the ore deposit can necessarily splash the protection chamber, and plays a guard action with screw rigid coupling wear-resisting piece in the inside of protection chamber.

Compared with the prior art, the utility model has the beneficial effects that: 1. through the cooperation of the crushing wheel, the feeding channel, the discharge hole and the driving device, the large-diameter ore soil is impacted and crushed into small-diameter powder more conveniently and efficiently. 2. The device has the advantages of small whole standing space, low energy consumption and suitability for crushing large-diameter mineral soil.

Drawings

FIG. 1 is an overall schematic diagram of the present embodiment;

FIG. 2 is an overall schematic view of the present embodiment at another angle;

FIG. 3 is an overall schematic of a crushing wheel;

FIG. 4 is a schematic view of the outer wheel;

fig. 5 is a cross-sectional view of the present embodiment.

Reference numerals: 1. a protection cavity; 12. a semi-arcuate panel; 13. a left side panel; 14. a right side panel; 2. a discharge port; 3. a first central axis; 4. a second central axis; 5. a motor; 6. a feed channel; 61. a feed chute; 62. a feed inlet; 63. an inclined plane; 7. a crushing wheel; 71. an outer wheel; 711. a first solid ring; 712. a first through hole; 72. a third wheel; 73. an inner wheel; 731. a second solid ring; 732. a second through hole; 8. and (5) a wear-resistant block.

Description of the embodiments

The present utility model will be described in detail below with reference to the accompanying drawings and examples.

The terms "first," "second," or "third," etc. are used herein to distinguish between different objects and not to describe a particular sequence.

The use of directional terms such as "upper", "lower", "left", "right", etc. in accordance with the present utility model are based on the directional and positional relationships shown in the drawings and are merely for convenience of description and to simplify the description, rather than to indicate or imply that the apparatus or elements referred to must have a specific orientation or be constructed and operated in a specific orientation, and thus should not be construed to limit the specific scope of the present utility model.

The term "fixedly connected" as used herein is to be construed broadly, i.e., any manner of connection between the two that does not undergo displacement or relative rotation during use.

The term "screw-in" as used herein is to be understood in a broad sense, that is, a connection manner in which two or more parts are connected together by using a mutual engagement force between threads, and tools such as a screw and a bolt may be used as a part for screwing the two parts.

Referring to fig. 1 to 5, a device for pulverizing mineral soil comprises a protection cavity 1, wherein the protection cavity 1 is integrally formed into a hollow semicircle, the protection cavity 1 is formed by enclosing a semi-arc-shaped panel 12, a right side panel 13 and a left side panel 14 which are opposite to each other, a crushing wheel 7 is arranged between the left side panel 13 and the right side panel 14, the crushing wheel 7 comprises an outer wheel 71 and an inner wheel 73, the outer wheel 71 is rotationally connected with a first central shaft 3 vertically inserted into the left side panel 13, the inner wheel 73 is rotationally connected with a second central shaft 4 vertically inserted into the right side panel 14, a lateral gap is reserved between the outer wheel 71 and the inner wheel 73, one ends of the first central shaft 3 and the second central shaft 4 are provided with a driving device for driving the central shaft to rotate, the driving device is a motor 5, a feeding channel 6 is arranged above the protection cavity 1, the feeding channel 6 is used for guiding mineral soil into the crushing wheel 7, and large mineral soil blocks in the crushing wheel 7 rotate along with the rotation of the crushing wheel, and the outer wheel 71 and the inner wheel 73 rotate at high speeds towards different directions until the mineral soil is thrown out from a discharge outlet 2.

The diameter of the third wheel 72 is smaller than that of the inner wheel 73, and the diameter of the inner wheel 73 is smaller than that of the outer wheel 71, so that a side gap is reserved between the outer wheel 71 and the inner wheel 73, and a larger gap is reserved on the side surface of the outer wheel 71, so that a large amount of large-diameter ore soil has enough space to shuttle through. The third wheel 72 is fixedly connected with the outer wheel 71, and the inner wheel 73 is sleeved on the third wheel 72, so that when the motor 5 drives the first central shaft 3 to rotate at a high speed, the outer wheel 71 also rotates at a high speed, and because the outer wheel 71 is fixedly connected with the third wheel 72, the third wheel 72 also rotates at a high speed, and similarly, the motor 5 drives the second central shaft 4 to rotate at a high speed, and the inner wheel 73 also rotates at a high speed. Outside ore soil is poured into the feeding channel 6, the mud materials enter the protection cavity 1, the outer wheel 71 and the third wheel 72 rotate in the same direction, the inner wheel 73 rotates in the opposite direction, the outer wheel 71, the third wheel 72 and the inner wheel 73 are all composed of a plurality of equally-spaced cuboids, the ore soil falling into the feeding channel is impacted by 4 layers of the outer wheel 71, the third wheel 72 and the inner wheel 73 in sequence, finally, the ore soil flows into the conveying equipment from the discharge port 2, and the large-diameter ore soil is crushed into fine powder.

Referring to fig. 1 and 5, in order to make the device not easy to splash to the outside when in normal use, the protection cavity 1 is installed outside the crushing wheel 7, and the mineral soil is inevitably splashed to the protection cavity 1 in the rotation process of the crushing wheel 7, and the abrasion-resistant block 8 is fixedly connected in the protection cavity 1 by a screw to play a protection role.

Referring to fig. 2, in order to conveniently pour external mineral soil into the protection cavity 1, a notch of the feed chute 61 is upward, the notch of the feed chute 61 is larger than a bottom of the feed chute 61, a feed inlet 62 is formed in the bottom of the feed chute 61, and an inclined surface 63 is arranged between the notch of the feed chute 61 and the feed inlet 62.

The above is only a preferred embodiment of the present utility model, and the protection scope of the present utility model is not limited to the above examples, and all technical solutions belonging to the concept of the present utility model belong to the protection scope of the present utility model. It should be noted that modifications and adaptations to the present utility model may occur to one skilled in the art without departing from the principles of the present utility model and are intended to be within the scope of the present utility model.

Claims (7)

1. The utility model provides a ore deposit powder equipment, includes protection chamber (1), protection chamber (1) is enclosed by half arc panel (12), left side board (13), right side board (14) and closes and form, a serial communication port, left side board (13) with between right side board (14) crushing wheel (7) have been seted up, crushing wheel (7) include outer wheel (71) and interior wheel (73), outer wheel (71) are connected with first center pin (3) rotation of perpendicular inserting left side board (13), interior wheel (73) are connected with second center pin (4) rotation of perpendicular inserting right side board (14), outer wheel (71) with leave the side space between interior wheel (73), the one end of center pin all is provided with the drive arrangement who is used for driving center pin rotation, feed channel (6) have been seted up to protection chamber (1) top, feed channel (6) are arranged in with ore deposit guide crushing wheel (7), outer wheel (71) with interior wheel (73) are towards different direction high-speed rotation, get into in the large-scale ore deposit (7) is smashed to ore deposit from the rotation of outer wheel (73), is followed to the blast gate is realized.

2. A mineral soil pulverizing apparatus as defined in claim 1, wherein the drive means is a motor (5).

3. The mine soil pulverizing device according to claim 1, wherein the outer wheel (71) comprises a plurality of equally spaced cuboids and circular rings fixedly connected to two ends of the cuboids, the circular rings are close to the left side panel (13) and are first solid circular rings (711), first through holes (712) for allowing the first central shaft (3) to pass through are formed in the first solid circular rings (711), the inner wheel (73) comprises a plurality of equally spaced cuboids and circular rings fixedly connected to two ends of the cuboids, the circular rings are close to the right side panel (14) and are second solid circular rings (731), and second through holes (732) for allowing the second central shaft (4) to pass through are formed in the second solid circular rings (731).

4. A mineral soil powdering device according to claim 3, wherein the outer wheel (71) is fixedly connected with a third wheel (72), the third wheel (72) comprises a plurality of equally spaced cuboids and a ring fixedly connected to one end of the cuboid, the ring faces the second solid ring (731), the inner wheel (73) is sleeved on the third wheel (72), the diameter of the third wheel (72) is smaller than that of the inner wheel (73), and the diameter of the inner wheel (73) is smaller than that of the outer wheel (71).

5. The mineral soil pulverizing device according to claim 1, wherein the feed channel (6) comprises a feed chute (61), a notch of the feed chute (61) faces upwards, the notch of the feed chute (61) is larger than a groove bottom of the feed chute (61), and a feed inlet (62) is formed in the groove bottom of the feed chute (61).

6. A mineral soil pulverizing apparatus as defined in claim 5, wherein a ramp (63) is provided between the slot opening of the feed chute (61) and the feed opening (62).

7. The ore soil pulverizing device according to claim 1, wherein the interior of the protection cavity (1) is fixedly connected with a wear-resistant block (8).