CN111617864A

CN111617864A - Ore machine with automatic feeding function

Info

Publication number: CN111617864A
Application number: CN202010503988.9A
Authority: CN
Inventors: 姜国英
Original assignee: Individual
Current assignee: Linyi Luokai Investment Co ltd
Priority date: 2020-06-05
Filing date: 2020-06-05
Publication date: 2020-09-04
Anticipated expiration: 2040-06-05
Also published as: CN111617864B

Abstract

The invention discloses an ore machine with an automatic feeding function, which structurally comprises a processing cabin, a feeding hole and an installation chassis, wherein the feeding hole is welded and installed at the upper end of the right side of the processing cabin, the feeding hole is positioned right above the right side of the installation chassis, and the installation chassis is welded right below the processing cabin.

Description

Ore machine with automatic feeding function

Technical Field

The invention belongs to the field of ore machinery, and particularly relates to ore machinery with an automatic feeding function.

Background

The ore machine is applied to ore mining and ore processing, and the ore is automatically processed or smashed by utilizing a mechanical transmission belt and processing equipment.

Based on the findings of the inventor, the following defects mainly exist in the prior art, such as:

when the hob stirs garrulous work to the ore, because the garrulous randomness of ore volume stirring to the direction of rotation that has little granular ore through the hob is driven and is fallen into in this clearance, and this gap inner space constantly is filled up by the entering of ore granule under the long-term rotatory garrulous work condition, so that original space is extruded, leads to the machine oil to be difficult to flow, and makes ore granule friction hob link increase surface friction power, influences the puddler work.

It is therefore desirable to provide a mineral machinery with an automatic feeding function.

Disclosure of Invention

In order to solve above-mentioned technique when the hob stirs garrulous work to the ore, because the garrulous randomness of ore volume stirring to the direction of rotation that has little granular ore to pass through the hob is driven and is fallen into in this clearance, and this gap inner space is constantly filled up by the entering of ore granule under the long-term rotatory garrulous work condition of stirring, so that original space is extruded, leads to the engine oil to be difficult to flow, and makes the ore granule friction hob link increase surface friction, influences the problem of puddler work.

The invention relates to an ore machine with an automatic feeding function, which has the purposes and effects and is achieved by the following specific technical means: its structure is including processing cabin, feed inlet, installation chassis, the feed inlet is being installed in the right side upper end welding of processing cabin, the feed inlet is located directly over the right side on installation chassis, the welding of installation chassis is under the processing cabin, the processing cabin is including stirring garrulous mechanism, power pivot, drive wheel, drive belt, the block is inlayed at the left side terminal surface of power pivot to the garrulous mechanism, the power pivot is located the right side top of drive belt, the outer terminal surface in drive wheel right side is wrapping up the drive belt, the drive belt is located the perpendicular under of feed inlet.

Further, the stirring mechanism comprises a screw rod, a movable block, a first embedding block and a rotating shaft mechanism, wherein the screw rod is positioned at the left side of the rotating shaft mechanism, the right end face of the screw rod is in contact with the first embedding block, the movable block is positioned at the upper end and the lower end of the screw rod, the movable block is installed on the inner end face of the left side of the first embedding block, the rotating shaft mechanism is arranged on the left end face of the power rotating shaft, and the movable block is provided with two symmetrical installation.

Furthermore, the rotating shaft mechanism comprises a rubber layer, a shaft sleeve, four interference mechanisms and four clamping grooves, wherein the rubber layer is located on the inner side end face of the shaft sleeve, the interference mechanisms are located at the left end and the right end of the clamping groove, the clamping groove is located in the center of the shaft sleeve, the interference mechanisms are symmetrically arranged on two sides of the clamping groove, and the shaft sleeve is designed in an oval shape.

Furthermore, interference mechanism includes first connecting axle, gyro wheel, anti-skidding recess, first connecting axle symmetry is installed in the left and right sides of gyro wheel, be equipped with anti-skidding recess on the surface of gyro wheel, anti-skidding recess adopts inclination design to encircle the parcel gyro wheel.

Further, the power rotating shaft comprises a telescopic rod, a second embedding block, a connecting block, a spring, a clamping tooth mechanism and a second connecting shaft, wherein the second embedding block is arranged at each of the left end and the right end of the telescopic rod, the second embedding block is positioned at each of the upper side and the lower side of the clamping tooth mechanism, the clamping tooth mechanism is arranged on the left side of the connecting block, the spring is wrapped on the end face of the outer side of the telescopic rod, the clamping tooth mechanism is positioned at the right side of the second connecting shaft, the clamping rotating shaft mechanism is embedded at the left end of the second connecting shaft, and an extension rod is arranged on the outer side of the embedding block and shelters from the.

Furthermore, latch mechanism includes the inoxidizing coating, inlays base, dogtooth, the below is located to the inoxidizing coating the left side of dogtooth, it is located the inoxidizing coating below to inlay the base, the dogtooth is located and inlays the base directly over, the lower terminal surface of dogtooth is equipped with protruding piece, the inoxidizing coating adopts the design of slot type.

Furthermore, the protective layer comprises a second rubber layer, a second mosaic block, a connecting plate and an air groove, the second rubber layer is located right above the second mosaic block, the second mosaic block is located right above the connecting plate, the connecting plate is located right below the air groove, the upper end of the air groove is attached to the second rubber layer, and four arc-shaped grooves are formed in the lower end face of the connecting plate.

Compared with the prior art, the invention has the following beneficial effects:

1. when the device is used, in order to solve the problem that the gap of the connecting end face of the screw rod device is blocked by ore particles in the prior device, the embedded block can shake up and down along with the appearance of the shaft sleeve through the embedded connection with the elliptical shaft sleeve while the power rotating shaft rotates through the elliptical design of the shaft sleeve in the rotating shaft mechanism, the movable block is driven to extrude ore in the connecting end face of the screw rod to crush the ore, and the ore can fall off along with the rotation of the screw rod to avoid blocking.

2. The power rotating shaft rotates, meanwhile, the inner connecting block can drive the convex teeth in the caliper mechanism embedded on the left end face of the power rotating shaft to lift upwards along with the amplitude of the convex teeth on the opposite face, the connecting shaft is jacked outwards to form regular fine vibration through the matching of the connecting shaft and the spring, power transmission can be carried out through the telescopic rod during jacking to keep rotating, and dust and ore fragments clamped on the spiral rod are shaken off through the fine vibration.

Drawings

Fig. 1 is a schematic view of the overall structure of an ore machine with an automatic feeding function according to the present invention.

Fig. 2 is a schematic structural diagram of an ore machining chamber with an automatic feeding function according to the present invention.

FIG. 3 is a schematic side view of a mineral crushing mechanism with automatic feeding function according to the present invention.

Fig. 4 is a schematic structural diagram of a mineral machinery rotating shaft mechanism with an automatic feeding function according to the present invention.

Fig. 5 is a schematic structural diagram of an ore mechanical interference mechanism with an automatic feeding function according to the present invention.

FIG. 6 is a schematic structural diagram of a mechanical power shaft for ore with automatic feeding function according to the present invention.

Fig. 7 is a schematic structural diagram of a mechanical latch mechanism for ore with an automatic feeding function according to the present invention.

Fig. 8 is a schematic structural diagram of a mechanical ore protective layer with an automatic feeding function according to the present invention.

Fig. 9 is a schematic side view of a mechanical latch mechanism for ore with automatic feeding function according to the present invention.

In the figure: the processing cabin comprises a processing cabin body-1, a feeding hole-2, an installation chassis-3, a stirring mechanism-11, a power rotating shaft-12, a driving wheel-13, a driving belt-14, a screw rod-111, a movable block-112, a first embedding block-113, a rotating shaft mechanism-114, a rubber layer-4 a, a shaft sleeve-4 b, an interference mechanism-4 c, a clamping groove-4 d, a first connecting shaft-4 c1, a roller-4 c2, an anti-skidding groove-4 c3, an expansion rod-121, a second embedding block-122, a connecting block-123, a spring-124, a clamping tooth mechanism-125, a second connecting shaft-126, a protective layer-5 a, an embedding base-5 b, a convex tooth-5 c, a second rubber layer-a 1, a second embedding block-a 2, a connecting plate-a 3 and an air groove-a 4.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example 1:

as shown in figures 1 to 5:

the invention provides an ore machine with an automatic feeding function, which structurally comprises a processing cabin 1, a feeding hole 2 and an installation chassis 3, wherein the feeding hole 2 is welded and installed at the upper end of the right side of the processing cabin 1, the feeding hole 2 is positioned right above the right side of the installation chassis 3, the installation chassis 3 is welded right below the processing cabin 1, and the ore machine is characterized in that:

the processing cabin 1 comprises a stirring mechanism 11, a power rotating shaft 12, a driving wheel 13 and a driving belt 14, wherein the stirring mechanism 11 is embedded and clamped on the left end face of the power rotating shaft 12, the power rotating shaft 12 is located above the right side of the driving belt 14, the driving belt 14 is wrapped on the outer end face of the right side of the driving wheel 13, the driving belt 14 is located under the feed port 2, and ore can be effectively transmitted to the upper surface of the driving belt 14 through positive rotation of the stirring mechanism 11 to finish automatic feeding.

Wherein, stirring garrulous mechanism 11 includes hob 111, movable block 112, first inlay solid piece 113, pivot mechanism 114, hob 111 is located the horizontal left side and the right-hand member face of pivot mechanism 114 and contacts with first inlay solid piece 113, movable block 112 is located hob 111's upper and lower both ends, movable block 112 is being installed to the terminal surface in the left side of first inlay solid piece 113, power shaft 12's left side terminal surface is located to pivot mechanism 114, movable block 112 is equipped with two symmetry installations, orders about pivot mechanism 114 when hob 111 rotates and drives first inlay solid piece 113 and the extrusion of movable block 112 ore disintegrating slag that drops in the gap.

Wherein, pivot mechanism 114 includes rubber layer 4a, axle sleeve 4b, interference mechanism 4c, block groove 4d, rubber layer 4a is located the medial surface of axle sleeve 4b, interference mechanism 4c is located both ends about block groove 4d, block groove 4d is located the positive center of axle sleeve 4b, interference mechanism 4c is equipped with four, and even symmetry is installed in block groove 4d both sides, the axle sleeve adopts oval appearance design, can drive first solid piece 113 of inlaying along with the outline forms slight vibration through the rotation effect of power pivot 12.

Wherein, interference mechanism 4c includes first connecting axle 4c1, gyro wheel 4c2, anti-skidding recess 4c3, the left and right sides at gyro wheel 4c2 is installed to first connecting axle 4c1 symmetry, be equipped with anti-skidding recess 4c3 on the surface of gyro wheel 4c2, anti-skidding recess 4c3 adopts the inclination design to encircle parcel gyro wheel 4c2, utilizes anti-skidding recess 4c3 to increase surface friction when inlaying power pivot 12, guarantees the stability of installation.

The specific use mode and function of the embodiment are as follows:

when the ore crushing device is used, ores need to be poured into the processing cabin 1 through the feeding hole 2, the stirring mechanism 11 embedded in the left end face of the processing cabin is driven by the rotating effect of the power rotating shaft 12 to extrude and crush the fallen ores, the embedded and fixed block 113 embedded in the outer end face of the shaft sleeve 4b is driven to slide up and down along with the elliptical appearance of the shaft sleeve 4b while the power rotating shaft 12 is driven, and the movable block 112 installed on the left end face of the movable block is driven to extrude ore residues falling into gaps while the movable block slides.

Example 2:

as shown in fig. 6 to 8:

the power rotating shaft 12 comprises an expansion link 121, a second embedding block 122, a connecting block 123, a spring 124, a latch mechanism 125 and a second connecting shaft 126, wherein the second embedding block 122 is arranged at the left end and the right end of the expansion link 121, the second embedding block 122 is arranged at the upper side and the lower side of the latch mechanism 125, the latch mechanism 125 is arranged on the left side of the connecting block 123, the spring 124 is wrapped on the outer end face of the expansion link 121, the latch mechanism 125 is arranged at the right side of the second connecting shaft 126, the rotating shaft mechanism 114 is embedded and clamped at the left end of the second connecting shaft 126, an extension rod is arranged on the outer side of the embedding block 122 and covers the outer side of the expansion link 121, and when the connecting block 123 and the second connecting shaft 126 vibrate through the latch mechanism 125, ore debris is reduced to fall on the inner side of the embedding block 122, and the left side and the right side of.

Wherein, latch mechanism 125 includes inoxidizing coating 5a, inlays base 5b, dogtooth 5c, the below is located to inoxidizing coating 5a the left side of dogtooth 5c, it is located inoxidizing coating 5a below to inlay base 5b, dogtooth 5c is located and inlays base 5b directly over, the lower terminal surface of dogtooth 5c is equipped with the protruding piece, inoxidizing coating 5a adopts groove formula design, can make dogtooth 5c striking inoxidizing coating 5a when latch mechanism 125 vibrates, utilizes inoxidizing coating 5 a's groove design to reduce buffering and dogtooth 5c wearing and tearing.

The protective layer 5a comprises a second rubber layer a1, a second mosaic block a2, a connecting plate a3 and an air groove a4, the second rubber layer a1 is located right above the second mosaic block a2, the second mosaic block a2 is located right above the connecting plate a3, the connecting plate a3 is located right below the air groove a4, the upper end of the air groove a4 is attached to the second rubber layer a1, the lower end face of the connecting plate a3 is provided with four arc-shaped grooves, impact force can be buffered and protected by the elasticity of the second rubber layer 1 and the buffer property of the air groove a4 when the convex teeth 5c collide with the outer end face of the protective layer 5a, and the problem that the protective layer 5a expands with heat and contracts with cold due to long-term friction collision of the convex teeth 5c can be avoided by the arc-shaped grooves below the connecting plate a 3.

The specific use mode and function of the embodiment are as follows:

in the invention, the connecting block 123 can drive the convex teeth 5c arranged on the left end face of the connecting shaft 126 to rub and drive the convex teeth 5c on the right end face of the connecting shaft 126 through the convex teeth 5c arranged on the embedded base 5b when rotating through the power rotating shaft 12, so that the convex teeth 5c on the left side and the right side collide, the convex teeth 5c on the right side fall into the grooves after the angle of the convex teeth 5c on the left side rises to the highest point, the lower ends of the convex teeth 5c collide with the second rubber layer a1 in the protective layer 5a, the impact force is buffered with the air groove a4 along with elasticity, finally, the whole power rotating shaft vibrates, and the latch mechanism 125, the telescopic rod 121 and the spring 124 are driven to continuously work through the rotation of.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims

1. The utility model provides an ore machinery with automatic feed function, its structure is including processing cabin (1), feed inlet (2), installation chassis (3), feed inlet (2) are being installed in the right side upper end welding of processing cabin (1), feed inlet (2) are located directly over the right side of installation chassis (3), the welding of installation chassis (3) is under processing cabin (1), its characterized in that:

processing cabin (1) is including stirring mechanism (11), power pivot (12), drive wheel (13), drive belt (14), the left side terminal surface of block at power pivot (12) is inlayed in stirring mechanism (11), power pivot (12) are located the right side top of drive belt (14), drive wheel (13) right side outer terminal surface is wrapping up drive belt (14), drive belt (14) are located feed inlet (2) under perpendicular.

2. The ore machine with the automatic feeding function according to claim 1, wherein the stirring mechanism (11) comprises a screw rod (111), a movable block (112), a first embedding block (113) and a rotating shaft mechanism (114), the screw rod (111) is located on the left side of the rotating shaft mechanism (114), the right end face of the screw rod is in contact with the first embedding block (113), the movable block (112) is located on the outer side of the screw rod (111), the movable block (112) is installed on the inner end face of the left side of the first embedding block (113), and the rotating shaft mechanism (114) is arranged on the left end face of the power rotating shaft (12).

3. The ore machine with the automatic feeding function as claimed in claim 2, wherein the rotating shaft mechanism (114) comprises a rubber layer (4a), a shaft sleeve (4b), an interference mechanism (4c) and a clamping groove (4d), the rubber layer (4a) is located on the inner end face of the shaft sleeve (4b), the interference mechanism (4c) is located at the left end and the right end of the clamping groove (4d), and the clamping groove (4d) is located in the center of the shaft sleeve (4 b).

4. The ore machine with the automatic feeding function of claim 3, wherein the interference mechanism (4c) comprises a first connecting shaft (4c1), a roller (4c2) and an anti-slip groove (4c3), the first connecting shaft (4c1) is symmetrically arranged at the left side and the right side of the roller (4c2), and the anti-slip groove (4c3) is arranged on the outer surface of the roller (4c 2).

5. The ore machine with the automatic feeding function as claimed in claim 1, wherein the power rotating shaft (12) comprises an expansion link (121), second embedding blocks (122), a connecting block (123), a spring (124), a latch mechanism (125) and a second connecting shaft (126), the second embedding blocks (122) are arranged at the left end and the right end of the expansion link (121), the second embedding blocks (122) are located at the upper side and the lower side of the latch mechanism (125), the latch mechanism (125) is arranged on the left side of the connecting block (123), the spring (124) is wrapped on the outer end face of the expansion link (121), the latch mechanism (125) is located on the right side of the second connecting shaft (126), and the rotating shaft mechanism (114) is embedded and clamped at the left end of the second connecting shaft (126).

6. A mineral machinery with automatic feeding function according to claim 5, wherein the latch mechanism (125) comprises a protective layer (5a), an embedding base (5b), and a convex tooth (5c), the embedding base (5b) is positioned below the protective layer (5a), and the convex tooth (5c) is positioned right above the embedding base (5 b).

7. A mineral machinery with automatic feeding function according to claim 6, wherein the protective layer (5a) comprises a second rubber layer (a1), a second mosaic block (a2), a connecting plate (a3) and an air groove (a4), the second rubber layer (a1) is positioned right above the second mosaic block (a2), the second mosaic block (a2) is positioned right above the connecting plate (a3), the connecting plate (a3) is positioned right below the air groove (a4), and the upper end of the air groove (a4) is attached to the second rubber layer (a 1).