CN210010167U - Inertia linear vibration sand screening machine - Google Patents

Abstract

The utility model relates to the technical field of sand screening machines, in particular to an inertia linear vibration sand screening machine, which comprises a base, wherein the left side and the right side of the upper end surface of the base are integrally provided with two brackets, a screening mechanism is jointly installed between the two brackets through bolts, the left end of the upper part of the base is provided with a feeding mechanism, a discharge hole at the bottom end of the feeding mechanism is over against the left upper end of the screening mechanism, the screening mechanism comprises a screening shell with a high left end and a low right end and a screen plate which is connected in a sliding way, a discharge pipeline of a lifting machine for transporting sand stones from the outside is aligned to a feed hopper of the feeding mechanism, then the sand stones entering the feeding shell can rotate and move downwards along a bending channel, the sand stones can be heated and dried through a heating rod in the moving downwards process, and the dried sand stones can continuously fall downwards and enter the inside of the screening shell, i.e. falls down the upper left side of the screen panel.

Description

Inertia linear vibration sand screening machine

Technical Field

The utility model relates to a sand sieving machine technical field, specific inertia linear vibration sand sieving machine that says so.

Background

At present, the processing of weathering is dried in the drying that can not be carried out before the sieve material with when the sieve material to the shale shaker that adopts in the market to very easily adhere on the screen board when leading to follow-up grit to sieve, still inconvenient simultaneously intercepts impurity clearance and separately retrieves with qualified grit, the screen board in inconvenient different apertures of changing, therefore influence follow-up screening effect, so still need improve the processing.

SUMMERY OF THE UTILITY MODEL

In order to make up for above not enough, the utility model provides an inertia linear vibration sand sieving machine to solve the problem among the above-mentioned background art.

The technical scheme of the utility model is that: an inertia linear vibration sand screening machine comprises a base, wherein the left side and the right side of the upper end face of the base are integrally provided with supports, two screening mechanisms are jointly installed between the supports through bolts, a feeding mechanism is installed at the left end of the upper portion of the base, a discharge hole at the bottom end of the feeding mechanism is right aligned to the left upper end of the screening mechanism, each screening mechanism comprises a screening shell with a high left and a low right and a screen plate in sliding connection with the screening shell, vibration motors are installed on the front side and the rear side of the screening shell through bolts, the vibration motors are of YZS-3-6 types, the left end of the upper portion of the screening shell is communicated with a material receiving cylinder positioned under the discharge hole at the bottom end of the feeding mechanism, a baffle is welded at the right end of the screen plate and is fixedly installed at the opening position at the right end of the screening shell through bolts, the upper portion of the, the air intake intercommunication of air-blower has the air inlet trunk line, the air inlet trunk line is terminal to be linked together in the screening casing and extend to its inside, the terminal intercommunication of air inlet trunk line has the air inlet to violently manage, the air inlet is violently managed terminal equidistance intercommunication and is had the air exit, the position of screen board right front is higher than the setting of left rear, just screening casing left rear intercommunication has the slag cleaning mouth, slag cleaning mouth end to end threaded connection has the sealing plug, feed mechanism is including the feeding casing and the feeder hopper of integral intercommunication at its top, feeding shells inner wall wholly still is equipped with the crooked passageway that feeds through in the feeder hopper bottom, feeding shells inner wall installs the heating rod, and the heating rod model is the AL.

Preferably, the sliding strips are welded on the front side, the rear side and the left side of the screen plate, the sliding rails matched with the sliding strips are arranged on the front side, the rear side and the left side of the inner wall of the screening shell, and the inner wall of each sliding rail is adhered with a rubber pad wrapped on the sliding strip.

The screen plate and the screening shell are convenient to slide and mount through the matching of the sliding strips and the sliding rails.

Preferably, the bottom end face of the screening shell is obliquely and downwards arranged in a left-high-right-low mode, a space exists between the opening at the right end of the screening shell and the bottom end of the baffle, the bottom end of the screening shell continuously extends towards the lower right side after exceeding the baffle, and the bottom end of the screening shell after extending is bent towards the middle.

This setting can guarantee that qualified grit can be because the straight right shift of inertia falls in the stock chest that has placed in advance when falling.

Preferably, the bottom end of the bending channel extends out of the feeding shell and is opposite to the material receiving barrel at the upper left end of the screening mechanism, and the outer wall of the feeding shell is further provided with air holes.

The arrangement can remove the redundant expanded hot air in the feeding shell through the arrangement of the air vents.

Compared with the prior art, the beneficial effect of this application:

the discharging pipeline of an external elevator for transporting the sand is aligned to the feeding hopper of the feeding mechanism, then the sand entering the feeding shell can move downwards along a bent channel in a rotating mode, the sand can be heated and dried through the heating rod in the downward moving process, the dried sand can continuously fall downwards and enters the inside of the screening shell from the material receiving barrel on the upper portion of the right end of the screening shell, namely the left side of the upper portion of the screen plate falls down, then the qualified sand can fall downwards from the screen plate of the screening shell under the vibration assistance of the vibration motor and rightwards along the inner bottom of the screening shell which is higher at the left side and lower at the right side, the bottom end of the screening shell is bent towards the middle, and therefore the qualified sand can be guaranteed to move rightwards inside a storage tank which is placed in advance due to inertia straight lines when falling, the sand which cannot be completely dried through the feeding mechanism can be adhered to the screen plate generally through the feeding mechanism, and at, The cooperation of violently managing of air inlet and air exit can continue to weather moist grit once more, thereby grit drying efficiency is higher, the screening effect is better, the impurity that leaves after the screening is accomplished just piles up by the scarfing cinder mouth, it just can make impurity be clear away smoothly to remove the sealing plug of unscrewing again, the sieve plate that need change different apertures simultaneously goes to sieve the branch in the use, can separate baffle and screening casing right-hand member with the help of the instrument, the draw runner roll-off slide rail with the sieve plate outer wall can the split again, the operation is comparatively simple.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a front external view of the present invention;

FIG. 3 is a schematic view of the connection between the screen shell and the screen plate of the present invention;

fig. 4 is a schematic view of the position relationship between the screening casing and the slag removing opening of the present invention.

Wherein the reference numerals are summarized as follows: 1. a base; 2. a support; 3. a screening mechanism; 301. a screening housing; 302. a screen plate; 303. a vibration motor; 304. a material receiving barrel; 305. a baffle plate; 306. a slide bar; 307. a blower; 308. a main air inlet pipeline; 309. an air outlet; 4. a feeding mechanism; 401. a feed housing; 402. a feed hopper; 403. a curved channel; 404. a heating rod; 5. a slag removal port; 6. and (4) sealing the plug.

Detailed Description

The invention is further described with reference to the following figures and specific embodiments.

Referring to fig. 1-4, the utility model relates to an inertia linear vibration sand sieving machine, which comprises a base 1, wherein the left and right sides of the upper end surface of the base 1 are integrally provided with a bracket 2, two brackets 2 are provided with a sieving mechanism 3 through bolts, the left end of the upper part of the base 1 is provided with a feeding mechanism 4, the discharge hole at the bottom end of the feeding mechanism 4 is over against the left upper end of the sieving mechanism 3, the sieving mechanism 3 comprises a sieving shell 301 with a high left end and a low right end and a sieve plate 302 slidably connected inside the sieving shell, the front and the back sides of the sieving shell 301 are provided with a vibration motor 303 through bolts, the left end of the upper part of the sieving shell 301 is communicated with a material receiving cylinder 304 positioned under the discharge hole at the bottom end of the feeding mechanism 4, the right end part of the sieve plate 302 is welded with a baffle 305, and the baffle 305 is fixed at, screening casing 301 upper portion is connected with air-blower 307, the air intake intercommunication of air-blower 307 has air inlet trunk line 308, air inlet trunk line 308 end communicates in screening casing 301 and extends to its inside, air inlet trunk line 308 end intercommunication has the air inlet to violently manage, the terminal equidistance intercommunication of air inlet violently manages has air exit 309, the position of screen board 302 right front is higher than the setting of left rear, just screening casing 301 left rear intercommunication has slag removing mouth 5, 5 terminal threaded connection in slag removing mouth have sealing plug 6, feed mechanism 4 is including feed casing 401 and the feeder hopper 402 of integral intercommunication at its top, feed casing 401 inner wall wholly still is equipped with the crooked passageway 403 that communicates in feeder hopper 402 bottom, heating rod 404 is installed to feed casing 401 inner wall.

Both sides and left side all weld draw runner 306 around the screen cloth board 302, both sides and left side all seted up around the inner wall of screening casing 301 with draw runner 306 assorted slide rail, just the slide rail inner wall is stained with the parcel and supports the rubber pad tight in the draw runner. The bottom end face of the screening shell 301 is obliquely arranged downwards in a left-high-right-low mode, a space exists between the opening at the right end of the screening shell 301 and the bottom end of the baffle 305, the bottom end of the screening shell 301 continuously extends towards the lower right after exceeding the baffle 305, and the bottom end of the screening shell 301 after extending is bent towards the middle. The bottom end of the curved channel 403 extends out of the feeding shell 401 and is opposite to the material receiving barrel 304 at the upper left end of the screening mechanism 3, and the outer wall of the feeding shell 401 is further provided with an air hole.

In this embodiment, a feeding pipe of an external elevator for transporting sand is aligned to a feeding hopper 402 of the feeding mechanism 4, then the sand entering the feeding housing 401 moves downwards along a curved channel 403, the sand can be heated and dried by the heating rod 404 during the downward movement, the dried sand can continuously fall downwards and enter the screening housing 301 from the material receiving barrel 304 at the upper part of the right end of the screening housing 301, that is, the sand falls to the left of the upper part of the screen plate 302, then the qualified sand falls downwards from the screen plate 302 of the screening housing 301 under the vibration of the vibration motor 303, and falls to the right along the inner bottom of the screening housing 301 with high left and low right, and the bottom end of the screening housing 301 is curved toward the middle, so that the qualified sand can fall into the storage tank placed in advance due to inertia straight line and right, and the sand which cannot be completely dried by the feeding mechanism 4 usually adheres to the screen plate 302, at this moment, with the help of air-blower 307 and air inlet trunk line 308, the air inlet is violently managed and the cooperation of air exit 309 can continue to weather moist grit once more, thereby grit drying efficiency is higher, the screening effect is better, the impurity that leaves after the screening is accomplished just piles up by scarfing cinder notch 5, remove back-out sealing plug 6 again and just can make impurity be clear away smoothly, the sieve plate 302 that needs to change different apertures in the use simultaneously goes to sieve the time, can separate baffle 305 and screening casing 301 right-hand member with the help of the instrument, the draw runner 306 roll-off slide rail with sieve plate 302 outer wall again can the split, the operation is comparatively simple.

The basic principles, main features and advantages of the present invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. The utility model provides an inertia straight line vibration sand sieving machine, includes base (1), its characterized in that: the screening machine is characterized in that the left side and the right side of the upper end face of the base (1) are integrally provided with supports (2), two screening mechanisms (3) are jointly installed between the two supports (2) through bolts, a feeding mechanism (4) is installed at the left end of the upper portion of the base (1), a discharge hole at the bottom end of the feeding mechanism (4) is just aligned to the left upper end of the screening mechanism (3), each screening mechanism (3) comprises a screening shell (301) with a high left end and a low right end and a screen plate (302) connected in a sliding manner in the screening shell, vibrating motors (303) are installed on the front side and the rear side of the screening shell (301) through bolts, the left end of the upper portion of the screening shell (301) is communicated with a material receiving cylinder (304) positioned under the discharge hole at the bottom end of the feeding mechanism (4), a baffle plate (302) is welded at the right end portion of the screen plate (305, the upper part of the screening shell (301) is connected with a blower (307), an air inlet of the blower (307) is communicated with an air inlet main pipeline (308), the tail end of the air inlet main pipeline (308) is communicated with the screening shell (301) and extends to the interior of the screening shell, the tail end of the air inlet main pipeline (308) is communicated with an air inlet transverse pipe, the tail end of the air inlet transverse pipe is communicated with an air outlet (309) at equal intervals, the position of the right front of the screen plate (302) is higher than the position of the left rear, and the left rear part of the screening shell (301) is communicated with a slag removing opening (5), the tail end of the slag removing opening (5) is connected with a sealing plug (6) in a threaded manner, the feeding mechanism (4) comprises a feeding shell (401) and a feeding hopper (402) integrally communicated with the top of the feeding shell, the feeding shell (401) inner wall is integrally provided with a curved channel (403) communicated with the bottom of the feeding hopper (402), and the inner wall of the feeding shell (401) is provided with a heating rod (404).

2. An inertial linear vibratory sand screen according to claim 1, wherein: both sides and left side all weld draw runner (306) around screen cloth board (302), both sides and left side all seted up with draw runner (306) assorted slide rail around screening casing (301) inner wall, just the slide rail inner wall is stained with the parcel and supports tightly in the rubber pad of slide rail.

3. An inertial linear vibratory sand screen according to claim 1, wherein: the bottom end face of the screening shell (301) is obliquely and downwards arranged in a left-high-right-low mode, a space exists between the opening at the right end of the screening shell (301) and the bottom end of the baffle (305), the bottom end of the screening shell (301) continuously extends towards the lower right side after exceeding the baffle (305), and the bottom end of the screening shell (301) after extending bends towards the middle.

4. An inertial linear vibratory sand screen according to claim 1, wherein: the bottom end of the bent channel (403) extends out of the feeding shell (401) and is opposite to the material receiving barrel (304) at the left upper end of the screening mechanism (3), and the outer wall of the feeding shell (401) is further provided with air holes.

Images