CN218835194U - Linear sieve movable discharge port - Google Patents

Abstract

The utility model discloses a rectilinear sieve activity discharge gate relates to the relevant technical field of rectilinear sieve. The utility model discloses a rectilinear sieve, first derivation fill, divide the material shell, shell and frame are derived to flexibility, be fixed with two sieves about corresponding in the rectilinear sieve, one side upper portion and the lower part of two sieves all are fixed with flexible splint, first derivation fill and second are derived the fill top and are fixed with jointly and divide the material shell, first derivation fill and second are derived the output of fighting and all fixed intercommunication that has flexibility to derive the shell, export has been seted up on the rear side upper portion of flexibility derivation shell, the flexibility is derived the shell outside and is provided with the frame with exporting the port position correspondingly. The utility model discloses a set up sharp sieve, first derivation fill, divide material shell, flexibility to derive shell and frame, solved the problem that sharp sieve discharge gate ejection of compact mode is relatively poor to multiple ejection of compact position suitability and discharge gate median septum warp the influence screening result easily after long-time the use.

Description

Linear sieve movable discharge port

Technical Field

The utility model belongs to the technical field of the straight line is sieved is relevant, especially relates to a straight line sieve activity discharge gate.

Background

The linear sieve is driven by two motors, when the two motors synchronously and reversely rotate, the exciting forces generated by the eccentric blocks of the two motors are mutually offset in the direction parallel to the axes of the motors and are superposed into a resultant force in the direction vertical to the axes of the motors, so that the motion trail of the sieve is a straight line. The two motor shafts have an inclination angle relative to the screen surface, under the combined action of exciting force and material self-gravity, the material is thrown up on the screen surface and makes forward linear motion in a jumping manner, so that the purpose of screening and grading the material is achieved, and after screening, the material is led out to corresponding equipment through a discharge port, but the two motor shafts still have the following defects in actual use:

1. when the linear screen discharging port works, two or more discharging positions are usually provided for outputting materials screened by the linear screen and screened by the linear screen, and the two materials can be conveyed to different processing equipment;

2. during the work of the discharge port of the linear screen, the linear screen is contacted with the bottom of the inner screen plate of the vibrating screen through the partition plate, so that materials on the vibrating screen are guided to the discharge port, the partition plate is vibrated by the vibrating screen and hit by the materials for a long time, the deformation is easy to occur, gaps between the materials are increased, and the materials are easy to leak during the work, so that the screening work is influenced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a rectilinear sieve activity discharge gate through setting up rectilinear sieve, first leading-out fill, dividing material shell, flexibility leading-out shell and frame, has solved rectilinear sieve discharge gate ejection of compact mode to the relatively poor and discharge gate median septum of multiple ejection of compact position suitability after long-time use easy deformation influence screening result's problem.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to a rectilinear sieve activity discharge gate, including rectilinear sieve, first derivation fill, divide the material shell, flexibility derivation shell and frame, be fixed with two sieves, two correspondingly from top to bottom in the rectilinear sieve one side upper portion and the lower part of sieve all are fixed with the elasticity splint, one side that rectilinear sieve bottom is close to the elasticity splint is fixed with the second derivation fill, one side that rectilinear sieve was kept away from to the second derivation fill is fixed with first derivation fill, first derivation fill and second are derived and are fought the top and be fixed with jointly and divide the material shell, first derivation fill and the output that the second was derived to fight all fixed intercommunication have flexibility derivation shell, the export has been seted up on the rear side upper portion of flexibility derivation shell, the flexible derivation shell outside is provided with the frame with derivation exit position corresponding, when using, the utility model discloses a rectilinear sieve separately carries the material through dividing the material shell and exports first derivation fill and the second derivation fill, and exports the frame through the flexible derivation on the shell of exporting that the material transported in first derivation fill and the second export and export through flexible derivation shell, the sealed structure of exporting the bottom of exporting the material.

Furthermore, a side connecting plate is fixed on one side of the linear sieve close to the first guide hopper, an outer connecting frame is fixed on the outer side of the material distribution shell, and the linear sieve is fixed with the outer connecting frame on the material distribution shell through the side connecting plate through a bolt and a nut, so that the linear sieve is connected with the material distribution shell.

Furthermore, first derivation fill and second derivation fill outside upper portion is fixed with the connection frame jointly, one side that the connection frame top is close to the rectilinear sieve is fixed in the bottom of rectilinear sieve, and first derivation fill and second derivation fill are connected in the bottom of rectilinear sieve through the connection frame.

Furthermore, a partition plate is fixed on the lower portion of one side, close to the linear sieve, of the material distribution shell, one side, close to the linear sieve, of the partition plate is movably connected between the two elastic clamping plates on the sieve plate, the bottom of the partition plate is arranged on one side, close to the tops of the first derivation hopper and the second derivation hopper, of the partition plate, and the screened materials are conveyed in the material distribution shell in a separated mode through the partition plate.

Further, the frame inner wall is fixed with the cardboard with the export position is fixed with correspondingly, the cardboard joint is in exporting the mouth, and the frame passes through the cardboard and exports the export closure on with flexibility derivation shell.

Furthermore, the two sides of the outer frame are correspondingly communicated with and inserted with mounting bolts up and down, the two sides of the flexible leading-out shell are correspondingly fixed with side plates with the two sides of the inner wall of the outer frame, the end parts of the mounting bolts are connected in the side plates in a threaded manner, the outer frame is inserted in the mounting bolts and screwed into the side plates, and therefore the flexible leading-out shell and the outer frame are connected together.

The utility model discloses following beneficial effect has:

1. the utility model discloses a set up the rectilinear sieve, first derivation fill, divide the material shell, flexibility derives shell and frame, the relatively poor problem of rectilinear sieve discharge gate ejection of compact mode to multiple ejection of compact position suitability has been solved, confirm the position that the material was derived, if direct down, just directly start the rectilinear sieve, if skew some point position, raise to the direction of keeping away from the rectilinear sieve through deriving the shell bottom with flexibility, and make flexibility derive the shell bottom be higher than its and first derivation fill or second derive after fighting the one end height of connecting, when the export does not shelter from, the material of carrying in the flexibility derives the shell is derived through the export, if the skew position is far away, can directly remove the bottom of flexibility derivation shell under the condition of good frame fixed on it and derive the position, make the utility model discloses it is various to derive the mode, can be applicable to the position that multiple material was derived better.

2. The utility model discloses a set up the sharp sieve, first derivation is fought and is divided the material shell, the problem of sharp sieve discharge gate median septum easy deformation influence screening result after long-time the use has been solved, the sieve leads to dividing the material shell to the material after screening on it through the elasticity splint, and lead to the baffle clamp that will divide in the material shell on it, and press from both sides tightly between elasticity splint and the baffle, prevent that the material from mixing in the position of deriving, and all seal the gap between sieve and the baffle from top to bottom, restrict the baffle well, prevent the position of baffle and sieve contact better because hitting of the material from causing the deformation, produce the gap.

Drawings

FIG. 1 is a perspective view of the assembly structure of the present invention;

FIG. 2 is a perspective view of the combined structure of the linear sieve, the first guide hopper and the second guide hopper of the present invention;

FIG. 3 is an enlarged view of the structure A of FIG. 2 according to the present invention;

FIG. 4 is a perspective view of the material distributing shell structure of the present invention;

fig. 5 is a perspective view of the flexible leading-out case structure of the present invention;

fig. 6 is a perspective view of the outer frame structure of the present invention.

Reference numerals:

100. a linear sieve; 101. a sieve plate; 102. an elastic splint; 103. a side connection plate; 200. a first discharge hopper; 201. a connecting frame; 300. a second leading-out hopper; 400. a material distributing shell; 401. a partition plate; 402. an outer connecting frame; 500. a flexible lead-out housing; 501. a lead-out port; 502. a side plate; 600. an outer frame; 601. installing a bolt; 602. and (4) clamping the board.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention.

Referring to fig. 1-6, the present invention relates to a movable discharge port of a linear sieve, including a linear sieve 100, a first discharge hopper 200, a distribution shell 400, a flexible discharge shell 500 and an outer frame 600, wherein two sieve plates 101 are fixed in the linear sieve 100 up and down correspondingly, when the linear sieve 100 works, the materials introduced therein are screened by the sieve plates 101 when vibrating, and are screened by one sieve plate 101, the other sieve plate 101 is guided, and finally guided to the position of the distribution shell 400, the upper and lower parts of one side of the two sieve plates 101 are both fixed with elastic clamping plates 102, the sieve plates 101 guide the materials screened thereon into the distribution shell 400 by the elastic clamping plates 102, and clamp the partition plates 401 in the distribution shell 400, and clamp between the elastic clamping plates 102 and 401, so as to prevent the materials from mixing at the positions led out, and seal the gaps between the sieve plates 101 and 401 up and down, the side of the bottom of the linear sieve 100 close to the elastic clamping plates 102 is fixed with a second discharge hopper 300, the second discharge hopper 300 has two discharge positions, the materials are uniformly discharged from the linear sieve 100, the linear sieve 100 and the second discharge hopper 300, the flexible discharge hopper 300 are both discharged into the second hopper 200, the flexible discharge hopper 200 and the second hopper 200, the second hopper 300 are both discharged from the flexible discharge hopper 500, the second hopper 200, the flexible hopper 200, export 501 has been seted up on the rear side upper portion of flexibility derivation shell 500, raise to the direction of keeping away from rectilinear sieve 100 through exporting the shell 500 bottom with flexibility, and make flexibility derivation shell 500 bottom be higher than its and first derivation fill 200 or the second export fill 300 one end height back of connecting, when export 501 does not shelter from, the material of carrying in the flexibility derivation shell 500 exports through export 501, the flexibility derivation shell 500 outside is provided with frame 600 with export 501 position correspondence, export 501 on the shell 500 is exported with flexibility to cardboard 602 in frame 600 seals.

As shown in fig. 1 to 3, a side connecting plate 103 is fixed on one side of the linear sieve 100 close to the first guiding hopper 200, an outer connecting frame 402 is fixed on the outer side of the material distributing shell 400, holes for inserting mounting bolts are correspondingly formed on the side connecting plate 103 and the outer connecting frame 402, when the material distributing shell 400 is placed on the tops of the first guiding hopper 200 and the second guiding hopper 300, and the side connecting plate 103 and the outer connecting frame 402 are correspondingly contacted, the mounting bolts are inserted into the outer connecting frame 402 and extend out of the side connecting plate 103, and then the mounting nuts are screwed onto the mounting bolts and tightened, so that the material distributing shell 400 and the linear sieve 100 are connected together.

As shown in fig. 1 to 3, a connection frame 201 is fixed to the upper portions of the outer sides of the first guide-out hopper 200 and the second guide-out hopper 300, the top of the connection frame 201 is close to one side of the linear screen 100 and is fixed to the bottom of the linear screen 100, the first guide-out hopper 200 and the second guide-out hopper 300 are fixed to the linear screen 100 through the connection frame 201, holes for inserting mounting bolts are correspondingly formed in the bottoms of the connection frame 201 and the outer connection frame 402, after the material separating shell 400 and the linear screen 100 are connected, the mounting bolts are inserted into the outer connection frame 402 and extend out of the connection frame 201, the mounting nuts are screwed onto the mounting bolts and are screwed, and the material separating shell 400 is connected with the first guide-out hopper 200 and the second guide-out hopper 300.

As shown in fig. 1 and 4, a partition plate 401 is fixed at a lower portion of one side of the distribution shell 400 close to the linear sieve 100, one side of the partition plate 401 close to the linear sieve 100 is movably connected between two elastic clamping plates 102 on the sieve plate 101, and is used for separating and conveying screened and screened materials in the distribution shell 400, the sieve plate 101 inserted with the partition plate 401 is fixed at a position of the linear sieve 100 close to the top, and conveys the screened materials, and the bottom of the partition plate 401 is arranged at a side of the first guide-out hopper 200 and the top of the second guide-out hopper 300 close to each other, so that the partition plate 401 close to the distribution shell 400 at one side of the first guide-out hopper 200 conveys the materials screened on the sieve plate 101 without screening function, and the partition plate 401 far away from the distribution shell 400 at one side of the first guide-out hopper 200 conveys the materials screened on the sieve plate 101 with screening function.

As shown in fig. 1, 5, and 6, the inner wall of the outer frame 600 is fixed with a clamping plate 602 corresponding to the position of the outlet 501, the clamping plate 602 is clamped in the outlet 501, and when the outer frame 600 is connected with the flexible outlet casing 500, the outlet 501 on the flexible outlet casing 500 is sealed.

As shown in fig. 1, 5, and 6, mounting bolts 601 are inserted into two sides of the outer frame 600 in a vertically corresponding manner, side plates 502 are fixed to two sides of the flexible lead-out case 500 in positions corresponding to two sides of the inner wall of the outer frame 600, end portions of the mounting bolts 601 are screwed into the side plates 502, the clamping plates 602 in the outer frame 600 are clamped into the lead-out openings 501, the mounting bolts 601 are screwed into the side plates 502 after the outer frame 600 and the side plates 502 are aligned, and the outer frame 600 and the flexible lead-out case 500 are connected together after the mounting bolts 601 are screwed.

The utility model discloses a concrete theory of operation does: in operation, after the rectilinear sieve 100, the first discharge hopper 200, the material distribution housing 400 and the flexible discharge housing 500 are connected together, the position for discharging the material is determined, if the material is directly downward, the rectilinear sieve 100 is directly started, if the position deviates from a point position, the bottom end of the flexible discharge housing 500 is lifted in a direction away from the rectilinear sieve 100, and the bottom end of the flexible discharge housing 500 is higher than the height of one end connected with the first discharge hopper 200 or the second discharge hopper 300, when the discharge port 501 is not blocked, the material conveyed in the flexible discharge housing 500 is discharged through the discharge port 501, if the position deviates further, the bottom of the flexible discharge housing 500 can be directly moved to the discharge position under the condition that the outer frame 600 is fixed on the flexible discharge housing, then the rectilinear sieve 100 is started, the material introduced into the rectilinear sieve 100 falls into the sieve plate 101 with the sieving function near the top of the sieve plate with the sieving function, falls onto the sieve plate 101 without the sieving function, the sieved material is guided onto one side of the inner partition plate 401 of the material distribution housing 400, the second discharge hopper 300, the material is directly discharged into the flexible discharge housing 500, and is directly discharged into the second discharge housing 500.

The above is only the preferred embodiment of the present invention, and the present invention is not limited thereto, any technical solutions recorded in the foregoing embodiments are modified, and some technical features thereof are replaced with equivalent ones, and any modification, equivalent replacement, and improvement made thereby all belong to the protection scope of the present invention.

Claims (6)

1. The utility model provides a rectilinear sieve activity discharge gate, includes rectilinear sieve (100), first derivation fill (200), divides material shell (400), flexible derivation shell (500) and frame (600), its characterized in that: be fixed with two sieve boards (101) about corresponding in rectilinear sieve (100), two one side upper portion and the lower part of sieve board (101) all are fixed with elasticity splint (102), one side that rectilinear sieve (100) bottom is close to elasticity splint (102) is fixed with the second and derives fill (300), the second is derived one side of fighting (300) keeping away from rectilinear sieve (100) and is fixed with first derivation fill (200), first derivation fill (200) and second are derived fill (300) top and are fixed with branch material shell (400) jointly, the output that first derivation fill (200) and second were derived fill (300) all is fixed the intercommunication has flexible derivation shell (500), export (501) have been seted up on the rear side upper portion of flexible derivation shell (500), the flexible derivation shell (500) outside is provided with export (600) position correspondently with.

2. The movable discharge hole of the linear sieve of claim 1, which is characterized in that: a side connecting plate (103) is fixed on one side, close to the first guide-out hopper (200), of the linear sieve (100), and an outer connecting frame (402) is fixed on the outer side of the material distribution shell (400).

3. The movable discharge hole of the linear sieve of claim 1, which is characterized in that: the upper parts of the outer sides of the first guide-out hopper (200) and the second guide-out hopper (300) are jointly fixed with a connecting frame (201), and one side, close to the linear screen (100), of the top of the connecting frame (201) is fixed to the bottom of the linear screen (100).

4. The movable discharge hole of the linear sieve of claim 1, which is characterized in that: a partition plate (401) is fixed on the lower portion of one side, close to the linear sieve (100), in the material distributing shell (400), one side, close to the linear sieve (100), of the partition plate (401) is movably connected between two elastic clamping plates (102) on the sieve plate (101), and the bottom of the partition plate (401) is arranged on one side, close to the tops of the first guiding-out hopper (200) and the second guiding-out hopper (300), of the partition plate.

5. The movable discharge hole of the linear sieve of claim 1, which is characterized in that: the inner wall of the outer frame (600) is fixed with a clamping plate (602) corresponding to the position of the outlet (501), and the clamping plate (602) is clamped in the outlet (501).

6. The movable discharge port of the linear screen according to claim 1, characterized in that: the flexible guide shell is characterized in that mounting bolts (601) are correspondingly inserted into two sides of the outer frame (600) in a vertically penetrating mode, side plates (502) are correspondingly fixed to two sides of the flexible guide shell (500) and two sides of the inner wall of the outer frame (600), and end portions of the mounting bolts (601) are connected into the side plates (502) in a threaded mode.

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