CN112850022A - Automatically cleaning belt assembly line - Google Patents

Abstract

The invention discloses a self-cleaning belt assembly line, which structurally comprises a support frame, a conveying table and a base support, wherein the support frame is embedded and fixed at the upper end position of the base support, the conveying table is movably clamped with the support frame, the sliding plate can slide and contract upwards along the sleeve frame by the pulling force of the boosting strip on the clearing mechanism on the sliding plate, so that the lower connecting plate can be attached to the bottom of the conveying belt, the collecting groove can scrape and collect dough attached to the bottom of the conveying table, the situation that viscous dough is adhered to the surface of the conveying table and is difficult to remove is effectively avoided, the thrust generated by the water in the lower cavity to the stressed roller can make the stressed roller rotate along the lower cavity, and the contact plate can be contracted towards the middle part under the matching of the boosting sheet by the extrusion of the moisture on the contact plate, so that the moisture can be discharged downwards between the contact plate and the inner wall of the lower cavity.

Description

Automatically cleaning belt assembly line

Technical Field

The invention relates to the field of belt assembly lines, in particular to a self-cleaning belt assembly line.

Background

Self-cleaning belt assembly line conveyer is mainly used for crossing regional equipment of conveying to the product, through placing the product on the conveyer belt, the product can be driven forward to the rethread conveyer belt and the transmission is carried out, is used to trades such as food processing more, and based on the above-mentioned description the inventor finds that current self-cleaning belt assembly line mainly has following not enough, for example:

because the dough can become sticky when meeting water, if the dough that contains more moisture is carried on automatically cleaning belt assembly line conveyer, then appear partly dough and adhere to and be difficult to drop on the conveyer belt surface easily, stay for a long time and then make remaining dough go mildy easily, lead to the condition that causes the pollution to the dough of newly placing on the conveyer belt.

Disclosure of Invention

In order to solve the problems, the invention provides a self-cleaning belt assembly line.

In order to achieve the purpose, the invention is realized by the following technical scheme: a self-cleaning belt assembly line structurally comprises a support frame, a conveying table and a base support, wherein the support frame is embedded in the upper end position of the base support, and the conveying table is movably clamped with the support frame; the conveying table comprises a conveying belt, a middle connecting plate and a clearing mechanism, the conveying belt is movably clamped with the middle connecting plate, and the clearing mechanism is connected with the middle connecting plate.

As a further optimization of the invention, the clearing mechanism comprises a sleeve frame, a lower connecting plate, a collecting groove, a sliding plate and a boosting strip, wherein the lower connecting plate is fixedly embedded at the bottom position of the sliding plate, the collecting groove and the lower connecting plate are of an integrated structure, the sliding plate is movably clamped with the sleeve frame, and the sliding plate can be continuously pulled to slide upwards along the sleeve frame through the boosting strip.

As a further optimization of the invention, the collecting tank comprises a frame body, a transition block, a counter-elastic sheet and an outward-pushing frame, wherein the transition block is fixedly embedded and connected with the inner wall of the frame body, the counter-elastic sheet and the transition block are of an integrated structure, the outward-pushing frame is movably clamped with the left end of the transition block, and the outward-pushing frame can be contracted inwards along the transition block through vibration generated by the friction between the mechanism and an object through rotation.

As a further optimization of the invention, the extrapolation frame comprises a stress block, two impact blocks and a guide frame, wherein the stress block is embedded and fixed at the inner wall position of the guide frame, the impact blocks are arranged at the inner position of the guide frame, and the two impact blocks are uniformly and symmetrically distributed in the guide frame.

As a further optimization of the invention, the lower connecting plate comprises a stressed roller, a lower row of cavities and a plate surface, wherein the stressed roller is movably clamped with the lower row of cavities, the lower row of cavities and the plate surface are of an integrated structure, and the two stressed rollers are uniformly distributed on the plate surface in a symmetrical mode in a group.

As a further optimization of the invention, the stress roller comprises a boosting sheet, a middle block and four contact plates, wherein the contact plates are connected with the outer surface of the middle block through the boosting sheet, and the four contact plates are uniformly and symmetrically distributed outside the middle block.

As a further optimization of the invention, the contact plate comprises two pushing pieces, two outer swinging plates, two connecting rings and two bearing plates, wherein the pushing pieces are arranged between the inner walls of the outer swinging plates and the bearing plates, the outer swinging plates are hinged with the bearing plates through the connecting rings, and the two outer swinging plates are uniformly and symmetrically distributed on the right sides of the bearing plates.

The invention has the following beneficial effects:

1. the boosting strip on the clearing mechanism can pull and contract the sliding plate along the upward sliding of the sleeve frame, so that the lower connecting plate can be attached to the bottom of the conveying belt, the collecting groove can scrape and collect the attached dough at the bottom of the conveying table, and the situation that the attached dough is difficult to remove on the surface of the conveying table due to the fact that the sticky dough is adhered to the surface of the conveying table is effectively avoided.

2. Thrust that the moisture that produces the atress roller through the intracavity portion down can make the atress roller rotate along the lower chamber of arranging, and through the extrusion that moisture produced to the contact plate, can make the contact plate shrink to the middle part under the cooperation of boosting piece to make moisture can discharge downwards between the inner wall in contact plate and lower chamber down, effectually avoided conveying platform surface adhesion's moisture to strike off the collection by the arc recess on the lower contact plate, and be difficult to the condition of cleaing away.

Drawings

FIG. 1 is a schematic view of a self-cleaning belt line according to the present invention.

FIG. 2 is a side view of a conveyor in half-section.

FIG. 3 is a side view of a half-section of the cleaning mechanism of the present invention.

FIG. 4 is a side view of a half-section of a collection trough according to the present invention.

FIG. 5 is a schematic structural diagram of an extrapolation frame side half section of the present invention.

FIG. 6 is a side view of a half-section of the lower plate of the present invention.

FIG. 7 is a schematic side view of a half-section of the stressed roller of the present invention.

Fig. 8 is a side view of a contact plate in half section.

In the figure: the device comprises a support frame-1, a conveying table-2, a base support-3, a conveying belt-21, an intermediate connecting plate-22, a clearing mechanism-23, a sleeve frame-a 1, a lower connecting plate-a 2, a collecting tank-a 3, a sliding plate-a 4, a boosting strip-a 5, a frame-a 31, a transition block-a 32, a rebound block-a 33, an outward pushing frame-a 34, a stress block-b 1, an impact block-b 2, a guide frame-b 3, a stressed roller-c 1, a lower row cavity-c 2, a plate surface-c 3, a boosting sheet-c 11, an intermediate block-c 12, a contact plate-c 13, a pushing sheet-d 1, an outward swinging plate-d 2, a connecting ring-d 3 and a bearing plate-d 4.

Detailed Description

The technical solutions 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, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1-5:

the invention provides a self-cleaning belt assembly line, which structurally comprises a support frame 1, a conveying table 2 and a base support 3, wherein the support frame 1 is fixedly embedded at the upper end of the base support 3, and the conveying table 2 is movably clamped with the support frame 1; the conveying table 2 comprises a conveying belt 21, an intermediate connecting plate 22 and a clearing mechanism 23, wherein the conveying belt 21 is movably clamped with the intermediate connecting plate 22, and the clearing mechanism 23 is connected with the intermediate connecting plate 22.

The clearing mechanism 23 comprises a sleeve frame a1, a lower connecting plate a2, a collecting groove a3, a sliding plate a4 and a boosting bar a5, wherein the lower connecting plate a2 is embedded at the bottom of the sliding plate a4, the collecting groove a3 and the lower connecting plate a2 are of an integrated structure, the sliding plate a4 is movably clamped with the sleeve frame a1, and the boosting bar a5 can continuously pull the sliding plate a4 to slide upwards along the sleeve frame a1, so that the upper end of the lower connecting plate a2 can be always attached to the surface of an object.

The collecting groove a3 comprises a frame body a31, a transition block a32, a rebound piece a33 and an outward-pushing frame a34, the transition block a32 is fixedly connected with the inner wall of the frame body a31 in an embedded mode, the rebound piece a33 and the transition block a32 are of an integrated structure, the outward-pushing frame a34 is movably clamped with the left end of the transition block a32, the outward-pushing frame a34 can be retracted inwards along the transition block a32 through vibration generated by friction of mechanism rotation and an object, and the outward-pushing frame a34 can be repeatedly stretched and retracted along the transition block a32 under the matching of the rebound piece a 33.

The outward pushing frame a34 comprises a force bearing block b1, an impact block b2 and a guide frame b3, the force bearing block b1 is embedded in the inner wall of the guide frame b3, the impact block b2 is installed in the inner position of the guide frame b3, two impact blocks b2 are arranged and are uniformly distributed in the guide frame b3 in a symmetrical mode, and the two impact blocks b2 can extend forwards along the guide frame b3 when the mechanism extends outwards.

The detailed use method and action of the embodiment are as follows:

in the invention, dough can be conveyed through the conveying table 2, the pulling force generated by the boosting strip a5 on the sliding plate a4 through the clearing mechanism 23 can enable the sliding plate a4 to slide upwards along the sleeve frame a1 and contract, so that the lower connecting plate a2 can be attached to the bottom of the conveying belt 21, the collecting groove a3 can scrape and collect dough attached to the bottom of the conveying table 2, the friction force between the lower connecting plate a2 and the bottom surface of the conveying table 2 can be reduced through the arc-shaped groove on the upper surface of the lower connecting plate a2, so that the lower connecting plate a2 can normally operate, and the outer pushing frame a34 can repeatedly stretch and contract along the transition block a32 under the coordination of the rebounding piece a33 through the vibration generated during the operation of the conveying table 2, so that the impacting block b2 can slide outwards along the guide frame b3, the impact generated by the force block b1 can be applied, so that the vibration generated by the impacting block b2 and the force-applied block b1 can vibrate the scraped dough scraps, the situation that sticky dough is adhered to the surface of the conveying table 2 and is difficult to remove is effectively avoided.

Example 2

As shown in fig. 6-8:

the lower connecting plate a2 comprises a stressed roller c1, a lower row of cavities c2 and a plate surface c3, the stressed roller c1 is movably clamped with the lower row of cavities c2, the lower row of cavities c2 and the plate surface c3 are of an integrated structure, two stressed rollers c1 are arranged, the two stressed rollers c1 are uniformly distributed on the plate surface c3 in a group, and the stressed rollers c1 can rotate along the inner wall of the lower row of cavities c2 through thrust generated by water flow to the stressed rollers c 1.

The stressed roller c1 comprises a boosting sheet c11, a middle block c12 and a contact plate c13, the contact plate c13 is connected with the outer surface of the middle block c12 through the boosting sheet c11, four contact plates c13 are uniformly distributed on the outer portion of the middle block c12 in a symmetrical mode, and the contact plate c13 can shrink towards the middle portion under the matching of the boosting sheet c11 due to the fact that the contact plate c13 is squeezed by water flow.

The contact plate c13 includes a push-out piece d1, an outer swing plate d2, a connecting ring d3 and a bearing plate d4, the push-out piece d1 is installed between the inner wall of the outer swing plate d2 and the bearing plate d4, the outer swing plate d2 is hinged to the bearing plate d4 through a connecting ring d3, two outer swing plates d2 are arranged and are uniformly distributed symmetrically on the right side of the bearing plate d4, and the push-out piece d1 can be enabled to push the push-out piece d1 outwards to swing outwards along the bearing plate d4 by rotating the mechanism to the right below.

The detailed use method and action of the embodiment are as follows:

in the invention, as the viscous dough contains more water, the surface of the conveying table 2 is still attached with water after the dough is scraped, and the water is scraped and collected by the arc-shaped groove on the lower connecting plate a2, if the viscous dough stays in the lower connecting plate a2 for a long time, the dough is deteriorated and the quality of the dough is influenced, the water in the lower cavity c2 generates thrust on the force-receiving roller c1, the force-receiving roller c1 can rotate along the lower cavity c2, the contact plate c13 can shrink towards the middle part under the coordination of the pushing-assisting sheet c11 through the extrusion of the water on the contact plate c13, so that the water can be discharged downwards between the contact plate c13 and the inner wall of the lower cavity c2, when the contact plate c13 rotates to be right below the lower cavity c2, the outward swinging of the outward swinging outward board d2 along the receiving plate d4 can be pushed by the pushing-out sheet d1, and the outward swinging outward board d2 can swing the moisture, the moisture attached to the surface of the conveying table 2 is effectively prevented from being scraped and collected by the arc-shaped groove on the lower connecting plate a2, and if the moisture stays in the lower connecting plate a2 for a long time, the moisture can deteriorate and influence the quality of dough.

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 (7)

1. The utility model provides a self-cleaning belt assembly line, its structure includes support frame (1), conveying platform (2), base support (3), support frame (1) is embedded in the upper end position of base support (3), its characterized in that: the conveying table (2) is movably clamped with the support frame (1);

the conveying table (2) comprises a conveying belt (21), an intermediate connecting plate (22) and a clearing mechanism (23), the conveying belt (21) is movably clamped with the intermediate connecting plate (22), and the clearing mechanism (23) is connected with the intermediate connecting plate (22).

2. A self-cleaning belt line as recited in claim 1, wherein: the clearing mechanism (23) comprises a sleeve frame (a1), a lower connecting plate (a2), a collecting groove (a3), a sliding plate (a4) and a boosting strip (a5), wherein the lower connecting plate (a2) is embedded and fixed at the bottom of the sliding plate (a4), the collecting groove (a3) and the lower connecting plate (a2) are of an integrated structure, and the sliding plate (a4) is movably clamped with the sleeve frame (a 1).

3. A self-cleaning belt line as claimed in claim 2, wherein: the collecting groove (a3) comprises a frame body (a31), a transition block (a32), a rebound sheet (a33) and an outward pushing frame (a34), wherein the transition block (a32) is fixedly embedded in the inner wall of the frame body (a31), the rebound sheet (a33) and the transition block (a32) are of an integrated structure, and the outward pushing frame (a34) is movably clamped with the left end of the transition block (a 32).

4. A self-cleaning belt line as claimed in claim 3, wherein: the outward push frame (a34) comprises a force bearing block (b1), an impact block (b2) and a guide frame (b3), wherein the force bearing block (b1) is embedded in the inner wall position of the guide frame (b3), and the impact block (b2) is installed in the inner position of the guide frame (b 3).

5. A self-cleaning belt line as claimed in claim 2, wherein: the lower connecting plate (a2) comprises a stress roller (c1), a lower row of cavities (c2) and a plate surface (c3), the stress roller (c1) is movably clamped with the lower row of cavities (c2), and the lower row of cavities (c2) and the plate surface (c3) are of an integrated structure.

6. A self-cleaning belt line as claimed in claim 5, wherein: the stress roller (c1) comprises a boosting sheet (c11), a middle block (c12) and a contact plate (c13), wherein the contact plate (c13) is connected with the outer surface of the middle block (c12) through a boosting sheet (c 11).

7. A self-cleaning belt line as claimed in claim 6, wherein: contact plate (c13) are including propelling movement piece (d1), pendulum plate (d2), link ring (d3), accept board (d4), propelling movement piece (d1) are installed between the inner wall of pendulum plate (d2) and accept board (d4), pendulum plate (d2) are through linking ring (d3) and accepting board (d4) hinged joint.

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