CN219745439U - Homogenization sieving mechanism convenient to clearance - Google Patents

Abstract

The utility model belongs to the technical field of mosquito-repellent incense production, in particular to a homogenizing sieving device convenient to clean, which comprises a sieving bin, wherein mounting grooves are formed in two sides of the inner wall of the sieving bin, a conveyor main body is arranged between the mounting grooves on two sides, a sieving conveyor belt is arranged outside the conveyor main body, and protection bayonets are formed in the front part and the rear part of the inner wall of the sieving bin; replace normal conveyer belt through sieving the conveyer belt for can realize the dynamic screening to the raw materials through the through-hole on sieving the conveyer belt at the conveyer main part itself and carry out pivoted in-process, reach the purpose that reduces raw materials and sieving mechanism and attach each other, collect the hopper through with install the guide arm between the mutually supporting be installed at the inside raw materials that can not pass through the screening of sieving the conveyer belt top of sieving the feed bin, and can realize the purpose of clearing up this raw materials through the empting to collecting the hopper.

Description

Homogenization sieving mechanism convenient to clearance

Technical Field

The utility model belongs to the technical field of mosquito-repellent incense production, and particularly relates to a homogenizing and sieving device convenient to clean.

Background

The mosquito-repellent incense is a mosquito-repellent object, the smoke generated after the medicine is ignited can drive away mosquitoes or fumigate to kill mosquitoes, the mosquito-repellent incense in China has a very long history, the traditional mosquito-repellent incense is divided into two types of incense and coil, the raw materials are required to be homogenized and sieved in the production and processing process of the mosquito-repellent incense, and a corresponding homogenizing process sieving device is used in the process.

At present, the homogenization sieving device in the prior art mainly comprises a sieving bin, a sieving bin bracket, a sieving plate, a homogenization stirring device and other structures, the sieving bin bracket supports the sieving bin, raw materials enter the sieving bin through an opening of the sieving bin and are screened through the sieving plate fixedly arranged in the sieving bin, and the raw materials after reaching the screening standards are conveyed into the homogenization stirring device for homogenization stirring, so that the purpose of homogenization screening of mosquito-repellent incense raw materials is achieved.

But among the prior art, fixed mounting sieves the inside sieve plate itself of sieving the feed bin and follows the holistic vibration of feed bin and vibrate that sieves, reaches the purpose that accelerates the sieve and sieves the raw materials, but this in-process raw materials itself probably attached on the sieve and block up the sieve mesh, and the relative reduction of sieve mesh then reduces the screening efficiency of sieve to the raw materials.

Therefore, a homogenization sieving device convenient to clean is provided for solving the problems.

Disclosure of Invention

In order to make up the defects of the prior art, solve the problem that the relative sieving efficiency of the sieve plate to the raw materials is reduced due to the mutual attachment of the raw materials and the sieve plate, the homogenization sieving device convenient to clean is provided.

The technical scheme adopted for solving the technical problems is as follows: the utility model discloses a homogenization sieving device convenient to clean, which comprises a sieving bin, wherein mounting grooves are formed in two sides of the inner wall of the sieving bin, a conveyor main body is arranged between the mounting grooves in two sides, a sieving conveyor belt is arranged outside the conveyor main body, protection bayonets are formed in the front part and the rear part of the inner wall of the sieving bin, mounting brackets are fixed on one sides above the protection bayonets in the front part and the rear part of the inner wall of the sieving bin, mounting guide rods are vertically fixed in the center of the top surface of each mounting bracket, a collecting hopper is arranged between the two mounting guide rods, linkage brackets are arranged in the front part and the rear part of each collecting hopper, through holes are formed in the top surfaces of the two linkage brackets, and the inner walls of the through holes are mutually clamped with the outer walls of the mounting guide rods.

Preferably, an annular magnet is fixed at the periphery of the through hole on the bottom surface of the linkage support, the bottom surface of the annular magnet is magnetically attracted to the top surface of the mounting support, a receiving slope is fixed on one side of the bottom of the collecting hopper, and smooth transition is realized between the receiving slope and the sieving conveying belt.

Preferably, a sieving hole is formed between the top surface of the receiving slope and the bottom surface of the inner wall of the collecting hopper, and the sieving hole is equal to the inner diameter of the surface through hole of the sieving conveying belt.

Preferably, a clamping plate is installed between the inner walls of the protection bayonets in a clamping manner, one side of the clamping plate is located above the sieving conveyor belt, and a guide rod linkage plate is fixed on the front surface wall of the clamping plate.

Preferably, a limiting guide rod is slidably mounted between the inner walls of the through holes of the guide rod linkage plates, one end of the limiting guide rod is fixed with the surface wall of the sieving bin, and a limiting connecting plate is arranged between the other ends of the limiting guide rod.

Preferably, a reset spring is slidably arranged between the outer walls of the limit guide rods, one end of the reset spring is connected with the front surface of the guide rod linkage plate, and the other end of the reset spring is fixed with the rear part of the limit linkage plate.

The utility model has the beneficial effects that:

the utility model provides a homogenizing sieving device convenient to clean, which is characterized in that a conveyor main body is installed in a sieving bin through an installation groove, a normal conveyor belt is replaced by a sieving conveyor belt, so that raw materials can be dynamically sieved through a through hole on the sieving conveyor belt in the process of rotating the conveyor main body, the purpose of reducing the mutual attachment of the raw materials and the sieving device is achieved, a collecting hopper is installed in the sieving bin through the mutual matching between the collecting hopper and an installation guide rod, the raw materials which cannot pass through the sieving conveyor belt can be collected, the purpose of cleaning the raw materials can be achieved through dumping the collecting hopper, the purpose of cleaning the surface of the sieving conveyor belt can be achieved through the mutual scraping between a receiving slope and the sieving conveyor belt in the process, the dynamic sieving efficiency of the raw materials through holes on the sieving conveyor belt is guaranteed, and the practicability of the device is improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model and do not constitute a limitation on the utility model. In the drawings:

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is a perspective view of a screening bin of the present utility model;

FIG. 3 is a perspective view of a conveyor body according to the present utility model;

FIG. 4 is a perspective view of a collection hopper in accordance with the present utility model;

FIG. 5 is a perspective view of a card of the present utility model;

legend description:

1. sieving a storage bin; 11. a mounting groove; 2. a conveyor body; 21. sieving a conveying belt; 12. a protective bayonet; 13. a mounting bracket; 14. installing a guide rod; 3. a collection hopper; 31. a linkage bracket; 32. a through hole; 33. a ring magnet; 34. receiving a ramp; 35. sieving with sieve pores; 4. a clamping plate; 41. a guide rod linkage plate; 42. a limit guide rod; 43. a limiting connecting plate; 44. and a return spring.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Specific examples are given below.

Referring to fig. 1-5, the utility model provides a homogenization sieving device convenient to clean, which comprises a sieving bin 1, wherein mounting grooves 11 are formed on two sides of the inner wall of the sieving bin 1, a conveyor main body 2 is arranged between the mounting grooves 11 on two sides, a sieving conveyor belt 21 is arranged outside the conveyor main body 2, protective bayonets 12 are formed on the front part and the rear part of the inner wall of the sieving bin 1, mounting brackets 13 are fixed on one side above the front part and the rear part of the inner wall of the sieving bin 1, mounting guide rods 14 are vertically fixed on the center of the top surface of the mounting brackets 13, a collecting hopper 3 is arranged between the two mounting guide rods 14, a linkage bracket 31 is arranged on the front part and the rear part of the collecting hopper 3, through holes 32 are formed on the top surfaces of the two linkage brackets 31, and the inner walls of the through holes 32 are mutually clamped with the outer walls of the mounting guide rods 14;

during operation, in order to solve the raw materials and take place to attach the problem that leads to the fact screening efficiency to reduce through passing through the storehouse screening process with sieve itself, install conveyer main part 2 through mounting groove 11 in screening feed bin 1 inside, and replace normal conveyer belt through screening conveyer belt 21, make the in-process that conveyer main part 2 itself carries out pivoted can realize the dynamic screening to the raw materials through the through-hole on the conveyer belt 21 that sieves, reach the purpose that reduces raw materials and sieving mechanism attached each other, the protection bayonet 12 is the structure of setting up on screening feed bin 1 inner wall and carrying out the installation to the protection device of conveyer belt 21, the relative installation between screening feed bin 1 and the conveyer main part 2 is realized to the installation support 13 by the mutual block between the installation guide arm 14 on screening feed bin 1 inner wall and through on it and the through-hole 32 on linking bridge 31.

Further, as shown in fig. 4, a ring magnet 33 is fixed on the periphery of the bottom through hole 32 of the linkage support 31, the bottom surface of the ring magnet 33 is magnetically attracted to the top surface of the mounting support 13, a receiving slope 34 is fixed on one side of the bottom of the collecting hopper 3, and a smooth transition is formed between the receiving slope 34 and the sieving conveyor belt 21.

In operation, the annular magnet 33 is fixed under the linkage bracket 31, the installation stability of the collecting hopper 3 is increased through the magnetic adsorption between the annular magnet and the installation bracket 13, and the collecting hopper 3 can achieve the aim of cleaning the surface of the sieving conveyor belt 21 through the mutual scraping between the receiving slope 34 and the sieving conveyor belt 21.

Further, as shown in fig. 3, a sieve hole 35 is formed between the top surface of the receiving slope 34 and the bottom surface of the inner wall of the collecting hopper 3, and the sieve hole 35 is equal to the inner diameter of the surface through hole of the sieving conveyor belt 21.

During operation, the screening holes 35 are formed between the receiving slope 34 and the bottom surface of the collecting hopper 3, so that raw materials entering the collecting hopper 3 to achieve screening marking can fall below the conveyor main body 2 from the screening holes 35 and the through holes on the screening conveyor belt 21, and the screening efficiency of the conveyor main body 2 on raw materials cannot be reduced after the collecting hopper 3 is installed.

Further, as shown in fig. 1 and 5, a clamping plate 4 is mounted between the inner walls of the protective bayonet 12 in a clamping manner, one side of the clamping plate 4 is located above the sieving conveyor belt 21, and a guide rod linkage plate 41 is fixed on the front surface wall of the clamping plate 4.

During operation, the protection bayonet 12 is used for installing the clamping plate 4, the clamping plate 4 can block the gap between the screening conveyor belt 21 and the inside of the screening bin 1, the screening conveyor belt 21 plays a certain protection role, and the guide rod linkage plate 41 is an auxiliary structure for realizing the installation of the clamping plate 4 by the screening bin 1.

Further, as shown in fig. 5, a limiting guide rod 42 is slidably mounted between the inner walls of the through holes of the guide rod linkage plate 41, one end of the limiting guide rod 42 is fixed to the surface wall of the sieving bin 1, and a limiting connecting plate 43 is disposed between the other ends of the limiting guide rod 42.

During operation, the guide rod linkage plate 41 is used for installing the limiting guide rod 42 through the upper through hole of the guide rod linkage plate 41, the limiting guide rod 42 is fixed with the side wall of the sieving bin 1, the limiting guide rod 42 can play a role in assisting in fixing the clamping plate 4, and the clamping plate 4 and the protection bayonet 12 can be scraped mutually through the reciprocating motion of the guide rod linkage plate 41, so that raw materials possibly attached to the clamping plate 4 can be cleaned.

Further, as shown in fig. 5, a return spring 44 is slidably mounted between the outer walls of the limit link 42, one end of the return spring 44 is connected to the front surface of the link plate 41, and the other end of the return spring 44 is fixed to the rear portion of the limit link plate 43.

During operation, the guide rod linkage plate 41 and the limiting connecting plate 43 are connected through the reset spring 44, so that the clamping plate 4 has a trend of moving towards the inner wall of the conveyor main body 2 under the elastic acting force of the reset spring 44, the purpose of protecting the sieving conveyor belt 21 is achieved, and the clamping plate 4 is pulled back and forth when the upper part of the clamping plate 4 is required to be cleaned.

Working principle: in order to solve the problem of reduced sieving efficiency caused by adhesion of raw materials to a sieve plate in the sieving process of a passing bin, a conveyor body 2 is mounted in a sieving bin 1 through a mounting groove 11, and a normal conveyor belt is replaced by a sieving conveyor belt 21, so that dynamic sieving of raw materials can be realized through a through hole on the sieving conveyor belt 21 in the rotating process of the conveyor body 2, a mounting bracket 13 is mounted on the inner wall of the sieving bin 1 and realizes relative mounting between the sieving bin 1 and the conveyor body 2 through mutual clamping between a mounting guide rod 14 on the mounting bracket and a through hole 32 on a linkage bracket 31, a ring magnet 33 is fixed below the linkage bracket 31 and increases the mounting stability of a collecting hopper 3 through magnetic adsorption between the ring magnet and the mounting bracket 13, the screening holes 35 are formed between the receiving slope 34 and the bottom surface of the collecting hopper 3, so that raw materials entering the collecting hopper 3 and reaching screening marks can fall below the conveyor main body 2 from the screening holes 35 and through holes in the screening conveyor belt 21, the protection bayonet 12 is used for installing the clamping plates 4, the guide rod linkage plate 41 is used for installing the limit guide rod 42 through the upper through holes, the limit guide rod 42 is fixed with the side wall of the screening bin 1, the guide rod linkage plate 41 and the limit connecting plate 43 are connected through the reset spring 44, the purpose of protecting the screening conveyor belt 21 is achieved due to the fact that the clamping plates 4 move towards the inner wall of the conveyor main body 2 under the elastic acting force of the reset spring 44, and the clamping plates 4 are pulled back and forth when cleaning is needed above the clamping plates 4.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims.

Claims (6)

1. The utility model provides a homogenization sieving mechanism convenient to clearance, includes feed bin (1) that sieves, feed bin (1) inner wall both sides all are provided with mounting groove (11), both sides install conveyer main part (2) between mounting groove (11), the externally mounted of conveyer main part (2) has conveyer belt (21) that sieves, its characterized in that: the utility model discloses a protection bayonet socket (12) has all been seted up to the inner wall front portion and the rear portion of screening feed bin (1), the top one side of the inner wall front portion of screening feed bin (1) and rear portion protection bayonet socket (12) all is fixed with installing support (13), the top surface center department vertical fixation of installing support (13) has installation guide arm (14), two be provided with between installation guide arm (14) and collect hopper (3), the front portion and the rear portion of collecting hopper (3) all are provided with linking bridge (31), two through-hole (32) have all been seted up to the top surface of linking bridge (31), the inner wall of through-hole (32) and the mutual block between the outer wall of installation guide arm (14).

2. A convenient cleaning homogenization sieving apparatus in accordance with claim 1, wherein: the periphery of the bottom surface through hole (32) of the linkage support (31) is fixedly provided with a ring-shaped magnet (33), the bottom surface of the ring-shaped magnet (33) is magnetically attracted to the top surface of the mounting support (13), one side of the bottom of the collecting hopper (3) is fixedly provided with a receiving slope (34), and smooth transition is achieved between the receiving slope (34) and the sieving conveying belt (21).

3. A convenient cleaning homogenization sifting apparatus as claimed in claim 2, wherein: a screening hole (35) is formed between the top surface of the receiving slope (34) and the bottom surface of the inner wall of the collecting hopper (3), and the inner diameter of the screening hole (35) is equal to that of the surface through hole of the screening conveying belt (21).

4. A convenient cleaning homogenization sifting apparatus as claimed in claim 3 wherein: the inner walls of the protection bayonets (12) are clamped and provided with clamping plates (4), one side of each clamping plate (4) is located above the sieving conveying belt (21), and a guide rod linkage plate (41) is fixed on the front surface wall of each clamping plate (4).

5. The easy-to-clean homogenizing and sieving apparatus of claim 4, wherein: a limiting guide rod (42) is slidably mounted between the inner walls of the through holes of the guide rod linkage plates (41), one end of the limiting guide rod (42) is fixed with the surface wall of the sieving bin (1), and a limiting connecting plate (43) is arranged between the other ends of the limiting guide rod (42).

6. A cleaning-facilitated homogenization sieving apparatus in accordance with claim 5 wherein: a reset spring (44) is slidably arranged between the outer walls of the limit guide rods (42), one end of the reset spring (44) is connected with the front surface of the guide rod linkage plate (41), and the other end of the reset spring (44) is fixed with the rear part of the limit linkage plate (43).