CN219729138U - Stacked grain storage container - Google Patents

Abstract

The utility model discloses a laminated grain storage container, which belongs to the technical field of household articles and comprises a container shell, wherein a grain storage box is fixedly connected inside the container shell, when grains need to be taken out, a button is pressed in a rotating assembly to drive a rack to slide inwards through a first chute, a tooth block inside a tooth column rotates on the rack, a second conical gear is driven to rotate through a second connecting rod fixedly connected with the tooth column, the second conical gear and the first conical gear are meshed to move, the first conical gear drives the first connecting rod to rotate, and a fixed amount of grains are collected into a grain conveying channel to fall into the bottom blanking box through a fixed amount of the grains, so that the grain output of the grains is easier to control when the grains are taken out by a user.

Description

Stacked grain storage container

Technical Field

The utility model relates to the technical field of household articles, in particular to a laminated grain storage container.

Background

The grain is a generic term of various plant seeds in cooked foods, and can also be called as grain, the grain storage container is usually used for storing grains such as rice, wheat, beans and the like, certain grains can be stored in family life, but not too much grains can be purchased, other grains are usually stored in one to two jin except rice and flour which are easy to consume, and the stored container is usually selected to have sealing performance.

The grain storage container consists of a grain storage cover, a grain storage box, a grain conveying channel, supporting legs, a rice cup and the like.

The conventional grain container is generally used for storing a variety of grains, and a plurality of grains are usually stored in daily life, so that a plurality of grain storage containers are needed, the stacked grain storage containers can meet the storage requirements of a plurality of grains, and most common grain storage containers in the market control the transportation of grains through the pressing and loosening of buttons when the grains are taken, the consumption of the grains is controlled according to the visual judgment of a user, and although the grains are conveniently taken out, the taken out amount is different from the needed amount when the grains are taken out, so that the grains need to be taken out for many times or the redundant grains need to be poured back into the container again, and the problem of inconvenience is caused.

Disclosure of Invention

1. Technical problem to be solved

The utility model aims to provide a laminated grain storage container which can control the grain consumption according to the visual judgment of a user, and is convenient for taking out grains, but the grain is easy to take out, and the grain is not matched with the required grain, so that the grain needs to be taken out for many times or the redundant grain needs to be poured back into the container again, so that the problem of trouble is solved.

2. Technical proposal

In order to solve the problems, the utility model adopts the following technical scheme.

The utility model provides a range upon range of grain storage container, includes the container shell, the inside fixedly connected with grain storage box of container shell, the top of grain storage box is connected with the lid, the inside center department position fixedly connected with grain delivery passageway of lid, the bottom fixedly connected with blanking fill of lid, the bottom fixedly mounted of container shell has the supporting leg, and evenly distributed is in the bottom, the below of container shell is provided with the blanking box, the bottom of grain storage box is provided with quantitative unloading subassembly, has solved the quantity of control grain according to user's vision judgement, although conveniently takes out grain, but when taking out grain, the quantity that appears taking out easily does not accord with the quantity that needs, leads to taking out many times or pouring unnecessary part back into the container again in, very troublesome problem, lets the user take out the grain of controlling more easily.

Further, quantitative unloading subassembly is including setting up the blanking mouth in the grain storage box bottom, the inner wall rotation of blanking mouth is connected with the impeller, the inside fixedly connected with head rod of impeller, the one end of head rod is provided with rotating assembly, has avoided the not fixed problem of blanking mouth ejection of compact, lets grain take out the volume more fixed.

Further, the blade of impeller uses the centre of a circle of head rod as the axle center evenly to be provided with six, and the width that two blades of same horizontal position are connected is unanimous with the width of blanking mouth, can block grain whereabouts, lets the impeller both can get the material also can play the barrier effect, has increased the practicality of impeller.

Further, the rotating assembly comprises a first conical gear arranged at one end of the first connecting rod, the first conical gear is embedded into the inner wall of the first inner groove, the first inner groove is formed in the inner wall of the container shell, one side of the first conical gear is connected with a second conical gear in a meshed mode, one end of the second conical gear is fixedly connected with a second connecting rod, the other end of the second connecting rod is fixedly connected with a tooth column, the tooth column is arranged in the second inner groove, the second inner groove is formed in the inner wall of the container shell, a rack is arranged at the bottom end of the tooth column, a control assembly is arranged in the tooth column, one end of the rack is fixedly connected with a button, the other end of the rack is provided with a restoring assembly, one end of the rack away from the button is provided with an adjusting assembly, the rack is arranged in the inner portion of the first sliding groove and is in sliding connection, the first sliding groove is formed in the inner wall of the container shell, the button is effectively used for transmitting force to the impeller, and power is provided for rotation of the impeller.

Further, the control assembly is including setting up at the inside U type groove of tooth post, U type groove is circumference array evenly distributed, every the inside in U type groove is all fixedly connected with third connecting rod, every the outer wall of third connecting rod all rotates and is connected with the tooth piece, every one side of tooth piece all is provided with the second spring, the both ends of second spring respectively with tooth piece and tooth post fixed connection, avoided the rack to resume can let the rotation assembly continue to drive the impeller and rotate, the problem that grain continues to fall can let each subassembly all can normally work.

Further, the adjusting part is provided with the baffle including setting up the one end that the button was kept away from at the rack, the bottom fixedly connected with slider of baffle, the inside threaded connection of slider has the threaded rod, the one end fixedly connected with dwang of threaded rod, the bottom sliding connection of slider has the third spout, the inside at container shell is seted up to the third spout, has solved the inconsistent problem of different grain volume demands, lets the container be suitable for better storing the grain of every variety.

Further, the restoring component comprises L-shaped connecting blocks arranged on two sides of the other end of the rack, the other end of each L-shaped connecting block is fixedly connected to the inside of the container shell, and a first spring is sleeved on the outer wall of each L-shaped connecting block.

3. Advantageous effects

Compared with the prior art, the utility model has the following beneficial effects:

according to the grain storage box, the grain conveying channel, the blanking hopper and the rotating assembly are matched with each other, when grains are required to be taken, the button is pressed in the rotating assembly to drive the rack to slide inwards through the first chute, the tooth blocks in the tooth columns rotate on the rack, the second conical gear is driven to rotate through the second connecting rod fixedly connected with the tooth columns, the second conical gear and the first conical gear are meshed to move, the first conical gear drives the first connecting rod to rotate, the impeller fixedly connected with the inner part of the first connecting rod rotates to enable a fixed amount of grains to fall into the blanking hopper from the blanking port, so that the grains are collected into the grain conveying channel and fall into the blanking box at the bottom, the grains are quantitatively taken out, the problem that the consumption of grains is controlled according to visual judgment of a user is solved, and although the grains are conveniently taken out, the taken out easily does not accord with the required quantity when the grains are taken out, so that the grains are required to be taken out repeatedly or redundant parts are poured back into the container again is solved, and the grain is easy to control the grain output when the grains are taken out.

According to the utility model, when the rack is pushed back after the periodic rotation is finished through the control assembly, the rack drives the tooth column to rotate, and the tooth block of the tooth column extrudes the second spring beside the tooth block to slide in the U-shaped groove when the rack is contacted with the tooth column, so that the tooth column does not rotate, and therefore, the rotating assembly does not drive the impeller to rotate, the problem that grains continuously fall due to the fact that the rotating assembly continuously drives the impeller to rotate due to the fact that the rack returns is avoided, and all the assemblies can work normally is avoided.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic diagram of the overall internal structure of the present utility model;

FIG. 3 is a schematic view of the structure of the rotating assembly of the present utility model;

FIG. 4 is an enlarged schematic view of the structure of FIG. 3A according to the present utility model;

FIG. 5 is a schematic diagram of a restoring assembly according to the present utility model;

FIG. 6 is an enlarged schematic view of the structure of FIG. 5B according to the present utility model;

fig. 7 is a schematic structural diagram of a control assembly according to the present utility model.

The reference numerals in the figures illustrate:

1. a container housing; 2. a grain storage box; 3. a cover; 4. a grain conveying channel; 5. a blanking hopper; 6. a blanking port; 7. an impeller; 8. a first connecting rod; 9. a first bevel gear; 10. a first inner tank; 11. a second bevel gear; 12. a second connecting rod; 13. a second inner tank; 14. tooth columns; 15. a rack; 16. a first chute; 17. a button; 18. an L-shaped connecting block; 19. a first spring; 20. a U-shaped groove; 21. a second spring; 22. a third connecting rod; 23. tooth blocks; 24. a baffle; 25. a slide block; 26. a threaded rod; 27. a third chute; 28. a rotating block; 29. support legs; 30. and a blanking box.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model; it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments, and that all other embodiments obtained by persons of ordinary skill in the art without making creative efforts based on the embodiments in the present utility model are within the protection scope of the present utility model.

Examples:

referring to fig. 1 to 7, a stacked grain storage container includes a container housing 1, a grain storage box 2 is fixedly connected to the inside of the container housing 1, a cover 3 is connected to the top of the grain storage box 2, a grain conveying channel 4 is fixedly connected to the center of the inside of the cover 3, a blanking bucket 5 is fixedly connected to the bottom of the cover 3, supporting legs 29 are fixedly mounted at the bottom of the container housing 1 and uniformly distributed at the bottom, a blanking box 30 is arranged below the container housing 1, and a quantitative blanking assembly is arranged at the bottom of the grain storage box 2; through the grain storage box 2 that sets up, the grain passageway 4, blanking fill 5 and rotating assembly mutually support, when grain is got to needs, push button 17 drives rack 15 through first spout 16 inwards to slide in rotating assembly, the inside tooth piece 23 of tooth post 14 rotates on rack 15, drive the rotation of second bevel gear 11 through the second connecting rod 12 with tooth post 14 fixed connection, second bevel gear 11 and first bevel gear 9 meshing motion, first bevel gear 9 drives first connecting rod 8 rotation, the inside fixed connection's of connecting rod 8 impeller 7 rotates and makes fixed quantity's grain fall to blanking fill 5 from blanking mouth 6, thereby grain is collected to the grain passageway 4 and is fallen to bottom blanking box 30, let the ration take out, the quantity of controlling grain according to user's vision judgement is solved, although conveniently take out grain, the quantity that appears easily and the quantity that needs is inconsistent when taking out grain, lead to taking out or in the unnecessary part is poured back into the container again, very trouble problem, let the user take out grain more easily to control the quantity of grain when taking out grain.

Referring to fig. 1-5, the quantitative blanking assembly comprises a blanking port 6 arranged at the bottom of the grain storage box 2, an impeller 7 is rotatably connected to the inner wall of the blanking port 6, a first connecting rod 8 is fixedly connected to the inside of the impeller 7, and a rotating assembly is arranged at one end of the first connecting rod 8; through the ration unloading subassembly that sets up, when the grain is got to the needs ration, head rod 8 runs through in blanking mouth 6 inside, lets the impeller 7 and the blanking mouth 6 form the unloading space through rotating head rod 8, lets grain whereabouts smoothly, and the contained angle equals between every blade of impeller 7 periodic rotation, and the space is unanimous, and the unloading volume is unanimous, has avoided the not fixed problem of blanking mouth ejection of compact, lets grain take the volume more fixed.

Referring to fig. 1-5, six blades of the impeller 7 are uniformly arranged with the center of the first connecting rod 8 as the axis, and the connecting width of two blades at the same horizontal position is consistent with the width of the blanking port 6; the width that is connected through the impeller 7 that sets up and two blades of same horizontal position is unanimous with the width of blanking mouth 6, can block the grain whereabouts, lets impeller 7 both can get the material also can play the barrier effect, has increased impeller 7's practicality.

Referring to fig. 1-3, the rotating assembly includes a first conical gear 9 disposed at one end of a first connecting rod 8, the first conical gear 9 is embedded into an inner wall of a first inner groove 10, the first inner groove 10 is disposed on an inner wall of a container housing 1, one side of the first conical gear 9 is engaged with and connected with a second conical gear 11, one end of the second conical gear 11 is fixedly connected with a second connecting rod 12, the other end of the second connecting rod 12 is fixedly connected with a tooth column 14, the tooth column 14 is disposed inside a second inner groove 13, the second inner groove 13 is disposed on an inner wall of the container housing 1, a rack 15 is disposed at a bottom end of the tooth column 14, a control assembly is disposed inside the tooth column 14, one end of the rack 15 is fixedly connected with a button 17, the other end of the rack 15 is provided with a restoring assembly, one end of the rack 15 far from the button 17 is provided with an adjusting assembly, the rack 15 is disposed inside the first chute 16, and is slidingly connected with the first chute 16 disposed on an inner wall of the container housing 1; through the rotating assembly who sets up, when grain is got to needs, push button 17 promotes rack 15 and inwards slides through first spout 16, and the inside tooth piece 23 of tooth post 14 rotates on rack 15 and drives tooth post 14 rotation, and tooth post 14 fixed connection's second connecting rod 12 rotates and drives second bevel gear 11 and rotate, and second bevel gear 11 meshes with first bevel gear 9, and first bevel gear 9 drives the impeller 7 rotation of head rod 8 and head rod 8 fixed connection, effectively makes button 17 with power transmission to impeller 7, provides power for the rotation of impeller 7.

Referring to fig. 1-7, the control assembly includes U-shaped grooves disposed inside the tooth column 14, the U-shaped grooves are uniformly distributed in a circumferential array, a third connecting rod 22 is fixedly connected inside each U-shaped groove, a tooth block 23 is rotatably connected to an outer wall of each third connecting rod 22, a second spring 21 is disposed on one side of each tooth block 23, and two ends of the second spring 21 are fixedly connected with the tooth block 23 and the tooth column 14 respectively; through the control assembly who sets up, when periodic rotation finishes rack 15 back propelling movement, rack 15 can drive tooth post 14 and rotate, through the second spring 21 of the tooth piece 23 extrusion tooth piece 23 next door of rack 14 when rack 15 and tooth post 14 contact in U type inslot slip, let tooth post 14 not rotate, therefore the rotating assembly can not drive impeller 7 and rotate, the problem that rack 15 resumes and can let rotating assembly continue to drive impeller 7 and rotate, cause grain to continue the whereabouts is avoided, each subassembly can all normally work.

Referring to fig. 1-6, the adjusting assembly includes a baffle 24 disposed at one end of the rack 15 far away from the button 17, a slider 25 fixedly connected to the bottom end of the baffle 24, a threaded rod 26 screwed inside the slider 25, a rotating block 28 fixedly connected to one end of the threaded rod 26, a third sliding chute 27 slidingly connected to the bottom of the slider 25, and the third sliding chute 27 is opened inside the container casing 1; through the adjusting part who sets up, when the volume of getting of grain needs to be changed, rotate the turning block 28 and drive threaded rod 26 rotation, threaded rod 26 and slider 25 threaded connection, slider 25 slides in threaded rod 26, drive the baffle 24 at slider 25 top and remove, through changing the front and back position of baffle 24 thereby change rack 15 forward propulsive distance, control tooth post 14 lets the cycle of rotating the subassembly change, thereby adjust impeller 7 pivoted cycle, the volume of control unloading, the inconsistent problem of different grain volume demands has been solved, let the container be suitable for better and store the grain of every variety.

Referring to fig. 1 to 6, the restoring assembly includes an L-shaped connection block disposed at two sides of the other end of the rack 15, the other end of the L-shaped connection block is fixedly connected to the inside of the container housing 1, and a first spring 19 is sleeved on the outer wall of the L-shaped connection block; through the reply subassembly that sets up, after pressing button 17, the rotation cycle is over, and the first spring 19 of atress compression originally is in the resilience after not atress extrusion, and L shape connecting block that one end is connected drives fixed connection's rack 15 and returns to original position.

In the utility model, when grains are required to be taken from a container, a button 17 is pressed to drive a rack 15 to slide inwards through a first chute 16, the movement of the rack 15 drives a tooth block 23 to rotate, the rotation of the tooth block 23 drives a tooth column 14 to rotate, the tooth column 14 drives a second bevel gear 11 to rotate through a second connecting rod 12, the rotation of the second bevel gear 11 drives a first bevel gear 9 to rotate, the rotation of the first bevel gear 9 drives a first connecting rod 8 to rotate, the rotation of the first connecting rod 8 drives an impeller 7 to rotate in a blanking port 6, grains at the top end of the impeller 7 drop downwards, and the grains drop into a blanking box 30 through a blanking hopper 5 and a grain conveying channel 4, so that the grains are quantitatively taken out.

Under the condition that grains are taken out, the button 17 is loosened, the first spring 19 returns to drive the L-shaped connecting block to move outwards under the action of the first spring 19 after being not extruded by force, the L-shaped connecting block moves to drive the rack 15 to move, and the button 17 fixedly connected with the rack 15 returns to the original position.

When the rack 15 is pushed back, in order not to enable the impeller 7 to rotate under force, the tooth block 23 in the tooth column 14 can squeeze the second spring 21 beside the tooth block 23 to slide in the U-shaped groove, so that the tooth block 23 cannot rotate due to pushing of the rack 15, the tooth column 14 cannot rotate, and when the rack 15 is pushed back, the rotating assembly cannot continuously drive the impeller 7 to rotate, and movement interference of all the assemblies is prevented.

Under the condition that daily consumption of grains is different in each household, the grain taking amount needs to be adjusted, the rotating block 28 is used for driving the threaded rod 26 to rotate in the third sliding groove 27, the threaded rod 26 is in threaded connection with the sliding block 25, the sliding block 25 slides on the outer wall of the threaded rod 26 to drive the baffle 24 at the top of the sliding block 25 to move back and forth in the third sliding groove 27, the forward pushing distance of the rack 15 is changed by changing the front and back positions of the baffle 24, the pushing distance of the rack 15 is shortened, the rotation number of turns of the tooth column 14 is reduced, the transmission of the rotating component is reduced, the rotation period of the impeller 7 is shortened, and grains falling from the blanking port 6 are reduced, so that the grain taking amount is reduced; otherwise, the grain taking amount becomes large.

The above description is only of the preferred embodiments of the present utility model; the scope of the utility model is not limited in this respect. Any person skilled in the art, within the technical scope of the present disclosure, may apply to the present utility model, and the technical solution and the improvement thereof are all covered by the protection scope of the present utility model.

Claims (7)

1. A laminated grain storage container comprising a container housing (1), characterized in that: the novel grain storage box is characterized in that the grain storage box (2) is fixedly connected to the inside of the container shell (1), the cover (3) is connected to the top of the grain storage box (2), the grain conveying channel (4) is fixedly connected to the position of the center inside the cover (3), the blanking hopper (5) is fixedly connected to the bottom of the cover (3), supporting legs (29) are fixedly installed at the bottom of the container shell (1), the blanking boxes (30) are uniformly distributed at the bottom of the container shell (1), and quantitative blanking components are arranged at the bottom of the grain storage box (2).

2. The laminated grain storage container of claim 1, wherein: the quantitative blanking assembly comprises a blanking port (6) arranged at the bottom of the grain storage box (2), an impeller (7) is rotatably connected to the inner wall of the blanking port (6), a first connecting rod (8) is fixedly connected to the inside of the impeller (7), and a rotating assembly is arranged at one end of the first connecting rod (8).

3. The laminated grain storage container of claim 2, wherein: six blades of the impeller (7) are uniformly arranged by taking the center of a first connecting rod (8) as the axis, and the connecting width of two blades at the same horizontal position is consistent with the width of the blanking port (6).

4. A laminated grain storage container as claimed in claim 3, wherein: the utility model provides a container, including rotating assembly, including setting up first conical gear (9) in head rod (8) one end, the inner wall in first inside groove (10) is inlayed to first conical gear (9), the inner wall in container shell (1) is seted up to first inside groove (10), one side meshing of first conical gear (9) is connected with second conical gear (11), the one end fixedly connected with second connecting rod (12) of second conical gear (11), the other end fixedly connected with tooth post (14) of second connecting rod (12), tooth post (14) set up the inside in second inside groove (13), the inner wall in container shell (1) is seted up to second inside groove (13), the bottom of tooth post (14) is provided with rack (15), the inside of tooth post (14) is provided with control assembly, the one end fixedly connected with button (17) of rack (15), the other end of rack (15) is provided with and resumes the subassembly, the one end that button (17) were kept away from to rack (15) is provided with adjusting part, rack (15) set up in the inside of first spout (16), the inside of first spout (16) is seted up to slide.

5. The laminated grain storage container of claim 4, wherein: the control assembly comprises U-shaped grooves arranged inside the tooth column (14), the U-shaped grooves are uniformly distributed in a circumferential array, each U-shaped groove is fixedly connected with a third connecting rod (22) in the U-shaped groove, each third connecting rod (22) is rotatably connected with a tooth block (23) on the outer wall, one side of each tooth block (23) is provided with a second spring (21), and two ends of each second spring (21) are fixedly connected with the tooth block (23) and the tooth column (14) respectively.

6. The laminated grain storage container of claim 4, wherein: the adjusting component comprises a baffle (24) arranged at one end, far away from the button (17), of the rack (15), a sliding block (25) is fixedly connected to the bottom end of the baffle (24), a threaded rod (26) is connected to the inner thread of the sliding block (25), a rotating block (28) is fixedly connected to one end of the threaded rod (26), a third sliding groove (27) is connected to the bottom of the sliding block (25) in a sliding mode, and the third sliding groove (27) is formed in the container shell (1).

7. The laminated grain storage container of claim 4, wherein: the recovery component comprises L-shaped connecting blocks arranged on two sides of the other end of the rack (15), the other end of each L-shaped connecting block is fixedly connected to the inside of the container shell (1), and a first spring (19) is sleeved on the outer wall of each L-shaped connecting block.