CN111762446A - Container, quantitative taking mechanism and powder storage device with quantitative taking mechanism - Google Patents

Abstract

The utility model relates to the technical field of packaging container, the utility model discloses a container, mechanism is taken to ration and powder storage device who takes the mechanism has the ration, wherein the ration is taken the mechanism and is included the mount pad and install in the distribution portion of mount pad, the mount pad is both ends open-ended tube structure, the distribution portion is installed inside the mount pad, the distribution portion is including connecting in a plurality of spacers of mount pad inner wall, the spacer uses the mount pad axle center as central evenly distributed, divide into the fan-shaped quantitative check room that a plurality of volumes equal with the mount pad inner chamber in circumference. This application has realized that the ration is got the material, and portable.

Description

Container, quantitative taking mechanism and powder storage device with quantitative taking mechanism

Technical Field

The application relates to the technical field of packaging containers, in particular to a container, a quantitative taking mechanism and a powder storage device with the quantitative taking mechanism.

Background

The milk powder tank is a container for storing milk powder, and in daily life, the volume of the milk powder tank for directly purchasing the milk powder by consumers is large, so that the milk powder tank is not easy to carry when going out.

To the above problem, most users adopt the mode of directly filling the milk powder in the milk powder can into the milk powder bottle to facilitate carrying, but the milk powder is not only easy to be sprinkled to the outside of the milk powder bottle, but also is not beneficial to quantitatively measuring the milk powder.

Disclosure of Invention

In order to improve the inconvenience of carrying to and the problem that the ration was taken to the inconvenient, this application provides a mechanism and has powder storage device that the mechanism was taken to ration to container, ration.

In a first aspect, the present application provides a container, which adopts the following technical solutions:

the container is a tank body with an opening on one side, the opening end of the tank body is provided with first threads, and one end, away from the opening of the tank body, of each first thread is connected with a first locking part.

In some embodiments, the first locking portion is a first clamping interface which is opened at one end of the first thread, which is far away from the opening of the tank body.

In some embodiments, the first locking portion is a first clamping block, an end of the first locking block is connected to one end of the first thread, the end of the first locking block is far away from the opening of the tank body, and the first clamping block and the first thread are arranged in a crossed mode.

In some embodiments, the inner cavity of the tank is tapered, and the caliber of the opening end of the inner cavity is larger than that of the bottom end of the inner cavity.

Through adopting above-mentioned technical scheme, the intussusception each other of the jar body of being convenient for increases the transportation volume of the same volume, reduces the cost of transportation.

In a second aspect, the present application provides a quantitative taking mechanism, which adopts the following technical scheme:

the quantitative taking mechanism comprises a mounting seat and a distributing part mounted on the mounting seat, the mounting seat is mounted at the opening of the container, the mounting seat is provided with a second thread matched with the first thread, the end part of the second thread is connected with a second locking part matched with the first locking part, the end part of the second locking part is connected with a second clamping block of the second thread, the second clamping block and the second thread are arranged in a cross mode, and the second clamping block can be clamped in the first clamping opening.

Through adopting above-mentioned technical scheme, take the second hasp portion on the mechanism mutually supporting through first hasp portion on the container and ration, realized that container and ration take the mutual locking of mechanism, it is not hard up after avoiding connecting.

The quantitative taking mechanism comprises a mounting seat and a distributing part mounted on the mounting seat, the mounting seat is mounted at the opening of the container, the mounting seat is provided with a second thread matched with the first thread, the end part of the second thread is connected with a second locking part matched with the first locking part, the second locking part is a second clamping opening formed in one end of the second thread, and the first clamping block can be clamped in the second clamping opening.

Through adopting above-mentioned technical scheme, take the second hasp portion on the mechanism mutually supporting through first hasp portion on the container and ration, realized that container and ration take the mutual locking of mechanism, it is not hard up after avoiding connecting.

In some embodiments, the mounting seat is a cylindrical structure with openings at two ends, the distribution portion is installed inside the mounting seat, the distribution portion includes a plurality of partition sheets connected to the inner wall of the mounting seat, and the partition sheets are uniformly distributed with the axis of the mounting seat as a center to divide the inner cavity of the mounting seat into a plurality of sector quantitative cells with equal volumes in the circumferential direction.

In some embodiments, the distribution portion further includes a first material separating plate and a second material separating plate respectively installed on two sides of the quantitative cell, the first material separating plate and the second material separating plate are connected to the axial center of the installation seat, the first material separating plate is provided with a first material through port, the second material separating plate is provided with a second material through port, and the second material through port and the first material through port do not overlap in the axial direction of the installation seat.

Through adopting above-mentioned technical scheme, on the one hand, the second separates the charging tray and can regard as the bottom plate of ration check room to ration check room is used for the ration to keep in the material, and the second separates the second feed opening on the charging tray and is used for following the indoor ejection of compact of ration check, and the first feed opening that separates the charging tray is used for the indoor feeding of ration check, the second feed opening with thereby the first feed opening is misaligned in mount pad axial direction guarantees that same ration check room does not have the circumstances of feeding simultaneously, ejection of compact, thereby ensures that the load of following the second feed opening is the capacity of a ration check room promptly, several realization ridge roof beams get the effect of material.

In some embodiments, the first material passing opening is arranged corresponding to at least one of the quantitative cell chambers, and the opening area of the first material passing opening is not smaller than the opening area of a single quantitative cell chamber, while the first material separating disc completely covers at least one quantitative cell chamber.

By adopting the technical scheme, the opening area of the first material passing hole is not smaller than that of a single quantitative grid chamber, so that the materials in the dough container fall into the quantitative grid chambers and the quantitative grid chambers are filled with the materials as far as possible; the volume of the material passing through the second feed opening at a time is the volume of the quantitative cell, so that the quantitative material taking purpose is achieved.

In some embodiments, the second opening is disposed corresponding to a single dosing cell, and the second opening has the same shape as the opening of the single dosing cell.

Through adopting above-mentioned technical scheme to can make the material in the ration check as far as possible pass through, reduce and remain, improve the degree of accuracy of the volume of getting material.

In some embodiments, a limiting block is arranged on a side surface of the first material separating plate opposite to the quantitative cells, a limiting groove is arranged on the distributing part corresponding to each quantitative cell, and when the limiting block enters any limiting groove, the second material passing opening coincides with an opening of one quantitative cell.

Through adopting above-mentioned technical scheme, when rotating the second and separating the charging tray, the first charging tray that separates rotates along with the second separates the charging tray in step, and when the stopper got into arbitrary spacing inslot, realized screens once to make screens can pass through the material volume the same with a ration check room volume from the second feed opening at every turn.

In some embodiments, the limiting block is in a right trapezoid shape, a trapezoid inclined plane is adjacent to the first material separating disc, and the limiting groove is in the same shape as the limiting block.

Through adopting above-mentioned technical scheme, the stopper becomes right trapezoid, and trapezoidal inclined plane and the adjacent setting of first material tray that separates, and spacing groove is unanimous with spacing block shape to guarantee that the second separates the material tray and can only rotate to a direction, and the reinforcing is rotating feeling of in-process, increase the perception to the screens.

In some embodiments, the distribution portion includes an annular fixing portion attached to the inner wall of the mounting seat, one side of the separation sheet is connected to the inner wall of the annular fixing portion, the other side of the separation sheet is connected to the outer wall of a mounting cylinder, the mounting cylinder is located at the axial center of the mounting seat, and two ends of the mounting cylinder are arranged in a penetrating manner.

In some embodiments, the retaining groove is located on the annular retainer portion.

In some embodiments, the end face of the mounting cylinder is provided with an annular insertion part, the first material separating disc and the second material separating disc are respectively provided with an annular insertion groove matched with the insertion part, or the end surface of the mounting cylinder is provided with an annular insertion groove, the first material separating disc and the second material separating disc are respectively provided with an annular insertion part matched with the insertion groove, or the end face of one end of the mounting cylinder is provided with an annular insertion part, the end face of the other end is provided with an annular insertion groove, the first material separating disc is provided with an inserting groove corresponding to the inserting part, the second material separating disc is provided with an inserting part corresponding to the inserting groove, or the end face of one end of the mounting cylinder is provided with an annular insertion part, the end face of the other end is provided with an annular insertion groove, the first material separating disc is provided with an inserting part corresponding to the inserting groove, and the second material separating disc is provided with an inserting groove corresponding to the inserting part.

Through adopting above-mentioned technical scheme, realized that the first separates the charging tray, the second separates the preliminary connection of charging tray and distribution portion.

In some embodiments, a first rotating shaft is arranged on one side of the first material separating disc, a second rotating shaft is arranged on one side of the second material separating disc, the first rotating shaft and the second rotating shaft are embedded in the installation cylinder and are connected with the installation cylinder in a rotating mode, the first rotating shaft is connected with the second rotating shaft in an embedded mode, and the first material separating disc and the second material separating disc rotate synchronously.

Through adopting above-mentioned technical scheme, realized that the first separates the synchronous rotation of charging tray, second separate the charging tray.

In some embodiments, a plurality of first insertion ports are formed in one end, away from the first material separating disc, of the first rotating shaft, a first insertion column matched with the first insertion ports is arranged at one end, away from the second material separating disc, of the second rotating shaft, and/or a plurality of second insertion columns are arranged at one end, away from the first material separating disc, of the first rotating shaft, and a second insertion port matched with the second insertion column is formed in one end, away from the second material separating disc, of the second rotating shaft.

In some embodiments, the first rotating shaft and the second rotating shaft are arranged in a hollow manner; first pivot inside is equipped with along the first joint post of first pivot axial setting, second pivot inside be equipped with the first joint ring of first joint post complex, and/or the inside second joint post that sets up along second pivot axial that is equipped with of second pivot, first pivot inside locate with second joint post complex second joint ring.

Through adopting above-mentioned technical scheme, realized that the first separates the charging tray, the second separates the further fixed of charging tray.

In some embodiments, a broken bridge rod is arranged on one side, away from the quantitative cell, of the first material separating disc, the broken bridge rod is arranged along the radial direction of the mounting seat, the length of the broken bridge rod is not smaller than the length of the inner diameter of the mounting seat, the broken bridge rod is fixedly arranged relative to the mounting seat, and the upper surface of the first material separating disc can be attached to the broken bridge rod when the first material separating disc rotates.

Through adopting above-mentioned technical scheme, broken bridge pole on the one hand is used for striking off the material of its upper surface when first separate charging tray rotates, ensures that the material can get into quantitative check room, and is full of quantitative check room, and on the other hand can break because of the mutual adhesion of tension effect between the material, and the material of being convenient for falls into quantitative check indoor, improves the degree of accuracy of getting the volume.

In some embodiments, the inner wall of the mounting seat is provided with a mounting groove for mounting a bridge breaking rod, and the bridge breaking rod is mounted in the mounting groove and fixedly arranged with the mounting seat.

Through adopting above-mentioned technical scheme, it is relative to have realized broken bridge pole the mount pad is fixed to be set up.

In some embodiments, a through hole leading into the first rotating shaft penetrates through the first material separating disc, an insertion shaft perpendicular to the bridge breaking rod is connected to the end of the bridge breaking rod, the insertion shaft is installed in the through hole, an expanded diameter portion is arranged at the end of the insertion shaft, and the outer diameter of the expanded diameter portion is larger than that of the through hole.

Through adopting above-mentioned technical scheme, realized broken bridge pole and the relative rotation of first separating the charging tray and be connected.

In some embodiments, a material guiding portion is arranged on one side of the mounting seat, the material guiding portion is arranged on one side of the mounting seat, where the second material separating disc is arranged, and the material guiding portion is funnel-shaped.

Through adopting above-mentioned technical scheme, have the guide effect to the material of output through guide portion.

In some embodiments, the end with the larger caliber of the material guiding part is rotatably connected with the mounting seat, a plurality of clamping parts are distributed on the inner wall of the end with the larger caliber of the material guiding part, and the second material separating disc is provided with a positioning opening for the clamping parts to be inserted.

Through adopting above-mentioned technical scheme, realized that first separates the synchronous rotation of charging tray, second separate the charging tray when rotating guide portion.

In some embodiments, the outer edge of the larger diameter end of the material guiding portion is provided with a table mouth reducing the diameter of the material guiding portion to the center of the material guiding portion, the inner edge of the end of the mounting seat abutting against the material guiding portion is provided with a fitting mouth expanding the diameter of the mounting seat to the periphery, and the table mouth is fitted into the fitting mouth.

Through adopting above-mentioned technical scheme, form seal structure between guide portion and mount pad, prevent that the material from leaking from both seams.

In a third aspect, the present application provides a powder storage device with a quantitative taking mechanism, which adopts the following technical scheme:

powder storage device with a dosing mechanism comprising a container according to claim or said, and a dosing mechanism according to claim.

In some embodiments, the container further comprises a cover body, wherein the cover body is arranged at one end of the mounting seat far away from the container and is connected with the mounting seat.

In some embodiments, the container further comprises a cover body, wherein the cover body is arranged at one end of the mounting seat far away from the container and is connected with the mounting seat.

In some embodiments, a plurality of support points are symmetrically distributed on the center of the inner wall of the cover body, a gap is formed between every two adjacent support points, and the support points are abutted to the outer wall of the material guiding portion when the cover body is mounted on the mounting seat.

In some embodiments, an insertion ring capable of being inserted into the material guiding portion is disposed on an inner wall of the cover, and the insertion ring abuts against the inner wall of the material guiding portion when the cover is mounted on the mounting seat.

Drawings

Fig. 1 is a schematic view of a connection structure between a container and a quantitative taking mechanism according to a first embodiment of the present application;

FIG. 2 is a schematic view of a connection structure between a container and a quantitative taking mechanism according to a second embodiment of the present application;

FIG. 3 is a schematic view of a dosing cell in the dosing mechanism provided herein;

FIG. 4 is a schematic view of the internal cross-sectional structure of the quantitative take mechanism provided herein;

FIG. 5 is an enlarged view of portion A of FIG. 4;

FIG. 6 is a schematic structural view of the first material separating tray and the second material separating tray separated from each other in the present application;

FIG. 7 is a schematic structural view of a first material separating tray and a second material separating tray when the first material separating tray and the second material separating tray are connected in the application;

FIG. 8 is an exploded view of the quantitative take mechanism provided herein;

fig. 9 is a schematic structural view of a quantitative taking mechanism provided herein;

fig. 10 is a schematic structural view of the quantitative taking mechanism provided by the present application when the material guiding portion is not installed;

FIG. 11 is a schematic view of the internal cross-sectional structure of the quantitative dispensing mechanism and the cover after installation;

FIG. 12 is an enlarged view of portion B of FIG. 4;

FIG. 13 is a schematic diagram of a powder storage device with a quantitative take off mechanism according to the present application;

fig. 14 is a schematic mechanism diagram of the material guiding portion and the cover body according to the present application.

Description of reference numerals: 1. a tank body; 11. a first thread; 1111. a first card interface; 1112. a first clamping block;

2. a mounting seat; 21. a second thread; 2111. a second clamping block; 2112. a second card interface; 2120. a first interface; 2220. a first plug-in column; 2123. a first clamp post; 2223. a first snap ring; 22. mounting grooves;

3. a distribution section; 31. a separator; 32. a dosing cell; 321. a first material separating disc; 3211. a first material through opening; 322. a second material separating disc; 3221. a second feed opening; 3210. a limiting block; 301. a limiting groove; 30. a fixed part; 33. mounting the cylinder; 331. a plug-in part; 3310. inserting grooves; 3212. a first rotating shaft; 3222. a second rotating shaft;

4. breaking a bridge rod; 41. a plug shaft; 411. an expanding portion;

5. a material guide part; 51. a clamping part; 52. positioning the opening; 53. a table mouth; 54. an embedding opening;

6. a cover body; 61. a support point; 62. and (4) inserting and connecting a ring.

Detailed Description

The present application is described in further detail below with reference to the attached drawings.

As shown in fig. 1 and 2, the embodiment of the present application discloses a container.

Example 1

As shown in fig. 1, the container disclosed in embodiment 1 of the present application includes a container body 1 with an open end, the container body 1 is in a cone shape, such as a cone shape, and the caliber of the open end is greater than that of the bottom end, thereby facilitating the nesting of the container bodies 1, increasing the transportation volume of the same volume, and reducing the transportation cost. Jar body 1 open end is equipped with first screw thread 11, and first screw thread 11 is kept away from 1 open-ended one end of jar body and is connected with first latch portion, and in this embodiment of this application, first latch portion is for offering in first screw thread 11 and keep away from the first joint interface 1111 of 1 open-ended one end of jar body.

Example 2

As shown in fig. 2, the structure of the container disclosed in embodiment 2 of the present application is substantially the same as that of embodiment 1, except that in this embodiment of the present application, the first locking portion is a first engaging block 1112 whose end is connected to the end of the first thread 11 far from the opening of the can body 1, and the first engaging block 1112 is arranged to intersect with the first thread 11.

As shown in fig. 1-12, the present application further discloses a quantitative dispensing mechanism adapted to the container, mounted to the open end of the container, and threadably engaged with the container.

Example 1

As shown in fig. 1, the quantitative taking mechanism disclosed in embodiment 1 of the present application includes a mounting seat 2 and a distribution portion 3 installed on the mounting seat 2, the mounting seat 2 is in a cylindrical structure, for example, a cylinder with openings at both ends, a second thread 21 matched with the first thread 11 is arranged at one end of the mounting seat 2, the end of the second thread 21 is connected with a second locking portion matched with the first locking portion, the second locking portion is a second locking block 2111 connected with the second thread 21 at the end, and the second locking block 2111 and the second thread 21 are arranged in a cross manner, for example, perpendicular to the second thread 21, the second locking block 2111 can be locked in the first locking port 1111 of the container disclosed in embodiment 1. Through the mutual cooperation of the first lock catch part on the container and the second lock catch part on the quantitative taking mechanism, the mutual locking of the container and the quantitative taking mechanism is realized, and the looseness after connection is avoided.

As shown in fig. 3, the distributing portion 3 is installed inside the mounting base 2, and includes an annular fixing portion 30 attached to an inner wall of the mounting base 2 and a plurality of separating plates 31 connected to the annular fixing portion 30, the annular fixing portion 30 is coaxially disposed with the mounting base 2, the plurality of separating plates 31 are radially disposed along the annular fixing portion 30, one side of each separating plate 31 is connected to the inner wall of the annular fixing portion 30, the other side of each separating plate 31 is connected to an outer wall of a mounting cylinder 33 located at an axial center of the annular fixing portion 30, and the separating plates 31 are uniformly distributed around the axial center of the annular fixing portion 30 to divide an inner cavity of the mounting base 2 into a plurality of fan-shaped quantitative cells 32 with equal.

As shown in fig. 4 and 5, the distributing part 3 further includes a first material separating disc 321 and a second material separating disc 322 respectively installed at two sides of the annular fixing part 30, an annular inserting part 331 is installed at an end surface of the installation cylinder 33, annular inserting grooves 3310 matched with the inserting part 331 are respectively installed on the first material separating disc 321 and the second material separating disc 322, thereby realizing the initial installation of the first material separating disc 321 and the second material separating disc 322, of course, an annular inserting groove 3310 is installed at an end surface of the installation cylinder 33, an annular inserting part 331 matched with the inserting groove 3310 is respectively installed on the first material separating disc 321 and the second material separating disc 322, or an annular inserting part 331 is installed at an end surface of one end of the installation cylinder 33, an annular inserting groove 3310 is installed at an end surface of the other end, an inserting groove 3310 corresponding to the inserting part 331 is installed on the first material separating disc 321, an inserting part 331 corresponding to the inserting groove 3310 is installed on the second material separating disc 322, or an annular inserting part 331 is installed at, the other end face is provided with an annular inserting groove 3310, the first material separating plate 321 is provided with an inserting part 331 corresponding to the inserting groove 3310, the second material separating plate 322 is provided with an inserting groove 3310 corresponding to the inserting part 331, and the primary installation of the first material separating plate 321 and the second material separating plate 322 can be realized by the above structure.

As shown in fig. 5, two ends of the mounting cylinder 33 are arranged in a penetrating manner, as shown in fig. 5 and 6, a first rotating shaft 3212 is arranged on one side of the first material separating disc 321, a second rotating shaft 3222 is arranged on one side of the second material separating disc 322, the first rotating shaft 3212 and the second rotating shaft 3222 are both embedded in the mounting cylinder 33 and rotatably connected with the mounting cylinder 33, as shown in fig. 6 and 7, one end of the first rotating shaft 3212, which is far away from the first material separating disc 321, is provided with a plurality of first inserting ports 2120, one end of the second rotating shaft 3222, which is far away from the second material separating disc 322, is provided with a first inserting column 2220 matched with the first inserting ports 2120, so that the first rotating shaft 3212 is embedded in the second rotating shaft 3222, and then the first material separating disc 321 and the second material separating disc 322 rotate synchronously. Of course, in other embodiments of the present application, a plurality of second inserting columns may be disposed at an end of the first rotating shaft 3212 away from the first material separating tray 321, and a second inserting port matched with the second inserting columns may be disposed at an end of the second rotating shaft 3222 away from the second material separating tray 322.

As shown in fig. 5, the first rotating shaft 3212 and the second rotating shaft 3222 are both hollow; inside being equipped with of first pivot 3212 along the first joint post 2123 of first pivot 3212 axial setting, inside being equipped with of second pivot 3222 with first joint post 2123 complex first joint ring 2223, through the mutually supporting joint of first joint post 2123 with first joint ring 2223, realized that first separating charging tray 321 separates charging tray 322 along the ascending joint of installation section of thick bamboo 33 axial with the second, avoid first separating charging tray 321 and second to separate each other of charging tray 322 and drop. Of course, in other embodiments of the present application, a second snapping column disposed along the axial direction of the second rotating shaft 3222 may be disposed inside the second rotating shaft 3222, and a second snapping ring engaged with the second snapping column may be disposed inside the first rotating shaft 3212.

As shown in fig. 7 and 8, the first material separating tray 321 is provided with a first material passing port 3211, the second material separating tray 322 is provided with a second material passing port 3221, and the second material passing port 3221 and the first material passing port 3211 do not overlap in the axial direction of the mounting base 2. As shown in fig. 9, the first material passing opening 3211 is disposed corresponding to at least one of the quantitative cells 32, and the opening area of the first material passing opening 3211 is not smaller than the opening area of a single quantitative cell 32, while the first material separating tray 321 completely covers at least one of the quantitative cells 32. As shown in fig. 10, the second material opening 3221 is provided corresponding to the single quantitative compartment 32, and the shape of the second material opening 3221 is the same as the opening shape of the single quantitative compartment 32.

Therefore, after the quantitative powder taking mechanism is installed at the open end of the container, the container is inverted, the material in the container falls into the quantitative cell 32 through the first through hole 3211, because the second through hole 3221 and the first through hole 3211 do not coincide in the axial direction of the installation base 2, the material is supported by the second separation tray 322, and when the second separation tray 322 is rotated until the second through hole 3221 coincides with the open end of the quantitative cell 32, the material in the corresponding quantitative cell 32 passes through the second through hole 3221. The first material passing opening 3211 is at least arranged corresponding to one quantitative compartment 32, and the opening area of the first material passing opening 3211 is not smaller than that of a single quantitative compartment 32, so that the material in the dough container falls into the quantitative compartment 32, and the quantitative compartment 32 is filled with the material as much as possible; the second material through opening 3221 and the first material through opening 3211 are arranged to be misaligned in the axial direction of the mounting seat 2, so that the material taking amount can be well controlled, and the volume of the material passing through the second material through opening 3221 at a time is the volume of the quantitative cell 32, so as to achieve the purpose of quantitative material taking; the shape of the second material passing port 3221 is the same as the shape of the opening of the single quantitative cell 32, so that the material in the quantitative cell 32 can pass through as much as possible, the residue is reduced, and the accuracy of the material taking amount is improved. In the process of rotating the second material separating disc 322 to take the material, the first material separating disc 321 rotates synchronously with the second material separating disc 322, so that the material is fed into the quantitative cell 32 synchronously while being discharged.

As shown in fig. 8, a limiting block 3210 is disposed on a side surface of the first material separating plate 321 opposite to the quantitative cells 32, a limiting groove 301 is disposed on the distributing portion 3 corresponding to each quantitative cell 32, the limiting groove 301 is located on the fixing portion 30, and when the limiting block 3210 enters any limiting groove 301, the second material passing opening 3221 coincides with an opening of one quantitative cell 32. Therefore, when the second material separating disc 322 is rotated, the first material separating disc 321 rotates synchronously with the second material separating disc 322, and when the limiting block 3210 enters any limiting groove 301, one-time blocking is realized, so that each-time blocking can pass through the material volume equal to the volume of one quantitative cell 32 from the second material passing opening 3221. The limiting block 3210 is in a right trapezoid shape, the trapezoid inclined plane is adjacent to the first material separating disc 321, and the limiting groove 301 is in the same shape as the limiting block 3210, so that the second material separating disc 322 can only rotate in one direction, hand feeling in the rotating process is enhanced, and sensing of clamping is increased.

As shown in fig. 9, the first bridge breaking rod 4 is installed on the side of the material separating disc 321 departing from the quantitative cell 32, the bridge breaking rod 4 is radially arranged along the mounting seat 2, the length of the bridge breaking rod is not less than the inner diameter of the mounting seat 2, the bridge breaking rod 4 is fixedly arranged relative to the mounting seat 2, and the upper surface of the first bridge breaking rod 4 can be attached to the bridge breaking rod 4 when the material separating disc 321 rotates. The inner wall of the mounting seat 2 is provided with a mounting groove 22 for mounting the broken bridge rod 4, and the broken bridge rod 4 is mounted in the mounting groove 22 and fixedly arranged with the mounting seat 2. As shown in fig. 11, a through hole passing through the first material separating disc 321 into the first rotating shaft 3212 penetrates through the first material separating disc, the end of the bridge breaking rod 4 is connected with an insertion shaft 41 perpendicular to the bridge breaking rod 4, the insertion shaft 41 is installed in the through hole, an end of the insertion shaft 41 is provided with an expanded diameter portion 411, and the outer diameter of the expanded diameter portion 411 is larger than that of the through hole. Broken bridge rod 4 is used for scraping off the material of its upper surface when first separate charging tray 321 rotates on the one hand, ensures that the material can get into quantitative check room 32, and is full of quantitative check room 32, and on the other hand can break because of the mutual adhesion of tension effect between the material, and the material of being convenient for falls into quantitative check room 32 in, improves the degree of accuracy of getting the volume.

As shown in fig. 8, one side of the mounting seat 2 is provided with a material guiding portion 5, the material guiding portion 5 is installed on one side of the mounting seat 2 where the second material separating plate 322 is arranged, the material guiding portion 5 is funnel-shaped, one end with a large caliber of the material guiding portion 5 is rotatably clamped with the mounting seat 2, a plurality of clamping portions 51 are distributed on the inner wall of one end with a large caliber of the material guiding portion 5, and the second material separating plate 322 is provided with a positioning port 52 for the clamping portions 51 to be inserted. Therefore, the rotating material guiding portion 5 can drive the second material separating tray 322 to rotate synchronously, so that the first material separating tray 321 rotates synchronously.

As shown in fig. 12, the outer edge of the larger diameter end of the material guiding part 5 is provided with a table mouth 53 which reduces the diameter of the material guiding part 5 toward the center thereof, the inner edge of the end of the mounting seat 2 abutting against the material guiding part 5 is provided with a fitting mouth 54 which expands the diameter of the mounting seat 2 toward the outer periphery thereof, and the table mouth 53 is fitted into the fitting mouth 54, so that a sealing structure is formed between the material guiding part 5 and the mounting seat 2, and the leakage of the material from the joint between the two is prevented.

The working principle is as follows: the material guiding part 5 is rotated to drive the whole of the first material separating disc 321 and the second material separating disc 322 to synchronously rotate along with the material guiding part 5, and then the first material separating disc 321 and the second material separating disc 322 rotate relative to the quantifying cell 32, because of the action of the limiting block 3210 on the first material separating disc 321 and the limiting groove 301 on the distributing part 3, the rotation of the material guiding part 5, the first material separating disc 321 and the second material separating disc 322 is step-wise rotated, namely under the action of the limiting block 3210 and the limiting groove 301, each time of rotation only rotates a fixed angle which is equal to the central angle of the quantifying cell 32, therefore, one rotation makes the first material through opening 3211 on the first material separating disc 321 align with one quantifying cell 32, so that each rotation feeds the materials into the quantifying cell 32, and at the same time, each corresponding rotation discharges the materials from the quantifying cell 32. Because the volume of each quantitative cell 32 is equal, and the first material passing opening 3211 and the second material passing opening 3221 are staggered, the volume of the material discharged each time is equal to the volume of one quantitative cell 32, and the quantitative discharging effect is achieved.

Example 2

As shown in fig. 2, the structure of the quantitative taking mechanism disclosed in embodiment 2 of the present application is substantially the same as that of embodiment 1, and the difference is that the second locking portion is a second locking interface 2112 provided at the outer end of the second thread 21, and the first locking block 1112 of the container disclosed in embodiment 2 can be inserted into the second locking interface 2112.

The embodiment also discloses a powder storage device with a quantitative taking mechanism, as shown in fig. 13, the powder storage device comprises the container of any embodiment and the quantitative taking mechanism of any embodiment, and further comprises a cover body 6, wherein the cover body 6 is installed at one end, far away from the container, of the installation base 2 and is in threaded connection with the installation base 2.

As shown in fig. 11 and 14, a plurality of support points 61 are symmetrically distributed on the inner wall of the cover 6, a gap is formed between adjacent support points 61, and the support points 61 abut against the outer wall of the material guiding portion 5 when the cover 6 is mounted on the mounting base 2, so that the balance of the cover 6 relative to the mounting base 2 can be provided when the cover 6 is covered, the cover 6 can be mounted conveniently, and the cover 6 can be prevented from being inclined. The inner wall of the cover body 6 is provided with an inserting ring 62 which can be inserted into the material guiding part 5, when the cover body 6 is arranged on the mounting seat 2, the inserting ring 62 is abutted against the inner wall of the material guiding part 5, so that the closure between the cover body and the material guiding part 5 is improved, the material is prevented from being spilled, and the retaining device is clean.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (30)

1. The container, for one side open-ended jar body (1), jar body (1) open end is equipped with first screw thread (11), its characterized in that, the open-ended one end of jar body (1) is kept away from in first screw thread (11) is connected with first locking part.

2. A container according to claim 1, characterized in that the first locking part is a first snap-in interface (1111) opened at one end of the first thread (11) far from the opening of the can body (1).

3. The container according to claim 1, wherein the first locking portion is a first clamping block (1112) which is connected to the end of the first thread (11) far away from the opening of the container body (1), and the first clamping block (1112) is arranged to intersect with the first thread (11).

4. A container according to claim 2 or 3, wherein the inner cavity of the can body (1) is tapered, and the caliber of the open end is larger than that of the bottom end.

5. Mechanism is taken to ration, its characterized in that includes mount pad (2) and installs in distribution portion (3) of mount pad (2), the opening part of container of claim 2 is installed to mount pad (2), mount pad (2) be equipped with first screw thread (11) complex second screw thread (21), second screw thread (21) end connection have with first hasp portion complex second hasp portion, second hasp portion be end connection in second joint piece (2111) of second screw thread (21), just second joint piece (2111) with second screw thread (21) cross arrangement, second joint piece (2111) can inlay card in first joint mouth (1111).

6. Mechanism is taken to ration, its characterized in that includes mount pad (2) and installs in distribution portion (3) of mount pad (2), the opening part of container of claim 3 is installed in mount pad (2), mount pad (2) be equipped with first screw thread (11) complex second screw thread (21), second screw thread (21) end connection have with first hasp portion complex second hasp portion, second hasp portion for offering in second screw thread (21) one end second joint mouth (2112), first joint piece (1112) can inlay card in second joint mouth (2112).

7. The quantitative taking mechanism according to claim 5 or 6, wherein the mounting seat (2) is of a cylindrical structure with two open ends, the distribution part (3) is mounted inside the mounting seat (2), the distribution part (3) comprises a plurality of separation sheets (31) connected to the inner wall of the mounting seat (2), and the separation sheets (31) are uniformly distributed by taking the axis of the mounting seat (2) as a center and divide the inner cavity of the mounting seat (2) into a plurality of fan-shaped quantitative cells (32) with equal volumes in the circumferential direction.

8. The quantitative taking mechanism according to claim 7, wherein the dispensing part (3) further comprises a first material separating plate (321) and a second material separating plate (322) respectively installed at two sides of the quantitative cell (32), the first material separating plate (321) is connected with the second material separating plate (322) at the axial center of the mounting seat (2), a first material passing opening (3211) is formed in the first material separating plate (321), a second material passing opening (3221) is formed in the second material separating plate (322), and the second material passing opening (3221) and the first material passing opening (3211) do not overlap in the axial direction of the mounting seat (2).

9. The quantitative taking mechanism according to claim 8, wherein the first material passing opening (3211) is provided corresponding to at least one of the quantitative cells (32), and an opening area of the first material passing opening (3211) is not smaller than an opening area of a single quantitative cell (32), while the first material separating tray (321) completely covers at least one of the quantitative cells (32).

10. The quantitative taking mechanism according to claim 9, wherein the second material opening (3221) is provided corresponding to a single quantitative cell (32), and the shape of the second material opening (3221) is the same as the shape of the opening of the single quantitative cell (32).

11. The quantitative taking mechanism according to claim 10, wherein a limiting block (3210) is disposed on a side surface of the first material separating plate (321) opposite to the quantitative cells (32), a limiting groove (301) is disposed on the distributing portion (3) corresponding to each quantitative cell (32), and when the limiting block (3210) enters any one of the limiting grooves (301), the second material passing opening (3221) coincides with an opening of one of the quantitative cells (32).

12. The quantitative taking mechanism according to claim 11, wherein the limiting block (3210) is in a right trapezoid shape, the inclined plane of the trapezoid is disposed adjacent to the first material separating disc (321), and the limiting groove (301) is in accordance with the limiting block (3210).

13. The quantitative taking mechanism according to claim 11, wherein the distribution portion (3) comprises an annular fixing portion (30) attached to an inner wall of the mounting seat (2), one side of the partition plate (31) is connected to the inner wall of the annular fixing portion (30), the other side of the partition plate is connected to an outer wall of a mounting cylinder (33), the mounting cylinder (33) is located at an axial center of the mounting seat (2), and two ends of the mounting cylinder (33) are arranged in a penetrating manner.

14. The quantitative taking mechanism according to claim 13, wherein the limiting groove (301) is located on the annular fixing portion (30).

15. The quantitative taking mechanism according to claim 13, wherein the end face of the mounting cylinder (33) is provided with an annular insertion portion (331), the first material separating disc (321) and the second material separating disc (322) are respectively provided with an annular insertion groove (3310) matched with the insertion portion (331), or the end face of the mounting cylinder (33) is provided with an annular insertion groove (3310), the first material separating disc (321) and the second material separating disc (322) are respectively provided with an annular insertion portion (331) matched with the insertion groove (3310), or one end face of the mounting cylinder (33) is provided with an annular insertion portion (331), the other end face is provided with an annular insertion groove (3310), the first material separating disc (321) is provided with an insertion groove (3310) corresponding to the insertion portion (331), the second material separating disc (322) is provided with an insertion portion (331) corresponding to the insertion groove (3310), or an annular inserting part (331) is arranged on the end face of one end of the installation barrel (33), an annular inserting groove (3310) is arranged on the end face of the other end of the installation barrel, an inserting part (331) corresponding to the inserting groove (3310) is arranged on the first material separating plate (321), and an inserting groove (3310) corresponding to the inserting part (331) is arranged on the second material separating plate (322).

16. The quantitative taking mechanism according to claim 13, wherein a first rotating shaft (3212) is disposed on one side of the first material separating tray (321), a second rotating shaft (3222) is disposed on one side of the second material separating tray (322), the first rotating shaft (3212) and the second rotating shaft (3222) are both embedded in the mounting cylinder (33) and rotatably connected with the mounting cylinder (33), the first rotating shaft (3212) is embedded in the second rotating shaft (3222) and the first material separating tray (321) and the second material separating tray (322) rotate synchronously.

17. The quantitative taking mechanism of claim 16, wherein a plurality of first insertion ports (2120) are formed in one end of the first rotating shaft (3212) away from the first material separating tray (321), a plurality of first insertion posts (2220) engaged with the first insertion ports (2120) are formed in one end of the second rotating shaft (3222) away from the second material separating tray (322), and/or a plurality of second insertion posts are formed in one end of the first rotating shaft (3212) away from the first material separating tray (321), and a second insertion port engaged with the second insertion posts is formed in one end of the second rotating shaft (3222) away from the second material separating tray (322).

18. The quantitative access mechanism of claim 17, wherein the first spindle (3212) and the second spindle (3222) are hollow; first pivot (3212) inside be equipped with along first pivot (3212) axial setting first joint post (2123), second pivot (3222) inside be equipped with first joint post (2123) complex first joint ring (2223), and/or second pivot (3222) inside be equipped with along second pivot (3222) axial setting second joint post, first pivot (3212) inside locate with second joint post complex second joint ring.

19. The quantitative taking mechanism according to claim 16, wherein a bridge breaking rod (4) is arranged on one side of the first material separating disc (321) away from the quantitative cell (32), the bridge breaking rod (4) is radially arranged along the mounting seat (2) and is not smaller than the length of the inner diameter of the mounting seat (2), the bridge breaking rod (4) is fixedly arranged relative to the mounting seat (2), and the upper surface of the first material separating disc (321) can be attached to the bridge breaking rod (4) when rotating.

20. The quantitative taking mechanism according to claim 19, wherein the inner wall of the mounting seat (2) is provided with a mounting groove (22) for mounting a bridge breaking rod (4), and the bridge breaking rod (4) is mounted in the mounting groove (22) and is fixedly arranged with the mounting seat (2).

21. The quantitative taking mechanism according to claim 19, wherein the first material separating disc (321) has a through hole penetrating into the first rotating shaft (3212), the end of the bridge breaking rod (4) is connected with an insertion shaft (41) perpendicular to the bridge breaking rod (4), the insertion shaft (41) is installed in the through hole, the end of the insertion shaft (41) is provided with an expanded diameter part (411), and the outer diameter of the expanded diameter part (411) is larger than the outer diameter of the through hole.

22. The quantitative taking mechanism according to claim 11, wherein a material guiding portion (5) is disposed on one side of the mounting seat (2), the material guiding portion (5) is mounted on one side of the mounting seat (2) where the second material separating tray (322) is disposed, and the material guiding portion (5) is funnel-shaped.

23. The quantitative taking mechanism according to claim 22, wherein the end with a larger caliber of the material guiding portion (5) is rotatably connected with the mounting base (2), a plurality of clamping portions (51) are distributed on the inner wall of the end with a larger caliber of the material guiding portion (5), and the second material separating disc (322) is provided with a positioning opening (52) for the clamping portions (51) to be inserted.

24. The quantitative taking mechanism according to claim 23, wherein a table mouth (53) reducing the diameter of the material guiding portion (5) is provided on an outer edge of one end of the material guiding portion (5) having a larger diameter, an engaging mouth (54) expanding the diameter of the mounting seat (2) toward the outer periphery of the mounting seat (2) is provided on an inner edge of one end of the mounting seat (2) abutting against the material guiding portion (5), and the table mouth (53) is engaged with the engaging mouth (54).

25. Powder storage device with a dosing mechanism, characterized in that it comprises a container according to claim 2 or 3 and a dosing mechanism according to claim 24.

26. Powder storage device with a dosing mechanism, characterized in that it comprises a container according to claim 2 or 3 and a dosing mechanism according to claim 21.

27. The powder storage device with a quantitative taking mechanism according to claim 25, further comprising a cover body (6), wherein the cover body (6) is mounted at one end of the mounting base (2) far away from the container and connected with the mounting base (2).

28. The powder storage device with a quantitative taking mechanism according to claim 26, further comprising a cover body (6), wherein the cover body (6) is mounted at one end of the mounting base (2) far away from the container and connected with the mounting base (2).

29. The powder storage device with a quantitative taking mechanism according to claim 27, wherein a plurality of support points (61) are symmetrically distributed on the inner wall of the cover body (6), a gap is arranged between every two adjacent support points (61), and when the cover body (6) is mounted on the mounting seat (2), the support points (61) are abutted against the outer wall of the material guiding portion (5).

30. The powder storage device with a quantitative taking mechanism according to claim 29, wherein the inner wall of the cover body (6) is provided with an insertion ring (62) capable of being inserted into the material guiding portion (5), and when the cover body (6) is mounted on the mounting seat (2), the insertion ring (62) abuts against the inner wall of the material guiding portion (5).

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