CN220518994U - Bottle capable of quantitatively taking powder granular materials - Google Patents

Abstract

The utility model discloses a bottle capable of quantitatively taking powder granular materials, which comprises a bottle cover and a bottle body, wherein a quantitative material taking device is arranged on the bottle cover, the quantitative material taking device comprises a quantitative storage space, a feeding channel and a discharging channel, the feeding channel comprises a feeding inlet and a feeding outlet, the discharging channel comprises a discharging inlet and a discharging outlet, the feeding outlet and the discharging inlet are opposite, a turning inner baffle is formed between the feeding outlet and the discharging inlet, the turning inner baffle extends upwards, the feeding channel is a funnel-shaped channel, and the feeding inlet of the feeding channel is larger than the feeding outlet. According to the quantitative material taking device, the quantitative material taking device is arranged on the bottle cap, a spoon is not required to be additionally prepared for quantitative material taking, the spoon is not required to be held for operation and cleaning, the sanitation standard is improved, the operation is very convenient and efficient, and quantitative materials can be poured out in a single time.

Description

Bottle capable of quantitatively taking powder granular materials

Technical Field

The utility model relates to the technical field of packaging containers, in particular to a bottle capable of quantitatively taking powder granular materials.

Background

In household commodities, we can find various granular and powdery products, from coffee, sugar and salt to protein powder of health lovers, washing powder and the like. These products are usually kept in containers of the type which require the removal of the granular powder with a spoon or a measuring device, which need to be opened before use and resealed with a metal or plastic cap in a simple manner after use, which are equipped with spoons which are placed directly in the container after use, which are easily moved or shaken during use, which easily cause the spoons to be buried by the powder in the container and which easily cause inconvenience for the user to take the spoons during use.

In order to solve the problems, a spoon is fixed below a bottle cap of the existing bottle, for example, CN203127410U discloses a bottle, a small hook is arranged on the bottle cap to hang the spoon on the small hook, but the spoon is easy to pollute a spoon handle when placed in the bottle, and when the bottle cap is unscrewed under the condition that things in the bottle are sticky, great resistance exists between the spoon and the contents to prevent the bottle cap from unscrewing, and the spoon is inconvenient to take in the bottle; in addition, there is also a bottle cap in which a spoon is folded and put into a bottle cap, for example, CN106882478A discloses a bottle cap with a spoon, and the spoon is sealed in a cavity through a sealing sheet, so that the spoon is prevented from leaking out of the air, but the spoon needs to be taken out of the bottle cap when being used each time, and then folded and put back into the bottle cap after being used up, so that the operation is complicated, and when the spoon is taken, the spoon is inevitably contacted with a hand, and when the spoon is used for contacting with objects in a packaging bottle, dust and bacteria are brought into the bottle, and the objects in the bottle are polluted.

Therefore, in order to solve the above-mentioned problems, it is necessary to design an integrated device for directly taking out the bottle cap quantitatively, so as to reduce pollution.

Disclosure of Invention

The utility model aims at: to the problem that above-mentioned exists, provide one kind and directly take powder or granular material with the bottle lid ration, need not to get with the ladle and get, simple structure, the simple operation for the material in the bottle is difficult for polluting.

The technical scheme of the utility model is as follows:

the utility model relates to a bottle capable of quantitatively taking powder granular materials, which comprises a bottle cover and a bottle body, wherein a quantitative material taking device is arranged on the bottle cover, the quantitative material taking device comprises a quantitative storage space, a feeding channel and a discharging channel, the feeding channel comprises a feeding inlet and a feeding outlet, the discharging channel comprises a discharging inlet and a discharging outlet, the feeding outlet and the discharging inlet are opposite, a turning inner baffle plate is formed between the feeding outlet and the discharging inlet, the turning inner baffle plate extends obliquely upwards, the feeding channel is a funnel-shaped channel, and the feeding inlet of the feeding channel is larger than the feeding outlet.

Further, the feed outlet of the feed channel is smaller than the discharge inlet of the discharge channel.

Above structure, quantitative storing space lower extreme is connected the feed outlet of feed channel and the ejection of compact entry of ejection of compact passageway to the feed outlet of feed channel is less for the ejection of compact entry of ejection of compact passageway, and sets up in quantitative storing space below export leftmost, and this structure makes granule or likepowder granule fill up quantitative storing space, along with piling up between the granule, fills or partly fills quantitative storing space and will produce the blocking effect and prevent granule or likepowder granule's further inflow, and can guarantee that the bottle returns the back, and the material flows into the ejection of compact passageway in most, and only very little part can return in the feed channel.

Further, a feeding inlet of the feeding channel is communicated with the bottom of the bottle cap, and a discharging outlet of the discharging channel is higher than the surface of the side edge of the bottle cap.

Further, the discharging channel is an L-shaped discharging channel.

Above structure, discharge channel's L type structure guarantees that the bottle is just immediately once more after, and the material can be stored in the discharge channel in the bulk flow from ration storing space temporarily, just can pour the material after the certain angle of slope.

Further, the quantitative storage space can be enlarged and reduced according to the required quantity.

Further, the size of the feeding outlet of the feeding channel can be adjusted according to the granularity of the materials, and the larger the particles are, the wider the feeding outlet is, the smaller the particles are, and the narrower the feeding outlet is.

Further, the device also comprises a cover, and the cover is connected with the discharging outlet of the discharging channel.

Further, the cover is one of a screw cover, a hinge cover or a spring cover.

Further, an internal thread is arranged in the bottle cap, an external thread is arranged on the bottle body, and the bottle cap and the bottle body are screwed and connected through the internal thread and the external thread.

In summary, due to the adoption of the technical scheme, the beneficial effects of the utility model are as follows:

1. according to the quantitative material taking device, the quantitative material taking device is arranged on the bottle cap, a spoon is not required to be additionally arranged for taking materials quantitatively, a certain amount of materials can be poured out only by inverting the whole bottle for a period of time and then recovering the bottle to be upright, the spoon is not required to be held by a hand for operation and cleaning after the spoon is used up, the sanitation standard is improved, the structure is simple, the operation is very convenient and efficient, and the quantitative materials can be poured out once.

2. According to the utility model, the feeding channel is arranged as the funnel-shaped channel, and the feeding outlet of the feeding channel is smaller than the discharging inlet of the discharging channel, so that when the bottle is recovered to be upright, a certain amount of materials in the quantitative storage space can flow into the discharging channel, and a part of materials can return to the feeding channel and flow back into the bottle.

3. According to the utility model, the cover and the bottle cap are detachably connected through the threads, so that the variety materials are prevented from being wetted and polluted, the whole device can be conveniently detached for cleaning, and the materials are filled in the bottle again, thereby realizing recycling.

Drawings

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

FIG. 2 is a schematic view of the vertical cross-section of the bottle cap of the present utility model;

FIG. 3 is a schematic view of the structure of the quantitative storage space of the present utility model with different shapes;

FIG. 4 is a schematic view of the transverse cross-section of the bottle cap of the present utility model;

FIG. 5 is a schematic diagram illustrating the operation of the entire process of the present utility model;

FIG. 6 is a schematic illustration of the operation of the present utility model for pouring material into a quantitative take off device;

FIG. 7 is a schematic diagram of the operation of pouring out material according to the present utility model;

reference numerals: 1-bottle cap, 11-quantitative storage space, 12-feeding channel, 121-feeding inlet, 122-feeding outlet, 13-discharging channel, 131-discharging inlet, 132-discharging outlet, 133-external screw thread, 14-internal screw thread, 15-turning internal baffle, 2-bottle body and 3-cover.

Detailed Description

It is noted that relational terms such as "first" and "second", and the like, are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The features and capabilities of the present utility model are described in further detail below in connection with examples.

The embodiment of the utility model discloses a bottle capable of quantitatively taking powder granular materials, which comprises a bottle cap 1 and a bottle body 2, wherein a quantitative material taking device is arranged on the bottle cap 1, the quantitative material taking device comprises a quantitative storage space 11, a feeding channel 12 and a discharging channel 13, the feeding channel 12 comprises a feeding inlet 121 and a feeding outlet 122, the discharging channel 13 comprises a discharging inlet 131 and a discharging outlet 132, the feeding outlet 122 and the discharging inlet 131 are opposite, a turning inner baffle 15 is formed between the feeding outlet 122 and the discharging inlet 131, the turning inner baffle 15 extends obliquely upwards, the feeding channel 12 is a funnel-shaped channel, and the feeding inlet 121 of the feeding channel 12 is larger than the feeding outlet 122.

In this embodiment, by modifying the bottle cap into a device capable of taking out materials quantitatively by itself, by arranging the quantitative storage space 11, the feeding channel 12 and the discharging channel 13 inside, only the whole device is needed to be inverted, the materials flow into the feeding channel 12 through the feeding inlet 121 of the feeding channel 12 and flow into the quantitative storage space 11 through the feeding outlet 122, after the quantitative storage space 11 is filled with the materials, the bottle is restored to an upright state, because the feeding outlet 122 of the feeding channel 12 is smaller than the discharging inlet 131 of the discharging channel 13, and the turning inner baffle formed between the feeding outlet 122 and the discharging inlet 131 extends obliquely upwards towards the feeding outlet 122, a part of the materials are blocked and do not enter the feeding outlet 122, and the arrangement of the two structures enables most of the materials to flow into the discharging channel 13 and then be poured into the receiving container from the discharging outlet 132 by tilting again by a certain angle; by means of the funnel-shaped structure, material is continuously fed into the dosing storage space 11 through the feed channel 12, and when material is poured into the small cavity through a small opening, the granular or powdery particles will fill or partially fill the cavity. With the accumulation between the particles, filling or partially filling the cavity will create a blocking effect and prevent further inflow of particles or powdery particles, which may allow a quantitative flow of material into the quantitative storage space 11.

As a technical optimization of the present utility model, the feed outlet 122 of the feed channel 12 is smaller than the discharge inlet 131 of the discharge channel 13.

In this embodiment, due to the special structure and the positional relationship between the feeding channel 12 and the discharging channel 13, it is ensured that a certain amount of material in the quantitative storage space 11 flows into the discharging channel 13 when the bottle is restored to the upright position, and a part returns to the feeding channel.

As a technical optimization scheme of the utility model, the feeding inlet 121 of the feeding channel 12 is communicated with the bottom of the bottle cap 1, and the discharging outlet 132 of the discharging channel 13 is arranged higher than the surface of the side edge of the bottle cap 1.

In this embodiment, material enters the feed channel 12 from the feed inlet 121 when the bottle is inverted; the discharge outlet 132 of the discharge channel 13 is arranged to facilitate pouring out of the material.

As a technical optimization scheme of the utility model, the discharging channel 13 is an L-shaped discharging channel.

In this embodiment, the discharging channel 13 is L-shaped, after the bottle is placed forward again, the material flows into the discharging channel 13 from the quantitative storage space 11, and at this time, the material is stored in the discharging channel 13, and needs to incline for a certain angle again, so that the material can be poured out from the discharging outlet 132 of the discharging channel 13.

As a technical optimization scheme of the present utility model, the quantitative storage space 11 can be enlarged and reduced according to the required amount.

In this embodiment, the quantitative storage space 11 is adjusted according to the amount of the material that is taken once, and more material is required for one-time taking, so that the quantitative storage space 11 is set to be larger, less material is required for one-time taking, and the quantitative storage space 11 is set to be smaller, so that production is performed according to actual conditions; meanwhile, the shape of the quantitative storage space 11 can be set into a semicircular shape or a square quantitative storage space as shown in fig. 3 according to the requirement.

As a technical optimization scheme of the present utility model, the size of the feeding outlet 122 of the feeding channel 12 can be adjusted according to the granularity of the material, and the larger the particle, the wider the feeding outlet 122, the smaller the particle, and the narrower the feeding outlet 122.

In this embodiment, too, the size of the feed outlet 122 of the feed channel 12 is adjusted according to the particle size of the material placed in the bottle, the particles are larger, the feed outlet 122 is set wider, the particles are smaller, and the feed outlet 122 is set narrower, so that the production is performed according to the actual situation.

As a technical optimization scheme of the utility model, the utility model also comprises a cover 3, wherein the cover 3 is connected with the discharging outlet 132 of the discharging channel 13; the cover 3 is one of a screw cover, a hinge cover or a spring cover.

In this embodiment, the lid is used to open and close the whole device, so that the whole device is not polluted and rewetted when being placed.

As a technical optimization scheme of the utility model, the bottle cap 1 is internally provided with the internal thread 14, the bottle body is provided with the external thread, and the bottle cap 1 and the bottle body 2 are screwed and connected through the internal thread and the external thread.

In this embodiment, the bottle cap 1 and the bottle body 2 are screwed through the internal thread and the external thread, so that after the materials in the bottle are used up, the bottle cap is unscrewed to refill the materials, or the bottle cap is disassembled to be cleaned, and the bottle can be reused.

In the specific operation method of the present utility model, as shown in fig. 5, 6 and 7, when the material is required to be taken, the bottle is inverted and shaken to allow the material in the bottle to flow into the feed channel 12 from the feed inlet 121 of the feed channel 12, flow into the quantitative storage space 11 through the feed outlet 122, and after the quantitative storage space 11 is filled with the material, the bottle is returned to the upright state, at this time, since the feed outlet 122 of the feed channel 12 is smaller than the discharge inlet 131 of the discharge channel 13 and the turning inner baffle 15 extends obliquely upward toward the feed outlet 122, the feed outlet 122 is smaller and positioned at the most corner with respect to the quantitative storage space, a certain amount of the material in the quantitative storage space 11 flows into the discharge channel 13 when the bottle returns to the upright state, a part returns to the feed channel, and then the cap 3 is opened, the discharge outlet 132 is aligned with the receiving container, and the whole bottle is inclined by a certain angle to shake the material which has flowed into the discharge channel 13 into the receiving container.

At the same time, most solid particles do not self-level when poured onto a surface, but rather tend to form a small mound shape. Thus, when poured into a small cavity through a small opening, the granular or powdery particles will fill or partially fill the cavity. As particles accumulate, filling or partially filling the cavity will create a plugging effect and prevent further inflow of particles or powdery particles. When the cavity is inverted, the particles will again fall freely under the force of gravity. With the division of the feed outlet 122 and the discharge inlet 131, a relatively precise amount of particles will fall into the discharge inlet 131 and a portion of the material will fall into the feed outlet 122 back into the bottle.

The foregoing examples merely represent specific embodiments of the present application, which are described in more detail and are not to be construed as limiting the scope of the present application. It should be noted that, for those skilled in the art, several variations and modifications can be made without departing from the technical solution of the present application, which fall within the protection scope of the present application.

Claims (9)

1. The utility model provides a but quantitative bottle of getting powder particulate material, includes bottle lid (1) and body (2), its characterized in that, be provided with quantitative extracting device on bottle lid (1), quantitative extracting device includes quantitative storing space (11), feed channel (12) and ejection of compact passageway (13), feed channel (12) are including feed inlet (121) and feed outlet (122), ejection of compact passageway (13) are including ejection of compact entry (131) and ejection of compact export (132), quantitative storing space (11) below is including feed outlet (122) and ejection of compact entry (131), feed outlet (122) and ejection of compact entry (131) are opposite, form turn internal baffle (15) between, turn internal baffle (15) slant upwards extend, feed channel (12) are funnel-shaped passageway, feed inlet (121) of feed channel (12) are greater than feed outlet (122).

2. A bottle for dosed quantities of powder-like material according to claim 1, characterized in that the feed outlet (122) of the feed channel (12) is smaller than the discharge inlet (131) of the discharge channel (13).

3. A bottle for dosed removal of powdered particulate material as claimed in claim 2, wherein the feed inlet (121) of the feed channel (12) is in communication with the bottom of the cap (1) and the discharge outlet (132) of the discharge channel (13) is arranged above the surface of the side edge of the cap (1).

4. A bottle for dosed quantities of powder-like particulate material as claimed in claim 2, wherein the discharge channel (13) is an L-shaped discharge channel.

5. A bottle for dosed quantities of powder-like particulate material as claimed in claim 1, wherein the dosing storage space (11) is expandable and contractible in accordance with the required quantity.

6. A bottle for dosed quantities of powdery granular material according to claim 2, characterized in that the feed outlet (122) of the feed channel (12) is adjustable in size according to the granularity of the material, the larger the particles, the wider the feed outlet (122) and the smaller the particles, the narrower the feed outlet (122).

7. A bottle for dosed quantities of powder-like particulate material as claimed in claim 1, further comprising a cap (3), the cap (3) being connected to the outlet (132) of the outlet channel (13).

8. A bottle for dosed quantities of powdered particulate material according to claim 7, wherein the cap (3) is one of a screw cap, a hinge cap or a spring cap.

9. The bottle capable of quantitatively taking powder granular materials according to claim 1, wherein the bottle cap (1) is internally provided with an internal thread (14), the bottle body is provided with an external thread, and the bottle cap (1) and the bottle body (2) are connected by screwing through the internal thread and the external thread.