CN114987950A

CN114987950A - Solid quantifying bottle

Info

Publication number: CN114987950A
Application number: CN202210713720.7A
Authority: CN
Inventors: 谢亚杰; 王群群
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-06-22
Filing date: 2022-06-22
Publication date: 2022-09-02

Abstract

The invention relates to a solid quantitative bottle, belonging to the bottle packaging field, which comprises a bottle cap part, a bottle body part and a spiral spring clamped between the bottle cap part and the bottle body part. The lower end of the bottle cap sleeve can swallow the spherical particles and store the spherical particles in the bottle cap sleeve. The bottom of the bottle body part is provided with a spiral revolution curved surface, the spherical particles spirally move downwards along the curved surface, the center of the spiral revolution curved surface is provided with a bottle body sleeve, the bottle body sleeve is sleeved outside the bottle cap sleeve, an inlet is arranged below the bottle body sleeve, the spherical particles roll along the spiral revolution curved surface and enter the bottle body sleeve through the inlet, the bottle cap is pressed every time, the bottle cap sleeve can move downwards to swallow the spherical particles and store the spherical particles in the bottle body sleeve, and after the bottle is turned, the spherical particles in the bottle cap sleeve can fall out from the outlet of the bottle cap. Therefore, each time the bottle cap is pressed, the quantitative spherical particles are finally poured out, and the function of quantitative fetching is realized.

Description

Solid quantifying bottle

Technical Field

The invention relates to a bottle for packaging commodities in solid particle form, in particular to a bottle capable of taking out a fixed amount of solid particles each time.

Background

The conventional packaging form of bottles is adopted for products such as candies, pills and the like which are produced in the form of solid particles. The bottle is convenient in filling, storing, taking out solid particles and the like. When the solid particles are taken out of the bottle, the quantity of the solid particles taken out is random, people often need to invert the bottle on hands or other articles (such as bottle caps), determine the quantity of the solid particles and put the solid particles into mouths for taking, and during the operation, the solid particles contact hands or other articles, so that bacteria are carried on the solid particles. This way of administering is on the one hand unsanitary and on the other hand the whole process is carried out with two hands cooperating, so that administering the solid particles becomes difficult or even impossible with one hand for disabled persons with only one hand or, in certain situations, when only one hand is free.

In order to solve the above problems, the present invention provides a solid quantitative bottle which can solve the above problems well.

Disclosure of Invention

In order to achieve the above object, the present invention provides a quantitative solid bottle, which can be operated with only one hand, and can pour out one or more solid particles only by pressing the cap of the quantitative solid bottle, wherein the number of the solid particles can be set and controlled. And no effect on the amount removed is obtained, not how much solid particles remain in the vial. For increasing the effect of use, the shape of the solid particles is preferably designed to be spherical or sphere-like. The principle of the invention for realizing the above functions is as follows:

the solid quantitative bottle comprises a bottle cap, a bottle body and a spiral spring clamped between the two parts; the bottle cap is buckled on the bottle body, a bottle cap sleeve is arranged at the center of the bottle cap and inserted into the bottle body, the bottle cap is allowed to be pressed down for a certain distance and is restored to the original state under the reaction of the spiral spring, after the bottle cap is pressed down each time, one spherical particle in the bottle body can enter the bottle cap sleeve at the center of the bottle cap, the solid quantifying bottle is turned over, the spherical particle can be poured out, and the function of quantitatively taking out the particle is realized;

optionally, the bottle cap is continuously pressed for multiple times, one spherical particle enters the bottle cap sleeve by pressing each time, the solid quantifying bottle is turned over, and the spherical particles stored in the bottle cap sleeve are poured out together.

A small bottle cap is arranged on the upper surface of the center of the bottle cap; the novel ball-shaped bottle cap is characterized in that a sleeve is arranged in the center of the bottle cap, an outlet at the upper end of the sleeve is connected with the bottle cap into a whole, the small bottle cap covers the outlet of the sleeve of the bottle cap, a valve structure is arranged at the other end of the sleeve of the bottle cap, the inner diameter of the valve is smaller than the diameter of the ball-shaped particles, and the ball-shaped particles cannot reversely fall out after the sleeve of the bottle cap swallows the ball-shaped particles. The valve at the lower end of the bottle cap sleeve is provided with an opening on the peripheral wall of the bottle cap sleeve so as to increase the elasticity of the valve, reduce the resistance and increase the trafficability when spherical particles pass through.

The bottle body comprises a bottle body side wall, a spiral revolution curved surface positioned at the bottom of the bottle body and a bottle body sleeve positioned at the center of the bottle body; this body sheathed tube lower extreme and spiral surface of revolution's inward flange are connected on the body sleeve pipe, have with an opening that the spiral surface of revolution lower extreme position corresponds, the inside spheroid granule of body rolls this spiral surface of revolution's lower extreme along spiral surface of revolution, and it is intraductal that this body cover is entered into to this opening of rethread. Due to mutual extrusion and gravity action among the particles, one spherical particle is always ensured to be positioned inside the lower end of the bottle body sleeve.

The bottle cap sleeve is arranged in the bottle body sleeve in a penetrating manner, and a certain height difference is formed between the edge of the lower end of the bottle cap sleeve and the lowest position of the spiral revolution curved surface, and the height difference is slightly larger than the diameter of the spherical particles; when the bottle cap is pressed down, the bottle cap drives the bottle cap sleeve to move downwards together and swallow spherical particles below the inner part of the bottle body sleeve; because the opening on the bottle cap sleeve valve structure is opened when spherical particles pass through, the spherical particles are closed after passing through, and the spherical particles cannot fall out reversely after entering the bottle cap sleeve; meanwhile, the upper end of the bottle body sleeve can prop open the small bottle cap on the upper surface of the bottle cap, the opening at the upper end of the bottle cap sleeve is opened, the bottle body is turned, the spherical particles automatically roll out of the bottle, and the function of quantitatively taking the spherical particles is realized, or the bottle body can be turned after the bottle cap is pressed for many times; at the moment, the bottle cap sleeve swallows one spherical particle by pressing the bottle cap at each time, so that a plurality of spherical particles are stored in the bottle cap sleeve by pressing for many times, and the quantifying bottle is turned over at the moment, so that the plurality of spherical particles roll out of the bottle cap sleeve together.

Optionally, the lower end of the bottle cap sleeve can be designed without a valve, and is only the end face of the common sleeve, the bottle cap is pressed under the condition that the spherical particles are swallowed by the bottle cap sleeve, and then the inlet at the lower end of the bottle body sleeve is also blocked, so that the spherical particles outside can not enter the bottle cap sleeve, the bottle cap is not loosened by pressing the bottle cap, the quantifying bottle is turned over, the spherical particles in the bottle cap sleeve can roll out, and at the moment, only one spherical particle can be taken out by pressing the bottle cap once.

Above be exactly this technical scheme, this solid ration bottle is very convenient to use, presses each time and all guarantees that at least one solid particle is taken out, and this function can not receive the influence of the remaining spheroid granule quantity in the bottle moreover. And the design model is verified by the 3D printed solid model.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only show some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a perspective view of a solid measuring flask

FIG. 2 is an exploded view of a solid dosing bottle

FIG. 3 is a perspective view of a vial cap

Fig. 4 is a top view of the bottle cap

Fig. 5 is an axial sectional view of the bottle cap

FIG. 6 is a perspective view of a cap with a valve structure on the cap sleeve

FIG. 7 is a perspective view of the body sleeve

FIG. 8 is a perspective view of the cap sleeve and body sleeve engaged

FIG. 9 is a schematic view of a bottom spiral surface of revolution of a bottle body

FIG. 10 is an axial cross-sectional view of the body

FIG. 11 is a diagram showing the movement locus of spherical particles in a solid quantitative bottle

Detailed Description

The following description of the embodiments of the present application is provided by way of specific examples, and other advantages and effects of the present application will be readily apparent to those skilled in the art from the disclosure herein. The present application is capable of other and different embodiments and its several details are capable of modifications and/or changes in various respects, all without departing from the spirit of the present application. It is to be noted that the features in the following embodiments and examples may be combined with each other without conflict.

It should be noted that the drawings provided in the following embodiments are only schematic and illustrate the basic idea of the present application, and although the drawings only show the components related to the present application and are not drawn according to the number, shape and size of the components in actual implementation, the type, quantity and proportion of the components in actual implementation may be changed at will, and the layout of the components may be more complex.

Throughout the specification, when a part is referred to as being "connected" to another part, this includes not only a case of being "directly connected" but also a case of being "indirectly connected" with another element interposed therebetween. In addition, when a certain part is referred to as "including" a certain component, unless otherwise stated, other components are not excluded, but it means that other components may be included.

The terms first, second, third, etc. are used herein to describe various elements, components, regions, layers and/or sections, but are not limited thereto. These terms are only used to distinguish one element, component, region, layer or section from another element, component, region, layer or section. Thus, a first element, component, region, layer or section discussed below could be termed a second element, component, region, layer or section without departing from the scope of the present application.

Also, as used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context indicates otherwise. It will be further understood that the terms "comprises," "comprising," and/or "comprising," when used in this specification, specify the presence of stated features, operations, elements, components, items, species, and/or groups, but do not preclude the presence, or addition of one or more other features, operations, elements, components, items, species, and/or groups thereof. The terms "or" and/or "as used herein are to be construed as inclusive or meaning any one or any combination. Thus, "A, B or C" or "A, B and/or C" means "any of the following: a; b; c; a and B; a and C; b and C; A. b and C ". An exception to this definition will occur only when a combination of elements, functions or operations are inherently mutually exclusive in some way.

FIG. 1 is a perspective view of the solid quantitative bottle, which comprises a bottle cap 1 and a bottle body 2, wherein the bottle cap is partially buckled on the bottle body.

Fig. 2 is an exploded view of the solid dosing bottle, wherein the parts involved are respectively: 1-bottle cap; 2-a bottle body; 3-small bottle cap; 4-a coil spring; and 5, a bottle body sleeve. It should be noted that, in consideration of the limitation of the part manufacturing process, the body portion of the solid quantitative bottle is divided into the part body 2 and the part body sleeve 5, in other words, in other embodiments, the body 2 and the body sleeve 5 may be made into an integral structure as long as the process can be realized, for example, by 3D printing technology.

Fig. 3 is a perspective view of the vial cap 3. The part characteristic part that it includes has: 3.1-vial cap body, which is covered on the outlet of the spherical particles on the upper surface of the cap 1 and cooperates with the cap body 1 through a transverse axis 3.2. In addition, a fixing plate 3.4 is provided, a fixing hole 3.5 is arranged on the fixing plate 3.4, and a connecting rod 3.3 is arranged between the fixing plate 3.4 and the small bottle cover main body 3.1. Wherein the fixing plate 3.4 is fixed with the bottle cap body 1 through the fixing hole 3.5 on the fixing plate. When the small bottle cap 3 is jacked up by the bottle body sleeve 5 arranged in the bottle body, the small bottle cap 3 rotates around the transverse shaft 3.2 on the small bottle cap, the connecting rod 3.3 is elastically deformed at the moment, and when the bottle cap main body 1 loses pressure and recovers, the small bottle cap 3 can recover under the action of the connecting rod 3.3 and covers the outlet of the bottle cap main body 1.

Fig. 4 is a top view of the closure 1 and fig. 5 is an axial cross-sectional view of the closure 1, showing the features of the closure 1 through fig. 4 and 5: 1.1-outlet on the upper surface of the bottle cap, 1.2-fixed column, 1.3-open shaft hole, 1.4-bottle cap sleeve, 1.5-bottle cap sleeve connecting wall and 1.6-bottle cap side wall. Wherein the outlet on the upper surface of the bottle cap 1.1 is matched with the main body of the bottle cap 3.1, and is matched with the fixing hole 3.5 on the bottle cap through the fixing column 1.2, and the transverse shaft 3.2 on the bottle cap is directly pressed into the open shaft hole 1.3 in consideration of the requirements of the assembly process.

Fig. 6 is a perspective view of the cover sleeve with a valve structure, and it can be seen that the valve 1.8 is additionally provided with bulges at the end of the cover sleeve 1.4, and a plurality of openings 1.7 are formed for increasing the elasticity, so that the end valve 1.8 is easier to expand outwards to swallow the spherical particles.

It should be noted that if the valve 1.8 is provided at the lower end of the cover sleeve 1.4, each time the cover is pressed, the cover sleeve 1.4 will swallow the individual spherical particles and store them in the tube, and when the solid metered dose bottle is turned over, all the spherical particles stored in the cover sleeve 1.4 will be removed.

Optionally, if the lower end of the bottle cap sleeve 1.4 is not designed with other structures and is reserved as a common sleeve end face, after the bottle cap is pressed down, the bottle cap sleeve 1.4 swallows one spherical particle, and at the moment, the bottle cap sleeve 1.4 also blocks other spherical particles, so that the spherical particles do not enter the bottle body sleeve any more.

At the moment, the bottle cap is required to be kept pressed down, the hand cannot be loosened, the fixed quantitative bottle is turned over at the moment, and only spherical particles in the bottle cap sleeve 1.4 are taken out. It should be noted that this embodiment can only ensure that one spherical particle is removed each time the bottle cap is pressed.

Fig. 7 is a perspective view of a bottle body sleeve of the solid quantitative bottle, wherein the characteristic parts are as follows: 5.1-body sleeve, 5.2-avoidance opening at the upper end of the 5.1-body sleeve, wherein the avoidance opening avoids the connecting wall 1.5 on the bottle cap sleeve when the bottle cap main body 1 relatively descends. 5.3-inlet of the spherical particles, and 5.4-lower edge of the inlet of 5.3, which is tangent with the spiral revolution surface (shown in figure 9) inside the bottle body, so that the spherical particles are smoother when rolling. 5.5 is the bottom surface of the solid measuring flask. Wherein 5.6 is a positioning protrusion on the bottom surface 5.5, because the body sleeve 5 and the body main body 2 are required to be positioned when they are matched, the positioning protrusion 5.6 has a positioning function.

Fig. 8 is a perspective view of the cap sleeve 1 and the body sleeve 5, and it can be seen that when the cap body 1 is pressed down, the body sleeve 5 protrudes and pushes the small cap 3 open, and the cap sleeve 1.4 blocks the inlet 5.3 of the spherical particles, so that the spherical particles outside the cap sleeve 1.4 can not enter the body sleeve 5.

Fig. 9 and 10 are a perspective view and an axial sectional view of a body 2 of a quantitative solid bottle, respectively, in which it can be seen that the body has a spiral surface of revolution 2.1 inside it, which ensures that all spherical particles roll on the surface toward the bottom one by one, and a circular hole 2.2 is formed in the center of the spiral surface of revolution, through which a body sleeve 5.1 passes, which allows for the manufacturing process of plastic parts, because the body is difficult to manufacture as one body, and it is only necessary to manufacture the body separately and assemble the body together.

Fig. 11 is a diagram of the movement locus of spherical particles inside the solid quantification bottle, and when a valve structure is adopted inside the port of the bottle cap sleeve 1.4, the spherical particles D swallowed at this time cannot fall out due to the blocking of the valve 1.8. After the bottle cap is loosened, the spherical particles C at the inlet 5.3 of the bottle body sleeve can enter the position of the original spherical particles D under the combined action of other spherical particles and self gravity, and meanwhile, the spherical particles A and the spherical particles B can roll downwards on the spiral revolution curved surface together to occupy the empty space in the front. When the cap is pressed again, the cap sleeve 1.4 will swallow the spherical particles C. It is concluded that each time the cap is pressed down, the cap skirt 1.4 will engulf a spherical particle and be stored inside it. When the novel bottle cap is used, the corresponding times of pressing the bottle cap can be determined according to the required quantity of the spherical particles, for example, when three spherical particles are required, the bottle cap is pressed for three times, so that the three spherical particles are stored in the bottle cap sleeve, at the moment, the bottle body is turned over, and the spherical particles in the required quantity roll out from the opening of the bottle body sleeve 5.1. Therefore, the bottle cap sleeve 1.4 with the valve 1.8 structure can store 1 spherical particle along with each pressing, and then the whole bottle is turned over, so that the spherical particles are poured into the mouth together for taking.

Optionally, the lower end of the bottle cap sleeve can be designed without a valve, and is only the end face of the common sleeve, the bottle cap is pressed under the condition that the spherical particles D are swallowed by the bottle cap sleeve 1.4, and then the inlet at the lower end of the bottle body sleeve is blocked, so that the spherical particles C outside can not enter the bottle cap sleeve, the bottle cap is pressed, the hand is not loosened, the quantitative bottle is turned over, the spherical particles D in the bottle cap sleeve roll out, and at the moment, the bottle cap is pressed once, and only one spherical particle is taken out.

To sum up, through the technique of this solid ration bottle, can realize setting for certain quantity to the spheroid granule, its operation is also very convenient, only need press can. In particular, the fixed quantitative bottle technology can meet the use requirement of one-hand operation.

Claims

1. A solid quantitative bottle is characterized by comprising a bottle cap, a bottle body and a spiral spring clamped between the bottle cap and the bottle body; the bottle cap is buckled on the bottle body, a bottle cap sleeve is arranged at the center of the bottle cap and inserted into the bottle body, the bottle cap is allowed to be pressed down for a certain distance and is restored to the original state under the reaction of the spiral spring, after the bottle cap is pressed down each time, spherical particles in the bottle body can enter the bottle cap sleeve at the center of the bottle cap, the solid quantifying bottle is turned over, the spherical particles can be poured out, and the function of quantitatively taking out the particles is realized;

optionally, the bottle cap is continuously pressed for multiple times, one spherical particle enters the bottle cap sleeve by pressing each time, the solid quantifying bottle is turned over at the moment, and the spherical particles stored in the bottle cap sleeve are poured out together.

2. The quantitative solid bottle as claimed in claim 1, wherein a small cap is provided at a central upper surface of the cap; the novel ball-shaped bottle cap is characterized in that a sleeve is arranged in the center of the bottle cap, an outlet at the upper end of the sleeve and the bottle cap are connected into a whole, the small bottle cap covers the outlet of the sleeve of the bottle cap, a valve structure is arranged at the other end of the sleeve of the bottle cap, the inner diameter of the valve is smaller than the diameter of the ball-shaped particles, and the ball-shaped particles cannot fall out reversely after the sleeve of the bottle cap swallows the ball-shaped particles.

3. The bottle for quantitative determination of solid content according to claim 2, wherein the cap sleeve has an opening on the peripheral wall thereof at the valve at the lower end thereof to increase the elasticity of the valve, reduce the resistance to passage of the particles, and increase the passability.

4. The quantitative solid bottle as claimed in claim 1, wherein the body comprises a sidewall, a spiral surface of revolution at the bottom of the body, and a body sleeve at the center of the body; this body sheathed tube lower extreme and spiral surface of revolution's inward flange are connected on the body sleeve pipe, have with an opening that the spiral surface of revolution lower extreme position corresponds, the inside spheroid granule of body rolls this spiral surface of revolution's lower extreme along spiral surface of revolution, and it is intraductal that this body cover is entered into to this opening of rethread. Due to mutual extrusion and gravity action among the particles, one spherical particle is always ensured to be positioned inside the lower end of the bottle body sleeve.

5. The quantitative solid bottle as claimed in claim 1, wherein the cap sleeve is inserted into the body sleeve, and the lower edge of the cap sleeve has a height difference from the lowest point of the spiral surface of revolution, which is slightly larger than the diameter of the spherical particles; when the bottle cap is pressed down, the bottle cap drives the bottle cap sleeve to move downwards together and swallow spherical particles below the inner part of the bottle body sleeve; because the opening on the bottle cap sleeve valve structure is opened when spherical particles pass through, the spherical particles are closed after passing through, and the spherical particles cannot fall out reversely after entering the bottle cap sleeve; meanwhile, the upper end of the bottle body sleeve can prop open the small bottle cap on the upper surface of the bottle cap, the opening at the upper end of the bottle cap sleeve is opened, the bottle body is turned, the spherical particles automatically roll out of the bottle, and the function of quantitatively taking the spherical particles is realized, or the bottle body can be turned after the bottle cap is pressed for many times; at this moment, the bottle cap sleeve can swallow one spherical particle by pressing the bottle cap at every time, so that a plurality of spherical particles can be stored in the bottle cap sleeve by pressing for many times, the quantitative bottle is turned over again, and the spherical particles roll out of the bottle cap sleeve together.

6. The solid dosing bottle according to claim 1, wherein the lower end of the cap sleeve is not designed as a valve, but is a normal end surface of the sleeve, and when the cap is pressed down, the cap sleeve also blocks the inlet at the lower end of the body sleeve after the ball particles are swallowed, so that the outer ball particles cannot enter the cap sleeve, the cap is pressed down and the hand is not loosened, and when the dosing bottle is turned over, the ball particles in the side cap sleeve roll out, and when the cap is pressed down, only one ball particle is taken out.