阅读说明：本技术 一种全方位无障碍的吸奶奶瓶 (All-round accessible milk feeding bottle that inhales ) 是由 徐观富 于 2020-12-30 设计创作，主要内容包括：本发明属于婴幼儿用品技术领域,一种全方位无障碍的吸奶奶瓶,其特征在于,包括奶瓶瓶体、奶瓶瓶盖,奶嘴、支撑块及硅胶吸管；支撑块放置在奶瓶瓶体瓶口处,奶瓶瓶体瓶口处与奶瓶瓶盖可拆卸连接,奶瓶瓶盖将支撑块固定在奶瓶瓶体瓶口处；支撑块上开设有第一通孔、第三通孔,第三通孔位于支撑块的中间部位,第三通孔为上端小下端大的通孔,第三通孔的大口端底部固定连接有多孔弧形板,多孔弧形板与第三通孔的大口端形成放置腔,放置腔内放置有第三重力球。本发明当婴儿倾斜甚至倒立时,处于最低位置的第一通孔将会在第二重力球的作用下,将奶瓶瓶体内腔与奶嘴连通,这样就可以保证婴儿无论什么姿势都可以喝到,在用奶瓶喝奶的时候无需专门照看。(The invention belongs to the technical field of infant products, and relates to an all-dimensional barrier-free milk sucking feeding bottle which is characterized by comprising a feeding bottle body, a feeding bottle cap, a nipple, a supporting block and a silica gel suction pipe; the supporting block is placed at the bottle mouth of the feeding bottle body, the bottle mouth of the feeding bottle body is detachably connected with a feeding bottle cap, and the supporting block is fixed at the bottle mouth of the feeding bottle body by the feeding bottle cap; first through-hole, third through-hole have been seted up on the supporting shoe, and the third through-hole is located the middle part of supporting shoe, and the third through-hole is the big through-hole of the little lower extreme in upper end, and the big mouth end bottom fixedly connected with porous arc of third through-hole, and the chamber is placed in the formation of porous arc and the big mouth end of third through-hole, places the intracavity and has placed the third gravity ball. When the baby inclines or even falls down, the first through hole at the lowest position can communicate the inner cavity of the bottle body of the feeding bottle with the nipple under the action of the second gravity ball, so that the baby can drink in any posture, and the feeding bottle is not required to be specially looked after when being used for drinking milk.)

1. An all-round accessible milk sucking feeding bottle is characterized by comprising a feeding bottle body (1), a feeding bottle cap (2), a nipple (3), a supporting block (4) and a silica gel suction pipe (5);

the supporting block (4) is placed at the bottleneck of the feeding bottle body (1), the bottleneck of the feeding bottle body (1) is detachably connected with the feeding bottle cap (2), and the supporting block (4) is fixed at the bottleneck of the feeding bottle body (1) by the feeding bottle cap (2);

the nipple (3) is clamped on the upper end surface of the feeding bottle cap (2);

a first through hole (44) and a third through hole (47) are formed in the supporting block (4), the third through hole (47) is located in the middle of the supporting block (4), the third through hole (47) is a through hole with a small upper end and a large lower end, a porous arc-shaped plate (8) is fixedly connected to the bottom of the large opening end of the third through hole (47), a placing cavity (10) is formed by the porous arc-shaped plate (8) and the large opening end of the third through hole (47), and a third gravity ball (9) is placed in the placing cavity (10);

the first through holes (44) are uniformly formed in the supporting block (4), the distances from the first through holes (44) to the third through holes (47) are equal, and the first through holes (44) and the third through holes (47) are used for communicating the inner cavity of the feeding bottle body (1) with the nipple (3);

an annular hole cavity (41), an inclined hole cavity (42) and a square hole cavity (43) are formed in the supporting block (4), openings at two ends of the inclined hole cavity (42) are different in size, one end with a large opening of the inclined hole cavity (42) is communicated with the annular hole cavity (41), one end with a small opening of the inclined hole cavity (42) is communicated with the square hole cavity (43), the annular hole cavity (41) is coaxial with the third through hole (47), the square hole cavity (43) is communicated with the first through hole (44), and a movable second gravity ball (7) is placed in the annular hole cavity (41);

one end, far away from the third through hole (47), of the square hole cavity (43) is elastically connected with a stop block (46) through a spring (45), the stop block (46) is matched with the square hole cavity (43) and can slide on the square hole cavity (43), a second through hole (461) is formed in the stop block (46), and the stop block (46) can control the connection and disconnection of the first through hole (44) through sliding on the square hole cavity (43).

2. The omnibearing barrier-free milk sucking bottle as claimed in claim 1, wherein the bottom end of the third through hole (47) is connected with a first gravity ball (6) through a silica gel suction pipe (5), and a liquid inlet hole is formed in the first gravity ball (6).

3. The omnibearing barrier-free milk sucking bottle as claimed in claim 1, wherein the stopper (46) is provided with an arc-shaped groove at its end away from the spring (45).

4. The all-round unobstructed milk bottle according to claim 1, characterized by that, the number of the inclined cavities (42) is the same as the number of the square cavities (43) and is not less than four, the adjacent inclined cavities (42) are communicated with the big mouth end, and the front and back side walls of the inclined cavities (42) are arc-shaped.

5. The omnidirectional barrier-free milk sucking bottle according to claim 1, wherein the gravity ball is made of silica gel or stainless steel.

6. An all-directional unobstructed nursing bottle according to claim 4, wherein the number of first through holes (44) is the same as the number of square bores (43), the first through holes (44) being located at the edge of the support block (4).

7. The omnibearing barrier-free milk sucking bottle according to claim 1, wherein the joints of the annular hole cavity (41) and the square hole cavity (43) with the inclined hole cavity (42) are provided with chamfers.

8. The omnibearing barrier-free milk bottle according to claim 1, wherein the diameter of the third gravity ball (9) is larger than the inner diameter of the small opening end of the third through hole (47) and smaller than the inner diameter of the large opening end of the third through hole (47).

Technical Field

The invention belongs to the technical field of infant products, and particularly relates to an all-dimensional barrier-free milk sucking feeding bottle.

Background

At present, a lot of people all directly use the feeding bottle to brew milk powder to feed babies, but babies are very good, the feeding bottle can be disorderly moved when the feeding bottle is used for drinking milk, most feeding bottles sold in the market at present are provided with a suction pipe, the babies can suck the milk by using the suction pipe of the feeding bottle when sitting, the position of the suction pipe of the feeding bottle cannot be automatically adjusted when lying, so that the babies cannot suck the milk, the feeding bottles need to be specially cared for the babies when drinking the milk, and the position of the suction pipe gravity ball inside the feeding bottle is adjusted at any time.

The invention is a Chinese patent No. CN201310226504.0, which provides an omnibearing water-sucking milk bottle, comprising a bottle body and a middle cover, wherein the middle cover is provided with a suction nozzle, the middle cover is internally provided with a first tray and a second tray, the upper end of the second tray is hermetically connected with the second tray, the second tray is provided with an inner water inlet hole and an outer water inlet hole, the inner water inlet hole is connected with a suction pipe, a non-closed annular cavity is formed between the top of the second tray and the inner wall of the first tray after assembly, a sealing ring is arranged in the annular cavity, the sealing ring seals the outer water inlet hole when the bottle is upright, so that the suction pipe, the inner water inlet hole and the suction nozzle form a forward water-sucking channel, when the milk bottle is turned upside down, the gravity of the sealing ring naturally falls, the outer water inlet hole is opened, the outer water inlet hole and the suction nozzle form an inverted water-sucking channel, which is similar to the milk bottle without the suction pipe at present, the omnibearing water outlet, the air in the bottle body can enter the mouth of the infant along with the milk through the suction pipe, so that the infant can drink too much air into the stomach to form flatulence, and the phenomenon of milk spitting due to the appearance of the flatulence is very unfavorable for the health of the infant. Therefore, an all-round barrier-free milk sucking bottle is designed to solve the problems.

Disclosure of Invention

In order to solve the problems that when a baby drinks milk by using a feeding bottle, the direction of the feeding bottle is often changed when the baby drinks the milk, the position of a milk sucking pipe in the feeding bottle cannot be automatically adjusted, so that the baby cannot suck the milk, and when the feeding bottle is inclined or inverted, because the improved feeding bottle has more openings and no openings through which milk passes, gas in the feeding bottle enters the mouth of the baby along with the milk, so that the stomach of the baby is inflated, the invention adopts the following technical scheme.

An all-round accessible milk sucking feeding bottle is characterized by comprising a feeding bottle body, a feeding bottle cap, a nipple, a supporting block and a silica gel suction pipe;

the supporting block is placed at the bottle mouth of the feeding bottle body, the bottle mouth of the feeding bottle body is detachably connected with a feeding bottle cap, and the supporting block is fixed at the bottle mouth of the feeding bottle body by the feeding bottle cap;

the nipple is clamped on the upper end surface of the bottle cap of the feeding bottle;

the supporting block is provided with a first through hole and a third through hole, the third through hole is positioned in the middle of the supporting block, the third through hole is a through hole with a small upper end and a large lower end, the bottom of the large opening end of the third through hole is fixedly connected with a porous arc-shaped plate, the porous arc-shaped plate and the large opening end of the third through hole form a placing cavity, and a third gravity ball is placed in the placing cavity;

the first through holes are uniformly formed in the supporting block, the distances from the first through holes to the third through holes are equal, and the first through holes and the third through holes communicate the inner cavity of the bottle body of the feeding bottle with the nipple;

an annular hole cavity, an inclined hole cavity and a square hole cavity are formed in the supporting block, openings at two ends of the inclined hole cavity are different in size, one end with a large opening of the inclined hole cavity is communicated with the annular hole cavity, one end with a small opening of the inclined hole cavity is communicated with the square hole cavity, the annular hole cavity is coaxial with the third through hole, the square hole cavity is communicated with the first through hole, and a second gravity ball capable of moving is placed in the annular hole cavity;

the end, far away from the third through hole, of the square hole cavity is elastically connected with a stop block through a spring, the stop block is matched with the square hole cavity and can slide on the square hole cavity, a second through hole is formed in the stop block, and the stop block can slide on the square hole cavity to control the on-off of the first through hole.

Preferably, the bottom of third through-hole is connected with first gravity ball through the silica gel straw, and the feed liquor hole has been seted up to first gravity ball inside.

Preferably, the end of the stop block far away from the spring is provided with an arc-shaped groove.

Preferably, the number of the inclined holes and the number of the square holes are the same and not less than four, the large opening ends of the adjacent inclined holes are communicated, and the front side wall and the rear side wall of each inclined hole are arc-shaped.

Preferably, the material of gravity ball can be silica gel or stainless steel.

Preferably, the number of the first through holes is the same as the number of the square bores, the first through holes being located at the edge of the support block.

Preferably, the annular hole cavity and the square hole cavity are respectively provided with a chamfer at the connection part with the inclined hole cavity.

Preferably, the diameter of the third gravity ball is larger than the inner diameter of the small opening end of the third through hole and smaller than the inner diameter of the large opening end of the third through hole.

Compared with the prior art, the invention has the beneficial effects that:

when a baby drinks milk from the feeding bottle upright, milk in the bottle enters the nipple through the first gravity ball and the silica gel suction tube and then enters the mouth of the baby, and when the baby tilts or even inverts the feeding bottle, the first through hole at the lowest position communicates the inner cavity of the bottle body of the feeding bottle with the nipple under the action of the second gravity ball, and only one first through hole is communicated, so that the feeding bottle can ensure that the baby can drink milk in any posture, and does not need to look after specially when drinking milk.

According to the omnibearing barrier-free milk sucking feeding bottle, due to the design of the placing cavity and the third gravity ball, the third through hole can be blocked when the baby inclines or even stands upside down, and the situation that gas in the feeding bottle enters the mouth of the baby along with milk through the third through hole when the baby drinks milk due to the fact that the first gravity ball is not in contact with the milk in the feeding bottle is prevented, and the stomach of the baby is inflated.

The large opening ends of the adjacent inclined holes are communicated, and the front side wall and the rear side wall of each inclined hole are in arc-shaped design, so that when a baby rotates the inclined milk bottle, the second gravity ball directly rolls from the front inclined hole to the rear inclined hole to communicate with the first through hole at the lowest point, and cannot be clamped in the front inclined hole due to the fact that the second gravity ball returns to the annular hole firstly.

In the omnibearing barrier-free milk sucking feeding bottle, the chamfer angle is arranged at the joint of the annular hole cavity and the square hole cavity and the inclined hole cavity respectively, so that the second gravity ball can move more smoothly in the process.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the support block of the present invention;

FIG. 3 is a cross-sectional view of the step of FIG. 2A-A according to the present invention;

FIG. 4 is a schematic view showing the movement of the second gravity ball when the baby bottle is tilted according to the present invention;

FIG. 5 is a schematic view of the movement of the second gravity ball when the inclined nursing bottle is rotated according to the present invention;

FIG. 6 is a schematic view of the structure of the baby bottle of the present invention drinking milk immediately;

FIG. 7 is a schematic view showing a structure in which an infant drinks milk while tilting the nursing bottle according to the present invention.

In the figure: 1. the feeding bottle comprises a feeding bottle body, 2, a feeding bottle cap, 3, a nipple, 4, a supporting block, 41, an annular hole cavity, 42, an inclined hole cavity, 43, a square hole cavity, 44, a first through hole, 45, a spring, 46, a stop block, 461, a second through hole, 47, a third through hole, 5, a silica gel suction pipe, 6, a first gravity ball, 7, a second gravity ball, 8, a porous arc-shaped plate, 9 and a third gravity ball.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application. In the drawings of the embodiments of the present application, hatching of various types in the drawings is not labeled according to national standards, does not require the material of elements, and distinguishes the sectional views of the elements in the drawings.

Please refer to fig. 1-7, which illustrate an all-directional and barrier-free milk bottle, which is an all-directional and barrier-free milk bottle that can drink milk regardless of how a baby holds the bottle with his/her hands and does not inflate the stomach by sucking more air during the milk drinking process. Concretely, an all-round accessible milk bottle of inhaling, includes feeding bottle body 1, feeding bottle lid 2, nipple 3, supporting shoe 4 and silica gel straw 5.

The supporting shoe 4 is placed at 1 bottleneck department of bottle body, and 1 bottleneck department of bottle body can dismantle with feeding bottle lid 2 and be connected, and feeding bottle lid 2 revolves soon when 1 bottleneck department of bottle body, and feeding bottle lid 2 will fix supporting shoe 4 at 1 bottleneck department of bottle body, and 3 joints of nipple are at the up end of feeding bottle lid 2.

First through-hole 44 has been seted up on the supporting shoe 4, third through-hole 47 is located the middle part of supporting shoe 4, third through-hole 47 is the through-hole that the lower extreme is big for the upper end, porous arc 8 of macrostoma end bottom fixedly connected with of third through-hole 47, porous arc 8 forms with the macrostoma end of third through-hole 47 and places chamber 10, place and place third gravity ball 9 in the chamber 10, the diameter of third gravity ball 9 is greater than the internal diameter of third through-hole 47 macrostoma end and is less than the internal diameter of third through-hole 47 macrostoma end, third gravity ball 9 blocks up third through-hole 47 when baby's slope or even handstand feeding bottle like this, prevent because first gravity ball 6 does not have the contact with the milk in the feeding bottle, lead to the gas in the baby drinks in the feeding bottle in the time in the feeding bottle gets into the baby's mouth along with milk via third.

First through-hole 44 is even to be set up on supporting shoe 4, first through-hole 44 equals to the distance of third through-hole 47, first through-hole 44 communicates 1 inner chamber of feeding bottle body with nipple 3 with third through-hole 47, the quantity of first through-hole 44 is the same with the quantity of square vestibule 43, first through-hole 44 is located the edge of supporting shoe 4, can make the milk in the feeding bottle of slope better soon drunk up like this, the bottom of third through-hole 47 is connected with first gravity ball 6 through silica gel straw 5, the feed liquor hole has been seted up to first gravity ball 6 inside.

The supporting block 4 is internally provided with an annular hole cavity 41, an inclined hole cavity 42 and a square hole cavity 43, openings at two ends of the inclined hole cavity 42 are different in size, one end with a large opening of the inclined hole cavity 42 is communicated with the annular hole cavity 41, one end with a small opening of the inclined hole cavity 42 is communicated with the square hole cavity 43, the annular hole cavity 41 is coaxial with the third hole cavity 47, the square hole cavity 43 is communicated with the first through hole 44, the annular hole cavity 41 is internally provided with a movable second gravity ball 7, and the joints of the annular hole cavity 41 and the square hole cavity 43 with the inclined hole cavity 42 are respectively provided with chamfers, so that the second gravity ball 7 can move more smoothly.

One end of the square hole 43 far away from the third through hole 47 is elastically connected with a stopper 46 through a spring 45, the stopper 46 is matched with the square hole 43 and can slide on the square hole 43, the stopper 46 is provided with a second through hole 461, the sliding of the stopper 46 on the square hole 43 can control the on-off of the first through hole 44, and one end of the stopper 46 far away from the spring 45 is provided with an arc-shaped groove, so that when the second gravity ball 7 extrudes the stopper 46, the stopper 46 can be better stressed.

The inclined bores 42 are four as many as the square bores 43, the adjacent inclined bores 42 are in large-mouth end communication, and the front and rear side walls of the inclined bores 42 are arc-shaped, so that when the baby turns the inclined bottle, the second gravity ball 7 will roll directly from the front inclined bore 42 to the rear inclined bore 42 and will be in communication with the first through hole 44 at the lowest point without being caught in the front inclined bore 42 by returning to the annular bore 41 first.

The gravity ball can be made of silica gel or stainless steel, and the health of the infant cannot be influenced in the using process of the gravity ball.

When the feeding bottle is upright, the second gravity ball 7 is positioned in the annular hole 41, the third gravity ball 9 is positioned on the perforated arc-shaped plate 8, the third through hole 47 is communicated, the first through hole 44 is disconnected and the spring 45 is in a free state, when an infant uses the feeding bottle to drink milk and tilts the feeding bottle, the second gravity ball 7 comes into the square hole 43 at the lowest point through the annular hole 41 and the inclined hole 42 to press the corresponding stopper 46, the spring 45 is compressed, the second through hole 461 is aligned with the first through hole 44 to communicate the first through hole 44, milk in the feeding bottle can reach the nipple 3 through the first through hole 44 at the lowest point, the infant cannot drink milk due to the fact that the first gravity ball 6 is not in contact with the milk in the feeding bottle during tilting, when the infant rotates the tilted feeding bottle, the second gravity ball 7 directly rolls from the first through hole 43 at the lowest point to the next inclined hole 42, the former first through hole 43 will be disconnected again under the action of the spring 45 and the stopper 46, so that the infant can always be ensured to suck milk when using the feeding bottle to drink milk.

When the feeding bottle is inclined to a certain degree, the third gravity ball 9 blocks the third through hole 47 under the action of the gravity of the feeding bottle, so that the situation that the first gravity ball 6 does not contact milk in the feeding bottle due to the fact that the inclination angle is too large is avoided, and gas in the feeding bottle enters the mouth of an infant along with the milk through the third through hole when the infant drinks milk, and the stomach of the infant is inflated.

The above; but are merely preferred embodiments of the present application; the scope of protection of the present application is not limited thereto; any person skilled in the art is within the technical scope of the present disclosure; the technical scheme and the improved concept of the application are equally replaced or changed; are intended to be covered by the scope of the present application.