CN114224738A - Feeding bottle for baby - Google Patents

Abstract

The invention discloses a baby feeding bottle, which comprises a storage bottle, a receiving hopper and a feeding trough; the receiving hopper is formed with a discharge hole; the storage bottle consists of a plurality of bottle bodies; a sealing disc is fixedly connected in the material receiving hopper; the upper part of the sealing disc is provided with a plurality of communicating ports; a gating disc is rotationally connected in the material receiving hopper; a gate is formed on the gate plate; a shifting block is formed outside the gating disc; a stop block is formed on the gating disc; a stop hemisphere is rotationally connected in the material receiving hopper; a stop groove is formed on the periphery of the stop hemisphere; when the stop block is positioned in the stop groove, the gating disc seals the communication opening; when the stop block is positioned outside the stop groove, the material can be discharged to the receiving hopper. The operation is simple and convenient, the workload is reduced, and the time and the labor are saved.

Description

Feeding bottle for baby

Technical Field

The invention belongs to the technical field of baby products, and particularly relates to a baby feeding bottle.

Background

Chinese patent document No. CN2120581U discloses a novel baby feeding bottle, which is characterized in that: the feeding bottle comprises a bottle cap (1), a pacifier (2), a clamping body (4) and the like, a disposable beverage bag is used for replacing the bottle body of the existing feeding bottle, the drinking sanitation is guaranteed, the trouble of cleaning and high-temperature disinfection of the bottle body is eliminated, the carrying is convenient, and the feeding bottle can be used for feeding the baby with the nutrient solution such as the fruit juice and the like.

The above patent can only carry one kind of food when in use, and can not carry solid and liquid foods at the same time, and can not meet different requirements of infants at different times.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: aiming at the defects existing in the prior art, the portable infant feeder which can contain various infant grains or water and can feed and feed water to infants is provided.

In order to realize the purpose of the invention, the following technical scheme is adopted for realizing the purpose: a baby feeding bottle comprises a storage bottle, a receiving hopper detachably connected to the upper end of the storage bottle and a feeding trough horizontally arranged on a rotating shaft rotatably connected to the periphery of the receiving hopper; and a discharge hole for feeding the feeding trough is formed in one side of the receiving hopper close to the feeding trough.

The storage bottle consists of a plurality of bottles for containing water and different kinds of grains; the lower part in the material receiving hopper is fixedly connected with a sealing disc capable of sealing each bottle body; a plurality of communicating ports which can be communicated with the corresponding bottle bodies are formed at the upper end of the sealing disc; a gating disc capable of closing each communication port is rotatably connected to the upper end of the sealing disc in the material receiving hopper; a gating port which can be respectively communicated with each communication port is formed at the upper end of the gating disc; the periphery of the gating disc is positioned outside the receiving hopper, and a shifting block is formed on the periphery of the gating disc.

A stop block is formed in the center of the upper end of the gating disc; a stop hemisphere with a rotating shaft parallel to the rotating shaft of the feeding trough is rotatably connected above the stop block in the material receiving hopper; the stop hemisphere can circumferentially rotate under the action of gravity; and a stop groove capable of being inserted into the stop block is formed on the periphery of the stop hemisphere.

When the stop block is positioned in the stop groove, the gating disc cannot rotate and seals each communication port; when the stop block is positioned outside the stop groove, the gating disc can rotate circumferentially, and the bottle body communicated with the gating opening can discharge materials to the material receiving hopper.

Compared with the prior art, the invention has the beneficial effects that: the baby feeder is convenient to carry, small in occupied space, regular in appearance and convenient to carry when the feeding trough and the storage bottle are combined, and can feed babies anytime and anywhere; the multifunctional infant food box can contain various infant grains and water, can meet the requirements of different infants on different foods when the infants are carried outdoors, and is simple and convenient; the invention can prevent accidental leakage, and the gating disc can be rotated only when the stop block is positioned outside the stop groove, so that grains or water can be poured out, and waste is avoided; the feeding amount of the baby can be controlled, the volume of the materials entering the closed cavity is the same, and the feeding amount of the baby can be controlled; the invention can recover water and grain, and the water and grain which are not used up can be stored back in the grain storage bottle, the operation is simple and convenient, the workload is reduced, and the time and the labor are saved.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic cross-sectional structure of the present invention.

Fig. 3 is a schematic exploded view of the present invention.

Fig. 4 and 5 are schematic sectional structural views of the receiving hopper of the invention.

Fig. 6 and 7 are schematic structural views of the strobe disk of the present invention.

Fig. 8 is a schematic structural view of the sliding column of the present invention.

Fig. 9 is a schematic view of the retaining hemisphere of the present invention.

Fig. 10 is a schematic view of the structure of the invention for feeding into the receiving hopper.

FIG. 11 is a schematic view of the feeding structure of the present invention into a feeding trough.

FIG. 12 is a schematic view of the structure of the reclaimed material of the present invention.

1. A material storage bottle; 11. a water storage bottle; 12. a grain storage bottle; 13. an external thread; 2. a receiving hopper; 21. rotating the column; 22. rotating the through groove; 221. sealing the clamping strip; 222. water outlet clamping strips; 223. discharging grain and clamping strips; 23. a sliding tube; 231. rotating the lug; 232. a slide through hole; 24. a discharge port; 25. an inner raised head; 3. a feeding trough; 31. hanging rope ears; 32. rotating the hole; 33. an open slot; 4. sealing the disc; 41. a water outlet; 42. a grain outlet; 43. positioning holes; 5. a gating disc; 51. selecting a port; 52. a stopper block; 53. shifting blocks; 531. a clamping groove; 54. a positioning column; 6. a sliding post; 61. extruding the column; 62. a stopper plate; 7. a stop hemisphere; 71. a stopper groove; 72. a connecting plate; 73. a rotating shaft; 8. an end cap; 81. positioning the through groove; 9. a spring.

Detailed Description

Referring to fig. 1 to 12, an infant feeding bottle according to the present embodiment includes a storage bottle 1, a receiving hopper 2 detachably connected to an upper end of the storage bottle 1 for receiving material, and a feeding trough 3 horizontally disposed on a rotating shaft rotatably connected to an outer periphery of the receiving hopper 2 for feeding; a discharge port 24 for feeding the feeding trough 3 is formed at one side of the receiving hopper 2 close to the feeding trough 3.

The storage bottle 1 consists of a plurality of bottles for containing water and different kinds of grains; a sealing disc 4 which can seal each bottle body and is coaxially arranged with the bottle body 1 is fixedly connected to the lower part in the material receiving hopper 2; a plurality of communicating ports which can be communicated with the corresponding bottle bodies are formed at the upper end of the sealing disc 4; a gating disc 5 which is longitudinally arranged and can seal the rotating shafts of the communicating ports is rotatably connected to the upper end of the sealing disc 4 in the material receiving hopper 2; the upper end of the gating disc 5 is provided with gating ports 51 which penetrate through the gating disc 5 and can be respectively communicated with the communication ports; the periphery of the gating disc 5 is positioned on the outer side of the material receiving hopper 2, and a shifting block 53 for driving the gating disc 5 to rotate is formed.

The number of the bottle bodies is two, and the bottle bodies comprise a water storage bottle 11 for containing water and a grain storage bottle 12 for containing grains; the number of the communicating ports is two, and the communicating ports comprise a water outlet 41 communicated with the water storage bottle 11 and a grain outlet 42 communicated with the grain storage bottle 12.

A positioning column 54 is formed in the center of the lower end of the gating disc 5; a positioning hole 43 rotatably connected with the positioning column 54 is formed in the central position of the upper end of the sealing plate 4; each communication opening is respectively arranged around the positioning hole 43, and the sealing plate 4 is tightly abutted to the gating plate 5, so that the gating plate 5 can seal each communication opening.

A stop block 52 is formed in the center of the upper end of the gating disc 5; a stop hemisphere 7 with a rotating shaft parallel to the rotating shaft of the feeding trough 3 is rotatably connected above the stop block 52 in the receiving hopper 2; the rotating shaft of the stopping hemisphere 7 is not coincident with the gravity center of the stopping hemisphere 7; the stop hemisphere 7 can rotate circumferentially under the action of gravity; a stop groove 71 which can be inserted into the stop block 52 is formed on the periphery of the stop hemisphere 7; a connecting plate 72 for connecting the two side portions of the stopping groove 71 is formed at the middle part of the stopping groove 71 near the periphery.

When the stop block 52 is located in the stop groove 71, the gate disc 5 cannot rotate, the gate disc 5 seals the communication ports, grains and water in the storage bottle 1 cannot enter the feeding groove 3, and water or grains are prevented from entering the receiving hopper 2 in the process of carrying the storage bottle 1.

Work as stop block 52 is located when the locking groove 71 is outer, gating dish 5 can circumferential direction, with the bottle of gating mouth 51 intercommunication can to connect the 2 ejection of compact of hopper, through stirring the adjustment of group 53 gating mouth 51 with correspond the intercommunication mouth intercommunication makes corresponding water or grain in the bottle enter into connect in the hopper 2, make then connect the hopper 2 to feeding groove 3 is reinforced, feeds grain watering to the baby, and easy operation is convenient, satisfies baby's diversified demand.

The discharge port 24 can be closed by the feeding trough 3, so that a closed cavity for quantitative charging is formed in the receiving hopper 2; grain or water entering the closed cavity is quantified, namely grain or water entering the water feeding groove 3 is quantified, so that the feeding amount of the baby can be controlled, and the healthy growth of the baby is facilitated.

The upper part of the receiving hopper 2 is longitudinally and slidably connected with a sliding column 6 which can limit the circumferential rotation of the stopping hemisphere 7; a stop plate 62 which can be abutted against the stop hemisphere 7 is formed at the lower end of the sliding column 6; the upper end of the sliding column 6 is formed with an extrusion column 61 which can tightly abut against the inner wall of the feeding trough 3 and has a diameter smaller than that of the sliding column 6.

A sliding pipe 23 which is longitudinally connected with the sliding column 6 in a sliding manner is formed in the center of the top end in the material receiving hopper 2; two rotating lugs 231 which are rotatably connected with the stopping hemisphere 7 are symmetrically formed at the lower end of the sliding tube 23; two rotating shafts 73 which are symmetrically arranged and rotatably connected with the corresponding rotating lugs 231 are respectively formed on the periphery of the stopping hemisphere 7 along the rotating shaft direction.

A sliding through hole 232 which penetrates to the outer side of the material receiving hopper 2 and is connected with the extrusion column 61 in a sliding manner is formed in the center of the top end in the sliding pipe 23; the extrusion column 61 penetrates out through the sliding through hole 232; an open groove 33 for accommodating the extrusion column 61 is formed at the upper end of the inner wall of the feeding trough 3; the lower end of the sliding pipe 23 is fixedly connected with an end cover 8 for closing the lower end of the sliding pipe 23; a positioning through groove 81 in sliding connection with the stop plate 62 is formed in the non-central position of the upper end of the end cover 8; a spring 9 for sliding the sliding column 6 upwards is arranged between the sliding column 6 and the end cover 8.

In a storage state, the storage bottle 1 and the feeding trough 3 are coaxially arranged, at the moment, the extrusion column 61 is not in contact with the inner wall of the feeding trough 3, the extrusion column 61 is located at a limit position far away from the stopping hemisphere 7, the stopping plate 62 is not in contact with the stopping hemisphere 7, and the storage bottle 1 can feed materials to the closed cavity; the inclination angle of the water storage bottle 1 is adjusted to enable the stop block 52 to be located outside the stop groove 71, and then the gate disk 5 is rotated to enable the gate 51 to be communicated with the water outlet 41 or the grain outlet 42, so that grains or water in the water storage bottle 1 enter the receiving hopper 2.

Under the state of feeding, storage bottle 1 with feeding trough 3 is perpendicular, this moment the squeeze column 61 with the 3 inner walls in feeding trough offset, squeeze column 61 is located and is close to the extreme position of locking hemisphere 7, stop plate 62 can restrict the circumferential direction of locking hemisphere 7, closed cavity can to feeding trough 3 is reinforced, and then can make locking hemisphere 7 restriction the rotation of stop block 52 prevents when feeding, the unexpected rotation of gating dish 5 causes the revealing of water or grain.

A rotating through groove 22 which penetrates to the outside and is in sliding connection with the shifting block 53 is formed in the inner wall of the receiving hopper 2 and is close to the lower part; a clamping groove 531 is formed at the upper end of the shifting block 53; a clamping portion capable of blocking the movement of the clamping groove 531 is formed on the inner wall of the rotating through groove 22; the joint portion comprises a sealing clamping strip 221 capable of blocking the movement of the joint groove 531 and a plurality of discharging clamping strips capable of blocking the movement of the joint groove 531.

When the sealing clamping strip 221 is located in the clamping groove 531, the gating disc 5 seals each communication port; when the discharging clamping strip is positioned in the clamping groove 531, the selective opening 51 is communicated with the corresponding communication opening.

The number of the discharging clamping strips is two; the two discharging clamping strips are respectively a water discharging clamping strip 222 and a grain discharging clamping strip 223 which are positioned at two sides of the sealing clamping strip 221; when the grain outlet clamping strip 223 is positioned in the clamping groove 531, the grain selecting opening 51 is communicated with the grain outlet 42; when the water outlet clamping strip 222 is positioned in the clamping groove 531, the selection opening 51 is communicated with the water outlet 41; the gating disc 5 is rotated forwards or reversely until obvious resistance exists, and then water or grains are poured into the receiving hopper 2.

An external thread 13 is formed on the periphery of the storage bottle 1 close to the upper end; an inner convex head 25 capable of being in threaded connection with the external thread 13 is formed on the inner wall of the material receiving hopper 2 below the sealing disc 4.

The receiving hopper 2 is rotated reversely, so that the receiving hopper 2 is separated from the storage bottle 1, the receiving hopper 2 is removed, water or grains are supplemented to each bottle body, the storage bottle 1 can be filled with different grains or water according to different use scenes, and meanwhile, the storage bottle 1 can be reused, so that the cost is saved; the inner raised head 25 of the material receiving hopper 2 is placed in the outer thread 13, the material receiving hopper 2 is rotated in the forward direction, so that the material receiving hopper 2 is hermetically connected with the material storage bottle 1, the material storage bottle 1 can be carried about, and water can be fed to a baby at any time and any place.

Two coaxially arranged rotating columns 21 are symmetrically formed on the outer wall of the receiving hopper 2; two rotating holes 32 which can be rotatably connected with the corresponding rotating columns 21 are formed on the inner wall of the feeding trough 3.

In a feeding state, the outer wall of the storage bottle 1 is abutted against the inner wall of the feeding trough 3; the storage bottle 1 is positioned in the feeding trough 3, and the feeding trough 3 occupies a small space, is regular in appearance and convenient to carry and store.

A rope hanging lug 31 for installing a hanging rope is formed at the upper end of the feeding trough 3; rope hanging lug 31 can install the hanging rope, through carrying hold the hanging rope carries storage bottle 1, it is more convenient to carry. In the scheme, water can be replaced by other liquid foods, and grains can be granular foods such as biscuits, candies and the like.

In the initial state, the sealing clamping strip 221 is positioned in the clamping groove 531, the gating disc 5 seals the water outlet 41 and the grain outlet 42, and the extrusion column 61 is not in contact with the inner wall of the feeding groove 3.

When carrying the baby and going out, often need for baby's portable water and grain, when using this product, storage bottle 1 is held to the hand, and the reverse rotation connects hopper 2 to make and connects hopper 2 and storage bottle 1 separation, removes to connect hopper 2. Proper amount of grain and water are respectively added into the water storage bottle 11 and the grain storage bottle 12, the receiving hopper 2 is covered again, the receiving hopper 2 is rotated in the positive direction, so that the inner raised head 25 slides to the inner limit position along the external thread 13, and the receiving hopper 2 is connected with the material storage bottle 1 in a sealing way. Storage bottle 1 is located feeding trough 3, and occupation space is little, and the outward appearance is regular, can be convenient put into the package of hand-carrying, anytime and anywhere feeds the baby. The rotating shaft 73 of the stopping hemisphere 7 is positioned at one side near the outer edge, and the stopping hemisphere 7 can rotate under the action of gravity, so that the rotating shaft 73 is always positioned at the upper part of the stopping hemisphere 7. In the process of carrying the storage bottle 1, the stop block 52 can enter the stop groove 71, so that the rotation of the stop block 52, namely the rotation of the gating disk 5, is limited, and the water or grain leakage caused by the accidental rotation of the gating disk 5 in the carrying process can be prevented.

When feeding a baby, the storage bottle 1 is held by a hand, the storage bottle 1 is adjusted to the position below the receiving hopper 2 (as shown in fig. 10), the stop hemisphere 7 rotates under the action of gravity, so that the stop groove 71 rotates below the rotating shaft 73, the stop block 52 is positioned outside the stop groove 71, and the gate disc 5 can rotate circumferentially. The shifting block 53 is rotated forward, so that the water outlet clamping strip 222 enters the clamping groove 531, at this time, the gate opening 51 is communicated with the water outlet 41, and the water in the water storage bottle 11 sequentially enters the receiving hopper through the water outlet 41 and the gate opening 51 until the receiving hopper 2 is full of water. The shifting block 53 is rotated reversely, so that the sealing clamping strip 221 enters the clamping groove 531, and the gating disc 5 reseals the water outlet 41. Adjusting storage bottle 1 to connect hopper 2 to be located the top, the low-angle outwards rotates feeding trough 3 to the outside and offsets with 3 inner walls of feeding trough to squeeze column 61, and at this moment, 3 inner walls of feeding trough still seal discharge gate 24. And adjusting the material storage bottle 1 again until the material receiving hopper 2 is positioned below the material storage bottle, continuously rotating the feeding trough 3 outwards to the limit position, and enabling the feeding trough 3 to be relatively vertical to the material storage bottle 1. The discharge port 24 is no longer sealed by the inner wall of the feeding trough 3, and the water in the receiving hopper 2 flows into the feeding trough 3 through the discharge port 24, so that the water is fed to the baby.

In the process that the feeding trough 3 rotates to the limit position, the extrusion column 61 abuts against the inner wall of the feeding trough 3, so that the extrusion column 61 slides towards the stop hemisphere 7, the spring 9 is compressed, the stop plate 62 further slides towards the stop hemisphere 7, and the stop plate 62 can abut against the stop hemisphere 7. When the receiving hopper 2 is adjusted to the lower position again, the stop hemisphere 7 rotates to abut against the stop plate 62, so that the stop groove 71 cannot rotate to the lower part of the rotating shaft 73, the stop block 52 is still in the stop groove 71, and the gate disc 5 cannot rotate circumferentially, thereby preventing water or grain leakage caused by accidental rotation of the gate disc 5 in the feeding process (as shown in fig. 11).

After feeding is completed, the feeding trough 3 is inclined, so that the residual water in the feeding trough 3 completely flows into the receiving hopper 2 through the discharge hole 24, then the feeding trough 3 is rotated inwards until the inner wall of the feeding trough 3 does not abut against the extrusion column 61 any more, and the discharge hole 24 is closed again by the inner wall of the feeding trough 3. The extrusion column 61 is not abutted against the inner wall of the feeding trough 3 any more, the stop plate 62 moves to the original position far away from the stop hemisphere 7 under the elastic force of the spring 9, the stop plate 62 cannot contact with the stop hemisphere 7, at this time, the receiving hopper 2 is positioned below, and the stop hemisphere 7 rotates to the position that the stop trough 71 is positioned below under the gravity action. The small-angle outward rotation feeding trough 3 makes the extrusion column 61 support tightly with feeding trough 3 inner wall, keeps feeding trough 3 sealed discharge gate 24 simultaneously, and extrusion column 61 slides to the direction that is close to locking hemisphere 7, and then makes locking plate 62 support tightly with locking hemisphere 7, and locking hemisphere 7 can not rotate. The storage bottle 1 is adjusted to be located above the feeding hopper 2 (as shown in fig. 12), the shifting block 53 is rotated in the forward direction, so that the water outlet clamping strip 222 enters the clamping groove 531, water in the receiving hopper 2 flows into the storage bottle 11 under the action of gravity, then the shifting block 53 is rotated in the reverse direction, so that the sealing clamping strip 221 enters the clamping groove 531, and the water outlet 41 is sealed again by the gating disc 5. The water recycling is increased, the water is not required to be supplemented repeatedly, the workload of a user is reduced, and time and labor are saved. Then, the feeding trough 3 is rotated inwards to be completely attached to the storage bottle 1, and the extrusion column 61 slides away from the stopping hemisphere 7 under the elastic force of the spring 9 and is no longer in contact with the inner wall of the feeding trough 3, so that the stopping plate 62 is no longer in contact with the stopping hemisphere 7. The stop hemisphere 7 rotates under the action of gravity until the stop block 52 enters the stop groove 71, and the stop hemisphere 7 limits the circumferential rotation of the gating disk 5, so that water and grain leakage is avoided.

Similarly, when feeding the baby with grain, the storage bottle 1 is adjusted to the receiving hopper 2 to be positioned below. The shifting block 53 rotates reversely, so that the grain discharging clamping strip 223 enters the clamping groove 531, the gate 51 is communicated with the grain discharging opening 42, and grains in the grain storage bottle 12 enter the material receiving hopper 2 until the material receiving hopper 2 is filled with grains. Forward rotation shifting block 53 for sealed card strip 221 enters into joint groove 531, adjusts the storage bottle 1 to connect hopper 2 to be located the top, and the low-angle outwards rotates feed trough 3 to squeeze column 61 and feed trough 3 inner wall to offset, adjusts storage bottle 1 again to connect hopper 2 to be located the below, continues to rotate feed trough 3 to extreme position outwards. The grain in the receiving hopper 2 flows into the feeding trough 3 through the discharge hole 24, and then the baby is fed.

After feeding is completed, the feeding trough 3 is inclined, so that the residual grains in the feeding trough 3 all flow into the receiving hopper 2 through the discharge port 24, then the feeding trough 3 is rotated inwards until the inner wall of the feeding trough 3 is not abutted against the extrusion column 61 any more, and the stop hemisphere 7 is rotated to the stop trough 71 under the action of gravity and is positioned below the stop trough. The low-angle outwards rotates feeding trough 3 and makes squeeze column 61 and 3 inner walls of feeding trough support tightly for stop plate 62 supports tightly with locking hemisphere 7, and adjustment storage bottle 1 is located the top to loading hopper 2, and reverse rotation shifting block 53 makes grain card strip 223 enter into joint groove 531 in, and the grain that connects in the hopper 2 flows into under the action of gravity in storing up grain bottle 12. Then, the shifting block 53 is rotated in the forward direction, so that the sealing clamping strip 221 enters the clamping groove 531, the feeding groove 3 is rotated inwards to be completely attached to the storage bottle 1, and the stopping hemisphere 7 is rotated to the stopping block 52 under the action of gravity to enter the stopping groove 71, so that water and grains are prevented from leaking.

When the baby goes out, the baby often needs to feed various foods, and the number of the grain storage bottles 12 in the product can be multiple. Through the different turned angle of control shifting block 53 for select opening 51 and different storage grain bottle 12 intercommunications, and then can pour out different kinds of food and feed the baby, simple and convenient.

According to the invention, the stopping hemisphere 7 is arranged, the rotating shaft 73 is positioned at the edge of the stopping hemisphere 7, the stopping hemisphere 7 can rotate around the rotating shaft 73 under the action of gravity to enable the stopping groove 71 to be positioned below the rotating shaft 73, the relative position of the charging hopper 2 and the storage bottle 1 is adjusted, when the stopping block 52 is positioned at the outer side of the stopping groove 71, the gating disc 5 can rotate circumferentially, and the gating disc 5 can seal the water outlet 41 and the grain outlet 42, so that the storage bottle 1 can be carried with one person, and can be used for feeding water at any time and any place; when the stop block 52 is positioned in the stop groove 71, the strobe disk 5 cannot rotate circumferentially, so that the strobe disk 5 can be prevented from accidentally rotating to cause water or grain leakage during carrying or feeding.

According to the invention, by arranging the feeding trough 3, the inner wall of the feeding trough 3 is attached to the water storage bottle 1 in a natural state, the occupied space is small, the carrying is convenient, when the feeding trough 3 rotates to be relatively vertical to the water storage bottle 1, grains or water in the material receiving hopper 2 enter the feeding trough 3, so that the baby is fed, and the baby is clean and sanitary; meanwhile, in the rotating process of the feeding trough 3, the extrusion column 61 can slide towards the direction close to the stop hemisphere 7, and then the stop plate 62 can abut against the stop hemisphere 7, so that the stop block 52 is kept in the stop trough 71, the circumferential rotation of the gating disc 5 is limited, the water or grain leakage caused by accidental rotation of the gating disc 5 in the feeding process is prevented, no new operation step is added, and the operation is simple and convenient.

According to the invention, by arranging the receiving hopper 2, when the sealing clamping strip 221 is positioned in the clamping groove 531, the selection opening 51 is not communicated with the grain outlet 42 and the water outlet 41, so that the receiving hopper 2 seals the water storage bottle 11 and the grain storage bottle 12, further, grains or water can be carried about by a baby, the diversified requirements of the baby are met, when the water outlet clamping strip 222 is positioned in the clamping groove 531, the selection opening 51 is communicated with the water outlet 41, water in the water storage bottle 11 can flow into the receiving hopper 2, further, the water or the grains can enter the feeding groove 3 for feeding, and the amount of the water or the grains entering the receiving hopper 2 is fixed, further, the feeding amount of the baby can be controlled, and the healthy growth of the baby is facilitated; when the grain discharging clamping strip 223 is positioned in the clamping groove 531, the selection opening 51 is communicated with the grain discharging opening 42, and water in the grain storage bottle 12 can flow into the receiving hopper 2 and further can enter the feeding groove 3 for feeding; through rotating the gating disc 5, water and grains in the storage bottle enter the feeding trough 3 respectively to feed, and the operation is simple and convenient.

The baby feeder is convenient to carry, small in occupied space, regular in appearance and convenient to carry when the feeding trough and the storage bottle are combined, and can feed babies anytime and anywhere; the multifunctional infant food box can contain various infant grains and water, can meet the requirements of different infants on different foods when the infants are carried outdoors, and is simple and convenient; the invention can prevent accidental leakage, and the gating disc can be rotated only when the stop block is positioned outside the stop groove, so that grains or water can be poured out, and waste is avoided; the feeding amount of the baby can be controlled, the volume of the materials entering the closed cavity is the same, and the feeding amount of the baby can be controlled; the invention can recover water and grain, and the water and grain which are not used up can be stored back in the grain storage bottle, the operation is simple and convenient, the workload is reduced, and the time and the labor are saved.

Claims (10)

1. An infant feeding bottle characterized in that: comprises a storage bottle, a receiving hopper detachably connected with the upper end of the storage bottle and a feeding trough horizontally arranged on a rotating shaft rotatably connected with the periphery of the receiving hopper; a discharge hole for feeding the feeding trough is formed in one side, close to the feeding trough, of the receiving hopper; the storage bottle consists of a plurality of bottles for containing water and different kinds of grains; the lower part in the material receiving hopper is fixedly connected with a sealing disc capable of sealing each bottle body; a plurality of communicating ports which can be communicated with the corresponding bottle bodies are formed at the upper end of the sealing disc; a gating disc capable of closing each communication port is rotatably connected to the upper end of the sealing disc in the material receiving hopper; and the upper end of the gating disc is provided with a gating port which can be respectively communicated with the communicating ports.

2. An infant feeding bottle as defined in claim 1, wherein: a shifting block is formed on the periphery of the gating disc and positioned on the outer side of the material receiving hopper; a stop block is formed in the center of the upper end of the gating disc; a stop hemisphere with a rotating shaft parallel to the rotating shaft of the feeding trough is rotatably connected above the stop block in the material receiving hopper; the stop hemisphere can circumferentially rotate under the action of gravity; a stop groove capable of being inserted into the stop block is formed in the periphery of the stop hemisphere; when the stop block is positioned in the stop groove, the gating disc cannot rotate and seals each communication port; when the stop block is positioned outside the stop groove, the gating disc can rotate circumferentially, and the bottle body communicated with the gating opening can discharge materials to the material receiving hopper.

3. An infant feeding bottle as defined in claim 2, wherein: the discharge hole can be closed by the feeding trough, so that a closed cavity for quantitative feeding is formed in the receiving hopper.

4. An infant feeding bottle as defined in claim 3, wherein: the upper part of the receiving hopper is longitudinally and slidably connected with a sliding column capable of limiting the circumferential rotation of the stopping hemisphere; a stop plate capable of abutting against the stop hemisphere is formed at the lower end of the sliding column; and an extrusion column which can be tightly abutted against the inner wall of the feeding trough is formed at the upper end of the sliding column.

5. An infant feeding bottle as defined in claim 4, wherein: in a storage state, the storage bottle and the feeding trough are coaxially arranged, the extrusion column is not in contact with the inner wall of the feeding trough at the moment, the extrusion column is located at a limit position far away from the stop hemisphere, the stop plate is not in contact with the stop hemisphere, and the storage bottle can feed materials to the closed cavity; under the feeding state, the storage bottle with the feeding trough is perpendicular, this moment the squeeze column with the feeding trough inner wall offsets, the squeeze column is located near the extreme position of locking hemisphere, the locking plate can restrict the circumferential direction of locking hemisphere, closed cavity can to the feeding trough is reinforced.

6. An infant feeding bottle as defined in claim 2, wherein: a rotating through groove which penetrates through the inner wall of the material receiving hopper and is connected with the shifting block in a sliding manner is formed in the inner wall of the material receiving hopper; a clamping groove is formed at the upper end of the shifting block; a clamping part capable of blocking the motion of the clamping groove is formed on the inner wall of the rotating through groove; the clamping part comprises a sealing clamping strip capable of blocking the motion of the clamping groove and a plurality of discharging clamping strips capable of blocking the motion of the clamping groove; when the sealing clamping strip is positioned in the clamping groove, the gating disc seals each communication port; when the discharging clamping strip is positioned in the clamping groove, the selective opening is communicated with the corresponding communication opening.

7. An infant feeding bottle as defined in claim 2, wherein: an external thread is formed on the periphery of the storage bottle close to the upper end; and an inner convex head which can be in threaded connection with the external thread is formed on the inner wall of the material receiving hopper below the sealing plate.

8. An infant feeding bottle as defined in claim 4, wherein: two coaxially arranged rotating columns are symmetrically formed on the outer wall of the material receiving hopper; two rotating holes which can be rotatably connected with the corresponding rotating columns are formed in the inner wall of the feeding trough; and in the feeding state, the outer wall of the storage bottle is abutted to the inner wall of the feeding trough.

9. An infant feeding bottle as defined in claim 2, wherein: and a rope hanging lug for installing a hanging rope is formed at the upper end of the feeding groove.

10. An infant feeding bottle characterized in that: comprises a storage bottle, a receiving hopper detachably connected with the upper end of the storage bottle and a feeding trough horizontally arranged on a rotating shaft rotatably connected with the periphery of the receiving hopper; a discharge hole for feeding the feeding trough is formed in one side, close to the feeding trough, of the receiving hopper; the storage bottle consists of a plurality of bottles for containing water and different kinds of grains; the lower part in the material receiving hopper is fixedly connected with a sealing disc capable of sealing each bottle body; a plurality of communicating ports which can be communicated with the corresponding bottle bodies are formed at the upper end of the sealing disc; a gating disc capable of closing each communication port is rotatably connected to the upper end of the sealing disc in the material receiving hopper; a gating port which can be respectively communicated with each communication port is formed at the upper end of the gating disc; a shifting block is formed on the periphery of the gating disc and positioned on the outer side of the material receiving hopper; a stop block is formed in the center of the upper end of the gating disc; a stop hemisphere with a rotating shaft parallel to the rotating shaft of the feeding trough is rotatably connected above the stop block in the material receiving hopper; the stop hemisphere can circumferentially rotate under the action of gravity; a stop groove capable of being inserted into the stop block is formed in the periphery of the stop hemisphere; when the stop block is positioned in the stop groove, the gating disc cannot rotate and seals each communication port; when the stop block is positioned outside the stop groove, the gating disc can rotate circumferentially, and the bottle body communicated with the gating opening can discharge materials to the material receiving hopper.

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