CN113171008A - Milk mixing device - Google Patents

Abstract

The invention relates to a milk mixing device, which comprises a shell and a quantitative milk powder device, wherein milk powder is arranged in a milk powder storage cavity of the shell, and a milk bottle is arranged below a powder leakage hole when milk powder is mixed. The milk powder piece is arranged on the bottom wall of the milk powder storage cavity, the quantitative powder storage hole is formed in the milk powder piece, and milk powder in the milk powder storage cavity can be filled into the quantitative powder storage hole. The driving piece drives the milk powder piece to move so that the quantitative powder storage hole moves to a position corresponding to the powder leakage hole and is communicated with the powder leakage hole, and the milk powder in the quantitative powder storage hole can fall into the feeding bottle through the powder leakage hole. Scrape whitewashed piece and set up in the top of hourglass powder hole, and scrape whitewashed piece subsides and locate milk powder piece dorsad in the surface in hourglass powder hole, after quantitative storage powder hole and hourglass powder hole intercommunication on milk powder piece, scrape whitewashed piece and cover quantitative storage powder hole, avoid storing up the milk powder in the milk powder intracavity and leak into the feeding bottle by hourglass powder hole through quantitative storage powder hole, make after quantitative storage powder hole and hourglass powder hole intercommunication, only store in the milk powder of quantitative storage powder downthehole can enter into the feeding bottle, realize the automatic ration of milk powder and add.

Description

Milk mixing device

Technical Field

The invention relates to the technical field of milk powder brewing structures, in particular to a milk mixing device.

Background

For families with infants, the brewing of milk powder is a very troublesome task. Especially at night, it is often necessary to brew milk powder overnight. According to the traditional mode, automatic milk powder brewing is realized by arranging an automatic milk powder brewing device, so that the complicated steps in the brewing process are reduced. However, since the conventional automatic milk powder brewing apparatus generally requires workers to mix the amount of milk powder in advance, only the milk powder needs to be mixed with water during the brewing process, thereby reducing the trouble of brewing the milk powder in the middle of the night. However, the amount of milk powder to be brewed needs to be prepared before the milk powder is brewed, and the brewing process is still complicated.

Disclosure of Invention

In view of the above, there is a need to provide a milk mixing device that reduces the complexity of the brewing process.

A milk mixing device comprises a shell and a quantitative milk powder device, wherein a milk powder storage cavity is formed in the shell, and a powder leakage hole is formed in the bottom wall of the milk powder storage cavity; quantitative milk powder ware includes driving piece, milk powder spare and scrapes powder spare, milk powder spare set up in store up on the diapire in milk powder chamber and can cover the hole that leaks whitewashed, milk powder spare on seted up with the quantitative storage powder hole that stores up the milk powder chamber and be linked together, scrape powder spare set up in the top in hole that leaks whitewashed, just scrape powder spare subside locate milk powder spare dorsad in the hole that leaks whitewashed is surperficial, the driving piece is used for the drive milk powder spare activity, so that the ration store up whitewashed hole activity extremely with the position that the hole that leaks whitewashed corresponds and with the hole intercommunication leaks whitewashed, it can cover to scrape powder spare the quantitative storage powder hole.

In one embodiment, the number of the quantitative powder storing holes is at least two, the quantitative powder storing holes are arranged at intervals, and the driving part is used for driving the milk powder part to move, so that different quantitative powder storing holes respectively move to positions corresponding to the powder leaking holes and are communicated with the powder leaking holes.

In one embodiment, the driving member is used for driving the milk powder piece to rotate around a rotation axis, the quantitative powder storing holes are arranged at intervals around the rotation axis of the milk powder piece, and a single quantitative powder storing hole can rotate around the rotation axis to a position corresponding to the powder leaking hole and is communicated with the powder leaking hole.

In one embodiment, the milk powder piece is of a disc-shaped structure, each quantitative powder storage hole is arranged around the center of the disc-shaped milk powder piece, and the rotation axis of the milk powder piece passes through the center of the disc-shaped milk powder piece; and/or

Scrape whitewashed piece and be sheet structure, just the lower surface subsides of scraping whitewashed piece are located milk powder piece dorsad in leak whitewashed hole on the surface, just the size of scraping whitewashed piece is greater than quantitative storage powder hole is located milk powder piece upper surface open-ended size, so that scrape whitewashed piece and can cover completely quantitative storage powder hole.

In one embodiment, the size of the opening of the powder leakage hole on the bottom wall of the powder storage cavity is larger than or equal to the size of the opening of the quantitative powder storage hole towards the bottom wall of the powder storage cavity, and the opening of the quantitative powder storage hole on the lower surface of the powdered milk piece can move completely to the opening of the powder leakage hole on the bottom wall of the powder storage cavity.

In one embodiment, a first placing space is formed on the side wall of the casing, the milk powder storage cavity is located above the first placing space and is communicated with the first placing space through the powder leakage hole, and the first placing space is used for placing a feeding bottle.

In one embodiment, the milk mixing device further comprises a sterilizing member disposed on the top wall of the first placing space, and the sterilizing member is used for sterilizing the feeding bottle.

In one embodiment, the milk mixing device further comprises an electric kettle and a water pump, a second placing space is further formed on the housing, the electric kettle is arranged in the second placing space, the water pump is arranged on the housing, and the water pump is used for pumping water in the electric kettle into the feeding bottle in the first placing space; or

The water pump is further included, a second placing space is formed in the shell, and the second placing space is used for placing the electric kettle; the water pump is arranged on the shell and used for pumping water in the electric kettle into the feeding bottle in the first placing space; or

The water bottle is characterized by further comprising a water pump, a second placing space is formed in the shell, a heating element is arranged in the second placing space and used for placing a water bottle, the heating element is used for heating water in the water bottle, and the water pump is used for pumping water in the water bottle into the feeding bottle in the first placing space.

In one embodiment, a fan is arranged on the shell and used for blowing air to the second placing space; and/or

The water pump is characterized in that a control switch is arranged on the outer wall of the shell, the driving piece and the water pump are electrically connected to the control switch, and the control switch is used for controlling the driving piece and the water pump to be started.

In one embodiment, a human body induction lamp is arranged on the outer wall of the shell.

The milk mixing device arranges the milk powder in the milk powder storage cavity of the shell, and when the milk powder is required to be mixed, the milk bottle is arranged below the milk leaking hole. Because the milk powder piece is arranged on the bottom wall of the milk powder storage cavity, and the quantitative milk powder storage hole is formed in the milk powder piece, the milk powder in the milk powder storage cavity can be filled into the quantitative milk powder storage hole. The driving part is utilized to drive the milk powder part to move so that the quantitative powder storage hole moves to the position corresponding to the powder leakage hole and is communicated with the powder leakage hole, and then the milk powder in the quantitative powder storage hole can fall into the feeding bottle through the powder leakage hole. And the powder scraping piece is arranged above the powder leakage hole and is attached to the surface of the milk powder piece, which is back to the powder leakage hole, so that after the quantitative powder storage hole in the milk powder piece is communicated with the powder leakage hole, the quantitative powder storage hole can be covered by the powder scraping piece, and the milk powder in the milk powder storage cavity is prevented from leaking into the milk bottle from the powder leakage hole through the quantitative powder storage hole. After the quantitative powder storage hole is communicated with the powder leakage hole, only the milk powder stored in one quantitative powder storage hole can enter the feeding bottle, so that the automatic quantitative addition of the milk powder is realized, and the milk powder amount is not required to be manually proportioned before brewing.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention and not to limit the invention.

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Furthermore, the drawings are not to scale of 1:1, and the relative dimensions of the various elements in the drawings are drawn only by way of example and not necessarily to true scale. In the drawings:

FIG. 1 is a schematic diagram of a milk preparing apparatus according to an embodiment;

FIG. 2 is a cross-sectional view of the milk preparing device shown in FIG. 1;

FIG. 3 is a schematic view of the milk preparing apparatus shown in FIG. 1 from another perspective;

FIG. 4 is a schematic view of the powdered milk component and the powder scraping component shown in FIG. 3;

fig. 5 is a schematic view of the milk preparing apparatus shown in fig. 1 from a further perspective.

Description of reference numerals:

10. the milk mixing device comprises a milk mixing device body 100, a shell body 110, a milk powder storage cavity 120, a powder leakage hole 130, a limiting column 140, a first placing space 150, a second placing space 200, a quantitative milk powder device 210, a driving part 220, a milk powder part 221, a quantitative powder storage hole 222, a powder fixing part 223, a connecting part 224, a connecting hole 230, a powder scraping part 232, a limiting hole 300, an electric kettle 400, a water pump 500, a control switch 20 and a milk bottle.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

Referring to fig. 1 and 2, the milk mixing device 10 according to an embodiment of the present invention can at least effectively reduce the complexity of making milk powder. Specifically, the milk mixing device 10 includes a housing 100 and a quantitative milk powder container 200, wherein a milk powder storage cavity 110 is formed on the housing 100, and a powder leakage hole 120 is formed on the bottom wall of the milk powder storage cavity 110; quantitative milk powder ware 200 includes driving piece 210, milk powder piece 220 and scrapes powder piece 230, milk powder piece 220 is last to have seted up quantitative storage powder hole 221, milk powder piece 220 set up in store up on the diapire of milk powder chamber 110 and can cover leak powder hole 120, scrape powder piece 230 set up in leak powder hole 120's top, just scrape powder piece 230 paste locate milk powder piece 220 dorsad in leak powder hole 120's on the surface, driving piece 210 is used for the drive milk powder piece 220 activity, so that quantitative storage powder hole 221 activity extremely with leak the position that powder hole 120 corresponds and with leak powder hole 120 intercommunication, it can cover to scrape powder piece 230 quantitatively store up powder hole 221.

The milk mixing device 10 arranges the milk powder in the milk powder storage cavity 110 of the housing 100, so that the feeding bottle 20 is arranged below the powder leakage hole 120 when the milk powder needs to be mixed. Since the milk powder piece 220 is disposed on the bottom wall of the milk powder storage cavity 110 and the milk powder piece 220 is provided with the quantitative powder storage hole 221, the milk powder in the milk powder storage cavity 110 can be filled into the quantitative powder storage hole 221. The driving member 210 drives the milk powder component 220 to move, so that the quantitative powder storage hole 221 moves to a position corresponding to the powder leakage hole 120 and is communicated with the powder leakage hole, and the milk powder in the quantitative powder storage hole 221 can fall into the feeding bottle 20 through the powder leakage hole 120. Moreover, since the powder scraping member 230 is disposed above the powder leaking hole 120, and the powder scraping member 230 is attached to the surface of the milk powder member 220 opposite to the powder leaking hole 120, when the quantitative powder storing hole 221 is communicated with the powder leaking hole 120, the quantitative powder storing hole 221 can be covered by the powder scraping member 230, so as to prevent the milk powder in the milk powder storing cavity 110 from leaking into the feeding bottle 20 from the powder leaking hole 120 through the quantitative powder storing hole 221. By the quantitative milk powder device 200, after the quantitative milk powder storage hole 221 is communicated with the milk powder leakage hole 120, only the milk powder stored in the quantitative milk powder storage hole 221 can enter the milk bottle 20, so that the automatic quantitative adding of the milk powder is realized, and the amount of the milk powder does not need to be manually proportioned before brewing.

When the quantitative powder storage hole 221 is not communicated with the powder leakage hole 120, the powdered milk piece 220 can cover the powder leakage hole 120, so that the powdered milk is prevented from leaking through the powder leakage hole 120.

In one embodiment, the size of the opening of the powder leakage hole 120 on the bottom wall of the powder storage cavity 110 is greater than or equal to the size of the opening of the quantitative powder storage hole 221 towards the bottom wall of the powder storage cavity 110, and the opening of the quantitative powder storage hole 221 on the lower surface of the powdered milk piece 220 can move completely until the powder leakage hole 120 is located in the opening of the bottom wall of the powder storage cavity 110. Specifically, the diameter of the powder leakage hole 120 is greater than or equal to the diameter of the quantitative powder storage hole 221, and the quantitative powder storage hole 221 can be completely overlapped and communicated with the powder leakage hole 120. After the quantitative powder storage hole 221 is communicated with the powder leakage hole 120, the milk powder in the quantitative powder storage hole 221 can fall into the feeding bottle 20 from the powder leakage hole 120, and the milk powder entering the feeding bottle 20 is prevented from being influenced by the residual milk powder in the quantitative powder storage hole 221.

In the present embodiment, the powder leakage hole 120 is a circular hole. The quantitative powder storage hole 221 is a circular hole. After the quantitative powder storage hole 221 is communicated with the powder leakage hole 120, the quantitative powder storage hole 221 and the powder leakage hole 120 are coaxially arranged to ensure that the quantitative powder storage hole 221 is completely communicated with the powder leakage hole 120. In other embodiments, the powder leakage hole 120 may also be a tapered hole, the smaller part of the tapered hole faces the feeding bottle 20, the larger part is located on the bottom wall of the milk powder storage chamber 110, and the communication part of the quantitative powder storage hole 221 and the powder leakage hole 120 can be located completely inside the powder leakage hole 120. Or the powder leakage hole 120 may have other shapes, the quantitative powder storage hole 221 and the powder leakage hole 120 may have the same or different shapes, as long as it can ensure that after the powder leakage hole 120 is communicated with the quantitative powder storage hole 221, the quantitative powder storage hole 221 can completely enter the aperture of the powder leakage hole 120, so that the whole milk powder in the quantitative powder storage hole 221 can fall into the feeding bottle 20 through the powder leakage hole 120.

In one embodiment, one metered powder storage hole 221 may hold 15 grams of powdered milk. In other embodiments, one quantitative powder storage hole 221 may also contain 5 g of milk powder, 10 g of milk powder, 20 g of milk powder, etc. When the quantitative powder storage hole 221 can contain 15 g of milk powder and the amount of milk powder to be brewed is 45 g of milk powder, the powder leakage hole 120 and the quantitative powder storage hole 221 can be communicated for three times, so that the milk powder in the three quantitative powder storage holes 221 enters the feeding bottle 20, and the proper proportion of the mixed milk powder and water is ensured. In this embodiment, the control of the amount of the milk powder contained in the single quantitative powder storage hole 221 is realized by controlling the aperture size and the depth size of the quantitative powder storage hole 221.

Referring to fig. 2, 3 and 4, in an embodiment, the number of the quantitative powder storage holes 221 is at least two, the quantitative powder storage holes 221 are arranged at intervals, and the driving member 210 is configured to drive the milk powder component 220 to move, so that the different quantitative powder storage holes 221 respectively move to positions corresponding to the powder leakage holes 120 and are communicated with the powder leakage holes 120. The efficiency of adding the milk powder into the milk bottle 20 through the leakage hole 120 by the quantitative powder storage hole 221 is improved by providing at least two quantitative powder storage holes 221.

Specifically, the driving member 210 is configured to drive the milk powder component 220 to rotate around a rotation axis, each quantitative powder storage hole 221 is spaced around the rotation axis of the milk powder component 220, and each quantitative powder storage hole 221 can rotate around the rotation axis to a position corresponding to the powder leakage hole 120 and is communicated with the powder leakage hole 120. In the process that the driving member 210 drives the milk powder component 220 to rotate, the quantitative powder storage hole 221 rotated to the position communicated with the powder leakage hole 120 is covered by the powder scraping component 230, so that the milk powder in the quantitative powder storage hole 221 is added into the feeding bottle 20, when the quantitative powder storage hole 221 is rotated away from the position communicated with the powder leakage hole 120, the milk powder in the milk powder storage cavity 110 can automatically fill the quantitative powder storage hole 221, and the other quantitative powder storage hole 221 adjacent to the quantitative powder storage hole 221 can be rotated to the position communicated with the powder leakage hole 120, so as to improve the efficiency of adding the milk powder into the feeding bottle 20.

In this embodiment, the milk powder member 220 has a disc-shaped structure, each quantitative powder storage hole 221 is disposed around a center of the disc-shaped milk powder member 220, and a rotation axis of the milk powder member 220 passes through the center of the disc-shaped milk powder member 220. Through setting up milk powder piece 220 to discoid structure, the driving piece 210 drive milk powder piece 220 of being convenient for rotates steadily, and then guarantees that each ration stores up powder hole 221 homoenergetic and communicates with the hourglass powder hole 120 steadily.

In other embodiments, the powdered milk component 220 may have other shapes, and the driving member 210 may be used to drive the powdered milk component 220 to move on the bottom wall of the powdered milk storage cavity 110, so that the quantitative powder storage hole 221 can move to a position communicating with the powder leakage hole 120. When the quantitative powder storage hole 221 is not communicated with the powder leakage hole 120, the powder leakage hole 120 is covered by the milk powder piece 220, so that the milk powder is prevented from leaking out of the powder leakage hole 120 when the quantitative powder storage hole 221 is not communicated with the powder leakage hole 120.

In one embodiment, the milk powder component 220 includes a powder fixing portion 222 and a connecting portion 223 disposed on the powder fixing portion 222, the quantitative powder storage hole 221 is opened on the powder fixing portion 222, and the driving component 210 is disposed on the casing 100 and connected to the connecting portion 223, so as to drive the powder fixing portion 222 to move through the connecting portion 223.

Specifically, a connecting hole 224 is formed in the connecting portion 223, the driving shaft of the driving member 210 is inserted into the connecting hole 224, and the driving member 210 drives the powder fixing portion 222 to rotate through the connecting portion 223. Further, the connecting hole 224 is a non-circular hole, and the portion of the driving shaft penetrating through the connecting hole 224 is matched with the size of the connecting hole 224, so that the driving part 210 is ensured to drive the connecting part 223 to drive the powder fixing part 222 to be stable.

In one embodiment, the powder scraping member 230 is fixed in the powder storing cavity 110, so as to ensure the stability of covering the quantitative powder storing hole 221 by the powder scraping member 230. Specifically, the powder scraping member 230 is provided with a limiting hole 232, a limiting post 130 is arranged in the milk powder storage cavity 110, and the limiting post 130 penetrates through the limiting hole 232 to limit the position of the powder scraping member 230 in the milk powder storage cavity 110. Further, the limiting hole 232 is a non-circular hole, the limiting column 130 is a non-circular cylinder, and the size of the limiting column 130 is matched with that of the limiting hole 232. In another embodiment, a limiting hole 232 can be formed in the milk powder storage cavity 110, and the powder scraping piece 230 is provided with a limiting column 130.

In an embodiment, the powder scraping member 230 is a sheet structure, the lower surface of the powder scraping member 230 is attached to the surface of the milk powder member 220 opposite to the powder leaking hole 120, and the size of the powder scraping member 230 is larger than the size of the opening on the upper surface of the milk powder member 220 of the quantitative powder storing hole 221, so that the powder scraping member 230 can completely cover the quantitative powder storing hole 221. The quantitative powder storage hole 221 is conveniently and effectively covered by the powder scraping piece 230, and after the quantitative powder storage hole 221 is communicated with the powder leakage hole 120, milk powder above the quantitative powder storage hole 221 can be effectively scraped by the powder scraping piece 230, so that only the milk powder in the quantitative powder storage hole 221 can enter the feeding bottle 20 through the powder leakage hole 120.

In this embodiment, when the driving member 210 drives the milk powder component 220 to move so that the quantitative powder storage hole 221 starts to communicate with the powder leakage hole 120, the powder scraping component 230 completely covers the quantitative powder storage hole 221, and the powder scraping component 230 does not release the coverage of the quantitative powder storage hole 221 until the quantitative powder storage hole 221 does not communicate with the powder leakage hole 120.

Referring to fig. 1, fig. 2 and fig. 5, in an embodiment, a first placing space 140 is formed on a side wall of the housing 100, the milk powder storage cavity 110 is located above the first placing space 140, the milk powder storage cavity 110 is communicated with the first placing space 140 through the powder leakage hole 120, and the first placing space 140 is used for placing the feeding bottle 20. When in use, the feeding bottle 20 can be arranged in the first placing space 140, and the first placing space 140 provides a placing position for the feeding bottle 20, so that the feeding bottle 20 is aligned with the powder leakage hole 120.

Specifically, a limiting clamp is arranged in the first placing space 140, and the feeding bottle 20 is arranged in the first placing space 140 and can be clamped on the limiting clamp. When the feeding bottle 20 is clamped on the stopper clip, the mouth of the feeding bottle 20 can be aligned with the powder leakage hole 120. Alternatively, a limiting groove may be formed on the bottom wall of the first placing space 140, and the feeding bottle 20 can be placed in the limiting groove to ensure that the mouth of the feeding bottle 20 can be aligned with the powder leaking hole 120.

In one embodiment, the milk mixing device 10 further comprises a sterilizing member (not shown) disposed on the top wall of the first accommodating space 140, and the sterilizing member is used for sterilizing the feeding bottle 20. In use, the feeding bottle 20 is placed in the first placing space 140, and the feeding bottle 20 can be sterilized by the sterilizing member before the powdered milk is added into the feeding bottle 20 through the powder leaking hole 120. In one embodiment, the sterilization member may be a sterilization lamp. Or the sterilizing member may be a heating member. Of course, the sterilizing member may be other members capable of sterilizing the baby bottle 20.

In one embodiment, the casing 100 includes a placing portion and a milk powder storing portion, the milk powder storing portion is disposed on the placing portion, the milk powder storing cavity 110 and the powder leaking hole 120 are formed on the milk powder storing portion, and the first placing space 140 is formed on the placing portion. Specifically, the milk powder storage part is detachably provided on the placing part. After use, the milk powder storage part can be detached from the placing part for cleaning. Because the milk powder storage part is not in direct contact with the brewed milk powder, the milk powder storage part does not need to be cleaned after the milk powder is brewed every time, and only needs to be cleaned regularly, so that the cleaning frequency can be reduced.

Referring to fig. 1 and 2, in an embodiment, the milk mixing device 10 further includes an electric kettle 300 and a water pump 400, the housing 100 further forms a second accommodating space 150, the electric kettle 300 is disposed in the second accommodating space 150, the water pump 400 is disposed on the housing 100, and the water pump 400 is used for pumping the water pump 400 in the electric kettle 300 into the milk bottle 20 in the first accommodating space 140. Specifically, the water pump 400 may be provided on a placing portion of the case 100 on which the second placing space 150 is formed. When the electric kettle 300 is used for heating water and milk powder needs to be mixed, the water pump 400 in the electric kettle 300 is driven into the feeding bottle 20 through the water pump 400.

In an embodiment, the milk mixing device 10 further includes a control element electrically connected to the water pump 400, so that the amount of milk powder can be mixed as required, the control element is used to control the inspiration time of the water pump 400, and further the amount of water entering the milk bottle 20 is controlled, thereby realizing quantitative water inlet and ensuring the mixing ratio of water and milk powder.

In another embodiment, the milk preparing device 10 further comprises a water pump 400, a second placing space 150 is formed on the housing 100, and the second placing space 150 is used for placing the electric kettle 300; the water pump 400 is disposed on the housing 100, and the water pump 400 is used for pumping the water pump 400 in the electric kettle 300 into the feeding bottle 20 in the first placing space 140. When in use, the electric kettle 300 can be placed in the second placing space 150, and after use, the electric kettle 300 can be taken out, so that water can be added or the electric kettle can be cleaned conveniently.

Specifically, the electric kettle 300 may be heated and then placed in the second placing space 150. Or the electric kettle 300 is placed in the second placing space 150 and is heated by connecting a power source with a connector in the second placing space 150.

In other embodiments, the milk mixing device 10 further includes a water pump 400, the housing 100 is formed with a second accommodating space 150, a heating component is disposed in the second accommodating space 150, the second accommodating space 150 is used for accommodating a water bottle, the heating component is used for heating water in the water bottle, and the water pump 400 is used for pumping the water pump 400 in the water bottle into the milk bottle 20 in the first accommodating space 140. When in use, water can be added into the kettle, and the heating element in the second placing space 150 is utilized to heat the water in the kettle.

In one embodiment, the milk mixing device 10 further comprises a temperature control element for controlling the temperature of the heated water in the electric kettle 300. When the temperature of the water in the electric kettle 300 is lower than the set temperature, the electric kettle 300 starts to heat, and when the temperature of the water is higher than the set temperature, the electric kettle 300 is controlled by the temperature control member to stop heating. Or in another embodiment the operation of the heating element is controlled by a temperature control element.

In one embodiment, a fan is disposed on the housing 100, and the fan is used for blowing air to the second placing space 150. Specifically, the fan is used for blowing air into the electric kettle 300 to accelerate the cooling degree of the water in the electric kettle 300. The electric kettle 300 heats water to boiling, and since the milk powder needs to be mixed with warm water, the temperature of the water in the electric kettle 300 can be reduced by the fan.

In one embodiment, a human body induction lamp is disposed on an outer wall of the housing 100. When the milk powder needs to be brewed at midnight, the human body induction lamp can illuminate, so that the milk powder can be brewed conveniently.

In an embodiment, a control switch 500 is disposed on an outer wall of the housing 100, the driving member 210 and the water pump 400 are both electrically connected to the control switch 500, and the control switch 500 is used for controlling the driving member 210 and the water pump 400 to start. When the control switch 500 is turned on, the driving member 210 drives the powdered milk member 220 to move so that powdered milk is added to the feeding bottle 20, and the water pump 400 drives the water pump 400 to feed the powdered milk into the feeding bottle 20. The milk is adjusted by one key through controlling the switch 500, and the complicated steps of adjusting the milk are further reduced.

The milk mixing device 10 can realize one-key milk mixing, is simple to operate, can realize quantitative milk powder adding, and ensures the mixing proportion of the milk powder. The milk mixing device 10 is small in size, clean, convenient and sanitary.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Claims (10)

1. A milk preparing device, characterized in that the milk preparing device comprises:

the milk powder storage device comprises a shell, wherein a milk powder storage cavity is formed in the shell, and a powder leakage hole is formed in the bottom wall of the milk powder storage cavity; and

quantitative milk powder ware, quantitative milk powder ware includes driving piece, milk powder spare and scrapes powder spare, milk powder spare set up in store up on the diapire in milk powder chamber and can cover the hole that leaks whitewashed, milk powder spare on seted up with store up the quantitative storage powder hole that milk powder chamber is linked together, scrape powder spare set up in the top in hole that leaks whitewashed, just scrape powder spare subside locate milk powder spare dorsad in the hole that leaks whitewashed is surperficial, the driving piece is used for the drive milk powder spare activity, so that the ration store up whitewashed hole activity extremely with the position that the hole that leaks whitewashed corresponds and with the hole intercommunication leaks whitewashed, it can cover to scrape powder spare the quantitative storage powder hole.

2. The milk mixing device as claimed in claim 1, wherein the number of the quantitative powder storing holes is at least two, each quantitative powder storing hole is arranged at an interval, and the driving member is used for driving the milk powder member to move, so that different quantitative powder storing holes respectively move to positions corresponding to the powder leaking holes and are communicated with the powder leaking holes.

3. The milk mixing device as claimed in claim 2, wherein the driving member is used for driving the milk powder piece to rotate around a rotation axis, each quantitative powder storing hole is arranged around the rotation axis of the milk powder piece at intervals, and a single quantitative powder storing hole can rotate around the rotation axis to a position corresponding to the powder leaking hole and is communicated with the powder leaking hole.

4. The milk mixing device as claimed in claim 3, wherein the milk powder member is a disc-shaped structure, each quantitative powder storing hole is arranged around the center of the disc-shaped milk powder member, and the rotation axis of the milk powder member passes through the center of the disc-shaped milk powder member; and/or

Scrape whitewashed piece and be sheet structure, just the lower surface subsides of scraping whitewashed piece are located milk powder piece dorsad in leak whitewashed hole on the surface, just the size of scraping whitewashed piece is greater than quantitative storage powder hole is located milk powder piece upper surface open-ended size, so that scrape whitewashed piece and can cover completely quantitative storage powder hole.

5. The milk mixing device as claimed in any one of claims 1 to 4, wherein the opening of the powder leaking hole on the bottom wall of the powder storage chamber has a size greater than or equal to the size of the opening of the quantitative powder storage hole towards the bottom wall of the powder storage chamber, and the opening of the quantitative powder storage hole on the lower surface of the powdered milk piece can move completely to the opening of the powder leaking hole on the bottom wall of the powder storage chamber.

6. The milk mixing device according to any one of claims 1 to 4, wherein a first placing space is formed on a side wall of the housing, the milk powder storage cavity is located above the first placing space, the milk powder storage cavity is communicated with the first placing space through the powder leakage hole, and the first placing space is used for placing a feeding bottle.

7. The milk mixing device as recited in claim 6, further comprising a sterilizing member disposed on a top wall of the first placing space, the sterilizing member being for sterilizing the feeding bottle.

8. The milk mixing device according to claim 6, further comprising an electric kettle and a water pump, wherein a second placing space is formed on the housing, the electric kettle is arranged in the second placing space, the water pump is arranged on the housing, and the water pump is used for pumping water in the electric kettle into the milk bottle in the first placing space; or

The water pump is further included, a second placing space is formed in the shell, and the second placing space is used for placing the electric kettle; the water pump is arranged on the shell and used for pumping water in the electric kettle into the feeding bottle in the first placing space; or

The water bottle is characterized by further comprising a water pump, a second placing space is formed in the shell, a heating element is arranged in the second placing space and used for placing a water bottle, the heating element is used for heating water in the water bottle, and the water pump is used for pumping water in the water bottle into the feeding bottle in the first placing space.

9. The milk preparing apparatus according to claim 8, wherein a fan is provided on the housing for blowing air to the second placing space; and/or

The water pump is characterized in that a control switch is arranged on the outer wall of the shell, the driving piece and the water pump are electrically connected to the control switch, and the control switch is used for controlling the driving piece and the water pump to be started.

10. The milk mixing device according to any one of claims 1-4, wherein a body-sensing light is provided on an outer wall of the housing.

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