KR20210032179A - Bottle warmer - Google Patents

Abstract

Disclosed is a baby bottle warmer. The baby bottle warmer of the present invention is configured to include a body, a heater, and an ultrasonic vibrator. The heater supplies steam to the inner space of the body. The ultrasonic vibrator forms a contact surface with the heater. Ultrasonic vibrations are transmitted to a liquid in a baby bottle and water in the heater to promote convective heat transfer.

Description

Bottle warmer {BOTTLE WARMER}

The present invention relates to a baby bottle warmer, and more particularly, to a baby bottle warmer for uniformly heating the baby bottle.

The most preferred method of breastfeeding is direct breastfeeding. However, if you are a working mom or are unable to breastfeed yourself, you should feed the expressed breast milk in a bottle. In the case of mature milk, it can be stored for about 4 hours at room temperature below 25℃. However, breast milk to be fed after 4 hours should be stored refrigerated or frozen to prevent spoilage.

The destruction of nutrients in breast milk begins at 40℃ and progresses rapidly from 45℃ or higher. If the expressed breast milk is heated in a microwave, the breast milk is not warmed evenly, causing burns to the baby as well as destroying the protein and vitamin components of the breast milk. Refrigerated and frozen breast milk should be heated to 40~45℃ or lower under the condition of uniformly heating the baby bottle, such as a bath, to prevent excessive nutrient destruction.

In this regard, Japanese Patent Application Publication No. 6397139 (hereinafter'Prior Document 1') discloses a baby bottle heating device.

The feeding bottle heating device of Prior Document 1 includes a body and a heating unit. The body holds the bottle and fluid (water). The heating unit is installed on the body to heat the fluid. The heat of the fluid is transferred to the bottle.

Since mold and bacteria easily reproduce in a humid environment, clean care is important for baby products with weak immunity. The feeding bottle heating device of Prior Literature 1 is cumbersome to fill and discard the fluid (water) in the body every day. In addition, the feeding bottle heating apparatus of Prior Literature 1 has a problem in that when the body falls on the table or falls below the table, the fluid is spilled to the outside.

The fluid in the body is heated by the heating unit and forms a circulating flow by natural convection. The fluid received heat energy from the heating unit rises in the body and transfers the heat energy to the baby bottle. The fluid whose temperature has been lowered falls within the body and receives heat energy from the heating unit again. Breast milk (milk, powdered milk) in the bottle also receives heat energy and forms a circulating flow in the bottle by natural convection.

The feeding bottle heating device of Prior Literature 1 heats the feeding bottle with a bath. Therefore, the breast milk in the baby bottle receives heat evenly from the surroundings, shows an even temperature overall, and can be stably heated.

It is desirable for the child to feed the child as much as he or she wants. In order to give your baby bottle on time when he wants it, you need to be able to quickly raise the temperature of the milk in the bottle. However, heat transfer by natural convection is a relatively slow form of heat transfer. Therefore, there is a need for a method capable of promoting convective heat transfer of the fluid that heats the baby bottle and the convective heat transfer of the breast milk (milk, powdered milk) in the baby bottle.

Japanese Registered Patent Publication No. 6397139 (Registration Date: 2018.09.07)

One problem to be solved of the present invention is to provide a feeding bottle warmer that increases the rate at which heat energy is transferred to breast milk (milk, milk powder) while stably heating breast milk (milk, powdered milk) in the feeding bottle by convective heat transfer of steam. Is in.

One problem to be solved of the present invention is to provide a baby bottle warmer that heats water to transfer heat energy to the baby bottle, while minimizing the risk of water spilling during the fall.

In the baby bottle warmer according to an embodiment of the present invention, ultrasonic vibration is transmitted to the liquid in the baby bottle and the water in the heater to promote convective heat transfer. Accordingly, while stably heating the breast milk (milk, powdered milk) in the baby bottle by convective heat transfer of steam, the rate at which heat energy is transferred to the breast milk (milk, powdered milk) can be improved.

A baby bottle warmer according to an embodiment of the present invention may include a body, the heater, and an ultrasonic vibrator.

The body may have an opening at the top.

The baby bottle may be inserted into the inner space of the body through the opening.

The heater may supply steam to the inner space.

The heater may contact the baby bottle.

The ultrasonic vibrator may form a contact surface with the heater.

The ultrasonic vibrator may generate ultrasonic vibration.

A hole may be formed at the lower end of the body.

The heater may include a seating plate, a receiving member, and a heating member.

The seating plate may cover the hole.

The baby bottle may be placed on the mounting plate.

The receiving member may be coupled under the seating plate.

The receiving member may contain water.

The heating member may heat water contained in the receiving member.

The ultrasonic vibrator may form a contact surface with the seating plate and the receiving member, respectively.

A first through hole may be formed in the mounting plate.

A second through hole may be formed in the receiving member.

The ultrasonic vibrator may form a contact surface with inner surfaces of the first through hole and the second through hole, respectively.

A plurality of holes through which steam passes may be formed in the seating plate.

The ultrasonic vibration may be transmitted to the steam passing through the holes to promote convective heat transfer in the inner space. Accordingly, the rate at which heat energy is transferred to breast milk (milk, powdered milk) can be improved.

The baby bottle warmer according to an embodiment of the present invention may be configured to include a bucket for storing water.

The bucket may be connected to the receiving member by a tube.

A water level sensor may be installed in the receiving member.

In order to maintain the water level of the receiving member, a valve may be installed in the tube to regulate the movement of water. Therefore, while heating water to transfer heat energy to the baby bottle, the risk of water spilling during conduction can be minimized.

The heater may be provided at the lower end of the body.

The heater and the ultrasonic vibrator may form a surface on which the baby bottle is placed.

A baby bottle warmer according to an embodiment of the present invention may be configured to include a plurality of rotating members.

The rotating members may be rotatably provided along the periphery of the opening.

The rotating members may rotate to block or open a space between the side surface of the baby bottle and the opening.

Each of the rotating members may include a core material and a deformable material.

The core material can be rotated in both directions by an actuator.

The deformable material may be attached to the core material.

The deformable material may be in close contact with the side surface of the baby bottle by rotation of the actuator.

The deformable materials may elastically deform and absorb the ultrasonic vibration.

The body may be configured to include an upper body and the lower body.

The upper body may form the opening.

The upper body may be coupled to the housing.

The lower body may form the inner space together with the upper body.

The lower body may be installed to be movable up and down in the housing.

The heater may be coupled to the lower body.

The heater may be provided at a lower end of the lower body.

The heater and the ultrasonic vibrator may form a surface on which the baby bottle is placed.

Long racks in the vertical direction may be coupled to the lower body.

The housing may be provided with a pinion, a motor and a guide member.

The pinion may engage the rack.

The motor may rotate the pinion.

The guide member may guide the vertical movement of the rack.

A protrusion may be formed on the rack.

The guide member may form a long guide groove in the vertical direction.

The protrusion may be inserted into the guide groove so as to move up and down.

According to an embodiment of the present invention, the ultrasonic vibration is transmitted to the liquid in the baby bottle and the water in the heater to promote convective heat transfer, so that the heating rate of the water in the heater and the convective heat transfer rate of the breast milk (milk, powdered milk) in the baby bottle can be increased. .

According to an embodiment of the present invention, the valve regulates water moving to the receiving member according to a signal from the water level sensor, so that the water level of the receiving member is kept constant, and water contained in the receiving member can be quickly heated.

According to an exemplary embodiment of the present invention, the water tank is connected to the receiving member by a tube, and only a small amount of water is moved to the receiving member by a valve, so that water from the bucket can be preserved without pouring out during fall.

According to an embodiment of the present invention, the ultrasonic vibration is transmitted to the steam passing through the holes to promote convective heat transfer of the steam in the inner space, so that the speed at which the heat energy of the steam is transferred to the baby bottle can be increased.

1 is a perspective view of a baby bottle warmer according to an embodiment of the present invention.
Figure 2 is a partial exploded perspective view of the baby bottle warmer of Figure 1;
3 and 4 are perspective views showing a state of use of the baby bottle warmer of FIG. 1.
Figure 5 is an exploded perspective view of the baby bottle warmer of Figure 1;
Figure 6 is a perspective cross-sectional view showing a state of use of the baby bottle warmer of Figure 1;
7 is a perspective view showing the housing, guide and cover of the baby bottle warmer of FIG. 1 omitted.
Figure 8 is a partial exploded perspective view of the baby bottle warmer of Figure 7;
Figure 9 is a bottom view of the rotating member of Figure 8;
Figure 10 is a plan view of the bottle warmer of Figure 3;
Figure 11 is a plan view of the baby bottle warmer of Figure 4;
12 is a partial cross-sectional view of the baby bottle warmer of FIG. 3.
13 is a partial perspective cross-sectional view of the baby bottle warmer of FIG. 3.
14 to 17 are perspective cross-sectional views showing the state of use of the baby bottle warmer of FIG.
18 is a partial enlarged view of the baby bottle warmer of FIG. 17;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of functions or configurations that are already known will be omitted in order to clarify the gist of the present invention.

1 is a perspective view of a baby bottle warmer 10 according to an embodiment of the present invention, and FIG. 2 is a partial exploded perspective view of the baby bottle warmer 10 of FIG. 1.

1 and 2, the baby bottle warmer 10 according to an embodiment of the present invention is a device that uniformly heats the baby bottle 1, holding the handle 710 and lifting the cover 700, The inside of the housing 400 is exposed. A body 100 is provided inside the housing 400.

3 and 4 are perspective views showing a state of use of the baby bottle warmer 10 of FIG. 1.

3 and 4, the user inserts the baby bottle 1 into the body 100. Thereafter, when the baby bottle warmer 10 is operated, the rotating member 300 is in close contact with the outer surface of the baby bottle 1. The rotating member 300 blocks the space between the side surface of the baby bottle 1 and the opening 111.

After that, steam is introduced into the body 100. Steam is blocked from leaking to the outside of the body 100 by the rotating member 300. The heat energy of the steam is uniformly transferred to the side of the baby bottle 1 within the body 100. Breast milk (milk powder, milk) inside the baby bottle 1 is uniformly heated by the thermal energy of steam under the rotating member 300.

5 is an exploded perspective view of the baby bottle warmer 10 of FIG. 1, and FIG. 6 is a perspective cross-sectional view showing a state of use of the baby bottle warmer of FIG. 1.

As shown in Fig. 5, the baby bottle warmer 10 according to an embodiment of the present invention includes a body 100, a heater 200, a rotating member 300, a housing 400, a guide 500, and a water bottle. Including 600, a cover 700, a first driving unit 800, a second driving unit 900, a control unit, an indicator 1000, a charger 1200, an ultrasonic vibrator 1300, and a temperature sensor 1400 It is composed of.

5 and 6, the housing 400 forms the exterior and skeleton of the baby bottle warmer 10. The housing 400 forms an opening hole 401 on the upper side. The housing 400 forms a cylindrical shape with an open top. The opening hole 401 is opened and closed by the cover 700. The user can move the cover 700 by holding the handle 710 of the cover 700.

As shown in FIG. 5, a plurality of mounting portions 410, a pair of guide members 420, and a pair of rails 430 are provided inside the housing 400.

In FIG. 5, the housing 400 is shown in a cross-sectional perspective view. It should be understood that the mounting portion 410, the guide member 420, and the rail 430, which are not shown in FIG. 5, are arranged in a symmetrical shape around the vertical center line CL of the housing 400.

5 and 6, the mounting portions 410 are portions that support the upper body 110. The mounting portions 410 are formed along the circumferential direction on the upper inner surface of the housing 400. Protrusions 411 are formed on the mounting portions 410. The protrusion 411 is inserted into the hole 112H of the seating portion 112.

The guide member 420 is a part that guides the vertical movement of the rack 910. The guide member 420 forms a long guide groove 421 in the vertical direction. A protrusion 911 inserted into the guide groove 421 is formed in the rack 910.

The rail 430 is a part that guides the vertical movement of the lower body 120. The rail 430 forms a long groove in the vertical direction. A slider 122 inserted into the groove of the rail 430 is formed on the outer surface of the lower body 120.

As shown in Figure 5, the housing 400 is formed with a mounting portion 450 to which the bucket 600 is mounted. The user can remove the water bottle 600 from the mounting part 450.

A lid 610 is formed in the bucket 600. The user can open the lid 610 and put water in the bucket 600. The water contained in the bucket 600 moves to the receiving member 220 through the tube 620. Water contained in the bucket 600 may move to the receiving member 220 by gravity.

3 to 5, the indicator 1000 visually displays the operating state of the baby bottle warmer (10). The indicator 1000 is coupled to the inner surface of the housing 400. Although not shown in detail, a groove into which the indicator 1000 is inserted is formed in the inner surface of the housing 400.

The housing 400 is made of a material that transmits light. The housing 400 may be made of transparent plastic. The inner or outer surface of the housing 400 may be painted with a paint that transmits light.

4 and 5, the indicator 1000 visually displays the operating state of the baby bottle warmer 10 by emitting an LED light. As shown in FIG. 5, the indicator 1000 includes an LED module 1010 and a shielding plate 1020.

A plurality of LEDs are mounted on the front of the LED module 1010. The control unit may be mounted on the LED module 1010. The control unit controls the blinking of multiple LEDs.

The shielding plate 1020 is coupled to the front surface of the LED module 1010. As shown in FIG. 5, holes corresponding to the shapes of numbers and symbols are formed in the shielding plate 1020. The light of the LED passes through the hole of the shielding plate 1020 and illuminates the inner surface of the housing 400.

As shown in FIG. 4, numbers and symbols corresponding to the hole shape of the shielding plate 1020 are displayed on the outer surface of the housing 400. The number displayed on the housing 400 may indicate the current temperature of breast milk (milk, milk) contained in the baby bottle 1. The symbol displayed on the housing 400 may mean a rate at which breast milk (milk powder, milk) reaches a target temperature.

A touch panel 1100 may be formed on the housing 400. The user may operate the baby bottle warmer 10 by pressing the touch panel 1100. The touch panel 1100 may display a power button (○), a temperature control button (△▽), a start button (▷), and a stop button (□). The touch panel 1100 is a known technology as disclosed in Korean Patent Application Laid-Open No. 2018-0076112, so a detailed description thereof will be omitted.

5, the housing 400 is mounted on the charger 1200. The charger 1200 may be provided as a wireless charger. A terminal 1210 to which external power is connected is formed in the charger 1200.

The charger 1200 charges a battery (not shown) of the baby bottle warmer 10 by electromagnetic induction or magnetic resonance. A primary coil generating an electromagnetic field may be installed in the charger 1200. A secondary coil for receiving an induced current may be installed at the lower end of the housing 400. Since the wireless charging technology is a known technology as disclosed in Korean Patent Application Publication No. 2019-0077836, a detailed description thereof will be omitted.

5 and 6, the body 100 forms a space in which the thermal energy of the steam is transmitted to the baby bottle body 1A (hereinafter,'internal space 101'). The body 100 forms an opening 111 at the top. The body 100 forms a cylindrical shape with an open top. The baby bottle 1 is inserted into the body 100 through the opening 111.

5 and 6, the body 100 is configured to include an upper body 110 and a lower body 120.

The upper body 110 forms an opening 111 at the top. The upper body 110 forms a cylindrical shape with open top and bottom. A seating portion 112 is formed at the upper end of the upper body 110.

The seating part 112 forms a shape extending radially from the upper end of the upper body 110. The seating portion 112 is seated on the upper surface of the mounting portion 410. The mounting portion 112 has a hole 112H into which the protrusion 411 of the mounting portion 410 is inserted.

The lower body 120 is installed in the housing 400 so as to move upwardly. The lower body 120 forms a cylindrical shape with an open top. A mounting portion 123 is formed inside the upper end of the lower body 120 along the circumferential direction.

Although not shown, a separate mounting plate may be mounted on the mounting part 123. When a separate mounting plate is mounted on the mounting part 123, a low-height baby bottle 1 or a baby food container can be placed on the upper surface of the separate mounting plate.

As shown in FIG. 5, a hole 121 is formed in the lower end of the lower body 120. The hole 121 is covered by the seating plate 210. The edge of the seating plate 210 is seated at the edge of the hole 121. The baby bottle 1 is placed on the upper surface of the seating plate 210.

As shown in FIG. 5, a first fastening part 124 and a second fastening part 125 are formed on the side of the lower body 120.

The first fastening portions 124 are portions to which the rack 910 is coupled. The first fastening parts 124 are provided in a pair. The first fastening parts 124 are formed on the outer surface of the lower body 120. The racks 910 are coupled to the first fastening portions 124 by bolts. Screw holes are formed in the first fastening portions 124. A hole into which a bolt is inserted is formed in the rack 910. The bolt is inserted into the hole and screwed into the screw hole.

As shown in FIG. 5, the second fastening portions 125 are portions to which the slider 122 is coupled. The second fastening parts 125 are provided in a pair. The second fastening parts 125 are formed on the outer surface of the lower body 120.

The sliders 122 are coupled to the second fastening portions 125 by bolts. Screw holes are formed in the second fastening parts 125. A hole into which a bolt is inserted is formed in the slider 122. The bolt is inserted into the hole and screwed into the screw hole.

The protrusion 911 of the rack 910 is inserted into the guide groove 421 of the guide member 420 so as to move upwardly. The slider 122 is inserted into the groove of the rail 430 of the rail 430 so as to move upwardly. Accordingly, the lower body 120 is installed in the housing 400 so as to move upwardly. The lower body 120 forms an inner space 101 together with the upper body 110.

In the body 100, the depth of the inner space 101 is adjusted by the vertical movement of the lower body 120. When the lower body 120 descends, the depth of the inner space 101 increases. When the lower body 120 rises, the depth of the inner space 101 decreases.

FIG. 7 is a perspective view of the baby bottle warmer of FIG. 1 in which the housing, guide, and cover are omitted.

As shown in FIGS. 5 to 7, the second driving unit 900 is configured to lift the lower body 120, and includes a rack 910, a pinion 920, and a motor 930.

5 and 7, the racks 910 are coupled to the side of the lower body 120. The rack 910 has teeth in the vertical direction. A mounting shaft 440 is formed in the housing 400. The pinion 920 is rotatably mounted on the mounting shaft 440.

The motor 930 is installed under the housing 400. The main gear 931 is mounted on the rotation shaft 811 of the motor 930. The main gear 931 meshes with the pinion 920. When the slider 122 is inserted into the groove of the rail 430, the protrusion 911 of the rack 910 is inserted into the guide groove 421 of the guide member 420. In this state, the rack 910 is engaged with the pinion 920.

Accordingly, the lower body 120 is installed in the housing 400 so as to move upwardly. The control unit controls the second driving unit 900. When the motor 930 rotates in both directions, the lower body 120 rises and falls.

As shown in FIG. 6, the guide 500 forms an inclined surface 501 between the opening hole 401 and the opening 111. The guide 500 is provided inside the opening hole 401. A stepped jaw 402 on which the guide 500 is seated is formed at the upper end of the housing 400. The edge of the guide 500 is seated on the stepped 402.

The guide 500 forms an inclined surface 501 inclined downward from an upper edge of the housing 400. The user holds the baby bottle 1 and lowers it to enter the body 100. The inclined surface 501 of the guide 500 guides the descending baby bottle 1 to the inner space 101 of the body 100.

As shown in FIGS. 5 to 7, the rotating members 300 are configured to block or open a space between the side surface of the baby bottle 1 and the opening 111, and are rotatably provided around the opening 111. The rotating members 300 are disposed at regular intervals along the periphery of the opening 111. 5 shows five rotating members 300. The number of the rotating members 300 may be various in addition.

8 is a partial exploded perspective view of the baby bottle warmer of FIG. 7.

As shown in FIG. 8, the first driving unit 800 is configured to rotate the rotating members 300 in both directions, and includes a plurality of actuators 810. The actuator 810 may be an electric motor. A plurality of mounting portions 113 are formed on the outer surface of the upper body 110.

The mounting parts 113 are parts to which the actuator 810 is coupled. Mounting parts 113 are formed along the circumferential direction on the upper outer surface of the upper body 110. The actuators 810 may be coupled to the mounting portions 113 by bolts. Insertion holes H are formed in the seating part 112. The rotation shafts 811 of the actuators 810 are inserted into the insertion holes H.

The control unit controls the first driving unit 800. When the actuators 810 rotate in both directions, the rotating members 300 rotate to block or open the space between the side surface of the baby bottle 1 and the opening 111.

9 is a bottom view of the rotating member of FIG. 8.

As shown in FIG. 9, each of the rotating members 300 includes a core material 310 and a deformable material 320.

The core member 310 is configured to rotate by the actuator 810 and is made of a plastic material that elastically deforms. The core 310 is configured to include a shaft 311 and a bar 312.

As shown in FIG. 8, the shaft part 311 is coupled to the rotation shaft 811 of the actuator 810 while being inserted into the insertion hole H. A hole 311H is formed in the shaft part 311. The rotation shaft 811 of the actuator 810 is inserted into the hole 311H of the shaft part 311. The shaft part 311 rotates simultaneously with the rotation shaft 811 of the actuator 810.

The bar 312 extends from the shaft part 311 in a direction inclined with the rotation shaft 811. The bar 312 may undergo elastic bending deformation by the reaction force of the baby bottle body 1A.

9, the deformable material 320 is attached to the core material 310. The deformable material 320 surrounds the top and side surfaces of the bar 312. The deformable material 320 may be made of a silicone or rubber material. The deformable material 320 may be elastically deformed by the reaction force of the baby bottle body 1A.

10 is a plan view of the baby bottle warmer of FIG. 3. 11 is a plan view of the baby bottle warmer of FIG. 4.

As shown in FIGS. 10 and 11, the rotating members 300 form a rotational symmetry around the center CT of the body 100. The control unit rotates the actuators 810 at the same time. The rotating members 300 form a rotationally symmetrical shape around the center CT of the body 100 in the open state and the closed state, respectively.

As shown in FIG. 10, in the open state, the rotating members 300 are disposed below the guide 500.

As shown in FIG. 11, in the closed state, the rotating members 300 are located in the space between the side surface of the baby bottle 1 and the opening 111. When the rotating member 300 rotates in a closed state, the deformable members 320 are in close contact with the side surface of the baby bottle 1 and elastically compressively deform by the reaction force of the bottle body 1A.

12 is a partial cross-sectional view of the baby bottle warmer of FIG. 3. 13 is a partial perspective cross-sectional view of the baby bottle warmer of FIG. 3.

12 and 13, the heater 200 supplies steam into the body 100. The heater 200 is provided at the lower end of the lower body 120. The heater 200 includes a seating plate 210, a receiving member 220, and a heating member 230.

A plurality of holes through which steam passes are formed in the seating plate 210. The seating plate 210 covers the lower end hole 121 of the lower body 120. The edge of the seating plate 210 is seated at the edge of the hole 121. The seating plate 210 forms the bottom surface of the body 100. The baby bottle 1 inserted into the inner space 101 of the body 100 is placed on the upper surface of the seating plate 210.

A first through hole 211 is formed in the mounting plate 210. The first through hole 211 is formed in the center of the seating plate 210. The ultrasonic vibrator 1300 forms a contact surface with the seating plate 210 through the inner surface of the first through hole 211.

12 and 13, the receiving member 220 is coupled under the seating plate 210. The receiving member 220 accommodates water supplied from the bucket 600. The water contained in the bucket 600 moves to the receiving member 220 through the tube 620.

A second through hole 221 is formed in the receiving member 220. The second through hole 221 is formed in the center of the receiving member 220. The ultrasonic vibrator 1300 forms a contact surface with the receiving member 220 through the inner surface of the second through hole 221.

A water level sensor 222 is installed in the receiving member. A valve 621 is installed in the tube 620 to regulate the movement of water. The control unit controls the valve 621 by receiving a signal from the water level sensor 222. The water level detection sensor 222 detects the minimum and maximum water levels of water.

When the water level detection sensor 222 detects the lowest water level, the control unit opens the valve 621. When the valve 621 is opened, the water contained in the bucket 600 moves to the receiving member 220 through the tube 620. When the water level detection sensor 222 detects the highest water level, the control unit closes the valve 621. The movement of water between the bucket 600 and the receiving member 220 is blocked. Accordingly, the water in the receiving member 220 continuously maintains a water level between the lowest and highest water levels.

The heating member 230 is a component that heats water accommodated in the receiving member 220 and may be provided as an electric heating wire. The heating member 230 is coupled to the receiving member 220. The wire connected to the heating member 230 is not shown.

12 and 13, the ultrasonic vibrator 1300 forms contact surfaces with the seating plate 210 and the receiving member 220, respectively. The ultrasonic vibrator 1300 is inserted into the first through hole 211 and the second through hole 221. The ultrasonic vibrator 1300 forms contact surfaces with inner surfaces of the first through hole 211 and the second through hole 221, respectively. The ultrasonic vibrator 1300 forms a surface on which the baby bottle 1 is placed together with the seating plate 210.

12 and 13, a temperature sensor 1400 is coupled to the heater 200. A hole into which the temperature sensor 1400 is inserted is formed in the seating plate 210 and the receiving member 220. The temperature sensor 1400 measures the temperature of the baby bottle body 1A.

The temperature sensor 1400 is provided as a contact temperature sensor 1400. The head 1410 of the temperature sensor 1400 protrudes upward from the seating plate 210. When the baby bottle 1 is placed on the seating plate 210, the head 1410 is pressed by the load of the baby bottle 1. The upper surface of the head 1410 is in close contact with the lower surface of the baby bottle 1. The head 1410 is connected to a thermistor.

The measured value of the temperature sensor 1400 is transmitted to the control unit. A temperature sensor that touches the bottom surface of an article and detects the temperature is a known technology as disclosed in Korean Patent Publication No. 1393220, so a detailed description thereof will be omitted.

14 shows the baby bottle warmer 10 in an inactive state. As shown in Fig. 14, the rotating member 300 is in the open state in the non-operating state of the baby bottle warmer 10. In the open state, the rotating members 300 are located under the guide 500.

In the non-operational state of the baby bottle warmer 10, the lower body 120 is in a lowered state. The lower body 120 forms an inner space 101 together with the upper body 110 in a descending state.

15 shows the ready state of the baby bottle warmer (10). When the user presses the power button (○) of the touch panel 1100, the baby bottle warmer 10 is in a ready state. When the user presses the power button (○) of the touch panel 1100, the lower body 120 rises.

When the lower body 120 rises, the seating plate 210 rises. When the lower body 120 rises, the depth of the inner space 101 decreases. In the ready state, the rotating member 300 is in an open state. The user may insert the baby bottle 1 into the body 100 while holding the upper portion of the baby bottle body 1A. When the baby bottle 1 is seated on the seating plate 210, the temperature sensor 1400 measures the temperature of the baby bottle body 1A. The measured value of the temperature sensor 1400 is transmitted to the control unit.

16 and 17 show the operating state of the baby bottle warmer (10). When the user presses the start button (▷) of the touch panel 1100, the baby bottle warmer 10 is in an operating state. When the user presses the start button (▷) of the touch panel 1100, the lower body 120 descends.

When the lower body 120 descends, the seating plate 210 descends. When the lower body 120 descends, the depth of the inner space 101 increases. Therefore, when the lower body 120 descends, part or all of the upper portion of the baby bottle body 1A is lower than the rotating member 300.

At this time, the rotating members 300 rotate to close the space between the side surface of the baby bottle body 1A and the opening 111. At this time, the rotating members 300 are elastically deformed and are in close contact with the side surface of the baby bottle body 1A. And the rotating members 300 are elastically deformed and are in close contact with each other. Accordingly, leakage of steam through the space between the side surface of the baby bottle body 1A and the opening 111 is blocked. The temperature sensor 1400 continuously measures the temperature of the bottom of the bottle body 1A.

As shown in FIG. 17, in the operating state, the heater 200 supplies steam to the inner space 101. When the temperature of the heating member 230 rises, the water contained in the receiving member 220 boils and steam is generated.

Steam passes through the hole of the seating plate 210 and flows into the inner space 101. Steam introduced into the inner space 101 forms a circulating flow that rises and then descends. Convection of steam occurs in the inner space 101.

The steam introduced into the inner space 101 rises and supplies heat energy to the top of the baby bottle body 1A. Accordingly, leakage of heat energy from the baby bottle body 1A to the atmosphere is prevented.

The steam that has lost heat energy is liquefied on the outer surface of the baby bottle body 1A or the inner surface of the body 100 while descending. The water attached to the outer surface of the baby bottle body 1A or the inner surface of the body 100 descends by gravity and flows into the receiving member 220.

The heat energy of the steam is transferred to breast milk (milk powder, milk) through the bottle body 1A. The temperature of breast milk (milk powder, milk) is raised by the heat energy continuously supplied from the steam. Breast milk (milk powder, milk) convections inside the body 1A and forms a uniform temperature distribution throughout.

18 is a partial enlarged view of the baby bottle warmer 10 of FIG. 17.

As shown in FIG. 18, the ultrasonic vibration generated by the ultrasonic vibrator 1300 is radially propagated through the inner surface of the second passage hole 221 into the water contained in the receiving member 220.

The ultrasonic vibration generated by the ultrasonic vibrator 1300 promotes convective heat transfer of water contained in the receiving member 220. In addition, the ultrasonic vibration generated by the ultrasonic vibrator 1300 promotes boiling heat transfer of water contained in the receiving member 220. The water contained in the receiving member 220 is rapidly phase-changed into steam by the ultrasonic vibration generated by the ultrasonic vibrator 1300. Therefore, the breast milk contained in the baby bottle 1 can reach the target temperature within a faster time.

As shown in FIG. 18, the ultrasonic vibrator 1300 forms a surface on which the baby bottle 1 is placed together with the seating plate 210. As shown in FIG. The ultrasonic vibration generated by the ultrasonic vibrator 1300 is radially propagated to the seating plate 210 through the inner surface of the first through hole 211.

Therefore, when the baby bottle 1 is placed on the upper surface of the seating plate 210, the ultrasonic vibration generated by the ultrasonic vibrator 1300 is the contact surface between the seating plate 210 and the baby bottle body 1A, and the ultrasonic vibrator 1300 It spreads to the breast milk (milk, powdered milk) inside the bottle 1 through the contact surface of the bottle body 1A.

The ultrasonic vibration generated by the ultrasonic vibrator 1300 promotes convective heat transfer of breast milk (milk, powdered milk) contained in the baby bottle 1. The breast milk contained in the baby bottle 1 increases the convective heat transfer speed by ultrasonic vibration generated by the ultrasonic vibrator 1300. While the breast milk contained in the baby bottle 1 is heated by the thermal energy of the steam, the temperature difference for each location is not largely formed, and a uniform temperature is formed as a whole. Therefore, as soon as the baby bottle 1 is taken out of the bottle warmer 10, the baby bottle 1 can be bitten by the child.

The ultrasonic vibration generated by the ultrasonic vibrator 1300 is transmitted to the rotating member 300 in close contact with the baby bottle body 1A. The deformable material 320 may be made of a silicone or rubber material. The deformable materials 320 are elastically deformed and may absorb ultrasonic vibrations. Therefore, even if the bottle body 1A vibrates by ultrasonic vibration, the deformable materials 320 are in close contact with the side surface of the bottle body 1A and maintain close contact with each other to prevent leakage of steam.

As shown in FIG. 18, the ultrasonic vibration generated by the ultrasonic vibrator 1300 is radially propagated to the seating plate 210 through the inner surface of the first through hole 211. Water contained in the receiving member 220 is vaporized by the heat energy of the heating member 230. The steam moves to the inner space 101 through a plurality of holes formed in the seating plate 210. Ultrasonic vibrations are transmitted to the steam passing through a number of holes.

Steam in the inner space 101 increases the convective heat transfer speed by ultrasonic vibration generated by the ultrasonic vibrator 1300. The steam introduced into the inner space 101 rises rapidly and supplies thermal energy to the baby bottle body 1A. Therefore, the breast milk contained in the baby bottle 1 can reach the target temperature within a faster time.

When the temperature of the breast milk (milk powder, milk) contained in the baby bottle 1 reaches the target temperature, the indicator 1000 visually displays this. When the temperature of the breast milk (milk powder, milk) contained in the baby bottle 1 reaches the target temperature, the amount of current supplied to the heating member 230 may decrease so that the temperature of the breast milk (milk powder, milk) is maintained.

When the user presses the stop button (□) of the touch panel 1100, the rotating members 300 rotate to an open state. Then, the lower body 120 rises. When the lower body 120 rises, the seating plate 210 on which the baby bottle 1 is placed rises. When the lower body 120 rises, the depth of the inner space 101 decreases. Accordingly, the user can take out the baby bottle 1 by holding the upper part of the baby bottle body 1A.

In the above, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have. Accordingly, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and the modified embodiments should be said to belong to the claims of the present invention.

10: baby bottle warmer
100: body 200: heater
101: inner space 210: seating plate
110: upper body 211: first through hole
111: opening 220: receiving member
112: seat 221: second through hole
H: insertion hole 222: water level sensor
112H: Hall 230: heating member
113: mounting part 300: rotating member
120: lower body 310: core
121: hole 311: shaft portion
122: slider 311H: hole
123: mounting part 312: bar
124: first fastening part 320: deformable material
125: second fastening part 500: guide
400: housing 501: inclined surface
401: opening hole 600: water bottle
402: step 610: lid
410: mounting portion 620: tube
411: protrusion 621: valve
420: guide member 700: cover
421: guide groove 710: handle
430: rail 800: first drive unit
440: mounting shaft 810: actuator
450: mounting part 811: rotating shaft
CL: center line 1000: indicator
900: second drive unit 1010: LED module
910: rack 1020: shielding plate
911: protrusion 1100: touch panel
920: pinion 1200: charger
930: motor 1210: power terminal
931: main gear 1300: ultrasonic vibrator
1: baby bottle 1400: temperature sensor
1A: body 1410: head

Claims (11)

A body forming an opening in the upper portion and into which a baby bottle is inserted through the opening;
A heater supplying steam to the inner space of the body and contacting the baby bottle; And
Forming a contact surface with the heater and comprising an ultrasonic vibrator for generating ultrasonic vibration,
The ultrasonic vibration is transmitted to the liquid in the baby bottle and the water in the heater to promote convective heat transfer,
Bottle warmer. The method of claim 1,
A hole is formed in the lower end of the body,
The heater,
A seating plate covering the hole and on which the baby bottle is placed;
A receiving member coupled under the seating plate and receiving water; And
Including a heating member for heating the water accommodated in the receiving member,
The ultrasonic vibrator forms a contact surface with each of the seating plate and the receiving member,
Bottle warmer. The method of claim 2,
A first through hole is formed in the mounting plate,
A second through hole is formed in the receiving member,
The ultrasonic vibrator forms a contact surface with inner surfaces of the first through hole and the second through hole, respectively,
Bottle warmer. The method of claim 2,
A plurality of holes through which steam passes are formed in the seating plate,
The ultrasonic vibration is transmitted to the steam passing through the holes to promote convective heat transfer in the inner space,
Bottle warmer. The method of claim 2,
It is connected to the receiving member and the tube, and includes a water container for storing water,
A water level sensor is installed in the receiving member,
The tube is provided with a valve that regulates the movement of water,
Bottle warmer. The method of claim 1,
The heater is provided at the lower end of the body,
The heater and the ultrasonic vibrator form a surface on which the baby bottle is placed,
Bottle warmer. The method of claim 1,
It includes a plurality of rotating members rotatably provided along the periphery of the opening,
The rotating members rotate to block or open the space between the side surface of the baby bottle and the opening,
Bottle warmer. The method of claim 7,
Each of the rotating members,
A core member rotated by an actuator; And
A deformable material attached to the core material and in close contact with the side surface of the baby bottle,
The deformable materials are elastically deformed and absorb the ultrasonic vibration,
Bottle warmer. The method of claim 1,
The body,
An upper body forming the opening and coupled to the housing; And
The heater is coupled, and includes a lower body installed to be movable up and down on the housing,
The heater is provided at the lower end of the lower body,
The heater and the ultrasonic vibrator form a surface on which the baby bottle is placed,
Bottle warmer. The method of claim 9,
A rack is coupled to the lower body,
The housing is provided with a pinion engaged with the rack, a motor for rotating the pinion, and a guide member for guiding the vertical movement of the rack,
Bottle warmer. A body forming an opening in the upper portion and into which a baby bottle is inserted through the opening;
A heater provided at the lower end of the body and supplying steam to the inner space of the body; And
Forming a surface on which the baby bottle is placed together with the heater, and comprising an ultrasonic vibrator for generating ultrasonic vibration,
The ultrasonic vibration is transmitted to the liquid in the baby bottle, the water in the heater, and the steam in the inner space to promote convective heat transfer of the liquid, water, and steam,
Bottle warmer.

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