U.S. patent application number 12/620382 was filed with the patent office on 2010-05-13 for baby food maker.
This patent application is currently assigned to SUNBEAM PRODUCTS, INC.. Invention is credited to Augusto Picozza, James Tracy.
Application Number | 20100116145 12/620382 |
Document ID | / |
Family ID | 39112149 |
Filed Date | 2010-05-13 |
United States Patent
Application |
20100116145 |
Kind Code |
A1 |
Tracy; James ; et
al. |
May 13, 2010 |
BABY FOOD MAKER
Abstract
A method and apparatus are provided for steaming and blending
food products such as baby food. The apparatus includes a base
including a steam chamber and a drive shaft. A container assembly
can be mounted to the base in an inverted position for steaming the
food and in an upright position for blending the food. The
apparatus may further include a baby bottle sterilizing unit and a
bottle warmer.
Inventors: |
Tracy; James; (Attleboro,
MA) ; Picozza; Augusto; (Boca Raton, FL) |
Correspondence
Address: |
HOFFMANN & BARON, LLP
6900 JERICHO TURNPIKE
SYOSSET
NY
11791
US
|
Assignee: |
SUNBEAM PRODUCTS, INC.
Boca Raton
FL
|
Family ID: |
39112149 |
Appl. No.: |
12/620382 |
Filed: |
November 17, 2009 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
11510014 |
Aug 25, 2006 |
7617766 |
|
|
12620382 |
|
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Current U.S.
Class: |
99/348 ; 141/85;
99/410 |
Current CPC
Class: |
A47J 44/00 20130101;
A47J 43/046 20130101; A47J 27/004 20130101; A47J 27/04 20130101;
A47J 36/2433 20130101 |
Class at
Publication: |
99/348 ; 99/410;
141/85 |
International
Class: |
A21B 7/00 20060101
A21B007/00; A47J 37/00 20060101 A47J037/00; B65B 3/00 20060101
B65B003/00 |
Claims
1-20. (canceled)
21. A food preparation assembly comprising: an apparatus for
steaming and blending food products, comprising: a base including a
support for a container; a steam chamber supported by the base and
including a steam exit port; a heater for providing heat to the
steam chamber; a drive shaft; an electric motor supported by the
base and operatively associated with the drive shaft; a container
assembly including a container, a steam inlet passage, and a lid
removably coupled to a top end portion of the container, the
container assembly being selectively mountable to the base support;
a blade assembly disposed within the container; a bottle holder
selectively mountable to the base, the bottle holder including a
steam inlet passage communicable with the steam exit port and an
interior chamber of the bottle holder, an external receptacle for
receiving at least the bottom end of a baby bottle, and an opening
within the bottle holder for allowing steam to flow from the
chamber into the receptacle; and a sterilizing unit selectively
mountable to the base including a sterilization chamber for holding
a plurality of bottles, the sterilization chamber being in fluid
communication with the steam exit port when mounted to the
base.
22. A food preparation assembly as described in claim 21, wherein
the steam exit port is selectively positionable between a first
position in fluid communication with the container and a second
position in fluid communication with the sterilizing unit.
23. A food preparation assembly as described in claim 22, wherein
the steam chamber includes a removable cap and the steam exit port
is disposed on the cap.
24. A food preparation assembly as described in claim 21, wherein
the lid is selectively locked to the container by a latching
mechanism.
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001] This application is a continuation application of U.S.
application Ser. No. 11/510,014, filed on Aug. 25, 2006, which is
incorporated by reference herein in its entirety for all
purposes.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The field of the invention relates to methods and assemblies
for steaming and blending food products.
[0004] 2. Brief Description of the Related Art
[0005] Various appliances have been designed for steaming and/or
blending food products. Baby food is often made by steaming food
products and then placing them in a blender. While two separate
appliances, namely a steamer and a blender, can be employed for
making pureed food such as baby food, some appliances have been
designed that provide both such functions. U.S. Pat. Nos. 6,076,452
and 6,550,372 and WO 2005/094648 A1 disclose food processing
devices that allow the user to first steam food products and then
blend them in the same device.
[0006] Appliances have also been designed for sterilizing baby
bottles. Some sterilizers intended for this purpose have employed
steam. U.S. Pat. Nos. 4,544,529 and 5,213,776 disclose such
sterilizing appliances.
[0007] Baby bottle warmers are commercially available for warming
baby bottles or other vessels containing baby food. WO 03/071910 A1
discloses a food warmer that employs steam to warm a food
containing vessel.
SUMMARY OF THE INVENTION
[0008] The present invention is directed to an apparatus and a
method for steaming and blending food products. An apparatus in
accordance with the invention includes a base having a support for
a container. A steam chamber is supported by the base and includes
a steam exit port. A heater provides heat to the steam chamber. A
drive shaft is rotatably supported by the base and an electric
motor is provided for rotating the drive shaft. The apparatus
further includes a container assembly including a container, and a
lid removably coupled to the top end portion of the container. A
steam inlet passage is provided in the container for allowing the
entrance of steam generated within the steam chamber. A blade
assembly is disposed within the container. The container assembly
is mountable to the base support in a first upright orientation
wherein the bottom end portion thereof adjoins the base support and
the drive shaft operatively engages the blade assembly. The
container assembly is also mountable to the base support in a
second inverted orientation wherein the steam exit port is in fluid
communication with the steam inlet passage.
[0009] An assembly for steaming and blending food products is
further provided in accordance with the invention. The assembly
includes a base for supporting a removable container, a steam
chamber within the base, a steam exit port in fluid communication
with the steam chamber, an electric heater for providing heat to
the steam chamber, a drive shaft rotatably mounted to the base, an
electric motor for rotating the drive shaft, and a container
assembly having a bottom end portion, an open top end portion and a
lid removably securable to the open top end portion. A blade
assembly is disposed within the container. A steam inlet passage is
provided for admitting steam into the container. Complementary
locking elements on the base and container assembly are provided
such that the container assembly can be removably locked to the
base in a first upright position where the drive shaft is coupled
to the blade assembly and a second inverted position where the
steam inlet passage is in fluid communication with the steam exit
port. The assembly can preferably be used for additional purposes
such as warming baby bottles and/or sterilizing baby bottles and/or
other food containers.
[0010] A method in accordance with the invention includes the steps
of providing a base including a steam chamber, a steam exit port in
fluid communication with the steam chamber, a drive shaft, and an
electric motor for rotating the drive shaft. A container assembly
is provided that includes a container having a bottom end portion
and an open top end portion, a lid removably mounted to the top end
portion, and a steam inlet passage. A blade assembly is positioned
within the container. The method further includes introducing food
into the container, placing the container on the base in an
inverted position such that the steam inlet passage communicates
with the steam exit port, causing the steam chamber to produce
steam, the steam entering the container through the steam inlet
passage and steaming the food, removing the container assembly from
the base after the food has been steamed, replacing the container
on the base in an upright position so that the drive shaft is
coupled to the blade assembly, and actuating the motor to cause
rotation of the drive shaft and coupled blade assembly, thereby
blending the food.
[0011] A food preparation assembly is further provided in
accordance with the invention. The assembly includes an apparatus
for steaming and blending food products. The apparatus includes a
base having a support for a container, and a steam chamber
supported by the base and including a steam exit port. A heater is
included for providing heat to the steam chamber. The base includes
a drive shaft. An electric motor is supported by the base and
operatively associated with the drive shaft. Further provided is a
container assembly including a container, a steam inlet passage,
and a lid removably coupled to a top end portion of the container,
the container assembly is selectively mountable to the base
support. A blade assembly is disposed within the container. A
bottle holder is selectively mountable to the base. The bottle
holder includes a steam inlet passage communicable with the steam
exit port and an interior chamber of the bottle holder. An external
receptacle for receiving at least the bottom end of a baby bottle,
and an opening within the bottle holder for allowing steam to flow
from the chamber into the receptacle. A sterilizing unit is
selectively mountable to the base including a sterilization chamber
for holding a plurality of bottles. The sterilization chamber is in
fluid communication with the steam exit port when mounted to the
base.
BRIEF DESCRIPTION OF THE DRAWINGS
[0012] FIG. 1 is an exploded, perspective view of a base assembly
for a baby food maker in accordance with the invention;
[0013] FIG. 2. is a sectional view thereof;
[0014] FIG. 3. is a bottom view thereof with the bottom cover
removed;
[0015] FIG. 4 is an exploded, perspective view of a container
assembly and associated components for use with the base
assembly;
[0016] FIG. 5 is a sectional view showing the container assembly
mounted to the base assembly in a first orientation for blending
food;
[0017] FIG. 6. is a sectional view showing the container assembly
mounted to the base assembly in a second, inverted orientation for
steam cooking food;
[0018] FIG. 7 is a sectional view showing a sterilizing unit
mounted to the base assembly;
[0019] FIG. 8 is a sectional view showing a bottle warmer mounted
to the base assembly;
[0020] FIG. 9 is a perspective view of an alternative embodiment of
baby food maker in accordance with the present invention;
[0021] FIG. 10 is a cross-sectional view of the baby food maker of
FIG. 9;
[0022] FIG. 11 is a cross-sectional view of the base of FIG. 9;
[0023] FIG. 12 is an exploded view of the container of FIG. 9;
[0024] FIG. 13 is a cross-sectional view of the container of FIG.
12;
[0025] FIG. 14 is a cross-sectional view of the baby food maker of
FIG. 9 showing the container in a steaming position;
[0026] FIG. 14A is a perspective view of the baby food maker
showing the container in an inverted position.
[0027] FIG. 15 is a perspective view of the baby food maker of FIG.
9 with a sterilizing unit attached thereto;
[0028] FIG. 16 is a cross-sectional view of the baby food maker
with sterilizing unit; and
[0029] FIG. 17 is a side elevational view of a steam chamber cover
of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
[0030] The detailed description which follows is directed to a
preferred embodiment of the invention, and is not intended as
limiting the invention to the specific structures disclosed. The
invention should instead be construed in accordance with the claims
that are appended.
[0031] With reference to FIGS. 1 to 4, an apparatus 10 for steaming
and blending food products is provided. The apparatus can be used
for making baby food or other types of pureed foods. As discussed
below, it can also be adapted for sterilizing or warming baby
bottles or other food containers. A base 12 is provided for
supporting a removable container 14, a steam chamber 16, and a
motor 18 for driving a blade assembly 20 or other blending device.
Referring specifically to FIGS. 1 and 2, the base 12 defines an
enclosure into which the steam chamber 16 extends. The base is
comprised of a bottom cover 12a and housing 12b. The steam chamber
is defined in part by a vessel 24 having a metal bottom that
readily conducts heat. The entire vessel can be formed of plastic
or metal. The vessel is preferably permanently secured to the base
12. An electric heater, such as a resistance heater 22, is
positioned in close proximity to the vessel. The heater is
supported by a bracket 23. A gasket 25 is provided between the
heater and bracket. The vessel 24 is substantially cylindrical and
has an open top end. The steam chamber further comprises a cover 26
that is removably mounted to the top end of the vessel. A
bayonet-type locking mechanism is employed to secure the cover 26,
including bayonet-type slots 28 in the cover 26. The cover includes
a top wall 30 and a skirt 32 extending downwardly from the top
wall. The skirt is indented near the top wall 30 and includes an
undulating surface to facilitate application and removal of the
cover. The lower portion of the skirt is generally cylindrical, but
includes a shoulder 29 that rests upon an annular surface 31 of the
base 12. A gasket 34 is positioned between the cover's shoulder 29
and the base to prevent the escape of steam. A steam exit port 36
is provided in the skirt 32. A resilient grommet 38 is secured to
the port 36, portions of which extend beyond the skirt walls. These
portions secure the grommet in place. The portion of the grommet
adjoining the outer surface of the skirt 32 provides a sealing
mechanism for an adjoining vessel, as described below. The cover 26
and base are designed such that the steam exit port 36 is oriented
in a selected direction when the cover is properly secured.
[0032] A receptacle 40 for a portion of the container 14 is defined
by the base 12 such that the container can be mounted to the base
in side by side relation to the steam chamber. A first locking
structure 42 in the form of one or more slots is provided at a
first elevation in the wall bounding the receptacle 40. A second
locking structure 44 is provided at a higher elevation. Both
locking structures 42, 44 are designed to interact with
complementary locking structures located on the container 14 and
container lid 50, respectively. The receptacle 40 includes a
plurality of levels or tiers. The bottom tier 46 has a relatively
small diameter while the upper tier 48 has a larger diameter. Each
tier includes a generally annular horizontal surface. The electric
motor 18 is mounted beneath the receptacle 40. A drive shaft 52 is
operatively associated with the motor and extends into the
receptacle 40. The drive shaft rotates about its longitudinal axis
when the motor is actuated. As shown in FIG. 3, the drive shaft is
driven by a belt 53 mounted to two pulleys, one associated with the
motor output shaft and the other with the drive shaft 52 for the
blade assembly 20.
[0033] With reference to FIGS. 4 to 6, the container 14 includes a
bottom wall 54 having a central opening as shown in FIGS. 5 and 6.
The blade assembly 20 is disposed within the container 14. In the
embodiment shown in FIGS. 4-6, the blade assembly may be mounted to
the bottom wall 54. The blade assembly 20 includes a coupling 58 to
which a plurality of blades 60 are mounted. The coupling 58 extends
partially below the bottom wall of the container and partially
above it. The middle portion of the coupling 58 is slotted for
receiving portions of the bottom wall 54 adjoining the central
opening. It is removably secured to the bottom wall of the
container. An annular seal 62 is provided between a shoulder
portion of the coupling and an annular ring 64 extending downwardly
from the bottom wall. The coupling includes a central passage 66
configured to receive the drive shaft 52. The passage is defined by
a multi-sided wall surface. The drive shaft includes corresponding
surfaces whereby the coupling and the blades are caused to rotate
upon rotation of the drive shaft.
[0034] The container includes an annular base portion 68 extending
below the bottom wall 54 as well as beyond the bottom of the
coupling 58. A plurality of projections 70 extend radially
outwardly from the outer surface of the base portion 68. The
projections are positionable within the bayonet-type slots
comprising the first locking structure 42 when the container is
mounted to the base in a first orientation as shown in FIG. 5. They
allow the container to be removably locked to the base 12 by
rotating the container once the projections are within the slots.
The apparatus 10 can be used for blending when the container is
locked in this position. The base portion also allows the container
to be placed upon a horizontal surface without danger of tipping
over. A handle 71 extends from a side wall of the container. A slot
73 may be formed in the upper wall of the handle 71 to receive a
tab 75 depending from the lid. The engagement of the tab 75 in slot
73 helps releasably retain the lid in the closed position. The top
end of the container 14 includes three rounded projections 69 that
extend radially outwardly, as shown in FIG. 4.
[0035] The container lid 50 includes a top wall 72 and a generally
cylindrical skirt 74 that is integral with the top wall 72. A
slotted opening 76 is formed in the top wall. A ramp 78 formed
integrally with the top wall of the lid extends below the opening
76. The top wall is formed so that, when inverted, liquid within
the lid will tend to flow towards the slotted opening. A partition
wall 80 extends from the bottom surface of the top wall and bisects
the interior portion of the lid. A plurality of projections 82
extend radially outwardly from the lid and are engageable with
slots in the base 12 comprising the second locking structure 44. A
steam inlet passage 84 extends through the skirt 74. When the
container is coupled to the base in an inverted orientation as
shown in FIG. 6, the steam inlet passage 84 is in fluid
communication with the steam exit port 36. The resilient grommet
forms a seal around the steam exit port and the portion of the
skirt 74 surrounding the steam inlet passage as it engages the
outer surfaces of the container lid 50 and the cover 126 of the
steam chamber 16. The skirt may further include one or more steam
vent openings (not shown). An annular gasket 85 is provided on the
upper surface of the lid 50.
[0036] A perforated screen 86 is removably coupled to the container
lid 50. The screen 86 is comprised of a thin, planar body portion
and a centrally located dome-like depression 88. A pair of parallel
walls 89 extend from the top surface of the screen and define a
slot that receives the outer end of the partition wall 80 of the
lid 50. The screen is thereby frictionally coupled to the lid and
mostly positioned within the skirt 74 thereof.
[0037] With reference to FIG. 6, a condensate collector 90 may be
positioned within the receptacle 40. The condensate collector
includes a vessel 92 having a radially outwardly extending handle
94 that extends outside the base 12 through a notch 93 in the upper
tier 48 when the vessel is within the receptacle 40. The bottom
wall of the vessel forms a hollow center protrusion that
accommodates the top end of the drive shaft 52 (FIG. 1). As shown
in FIG. 6, the lid gasket 85 forms a seal between the condensate
collector 90 and the lid to prevent steam from entering the
condensate collector. The lid gasket forms a seal between the
condensate collector 90 and the lid 50 to prevent steam from
entering the portion of the receptacle 40 outside the condensate
collector.
[0038] Referring now to FIG. 7, the apparatus 8 can be adapted for
sterilizing baby bottles or other food containers. A sterilizing
unit 97 may be provided and include a housing assembly 95 having a
generally U-shaped housing 96. The housing assembly 95 includes a
sterilization chamber 98 for holding a plurality of baby bottles. A
housing extension 100 is connected to, and is preferably integral
with the housing 96. The housing assembly includes a base unit 102
and a removable cover 104. The base unit 102 includes supports 106
for bottles that allow them to be mounted upside down. The supports
further allow steam to enter the bottles. The base unit preferably
includes eight supports 106, though it can be configured to hold a
greater or lesser number of bottles and/or other types of food
containers. The portion of the base unit 102 comprising the bottom
of the housing extension 100 includes a steam inlet port 108 that
adjoins the steam exit port 36 when mounted to the base 12. It
further includes locking members (not shown) similar to those
provided on the container lid 50 for securing it to the slots in
the base 12 comprising the second locking structure 44 (FIG. 2).
One or more legs 110 extend from the bottom wall of the base unit
102 for supporting the housing 96. When the housing assembly is
coupled to the base 12 and the cover 104 is mounted to the base
unit 102, steam can flow from the exit port 36 into the housing
extension 100 and then into the sterilization chamber 98. One or
more vents (not shown) can be provided for venting the
sterilization chamber.
[0039] FIG. 8 shows the apparatus as configured for warming a baby
bottle 112. A bottle holder 114 is provided that includes a first
open end to which the lid 50 can be secured. The opposite end of
the bottle holder is configured as a receptacle 116 for the bottle.
The receptacle is bounded by a generally conical side wall of the
holder 114 as well as a bottom wall. Both the side wall and the
bottom wall include openings 118 that allow steam to enter the
receptacle and thereby provide heat to the bottle contained
partially therein. The bottle holder 114 and associated lid 50 are
mounted to the base in the same manner as the container 14 is
mounted thereto. Steam enters the bottle holder through the steam
inlet passage 84 in the lid 50 and travels upwardly through the
openings 118 into the receptacle 116 where it heats the bottom
portion of the bottle. The condensate collector 90 is preferably
employed during the bottle warming process to collect the water
formed as the steam condenses about the bottle or the inner
surfaces of the holder 114.
[0040] An alternative preferred embodiment of the present invention
is shown in FIGS. 9 to 16. The baby food maker 120 of this
embodiment is similar to the embodiment described above. With
specific reference to FIGS. 9-11, a base 122 includes a steam
chamber 124 and a receptacle 126 for receiving a removable
container 128. The container 128 is selectively covered by a lid
129. The base includes a motor 130 for driving a blade assembly 132
disposed within the container 128. Container 128 may include a
separate blade assembly 132 that is removable from the container to
help facilitate cleaning.
[0041] The steam chamber 124 includes a vessel 134 for holding a
liquid. The chamber is in communication with a heating element 136
which is capable of turning the liquid, such as water, into steam.
The vessel 134 is covered by a removable cover 140 which may be
secured by bayonet-type locking mechanism of the type described
above. Cover 140 includes a top wall 142 and skirt 144. A steam
exit port 146 may be disposed on skirt 144.
[0042] With reference to FIGS. 11 to 13, removable container 128,
assembled with the lid 129 and blade assembly 132, may be placed
within the base receptacle 126 in a first orientation such that the
container 128 may perform as a blender for chopping and pureeing
foods. The container 128 may be removably secured to the base
receptacle by way of complementary locking structures 148a on the
base (FIG. 11) and 148b on the container (FIG. 12) as described
above with respect to the embodiment shown in FIG. 5.
Alternatively, the container 128 may be placed on base 122 in a
second orientation, inverted with respect to the first orientation,
such that lid 129 sits in receptacle 126. In the second
orientation, the contents of the container may be steamed.
[0043] Lid 129 may be removably attached to a screen 147 similar to
screen 86 as described above. The manner of securement of the
screen to the lid may differ from that of the previously described
embodiment in that screen 147 may be held in place by way of
engagement of the screen perimeter with the inside of lid skirt
149. The engagement may be secured by outwardly projecting tabs
147a (FIG. 12) disposed on the screen 147 which interlock with
indentations (not shown) formed on the inner surface of the lid's
skirt 149. Screen 147 may be easily removed from lid 129 to
facilitate cleaning.
[0044] Lid 129 may be secured to the container 128 by way of
interlocking structures, such as a bayonet-type connector as in the
previously described embodiment, in which the lid is rotated with
respect to the container to secure the lid to the container. A
latching mechanism 145 may be provided to selectively lock the lid
to the container. Preferably, the latching mechanism 145 includes a
latch 145a pivotally secured to the handle 128a of the container
128 and biased in a locking position. The biasing may be provided
by a section of resilient material 145b. The latching mechanism 145
further includes a projecting member 147b extending from the screen
147. The projecting member 147b extends through a notch 149a formed
in lid skirt 149 and beyond the lid skirt 149. The latch 145a
includes a locking end 145c which engages the projecting member
147b when the lid is secured to the container 128. When the lid 129
is rotated to the closed position, the projecting member 147b
engages the latch 145a and deflects it away from the projecting
member. The projecting member 147b includes a notched portion 147c
(FIG. 12) which receives the locking end 145c. Once the locking end
145c is positioned within the notch 147c, the latch 145a springs
back and the lid 129 may not be rotated until the user depresses
the latch 145a. The depression of the latch 145a results in the
locking end 145c being moved away from the projecting member 147b
and out of notch 147c, thereby permitting the lid 129 to be rotated
and removed from the container 128.
[0045] With reference to FIGS. 12 and 13, container 128 may include
a housing 150 with a bottom portion 152 removably attached to the
housing 150. The attachment may be achieved by way of cooperating
bayonet-type connectors on the housing 153a (FIG. 13) and on the
bottom portion 153b (FIG. 12) in a manner known in the art. The
bottom portion 152 may be removed or attached to the housing 150 by
rotating the bottom portion and housing with respect to each other.
The housing 150 may include a bottom wall 154 having an opening
156, defined by upwardly extending walls 158. A drive member 160
disposed on the bottom portion 152 extends through the opening 156.
The blade assembly 132 is removably securable to the drive member
160. Blade assembly 132 includes a hub 162 and blades 164 extending
from the hub. Hub 162 may have an inner annular opening 166, which
receives the upwardly extending walls 158. A blade assembly upper
end 168 may be rotationally fixed to a drive member upper end 170
such that they will spin together. The connection between the blade
assembly upper end 168 and drive member 160 permits the blade
assembly to be moved axially relative to the drive member. This may
be achieved by way of complimentary configurations of a type known
in the art.
[0046] Drive member 160 may be operably connected to a clutch
mechanism 172 which prevents the blade assembly 132 from turning
when the container lid 129 is not secured to the container. The
drive member 160 and clutch mechanism 172 may be disposed on the
bottom portion 152. Drive member 160 is preferably longitudinally
translatable with respect to the bottom portion 152. This
translational movement permits the drive member and the blade
assembly attached thereto to be disposed in and out of engagement
with the motor 130 via the clutch mechanism 172.
[0047] In order to move the drive member, the upper end of the
drive member 170 may include a post 174 that extends through an
opening 176 in the top of the blade assembly 132. Screen 147 may
further include an opening 178 to permit a post-like actuator 180
to extend there-through. Actuator 180 is secured to the lid and
engages the blade assembly 132 when the lid 129 is properly secured
on the container housing and forces the drive member 160
downwardly.
[0048] Referring additionally to FIGS. 10 and 13, the clutch
mechanism 172 may include a first clutch part 182 disposed on the
bottom of the drive member. The bottom portion 152 may include a
coupling 184 having an opening 186 for receiving a drive shaft 188
operably connected to the motor 130. When the container 128 is
secured in the base 122, the drive shaft 188 extends into the
opening such that rotation of the drive shaft 188 causes the
coupling 184 to rotate. An upper portion of the coupling includes a
second clutch part 190. When the drive member 160 is depressed,
such as when the lid 129 is secured on the container 128, the first
and second clutch parts 182 and 190 engage each other. This causes
the drive member 160 and drive shaft 188 to be coupled together.
Therefore, rotation of the drive shaft causes the drive member and
the blade assembly 132 attached thereto to rotate. In the preferred
embodiment, the first and second clutch parts are toothed
structures. However, it is within the contemplation of the present
invention that other power transferring configurations could be
employed.
[0049] The drive member 160 is preferably biased upwardly by a
spring 192. When the lid 129 is removed from the container 128, the
first clutch part 182 moves out of engagement with the second
clutch part 190. Therefore, rotation of the drive shaft 188 and the
second clutch part 190 does not cause rotation of the blade
assembly 132. Accordingly, the lid 129 preferably needs to be
secured to the housing 150 in order for the blades 164 to spin.
[0050] With reference to FIGS. 14 and 14A, container 128 may be
secured to base 122 in an inverted orientation such that the lid
129 is positioned within the base receptacle 126. The container may
be securely held in place by the cooperation of a plurality of
radially extending tabs 129b formed on the lid with corresponding
locking structures 148c in the base. In this orientation, the steam
exit port 146 is in fluid communication with a steam inlet passage
194 leading to the inside of the container 128. Food supported by
the screen 147 can be steamed as described above. A condensate
collector 196, of a type as described above, may be placed within
the receptacle of the base 126 to collect fluid that has condensed
and exited out of the vents 129a in the lid 129.
[0051] With reference to FIGS. 15 and 16, the preferred embodiment
may accommodate a sterilizing unit 198 removably mountable to base
122. Sterilizing unit 198 may include a chamber 200 for
accommodating a plurality of baby bottles 202. The sterilizing unit
may include a removable portion 204 to permit access to the
chamber. The chamber 200 may include a rack 206 for supporting
bottle caps and/or nipples 208 so they may be sterilized. The
bottles may be placed upon a porous screen 210 such that
condensation drains away from the bottles. In the present
embodiment, the sterilizing unit 198 may be disposed on base 122
adjacent the steam chamber 124. The steam chamber 124 is preferably
disposed between the sterilizing unit 198 and the base receptacle
126. In addition, the presently described embodiment may also
accommodate a bottle warmer in a manner as described above with
respect to FIG. 8.
[0052] Steam may be selectively communicated to the sterilizing
unit 198 and container 128 positioned in receptacle 126 by
selective positioning of the steam exit port 146. To achieve this,
the cover 140 of the steam chamber is preferably securable on the
vessel 134 in a first and second position. In the first position,
shown in FIG. 14, the steam exit port 146 is in communication with
the inlet passage 194 of container 128 and the steam may be used
for steaming the food held in the container 128. In a second
position, shown in FIG. 16, the steam exit port 146 is in
communication with a steam inlet port 212 of the sterilizing unit
198. Steam may then enter the sterilization chamber 200 and
sterilize its contents. The ability to secure the cover 140 in two
positions may be achieved by way of bayonet-type locking mechanism
as shown in FIG. 17. The cover 140 may include a pair of generally
L-shaped slots 140a diametrically disposed thereon. The slots 140a
each receive one of a pair of tabs (not shown) extending outwardly
from opposite sides of the steam vessel wall. When the cover is
rotated the tabs engage the slots 140a thereby securing the cover
140. When the steam is desired to communicate with the container
128, a user may orient the cover 140 such that when it is
tightened, the steam exit port 146 aligns with the container 128,
as shown in FIG. 14. Alternatively, when the steam is desired to
communicate with the sterilizing unit 198, a user would orient the
cover 140 such that when it is tightened, the steam exit port 146
would align with steam inlet port 212 on the sterilizing unit 198,
as shown in FIG. 16. In this embodiment, the steam is directly
provided to the container, bottle warmer, or sterilizing unit, and
it does not have to travel through any tubing or along any
significant distance.
[0053] The operation of the baby food maker in each of the above
described preferred embodiments is similar. The operation will now
be described with reference to the embodiment set forth in FIGS. 1
to 8, and distinctions between the operation of this embodiment and
the alternative preferred embodiment shown in FIGS. 9 to 17 will be
noted. The preparation of baby food is begun by cutting uncooked
food into pieces of appropriate size. The screen 86 is mounted to
the lid 50 and the food is placed in the container 14. The
container and lid forming a container assembly. In the alternative
preferred embodiment, the blade assembly 132 is positioned in the
container on the drive member 160. No further handling of the food
is necessary until after it is cooked and ready to be served. The
lid 50 is then coupled to the container 14. In the alternative
preferred embodiment, the act of securing the lid onto the
container causes the drive member 160 to be urged downwardly and
the first 182 and second 190 clutch parts to be rotatably locked
together as shown in FIG. 13. The condensate collector 90 is
positioned in the base receptacle 40 as shown in FIG. 6. The steam
chamber vessel 24 is filled with an appropriate amount of water and
the cover 26 of the steam chamber is secured thereto as shown in
FIG. 6. In the alternative preferred embodiment, the cover 140 of
the steam chamber is secured so that the steam exit port 146 is in
communication with the steam inlet port 194 of the container
128.
[0054] With reference to FIGS. 2 and 6, the container 14 and lid 50
are then mounted to the base 12 such that the lid 50 is supported
by the upper tier 48 and the annular gasket 85 forms a seal between
the lid and the condensate collector 90. The container and lid are
locked to the base by the complementary locking elements 82, 44 on
the lid and base, respectively. When locked to the base, the steam
exit port 36 is in fluid communication with the steam inlet passage
84. Electrical power is provided to the heater 22, causing the
water in the vessel 24 to boil and steam to be generated in the
steam chamber 16. The steam exits the steam chamber through the
steam exit port 36 and enters the container 14 through the steam
inlet passage 84 in the lid 50. The steam travels upwardly through
the screen 86, thereby cooking the food. As the steam condenses, it
returns to liquid form and drips through the screen 86 and onto the
inner surface of the lid 50. Because this surface is inclined in
the direction of the slotted opening 76, the condensate flows
towards the opening and into the condensate collector. The
apparatus may be provided with a timer (not shown) for setting the
cooking time. It may also include a circuit (not shown) for
terminating power to the heater 22 when the vessel no longer
contains water or the water level is below a preset minimum.
[0055] Once the food is cooked, the container is removed from the
base 12 and the condensate collector 90 is removed from the
receptacle 40. The container 14 is placed on the base in the
position shown in FIG. 5 such that its base portion 68 rests on the
bottom tier 46 of the receptacle 40 and the projections 70 enter
the bayonet-type slots of the first locking structure 42. The
container is rotated to lock it in position on the base 12.
Electrical power is supplied to the motor 18, causing the blade
assembly 20 to rotate and blend the contents of the container 14.
The blade assembly can be operated at a single speed or multiple
speeds, as known in the blender art. Condensate from the collector
90 can be added to the container through the slotted opening 76 in
the lid. Once the blending process is complete, the container
assembly is removed from the base 12 and the contents removed for
consumption or storage. The present invention permits the food to
be chopped/pureed or blended and steamed without the food being
touched by the user. It is also within the contemplation of the
present invention that the container 14 with its food contents may
be placed within the base to permit the food to be chopped and then
placed in an inverted position in the base so that the food may be
steam cooked.
[0056] In order to operate the sterilizing unit, in the embodiment
shown in FIG. 7, the sterilizing unit 97 is mounted on base 12 such
that the base receptacle 40 is disposed between the sterilization
unit 97 and the steam chamber 16. The housing extension 100 is
positioned adjacent the steam chamber such that the steam exit port
36 aligns with the steam inlet port 108. The sterilizing unit's
cover 104 may be removed so that bottles may be placed within the
sterilization chamber 98. In the embodiment shown in FIGS. 15 and
16, the sterilization unit 198 is positioned on the base 122
adjacent to the steam chamber 124. The cover 140 may then be
positioned and secured on the vessel 134 such that the steam exit
port 146 is aligned with the steam inlet port 212. The heating
element may then be energized to generate steam which flows into
the sterilization chamber.
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