1. Field of the Invention
The present invention relates to infant support apparatuses, and more particularly to infant support apparatuses capable of rocking motions.
2. Description of the Related Art
It is well known that gentle and regular rocking motions can help to soothe young children. Accordingly, multiple types of devices have been developed to recreate an appropriate rocking motion that can soothe children, which include bouncing apparatuses, travel swings, gliders and rocking apparatuses. However, the existing devices may have some disadvantages. For example, baby cradles may not be easy to collapse for storage or transport. Other rocking supports may have a support structure where the child is placed that is held on support legs at a relatively high position, which may be detrimental to its stability.
Therefore, there is a need for an infant supporting apparatus that is capable of rocking motions, and can address at least the foregoing issues.
The present application describes an infant supporting apparatus. The infant supporting apparatus includes a base frame, a support frame and a resting support. The base frame includes a first and a second leg frame portion pivotally connected with each other about a first pivot axis, wherein the first and second leg frame portions have foot portions. The support frame is assembled with the base frame, and includes a first and a second support frame portion pivotally connected with each other about a second pivot axis spaced apart from the first pivot axis, the first and second pivot axes being vertically aligned with each other. The resting support is suspended from the first and second support frames for receiving the placement of a child. In some configurations, the infant supporting apparatus is provided with additional functional features including a recline adjustment mechanism for the resting support, a stabilizing structure operable to keep the infant supporting apparatus stationary, and a detachable vibrating unit operable to impart vibration to the resting support.
Likewise, the leg frame portion 110 can be formed as a unitary tubular assembly of a U-like shape including two spaced-apart leg segments 110A and 110B, and a foot portion 110C of a curved shape extending along the pivot axis X1 between the two leg segments 110A and 110B. The foot portion 110C can be connected with the two leg segments 110A and 110B adjacent to the lower ends thereof. In a deployed state, the leg segments 110A and 110B can likewise rise upward in a same direction toward the pivot axis X1.
The two upper ends of the leg segments 108A and 110A can be pivotally connected with each other via a pivot structure 112A, and the two upper ends of the leg segments 108B and 110B can be pivotally connected with each other via a pivot structure 112B. The two pivot structures 112A and 112B can have the same pivot axis X1, and respectively form two apexes of the base frame 104. Accordingly, the two leg frame portions 108 and 110 can be operable to rotate about the pivot axis X1 toward each other when the frame structure 102 is collapsed, and away from each other when the frame structure 102 is deployed for use. In one embodiment, at least one of the two pivot structures 112A and 112B (e.g., the pivot structure 112A) may also include a latch mechanism that may be operable to lock the two leg frame portions 108 and 110 in the deployed state. The latch mechanism may be unlocked by pressing a release button 114 provided on an outer side of the pivot structure 112A.
Referring again to
More specifically, the support frame portion 118 can be formed as a unitary tubular assembly including two spaced-apart support segments 118A and 118B, and a lateral segment 118C extending along the pivot axis X2 between the two support segments 118A and 118B. The lateral segment 118C can be connected with the two side segments 118A and 118B adjacent to the upper ends thereof. The two support segments 118A and 118B can bend from the lateral segment 118C and extend in a same direction toward the pivot axis X2.
Likewise, the support frame portion 120 can be formed as a unitary tubular assembly including two spaced-apart support segments 120A and 120B, and a lateral segment 120C extending along the pivot axis X2 between the two support segments 120A and 120B. The lateral segment 120C can be connected with the two side segments 120A and 120B adjacent to the upper ends thereof. The two support segments 120A and 120B can bend from the lateral segment 120C and extend in a same direction toward the pivot axis X2.
The two lower ends of the support segments 118A and 120A can be pivotally connected with each other via a pivot structure 122A, and the two lower ends of the support segments 118B and 120B can be pivotally connected with each other via a pivot structures 122B. The two pivot structures 122A and 122B can have the same pivot axis X2. The pivot axis X2 can be vertically aligned with the pivot axis X1, and can be located under the pivot axis X1. The support segments 118A and 120A once assembled together can form a V-like shape and respectively converge from the lateral segments 118C and 120C to the pivot structure 122A. The support segments 118B and 120B once assembled together can likewise form a V-like shape and respectively converge from the lateral segments 118C and 120C to the pivot structure 122B.
In addition, the support segments 118A and 118B of the support frame portion 118 can be respectively connected pivotally with the leg segments 108A and 108B of the leg frame portion 108 about a pivot axis X3, and the support segments 120A and 120B of the support frame portion 120 can be respectively connected pivotally with the leg segments 110A and 110B of the leg frame portion 110 about a pivot axis X4. The two locations where the support segments 118A and 120A are respectively connected with the leg segments 108A and 110A can be symmetrical relative to a vertical axis intersecting the pivot axes X1 and X2, and lower than the pivot axis X1. Likewise, the two locations where the support segments 118B and 120B are respectively connected with the leg segments 108B and 110B can be symmetrical relative to the vertical axis intersecting the pivot axes X1 and X2, and lower than the pivot axis X1.
In some embodiments, the pivot connections implemented between the support segments 118A and 118B of the support frame portion 118 and the leg segments 108A and 108B of the leg frame portion 108 can use conventional rivet assemblies. In other embodiments, concealed type rivet assemblies may be implemented for the pivot connections between the support segments 118A and 118B of the support frame portion 118 and the leg segments 108A and 108B of the leg frame portion 108.
In conjunction with
In conjunction with
For mounting the coupling part 126 with the leg segment 108A, the column 132 can be inserted through an opening 140 of the leg segment 108A into its interior. As the column 132 travels through the opening 140, the rim of the opening 140 can press the barbs 136 toward the column 132. Once the column 132 is fully inserted inside the leg segment 108A, the base 130 can lie adjacent to an outer surface of the leg segment 108A, and the barbs 136 can deflect outward and abut against an inner surface of the leg segment 108A around the opening 140 to prevent disassembly of the coupling part 126. The rivet 128 assembled with the support segment 118A then can be inserted from the side of the base 130 through the hole 138, until a head 128A of the rivet 128 travels past the distal end of the hole 138 and engages with the flange 134 inside the leg segment 108A. The leg segment 108A and the support segment 118A can be thereby pivotally assembled with each other. It is noted that the same pivot connection 124 can be applied to pivotally connect each of the leg segments 108A and 108B with the corresponding support segments 118A and 118B. The pivot connection 124 is realized only from the inner side of the frame structure 102 (i.e., the side facing the central region of the base frame 104 where is placed the resting support 103), and cannot be visible from an outer sidewall of the leg segment 108A facing the outside of the infant supporting apparatus 100. Accordingly, the outer appearance of the frame structure 102 can be improved.
Referring again to
Referring to
The bottom portion 146 can have a torso portion 148 adapted to support the back or trunk of the child, and a foot portion 150 adapted to support the leg and/or feet of the child. When a child is placed on the bottom portion 146, the head of the child is located in a head resting area close to the support segments 118B and 120B, and the foot of the child can be disposed adjacent to the foot portion 150 near the support segments 118A and 120A.
In one embodiment, the resting support 103 can also include a recline adjustment mechanism 152 operable to adjust an angle of inclination of the torso portion 148 relative to the lateral segments 118C and 120C of the support frame portions 118 and 120. As shown in
The lock device 156 can be affixed with the lateral segment 118C. In one embodiment, the lock device 156 can be constructed as a clamping device operable to clamp and release the strap 154. The lock device 156 can have a release tab 158 that can be actuated by a caregiver to unlock the lock device 156. When the lock device 156 is in a locked state, travel of the strap 154 through the lock device 156 is blocked so as to fix a length of the strap 154 joining the two lateral segments 118C and 120C. When the lock device 156 is unlocked, the strap 154 can be pulled to slide through the lock device 156 so as to adjust the length of the strap 154 joining the two lateral segments 118C and 120C: an increase of the length of the strap 154 joining the two lateral segments 118C and 120C can result in lowering the torso portion 148 relative to the lateral segments 118C and 120C to a recline position, and a decrease of the length of the strap 154 joining the two lateral segments 118C and 120C can result in rising the torso portion 148 relative to the lateral segments 118C and 120C to an upright position. The position of the lock device 156 can allow easy access and operation for adjusting the inclination of the torso portion 148 according to the needs.
Referring again to
When the infant supporting apparatus 100 is unused, the frame structure 102 can be folded to a collapsed state as shown in
In conjunction with
The adjustable foot 168 can have a first surface 168A and a second surface 168B extending at an angle relative to each other, and an inner cavity 168C. The adjustable foot 168 can be snapped over the base 166, so that the base 166 is partially received in the inner cavity 168C and the first surface 168A smoothly prolongs the lower surface 166A of the base 166. In this configuration, the pad assembly 164 does not extend below the lowest point of the leg frame portions 108 and 110.
When the infant supporting apparatus 100 has to be kept stationary, the stabilizing structure 162 can be deployed by rotating downward the adjustable foot 168 of each pad assembly 164 so that the second surface 168B can lie below the lowest point of the leg frame portions 108 and 110 and rest against the ground surface. The pad assemblies 164 can thereby provide multiple stabilizing contact points against the ground surface that can block the rocking motion and keep the infant supporting apparatus 100 stationary. A stationary configuration of the infant supporting apparatus 100 may be needed, e.g., for feeding, nap time, or the like.
Multiple arrangements may be possible for the pad assemblies 164. In the embodiment shown in
In other embodiments (not shown), four pad assemblies 164 may be respectively provided at the four lower corner regions of the base frame 104. When this configuration of the stabilizing structure 162 is deployed, the infant supporting apparatus 100 can be held stationary in a position where the foot portions 108C and 110C do not contact with the ground surface.
For attaching the vibrating unit 170 with the pivot structure 122A, the outer shell assembly 188 can be inserted in the recess 176 of the outer housing 172, until the keying rib 182 mates with the groove 192 and the knobs 180A and 180B respectively engage with the recesses 190A and 190B. The engagement of the keying rib 182 with the groove 192 can block rotation of the vibrating unit 170. Once the vibrating unit 170 is powered on, vibration can be effectively transmitted from the pivot structure 122A through the two support frame portions 118 and 120 to the resting support 103. Vibration dispersion through the base frame 104 can be prevented owing to the firm engagement between the vibrating unit 170 and the pivot structure 122A.
When the vibrating unit 170 is not needed, the caregiver can apply a downward force on the vibrating unit 170, which forces the detent 184 to deflect for disengaging the knob 180B from the recess 190B. The vibrating unit 170 then can be removed from the pivot structure 122A.
The structures as described herein can include various advantages. With the symmetrical frame structure, the weight load can be transmitted from the support segments directly to the leg segments to which they are respectively assembled, which can provide a stronger design. Moreover, the infant supporting apparatus is easy to collapse and deploy, and has a better appearance.
In addition, the recline adjustment mechanism, the stabilizing structure and the vibrating unit may add functional features that can advantageously modify the configuration of the infant supporting apparatus according to the needs of the caregiver and provide comfort to the child. It will be understood that the frame structure as described herein may also be implemented without these functional features, or with any combination of one or more of these functional features.
Therefore, realizations of the infant supporting apparatus have been described in the context of particular embodiments. These embodiments are meant to be illustrative and not limiting. Many variations, modifications, additions, and improvements are possible. These and other variations, modifications, additions, and improvements may fall within the scope of the inventions as defined in the claims that follow.
This application claims priority to U.S. Provisional Patent Application No. 61/689,389 filed on Jun. 5, 2012, the entirety of which is incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
341238 | Heinss | May 1886 | A |
1463571 | Brame | Jul 1923 | A |
3344443 | Bounell | Oct 1967 | A |
4377011 | Kinberger | Mar 1983 | A |
4996732 | Chang | Mar 1991 | A |
5307531 | Kao | May 1994 | A |
5496094 | Schwartzkopf et al. | Mar 1996 | A |
5694655 | Shepler et al. | Dec 1997 | A |
6386986 | Sonner et al. | May 2002 | B1 |
6851745 | nee Wilkins et al. | Feb 2005 | B2 |
8142297 | Zhang | Mar 2012 | B2 |
20070257534 | Schulte et al. | Nov 2007 | A1 |
20100163088 | Zeng | Jul 2010 | A1 |
20100255919 | Kelly et al. | Oct 2010 | A1 |
20110148155 | Chapman et al. | Jun 2011 | A1 |
20130012329 | Burns et al. | Jan 2013 | A1 |
Number | Date | Country |
---|---|---|
738030 | Oct 1955 | GB |
2214421 | Sep 1989 | GB |
2427152 | Dec 2006 | GB |
2447099 | Sep 2008 | GB |
Number | Date | Country | |
---|---|---|---|
20130318709 A1 | Dec 2013 | US |
Number | Date | Country | |
---|---|---|---|
61689389 | Jun 2012 | US |