In a patient simulator, in particular a premature baby, newborn or child simulator, including a simulated thorax, a pneumatic lung simulator and a simulated trachea leading to the lung simulator, wherein the simulated thorax includes a simulated chest including at least one liftable and lowerable chest element to simulate lifting and lowering of the chest, the at least one liftable and lowerable chest element cooperates with a lifting and lowering mechanism actuatable independently of the lung simulator.

A robot 150 is placed on a touch panel. When touch sensor action sections 156a to 156c provided on a bottom face 150b of the robot act on a touch pad, an information processing device shows a face image in a rectangular area 16 of a display screen 14 of the touch panel. The rectangular area 16 corresponds to the bottom face of the robot. The face image is grabbed from the bottom face 150b of the robot 150 and appears in a face section 152. Further, the brightness of pixels in areas 18a and 18b of the display screen 14 is changed. The areas 18a and 18b correspond to optical sensors 160a and 160b provided on the bottom face 150b of the robot. The robot 150 detects the change in question, converting the change into a motion of an internal actuator, sound output, light emission, and so on in accordance with predetermined rules.

A robot 150 is placed on a touch panel. When touch sensor action sections 156a to 156c provided on a bottom face 150b of the robot act on a touch pad, an information processing device shows a face image in a rectangular area 16 of a display screen 14 of the touch panel. The rectangular area 16 corresponds to the bottom face of the robot. The face image is grabbed from the bottom face 150b of the robot 150 and appears in a face section 152. Further, the brightness of pixels in areas 18a and 18b of the display screen 14 is changed. The areas 18a and 18b correspond to optical sensors 160a and 160b provided on the bottom face 150b of the robot. The robot 150 detects the change in question, converting the change into a motion of an internal actuator, sound output, light emission, and so on in accordance with predetermined rules.

In an aspect, a toy assembly is provided, and includes a toy assembly housing, an extensible object inside the toy assembly housing, an extension mechanism, and an extension member power source. The extensible object includes a base, and first and second extension members. The extension mechanism is operable to drive the first and second extension members towards extended positions, and is operatively connected to the second extension member via a lost motion connection. Driving of the extension mechanism by the extension mechanism power source drives the first extension member towards the extended position for the first extension member to break or open the toy assembly housing to expose the extensible object while consuming at least a portion of the lost motion in the lost motion connection. Upon consuming the lost motion, further driving the extension mechanism drives the first and second extension members towards the extended positions.

The present disclosure and related inventions describe a greeting card with audio capabilities and party blower. The greeting card can include a squeeze trigger which initiates audio playback and the unfurling of the party blower. Release of the squeeze trigger causes the retraction of the party blower.

An articulating mechanical toy including a universal docking mechanism having a left articulating wing, and a right articulating wing is provided. The left articulating wing assembly and the right articulating wing assembly each include a first linkage that may be attached at a respective one of the opposite ends of the docking mechanism. Each respective wing may also include a pair of movable linkages that are connected in series and are removably attachable to a respective primary linkage. Disposed about each movable linkage are a plurality of feather like elements that are coupled to one another via monofilament suture. The articulating toy mechanism is configured and designed to be controlled by a user (e.g., a child). The mechanical toy may include interchangeable left and right wing assemblies and may be interchangeably, attached to a plurality of toys—such as action figures—via the docking mechanism.

A toy doll with a reconfigurable clothing article is disclosed. In particular, a toy doll with a reconfigurable clothing article and an electronic system that generates outputs is disclosed. In one embodiment, the clothing article can be reconfigured relative to the body of the toy doll. In one embodiment, the body of the toy doll includes a display portion that can be used to generate various visual displays.

A toy building block robot and a main control box thereof are disclosed. The main control box comprises a toy building-block robot main control housing, a toy building-block robot main control board, and a battery. The toy building-block robot main control board is installed in the toy building-block robot main control housing. The battery is connected to the toy building-block robot main control board, so as to supply power to the toy building-block robot main control board. A plurality of connection mechanisms are disposed on the toy building-block robot main control housing for engaging the toy building-block robot main control housing with other components of the toy building block robot. In the present disclosure, whether the assembly of the components in the main control box, or the engagement between the main control box and other components of the toy building block robot, can both be realized through a connection mechanism.

In an aspect, a toy assembly is provided, and includes a toy assembly housing, an extensible object inside the toy assembly housing, an extension mechanism, and an extension member power source. The extensible object includes a base, and first and second extension members. The extension mechanism is operable to drive the first and second extension members towards extended positions, and is operatively connected to the second extension member via a lost motion connection. Driving of the extension mechanism by the extension mechanism power source drives the first extension member towards the extended position for the first extension member to break or open the toy assembly housing to expose the extensible object while consuming at least a portion of the lost motion in the lost motion connection. Upon consuming the lost motion, further driving the extension mechanism drives the first and second extension members towards the extended positions.

A robot according to an embodiment of the present invention includes: a head part; an ear rotatably connected to the head part; a moving frame connected to the head part, the moving frame moving vertically to allow the ear to rotate; a neck body coupled to the heat part; a main actuator configured to allow the neck body to rotate; and sub actuator configured to allow the moving frame to move vertically. The main actuator and the sub actuator may be disposed to be symmetrical to each other with respect to the neck body.