A mannequin for supporting a pair of trousers whereon a laser marking is performed, having two leg structures housed inside the trouser legs. Each structure has a longitudinal axis, upper and lower areas, front and rear planes, an inner side and outer side. The separation between the inner and outer sides varies due to the tensing mechanism in order to go from a non-operative loosened position (A) to a maximum tensed end position (B) to perform the marking. Each leg structure is coupled to a respective main rotation axis around which rotates by a respective articulation having the mannequin for each leg structure. The main rotation axis is parallel to the direction of the dimension of the rise of the pair of trousers or collinear with it. The front planes can form at least two angles greater and/or less than 180° when rotated around the respective main rotation axes thereof.

A mannequin for supporting a pair of trousers whereon a laser marking is performed, having two leg structures housed inside the trouser legs. Each structure has a longitudinal axis, upper and lower areas, front and rear planes, an inner side and outer side. The separation between the inner and outer sides varies due to the tensing mechanism in order to go from a non-operative loosened position (A) to a maximum tensed end position (B) to perform the marking. Each leg structure is coupled to a respective main rotation axis around which rotates by a respective articulation having the mannequin for each leg structure. The main rotation axis is parallel to the direction of the dimension of the rise of the pair of trousers or collinear with it. The front planes can form at least two angles greater and/or less than 180° when rotated around the respective main rotation axes thereof.

The present application discloses a mannequin. The mannequin includes: a support frame; plates, being configured to enclose the shell of the torso, and comprising driving plates; circumference regulating devices, being configured to support the driving plate and driving it to move; the torso comprising a plurality of regulating regions provided with the driving plates, the plates further comprising driven plates capable of moving together with the driving plates when driven by the driving plates, and at least one of the plurality of regulating regions is provided with the driven plate. Relaxation and contraction of the overall outline of the torso can be achieved simply by controlling the movement of the plates by transmission devices, and the size of the chest, waist, abdomen and hip circumferences of the mannequin can be adjusted, thereby accurately simulating the figure of the human body and achieving high adjustment accuracy.

An adjustable three dimensional mannequin head is provided for fitting a variety of head gear including but not limited to wigs, hats, caps, helmets and similar items. The adjustable mannequin head consist of a plurality of parts that move in a synchronized manner to expand and contract the size of the adjustable mannequin head to allow fitting to size; wigs, hats, and similar items. The mannequin head consist of four quadrants that make up the crown of the head. These four quadrants are mechanically adjusted by a single screw, which when turned will either expand or contract the adjustable mannequin head based on the direction the screw is turned. The adjustable mannequin head provides matching and fitting head gear to individual heads.

A body-size-adjustable dressmaker form includes a central-support adjusting system, a neck adjusting system, a chest adjusting system, a waist adjusting system, a hip adjusting system, an arm adjusting system, a base and an upper-body outer housing. The chest adjusting system, the waist adjusting system and the hip adjusting system each include a multi-axis synchronous co-directional adjusting device and an adjusting knob. The central-support adjusting system includes an upper-body support assembly provided with mounting positions adapted to the multi-axis synchronous co-directional adjusting devices. Each multi-axis synchronous co-directional adjusting device includes a telescopic structural member connected with the adjusting knob. Multiple housing units are sequentially connected to form the upper-body outer housing, and the multiple housing units are connected with the telescopic structural members respectively. When the adjusting knob is rotated, the telescopic structural members drive the housing units to move close to or away from each other.

A body-size-adjustable dressmaker form includes a central-support adjusting system, a neck adjusting system, a chest adjusting system, a waist adjusting system, a hip adjusting system, an arm adjusting system, a base and an upper-body outer housing. The chest adjusting system, the waist adjusting system and the hip adjusting system each include a multi-axis synchronous co-directional adjusting device and an adjusting knob. The central-support adjusting system includes an upper-body support assembly provided with mounting positions adapted to the multi-axis synchronous co-directional adjusting devices. Each multi-axis synchronous co-directional adjusting device includes a telescopic structural member connected with the adjusting knob. Multiple housing units are sequentially connected to form the upper-body outer housing, and the multiple housing units are connected with the telescopic structural members respectively. When the adjusting knob is rotated, the telescopic structural members drive the housing units to move close to or away from each other.

The present disclosure discloses a human body simulation model, a fitting device, a fitting server, and a control method. The human body simulation model includes: a human body model; a photodeformable shaping garment; a plurality of excitation light sources; a plurality of elastic elements; and a first controller configured to control at least a part of the plurality of excitation light sources to emit light waves to the photodeformable shaping garment according to body shape parameters of a user received, so that the photodeformable shaping garment is deformed to simulate a body shape of the user.

Aspects herein are directed to a support garment testing system comprising a torso form having a motion tracking sensor associated with one or more breast structures of the torso form. A support garment is secured to the torso form, and the torso form is mounted on a motion platform that, when actuated, causes displacement of the breast structures. The amount of displacement is measured by the sensor, and the data is used to assign a level of support provided by the support garment.

A dress form stand has a joint connector formed as a socket body. The socket body has a socket for connecting to a vertical post, and the vertical post connects to a dress form. A plurality of swivel legs each have a hook joint formed as a hook, and each swivel leg has a leg abutment inside surface that opposes the abuts against a socket body inside abutment surface formed on the socket body when the hook joint is in an engaged configuration. A plurality of leg extension tips are formed at a distal end of the plurality of swivel legs.

A garment manikin (mannequin) limb catcher to prevent damage to manikin limbs caused by accidental bumps once the limb is attached to a manikin torso. In situations where a manikin limb is attached to a torso by magnets, a bump to the limb can break the magnetic holding force, thus causing the limb to fall. This invention describes a limb with lead-in pin that has a bent tip, the pin being inserted into a hole on the torso. If bumped, the bent tip will catch on the hole's rim and prevent the limb from falling. In another variant, the torso can have the lead-in pin with a bend, and the limb has a hole. The pin with a bent tip acts as a catching element, and the hole acts as a stopping element.