According to one aspect, this disclosure describes a novel indirect weight sensing device, systems, and related processes. In at least one embodiment, the present systems include one or more springs with known properties, at least one metal plate on which the springs are fastened and through which the container load is transferred from the container to the ground, a spring deformation sensor by which spring deformation is reckoned, a digital level by which general orientation of the upper plate is determined relative to the ground, a computing unit to collect and process data from the spring deformation sensor and digital level, and an antenna or other such hardware to wirelessly connect to another device and interface with the computing unit.

According to one aspect, this disclosure describes a novel indirect weight sensing device, systems, and related processes. In at least one embodiment, the present systems include one or more springs with known properties, at least one metal plate on which the springs are fastened and through which the container load is transferred from the container to the ground, a spring deformation sensor by which spring deformation is reckoned, a digital level by which general orientation of the upper plate is determined relative to the ground, a computing unit to collect and process data from the spring deformation sensor and digital level, and an antenna or other such hardware to wirelessly connect to another device and interface with the computing unit.

The invention discloses a solar electronic scale which comprises a casing without an external interface; a panel is covered with the casing, and together with the casing forms an accommodating cavity; a display assembly is installed in the accommodating cavity, and can display various information to the outside; the sensing component is arranged on the casing and can be in contact with the support platform; wherein the sensing component is used to sense the target weighing object placed on the panel to obtain the target weighing object and transmit the weight information to the display assembly for display; the power supply component includes the battery and the solar charging component, both of which are arranged in the accommodating cavity; the battery is electrically connected to the display assembly, the induction component and the solar charging component, and can balance power consumption for power consumption components in the accommodating cavity through the solar charging assembly. The solar electronic scale can meet the needs of users for weighing anytime and anywhere, and is conducive to ensuring the weighing accuracy of the electronic scale.

The invention discloses a solar electronic scale which comprises a casing without an external interface; a panel is covered with the casing, and together with the casing forms an accommodating cavity; a display assembly is installed in the accommodating cavity, and can display various information to the outside; the sensing component is arranged on the casing and can be in contact with the support platform; wherein the sensing component is used to sense the target weighing object placed on the panel to obtain the target weighing object and transmit the weight information to the display assembly for display; the power supply component includes the battery and the solar charging component, both of which are arranged in the accommodating cavity; the battery is electrically connected to the display assembly, the induction component and the solar charging component, and can balance power consumption for power consumption components in the accommodating cavity through the solar charging assembly. The solar electronic scale can meet the needs of users for weighing anytime and anywhere, and is conducive to ensuring the weighing accuracy of the electronic scale.

An cooking apparatus for generating a load capacity of a object. The cooking apparatus may be the likes of a cooking stove appliance. The cooking apparatus further comprises a load capacity apparatus for sensing an object load capacity's.

The invention relates to a balancer (1) for a movable component with a component weight, having a spindle mechanism (32), on the rotation element (34) of which the component can be suspended, and at least one compression spring (30) which is connected, at one of its ends (29), to a translation element (36) of the spindle mechanism, wherein the compression spring is able to be compressed by means of the translation element in the event of a rotation of the rotation element brought about by the component weight.

The invention relates to a balancer (1) for a movable component with a component weight, having a spindle mechanism (32), on the rotation element (34) of which the component can be suspended, and at least one compression spring (30) which is connected, at one of its ends (29), to a translation element (36) of the spindle mechanism, wherein the compression spring is able to be compressed by means of the translation element in the event of a rotation of the rotation element brought about by the component weight.

According to one aspect, this disclosure describes a novel indirect weight sensing device, systems, and related processes. In at least one embodiment, the present systems include one or more springs with known properties, at least one metal plate on which the springs are fastened and through which the container load is transferred from the container to the ground, a spring deformation sensor by which spring deformation is reckoned, a digital level by which general orientation of the upper plate is determined relative to the ground, a computing unit to collect and process data from the spring deformation sensor and digital level, and an antenna or other such hardware to wirelessly connect to another device and interface with the computing unit.

According to one aspect, this disclosure describes a novel indirect weight sensing device, systems, and related processes. In at least one embodiment, the present systems include one or more springs with known properties, at least one metal plate on which the springs are fastened and through which the container load is transferred from the container to the ground, a spring deformation sensor by which spring deformation is reckoned, a digital level by which general orientation of the upper plate is determined relative to the ground, a computing unit to collect and process data from the spring deformation sensor and digital level, and an antenna or other such hardware to wirelessly connect to another device and interface with the computing unit.

According to one aspect, this disclosure describes a novel indirect weight sensing device, systems, and related processes. In at least one embodiment, the present systems include one or more springs with known properties, at least one metal plate on which the springs are fastened and through which the container load is transferred from the container to the ground, a spring deformation sensor by which spring deformation is reckoned, a digital level by which general orientation of the upper plate is determined relative to the ground, a computing unit to collect and process data from the spring deformation sensor and digital level, and an antenna or other such hardware to wirelessly connect to another device and interface with the computing unit.