A control method for a heating device and a heating device are provided. The heating device includes an electromagnetic wave generation module configured to generate an electromagnetic wave signal for heating an object to be processed. The control method includes: determining or obtaining attribute information of the object to be processed, the attribute information at least including food groups, and each of the food groups including at least one food variety; determining operating power and/or operating time of the electromagnetic wave generation module according to the attribute information; and controlling the electromagnetic wave generation module to operate according to the operating power and/or the operating time. Uneven heating and local overheating caused by different contents of substances in foods of different varieties are reduced as compared with using a fixed operating parameter.

An electromagnetic pulse additive device for a connection ring of a heavy-lift carrier rocket is provided. The device includes brackets, a gear disk rotatably matched with the annular ground rail through a plurality of rolls arranged in a circumferential direction of the gear disk, a first drive motor, an annular ground rail, and a guide rail in a semicircular shape arranged at top ends of the brackets. An output shaft of a first drive motor is fixedly provided with a first drive gear engaged with the gear disk. The guide rail is slidably provided with three lifting modules which respectively drive a bending module, an electromagnetic head arranged electromagnetic coil electrically connected with a capacitor and a discharge circuit, and a rotational friction and extrusion module including a second drive motor and a friction bar fixedly connected to an output shaft of the second drive motor to rise and fall.

A device for continuously heating foodstuffs includes a channel arranged to receive an electrically conductive liquid. Side walls of the channel include mutually opposite electrodes that are arranged in pairs which are connected to a current source. A first pair of mutually the opposite electrodes is arranged on the side walls of the channel at a distance along the channel. A second pair of mutually opposite electrodes is arranged in electrical contact with the interior of the channel. Each pair of electrodes is electrically connected to a respective one of separate secondary windings of a transformer of the current source. The secondary windings are arranged to be excited by at least one primary winding.

An injection molding device includes an injection machine, a molding die, and a high frequency oscillation device. The injection machine injects a resin material containing a dielectric heat generating material while keeping fluidity by temperature control. The molding die includes a cavity being a channel of flow of the resin material, and a pair of electrodes, each of which faces the cavity, the pair of electrodes being disposed to sandwich the resin material therebetween in a direction crossing a direction of the flow. The high frequency oscillation device applies a high frequency alternate-current voltage to the pair of electrodes.

An injection molding device includes an injection machine, a molding die, and a high frequency oscillation device. The injection machine injects a resin material containing a dielectric heat generating material while keeping fluidity by temperature control. The molding die includes a cavity being a channel of flow of the resin material, and a pair of electrodes, each of which faces the cavity, the pair of electrodes being disposed to sandwich the resin material therebetween in a direction crossing a direction of the flow. The high frequency oscillation device applies a high frequency alternate-current voltage to the pair of electrodes.

A thermal increase system may be coupled to a containment structure for containing a load. The system includes a plurality of shelf support structures disposed within a cavity. The plurality of shelf support structures is configured to support a repositionable electrode at a plurality of positions within the cavity. The system includes a first electrode disposed at a first surface of the containment structure, wherein the repositionable electrode is disposed within the containment structure so as to divide the cavity into separate volumes. The system includes a radio frequency signal source electrically connected to one or both of the first electrode and the repositionable electrode. The radio frequency signal source is configured to provide radio frequency energy to either or both of the first electrode and the repositionable electrode.

A thermal increase system may be coupled to a containment structure for containing a load. The system includes a plurality of shelf support structures disposed within a cavity. The plurality of shelf support structures is configured to support a repositionable electrode at a plurality of positions within the cavity. The system includes a first electrode disposed at a first surface of the containment structure, wherein the repositionable electrode is disposed within the containment structure so as to divide the cavity into separate volumes. The system includes a radio frequency signal source electrically connected to one or both of the first electrode and the repositionable electrode. The radio frequency signal source is configured to provide radio frequency energy to either or both of the first electrode and the repositionable electrode.

A method for chemical production includes applying electromagnetic heating to a composition that includes a catalytic component and an electromagnetic susceptor. Responsive to application of radio frequency energy, the electromagnetic susceptor causes the catalytic component to become heated. The heated electromagnetic susceptor and catalytic component interact with a chemical to form a product.

A method for chemical production includes applying electromagnetic heating to a composition that includes a catalytic component and an electromagnetic susceptor. Responsive to application of radio frequency energy, the electromagnetic susceptor causes the catalytic component to become heated. The heated electromagnetic susceptor and catalytic component interact with a chemical to form a product.

A refrigerator having a thawing device. The thawing device includes: a cavity, a device door, a radio frequency generator module, an upper electrode plate and a lower electrode plate, and a detection module, configured to detect an incident wave signal and a reflected wave signal of an electrical connection wire connecting the radio frequency generation module to the upper electrode plate, and calculate a load impedance of the radio frequency generation module according to a voltage and a current of the incident wave signal and a voltage and a current of the reflected wave signal to determine the thawing progress of the object to be processed.