The present invention discloses a flame simulating device, comprising a mist generating chamber, an atomizing head, an air orifice and a nozzle. The inside of the mist generating chamber is provided with a liquid and the atomizing head, the atomizing head being capable of atomizing the liquid inside the mist generating chamber, the two sides of the nozzle being set as Coanda curved surfaces, the cross section of the air orifice being in a constricted shape and providing an air flow blown upward such that under the Venturi effect, the air flow blown upward will guide and attract the mist from inside the mist generating chamber to vent out and flow into a nozzle inlet. Due to the Coanda curved surface on the side of the nozzle, the mist flows along both sides of the nozzle under the Coanda effect and then vents out of the nozzle.

An apparatus and method for aesthetic enhancement of indoor and outdoor living spaces combines fire, bubbling water and light reflection to foster enjoyment and relaxation. Wall assemblies having glass panes are spaced apart from each other to provide a chamber to hold water separate from a burner assembly. Air pumped into the water forms air bubbles in the water. A LED light strip illuminates the water, bubbles and glass panes in changing colors.

The present invention discloses a regulating mechanism regulating the flows from a plurality of gas outlets in a fuel gas valve, comprising an actuator, a push rod, a presser plate assembly, regulating rods and a valve body. Wherein the valve body has a plurality of gas outlets, a regulating rod is provided in each regulating port which exists between the gas inlet and each gas outlet, a resetting device is provided between each regulating rod and the valve body, and the actuator drives the push rod which is around by the regulating ports to move along the axis. The push rod causes the presser plate assembly to move up and down to press or relax the regulating rods and simultaneously change the degree of opening between the head portion of each regulating rod and the corresponding regulating port so that the flow from each gas outlet changes synchronously.

A multifunctional electric fireplace includes a casing, a main control board, a decorative light guide plate, a light emitting device, and a simulated charcoal. The decorative light guide plate is disposed on the inner wall of an accommodating chamber of the casing, so that the light of the light emitting device is irradiated on the side of the decorative light guide plate. The main control board controls the light change of the light emitting device, so that the decorative light guide plate exhibits various statics patterns or dynamic patterns to form realistic visual effects. The functions of simulation are diverse, which can meet the requirements for aesthetics.

A fireplace with a smart glass panel and use of a smart glass panel in a fireplace are provided. The fireplace comprises a heating mechanism, and a smart glass panel positioned proximate to the heating mechanism. The smart glass panel comprising a transparent pane, where at least a portion of the smart glass panel has optic or thermal transmission properties that may be altered between a first state and a second state.

The present invention discloses a simulated solid fuel, including a fuel body, a flow guiding device, a mist source and a light source. The fuel body houses a mist distribution chamber and an air directing chamber which are isolated from each other, and the surface of the fuel body includes mist outlets and mist inlets, the mist outlets and the mist inlets all communicating with the mist distribution chamber. The flow guiding device provides an upwardly rising air flow in the air directing chamber. The mist source delivers mist to the mist distribution chamber through the mist inlets, and is then attracted by the air flow injected from the air ejection port to move toward the middle area of the fuel body to form a flame shape, and is irradiated by the light emitted from the light source, thereby truly simulating the realistic effect of solid fuel combustion.

A flame simulating assembly is provided with a reflected flickering light that includes only one light source. Light from the light source passes through a rotating flicker element onto an angled reflector, or mirror, that reflects light up onto a simulated fuel bed and the some of the light is reflected off of the flicker elements towards a flame screen to create a simulated flame. The clipping flicker elements creates a fluttering light effect due to the flicker elements intermittently dipping into the light path. This fluctuating light is reflected onto the logs and ember bed in front and creates a dancing effect, which simulates glowing embers.

A flame simulating assembly is provided with a reflected flickering light that includes only one light source. Light from the light source passes through a rotating flicker element onto an angled reflector, or mirror, that reflects light up onto a simulated fuel bed and the some of the light is reflected off of the flicker elements towards a flame screen to create a simulated flame. The clipping flicker elements creates a fluttering light effect due to the flicker elements intermittently clipping into the light path. This fluctuating light is reflected onto the logs and ember bed in front and creates a dancing effect, which simulates glowing embers.

An electric fireplace includes a housing, a main control board, a flame processing device, a simulated wood, a light-emitting device, a light-reflecting device, and simulated bricks. All the inner walls of an accommodating chamber of the housing are bonded with the simulated bricks to form a three-dimensional brick wall effect. The flame-shaped light projects on the simulated bricks from a gap between the rear inner wall of the accommodating chamber and the simulated wood, enabling the flame burning effect of the electric fireplace to more three-dimensional.