A modular pyrotechnic launch unit includes a launch module, a first module, and a second module. The launch module includes a launch barrel. The first module is coupled in series to the launch module. The first module includes a first ignition state in which the first module ignites a pyrotechnic element that will then pass through the launch barrel. The first module also includes a first pass-through state in which the first module allows a pyrotechnic element ignited by another module to pass through the first module. The second module is coupled in series to the first module. The second module includes a second ignition state in which the second module ignites a pyrotechnic element that will then pass through the first module and through the launch barrel.

A modular pyrotechnic launch unit includes a launch module, a first module, and a second module. The launch module includes a launch barrel. The first module is coupled in series to the launch module. The first module includes a first ignition state in which the first module ignites a pyrotechnic element that will then pass through the launch barrel. The first module also includes a first pass-through state in which the first module allows a pyrotechnic element ignited by another module to pass through the first module. The second module is coupled in series to the first module. The second module includes a second ignition state in which the second module ignites a pyrotechnic element that will then pass through the first module and through the launch barrel.

A modular pyrotechnic launch unit includes a launch module, a first module, and a second module. The launch module includes a launch barrel. The first module is coupled in series to the launch module. The first module includes a first ignition state in which the first module ignites a pyrotechnic element that will then pass through the launch barrel. The first module also includes a first pass-through state in which the first module allows a pyrotechnic element ignited by another module to pass through the first module. The second module is coupled in series to the first module. The second module includes a second ignition state in which the second module ignites a pyrotechnic element that will then pass through the first module and through the launch barrel.

A modular pyrotechnic launch unit includes a launch module, a first module, and a second module. The launch module includes a launch barrel. The first module is coupled in series to the launch module. The first module includes a first ignition state in which the first module ignites a pyrotechnic element that will then pass through the launch barrel. The first module also includes a first pass-through state in which the first module allows a pyrotechnic element ignited by another module to pass through the first module. The second module is coupled in series to the first module. The second module includes a second ignition state in which the second module ignites a pyrotechnic element that will then pass through the first module and through the launch barrel.

A cold spark fire electronic eruptive apparatus characterized in that the erupting apparatus is comprised of an ejecting unit, an activation unit, a power unit, and a storage unit, wherein, the storage unit stores a cold fireworks material for discharge, the power unit is connected to the storage unit and also is connected with a heating unit, the power unit transmitting the cold fireworks material in the storage unit to the heating unit, and the heating unit activating the cold fireworks raw material, sending it to the air removal unit for eruption.

A cold spark fire electronic eruptive apparatus characterized in that the erupting apparatus is comprised of an ejecting unit, an activation unit, a power unit, and a storage unit, wherein, the storage unit stores a cold fireworks material for discharge, the power unit is connected to the storage unit and also is connected with a heating unit, the power unit transmitting the cold fireworks material in the storage unit to the heating unit, and the heating unit activating the cold fireworks raw material, sending it to the air removal unit for eruption.

A cold spark waterfall machine, which comprises an accelerating unit, a heating unit, a power unit, and a storage unit. The storage unit stores a cold fireworks raw material for discharging. The power unit is connected to the storage unit wherein the storage unit is connected with the heating unit, and the power unit transmits the cold fireworks raw material in the storage unit to the heating unit. The heating unit activates the cold fireworks raw material and sends the cold fireworks raw material to the acceleration unit. The acceleration unit causes the activated material to accelerate in a downward eruption, thus forming a waterfall of low temperature sparks.

A cold spark waterfall machine, which comprises an accelerating unit, a heating unit, a power unit, and a storage unit. The storage unit stores a cold fireworks raw material for discharging. The power unit is connected to the storage unit wherein the storage unit is connected with the heating unit, and the power unit transmits the cold fireworks raw material in the storage unit to the heating unit. The heating unit activates the cold fireworks raw material and sends the cold fireworks raw material to the acceleration unit. The acceleration unit causes the activated material to accelerate in a downward eruption, thus forming a waterfall of low temperature sparks.

The present disclosure provides a cold firework spurting apparatus, comprising: a feeding device; a conveying device; a heating mechanism; and a spurting device configured to ignite and spurt the metal powder heated by the heating mechanism, wherein an output end of the feeding device is open to the conveying device and an output end of the conveying device is open to the spurting device. Accordingly, the metal powder inside the conveying device is continuously heated by the heating mechanism attached to the conveying device during the conveying process such that the metal powder is constantly heated during the conveying process so as to form the metal powder ignited at high temperature. The ignited metal powder at high temperature is led and spurted outwards by means of an air flow formed by the spurting device so as to form a spurting effect of cold firework.

The present disclosure provides a cold firework spurting apparatus, comprising: a feeding device; a conveying device; a heating mechanism; and a spurting device configured to ignite and spurt the metal powder heated by the heating mechanism, wherein an output end of the feeding device is open to the conveying device and an output end of the conveying device is open to the spurting device. Accordingly, the metal powder inside the conveying device is continuously heated by the heating mechanism attached to the conveying device during the conveying process such that the metal powder is constantly heated during the conveying process so as to form the metal powder ignited at high temperature. The ignited metal powder at high temperature is led and spurted outwards by means of an air flow formed by the spurting device so as to form a spurting effect of cold firework.