The present invention provides devices and methods for the impregnation of air with the vapor or aerosol of a substance in a ‘controllable manner to enable the testing or training of detection means to evaluate and quantify the presence of the substance in an enclosed volume, and iη• particular to enable production of training aids and quality assurance test items for use in canine-olfaction based security screening.

A vehicle for detecting and neutralizing an incendiary object comprises a detecting device configured to mount at fore-end of the vehicle is disclosed. The detecting device comprises: one or more platforms configured to be mounted at the fore end of the vehicle. The one or more platforms are located proximal to the ground surface such that they hover over the ground surface at a predetermined distance. A plurality of sensors wherein each of the plurality of sensors mounted on the at least one of the one or more platforms for capturing information related to the incendiary object. A neutralizing device interfaced with the detecting device, wherein the neutralizing device comprises: a neutralizing arm member which actuates in one or more directions for handling and neutralizing the incendiary object based on the information related to the incendiary object. An annihilator device equipped with the neutralizing device to annihilate the incendiary object.

A vehicle for detecting and neutralizing an incendiary object comprises a detecting device configured to mount at fore-end of the vehicle is disclosed. The detecting device comprises: one or more platforms configured to be mounted at the fore end of the vehicle. The one or more platforms are located proximal to the ground surface such that they hover over the ground surface at a predetermined distance. A plurality of sensors wherein each of the plurality of sensors mounted on the at least one of the one or more platforms for capturing information related to the incendiary object. A neutralizing device interfaced with the detecting device, wherein the neutralizing device comprises: a neutralizing arm member which actuates in one or more directions for handling and neutralizing the incendiary object based on the information related to the incendiary object. An annihilator device equipped with the neutralizing device to annihilate the incendiary object.

An explosive detection system may include a suction nozzle having a suction port for introducing air containing explosive particles at one end thereof, a discharge nozzle having a discharge port for discharging air at one end thereof, a sensing block in which a detection material capable of detecting explosive particles in the air is disposed, a sensor unit for emitting light to the sensing block and outputting a sensing signal, a first guide pipe connected to the other end of the suction nozzle and guiding the air introduced through the suction nozzle to the sensing block in which the detection material is disposed, a suction force generating unit formed at the other end of the discharge nozzle and to suck air through the suction port and to provide a suction force for sucking air into the sensing block and discharging the air to a discharge port formed at one end of the discharge nozzle, a second guide pipe formed between the sensing block and the suction force generating unit and discharging the air introduced into the sensing block by the suction force generated by the suction force generating unit to the discharge port of the discharge nozzle, and a controller for determining whether explosive particles are present in the air using the sensing signal.

An explosive detection system may include a suction nozzle having a suction port for introducing air containing explosive particles at one end thereof, a discharge nozzle having a discharge port for discharging air at one end thereof, a sensing block in which a detection material capable of detecting explosive particles in the air is disposed, a sensor unit for emitting light to the sensing block and outputting a sensing signal, a first guide pipe connected to the other end of the suction nozzle and guiding the air introduced through the suction nozzle to the sensing block in which the detection material is disposed, a suction force generating unit formed at the other end of the discharge nozzle and to suck air through the suction port and to provide a suction force for sucking air into the sensing block and discharging the air to a discharge port formed at one end of the discharge nozzle, a second guide pipe formed between the sensing block and the suction force generating unit and discharging the air introduced into the sensing block by the suction force generated by the suction force generating unit to the discharge port of the discharge nozzle, and a controller for determining whether explosive particles are present in the air using the sensing signal.

A training aid for use in training canines to detect an explosive material includes an explosive material adsorbed in the pores of a high surface area mesoporous or nanoporous host material. By adjusting the surfaces of the pores of the substrate material, the substrate can accommodate various types of explosive materials in a non-detonable and non-flammable manner, including nitroaromatics, nitroamines, nitrate-based explosives, and peroxide-based explosives. When the training aid is in an unsealed condition, a continuous flux of explosive material is released without providing any explosive or flame hazard to the trainer and canine.

A training aid for use in training canines to detect an explosive material includes an explosive material adsorbed in the pores of a high surface area mesoporous or nanoporous host material. By adjusting the surfaces of the pores of the substrate material, the substrate can accommodate various types of explosive materials in a non-detonable and non-flammable manner, including nitroaromatics, nitroamines, nitrate-based explosives, and peroxide-based explosives. When the training aid is in an unsealed condition, a continuous flux of explosive material is released without providing any explosive or flame hazard to the trainer and canine.

An explosive detection system may include a suction nozzle having a suction port for introducing air containing explosive particles at one end thereof, a discharge nozzle having a discharge port for discharging air at one end thereof, a sensing block in which a detection material capable of detecting explosive particles in the air is disposed, a sensor unit for emitting light to the sensing block and outputting a sensing signal, a first guide pipe connected to the other end of the suction nozzle and guiding the air introduced through the suction nozzle to the sensing block in which the detection material is disposed, a suction force generating unit formed at the other end of the discharge nozzle and to suck air through the suction port and to provide a suction force for sucking air into the sensing block and discharging the air to a discharge port formed at one end of the discharge nozzle, a second guide pipe formed between the sensing block and the suction force generating unit and discharging the air introduced into the sensing block by the suction force generated by the suction force generating unit to the discharge port of the discharge nozzle, and a controller for determining whether explosive particles are present in the air using the sensing signal.

An explosive detection system may include a suction nozzle having a suction port for introducing air containing explosive particles at one end thereof, a discharge nozzle having a discharge port for discharging air at one end thereof, a sensing block in which a detection material capable of detecting explosive particles in the air is disposed, a sensor unit for emitting light to the sensing block and outputting a sensing signal, a first guide pipe connected to the other end of the suction nozzle and guiding the air introduced through the suction nozzle to the sensing block in which the detection material is disposed, a suction force generating unit formed at the other end of the discharge nozzle and to suck air through the suction port and to provide a suction force for sucking air into the sensing block and discharging the air to a discharge port formed at one end of the discharge nozzle, a second guide pipe formed between the sensing block and the suction force generating unit and discharging the air introduced into the sensing block by the suction force generated by the suction force generating unit to the discharge port of the discharge nozzle, and a controller for determining whether explosive particles are present in the air using the sensing signal.

A vehicle for detecting and neutralizing an incendiary object comprises a detecting device configured to mount at fore-end of the vehicle is disclosed. The detecting device comprises: one or more platforms configured to be mounted at the fore end of the vehicle. The one or more platforms are located proximal to the ground surface such that they hover over the ground surface at a predetermined distance. A plurality of sensors wherein each of the plurality of sensors mounted on the at least one of the one or more platforms for capturing information related to the incendiary object. A neutralizing device interfaced with the detecting device, wherein the neutralizing device comprises: a neutralizing arm member which actuates in one or more directions for handling and neutralizing the incendiary object based on the information related to the incendiary object. An annihilator device equipped with the neutralizing device to annihilate the incendiary object.