Abstract: A device for generating high pressure ozone water by using a low pressure ozone gas source includes an ozone gas and water mixture bucket. A water inlet of the ozone gas and water mixture bucket is connected with a tap water inlet through a pipe system and a water inlet solenoid valve. A water outlet of the ozone gas and water mixture bucket is connected with a water outlet through the pipe system and a water outlet one-way valve. An ozone gas inlet of the ozone gas and water mixture bucket is connected with an ozone inlet through the pipe system and an ozone gas inlet one-way valve. The ozone gas and water mixture bucket is provided with an off-gas outlet. The off-gas outlet is connected with a discharge outlet through the off-gas destruct bucket. The water inlet solenoid valve is connected with a power control unit.

Abstract: A device for generating high pressure ozone water by using a low pressure ozone gas source includes an ozone gas and water mixture bucket. A water inlet of the ozone gas and water mixture bucket is connected with a tap water inlet through a pipe system and a water inlet solenoid valve. A water outlet of the ozone gas and water mixture bucket is connected with a water outlet through the pipe system and a water outlet one-way valve. An ozone gas inlet of the ozone gas and water mixture bucket is connected with an ozone inlet through the pipe system and an ozone gas inlet one-way valve. The ozone gas and water mixture bucket is provided with an off-gas outlet. The off-gas outlet is connected with a discharge outlet through the off-gas destruct bucket. The water inlet solenoid valve is connected with a power control unit.

Abstract: A device for sterilizing an ice machine using ozone gas from an electrolytic ozone generator includes a pure water tank (2), a pure water refilling device (1), and the electrolytic ozone generator (3). The pure water tank (2) is connected to a gas-feeding solenoid valve (4) and a gas-discharging solenoid valve (5). The gas-discharging solenoid valve (5) is connected to a reducing carbon tank (6), which is connected to a vent (10). The gas-feeding solenoid valve (4) is connected to a tee pipe (11-4) of the ice machine (11). The tee pipe (11-4) is connected to a water pump (11-2) in an ice-machine water tank (11-1) and an ice-machine evaporator (11-3) through loop piping. A controlling circuit board (7) is connected to power source (8), and further connected to the electrolytic ozone generator (3), the gas-feeding solenoid valve (4), the gas-discharging solenoid valve (5), and a motherboard (11-6).

Abstract: A device for sterilizing an ice machine using ozone gas from an electrolytic ozone generator includes a pure water tank (2), a pure water refilling device (1), and the electrolytic ozone generator (3). The pure water tank (2) is connected to a gas-feeding solenoid valve (4) and a gas-discharging solenoid valve (5). The gas-discharging solenoid valve (5) is connected to a reducing carbon tank (6), which is connected to a vent (10). The gas-feeding solenoid valve (4) is connected to a tee pipe (11-4) of the ice machine (11). The tee pipe (11-4) is connected to a water pump (11-2) in an ice-machine water tank (11-1) and an ice-machine evaporator (11-3) through loop piping. A controlling circuit board (7) is connected to power source (8), and further connected to the electrolytic ozone generator (3), the gas-feeding solenoid valve (4), the gas-discharging solenoid valve (5), and a motherboard (11-6).

Abstract: An electrolytic ozone cell anode spring fastening board structure includes a solid polymer electrolyte membrane (1), an anode electrocatalyst layer (2), a diffusion layer (3), frame body and support parts (5). A diffusion layer counterpiece (4) has one side attached to the diffusion layer (3), the other side of the diffusion layer counterpiece (4) equipped with a centered elevated step, which contacts the center of the convex side of a spherical spring board (6). In addition, the solid polymer electrolyte membrane (1), frame body and support parts (5), diffusion layer (3), diffusion layer counterpiece (4) and spring board (6) are held together by mechanical fastening means. It prevents a decrease in ozone generation rate in electrolytic ozone cell that can occur from the metal board deformation and thinning of the anode electrocatalyst layer.

Abstract: An electrolytic ozone generator with membrane electrode includes a proton exchange membrane (2), an anode electrocatalyst layer (3), an anode diffusion layer (4), a flow field plate (5), a cathode structure (1) and a frame body (6). The frame boy (6) has a frame sealing groove (11) therein. A seal (7) is provided in the frame sealing groove (11). The frame body (6) is tightly connected with the cathode structure (1) through screws (9) so that the seal (7) is to seal the proton exchange membrane (2), the anode electrocatalyst layer (3) and the frame body (6) completely and tightly. The present invention has a simple structure, is cost-effective and provides a better seal effect to achieve mass production. After a period of operation, the electrolytic ozone generator still keeps an excellent seal, so that the electrolytic ozone generator can generate ozone steadily.

Abstract: An electrolytic ozone cell anode spring fastening board structure includes a solid polymer electrolyte membrane (1), an anode electrocatalyst layer (2), a diffusion layer (3), frame body and support parts (5). A diffusion layer counterpiece (4) has one side attached to the diffusion layer (3), the other side of the diffusion layer counterpiece (4) equipped with a centered elevated step, which contacts the center of the convex side of a spherical spring board (6). In addition, the solid polymer electrolyte membrane (1), frame body and support parts (5), diffusion layer (3), diffusion layer counterpiece (4) and spring board (6) are held together by mechanical fastening means. It prevents a decrease in ozone generation rate in electrolytic ozone cell that can occur from the metal board deformation and thinning of the anode electrocatalyst layer.