The disclosure encompasses systems and methods for performing high temperature and high humidity curing of tablets using air flow delivered from a recirculating air handler to a pan coater of a tablet coating device. The recirculating air handler may be integrated into a preexisting tablet coating device so that the air flow may be delivered by the preexisting air handler or by the recirculating air handler as desired.

A painting system includes painting unit including a first painting robot and a second painting robot, a cartridge carrier, and a cleaning tank. The painting robots each include a robot arm including a painting machine. The cartridge carrier includes a cartridge grip part. A first region is a region where a movable region of the painting machine of the first painting robot overlaps with a movable region of the cartridge grip part. A second region is a region where the movable region of the painting machine of the second painting robot overlaps with the movable region of the cartridge grip part. The cleaning tank is provided in a position including at least a part of the first region and at least a part of the second region.

A coating apparatus includes a first module and a second module constituting a coating area where a coating target is coated. The first module includes a first frame and a coating robot. The second module includes a second frame. When the first module and the second module are arranged to adjoin each other in a movement path direction in which the coating target relatively moves along the coating area, the first frame of the first module and the second frame of the second module that are arranged to adjoin each other are configured to be coupled together.

In embodiments, the sunblock lotion spray booth comprises a booth, a plurality of spray columns, a plurality of canisters, a pump, a ventilator, and one or more payment receiving devices. The booth may be adapted to spray one or more tanning products onto a user via the plurality of spray columns located within the booth once a payment receiving device and an activation button have been activated. As non-limiting examples, the one or more tanning products may be sunblock lotions having different SPF values, bronzers, or combinations thereof. One or more of the plurality of spray columns may be height-adjustable. The pump may move the tanning products from the plurality of canisters to a plurality of nozzles located on the spray columns via tubing within the walls of the booth. The ventilator may circulate air within the booth.

In embodiments, the sunblock lotion spray booth comprises a booth, a plurality of spray columns, a plurality of canisters, a pump, a ventilator, and one or more payment receiving devices. The booth may be adapted to spray one or more tanning products onto a user via the plurality of spray columns located within the booth once a payment receiving device and an activation button have been activated. As non-limiting examples, the one or more tanning products may be sunblock lotions having different SPF values, bronzers, or combinations thereof. One or more of the plurality of spray columns may be height-adjustable. The pump may move the tanning products from the plurality of canisters to a plurality of nozzles located on the spray columns via tubing within the walls of the booth. The ventilator may circulate air within the booth.

Provided is a can inner surface-coating apparatus with which inspection of bottomed cylinders can be favorably performed in parallel without being affected by the coating process. In the can inner surface-coating apparatus, inspection cameras to be used for inspection following coating of the inner surface of a bottomed cylinder that will become the body of a can or bottle-shaped can are disposed above spray devices that are used for coating the inner surface of bottomed cylinders. Moreover, the coating area including the spray devices and the inspection area including the inspection cameras are covered with a cover. By supplying air inside the cover from the upper part (air supply port) of the inspection area and discharging the air out of the cover from the lower part (coating mist collection duct) of the coating area, an air flow is formed from the upper part of the inspection area to the lower part of the coating area.

A volatile organic compound (VOC) removal system for removing VOC generated during a painting process of a vehicle body includes a paint spraying booth where paint is applied to the vehicle body, a paint baking oven for fixing the paint on the vehicle body applied with the paint in the paint spraying booth, an integration chamber for receiving a booth discharge gas from the paint spraying booth through a booth gas inflow line, to receive an oven discharge gas from the paint baking oven through an oven gas inflow line, and to form a mixture gas by mixing the received booth discharge gas and the received oven discharge gas, a VOC concentrator for forming a process gas by concentrating the mixture gas supplied from the integration chamber to increase a VOC concentration, and a VOC removing apparatus for removing VOC from the process gas supplied from the VOC concentrator.

A volatile organic compound (VOC) removal system for removing VOC generated during a painting process of a vehicle body includes a paint spraying booth where paint is applied to the vehicle body, a paint baking oven for fixing the paint on the vehicle body applied with the paint in the paint spraying booth, an integration chamber for receiving a booth discharge gas from the paint spraying booth through a booth gas inflow line, to receive an oven discharge gas from the paint baking oven through an oven gas inflow line, and to form a mixture gas by mixing the received booth discharge gas and the received oven discharge gas, a VOC concentrator for forming a process gas by concentrating the mixture gas supplied from the integration chamber to increase a VOC concentration, and a VOC removing apparatus for removing VOC from the process gas supplied from the VOC concentrator.

A next generation painting robot with advanced fluid delivery system, enhanced kinematics and a service airlock compartment. The painting robot includes a fluid delivery system which places color changing valves and pumping hardware on the back side of the robot's mounting pedestal, where it can be serviced without a technician having to enter the spray booth. The fluid delivery system also allows smaller and lighter robot arms, and is designed to minimize paint waste and wait time during color changes. The robot also features kinematics providing redundant inner arm rotation. The arm kinematics, along with the smaller arms, a paint supply line routed through the center of first and third arm joints, and optimized motor conductor routing, dramatically improve near reach flexibility. The improved near reach flexibility in turn allows a smaller spray booth than possible with previous robot architectures.

A next generation painting robot with advanced fluid delivery system, enhanced kinematics and a service airlock compartment. The painting robot includes a fluid delivery system which places color changing valves and pumping hardware on the back side of the robot's mounting pedestal, where it can be serviced without a technician having to enter the spray booth. The fluid delivery system also allows smaller and lighter robot arms, and is designed to minimize paint waste and wait time during color changes. The robot also features kinematics providing redundant inner arm rotation. The arm kinematics, along with the smaller arms, a paint supply line routed through the center of first and third arm joints, and optimized motor conductor routing, dramatically improve near reach flexibility. The improved near reach flexibility in turn allows a smaller spray booth than possible with previous robot architectures.