A paint transfer system for both automatically and manually transferring paint from a paint container directly to a paint brush including a paint container member, a pump mechanism, and a paint brush apparatus coupled together in fluid communication wherein the paint brush apparatus includes a paint brush having a bladder member or housing member positioned and located within the paint brush adjacent to or within its bristle members as well as an optional valve control member for controlling and distributing the flow of paint to the bristle members. In some embodiments, a remote controller is positioned between the paint brush apparatus and the paint container member for allowing a user to selectively activate the flow of paint from the paint container to the paint brush apparatus. A variety of different pumping mechanisms are utilized for transferring paint from the paint container member to the paint brush apparatus.

A caulk gun includes a body, a pump supported on the body, a motor supported by the body to drive the pump, a trigger supported on the body. The body is configured to support a sealant container adjacent the outlet. A force generated by the pressurized air in the fluid passage is configured to be transmitted to a portion of the sealant container. The pump is in fluid communication with the inlet and configured to drive pressurized air through the fluid passage. Actuation of the trigger is configured to actuate the motor. The pressure release mechanism is positioned at least partially within the fluid passage. The pressure release mechanism is moveable between a first position in which pressurized air can be vented from the fluid passage and a second position in which the pressure release mechanism inhibits venting of pressurized air from the fluid passage.

A caulk gun includes a body, a pump supported on the body, a motor supported by the body to drive the pump, a trigger supported on the body. The body is configured to support a sealant container adjacent the outlet. A force generated by the pressurized air in the fluid passage is configured to be transmitted to a portion of the sealant container. The pump is in fluid communication with the inlet and configured to drive pressurized air through the fluid passage. Actuation of the trigger is configured to actuate the motor. The pressure release mechanism is positioned at least partially within the fluid passage. The pressure release mechanism is moveable between a first position in which pressurized air can be vented from the fluid passage and a second position in which the pressure release mechanism inhibits venting of pressurized air from the fluid passage.

One general aspect includes a liquid dispenser with a mount having a mount aperture. A liquid flow path assembly is removably secured to the mount and has an inlet configured to receive liquid, an outlet configured to dispense liquid and a passageway fluidly coupling the inlet to the outlet. A third aperture apart from the inlet and the outlet is fluidly coupled to the passageway and forming a valve guide. The liquid flow path assembly is disposed on the mount to align the third aperture with the mount aperture. An elongated valve has a valve stem guided by the valve guide and extends through the third aperture and the mount aperture. A latch assembly secures the liquid flow path assembly to the mount.

One general aspect includes a liquid dispenser with a mount having a mount aperture. A liquid flow path assembly is removably secured to the mount and has an inlet configured to receive liquid, an outlet configured to dispense liquid and a passageway fluidly coupling the inlet to the outlet. A third aperture apart from the inlet and the outlet is fluidly coupled to the passageway and forming a valve guide. The liquid flow path assembly is disposed on the mount to align the third aperture with the mount aperture. An elongated valve has a valve stem guided by the valve guide and extends through the third aperture and the mount aperture. A latch assembly secures the liquid flow path assembly to the mount.

Pneumatic spray guns (10) for applying sprayable materials (M) to various surfaces are disclosed. During use of the pneumatic spray guns (10), a tube (T) of flowable texture material (M) to be sprayed is loaded into a pressure canister (12) of the spray gun (10). Pressurized air is fed to the tube (T) of material (M) to be sprayed and is also fed to a spray nozzle region of the gun (10) to contact the material (M) after it has exited the tube (T) in order to provide a desired spray pattern (S). The pressure applied to the pressure canister (12) and/or the pressure applied to the spray nozzle (20) may be varied in order to control the spray pattern (S).

The present disclosure relates to a metering and mixing device including a cartridge holder (1) and a cartridge (2). A surface-to-surface, and also positive and non-positive connection exists between the cartridge and the holder. The present disclosure also relates to a method for coating substrates with two- or multicomponent coating media, in which the metering and mixing device is used.

The present disclosure relates to a metering and mixing device including a cartridge holder (1) and a cartridge (2). A surface-to-surface, and also positive and non-positive connection exists between the cartridge and the holder. The present disclosure also relates to a method for coating substrates with two- or multicomponent coating media, in which the metering and mixing device is used.

A variety of dispensing manifolds which are removable connectable to a single deformable container having a single exit portion are disclosed. The dispensing manifolds of the present disclosure provide a single deformable container having a single exit with one or more outlets from which a fluid can be controllably dispensed. The present disclosure also provides a single force generation mechanism, a deformable container holding a fluid or substance, and dispensing mechanisms all on one machine, i.e., a carrier; a system that may also include a pressurized air source that assists a flow of a fluid; and a system that allows for a continuous flow a substance. The systems of the present disclosure provide a deformable container and a method of dispensing wherein, during dispensing, an actuation member is continuously free of contact with the fluid or substance within the container and the actuation member only contacts the exterior surface of the deformable container.

A dispenser includes a syringe container having a first end and a second end, the syringe container having a length direction extending between the first end and the second end, a plunger movable within the syringe container along the length direction of the syringe container and configured to be positioned on a surface of an underfill solution to be received within the syringe container at a first region between the plunger and the second end, a cap attached airtightly to the first end of the syringe container, a first gas supply line configured to supply a first gas into the syringe container through the cap, and a second gas supply line extending from the cap to the plunger, the second gas supply line being in fluid communication with the first region and configured to supply a second gas into the underfill solution to be received within the syringe container at the first region through a through hole of the plunger.