Provided is a vacuum cleaner. The switching valve apparatus of the vacuum cleaner includes an outer casing and a counterflow air passage. The outer casing is provided with a first vent opening and a second vent opening arranged side by side along the circumferential direction of the outer casing. In the case where the counterflow air passage is at the first angular position, the outer casing seals the counterflow air outlet of the counterflow air passage; in the case where the counterflow air passage is at the second angular position, the counterflow air outlet communicates with the first vent opening and is staggered with the second vent opening; and in the case where the counterflow air passage is at the third angular position, the counterflow air outlet communicates with the second vent opening and is staggered with the first vent opening.

The present disclosure describes a computer-implemented method that includes: monitoring an air pressure gap between two positions inside a pipe of an air filtration system; generating a first cleaning pulse inside the pipe to cause a drop of the air pressure gap being monitored; comparing a characteristic of the drop of the air pressure gap with a known profile; and based on results of the comparing, determining a status of at least one filter or filter cleaning component of the air filtration system.

A bypass valve may include a body defining a dirty air passageway, a nozzle coupling port configured to fluidly couple the dirty air passageway to a nozzle of the surface cleaning device, a wand coupling port configured to fluidly couple the dirty air passageway to a wand of the surface cleaning device, a suction coupling port configured to fluidly couple the dirty air passageway with a suction motor of the surface cleaning device, a wand receptacle configured to removably couple to the wand, and a valve bypass arrangement configured to selectively redirect air flowing through the body such that a majority of the air flowing through the body transitions between flowing through one of the wand coupling port and the nozzle coupling port. The valve bypass arrangement redirects the air in response to the wand being coupled to or decoupled from the wand receptacle.

Embodiments of a valve having a housing including an inlet, an outlet, and an interior chamber in fluid communication with the inlet and the outlet are disclosed. The valve also includes a seat fitting having a first screen held in place by a first retainer ring. The seat fitting includes a valve seat. The valve further includes an outlet fitting having a second screen held in place by a second retainer ring. The second retainer ring includes a plurality of ribs extending from a ring body such that the plurality of ribs create a gap between the ring body and the second screen. Further, the valve includes a valve plug configured to selectively engage the valve seat to open and close a passage between the interior chamber and the outlet. The seat fitting is contained at least partially within the outlet fitting to define the outlet of the housing.

A vacuum cleaner includes an air inlet, a filter, a fan, and a main air outlet. The filter has a clean side and an unclean side. An unclean air chamber is formed between the air inlet and the unclean side of the filter. A first air chamber is formed between the clean side of the filter and the fan. An air outlet chamber is formed between the fan and the main air outlet. The upstream end of the air outlet chamber is connected to the first air chamber. An airflow may enter the vacuum cleaner from an external environment via the air inlet under the action of the fan, and sequentially passes through the unclean air chamber, the filter, the first air chamber and the air outlet chamber the main air outlet. The vacuum cleaner may include a self-cleaning air passage and an air supply air passage.

A quick release purge valve and a substrate container using same are provided. The container includes a base which has a cover plate and a bottom plate. The quick release purge valve includes a snap plate, a gasket fitting, and a valve element. The snap plate detachably engages with the bottom plate and is at most evenly aligned with the bottom plate. The gasket fitting is disposed between the cover plate and the bottom plate and has an airflow conduit communicating the two plates. The valve element is disposed in the conduit for limiting a flow direction of the gas. The gasket fitting is fixed in the base when the snap plate and the bottom plate are in an engaged state and is removable from the base when the snap plate and the bottom plate are in a disengaged state.

Specialized arch gaskets for dust collection systems are provided that reinforce certain connections points within the system. More particularly, the arch gaskets may better reinforce the pressure conditions of the dust collection system and enhance the sanitary conditions within the system. The large side engagement formed by the legs of the arch gasket is able to provide a desirable amount of adhesive surface to connect to the desired component in the system (e.g., a door), which may allow a user to more easily install the arch gasket into the system at its intended location.

A filter for compressed air systems is provided. The filter includes a filter housing with a filter therein between an air inlet and an air outlet. Compressed air flowing between the air inlet and the air outlet passes through the filter housing and the filter element. A base is removably fastened to the filter housing which may be separated from the filter housing to allow the filter element to be removed and replaced.

A dust filtering and collection system for filtering dust and other particles from an incoming air stream generally used for conveying granular material, the filtering system receives the air from within the tank trailer, pre-separates the heavy dust particles and other debris at the bottom of a filter housing, without its impingement upon the filter tube(s) contained upwardly therein, and then passes the partially filtered air upwardly through filter tube(s) for purifying the air before discharge to atmosphere. The filter housing for the system includes a cylindrical housing upwardly, an integral cone shaped housing at its bottom, into which the dust particles settle, it has a transverse plate at its upper segment, which supports the filter tube(s), an air inlet being centrifugally and integrally formed at the bottom of the cylindrical member of the filtration system.

A panicle catcher for capturing entrained particles in a fluid is disclosed. The particle catcher can include an enclosure defining a flow channel between an inlet and an outlet. Trapping means may be incorporated into the particle catcher. Where provided, the trapping means can be arranged at or near the inlet to allow fluid comprising entrained particles to enter the flow channel through the inlet and to substantially prevent the fluid comprising entrained particles from exiting the flow channel through the inlet. Filtering means may also be incorporated into the particle catcher. Where provided, the filtering means can be arranged at or near the outlet to keep at least some a part of the entrained particles from exiting the flow channel through the outlet.