In accordance with an aspect of this invention, a dust collection system employs a cyclonic separator in which an intake hose connects to an inlet tube near the top of the cyclone, and an outlet hose connects to the vortex tube that extends out the top of the cyclone. The base or nose of the cyclone connects to a hopper which can be an open-bottom, generally cylindrical container, to which a poly film bag is attached, e.g. using an elastic strap, a steel band with clamp, or equivalent.
A support grid or equivalent structure covers the open bottom as a means to hold against the poly film of the bag and prevent the polyfilm from being sucked up into the open-bottom container. This can be a grid or grill of rods or fairly rigid wire members. Favorably, a 3-mil plastic bag hangs down from the container and is held in place by a ring clamp, plastic band or elastic strap. In operation, the dust is separated from the air stream by the cyclone, and the dust drops down into the open-bottom container. While the vacuum is present during operation, the plastic film of the bag is pulled up against the grille or gridwork to close off the bottom of the container. When the vacuum is shut off, the bag relaxes and drops down from the bottom of the container, allowing the dust to flow down through the grid into the bag. The spacing or mesh size of the gridwork is open enough so that particles of the collected material do not build up across it and block the flow. When the vacuum is turned on again, the bag is sucked up against the grid, and the sides of the bag just below that seal against themselves to close off the collected material. The dust or other materials in the bag form a more or less rigid mass below the part of the bag that collapses against itself, so the already-collected dust does not pass back up through the grid. This preserves the capacity of the container for additional dust to enter it. When the bag is full, it can be pulled off, or in some cases cut off, and disposed of.
In a typical system, the cyclonic separator may include a cone with or without an upper barrel, and in some cases may be of low-profile Thiele design (see Witter et al., US 2019-0134649)
Some examples of dust collectors with this feature of negative-pressure external bagging can be a wall-mounted vacuum separator with a 5-gallon-size open-bottom container and an associated 30-gallon polyfilm bag. This arrangement can be used on a cart-based vacuum separator with this bagger arrangement in place of rigid dust collection drum or barrel. Also, a more powerful concrete dust collector on a cart can employ this bagger system, with individual polyfilm bags or with a Longo-pac continuous bag system A portable stand can employ a pre-separator for gathering larger chunks or debris, and this can employ the bagger system of the present invention. Such a bagger can be used, for example, for floor refinishing where large amounts of wood dust and grindings are collected.
For some systems, a 5-gallon drum may be used as the open bottom container for direct bagging in place of a much larger rigid barrel, e.g., 50 gallon steel drum.
A tubular bag can be accordion-folded over the container, providing in effect multiple bags. Any of a variety of bags of various sizes can be employed with any given separator or cyclone.
It is possible to use a sealing or semi-sealing flap in place of a grid on the bottom of the drum. Alternatively, a grid may be formed of a rigid plate or platform with multiple holes or openings in it of sufficient size to permit flow of dust into the bag. In that case, a supplemental flexible skirt may also be employed to help prevent the polyfilm bag from being sucked through the holes or openings.
Bracketry may be attached or affixed to the container to allow the arrangement to be mounted onto a wall or onto a shop vacuum cleaner.
Thus, with the arrangement of the present invention, a dust separation and storage section can consist of or employ a rigid intermediate storage hopper with an open bottom, a support grid or equivalent, and a flexible, unsupported non-porous bag under negative pressure. The dust storage section that provides intermediate dust storage can be used with flexible bags of any desired capacity, and the bags are easily closed off and removed for convenient disposal.
While the system is running and vacuum is present, the flexible poly bag is pulled up against the open bottom opening(s) of the hopper, thus sealing the hopper opening(s). This prevents the separation efficiency of the cyclonic separator from being compromised from diminished vacuum. The dust stored in the intermediate hopper is kept in the hopper by the bag being sucked up against the bottom grid while the system is running. When the vacuum is turned off, the internal vacuum disappears, and the pressure inside the bag equalizes. Then the bag drops open and the dust falls into the bag. The dust accumulates after each cycle until the bag reaches its capacity. At that time the bag can be removed (without need of separating the container or hopper from the cyclone) and the filled bag can be easily disposed of.
Beginning with
A grid or grill of spaced bars or wires 19 is present at the open lower end of the container 16, designed with suitable aperture size so that separated dust can pass through when the system is off, but that when the system is on, the associated polyfilm bag 20 will not get sucked up into the container 16. Here, the dust collection bag 20 is formed of a polyfilm of about 3-mil thickness. In some operations, the film could be thicker or thinner. The bag has its top end disposed onto the outside wall of the container 16, and that is secured by a strap or band 22, e.g., an elastic strap. The separated materials, i.e., dust and other debris, are represented as 21, and are contained in the bottom part of the bag 20.
As shown in
The possible arrangement of a cassette with a multiple of bags, in the form of an accordion-folded polyfilm tube 220, is shown in
This same embodiment as an injection-molded bagger of a durable rigid plastic resin is shown in
While several embodiments have been shown and discussed hereinabove, many variations and re-configurations are possible without departing from the main principles of this invention. The units may be made of a wide variety of materials as need be for different purposes.
This application claims priority under 35 U.S.C. § 121(e) of Provisional Patent Application Ser. No. 62/870,435, filed Jul. 3, 2019. The disclosure contained therein is incorporated herein by reference. Dust collectors in general require movement of a stream of air through a separator, e.g., a cyclone, with air pressure driving the air stream to separate the entrained dust from the air. Dust collectors thus require sections operating either under positive (above atmospheric) pressure or negative (sub-atmospheric) pressure. When the fan or blower is in advance of the cyclone, the pressure is positive, and where the fan or blower is after the cyclone, the air pressure is negative. There are advantages to employing a negative pressure system, including that any leakage that affects the dust collection drum or barrel will leak air into the drum, and will not leak dust out of the drum into the ambient. Thus, indoor systems are preferably negative pressure systems. Single-stage dust collectors have a blower that sucks the dust-laden air from the dust source, i.e., grinder, saw, or other tool, under negative pressure, and then draws the dust-laden air through the blower. After the blower, the air is under positive pressure. In a positive-pressure system, the dust-laden air enters a filter of one sort or another that allows the bulk of the particulates and other such material to fall downward into a bag for disposal. Because the bag is under positive pressure, it inflates. Some operators prefer the convenience of this system because of the easy removal and disposal of the bag. These are typical poly film bags, but can be paper or other plant-based products. The bags should be flexible, and substantially air-impermeable. In dust collector systems that operate under negative pressure the dust-laden air stream is under vacuum when it passes through the cyclone and dust-bin sections, so that the air reaching the blower is mostly clean. The air after leaving the blower is under positive pressure as it passes through a final filter. The negative pressure in the dust separation and collection section has traditionally required a rigid dust storage container, e.g., drum, to resist collapse from negative pressure. A bag or liner may be used with these to make dust removal more convenient, but then these require a mechanism such as an air lock, internal bag support, or vent tube to evacuate the air behind the liner. Where an exceptionally long hose connects the dust-producing tool with the intake of the dust collector, more suction is required, and that means the air pressure within the dust collector becomes even more negative. In a prior arrangement of DeMarco U.S. Pat. No. 4,820,315 a bagger (for asbestos removal) has a flexible poly bag supported on the outside of an open cylinder to collect the separated material. The cyclone and cylinder operate under negative pressure. An elastic band holds the upper part of the bag onto the outside of the cylinder. The unit has a platform that moves up to support the bag material below the cylinder. The bottom of the bag is drawn across the open bottom of the cylinder during operation, and the bag is later pulled down to allow the collected material to fall from the cylinder into the bag. There is no mention of how the poly film of the bag is kept from being sucked up into the cylinder by the negative operating pressure inside the cylinder during operation. A LongoPac system is described in U.S. Pat. No. 5,037,370 to Sture Sundberg, which employs a long tube of polyfilm folded onto a bag cassette, and this tube is pulled down and tied off with cable ties or the like to form individual collection bags. The Sundberg patent describes the folding method of forming these bag tubes. The Longopac bag cassette can be used for bagging dust under negative pressure. In such system a storage hopper under the cyclone receives the dust that is separated out in the cyclone. There is a semi-rigid flap valve at the base of the hopper held closed by negative pressure in the cyclone, which closes off the bottom of the hopper section. When the blower is turned off, the pressure equalizes and the flap drops open, allowing the collected dust to flow down into the bag, which may in some cases be a Longopac bag or similar tubular bag. When that bag is filled, the filled section can be closed off using a pair of cable ties, and then the filled section is cut off between the two cable ties. This helps avoid contamination from the dust, as the bag does not have to be lifted out of a drum. These tubular bags are typically a length of successive bags 72 feet long. The semi-flexible flap by itself may leak significant amounts of air, which may compromise the cyclone operation. In actual use, the tubular bag is sucked up against the valve flap, providing effective sealing.
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