In one embodiment, a cleaning device for a compact HVAC unit includes a flexible belt, and a collection element attached to the flexible belt at a first end of the belt. The collection element and the belt form a collection area therebetween, and wherein the collection element has a port therein at the first end of the belt, the port configured to remove debris collected in the collection area.
In other aspects of the cleaning device, the flexible belt has a bent end portion at an opposite end of the belt from the collection element. The bent portion is bent in one aspect in a direction toward the collection element to form a deflection portion that assists in introducing the cleaning device into compact HVAC unit. The belt includes in one aspect at least one notch to assist in alignment of the cleaning device in an interior of the HVAC unit. The at least one notch is positioned near the port and is configured to engage an interior wall portion of the HVAC unit. In one aspect, the flexible belt is formed from aluminum. In another aspect, the collection area is a pocket into which debris is blown, the pocket formed from the collection element and apportion of the belt. The port in one aspect is configured to attach to an external vacuum to allow suction of debris from the collection area. The port is in one aspect positioned to be at a bottom of the cleaning device when installed for cleaning of the HVAC unit.
In another embodiment, a method includes inserting a cleaning device, having a flexible belt, a debris collection area, and a debris removal port, between a wall and a condenser coil of an HVAC unit, blowing debris collected in the HVAC unit along the belt toward the debris collection area, and removing the debris collected in the debris collection area via the port and an external vacuum.
Other aspects of the method include inserting at one end of a condenser coil of the HVAC unit and introducing the cleaning belt around the condenser coil to an opposite side of the HVAC unit. Further aspects include the vacuum port being positioned at a low part of the HVAC unit for cleaning; blowing debris is performed from an end of the cleaning device opposite the vacuum port, toward the collection element and the vacuum port; the collection element and the belt forming a pocket for collecting debris, and wherein removing collected debris comprises vacuuming the collected debris from the pocket.
In another embodiment, a method includes inserting a cleaning device between a wall and a condenser coil of an HVAC unit, the cleaning device comprising a belt that wraps at least partially around the condenser coil, a collection element on the belt to collect debris, and a vacuum port configured to remove collected debris from the collection element; blowing debris collected in the HVAC unit toward the collection element along the belt; and removing collected debris with the vacuum port and an external vacuum.
Embodiments of the present disclosure provide apparatuses and methods to efficiently remove dirt, dust, and debris from a compact heating and cooling unit. A debris catching cleaning device is provided for the cleaning of non-removable cooling chassis on, for example, compact heating and cooling units. Such units, including by way of example only and not by way of limitation, include units manufactured by Magic-Pak, Comfort Pack, Condo Pak and other manufacturers. The units are traditionally a vertical compact heating and cooling unit that has a non-removable cooling chassis. Such units are traditionally lower cost than full-house or full-building units, typically costing in the neighborhood of $4,000 and more. Their compact nature and non-removable chassis makes keeping the units clean a difficult process. The heating and/or cooling units may be referred to in this application as heating, ventilating, and cooling (HVAC) units.
The cooling chassis of a heating/cooling unit such as those described typically contains a condenser surrounded by a condenser coil that has fins or the like. Debris such as blowing leaves, cottonwood, and the like, can accumulate in the condenser coil. The buildup of dirt and debris is not easily removed from the condenser coil. The inability to properly remove dirt and debris will cause the unit to run harder and therefore reduce the efficiency and length of life of the entire unit. Such units do not have readily available major replacement parts, so a failed unit will result in a full replacement unit being required.
Cleaning of such units is typically performed by using compressed oxygen or straight air and blowing debris out of the condenser coil into any open space within the unit where it can and will reside until the unit is fired up. This creates static on the coil to which the debris will cling to all over again, or the debris may be blown out a louver to an outside of the building. The blown debris may cause an aesthetic issue on a higher-end building such as an apartment complex or the like. Further, if units are cleaned in this manner and not cleaned in a proper order, such as if the level below has already been cleaned, when the unit above is cleaned and that dirt and debris does make it out of the louver, gravity will take it and bring it down to the previously cleaned unit. If that previously cleaned unit is running, the debris will again be sucked into the running unit to the static on the coil and the debris will re-enter the already cleaned unit.
Embodiments of the present disclosure provide an apparatus and method for the cleaning of compact heating and cooling units that addresses not only the problems of cleaning dirt and debris, but also the collection thereof to prevent cleaned debris being reintroduced into the unit or other nearby units.
A typical compact heating and/or cooling unit 500 is shown in partial cutaway side view in
Referring to
Referring to
In one embodiment, a pair of notches 212 and 214 are present in the belt 202 to assist in alignment of the device 200 within a heating and cooling unit such as unit 500. It should be understood that heating and cooling units from different manufacturers may be slightly different and therefore the notches 212 and 214 may be present or not, and may be sized differently, to accommodate different units 500, without departing from the scope of the disclosure. Further, it should be understood that the length and width of the belt 202 (and of belt 102) may be changed to accommodate those different sizes of units, also without departing from the scope of the disclosure.
The collection element 204 in one embodiment includes a v-shaped notch 220 therein, with the open end of the v-shape positioned away from the vacuum port 206 toward the end 218 of the belt 202.
In one embodiment, that portion of the collection element 204 that is in the vicinity of the vacuum port 206 is tapered from a full width at the vacuum port to a smaller width at a bottom of the cleaning device 200, as shown in the end elevation view of
A face plate such as plated 502 is removed from unit 500.
After the front panel 502 of the unit 500 is removed and the screws 504 that hold the condenser coil 506 in place are removed the device 200 is inserted into the unit 500 as shown in
The clamps 550 are added to maintain as much of a vacuum as possible. In one embodiment, the vacuum hose 560 is connected to a large CFM vacuum external to the unit. Then, air is blown into the opposite side of the unit as indicated at arrow 570 in
In one embodiment, the device 200 is constructed from 28-gauge aluminum. It should be understood that the device 200 could be made of different material without departing from the scope of the disclosure. For example, the belt 202 could be made out of molded plastic future to reduce costs, and potentially hinged at the collection element 208 end 216 to make the device 200 more conducive to space and ease of use. Any material which can withstand the flexibility and durability to be used as a belt may be used without departing from the scope of the disclosure, such as sheet metal, other plastics, or the like. The belt should have enough rigidity to withstand being introduced into a compartment of an HVAC unit, and deflect around a condenser coil as discussed, without being too flimsy that it does not maintain its integrity. The examples of aluminum and flexible plastics are examples only. Those of skill in the art will readily understand other materials may be used without departing from the scope of the disclosure.
The size and thickness of the belt 202 and collection element 204 may be changed due to regulations or different sizes of units 500. For example, due to regulations that have been enacted in 2019, it is possible that the collection area 208 comprising a portion of belt 202 and collection element 204 at the end 216 of device 200 may potentially be a little thinner than a currently embodied ¾. It is also possible that the clamps 550 could be installed on the outside of the device and integrated therewith, instead of using unattached clamps 550 as shown. Also, the length of the belt 202 may be lengthened or shortened to ensure that it is properly seated and suitable for collecting debris blown toward the collection area 208.
As has been described, the device 200 (and device 100) are used in one embodiment as follows:
The above-disclosed subject matter is to be considered illustrative, and not restrictive, and the appended claims are intended to cover all such modifications, enhancements, and other embodiments, which fall within the true scope of the present disclosure. Thus, to the maximum extent allowed by law, the scope of the present disclosure is to be determined by the broadest permissible interpretation of the following claims and their equivalents, and shall not be restricted or limited by the foregoing detailed description.
The present application is based on and claims the benefit of U.S. provisional patent application Ser. No. 62/947,041, filed Dec. 12, 2019, the content of which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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62947041 | Dec 2019 | US |