This invention relates generally to air conditioning systems wherein a vapor compression refrigerant is used to cool air supplied to an indoor space and in particular to a device for dampening compressor-induced vibration in an air conditioning system.
In central air conditioning systems typically used in residences, a compressor is operable to circulate a vapor compression refrigerant between an indoor heat exchanger and an outdoor heat exchanger. In recent years, scroll-type compressors for the most part have replaced reciprocating-type compressors in residential air conditioning systems. For cost reasons, such scroll-type compressors typically do not include vibration-dampening springs to isolate the motor and compressor mechanism from the outer housing of the compressor. The refrigerant lines on the suction and discharge sides of the compressor are rigidly attached to this outer housing. Therefore, unlike older-style reciprocating compressors, there is a direct vibration transmission path to these refrigerant lines.
In particular the refrigerant line between the indoor heat exchanger and the compressor is susceptible to such vibrations because the line is relatively rigid due its relatively large diameter (e.g., ⅞ inch). In a non-heat pump air conditioning system, where the indoor heat exchanger operates as an evaporator, this refrigerant line corresponds to the compressor suction line, through which vapor refrigerant is drawn from the evaporator to the compressor. The length of such suction line may be about 40 feet, with most of the line being inside the building that is serviced by the air conditioning system. In a heat pump system, this refrigerant line corresponds to the compressor suction line when the system is operated in a cooling mode and to the compressor discharge line when the system is operated in a heating mode.
Such vibrations in the refrigerant line between the compressor and indoor heat exchanger may cause a droning noise that is readily detectable by occupants of the building. This droning noise results when a 120 Hz and/or 240 Hz vibration, which is typically associated with electric motor noise, is modulated by a low frequency (2 Hz or less) standing wave in the refrigerant line, which varies the intensity of the 120 Hz vibration and/or 240 Hz vibration. The standing wave causes displacement of the refrigerant line, such that contact between the line and a wall, floor or other structural component results in points of noise transmission inside the building.
One solution that has been proposed to inhibit such vibrations is to strap one or more strips of rubber around the refrigerant line, which reduces vibration by adding mass to the line and by frictional damping. The length of each rubber strip preferably corresponds to ¼ of the wavelength of the standing wave vibration (e.g., 24 inches). This solution typically is used as a “field fix” after the system installer has received a complaint about noise from a customer. The number of ¼ wavelength rubber strips needed is determined in the field, largely by trial and error. Further, the rubber strips are typically wrapped around sections of the refrigerant line that are external to a cabinet in which the outdoor heat exchanger and compressor are housed.
In accordance with the present invention, a device is provided for dampening compressor-induced vibration in an air conditioning system of the type having an indoor unit and an outdoor unit. The outdoor unit includes a compressor operable to circulate a vapor compression refrigerant between the indoor and outdoor units via a refrigerant conduit. The device is comprised of plural vibration dampening elements spaced apart along the conduit, with the spacing between adjacent elements corresponding to a wavelength of a compressor-induced natural vibratory frequency of the conduit.
In accordance with one embodiment of the invention, each vibration dampening element is comprised of a flexible member surrounding the conduit and and a relatively rigid sleeve surrounding the flexible member. In accordance with another embodiment of the invention, each of the elements includes a chamber containing plural particles in a relatively densely packed arrangement, whereby each particle is in frictional contact with at least one other particle. In accordance with yet another embodiment of the invention, each of the vibration dampening elements is comprised of plural sections of enhanced flexibility formed in the conduit. In accordance with still another embodiment of the invention, the device includes a tubular member interposed in the conduit to define a part thereof. The vibration dampening elements are spaced along the tubular member.
In accordance with a preferred embodiment of the invention, the device is located inside of a cabinet in which the compressor is housed. When a portion of the conduit inside of the cabinet includes an access component, such as a service valve, the dampening device is preferably located between the compressor and the access component. Further, in a heat pump system having a reversing valve inside of the cabinet between the compressor and service valve, the device is preferably located between the compressor and the reversing valve. Further, the interval between adjacent vibration dampening elements is preferably about one-fourth of the wavelength of the compressor induced natural vibratory frequency of the conduit.
The best mode for carrying out the invention will now be described with reference to the accompanying drawings. Like parts are marked in the specification and drawings with the same respective reference numbers. In some instances, proportions may have been exaggerated in order to depict certain features of the invention.
Referring now to
Referring also to
One skilled in the art will recognize that in a cooling mode, first heat exchanger 14 operates as an evaporator to cool supply air by transferring heat from the air flowing over the outside of heat exchanger 14 to the refrigerant flowing inside heat exchanger 14, which results in evaporation of the refrigerant. Likewise, second heat exchanger 24 operates as a condenser to condense the evaporated refrigerant by rejecting heat from the refrigerant to outdoor air flowing over the outside of heat exchanger 24. In the cooling mode, first refrigerant line 28 functions as the suction line for compressor 26 and second and third refrigerant lines 30,32 function as discharge lines for compressor 26. However, in the case of a heat pump system operating in a heating mode, the roles of heat exchangers 14,24 are reversed. Heat exchanger 14 operates as a condenser to heat the supply air and heat exchanger 24 operates as an evaporator. A reversing valve, not shown, would be located in line 28. In the heating mode, line 28 would function as the hot gas line from compressor 26 to condenser 14 and line 30 would function as a suction line from evaporator 24 to compressor 26.
As can be best seen in
As previously mentioned, such vibrations are typically associated with the vibration from the electric motor (not shown) that operates compressor 26. Such noise may include one or both of 120 Hz and 240 Hz vibrations, modulated by a low frequency (2 Hz or less) standing wave in first refrigerant line 28. The modulation produces a droning noise of varying intensity inside building 11 when the vibration of line 28 causes contact with walls or other structural components of building 11. This droning noise is readily detectable by occupants of building 11.
In accordance with the present invention, a device for dampening compressor-induced vibrations is provided. In accordance with a first embodiment of the invention, as shown in
In the case of a heat pump system, wherein the reversing valve (not shown) would be located in line 28 between compressor 26 and service valve 38, device 33 would be located between compressor 26 and the reversing valve. The portion of tubular member 34 surrounded by each element 35 has plural convolutions 34a to enhance the flexibility of tubular member 34. These convolutions may be formed by inserting an expanding roller into tubular member 34 after elements 35 are fitted over tubular member 34, so that convolutions 34a “lock” each element 35 into snug-fit engagement with tubular member 34. Although two elements 35 are shown in
Tubular member 34 has a male end 34b and a swaged female end 34c for connecting tubular member 34 to a section of line 28 between service valve 38 and compressor 26, such that tubular member 34 forms a part of first refrigerant line 28. Tubular member 34 is preferably made of the same material as line 28 and has the same diameter. For example, if line 28 is a copper tube with a ⅞ outer diameter, tubular member 34 is also a copper tube with a ⅞ inch outer diameter. Each flexible member 36 is preferably an elastomeric material such as rubber. Each sleeve 37 is preferably made of steel or iron.
The spacing L between adjacent elements 35 corresponds to the wavelength of a compressor-induced natural vibratory frequency of line 28 and is preferably about ¼ of the wavelength of the natural vibratory frequency, which allows the full amplitude of the vibration to be dampened. For example, if line 28 is a ⅞ inch diameter copper tube, the compressor-induced natural vibratory frequency may have a wavelength of about eight feet, so that the spacing L would be about two feet. Alternatively, in lieu of interposing a tubular member into line 28, elements 35 could be spaced along line 28 in concentric relationship therewith. In that case, line 28 could include corrugations associated with each element 35 to lock elements 35 in place on line 28.
In operation, device 33 dampens compressor-induced vibrations by (i) adding mass to line 28; (ii) increasing the flexibility of line 28 due to convolutions 34a; and frictionally damping vibrations by means of the snug-fit contact between elements 35 and tubular member 34. The frictional damping provided by flexible members 36 is enhanced by its snug-fit engagement with both tubular member 34 and the corresponding sleeve 37.
In accordance with a second embodiment of the invention, as shown in
When used in an air conditioning system, device 40 would be connected in line 28 between compressor 26 and service valve 38, inside cabinet 22, in the same manner as shown in
The interval M between adjacent ones of the weighted elements 44 as best shown in
In accordance with a third embodiment of the invention, as shown in
The interval N between adjacent ones of bellows sections 54 corresponds to the wavelength of a compressor-induced natural vibratory frequency of first refrigerant line 28. Preferably, the interval N is about ¼ of the wavelength of the natural vibratory frequency, which allows the full amplitude of the vibration to be dampened. For example, if line 28 is a ⅞ inch diameter copper tube, the compressor-induced natural vibratory frequency may have a wavelength of about eight feet, so that the interval N between adjacent ones of bellows sections 54 would be about two feet. Although two bellows sections 54 are shown in
The dampening device according to the present invention is preferably incorporated into the outdoor unit of an air conditioning system by the manufacturer, thereby reducing the need for “field fixes” of compressor-induced noise problems by system installers and service personnel. The best mode for carrying out the invention has now been described in detail. Since changes in and modifications to the above-described best mode may be made without departing from the nature, spirit and scope of the invention, the invention is not to be limited to the above-described best mode, but only by the appended claims and their equivalents.
Number | Name | Date | Kind |
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2395144 | Stivason | Feb 1946 | A |
4408467 | Murnane et al. | Oct 1983 | A |
H001317 | Ng | Jun 1994 | H |
5634347 | Hanson et al. | Jun 1997 | A |
5655367 | Peube et al. | Aug 1997 | A |
6167984 | Johansson et al. | Jan 2001 | B1 |
6655165 | Eisenhour | Dec 2003 | B1 |
Number | Date | Country | |
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20060048535 A1 | Mar 2006 | US |