The present invention generally relates to industrial blowers. More particularly, the present invention relates to a high-speed, belt-driven blower having an improved spindle assembly and an air cooling system in order to cool various components of the blower and improve the reliability and durability of the blower.
Compact belt-driven centrifugal blowers are commonly used in air drying and blow-off applications. These types of applications include aqueous-based in-line process cleaners which are used in a variety of manufacturing industries, consisting of wash and blow-off/dry cycles all in one self-contained machine. Other applications include ultra-high performance air knives, high volume blow-off, and de-watering applications typical with canning, beverage and electronic industries. Such blowers are also used in air evacuation, aeration and large fluidized beds. Advantages of the belt-driven centrifugal blowers are primarily improved efficiency over other types of blowers, such as so-called regenerative blowers, and perhaps just as important, the ability to maintain pressure delivery at the more useful higher flowrates.
Current blower products are all very similar in design and performance, and all suffer from the same performance limitations. One such design plan is the containment of the high-speed impeller spindle assembly (bearing) housing within the compressed-air collector housing. Understanding that air compression necessarily raises the process gas (air) temperature, the spindle housing and thus the critical high-speed bearing elements are exposed directly to the hotter compressed-air stream, limiting not only delivery pressures (i.e., gas or air temperature rise) but also the ability to manage thermal dissipation in the critical precision bearing elements. Increased bearing operating temperature has been shown to reduce overall life, shorten lubricant life and pose limitations on speed. As a rule, a 20° F. rise in operating temperature will generally reduce lubricant life by a factor of one-half. All of the current art products incorporate this design, and hence all suffer from the same shortcomings. As such, current art designs employ larger diameter impeller wheels, offsetting with slower rotational operating speeds. This scheme, unfortunately, reduces specific speed of the compressor machinery aspect with the adjunct result of reducing compressor efficiency. Reduced compressor efficiency, on the other hand, leads directly to increased drive power requirements (hence more load and heat generated within bearings, belt and idler) and increased discharge gas-air temperatures, resulting in even less cooling efficacy.
For the same reasoning, durability and life of the drive belt and the belt tensioning system, which consists of a bearing equipped idler pulley assembly, can also be extended if temperature rise in these components can be appropriately managed. Belt manufacturers, in fact, state that an 18° F. operating temperature rise within the belt may reduce life by a factor of one-half. Further, a 36° F. ambient temperature rise is sufficient to cause this 18° temperature rise. Thus, the ability to manage temperature within the drive belt assembly can be shown to promote longevity of the drive system proper.
The manufacturers which produce high-speed, belt-driven blowers (compressor) products employ either identical or very similar designs for the high-speed spindle arrangement. It should be noted that “high-speed” typically means speed ranges from 12,000 to 20,000 RPM, with new art arrangements having speeds up to 28,000 RPM. A typical prior art arrangement is depicted in
With reference to
It is common to position the spring 8 on the pulley side (as illustrated in
Attempts to compensate for the un-loading of the opposite bearing, instability and rapid failures described above, by increasing spring pre-load of the spindle assemblies of prior art results in reduced operating life due to additional pre-load. Typical operating life for current art systems range from under 2,000 to approximately 6,000 hours, or less than one year if operating on a continuous basis.
Positioning the spring at the pulley end, which is typical, is potentially troublesome as the heavy belt load, considering applied radial loads, attempts to misalign the bearing races of the bearing elements 5 and 6 at the adjacent bearing, and hence “skew” the ball track. The spring 8 is the only functioning part of the system 1 which can apply sufficient axial load to maintain this alignment. Increasing spring pre-load necessarily compromises bearing life, due in part to elevated spring load. Attempting to add bearings, i.e., “duplex” them in order to improve load carrying characteristics of the individual bearings cannot be effectively accomplished with a spring-loaded system. This is due to the poor stiffness characteristics of the spring system. Typically, only one of the bearings will carry load while the second bearing simply “goes along for the ride”.
It is, therefore, an object of this invention to incorporate a system which provides a separate, cool-air stream to the bearing assembly, for the purpose of controlling bearing temperature rise.
It is another object of this invention to provide a cool-air stream to the backside (or backplate) of the compressor housing itself, such that temperature rise due to the compressed air stream is effectively prevented from progressing towards the critical bearing mounting locations.
It is another object of this invention to provide a separate cool-air stream to the belt drive system, including the tensioning and idler pulley system, with the effect of controlling temperature rise in the drive belt and the idler pulley-bearing assembly.
It is another object of this invention to incorporate a fully enclosed drive system with cooling air entry and exhaust ports purposefully positioned to enable an efficient and highly effective cooling system.
It is another object of this invention to design the drive system enclosure such that entering cooling air may further be screened or filtered thus preventing debris from entering the system.
It is another object of this invention to incorporate sound absorbing and attenuating materials with cooling-air entry filtration.
It is another object of this invention to design the enclosure such that noise absorbing material may be conveniently applied to the enclosure interior, and manage noise which is developed in the drive-belt system, resulting in quieter system operation.
It is a further object of the present invention to incorporate an improved spindle assembly, wherein a rigid pre-load design is implemented which enables the use of additional bearings to improve load carrying characteristics and operating life of the system.
The present invention accomplishes these objects and provides other related advantages.
The present invention resides in a high-speed, belt-driven centrifugal blower having design characteristics which markedly improve life expectancy.
In one embodiment, the blower incorporates a self-contained air cooling system. The blower generally comprises a housing having air inlet and outlet apertures. Typically, the housing is comprised of a mounting plate and a cover attached to the mounting plate. Inlet apertures are typically formed in the cover, and the outlet apertures are formed in the mounting plate. To reduce noise, the cover preferably includes a sound dampening material.
A drive assembly is connected to a drive motor and disposed within the housing. A centrifugal compressor is connected to the drive assembly and disposed exteriorly to the housing adjacent to the outlet apertures. Air flows through the air inlet apertures, over the drive assembly and exit through the outlet apertures to cool various components of the drive assembly.
The drive assembly comprises a drive pulley rotatably connected to the drive motor. The drive pulley includes fan blades which draw air into the housing. As such, the drive pulley is positioned adjacent to the housing air inlet apertures.
A spindle assembly is connected to the centrifugal compressor and at least partially disposed within the housing. Typically, the spindle assembly is disposed adjacent to the outlet apertures of the housing. Cooling fins may extend from a housing of the spindle assembly to further cool the assembly. Air vents are also preferably formed in the spindle assembly housing.
A belt interconnects the drive pulley and a pulley of the spindle assembly, which powers the centrifugal compressor. A belt tensioning assembly is typically connected to the belt, and includes an automatic belt tensioner coupled to an idler. As described above, as the drive pulley is rotated by the drive motor, the belt causes a shaft of the spindle assembly to rotate and power the centrifugal compressor. Rotation of the drive pulley also causes air to enter the housing through the inlet apertures, flow over the belt and spindle assembly, and exit through the outlet apertures, thus cooling the entire drive assembly and prolonging the life of the blower.
In another embodiment, the blower incorporates a spindle assembly having a rigid bearing arrangement. The spindle assembly generally comprises a housing having a pulley end portion and an impeller end portion. A rotatable shaft extends through the housing to interconnect the pulley and the impeller. A bearing element is disposed between the shaft and the housing at the pulley end portion, and a bearing element is disposed between the shaft and the housing at the impeller end portion. The bearing elements comprise ball bearings disposed between inner and outer races, having offset grooves formed therein. Typically, the bearing elements are angular contact-type. Preferably, multiple bearing elements are disposed at either or both ends. The use of multiple bearing elements allows load sharing and enables reduction of load on any individual bearing, and hence a reduced fraction of dynamic load rating capacity. This results in markedly improved life expectancy.
A spacer set is disposed between the bearing elements, and a lock axially secures the bearing elements and spacer set rigidly in place. The lock preferably comprises a pre-loading ring, disposed between the pulley, and in contact with at least a portion of the bearing at the pulley end portion. The pulley fastener may be tightened to a predetermined torque for optimal pre-loading.
A seal is disposed between the pulley and the housing of the spindle assembly to prevent unwanted foreign matter and debris from entering the assembly. The seal may comprise a lip or controlled-gap seal. Alternatively, the seal comprises a labyrinth seal.
To cool the spindle assembly, air vents are formed in the housing thereof. Also, the spindle assembly housing includes an inner sleeve comprised of a metal having a first coefficient of thermal expansion similar to the other internal components, and an outer casing attached to the inner sleeve and comprised of a metal having a second coefficient of thermal expansion. This enables heat dissipation while maintaining the rigid pre-loading arrangement described above.
Other features and advantages of the present invention will become apparent from the following more detailed description, taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention.
The accompanying drawings illustrate the invention. In such drawings:
The present invention resides in a belt-driven industrial blower, generally referred to by the reference number 10 incorporating a self-contained air cooling system 12 for cooling various components of the blower 10 to prolong the longevity and useful life of the blower 10.
With reference now to
As illustrated in
With reference now to
With reference now to
With continuing reference to
To further facilitate the removal of heat therefrom, the housing of the spindle assembly 38 may include heat dissipating fins 60 or the like extending therefrom, or clamped thereto for further dissipating heat “Q”. Additional webbing or fins 62 may also be provided. Moreover, the housing of the spindle assembly 38, as well as the back plate 56, may be comprised of metals which facilitate heat dissipation, such as aluminum.
Tests have shown that this system 12 is quite effective. Temperature probes mounted directly on the spindle assembly 38, just outboard of the outer bearing race, verify that the assembly 38 may run as much as 65° F. cooler than the compressed air stream, measured at the discharge outlet 50 of the compressor 40. Compared to tests run without the cooling feature, spindle housing 38 running temperatures are approximately 20° F. lower. Compared to current art, bearing operating temperatures are estimated at 40° F. to 50° F. lower. At the 23,000 RPM operating point, bearing temperatures will typically run only 30-35° F. above the ambient. As even a 20° F. increase in running temperature will reduce grease life by a factor of one-half and an 18° F. temperature rise in the belt can cut belt life in one-half, it will be appreciated by those skilled in the art that the self-contained air cooling system 12 of the present invention can significantly improve the operating life of the blower 10.
With reference now to
With reference now to
A spacer set 74 comprised of inner and outer spacer elements 76 and 78 are disposed between the bearing elements 70. The tubular spacers 76 and 78 intermediate the bearing elements 70 must be precisely flush and parallel to each other in order to incorporate assembled pre-load of the bearing system appropriately.
Each bearing element 70 incorporates a precise amount of offset-grind, or grooves, on the inner/outer race 80 and 82 faces. When assembled and clamped together, these offset gaps are closed with the pre-load force being precisely determined by the displacement. However, the bearings 84 themselves may be obtained in “flush” sets, i.e. no offset-grind incorporated, with the spacers 74 instead incorporating the necessary offset grind.
With particular reference to
Thus, the clamping/pre-loading function is achieved by the pulley fastener 64, which clamps pulley 36, seal/pre-loading ring 90, bearing inner races 80 and inner tubular spacer 76 all being interacted by shaft shoulder 92. In a particularly preferred embodiment, the fastener is a 1/4-28 UNF size, although other sizes can be employed in the range of #10 screw size up to 1/2″ diameter. The 1/4-28 fastener is torqued to 100 lb-in, with a range of 20 to 200 lb-in torque being applicable to develop from 400 to 4000 lbs of compressive load. Clearly, other size fasteners would necessarily require different torque values. The design is entirely robust for applied axial loads in either direction.
The bearing element 70 may be duplexed or arranged in “tandem” pairs at both ends of the spindle, as illustrated in
It should be noted that other embodiments of the present invention can be realized, all within the scope and spirit of the invention. Such would include, but not necessarily limited to, the arrangement depicted in
Another intent of the present invention is to provide means for retaining the entire spindle assembly within its housing, and provide at the same time means for sealing the sensitive bearing element 70 from outside contaminants. The clamping/retaining ring 86 is designed to provide both functions. The retainer 86 is attached to the housing 72 via a fastener 88, such as the illustrated screw. The retainer incorporates a gland which accommodates a seal element 94. The seal element 94, as disclosed in
For the same reasons as explained above, the selection, quantity and fastening torque of the attaching screw 88 are all crucial parameters of the present design. In the preferred embodiment, five screws of 8-32 size are employed with a fastening torque specification of 20 lb-in, with a torque range of 5 to 100 lb-in being applicable. Clearly, other attachments screws in size and quantities may be selected and be within the scope of the present invention. It should also be noted that a threaded ring may be employed in lieu of the ring with separate attachment screws 88.
With reference now to
With reference now to
Thus, the present invention employs an integral ferrous sleeve 72 having a similar or identical coefficient of thermal expansion and conductivity as the internal bearing elements 70 and spacers 74. Thus, the thermally induced growth or shrinkage of the these components is matched by the housing liner 72 due to the similar coefficients of thermal expansion. Cast aluminum 56 is over-molded around the cast ferrous liner 72, the resulting construction comprising a single composite casting, as illustrated in
Another problem encountered with prior art spindle assemblies 38 is that when operating at higher temperature and fully sealed, the assembly 38 housing will tend to self-pressurize as it warms. Aggressive sealing must be incorporated to prevent bearing lubricant from being “blown” out of the ends of the spindle and potentially into the working air stream. However, incorporating aggressive positive sealing means necessarily incurs increased frictional losses and increased seal wear rates. Heat generated by seals has been shown to elevate bearing running temperatures at the inner race 80, with associated life impacting consequences.
Thus, it is an object of the present invention to incorporate a vented bearing housing which effectively and necessarily precludes large differential pressures from developing within the housing. As shown in
Although several embodiments have been described in detail for purposes of illustration, various modifications may be made without departing from the scope and spirit of the invention. Accordingly, the invention is not to be limited, except as by the appended claims.
This application claims priority from U.S. Provisional Application Ser. No. 60/369,736, filed Apr. 4, 2002.
Number | Date | Country | |
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60369736 | Apr 2002 | US |
Number | Date | Country | |
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Parent | 10407718 | Apr 2003 | US |
Child | 11122580 | May 2005 | US |