Patent Application
20070141248
This invention relates generally to the application of a sprayed insulation mixture, and more particularly to an apparatus and method for applying the sprayed mixture in high reach areas of extended elevation or height.
Sprayed insulation is commonly used in the construction industry for insulating the open cavities of building walls, floors, ceilings, attics and other areas. Insulating materials, such as loose fiberglass, rock wool, mineral wool, fibrous plastic, cellulose, ceramic fiber, etc. that is combined with an adhesive or water, are sprayed into such open cavities to reduce the rate of heat loss or gain there-though. The properties of the insulation mixture, comprising insulation combined with the adhesive or water, allow it to adhere to vertical or overhanging surfaces, thus allowing for the application of insulation prior to the installation of wallboard and similar cavity enclosing materials.
Various systems have been devised for the application of spayed insulation mixtures into open cavities. Such systems typically utilize a loose insulation blower that draws loose insulation out of a hopper and pneumatically conveys it through a hose and out of the outlet end of an applicator nozzle. The adhesive that is mixed with the insulation is preferably a liquid adhesive that is sprayed onto the airborne insulation as it leaves the outlet end of the applicator nozzle. The water may also be sprayed onto the insulation when the insulation includes a dry adhesive material within the insulation mix, with the water thereafter activating the adhesive properties of the material. The liquid adhesive or water that is added to the airborne insulation is typically pumped from a reservoir and through one or more spray tips located proximal to the end of the applicator nozzle.
In applying sprayed insulation into open cavities, installers typically manually hold the outlet end of the applicator nozzle towards the open cavity. The installer then sprays the insulation mixture into the cavity until the cavity is filled. To ensure that the cavity is completely filled, an installer typically sprays an excess amount of mixture into the cavity such that an excess quantity of sprayed insulation has accumulated beyond an opening of the cavity defined by the cavity's confining boundaries, i.e. beyond the opening of a wall cavity defined by wall studs. The excess quantity of insulation is then removed or “scrubbed off,” utilizing a hand-held scrubber, to define a boundary of the sprayed insulation lying substantially planar at the cavity's opening.
A separate vacuum system is typically utilized to gather the excess insulation that is scrubbed-off or removed from the cavity's opening. In utilizing such a vacuum system, excess or scrubbed-off insulation is gathered or swept into a localized area. The gathered excess insulation is then drawn into the end of a vacuum inlet typically held by an installer. A vacuum fan then draws the excess material into the vacuum inlet and through a vacuum hose, and thereafter deposits the material into a bin or other container.
When applying sprayed insulation to a given open cavity, a preferred application distance is maintained between the outlet end of the applicator nozzle and the cavity for a given R value of insulation to ensure that a predetermined density or consistency of the sprayed insulation is maintained within the cavity. It is thus desirable to maintain a constant application distance during the application of an insulation of given R value. However, because present applicator nozzles are hand-held by the installer without any means for maintaining a constant distance between the nozzle outlet and the cavity to be sprayed, inconsistencies in application distance may occur, thus resulting in insulation applications lacking in uniform density.
Also, in maintaining a desired application distance between the nozzle outlet and the cavity to be sprayed, the installer and hand-held applicator nozzle must thus remain proximal to the cavity opening when spraying the insulation therein. However, maintaining this desired proximity between the installer and cavity is difficult when spraying the insulation into wall or ceiling cavities having an extended height or elevation because such extended elevations (i.e. located beyond about nine feet in height) are typically out of reach of the installer utilizing a hand-held insulation applicator nozzle and hand-held scrubber.
Various stilts, ladders and scaffolding systems are presently utilized by sprayed insulation installers to bring the installers into proximity with elevated cavities openings to be insulated. However, a number of disadvantages are associated with the use the use of such stilts, ladders and scaffolding. For example, their use presents numerous workplace safety hazards because each requires the installer to be elevated (i.e. on the stilts, ladder or scaffold) while spraying the insulation mixture into the elevated cavities or scrubbing the excess mixture therefrom. Thus, when in an elevated position on a ladder or stilts and working with the insulation applicator nozzle or hand-held scrubber, the installer handling the spray equipment is subject to the risk of falling and possible injury. Although the use of scaffolding systems presents less of a falling risk for the installer than stilts or ladders, the risk is nonetheless present while also requiring additional time and expense for transporting, mobilizing and setting-up of the scaffolding at a particular job site.
In addition to the inherent disadvantages associated with the use of stilts, ladders and scaffolding in elevating an insulation installer to a location proximal to an elevated wall or ceiling cavity, disadvantages are also associated with the sprayed insulation system itself, namely the spraying, scrubbing and subsequent vacuuming of the scrubbed excess insulation. Present systems utilizing such spraying, scrubbing and vacuuming procedures are not integrated, thus essentially requiring the execution of three separate procedures using three separate pieces of equipment. While a lone installer can perform each of the three separate procedures, use of a lone installer to perform all of the procedures is generally avoided because the overall execution of the three procedures is labor intensive and exhausting.
For example, the installer, after spraying a given course the insulation with the applicator nozzle, would have to dispose of (i.e. put down) the applicator nozzle and then utilize the hand-held scrubber to remove the excess sprayed insulation. After removing the excess insulation with the hand-held scrubber, the installer would then have to dispose of the scrubber and then utilize the vacuum system to gather the scrubbed, excess insulation. Because use of a lone installer to perform each of these procedures is too labor intensive, three-person teams are typically utilized instead, with each person of the team performing one of the three spraying, scrubbing and vacuuming procedures. However, the use of three-person teams, although less labor intensive for a given installer, results in undesirable additional costs associated by employing two additional installers for a given insulation job.
Thus, what is needed is an integrated, sprayed insulation system that allows an installer to maintain a constant application distance between the applicator nozzle outlet and the cavity to be sprayed. Such a system should also facilitate the application of the sprayed insulation mixture into elevated wall and ceiling cavities and the scrubbing of excess mixture therefrom while avoiding the use of stilts, ladders and scaffolding. The system should also allow a single installer to efficiently perform all three of the spraying, scrubbing and vacuuming procedures in an effort to minimize the labor costs associated with the utilization of three-person teams. The present invention fulfills each of the foregoing needs.
This invention relates generally to the application of a sprayed insulation mixture, and more particularly to an apparatus and method for applying the sprayed mixture in high reach areas of extended elevation and removing any excess mixture therefrom. In one embodiment of a system for spraying an insulation mixture into a cavity and removing any excess mixture therefrom, the system preferably comprises a lift defining upper and lower ends, with the upper end of the lift being adjustably movable between lowered and raised positions. An insulation applicator is located on the lift proximal to the upper end for spraying the insulation mixture into the cavity. The applicator may be movably connected to the lift and driven to move in a reciprocating, sweeping motion.
In a preferred embodiment, a scrubber is located on the lift above the applicator for removing or scrubbing any excess insulation from the cavity while in another embodiment the applicator is located on the lift above the scrubber. A vacuum inlet is preferably located on the lift below the applicator for receiving any stray or “fly-off” insulation from the applicator and the excess insulation removed from the cavity by the scrubber. A gauge may also be located on the lift for maintaining a predetermined spray distance between the applicator and the cavity. A driven elevation mechanism is operably associated with the lift for adjustably moving at least the upper end of the lift between the lowered and raised positions. A control is operably associated with the insulation applicator, scrubber, vacuum inlet and driven elevation mechanism to control the function of each component.
The lift comprises both a base, located at the lift's lower end, and a plurality of extenders. Each extender of the plurality is located adjacent to at least one other extender, with adjacent extenders of the plurality movably connected to one another. At least one extender of the plurality is supported by the base while at least one extender of the plurality defines the upper end of the lift. The driven elevation mechanism operably associates the extenders of the plurality to one another to adjustably move the upper end of the lift between the lowered and raised positions.
The base preferably comprises a longitudinal frame located at the lower end of the lift for supporting at least one extender of the plurality, thus providing support for the lift while the lift is in both the lowered and raised positions. In an embodiment, the lift comprises a “ladder lift” wherein each extender of the plurality comprises a stanchion. A lower stanchion is supported by the base while an upper stanchion defines the upper end of the lift. Depending upon the desired height of the overall lift, one or more intermediate stanchions may be located between the lower and upper stanchions.
In one embodiment of the ladder lift, adjacent stanchions are movably connected to one another to define a telescopic relationship while in another embodiment, adjacent stanchions are movably connected to one another to define a parallel relationship. At least one elongated guide is preferably located between each adjacent stanchion of the plurality to enable a translational movement between the stanchions. The at least one guide comprises a common “double V-guide” having engaging sections movably secured to one another to facilitate a translational movement there-between. The ladder lift preferably utilizes a driven elevation mechanism comprising either a motor-driven cable assembly or a plurality of actuators to operably associate the stanchions of the plurality to one another.
In another embodiment, a “scissors lift” is utilized wherein each extender of the plurality comprises an assembly of first and second crossed links. A lower assembly is supported by the base while an upper assembly defines the upper end of the lift and supports a carrier. Depending upon the desired height of the overall lift, one or more intermediate assemblies may be located between the lower and upper assemblies. The elevation mechanism of the scissors lift may comprise at least one motor-driven machine screw or at least one actuator to operably associate the assemblies of the plurality.
In one embodiment of the invention, the applicator, optional drive, scrubber and vacuum inlet are located on the upper stanchion of the lift, preferably proximal to a front surface of the stanchion. In another embodiment, the components are located on the carrier supported by the upper assembly of the lift, preferably proximal to a front surface of the carrier. To ensure a consistent application of the insulation mixture by the applicator, a gauge may be located on the lift for maintaining a predetermined distance between the applicator and cavity. The gauge may comprise an adjustable probe located on the lift, an adjustable toe defined on the base, an adjustable arm utilized on the scrubber or the forward end of the base itself.
The applicator, optional reciprocating applicator drive, scrubber, vacuum inlet and elevation mechanism are operably associated with the control. The control preferably comprises a plurality of switches for operation of at least the foregoing components of the system. In one embodiment, the control is used in a “manual mode” wherein the components are energized and de-energized independently of one another via the independent switches for each. In another embodiment, the control is used in an “automatic mode” wherein the components are each automatically energized and de-energized in relation to the operation of the elevation mechanism.
With regard to either a manual or automatic use of the system, the sprayed insulation mixture is preferably applied to a wall cavity from the lower end of the cavity to the cavity's upper end (i.e. bottom-to-top). A bottom-to-top application of the sprayed insulation mixture allows the applied mixture to form a solid base within the cavity, thereby building upon that solid base as the applicator moves from the wall cavity's lower to upper ends. In the preferred embodiment of the invention, any excess mixture is removed from the cavity by the scrubber preferably from the upper end of the cavity to the cavity's lower end (i.e. top-to-bottom) while in an alternate embodiment the excess mixture is removed from the cavity by the scrubber during the application of the insulation from the lower end of the cavity to the cavity's upper end (i.e. bottom-to-top).
In use in an application process for the preferred embodiment of the system having the scrubber located on the lift above the applicator, the lift is positioned at the lower end of the wall cavity, with the lift having the applicator, scrubber and vacuum inlet located thereon. During the positioning process, the distance between the applicator and cavity 1 may be gauged with the gauge. The insulation blower and pump and the vacuum fan are energized such that the insulation mixture is sprayed into the cavity with the applicator, with the vacuum inlet receiving any stray or “fly-off” mixture from the applicator, as the applicator, scrubber and vacuum inlet ascend on the lift from the lower end of the cavity to an upper end of the cavity. The optional reciprocating drive may be energized for reciprocating the applicator from side-to-side as the applicator is spraying the insulation mixture into the cavity. During the ascent, the rate of ascent, the flow of adhesive or water to the applicator, and the rate of the side-to-side or sweeping movement of the applicator may be controlled.
Upon reaching the upper end of the cavity, the insulation blower and pump and the optional reciprocating drive are de-energized and the scrubber is energized. Any excess mixture is thus removed from the cavity with the scrubber, with the vacuum inlet receiving the removed mixture, as the applicator, scrubber and vacuum inlet descend on the lift from the upper end of the cavity to the cavity's lower end. During the descent, the rate of descent may be controlled. Upon reaching the lowered position, the lift is repositioned to the lower end of another cavity, and the sequence is repeated for the application of the next insulation course.
In use in an alternate application process for the embodiment of the system having the applicator located on the lift above the scrubber, the lift is again positioned at the lower end of the wall cavity, with the lift having the applicator, scrubber and vacuum inlet located thereon. During the positioning process, the distance between the applicator and cavity may again be gauged with the gauge. The insulation blower and pump and the vacuum fan are energized such that the insulation mixture is sprayed into the cavity with the applicator, with the vacuum inlet receiving any stray or “fly-off” mixture from the applicator, as the applicator, scrubber and vacuum inlet ascend on the lift from the lower end of the cavity to an upper end of the cavity. The optional drive may be energized for reciprocating the applicator from side-to-side as the applicator is spraying the insulation mixture into the cavity. The scrubber is also energized during the ascent such that any excess mixture is removed from the cavity during the ascent, with the vacuum inlet again receiving the removed mixture. During the ascent, the rate of ascent, the flow of adhesive or water to the applicator and the rate of the side-to-side or sweeping movement of the applicator may again be controlled. Upon reaching the upper end of the cavity, the lift 20 and attached components are repositioned to the lower end of another cavity and the sequence is repeated for the application of the next insulation course. However, an optional, subsequent scrubbing operation may be performed wherein any excess mixture remaining after the ascent is removed from the cavity with the scrubber, with the vacuum inlet again receiving any removed mixture.
This invention relates generally to the application of a sprayed insulation mixture, and more particularly to an apparatus and method for applying the sprayed mixture in high reach areas of extended elevation and removing any excess mixture therefrom.
In the preferred embodiment of the invention, a scrubber 50 is also located on the lift 20 above the applicator 42 for removing or scrubbing any excess insulation from the cavity 15. In another embodiment, to be further discussed, the scrubber 50 is located on the lift 20 proximal to the upper end 25 with the applicator 42 located on the lift above the scrubber. In both embodiments, a vacuum inlet 55 is preferably located on the lift 20 below the applicator 42 for receiving any stray or “fly-off” insulation from the applicator and the excess insulation removed from the cavity 15 by the scrubber 50. A gauge 60 may also be located on the lift 20 for maintaining a predetermined spray distance between the applicator 42 and the cavity 15. A driven elevation mechanism 65 is operably associated with the lift 20 for adjustably moving at least the upper end 25 of the lift between the lowered and raised positions 35 and 40. A control 70 is operably associated with the insulation applicator 42, scrubber 50, vacuum inlet 55 and driven elevation mechanism 65 to control the function of each component.
The base 75 illustrated within
The frame 85 is thus comprised of a rigid material, such as aluminum, steel, fiberglass, plastic, composite materials or other similar materials capable of providing support to the lift 20 and other components located thereon. A plurality of wheels 90 on rotating casters 95 may be located on the frame 85 to facilitate a movement of the lift 20 between locations. Such wheels 90 are preferably lockable to immobilize the lift 20 when located in a desired position.
In an embodiment of the lift 20 illustrated in
Each stanchion is comprised of a material having a rigidity capable of supporting the other stanchions, as well as the applicator, scrubber and vacuum inlet located on the upper stanchion 140. The stanchions 100 are thus preferably comprised of aluminum, steel, fiberglass, plastic, composite materials, or other similar materials having the desired rigidity. In the embodiment of the invention illustrated in
In defining the foregoing movable connections between stanchions, at least one elongated guide 150 is preferably located between each adjacent stanchion 100 of the plurality to enable a translational movement between the adjacent stanchions. As illustrated in
The lift 20 preferably utilizes a driven elevation mechanism 65 comprising either a motor-driven cable assembly 190 or a plurality of actuators 195 to operably associate the stanchions 100 of the plurality to one another. Referring again to
The motor-driven reel 205 is located at the lower end 30 of the lift 20 while each opposing puller pair 210 of the series operably associates connected, adjacent stanchions 100. The motor-driven reel 205, a common device understood in the art, is operable to rotate in both forward and reverse directions. The forward and reverse directions of the reel may be accomplished via the use of a reversible, electric motor or via the use of a gear system or transmission located between the motor and reel. Although
The reel 205 moves the cable 200 through the opposing pulley pairs 210 to operably associate the connected, adjacent stanchions 100. The opposing pulleys 210a and 210b of each pair 210 are located on respective upper and lower portions 115 and 120 of the connected, adjacent stanchions 100, with the respective pulley pairs operably associating the respective stanchions. The cable 200 thus runs through the opposing pulleys 210a and 210b of each pulley pair 210, with one end of the cable connected to the motor-driven reel 205 and the opposite end 207 of the cable connected to the lower portion 120 of the upper stanchion 140.
Thus, when the motor-driven reel 205 is actuated to draw in the cable 200, the length of the cable between the reel and upper stanchion 140 is progressively shortened. A shortening of the cable's length causes the opposing pulleys 210a and 210b of each pair 210 to be drawn together to move the respective upper and lower portions 115 and 120 of the respective adjacent stanchions 100 towards one another, resulting in an elevation of each stanchion and a raising of the upper stanchion 140 defining the upper end 25 of the lift 20.
A lengthening of the cable 200 between the reel 205 and the upper stanchion 140 will conversely allow the opposing pulleys 210a and 210b of each pair 210 to be spread apart, via the weight of each stanchion, thus allowing the respective upper and lower portions 115 and 120 of the respective adjacent stanchions 100 to move away from one another. As the respective upper and upper and lower portions 115 and 120 of the connected adjacent stanchions 100 move away from one another, the elevation of each stanchion will be reduced to lower the upper stanchion 140 defining the upper end 25 of the lift 20.
Referring again to
Each cylinder 210 of each actuator 195 is preferably located on the lower portion 120 of a given stanchion 100, with the rod 220 having a driven end 225 connected to the lower portion of the connected, adjacent stanchion. Each actuator 195 is preferably connected to a common air compressor or hydraulic pump such that the rods 220 of the actuators are driven simultaneously upon actuation of the compressor or pump. Similarly, each actuator 195 is controlled by the control 70, to be discussed further, such that the rod 220 of each actuator will retract into the respective cylinder 210 when the control allows the fluid to be released from each cylinder.
Thus, when the air compressor or hydraulic pump is actuated, the air or fluid is forced into the cylinder 210 to drive the rod 220 upwardly against the lower portion 120 of the connected adjacent stanchion 100, thus raising the elevation of each stanchion to raise the upper stanchion defining the upper end of the lift. A release of air or fluid from within the cylinders 210 via the control 70, to be further discussed, will cause the rod 220 of each actuator 195 to retract into the respective cylinder, thus lowering the elevation of each stanchion to lower the upper stanchion 140 defining the upper end 25 of the lift 20.
Although
In the embodiment of the lift 20 illustrated in
The first and second crossed links 240 and 245 of each assembly 235, preferably comprised of aluminum, fiberglass, steel, composite materials or similar materials, are rotatably connected to one another at a midpoint 270 and define upper and lower sets 275 and 280 of laterally opposing link ends 285a and 285b. The link ends 285a and 285b of at least one set of each assembly 235 of the plurality are rotatably connected to the link ends of the at least one adjacent assembly. Thus, if a given assembly 235 is located adjacent to two assemblies (i.e. the intermediate assembly 265 located between upper an lower assemblies 255 and 250), the upper and lower sets 240 and 245 of opposing link ends 285a and 285b of that assembly are rotatably connected to the link ends of the respective adjacent assemblies. However, if a given assembly 235 is located adjacent to only one assembly, i.e., the lower assembly 250 supported by the base 75 or the upper assembly 255 defining the upper end 25 of the lift 20, that assembly will have only one set of link ends 285a and 285b (i.e. an upper or lower set of link ends) rotatably connected to the link ends of the adjacent assembly.
For example, the lower assembly 250 supported by the base 75 has the lower set 280 of link ends 285a and 285b operably associated with the base 75 and the upper set 275 of link ends rotatably connected to the respective link ends of the adjacent assembly located above it. Similarly, the upper assembly 255 defining the upper end 25 of the lift 20, also supporting the carrier 260 located there-above, has the upper set 275 of link ends 285a and 285b operably associated with the carrier and the lower set 280 of link ends rotatably connected to the respective link ends of the assembly located below it.
The elevation mechanism of the embodiment illustrated in
Thus, a rotation of the motor-driven screw 290 in one direction will draw the link ends 285a inwardly while a rotation of the screw in the opposite direction will move the link ends outwardly. Although the driven end 295 of the motor-driven machine screw 290 is illustrated as threadedly associating with link ends 285a, it is understood that the driven end could also be associated with link ends 285b instead with the link ends 285b translatingly associated with the base and 285a rotatably associated with the base. It is also understood that a driven screw having opposing threaded ends could be threadedly associated with both link ends 285a and 285b as well, with each the link end translatingly associated with the base 75.
Inwardly drawing the link ends 285a results in the crossed links 240 and 245 of the respective assembly 235 rotating about their midpoint 270 to inwardly draw the other link ends of the other assemblies rotatably connected thereto, resulting in a gain in elevation of each assembly of the plurality to ultimately raise the elevation of the upper assembly 255 defining the upper end 25 of the lift 20. Conversely, outwardly moving the link ends 285a results in the crossed links 240 and 245 of the respective assembly 235 rotating about their midpoint 270 in an opposite direction to outwardly move the other link ends of the other assemblies rotatably connected thereto, resulting in a loss in elevation of each assembly of the plurality to ultimately lower the elevation of the upper assembly 255 defining the upper end 25 of the lift 20.
Thus, when the air compressor or hydraulic pump is actuated to force air or fluid into the cylinder 210 of the at least one actuator 195, the respective rod end 225 is driven upwardly against the upper set 275 of link ends 285b to spread the upper set from the lower set 280. A release of air or fluid from within the cylinder 210 via the 70, to be further discussed, will cause the rod end 225 of the at least one actuator 195 to retract into the respective cylinder 210, thus bringing the upper set 275 of link ends 285b into proximity with the lower set 280.
A spreading of the upper set 275 of link ends 285b from the lower set 280 results in the crossed links 240 and 245 of the assembly 235 rotating about their midpoint 270 to spread other upper and lower sets of link ends of the other assemblies, rotatably connected thereto, resulting in a gain in elevation of each assembly of the plurality to ultimately raise the elevation of the upper assembly 255 defining the upper end 25 of the lift 20. Conversely, bringing the upper set 275 of link ends 285b into proximity with the lower set 280 results in the crossed links 240 and 245 of the assembly 235 rotating about their midpoint 270 in an opposite direction to bring the other upper sets of the other assemblies, rotatably connected thereto, into proximity with their respective lower sets, resulting in a loss in elevation of each assembly of the plurality to ultimately lower the elevation of the upper assembly 255 defining the upper end 25 of the lift 20.
Although
Regardless of the type or location of the elevation mechanism 65 used to raise or lower the assemblies 235 and upper end of the lift 20, the laterally opposing link ends 285a and 285b of the assemblies of the lift will move in relation to one another during the operation of the elevation mechanism. To facilitate a movement of the lower set 280 of the link ends 285a and 285b of the lower assembly 250 in relation to the base 75, the lower set of link ends are operably associated with the base. In the embodiment of the invention illustrated in
Thus, as the elevation mechanism 65 raises or lowers the lift 20, the link ends 285b rotate in relation to the base 75 while the other link ends 285a translate on the base respectively towards or away from the rotating links. The operation of the upper set 275 of link ends 285a and 285b of the upper assembly 255 in relation to the carrier 260 undergoes a similar operation, with the laterally opposing link ends rotating and translating respectively in relation to the carrier. While
Referring to
In both embodiments, a vacuum inlet 55 is preferably located on the lift 20 below the applicator 42 to receive any stray or “fly-off” insulation from the applicator and the excess insulation removed from the cavity 15 by the scrubber 50.
The applicator 42 preferably comprises an insulation spray nozzle 43 located between a pair of spray tips 44. The nozzle 43 sprays loose insulation out of an outlet end 45 defined therein while the spray tips 44 spray liquid adhesive or water onto the airborne insulation to create the insulation mixture 10. The insulation is moved by a driven blower from an insulation source, such as a hopper, and through an applicator hose to the nozzle 43 of the applicator 42. The liquid adhesive or water is moved by a driven pump from a reservoir and through a liquid hose to the spray tips 44 of the applicator 42. The insulation mixture 10 thus leaves the applicator and is sprayed into a wall or ceiling cavity 15.
The applicator 42 is located on the lift 20 preferably at a slight downward angle α from horizontal to allow the sprayed insulation to pack together and form a solid base within the cavity 15 as the applicator moves from a lower end of the wall cavity to an upper end. The downward angle α (illustrated only in
In the preferred embodiments illustrated in
In the embodiment illustrated in
In embodiments of the invention illustrated in
The scrubber 50, preferably comprising a reversible, motor-driven rotary brush or textured wheel 51 located at the end of an arm 52, scrubs excess insulation mixture 10 from the cavity 15. The rotary brush or wheel 51 of the scrubber 50 is preferably driven such that a forward surface 54 of the brush or wheel 51 rotates in the direction of the ascent or descent of the scrubber and other components on the lift 20. Thus, if the scrubber 50 is ascending on the lift 20, the forward surface 54 of the brush or wheel 51 preferably rotates in an upwardly direction. Conversely, if the scrubber 50 is descending on the lift 20, the forward surface 54 of the brush or wheel 51 preferably rotates in a downwardly direction. However, it is understood that the forward surface 54 of the brush or wheel 51 may be driven to rotate in either direction during either an ascent or descent of the scrubber 50 on the lift 20.
In the embodiment illustrated in
The vacuum inlet 55, preferably comprising a hopper connected to a vacuum hose and vacuum fan, receives any stray or “fly-off” insulation from the applicator 42 and the excess insulation removed from the cavity 15 by the scrubber 50. In the embodiments illustrated in
As illustrated in
In one embodiment, the gauge 60 comprises a forwardly-directed probe 300 of adjustable length located on the lift 20 and having an end 305 adapted for contact with a wall frame, rear surface of a wall cavity 15 or other structure. As illustrated in
In an alternate embodiment illustrated again in
In another embodiment illustrated in
In yet another embodiment, the base 75 defines the gauge 60 such that the base's forward end 77 is located forward of the extenders 80 of the lift by a pre-determined distance. Thus, when the forward end 77 of the base 75 is in contact with the wall frame as illustrated in
The applicator 42, optional reciprocating applicator drive 47, scrubber 50, vacuum inlet 55 and elevation mechanism 65 are operably associated with the control 70. The control 70, as illustrated in
The control 70 further comprises a scrubber motor on/off switch 350 and direction control switch 351 for energizing and de-energizing the scrubber 50 and changing the rotational direction of the forward surface 54 of the brush or wheel 51 between upwardly and downwardly directions, respectively, and a vacuum fan on/off switch 355 for energizing and de-energizing the vacuum fan of the vacuum inlet 55. The pump flow control switch 335 and the reciprocating drive rate control switch 345 preferably utilizes rheostats, stepped rotary switches, variable frequency drive controls, or other controls understood in the art, to control the rate of rotation of the liquid pump motor and of the motor-driven crank 48, the motor-driven machine gear 62 or the linear actuator 49 of the reciprocal drive 47. The scrubber direction control switch 351 utilizes common motor controllers understood in the art to change the direction of the motor-driven scrubber 50.
The control 70 further comprises an ascend/descend switch 360 for the operation of the elevation mechanism 65 of the lift 20 and an ascend/descend rate control switch 365 for controlling the rate of the lift's ascent or descent. For embodiments of the system utilizing a motor-driven reel 205 or a motor-driven machine screw 290 as the elevation mechanism 65, the ascend/descend switch 360 utilizes common motor controllers known in the art to energize and de-energize the motor in forward and reverse directions to thus cause the lift 20 to ascend and descend, respectively. The rate control switch 365 utilizes rheostats, stepped rotary switches, variable frequency drive controls, or other controls understood in the art to control the rate of rotation of the motors for both of these elevation mechanisms to change the respective rates of ascent or descent of the lift 20.
For embodiments of the system utilizing hydraulic or pneumatic actuators 195 as the elevation mechanism 65, the ascend/descend switch 360 utilizes common motor controllers known in the art to energize a hydraulic pump or air compressor motor to create a forward flow of air or hydraulic fluid to the actuators to thus cause the lift 20 to ascend. The ascend/descend switch 360 further utilizes fluid flow regulators or valves understood in the art to permit a backflow of air or hydraulic fluid from the actuators 195 to cause the lift 20 to descend under its own weight. The rate control switch 365 again utilizes fluid flow regulators understood in the art to control the rate of air or hydraulic fluid to and from the actuators 195 to change the respective rates of ascent or descent of the lift 20.
The control 70 may be operated in either a “manual mode” or in an “automatic mode” via an operation of the manual/automatic mode selection switch 370. In the manual mode, the blower and pump for the applicator 42, the optional reciprocating applicator drive 47, the motor for the scrubber 50 and the vacuum fan for the vacuum inlet 55 are each energized, de-energized and/or controlled independent of one another via the independent control switches for each located on the control 70. The elevation mechanism 65 is also controlled independently of the other components in the manual mode to adjust the elevation of the lift 20 via the respective control switches located on the control as well. In the automatic mode, an operation of the ascend/descend switch 360 will result in the automatic energization and/or de-energization of at least the elevation mechanism 65, the blower and pump for the applicator 42, the optional reciprocating applicator drive 47, the motor for the scrubber 50 and the vacuum fan for the vacuum inlet 55 in relation to the operation of the elevation mechanism 65 of the lift 20.
With regard to either a manual or automatic use of the system 5, as illustrated in
Upon reaching the upper end 17 of the cavity 15, as illustrated in
Upon reaching the upper end 17 of the cavity 15, the lift 20 and attached components are repositioned to the lower end of another cavity and the sequence is repeated for the application of the next insulation course. However, as illustrated in
To facilitate the foregoing operation, the components of the system are thus energized and de-energized either manually or automatically with the control 70. After positioning and optionally gauging the lift 20 at the lower end 16 of the cavity 15, the manual mode of the control 70 may be utilized via an operation of the selection switch 370. When in the manual mode for the preferred embodiment of the system 5 having the scrubber 50 located on the lift 20 above the applicator 42 (
When the upper end 25 of the lift 20 reaches the raised position (i.e. at the upper end of the cavity 15,
When in the manual mode for the alternate embodiment of the system 5 having the applicator 42 located on the lift 20 above the scrubber 50 (
When the upper end 25 of the lift 20 reaches the raised position (i.e. at the upper end of the cavity 15), the applicator 42 and the optional reciprocating applicator drive 47 are preferably de-energized via an operation of the respective blower and pump switches 325 and 330 and the optional reciprocating drive switch 340. The scrubber 50 and vacuum fan of the vacuum inlet 55 are also preferably de-energized via an operation of the respective scrubber and vacuum fan switches switch 350 and 355. The elevation mechanism switch 360 is operated (i.e. moved to the descend position) to cause the lift 20 to descend from the upper end of the cavity 15 to the cavity's lower end and the lift 20 and attached components are repositioned to the lower end of another cavity and the sequence is repeated for the application of the next insulation course. It is understood, however, that various components (i.e. the vacuum fan for the vacuum inlet) may remain energized during the descent and when repositioning the lift.
If an optional, subsequent scrubbing operation is desired (
After positioning and optionally gauging the lift 20 at the lower end of the cavity 15, the automatic mode of the control 70 may be utilized via an operation of the selection switch 370. When in the automatic mode for the preferred embodiment of the system 5 having the scrubber 50 located on the lift 20 above the applicator 42 (
When the upper end 25 of the lift 20 reaches the raised position (
When in the automatic mode for the alternate embodiment of the system 5 having the applicator 42 located on the lift 20 above the scrubber 50 (
When the upper end 25 of the lift 20 reaches the raised position, the limit switch 375 preferably located on the lift's upper end is triggered, causing an automatic de-energization of the blower, pump and the optional reciprocating drive 47 of the applicator 42, and the vacuum fan for the vacuum inlet 55, and further causing the lift to automatically descend to the lowered position. After the lift 20 and attached components reach the lowered position, it is repositioned to the lower end of another cavity and the sequence is repeated for the application of the next insulation course.
If the optional, subsequent scrubbing operation is desired (
While this foregoing description and accompanying drawings are illustrative of the present invention, other variations in structure and method are possible without departing from the invention's spirit and scope.
