PURLIN CLIP ASSEMBLY AND SYSTEM

Abstract

A weight-bearing system for hanging items from the roof structure of a metal building is disclosed. The system includes a purlin with at least one flange, a span aperture in the vertical span of the purlin, a clip that attaches to the purlin using the span aperture, and a fastener on the clip for transferring weight applied to the fastener to the clip and to the vertical span of said purlin.

Description

BACKGROUND

The invention relates to building structures and is particularly advantageous in prefabricated metal buildings.

As used herein, the term “metal building,” typically refers to a steel structure with a steel frame (although sometimes a wood frame) that is easier and faster to build then some other types of construction. Metal buildings also can require less upkeep than buildings made using other materials. Examples include barns, garages, carports, storage buildings and the like. Metal buildings are also used commercially for stores, churches, and schools. Others are used in the agricultural context such as animal barns and crop storage.

Prefabricated metal buildings can be assembled more quickly than conventional structures and often at lower cost. Their footprint can be modified quickly for ease of expansion and flexibility of use. Generally speaking, a steel building can have a longer lifetime than a similar structure made of wood, and the lower fire hazard can make metal buildings less expensive to insure.

The structural elements of many metal buildings includes vertical posts to which purlins connect to form the framework for the roof. As used herein, a purlin is a longitudinal member in a roof frame for supporting common rafters between the plate and the ridge. In certain metal buildings the purlins are roughly Z-shaped girders formed of a web or span that orients vertically in construction and two flanges which extend at 90° from the web in opposite directions from one another.

In many circumstances (including some required by building codes) insulation is then placed into the roof structure following which the purlins are covered with a sheet, typically a synthetic fabric material. Thus, from the perspective inside the building, the sheet forms the ceiling and hides the purlins and the other parts of the roof structure

Because of the various uses for metal buildings, however, a need often exists to hang various items from the ceiling (e.g., loudspeakers, lighting, HVAC components), which in turn means hanging those items from the roof structure behind the roof fabric. In one conventional method, this is typically done by puncturing the fabric ceiling at the intended location, and then driving (e.g.) self-tapping screws into the roof structure. This is generally unsatisfactory for several reasons including the exploratory nature of puncturing the ceiling fabric and the fact that many users take the shortcut of hanging a clip from the flange of the purlin, with the flange being the weakest point of the roof structure. In some cases, hanging items from a purlin flange violates building codes.

As another problem, the desired or necessary amount of insulation required in any given circumstance (e.g., local climate; expected purpose for the building) can make a current pre-engineered metal roof structure unattractive or simply inappropriate. In particular, because either glass wool or foam board insulation provides only about R-3 to R-5 per inch of thickness, the amount of insulation required to reach (e.g.) R-60 may be either unworkable or disadvantageous in current pre-engineered metal structures.

Thus a need exists for a more efficient method of using a roof structure under a fabric ceiling, for avoiding excessive weight on purlin flanges, for positioning hanging items from stronger portions of the roof structure, and for avoiding unnecessary or excess openings in a fabric ceiling.

SUMMARY

In one aspect the invention is a weight-bearing system for hanging items from the roof structure of a metal building. The system includes a purlin with at least one flange, a span aperture in the vertical span of the purlin, a clip that attaches to the purlin using the span aperture, and a fastener on the clip for transferring weight applied to the fastener to the clip and to the vertical span of said purlin.

In another aspect the invention is a method for hanging items inside of metal buildings. The method includes the steps of positioning a plurality of purlin-supported fasteners against the roof side of the fabric ceiling of a metal building in a manner that urges the fasteners directly into contact with the fabrics. Thereafter, and starting from a position inside the building and below the fabric ceiling, locating at least one of the fasteners underneath the fabric ceiling that are contacting the fabric and hanging a weighted item from the at least one located fastener.

In another aspect the invention is a roof structure that includes a plurality of struts supported by vertical posts, a plurality of purlins supported by the struts, a fabric ceiling under the purlins, and a plurality of clips attached to the purlins in which each clip includes a fastener that bears against said fabric ceiling to flex the fabric ceiling at the point of the fastener.

In yet another aspect the invention is an improved system for weight-bearing fixtures in metal buildings. In this aspect the system includes a purlin and a clip attached to the purlin. The purlin includes a vertical span, at least one flange at an oblique angle to the span, and a span aperture defined by the purlin and positioned midway along the vertical span. The clip includes an outer frame formed of an outer base, an outer column extending vertically from the outer base, and an outer finger protruding from the outer column at an oblique angle to the outer column. The clip further include an inner frame inside of the outer frame and formed of an inner base, an inner column extending vertically from the inner base, and an inner finger protruding from the inner column at an oblique angle to the inner column. The inner frame and the outer frame are attached to one another in a manner that permits the inner frame and the outer frame to move with respect to one another a defined distance parallel to the axis of the respective columns, and with the fingers of the inner frame and the outer frame being positioned into and through the span aperture in the purlin.

In yet another aspect the invention is a clip for supporting weight from the roof of a metal building. The clip includes an outer frame formed of an outer base, an outer column extending vertically from the base, and an outer finger protruding from the outer column at an oblique angle to the outer column. The clip also includes an inner frame inside of the outer frame and formed of an inner base, an inner column extending vertically from the inner base, and an inner finger protruding from the column at an oblique angle to the inner column. The inner frame and the outer frame are attached to one another in a manner that permits the inner frame and the outer frame to move with respect to one another a defined distance parallel to the axis of the respective columns.

In yet another aspect the invention is a clip for supporting weight from the roof of a metal building, in which the clip includes a column, a clip flange on the column and oriented perpendicular to the column, a column base, a fastener depending from the bottom of the column base, and a base shelf extending from the base in a direction perpendicular to both the column and the clip flange.

The foregoing and other objects and advantages of the invention and the manner in which the same are accomplished will become clearer based on the following detailed description taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a partial perspective view of an exemplary framework for a metal building.

FIG. 2 is a perspective view of the clip and purlin of present invention in an environmental setting.

FIG. 3 is an enlarged cutaway view of the clip, a purlin, the fastener and the fastener bearing against the fabric ceiling.

FIGS. 4 and 5 are opposite perspective views of one embodiment of a clip according to the invention.

FIG. 6 is an exploded view of one embodiment of a clip according to the invention.

FIG. 7 is a perspective exploded view illustrating a segment of the purlin and a clip.

FIG. 8 is a side elevational view of the clip as inserted into the purlin

FIG. 9 is a perspective view of a portion of the clip that passes through the purlin.

FIG. 10 is a side elevational view similar to FIG. 7 but showing the clip in the open orientation in which it grips the purlin.

FIG. 11 is a view similar to FIG. 8, but showing the open the position of FIG. 10.

FIG. 12 is a perspective view of a second embodiment of the clip and purlin of present invention in an environmental setting.

FIGS. 13 and 14 are perspective views of a second embodiment of a clip according to the invention in the closed position.

FIGS. 15 and 16 are perspective views of the clip of FIGS. 13 and 14 but now in the opened position.

FIG. 17 is a partially exploded view of the second embodiment of the clip.

FIGS. 18 and 19 are respective perspective views of the second embodiment of the clip inserted into the web portion of the purlin.

FIG. 20 is a perspective view of a third embodiment of the invention.

FIGS. 21 and 22 are elevational views of the third embodiment.

FIG. 23 is a perspective view of the third embodiment attached to the span of a purlin.

DETAILED DESCRIPTION

FIG. 1 illustrates in general upper portions of a roof structure 20. The structure is formed from a plurality of vertical posts 21, a plurality of struts 22 supported by the vertical posts 21, and which in turn support a plurality of purlins 23. As set forth in the background, because of the multitude of uses and flexibility provided by metal buildings of this type, FIG. 1 also illustrates several appliances 24 supported by the purlins 23.

FIG. 2 is a cutaway view of a roof structure in a metal building that incorporates a plurality of clips 25 that are attached to respective purlins 23. Each clip includes a fastener 26 as part of the clip 25 and in which (e.g. FIG. 3) the fastener 26 depends from the clip 25 so that the fastener 26 bears against the fabric ceiling 27 to flex or tent the ceiling fabric at the position of the fastener 26. FIG. 2 also illustrates some insulation 30 which is almost always present in any metal building that is expected to be used for a public purpose (auditorium, school, gymnasium, etc.) both to add comfort to the users and make any use of heating, ventilation and air conditioning systems more efficient.

As is generally well understood in the art, the fabric ceiling 27 is typically held in place by longitudinal banding parallel to the purlins 23 combined with transverse banding perpendicular to the purlins. In general, the spacing and position of the longitudinal banding will depend on the spacing between purlins, and the transverse banding will be positioned to create generally equal segments and with at least some banding close to any roof edges.

As will be seen in several of the illustrations, the fasteners 26 are illustrated as a T-nut of the type that has interior female threads. Based on this, FIG. 2 illustrates a plurality of hanger bolts 31 that can engage the fasteners 26 and from which appliances 24 such as those illustrated in FIG. 1 can be suspended.

FIG. 3 illustrates aspects of the invention in greater detail. FIG. 3 illustrates a purlin 23 which includes at least one flange 32 positioned near the ceiling fabric 27, and a second flange 33 at the top of the purlin, with a span 34 between the flanges 32 and 33. A span aperture 35 (illustrated in larger scale in FIG. 7), is in the vertical span 34 of the purlin. A flange aperture 36 (FIG. 7) is in the flange 32 at the ceiling. The clip 25 attaches to the purlin 23 using both of the apertures 35 and 36. The fastener 26 depends from the clip 25 and serves to transfer weight applied to the fastener 26 to the clip 25 and in turn to the (strong) vertical span of the purlin.

As FIG. 3 makes evident, and one of the disadvantages of the prior art, if the weight of a hanging object were supported only by the flange 32, the weight-bearing capacity would be greatly reduced as compared to the combination of the clip attached to the vertical span 34 of the purlin 23.

FIG. 3 also illustrates that the fastener 26 depends through the flange aperture 36 in the purlin. In the illustrated embodiment the fastener is a T-nut 26 and (as just referenced with respect to FIG. 2), threaded bolts 31 can be inserted into the T-nut 26 and an appliance 24 can be suspended from the threaded bolt 31.

As will be further described with respect to (e.g.) FIGS. 12-19 the purlin 23 can include a second span aperture 37 in the span of the purlin 23 and with the clip 25 attached to both of the span apertures 35 and 37 as well as to the flange aperture 36.

As best illustrated in FIGS. 4-11, the clip 25 includes a plurality of fingers (to be described further herein) for engaging each of the span apertures 35 and 37.

FIG. 3 also illustrates an important aspect and advantage of using the invention. The plurality of purlin 23-supported fasteners 26 can be positioned against the roof side of the fabric ceiling 27 of the roof structure 20 in a manner that urges the fasteners 26 directly into contact with the fabric 27. FIG. 3 shows this as the tent or flex in the fabric 27 at the T-nut 26. With the fabric 27 bearing directly against the fasteners 26, and starting from a position inside the metal building and below the fabric ceiling 27, the fasteners can be easily located underneath the fabric ceiling at the positions where they contact the fabric 27, so that a weighted item can be suspended from the located fasteners 26 without the need to explore or open the fabric to find items that are otherwise hidden from view.

FIGS. 4 through 11 illustrate a first embodiment of the clip 25 in more detail. The clip 25 is illustrated in the form of an outer frame 40 and an inner frame 41 with the inner frame 41 inside of the outer frame 14. The outer frame includes an outer base 42 which in the illustrated embodiment is not a separate part, but generally the partially five-sided structure shown in the drawings. An outer column 43 extends vertically (the orientation refers to the position in use) from the outer base and terminates at an outer finger 44 that protrudes or extends from the top of the outer column 43 at an oblique angle (90° as illustrated) to the outer column.

In the illustrated embodiment the outer frame 40 has two parallel columns 43 and two of the outer fingers 44. A pair of rivets 45 (at least one extends through the outer column 43.

The inner frame 41 is inside of the outer frame 40 and is formed of and inner frame base 46 which again represents a portion of the inner frame 41 rather than a separate element and is illustrated in a generally triangular shape. An inner column 47 (two are illustrated) extends vertically from the inner frame base 46 and likewise terminates in an inner finger 50 (two are shown) at an oblique angle (also illustrated as) 90° from the inner column. The inner frame 41 and the outer frame 40 are attached to one another in a manner that permits the inner frame 41 and outer frame 40 to move with respect to one another a defined distance parallel to the axis of the respective outer 43 and inner 47 columns. As best illustrated in FIGS. 8-11 the fingers 44 and 50 of the inner and outer frames 41, 40 are positioned into and through the span aperture 35 in the span 34 of the purlin 23.

FIG. 6 is an exploded view of the clip 25 that helps illustrate the structure and function of the clip 25. In particular, FIG. 6 illustrates a rivet slot 51 in the inner column 47 that together with the rivets 45 permits the movement of the inner frame 41 and the outer frame 40 with respect to one another.

FIG. 6 also illustrates the fastener 26, again in the form of a T-nut which is positioned in a fastener opening 52 in the outer base 42.

FIG. 7 is an exploded view of the clip 25 and the purlin 23. The purlin includes the flanges 32 and 33, the span 34, and the span aperture 35. FIG. 7 illustrates that when the fingers 44 and 50 are positioned into and through the span aperture 35, the fastener 26 that depends from the outer base 42 projects through the flange aperture 36.

FIGS. 8 and 9 illustrate aspects of the relationship between the clip 25 and the purlin 23 when the fingers 44 and 50 have been inserted through the span aperture 35. FIGS. 8 and 9 illustrate a position referred to as “closed” meaning that the inner and outer frames are in a position that minimizes the axial length of the clip 25 and allows the fingers 44 and 50 be inserted through the span aperture 35.

FIG. 9 is an enlarged view of the fingers 44 and 50 extending through the span aperture 35 and further illustrates that the fingers can include a flexed portion that provides a spring force in which the inner fingers 50 push against the outer fingers 44.

FIGS. 10 and 11 are very similar to FIGS. 8 and 9, but show the clip 25 in an open position with respect to the purlin 23 and particularly with respect to the span aperture 35. To change from the orientation of FIGS. 8 and 9 to that of FIGS. 10 and 11, the user, after having inserted the fingers 44, 50 can use the base portions 42 and 46 to physically slide the inner frame upwardly (again in the orientation of use) to engage opposite portions of the circumference of the span aperture 35. In the illustrated embodiment inner finger notches 53 and outer finger notches 54 engage the span aperture 35 to help fix the clip 25 in position with respect to the purlin 23. In this position the fastener 26 extends through the flange aperture 36 to form a position over which the fabric ceiling 27 can flex for the purpose described (locating the fastener 26) with respect to FIG. 3.

FIG. 12 is a cutaway perspective view analogous to FIG. 2, but showing the use of a second embodiment of the clip broadly designated at 55. As FIG. 12 illustrates, the second embodiment clip 55 can be used independently of the presence of a flange aperture 36, although it will be understood that if a flange aperture is present, the second embodiment of the clip can be used with or without the flange aperture 36. Thus, in FIG. 12 the fastener 26 simply depends toward the ceiling fabric 27 without passing through any flange aperture 36. This gives a flexible option for reducing the number of flange openings, either partially or completely, in the purlin 23.

FIGS. 13 and 14 are analogous to FIGS. 4 and 5 in showing the second embodiment of the clip in a “closed” position. The second embodiment is formed of a single inner column 57 in an outer frame 40 substantially the same as the outer frame in the first embodiment, and with at least one (and two are shown) clip flanges 60 extending perpendicularly from the column 43 of the outer frame 40. Each clip flange 60 has a clip flange hole 61 which can be used as one method of fastening the clip flanges 60 to the span 34 of a purlin 23. A second outer finger 48 is position near the outer base 42 and defines a spacing between the outer fingers 44 and 48 that substantially matches the spacing of the two span apertures 35, 37 (FIG. 18). A second inner finger 49 is likewise positioned near the inner frame base 46 or any equivalent position on the single inner column 57. The spacing of the inner fingers likewise matches the position of the span apertures 35, 37.

FIGS. 15 and 16 show the second embodiment of the clip 55 in the opened position including the inner finger notches 53 and the outer finger notches 54, each of which action the same manner as described with respect to the first embodiment. FIGS. 15 and 16 also illustrates the flexed portions 62 on the inner finger which can provide a spring force in the same manner as in the first embodiment 25 of the clip. FIGS. 15 and 16 also help illustrate the respective second outer finger notches 56 and the second inner finger notches 58.

FIG. 17 is analogous to FIG. 6 and shows the second embodiment of the clip 55 in exploded fashion. In addition to illustrating the single inner column 57, FIG. 17 also shows an extended rivet slot 63 in the single inner column with the extended rivet slot 63 cooperating with the rivets 45 in the same manner as in the first embodiment to allow the movement of the single inner column 57 and the outer frame 40 with respect to one another. FIG. 17 also helps illustrate that the single inner column 57 includes a column tab 64 that gives a user a place of purchase to move the single inner column 57 with respect to the outer frame 40.

FIGS. 18 and 19 are respective perspective or isometric views of the second embodiment of the clip 55 connected to a purlin 23 and in particular illustrating the use of the clip 55 with respect to the purlin 23 in a manner independent of any flange aperture (e.g. 36 in FIG. 7). Used in this manner, the clip 55 can still be attached to the purlin 23 using the span apertures 35 and 37. Independently of that connection, however, or alternatively combined with the span aperture connection, the second embodiment of the clip 55 can be fastened to the purlin 23 using one or both of the clip flanges 60, the clip flange holes 61 and an appropriate fastener illustrated as the metal screw 66.

Going further, however, the skilled person will understand that if desired or necessary, fastening the clip 55 using the clip flanges 60 offers the capability to attach to a purlin 23 that has no openings whatsoever other than any opening that would be created using (for example) the metal screw 66. In such use, the fingers (e.g., 44, 50) of the clip can be physically removed to allow the remainder of the clip 55 to fit flush or nearly flush against the purlin 23.

The clips 25 and 55 illustrated herein thus can provide significant flexibility in the construction and use of metal buildings. First, because the clips 25, 55 are independent of the purlin, they avoid adding additional manufacturing costs to the purlin itself. Second, because the clips 25, 55 are provided initially independently of the purlins 23, the clips 25, 55 can be located anywhere along the purlin as may be desired or necessary in the circumstances. Clips 25, 55 can be added by the user by having the user form (e.g., drill, cut) the necessary openings in the purlin 23, or purlins can be manufactured with the desired openings at regular or custom spacing. Such choices are economic in nature, rather than any limitation on the invention.

The combination of the clip 25, 55 combined with a perforated purlin 23 places all hanging weight on the web (the strongest part of the purlin) and none on the flanges 32, 33. Additionally, because the fastener 26 rests gently against the vapor barrier ceiling 27, the fastener 26 can be located easily by feel.

As another advantage, the fastener 26 on the clip 25, 55 provides the capacity to fix extra insulation in climates or for purposes where a high R-value is required, and where a metal building might otherwise be unacceptable. Exemplary foam board insulation can have a capacity of about R-4 or R-5 per inch (thickness) and glass wool is about R-3 or R-4 per inch. As a result, if (again, for example) R-60 is desired or necessary, 12-15 inches of foam board or 20 inches of glass wool could be required. Using the invention, such thicknesses can be easily suspended in the metal building context by selecting a hanger bolt 31 of a desired length. Additionally, a hanger bolt can terminate in its own fastener so that an appliance can still be supported, all using the strength of the purlin's 23 vertical span 34.

The clip is formed of two sliding parts so that when the sliding parts are completely nested, the clip can be easily added to a perforation in a purlin. The sliding parts can then be adjusted so that the notches 53, 54 engage the opposite sides (noon and 6 o'clock) of the perforation in the purlin. This locks the clip in place and positions the fastener both through the opening in the flange and extending slightly below the flange to touch the fabric barrier for ease of location later.

The clips are used rather than some permanent structure because minimizing weight is important and the use of clips makes the choice of the number of necessary clips in any installation completely optional for maximum design freedom. Because the (typically steel) purlins are manufactured, sold and transported all on the basis of weight, using the clips as an optional separate item adds value to the overall system.

FIGS. 20, 21, 22, and 23 illustrate a third embodiment of the invention. Where possible, the same reference numerals are used to identify items common to the first two embodiments and the expected environment.

FIG. 20 is a perspective view of the clip 70, again for supporting weight from the roof of a metal building. The clip 70 includes the column 71 illustrated as a pair of flat panels fastened together by one or more rivets or clinches 45. The column 70 can also be a single piece, but the illustrated embodiment reflects to some extent one of the techniques by which such a clip can be formed. The clip 70 has a clip flange 60 (two are illustrated) on the column 70 and oriented perpendicularly to the column 71. The column 71 is fixed to a column base 72 generally analogous to the other embodiments. A fastener 26, with the purposes described previously, depends from the bottom of the column base 72.

In this embodiment, a base shelf 73 extends from the base 72 in a direction that is perpendicular to both the column 71 and the clip flanges 60.

Stated differently, if the embodiment illustrated in FIG. 20 were oriented on Cartesian (or “coordinate”) axes, and if the column 71 is considered to be along the x-axis (vertical in FIG. 20) and in the x-y plane, then the clip flanges 60 are in a plane parallel to any x-z plane and the base shelf 73 is in a plane parallel to any y-z plane.

The clip 70 can be formed of metal which in most cases supplies the necessary loadbearing strength to hang heavier objects from the ceiling. That said, the clip can be formed of other materials (e.g., engineering polymers; fabric reinforced materials, ceramics) depending upon the expected weight that the clip 70 will likely bear in particular circumstances.

FIG. 21 is a side elevational view of the clip 70 and illustrating the perpendicular relationship between the column 71 and the clip flanges 60.

FIG. 22 is another elevational view taken perpendicularly to FIG. 21 and showing the perpendicular relationship between the column 71 the base shelf 73. FIGS. 20 and 22 also illustrate the clip flange holes 61.

FIG. 23 is a perspective view of the clip 70 fastened to a purlin span 34 using a pair (only one is shown) of metal screws 66 to fasten the clip flange 60 to the purlin span 34. In this orientation, the purlin can be similar or identical to those illustrated in (for example) FIGS. 1 and 3. In FIG. 23, the clip flange 60 is fastened to the purlin span 34, and the base shelf 73 extends along and rests against the bottom flange 32 of the purlin to position the clip 70 against the purlin in a desired vertical position and to help prevent torsional forces from moving the clip 70 out of position. As FIGS. 20, 22 and 23 illustrate, in this embodiment the base 72 has five sides that outline a geometric solid (empty) with one face coplanar with the face of the clip flange 60 fixed against the purlin span 34.

Although not specifically illustrated in this embodiment, a fabric ceiling material 27 can be positioned under a plurality of purlins that they are against the fastener 26 so that the fabric flexes as it bears against the fastener or alternatively the fastener can be quickly located underneath the fabric even if the fabric isn't flexed.

As with the other embodiments, the hanger 31 can engage with the fastener 26 on the clip 70 and depend through and below any fabric ceiling material to support a weighted object on the hanger as may be desired or necessary.

Thus, a plurality of the illustrated embodiment of the clips 70 can be used in a manner similar to the other embodiments in a building that includes a plurality of vertical posts 21 and struts 22 in conjunction with the fabric ceiling 27 to permit items to be supported from the clips 70 and the purlins 23.

It will be understood that such a plurality of the clips 70, as with the other clip embodiments 25 and 55 can be installed in a customized pattern when the location of heavy objects is known. Alternatively, any of the clips 25, 55, and 70, can be placed in some other pattern from which they can be used on an as-selected basis.

As shown in FIG. 23 the third clip embodiment 70 can be placed on the opposite side of the purlin span 34 from the side on which the first clip embodiment is typically placed (e.g., FIG. 2).

In cases in which the column 71 is formed from two pieces (or a folded piece), these pieces can be held together with a rivet 45 (two are illustrated) or a clinch lock (i.e., drawing or forming the part materials into an interlock).

In the drawings and specification there has been set forth a preferred embodiment of the invention, and although specific terms have been employed, they are used in a generic and descriptive sense only and not for purposes of limitation, the scope of the invention being defined in the claims.

Claims

1. A clip for supporting weight from the roof of a metal building, said clip comprising: a column oriented on a x-y plane extending along an x-axis from a y-z plane;a clip flange oriented on the y-z plane extending perpendicularly from said column along a z-axis;a column base depending from and extending below the column forming a bottom face parallel to an x-z plane;a fastener depending from the bottom face of said column base; anda base shelf oriented on the x-z plane extending from said column base along the x-axis, wherein the base shelf extends from a terminal edge of the bottom face.

2. A clip for supporting weight according to claim 1 comprising two clip flanges.

3. A clip for supporting weight according to claim 1 formed of metal.

4. A clip according to claim 1 fastened to a purlin.

5. A clip fastened to a purlin according to claim 4 wherein; said purlin includes a span and two purlin flanges, with said purlin flanges extending perpendicularly in opposite directions from the top and bottom of said purlin span.

6. A clip fastened to a purlin according to claim 5 wherein said clip flange is fastened to said span of said purlin; andsaid base shelf extends along and rests against said bottom purlin flange to position said clip against said purlin in a desired vertical position and to help prevent torsional forces from moving said purlin out of position.

7. The combination of a clip fastened to a purlin according to claim 6; and a fabric ceiling material under said purlins that bears against said fastener and flexes as it bears against said fastener.

8. The combination of claim 7 and further comprising a hanger engaged with said fastener and depending through and below said fabric ceiling material.

9. The combination of claim 8 and further comprising a weighted object supported on said hanger.

10. A clip for supporting weight from the roof of a metal building, and in which the clip structure can be oriented on Cartesian axes said clip comprising: a column in the x-y plane;clip flanges attached to said column and in a plane parallel to any x-z plane; anda base shelf in a plane parallel to any y-z plane.

11. A clip according to claim 10 fastened to a purlin according to claim 4 wherein; said purlin includes a span and two purlin flanges, with said purlin flanges extending perpendicularly in opposite directions from the top and bottom of said purlin span;said clip flanges are fastened to said span of said purlin; andsaid base shelf extends along and rests against said bottom purlin flange to position said clip against said purlin in a desired vertical position and to help prevent torsional forces from moving said purlin out of position.

12. The combination of a clip fastened to a purlin according to claim 11; and a fabric ceiling material under said purlins that bears against said Fastener and flexes as it bears against said fastener;and further comprising a hanger engaged with said fastener and depending through and below said fabric ceiling material.

13. The combination of claim 12 and further comprising a weighted object supported on said hanger.

14. A roof structure comprising a plurality of struts supported by vertical posts and a plurality of purlins supported by the struts;a fabric ceiling under the purlins; anda plurality of clips attached to the purlins in which each said clip includes a column, a clip flange extending perpendicularly from said column, a column base depending from and extending below the column forming a bottom face that is perpendicular to both the column and the clip flange, a fastener depending from the bottom face of said column base, a base shelf extending from a terminal edge of said bottom face; anda fastener depending from said bottom face of said column base and that bears against said fabric ceiling to flex said fabric ceiling at the position of said fastener.