Conventional laundry drying racks are used to dry laundered items. Laundry drying racks have particular application when the laundered items are too delicate to be placed in an electric dryer or may shrink therein. Laundry drying racks may also be used for temporary storage such as during folding or ironing tasks.

In order to minimize the costs of such laundry drying racks to end consumers, it is desirable that the laundry drying racks be shipped and packaged in a disassembled state. Such disassembly allows for the components of such laundry drying rack to be compactly packaged thereby lowering shipping costs. Further avoidance of assembly by the manufacturer avoids the associated assembly costs, the saving of which may be passed along to the consumer.

Conventional laundry drying racks, however, frequently comprise numerous components which makes assembly difficult and time consuming. Further, use of fasteners for the assembly may further require tools for the attachment thereof.

Accordingly, there is a need in the art for an improved laundry drying rack which is structurally stable, easy to assemble, and has components which are relatively low in cost to manufacture, in comparison to the prior art.

SUMMARY OF THE INVENTION In accordance with an embodiment of the present invention, there is provided a laundry drying rack. The laundry drying rack has an elongate leg member having an opening formed laterally therein. The laundry drying rack is further provided with a connecting rod having a connecting rod distal end thereof. The laundry drying rack is further provided with an end connector having a

resilient pronged end and a post end. The post end is sized and configured to extend within the opening of the elongate leg member for rotatably connecting the elongate leg member to the end connector. The laundry drying rack is further provided with a tubular coupling having a coupling distal end, an opposing coupling proximal end, and an internal ridge formed circumferentially therein. The coupling proximal end is sized and configured to axially receive the connecting rod distal end therein. The coupling distal end is sized and configured to axially receive the resilient pronged end of the end connector therein. The internal ridge is sized and configured to concentrically engage the resilient pronged end of the end connector for rotatable engagement of the tubular coupling thereabout.

In the preferred embodiment of the present invention, the post end of the end connector has a post. The post is sized and configured to extend within the opening of the elongate leg member for radially connecting the elongate leg member to the end connector. The post may be sized and configured for press-fit engagement with the opening of the elongate leg member. Further, the end connector may have a radially extending flange disposed between the resilient pronged end and the post end. The flange is sized and configured to abut the elongate leg member adjacent the opening when the post end is extended therewithin. The flange is further sized and configured to abut the coupling distal end when the resilient pronged end is axially received therewithin.

The resilient pronged end of the end connector preferably has a pair of resilient prongs, the resilient prongs are sized and configured to expand radially outward to engage the tubular coupling adjacent the internal ridge when axially received within the coupling distal end. The resilient prongs comprise opposing sides of a cylindrical member having a lengthwise slot defining the resilient prongs in spaced relation thereto. The resilient prongs are sized and configured to contract radially inward within

the lengthwise slot during axial insertion into the coupling distal end. The resilient prongs each terminate with a prong head thereof. The prong heads each have an engagement surface for engaging the tubular coupling adjacent the internal ridge when the pronged end is axially received within the coupling distal end. The coupling distal end of the tubular coupling has a distal end inner surface tapering towards and terminating at the internal ridge. The resilient prongs are sized and configured to contract radially inward in slidable engagement with the distal end inner surface during axial insertion into the coupling distal end.

In addition, the coupling distal end of the tubular coupling may have a distal end inner surface tapering towards and terminating at the internal ridge. The resilient pronged end of the end connector is sized and configured to contract radially inward in slidable engagement with the distal end inner surface during insertion thereof into the coupling distal end. The end connector may have a plug which is sized and configured to extend within the coupling distal end when the pronged end is axially received within the coupling distal end. The plug is sized and configured to engage the coupling distal end in press-fit engagement therewith. The coupling proximal end may be sized and configured to engage the connecting rod distal end in press-fit engagement therewith. The coupling proximal end has a proximal end inner surface tapering towards the coupling distal end for axially receiving the connecting rod distal end in press- fit engagement.

The laundry drying rack may further include a second elongate leg member having an opening formed laterally therein. The post end of the end connector is sized and configured to extend within the openings of the leg members for rotatably connecting the leg members to each other.

The elongate leg members cooperatively forming a collapsible leg of the laundry drying rack. The opening of each elongate leg member may be disposed adjacent a

respective distal end thereof. The opening of each elongate leg member may alternately be disposed adjacent a center segment thereof.

In another embodiment of the present invention, there is provided a laundry drying rack having an elongate leg member having an opening formed laterally therein. The laundry drying rack is further provided with a connecting rod having a connecting rod distal end thereof. The laundry drying rack is further provided with a cylindrical connector having an open end, an opposing flanged end, and a post section disposed therebetween. The open end has a recess formed therein extending axially toward the flanged end. The recess is sized and configured to axially receive the connecting rod distal end therein for engagement of the cylindrical connector to the connecting rod. The flanged end has a flange extending radially therefrom. The post section is sized and configured to extend through the opening of the elongate leg member with the flange abutting the elongate leg member adjacent the opening. The post section has an external groove circumferentially formed therein. The laundry drying rack further has an elastic retaining ring sized and configured to receive the open end of the cylindrical connector therethrough. The elastic retaining ring is further sized and configured to concentrically engage the external groove, for capturing the elongate leg member between the flange and the elastic retaining ring about the post section.

Preferably, the cylindrical connector is sized and configured to engage the connecting rod distal end in press-fit engagement therewith. The recess is tapered toward the flanged end for axially receiving the connecting rod distal end in press-fit engagement. Further, the cylindrical connector has an outer surface tapering from the external groove towards the open end for receiving the retaining ring thereover. The elastic retaining ring may be sized and configured to radially expand in slidable engagement over the outer surface of the cylindrical connector towards the external groove. The elastic

retaining ring has ring inner surface tapering towards the open end of the cylindrical connector when the elastic retaining ring is engaged with the external groove.

The laundry drying rack may further include a second elongate leg member having an opening formed laterally therein. The post section is sized and configured to extend within the openings of the leg members for rotatably connecting the leg members to each other. The elongate leg members cooperatively form a collapsible leg of the laundry drying rack. The opening of each elongate leg member is disposed adjacent a respective distal end thereof. The opening of each elongate leg member may alternately be disposed adjacent a center segment thereof.

As such, based on the foregoing, the present invention is believed to mitigate the inefficiencies and limitations associated with prior art laundry drying racks.

Accordingly, the present invention represents a significant advance in the art. This advancement will be better appreciated in view of the following discussion and drawings in which like numbers refer to like parts through.

Figure 1 is a perspective view of a laundry drying rack of the present invention; Figure 2 is a side view of the laundry drying rack of Figure 1 ; Figure 3 is a side view of a disengaged end connector set of an aspect of the present invention; Figure 4 is a cross-sectional side view of an end connector set as shown engaged with a connecting rod (partially depicted) and leg members (partially depicted) of the laundry drying rack of Figure 1 as seen along axis 4-4; Figure 5 is a perspective exploded view of the end connector set, connecting rod and leg members of Figure 1; Figure 6 is a side view of a disengaged cylindrical connector set of an aspect of the present invention; Figure 7 is a cross-sectional side view of a cylindrical connector as shown engaged with a connecting rod (partially depicted) and leg members (partially

depicted) of the laundry drying rack of Figure 1 as seen along axis 7-7 ; and Figure 8, is a perspective exploded view of the cylindrical connector set, connecting rod and leg members of Figure 7.

DETAILED DESCRIPTION An improved drying rack is shown in Figures 1-8.

Referring now to Figure 1, a collapsible laundry drying rack 210 is shown. The laundry drying rack may be provided with two opposing collapsible legs 212, 214 which are joined by a plurality of connecting rods 216. Laundry is hung on the connecting rods 216 to dry the laundry during use of the laundry drying rack 210.

Referring now additionally to Figure 2, the collapsible legs 212,214 may be formed by a series of scissor linkages 218. The scissor linkages 218 allow the legs 212,214 to collapse for ease of shipment and storage, and to expand for subsequent usage of the laundry drying rack 210.

Each of the scissor linkages 218 include a pair of crossed elongate leg members 220. The elongate leg members 220 preferably include central openings 222 and distal openings 224 laterally disposed therethrough. As discussed in detail below, selective usage of end connector sets 226 (Figures 3-5) and cylindrical connector sets 228 (Figures 6-8) in conjunction with the openings 222,224 are used to rotatably connect the leg members 220 to each other as well as to the connecting rods 216. In this regard, the end connector sets 226 and cylindrically connector sets 228 allow joining of a pair of the elongate leg members 220 at their respective central openings 222 to form a given scissor linkage 218. Further, the end connector sets 226 and cylindrically connector sets 228 further allow interconnection of adjacent scissor linkages 218 by joining the distal openings of the leg members 220 of such adjacent scissor linkages 218. As is depicted, three such scissor linkages 218 are used to form each leg 212,214, but the number can vary. Usually, two to four such scissor

linkages 218 are joined, depending upon the desired size of the laundry drying rack 210.

At the top of the laundry drying rack 210, on each leg 212,214 is a cross bar 230 which connects the ends of the leg members 220 of the top-most scissor linkage 218. The cross bars 230 also stabilize the legs 212,214 and lock them into position because the fixed connection of the central and distal openings 222,224 form a triangular arrangement of fixed dimension. Each cross bar 230 may further include a distal opening 232 laterally formed in a distal end thereof and a notch 234 formed in an opposing distal end thereof. The notch 234 (Figure 2) is used to releasably engage the cross bar 230 from the distal end of the adjacent leg member 220. As such, the cross bar 230 may be disengaged and rotated to allow the legs 212,214 to be collapsed, as depicted in Figure 2. Other ways to releasably connect a stabilizing bar 230 can be used.

Further, additional, or fewer, openings, 236 may be formed in the cross bar 230 between the distal opening 232 and the notch 234 for attachment of the connecting rods 216 across the top of the laundry drying rack 210.

On one of the scissor linkages 218, typically on the bottom-most scissor linkage 218, a locking bar 238 is provided. The locking bar 238 connects to opposing leg members 220 of the scissor linkages 218 in order to hold them in a fixed relative position and thereby further stabilized the laundry drying rack 210 in the expanded position. The locking bar 238 is preferably provided on each of the legs 212,214 as shown, but could be on only one of the legs 212,214. The locking bar 238 can comprise an elongated member that has ends configured to engaged the abutting leg members 220. The engagement can be by through the use of pins 239, as shown, in order to fix the locking bar 238 to the adjacent leg members 220. Other engagement arrangements may be used, such as a mating projection and slot arrangement, in which one of the leg members 220 or the locking bar 238 has a slot and the other has a protrusion that engages the slot to restrict relative

motion of the engaged parts. Alternatively, one end of the locking bar 38 can be rotatably connected to one of the leg members 20 and the other end of the locking bar 238 can releasably engage the other leg member 220.

The connecting rods 216 preferably comprise wooden dowels 240 coated with a thin plastic coating 242. A polyvinylchloride (PVC), polyethylene or polypropylene or other plastic coating could be used. The plastic coating 242 is preferably thin relative to the diameter of the dowel 240. A thickness of a few thousandths of an inch is believed suitable. The wooden dowels 240 could be dipped in plastic to form the plastic coating 242. The plastic coating 242 provides a relatively smooth, snag-free exterior, while the wooden dowel 240 provides strength for the connecting rod 216. The coating is provides the connecting rods 216 with water-proof and insulative qualities so as to mitigate the adverse effects of moisture from laundry placed on the connecting rods 216.

Latex or oil based paints could be used, but are preferably not used for the plastic coating 242 as they lack sufficient water-proof or durability characteristics.

As mentioned above, various components of the connector sets 226,228 (Figures 3-5) are selectively used to connect the leg members 220 to each other as well as to the connecting rods 216. The end connectors 226 and cylindrical connectors 228 and associated components are advantageously integrally molded of polyvinylchloride (PVC), polyethylene, polypropylene, nylon, Teflon@ or other plastic materials so that each component forms a single piece upon completion of molding of that piece.

Preferably, end connector sets 226 are disposed through the distal openings 224 of the leg members 220 of the top-most scissor linkages 218 and the associated adjacent cross bar 230. Further, the end connector sets 26 are preferably used to attach the two cross bars 230 to each other with interposed connecting rods 216. The end connector sets 226 also preferably interconnect the leg members 220 about their respective central openings 222 to

form the bottom-most scissor linkage 218. As discussed further below, the cylindrical connector sets 226 are used to rotatably connect leg members 220 at the various other unconnected central and distal openings 222,224.

As discussed below, the end connector sets 226 have a relatively high resistance to being axially disengaged in comparison the to the cylindrical connector sets 228 Figures 6-8). In this regard, usage of the end connector sets 226 at all of the central and distal openings 222,224 of the leg members 220 is desirable and is contemplated to result in a comparably stable structure of the laundry drying rack 210. However, it is further contemplated that the end connector sets 226 are more structurally complex, and therefore more expensive to manufacture in comparison to the cylindrical connector sets 228. As such, the selective usage of the end connector sets 226, as described above, is a preferred balance between component utility and cost. While not a desirable, it is believed possible to use only end connector sets 226, or only end connector sets 228, for the entire laundry stand.

Referring now to Figures 3-5, an end connector set 226 is depicted. In particular, Figure 3 depicts a side view of a disengaged end connector set 226 of an aspect of the present invention. Figure 4 is a cross-sectional side view of the end connector set 226 as shown engaged with a connecting rod 216 (partially depicted) and leg members 220 (partially depicted) of the laundry drying rack 210 of Figure 1 as seen along axis 4-4. Figure 28 is a perspective exploded view of the end connector set 226, connecting rod 216 and leg members 220 of Figure 4 as they extend along longitudinal axis 245.

Each end connector set 226 includes an end connector 244 and a tubular coupling 246. The end connector 244 has an end 248 with resilient prongs and a post end 250. The post end 250 may be sized and configured to extend within the central opening 222 (as well as distal opening 224 and the openings 232,236 of the cross-bar 230, though not

shown) of the elongate leg member 220 for connecting the elongate leg member 220 to the end connector 244.

The post end 250 is preferably nailed, staked, glued or otherwise fastened to one of the members 220, but not fastened to both in order to allow joined members 220 to rotate about the common post 250. The tubular coupling 246 has a coupling distal end 252, an opposing coupling proximal end 254, and an engaging surface 256 that advantageously takes the form of an internal ridge, or recess. The engaging surface 256 is illustrated as an interval ridge 256 and will be referred to as such in the remaining description. The ridge preferably extends around the entire interior circumference of the coupling 246. The coupling proximal end 254 is sized and configured to axially receive a connecting rod distal end 258 of the connecting rod 216 therein. The coupling distal end 252 is sized and configured to axially receive the pronged end 248 of the end connector 244 therein. The engaging surface 256 is sized and configured to engage the pronged end 248 of the end connector 244 and preferably, but optionally to allow rotatable engagement of the tubular coupling 246.

In the preferred embodiment of the present invention, the post end 250 has a post 260. The post 260 is sized and configured to extend within the openings 222 of the elongate leg members 220 for connecting the elongate leg members 220 to the end connector 226. The post 260 may be sized and configured for press-fit engagement with the openings 222 of the elongate leg member 220. The end connector 244 may have a radially extending flange 262 disposed between the pronged end 248 and the post end 250.

The flange 262 is sized and configured to abut the adjacent-most leg member 220 adjacent the opening 222 thereof when the post end 250 is extended therewithin, as shown in Figure 4. The flange 262 is preferably, but optionally further sized and configured to abut the coupling distal end 252 of the tubular coupling 246 when the pronged end 248 is axially received therewithin, as further shown in Figure 4.

The pronged end 248 preferably includes a pair of resilient prongs 264. The resilient prongs 264 may comprise opposing sides of a cylindrical member having a lengthwise slot 268 defining the resilient prongs 264 in spaced relation thereto. The resilient prongs 264 each terminate with a prong head 266 thereof. The prong heads 266 each have an engagement surface 270 for engaging the tubular coupling 246 adjacent the engaging surface 256 formed of internal ridge, or recess 256 when the pronged end 248, and more particularly the resilient prongs 264, are axially received within the coupling distal end 252.

The coupling distal end 252 of the tubular coupling 246 has a distal end inner surface 276 that preferably, but optionally tapers towards and terminates adjacent to the internal ridge 256. The surface 276 could be cylindrical, forming a ledge 256 to engage prongs 264, or forming a recess to engage prongs 256. In this regard, during insertion of the prongs 264 into the coupling distal end 252, the prongs 264 are sized and configured to expand radially outward as the prongs slid along the distal end inner surface 276 towards the internal ridge 256. Thus, the resiliency of the prongs 264 allow them to resiliently engage the tubular coupling 246 adjacent the internal ridge 256 when axially received within the coupling distal end 252.

The resilient prongs 264 are further sized and configured to contract radially inward in slidable engagement with the distal end inner surface 276 during axial insertion into the coupling distal end 252. The coupling distal end 252 of the tubular coupling 246 has a distal end inner surface 276 tapering towards and terminating at the internal ridge 256. The pronged end 248 of the end connector 244 is sized and configured to contract radially inward in slidable engagement with the distal end inner surface 276 during insertion thereof into the coupling distal end 252. As such, once the prongs 264 have cleared the internal ridge 256 the resiliency of the prongs 264 allow the prongs 264 to contract radially inward

within the lengthwise slot 268 during axial insertion into the coupling distal end 252 beyond the internal ridge 256.

Such contraction allows the engagement surfaces 270 of the prong heads 266 to securely engage the tubular coupling 246 adjacent the internal ridge 256 thereby locking the end connector 244 to the tubular coupling 246.

The end connector 244 also preferably, but optionally, has a plug 272. The plug 272 is sized and configured to extend within the coupling distal end 252 when the pronged end 248 is axially received within the coupling distal end 252. In this regard, the resilient prongs 264 extend from the plug 272. The plug 272 is preferably sized and configured to engage the coupling distal end 252 in press- fit engagement therewith.

The coupling proximal end 254 is sized and configured to receive the connecting rod distal end 258. The coupling proximal end 252 preferably, but optionally, has a proximal end inner surface 274 tapering inward towards the coupling distal end 252, for axially receiving the connecting rod distal end 258 in press-fit engagement.

If the distal end of the rod 216 were too close to the engaging surface 256, then the rod 216 could prevent engagement of the prongs 264 with the engaging surface 256.

Advantageously, an impediment to passage of the rod 216 is provided in order to limit the insertion of the rod into the coupling 246. An internal ledge 275 (Fig. 26) extending around the inner circumference of the coupling, can be easily formed in the coupling 246 as it is molded in order to limit the insertion depth of the rod 216. In order to further, positively secure attachment of the connecting rod distal end 258 to the tubular coupling 246, a nail, staple, adhesive or other mechanism may further be used. A staple is shown in Figure 4.

The end connector 244 and coupling 246 allow the use of solid rods 216, and allow easy connection to the legs forming the laundry drying rack. It is believed advantageous to fasten the distal end of post 260 to the leg member 220 through which that distal end is inserted.

That prevents the post 260 from being pulled out of the member 220 along the longitudinal axis 245. As shown in Fig. 5, this can be achieved by a nail or staple being driven through the leg member 220 into the post 260, or it could be a screw or glue or other fastening mechanism.

The tapered end of the prongs 264, and/or the tapered walls 276 of the coupling 246 forming the recess into which the prongs 264 are inserted, make it easy to connect the rods 216 to the leg members 220. The connector 244 can be fastened to the leg members 220 at the factory, and the coupling 246 can be fastened to the rods 216 at the factory. Both are preferably fastened using nails, brads, staples or such in order to provide for a fast but inexpensive and sturdy connection. The coupling 246 and connector 244 still allow a compact assembly of parts for shipment. The couplings 246 only add a couple of inches to the length of the rods 216. While the connectors 244 extend perpendicular to the collapsed legs formed by scissor linkages 218, the connectors are short and do not take up much room.

Upon receipt, the prongs 64 need only be inserted into couplings 246 in order to fasten the rods 216 to the legs of the laundry rack and thereby prevent separation of the laundry rack along longitudinal axis 245 that runs along the length of each rod 216. The parts snap together, with the tapered surfaces making the insertion and assembly easy to achieve.

Referring now to Figures 6-8, a cylindrical connector set 228 is depicted. In particular, Figure 6 depicts a side view of a disengaged cylindrical connector set 228 of an aspect of the present invention. Figure 7 is a cross- sectional side view of a cylindrical connector set 228 as shown engaged with a connecting rod 216 (partially depicted) and leg members 220 (partially depicted) of the laundry drying rack 210 of Figure 1 as seen along axis 7-7.

Figure 8 is a perspective exploded view of the cylindrical connector set 228, connecting rod 216 and leg members 220 of Figure 7 along longitudinal axis 245.

Each cylindrical connector set 228 is provided with a cylindrical connector 278 held to the leg member 220 through which the connector 278 is inserted by a retaining member 292. The retaining member 292 can comprise any of a variety of fasteners that hold the connector 278 to the leg member 220 and prevent removal from the opening in that leg member through which the connector 278 is inserted.

Nails, screws and other such fasteners can be used.

Preferably, a snap ring, lock ring, or other member that engages a mating recess 286 to prevent movement of the part containing the recess along longitudinal axis 245 (Fig. 8) is used because they allow easy assembly by the user.

Advantageously the retaining member 292 comprises a retaining ring 292. The cylindrical connector 278 has an open end 280, an opposing flanged end 282, and a post section 284 disposed therebetween. The open end 280 has a recess 286 formed therein extending axially toward the flanged end 282. The recess 286 is sized and configured to axially receive the connecting rod distal end 258 therein for engagement of the cylindrical connector 278 to the connecting rod 216. The flanged end 282 has a flange 288 extending radially therefrom.

The post section 284 is sized and configured to extend through the distal openings 224 (as well as the cental openings 222, though not shown) of the elongate leg members 220 with the flange 288 abutting the elongate leg member 220 adjacent the distal opening 224 of the adjacent-most leg member 220. The post section 284 has an external groove 284 circumferentially formed therein. In this regard, the post section 284 has an outer surface 300 which slidably interfaces with the leg members 220 at the distal openings 222 thereof. The retaining ring 292 is sized and configured to receive the open end 280 of the cylindrical connector 278 therethrough. The retaining ring 292 is 'further sized and configured to concentrically engage the external groove 284, for capturing the elongate leg member 220 between the flange 288 and the retaining ring 292 about the post section 284.

In the preferred embodiment, the cylindrical connector 278 is sized and configured to engage the connecting rod distal end 258 in press-fit engagement therewith. As such, the recess 286 may be tapered outward toward the open end 280 for axially receiving the connecting rod distal end 258 in press-fit engagement. The end 58 of the rod 216 may also be tapered. The cylindrical connector 228 has an outer surface 298 tapering from the external groove 290 towards the open end 280 for receiving the retaining ring 292 thereover. The elastic retaining ring 292 is sized and configured to radially expand in slidable engagement over the outer surface 298 of the cylindrical connector towards the external groove 290.

The elastic retaining ring 292 has a ring inner surface 294 tapering towards the open end 280 of the cylindrical connector 278 when the elastic retaining ring 292 is engaged with the external groove 290. Having slid the retaining ring 292 over the outer surface 298 of cylindrical connector 278, the retaining ring 292 radially expands as the mating tapered surfaces 294,298 slide over each other, and then the ring snugly engages the external groove 290. Such engagement is contemplated to radially constrict the open end 280 of the cylindrical connector 278 about the connecting rod distal end 258. Further, it is contemplated that the sizing of the retaining ring 292 is configured to resist removal from such engagement with the external groove 90 thereby securing the leg members 220 between the retaining ring 292 and the flange 288. Such removal is further resisted with the particular tapering of the inner surface 294.

In addition, it is contemplated that the above described components comprising the various embodiments of the laundry drying rack 210 may be provided unassembled or partially assembled to an end user. Such unassembled or partially assembled components may therefore comprise a kit for constructing the laundry drying rack 210. It is contemplated that such disassembled state allows for easy

shipping and packaging and avoidance of assembly/manufacturing costs.

In order to aid an end user with the assembly of such kit constructing the laundry drying rack 210, the various components thereof may be particularly sized and even color coded in order to ensure proper assembly thereof. In this regard, the end connector set 226, the cylindrically connector sets 228, and opening 222,224 etc. may be sized differently so as to only fit within selected ones of the distal and central openings 224,222 of the leg members 220, as well as the distal openings 232, notch 234 and additional openings 236 of the cross bar 230.

In this regard, the post end 250 of the end connector 244 and the post section 284 of the cylindrical connector 278 may be sized differently so as to correspond to respective selective ones of the distal and central openings 224,222 of the leg members 220, as well as the distal openings 232, notch 234 and additional openings 236 of the cross bar 230.

The above parts can be provided in the form of a kit for compact shipping, and assembled by the user or by a retailer. Each kit advantageously includes two collapsible legs each having at least a pair of elongate leg members joined to rotate about a common axis to collapse and expand the legs. The kit also includes a plurality of connecting rods having opposing distal ends and sized so the opposing ends can connect to a different one of the collapsible legs.

Further, the kit includes a plurality of connectors each having an open end, an opposing flanged end, and a post section disposed therebetween. The open end has a recess formed therein extending axially toward the flanged end, and a distal end configured to receive a connecting rod in the recess when the laundry rack is assembled. The flanged end has a flange that prevents passage of the connector through an opening in a leg member through which the connector is inserted during use. The post end having an external groove circumferentially formed therein, the

post section being sized to place the groove on a side of the leg member through which the connector is inserted that is opposite the flanged end of the connector. One of the cylindrical connectors and connecting members is inserted through openings in the leg members to join the leg members so they rotate about the common axis to collapse and expand the legs, each leg having correspondingly located cylindrical connectors.

The kit also includes a plurality of retaining members, preferably taking the form of elastic retaining rings sized and configured to receive the open end of the cylindrical connector therethrough and engage the groove to capture the'elongate leg member through which the connector is inserted between the flange and the ring when the laundry rack is assembled. Moreover, the kit includes at least one pronged connector fastened to each leg. Each pronged connector has an end with resilient prongs and a post end. The post end is sized and configured to extend through an opening of an elongated member on each leg to fasten the connector to each leg. Each leg has correspondingly located pronged connectors.

Finally, each kit has at least two tubular couplings each having a distal end, an opposing proximal end, and an internal engaging surface therein. The proximal end of the at least two couplings is connected to opposing ends of a connecting rod, with the distal end being sized and configured to axially receive the prongs therein. The internal ridge or engaging surface is configured and located to engage the resilient prongs and restrain removal of the prongs from the coupling When the kit comprising the various components of the laundry drying rack is provided, there is also provided a simple and fast method of forming a laundry drying rack.

The method comprises inserting distal ends of a connecting rod into the recesses of corresponding connectors on both legs to connect the legs together, and inserting distal ends of the couplings on the at least one connecting rod over the corresponding prongs on opposing legs to engage

the prongs with the internal recess of the engaged coupling to restrain the legs from moving away from each other along a longitudinal axis of the rod having the couplings.

Even the assembly of various sub-components at the factor level is simplified with the above invention. The flanged connectors 278 can be inserted into the openings through the end members 220 from only one side in order to assemble the scissor sections 218 forming each of the two opposing legs 212,214 of the drying rack. The length of the post 300 will vary depending on the dimensions of the- members 220 through which the connector 278 is inserted.

The size of the openings in the end members 220 can be varied and correlated with the size of the connectors 278 in order to ensure the correct parts are placed through the correct openings. That allows easy and fast assembly of the legs 212,214. The couplings 246 are easily inserted onto and fastened to the connecting rods 16. The pronged end connectors 244 are easily inserted into appropriate openings 222,224 and fastened to the appropriate member 220.

The above description is given by way of example, and not limitation. Further, the various features of this invention can be used alone, or in varying combinations with each other and are not intended to be limited to the specific combination described herein. Thus, the connectors can be used by themselves in other applications.

The unassembled parts can be provided by themselves in kit form. The parts when assembled together to form a laundry stand, or laundry drying rack forms yet another advantageous combination.

Further, the prongs 264 and pronged end 248 could be formed on or connected to a distal end of the connecting rods 216, and the couplings 246 have an additional internal engaging surface to connect the pronged end 248. Further, the pronged end 248 on the connector 2248 could be replaced with the tubular end 252 having an internal engaging surface such as ridge 256 to engage a pronged end 248 located on a rod 216. Additionally, for the parts

benefitting from a press-fit, the press-fit can be achieved by using the raised ridges or the tapered surfaces described in various embodiments of this disclosure.

Additional modifications and improvements of the present invention may also be apparent to those of ordinary skill in the art. Thus, the particular combination of parts described and illustrated herein is intended to represent only one embodiment of the present invention, and is not intended to serve as limitations of alternative devices within the spirit and scope of the invention.

Moreover, the invention is not to be limited by the illustrated embodiments but is to be defined by the following claims when read in the broadest reasonable manner to preserve the validity of the claims.