GB1559486A - Window blind roller and fittings - Google Patents

Description

(54) WINDOW BLIND ROLLER END FITTINGS (71) We, BRENEMAN, INC., a Corporation organised under the laws of the State of Ohio, United States of America, of 1133 Sycamore Street, Cincinnati, Ohio, United States of America, do hereby declare the invention, for which we pray that a patent may be granted to us, and the method by which it is to be performed, to be particularly described in and by the following statement: This invention relates to end fittings for window blind rollers, also known as window shade rollers.

One form of window blind roller contains a return spring, one end of which is connected to the roller, while the other end is held stationary by being connected to a stationary part of an end fitting of the roller; this stationary part is known as a spear, and serves to support the associated end of the roller by being received in a mounting bracket. The end fitting also contains a clutch which holds the roller stationary, with the blind unwound to the required extent, until the return spring is required to rewind the blind.

The present invention provides an end fitting for this form of window blind roller, which fitting comprises only a few components. This simplifies both manufacture and assembly of the end fitting.

According to one aspect of the present invention, an end fitting for a window blind roller comprises a first member which is rotatably carried by a second member, the two members being kept assembled against axial separation by a radially-extending projection or projections on at least one of the members engaging a portion or portions of the other member, the second member having a mounting portion for attachment to a mounting bracket, while the first member has a connecting portion for attachment to a return spring, and the end fitting also including a clutch comprising at least one clutch element which cooperates withRcitutch surfaces on the first and second members to control rotation of the first member, and the said projection or projections being radially displaceable to permit assembly of the first and second members.

In a preferred form of the invention, the connecting portion of the first member also includes spring-retaining lugs which extend parallel to but are spaced from the cylindrical surface of the barrel of the first mernber, the lugs each being free at their end remote from the clutch surfaces of the first member; a helical drive spring may then be anchored to the first member by having its turns frictionally received between the barrel of the first member and the springretaining lugs. This method of anchonng the spring is simple, but sufficiently effective; unlike some methods of anchoring the sprint, this method results in a radially-inward com- pressive force on the spring coils, which force is fairly evenly distributed around the spring. This force is exerted on the spring by the spring-retaining lugs, and these lugs may engage the inside of a tube which forms the main part of the roller, so that an increased compressive force is obtained.

According to another aspect of the invention, a window blind roller includes an end fitting according to the first aspect.

The invention may be carried into practice in various ways, but one particular end fitting for a window blind roller embodying the invention will now be described by way of example with reference to the accompanying drawings, in which: Figure 1 is a side elevational view of an inner member or structure forming part of the end fitting; Figure 2 is a side elevational view of an outer member or spring-retaining structure and a fragmentary portion of a spring support dowel in accordance with the invention, showing the relative alignment there between; Fig. 3 is an elevational view of an assembled spear structure, spring retaining structure and spring supporting dowel, in accordance with an embodiment of this in invention; Fig. 4 is an elevational view of the assembly of Fig. 3, together with the addition of a drive spring inserted in secured position; Figs. Sa and 5b are cross-sectional views along section Va-b - Va-b of Fig. 4 showing a ball clutch in a locked and an unlocked position; and Fig. 6 is a longitudinal cross-sectional view of the assembly shown in Fig. 4, along the plane VI-VI.

DETAILED DESCRIPTION Referring to Fig. 1, the spear structure 10 has certain portions which engage an external window shade support bracket, while others act to form part of a ball clutch arrangement. In the embodiment illustrated, such portions include a solid. substantially rectangular spear 11, preferably as an integral part of spear structure 10. Typically, spear 11 is received in a slotted external bracket used for supporting the shade and preventing rotation of the spear. Spear structure 10 further integrally includes an end cap 15, a barrel 12 and a flange 13 at the end of barrel 12. End cap portion 15 is a thin disc-like cylindrical solid. Barrel 12 is a tubular section having a blind central cylindrical opening with a pair of internal ribs 17. Flange 13 surrounds an end portion of barrel 12 to provide a truncated coneshaped ridge near such end portion, as illustrated. Spear 11 projects from end cap 15 in a first direction along the central axis of end cap 15 and barrel 12 projects in the opposite direction. To provide for compression, or annular contraction, of the flanged end of barrel 12 there are two (or more) diametrically opposed slots 16, parallel to the central axis of structure 10, extending through flange 13 and a portion of barrel 12. It can be appreciated that the number of slots can vary. A ratchet arrangement 14 is part of spear structure 10 and is used as part of a ball clutching arrangement for a spring drive of the shade. Ratchet arrangement 14 surrounds a portion of barrel 12 adjacent end cap 15 and includes circumferentially-spaced protrusions extending radially outward from barrel 12. A crosssectional view of ratchet arrangement 14 is shown in Figs. 5.a and Sb. Typically, spear structure 10 is made as one piece, preferably from nylon, by an injection moulding process.

Fig. 2 shows a spring retaining structure 20 which includes a spring-retaining barrel 21 and spring-compression lugs 22. Also shown is the relative alignment of a spring support dowel 25 having a slotted end 30, disposed coaxially with barrel 21. An end disc 23 provides a support or base from which project barrel 21 and lugs 22. End disc 23 is a disc-like cylindrical solid having an aligned central cylindrical opening (not seen in Fig. 2). Barrel 21 is a tubular projection having an aligned central cylindrical opening. The central openings of disc 23 and barrel 21 are aligned and communicate with one another. The diameter of the opening of disc 23 is at least as great as the diameter of the opening in barrel 21.

The lugs 22 are circuniferentially spaced, axially aligned portions forming in essence a slotted cylindrical shell. One end of each lug can be tapered toward the central axis of barrel 21. Lugs 22 are longitudinally aligned with the central axis of barrel 21, circumferentially spaced from each other around the barrel, and radially spaced therefrom so that the end of a coil spring can be fitted into the annular space between lugs 22 and barrel 21.

Fig. 6 shows a cross-sectional view of spring-retaining structure 20, where it can be observed that end disc 23 has recesses 24 in its lateral side 26, opposite from barrel 21, for receiving balls 61. In accordance with an embodiment of this invention, the recesses have canted floors 62 (Fig. 6), i.e., the floors of the recesses angularly deepen as the radial distance from the central axis increases. During manufacture, canted floors 62 are particularly advantageous for retaining balls 61 against side walls 63 of the recesses. Such positive placement of balls 61 facilitates the manufacturing process. The cross sectional view in Fig. 5b shows how a ball placed on canted floor 62 would automatically (i.e., by gravity) roll into position against sidewall 63. Preferably, as with spear structure 10, spring-retaining structure 20 is made from nylon by an injection moulding process. Of course, structure 10 and 20 could be made from various other materials, including, for example, various other plastics.

Fig. 3 shows an assembly of spring support dowel 25, spring-retaining structure 20 and spear structure 10. In particular, barrel 12 and flange 13 of spear structure 10 have been inserted through the central opening in barrel 21 of spring-retaining structure 20.

During insertion, the slots 16 permit portions of barrel 12, including the flange 13, to squeeze toward each other, and then to snap outward once through barrel 21. The lengths of barrels 12 and 21 are adapted so that when ridge flange 13 snaps outward it butts against the end of barrel 21, at which time end cap 15 is flush against (or narrowly clears) end disc 23. Accordingly, structures 10 and 20 are simply and positively connected, being self-retaining. The insertion of spear structure 10 into structure 20, or at least the insertion of the balls 61 into their recesses 24, is preferably done with the ball-retaining recesses of structure 20 opening upward. That is, after initial insertion of spear structure 10 but prior to the time when ridge 13 snaps out into place behind the end of barrel 21, the balls 61 are placed into their recesses 24, where they rest on canted floors 62, whereupon spear assembly 10 is inserted the rest of the way into structure 20. The one-way clutching action required in a shade roller is complete after the simple operations of inserting the balls into the ball-retaining recesses and inserting structure 10 fully into structure 20.

After the complete insertion of spear structure 10, dowel 25 is inserted in the central opening of its barrel 12. The diametral fit between dowel 25 and barrel 12 is such that hte presence of the dowel prevents barrel 12 from being compressed sufficiently to allow flange 13 to pass back through barrel 21 of structure 20. This further ensures the proper cooperation of structures 10 and 20 both in support of the final shade assembly and in the clutching action to control shade winding. While it is possible to merely secure dowel 25 within the opening of barrel 12 by gluing or other such measures, it is preferred to use a self-retaining, snap-fit construction as illustrated. This includes a straight-sided groove 32 (Figs. 2 and 6) around the circumference of dowel 25 immediately inward of the diametral slot 31 which forms the aforementioned divided end 30 of the dowel. Also, barrel 12 of spear structure 10 has a conical internal ridge 18 (Figs. I and 6) similar to its outer such ridge 13 already described.

When dowel 25 is inserted into spear structure 10, the interaction between ridge 18 and dowel 25 at first causes diametral enlargement of the spear structure barrel, but when the groove 32 comes into alignment with ridge 18 the latter snaps into place within the groove locking the dowel in place.

In this operation the end slot 31 of dowel 25 (which preferably has the same such shape at each end) must first be rotated into alignment with the internal ribs 17 of the spear structure barrel, which thus slide into such end slot and there act to preclude relative rotation between the dowel and the spear structure.

Referring to Figs. 4 and 6, a spring 41 is shown, which is to be understood as being attached to dowel 25 at the end thereof opposite spring retainer 20 (not shown) in a conventional way, as by an offset diametrally disposed end of the spring which engages the slot in the cnd of the dowel.

At the opposite end, shown in the drawings, the spring is compressed (i.e., radially contracted) and inserted between lugs 22 and barrel 21. The securing of spring 41 between lugs 22 and barrel 21 is particularly advantageous because this securely retains one end of the spring without the need for any mechanical fasteners such as pins, clips, staples or tacks, which are often used for such purpose. Further, eliminating such attachment devices simplifies and reduces the labour and time required by the manufacturing process. Spring 41 is secured by a simple axial thrusting insertion, preferably including at least some rotation of thc spring end at the same time.

In this connection, it should be observed that the inside diameter of spring 41 prefer ably fits complementarily over the ou. outside of barrel 21, with the annular clearance between the inside surfaces of the lugs 22 and the outside of barrel 21 being preferably on the order of, or slightly less than, the diameter of the wire from which spring 41 is wound, so as to provide an interference fit there be tween. Further, the lugs are preferably at least slightly flexible. Accordingly, in such a preferred embodiment, when the spring is inserted into place, the lugs are forced outwardly at least slightly, whereupon their natural resilience or "plastic memory" causes them to grip the outside of the spring, contracting it annularly, radially about the barrel 21. The end of spring 41 inserted between lugs 22 and barrel 21 may if desired have a lateral, radially bent end portion.

Such an end portion is inserted between lugs 22 and can butt up against the side of a lug to ensure that no rotation of drive spring 41 can occur with respect to spring retaining structure 20. Because the entire spring motor assembly, including lugs 22, is subsequently inserted into a tube, any such bent end portion of the spring should have a radial extension less than the maximum radial extension of any portion of lugs 22, so as not to engage the inside wall of such tube. It is to be pointed out, however, that such an offset or bent end of the drive spring is not essential to the satisfactory practice of the invention, since the engagement of the spring between the barrel 21 and lugs 22 will hold the spring very satisfactorily against rotational slippage of the spring, allowing the latter to be torsionally wound upon the dowel for driving operation between the spear structure 10 and its receiving and cooperating structure, upon rotation there between through the ball clutch.

Figs. 5a and Sb illustrate the operation of the ball clutch. In the locked position, shown in Fig. 5n, one (or, at times, two) side of the ratchet surface arrangement 14 is engaged by one (or both) of the balls 61. In the unlocked position, shown in Fig. Sb, the sides of ratchet arrangement 14 are free to turn, clear of balls 61. As will be understood, the basic nature of such a clutch is known in the art and no detailed description is therefore required here.

Fig. 6 shows a cross-sectional view of a completely assembled shade support roller and spring motor. In this view, an outer shade support tube 64 is shown in place over drive spring 41, the spring motor assembly having been inserted fully therein.

During such insertion, lugs 22 frictionally engage, and preferably embed into, the inside wall of tube 64, and this serves to radially compress or contract the lugs tightly about spring 41, forcibly trapping the same against barrel 21. Tube 64 provides an attachment means, and a support for, the window shade panel.

Various modifications and variations will no doubt occur to those skilled in the various arts to which this invention pertains.

For cxample, the support dowel may be provided with side protrusions to positively engage the slots in the barrel of the spear assembly. Also, spring retaining surfaces may he grooved to improved retention.

Claims (19)

1. WHAT WE CLAIM IS:- 0. An end fitting for a window blind roller, comprising a first member which is rotatably carried by a second member, the two members being kept assembled against axial separation by a radially-extending projection or projections on at least one of the members engaging a portion or portions of the other member, the second member having a mounting portion for attachment to a mounting bracket, while the first member has a connecting portion for attachment to a return spring, and the end fitting also including a clutch comprising at least one clutch element which cooperates with clutch surfaces on the first and second members to control rotation of the first member, and the said projection or projections being radially displaceable to permit assembly of the first and second members.
2. 2. A fitting as claimed in Claim 1 in which the mounting portion of the second member comprises an integral portion which projects along the axis of rotation of the first member, and is integral with the rest of the second member, and the second mcmber also includes a cylindrical barrel on which the first member is rotatably mounted, the barrel carrying the said projection or projections at its end remote from the mounting portion.
3. 3. A fitting as claimed in Claim 2 in which the mounting portion is of rectangular cross-section.
4. 4. A fitting as claimed in Claim 2 or Claim 3 in which the end of the barrel carrying the projection or projections is com- pressible to allow radial displacement thereof.
5. 5. A fitting as claimed in any of the preceding claims in which the clutch surfaces on the second member are in the form of a ratchet.
6. 6. A fitting as claimed in Claim 5 when appendant to Claim 2, in which the clutch surfaces on the second member lie between the mounting portion and the barrel thereof.
7. 7. A fitting as claimed in Claim 6 in which the clutch surfaces are separated from the mounting portion by a generally disclike end cap portion of the second member.
8. 8. A fitting as claimed in any of the preceding claims in which the first member has a recess or recesses which afford the clutch surfaces on the first member, the recess or recesses being open at one axial end.
9. 9. A fitting as claimed in any of the preceding claims in which the connecting portion of the first member includes a barrel with a bore by which the first member is rotatably mounted on the second member.
10. 10. A fitting as claimed in Claim 8 and Claim 9 in which the open end of the or each recess which affords the clutch surfaces on the first member is at the end of the recess remote from the barrel of the first member.
11. 11. A fitting as claimed in Claim 9 or Claim 10 in which the connecting portion of the first member also includes springretaining lugs which extend parallel to but are spaced from the cylindrical surface of the barrel of the first member, the lugs each being free at their end remote from the clutch surfaces of the first member.
12. 12. A fitting as claimed in Claim 8 or Claims 8 and 9 or Claim 10 or Claims 8 and 11. 12 in which the or each recess is closed at its other axial end by a wall which is an gled to the direction normal to the axis of the first member in the sense to deepen the recess at greater radii.
13. 13. A fitting as claimed in any of the preceding claims in which the or each clutch element is a ball.
14. 14. A fitting as claimed in Claim 2 or any of Claims 3 to 13 when appendant to Claim 2, which also includes a rod having one end anchored in the barrel of the second member. and a helical drive spring positioned around the rod and anchored at one end to the first member and at the other end to the rod.
15. 15. A fitting as claimed in Claim 14 whe. appendant to Claim 11, in which the sr 3 is anchored to the first member bv has lv its turns frictionally received between the barrel of the first member and the spring retining lugs.
16. A A fitting as claimed in Claim 14 or r'iim 15 in which the rod ('i is anchored in the barrel of the second member bv the intereneaeement of radially-extending inter locking portions on the rod and the barrel.
17. 17. A fitting as claimed in Claim 16 in which the interlocking portions are resiliently displaceable to allow assembly of the rod to the second member.
18. 18. An end fitting for a window blind roller, the end fitting being substantially as herein described with reference to Fthe accompanying drawings.
19. 19. A window blind roller including an end fitting as claimed in any of the preceding claims.