GB1602031A - System for building a framework for supporting a machine or mechanism having a rotatable shaft - Google Patents

Description

(54) SYSTEM FOR BUILDING A FRAMEWORK FOR SUPPORTING A MACHINE OR MECHANISM HAVING A ROTATABLE SHAFT (71) We, N. V. PHILIPS' GLOEI LAMPENFABRIEKEN, a limited liability Company, organised and established under the laws of the Kingdom of the Netherlands, of Emmasingel 29, Eindhoven, the Netherlands, 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:- The invention relates to a system for building a framework for supporting a machine or mechanism having a rotatable shaft.

The invention relates particulariy to a system comprising a plurality of rods and a plurality of elements of which some form coupling elements for coupling the rods to one another and at least one is constructed as a bearing element for supporting said shaft, each rod comprising a plurality of ribs which extend parallel to each other longitudinally of the rod, and each of the coupling and bearing elements being formed with grooves each of which is capable of receiving a rib of one of the rods, the ribs and grooves having cross-sectional shapes such that when a rib is received in a groove the rib and the groove interlock with each other in directions transverse to their longitudinal axes, and each of the coupling and bearing elements being divided into two separate sections such that each groove in each element is divided along a plane extending longitudinally of the groove into two parts lying one part in each section of the element, screw-threaded connections being provided for connecting the two sections of each element together.

Such a construction permits a ready assembly of the framework. To connect a coupling or bearing element to a rod it is necessary simply to separate the two sections of the element and then bring them together again with the two parts of one of the grooves of the element engaging over the selected rib of the rod, after which the two sections of the element are connected together by means of the screw-threaded connections so that the wafls of the two parts of the relevant groove grip the respective rib. Before tightening the screw threaded connections the coupling or bearing element can be slid along the rib to locate it in any desired position on the rod.

According to the present invention in a building system of the above construction each rib of each rod has a convexly curved surface facing outwardly away from the longitudinal axis of the rod, said surfaces of all the ribs of each rod lying on an imaginary circumscribing cylinder whose axis coincides with the longitudinal axis of the rod. This permits the use in the system of a further clamping element which comprises separate sections each having a partcylindrical clamping surface for engagement with the convexly curved surface or surfaces of one or more of the ribs of one of the rods. Unlike the grooved coupling elements this further coupling element, before being clamped on a rod, can be rotated around the rod as well as slid along it. The further coupling element is therefore useful in a situation in which two rods are to be coupled together in relative positions which cannot be obtained with the use of grooved coupling elements.

Preferably, the ribs of all the rods have cross-sections of identical shape and size so that any of the coupling and bearing elements will fit on any of the rods.

In a preferred embodiment of the invention the ribs and grooves each have a dovetail cross-section.

Preferably, the aforesaid circumscribing cylinder of each rod has a diameter of 6, 10, 15, 25 or 40 mm or a multiple thereof. The rods can then be selected so that their permissible stresses as well as their rigidities substantially form a geometric progression.

A system according to this embodiment of the invention may comprise a rod which has a circumscribing cylinder with a diameter of 6 mm and which consists of two ribs disposed diametrically opposite one another with respect to the longitudinal axis of the rod and adjoining one another at their bases, and a plurality of rods each of which comprises four ribs spaced evenly about the longitudinal axis of the respective rod, and wherein the coupling and bearing elements are of rectangular shape and are each formed with one of said grooves in each of the four sides of the respective element, each groove extending along the entire length of the respective side and the lengths of the sides of each element being multiples of 5 mm.

Embodiments of the invention will now be described in detail with reference to the accompanying drawings, in which Figures la, b, c, d and e are perspective views of portions of five rods each comprising longitudinal ribs in accordance with an embodiment of the invention Figures 2a and 2b are a part-sectional side view and an elevation, respectively, of a bearing element formed with grooves in accordance with an embodiment of the invention, Figures 3a and 3b are apart-sectional side view and an elevation, respectively, of a coupling element formed with grooves in accordance with an embodiment of the invention, Figures 4a and 4b are views, looking in directions at right angles to one another, of a clamping block which can optionally be used in a system according to the invention, and Figure 5 is a perspective view of part of a supporting framework built from a system according to an embodiment of the invention.

The five rods shown in Figures la, b, c, d and e, and numbered 1 to 5 respectively, each comprise a plurality of ribs 6 which extend parallel to each other longitudinally of the rod and which are evenly spaced about the longitudinal axis of the rod. Each rib has a convexly curved surface 6a facing outwardly away from this axis, which surface lies on an imaginary cylinder whose axis coincides with the longitudinal axis of the rod. The surfaces 6a of all the ribs of each rod lie on the same imaginary cylinder, which thus constitutes a circumscribing cylinder of the rod. The rod I in Figure la, which rod consists solely of two ribs disposed diametrically opposite one another with respect to the longitudinal axis of the rod and adjoining one another at their bases, has the smallest circumscribing cylinder. In a practical example the circumscribing cylinder of the rod I has a diameter of 6 mm and the circumscribing cylinders of the rods 2, 3, 4 and 5 in Figures Ib, c, d and e, each of which rods has four ribs, have diameters of 10, 15,25 and 40 mm respectively. In addition to the convexly curved, outwardly facing surface 6a, each rib of each rod has two undercut sides. In the embodiment shown this is obtained by giving the ribs a dovetail cross-section. The height, the angle of inclination of the sides and the width of the base of the dovetail cross-section of the ribs are the same for all the rods. The height amounts to approximately 2.5 mm in the above practical example.

Figure 5 shows portions of three rods 3 of the form shown in Figure Ic, which rods are coupled to one another by three coupling elements 24 of the construction shown in Figures 3a and b. The rods and coupling elements form part of a framework for supporting a machine or mechanism (not shown) which includes a rotating shaft 25.

The shaft is supported by a bearing element 26 of the construction shown in Figures 2a and b. This bearing element is of rectangular shape and is divided into two separate halves 7 and 8 which are connected together by four bolts 9. The lengths of the four sides of the bearing element may be multiples of 5 mm, for example. The bearing element 26 is formed in each of its four sides with a groove 10 which extends along the entire length of the respective side, the four grooves adjoining one another at their ends.

The grooves have a dovetail cross-section which corresponds to that of the ribs 6 of the rods 3 so that a rib of one of the rods can be received in any of the grooves or the bearing element. Due to the sides of the ribs 6 being undercut, when a rib is received in a groove the rib and the groove interlock with each other in directions transverse to their longitudinal axes. The bearing element 26 is divided into the two halves 7 and 8 along a plane 27 which contains the longitudinal centrelines of the four grooves in the bearing element. Thus, each groove is divided longitudinally by the plane 27 into two parts lying one part in each half of the bearing element. When the bearing element 26 is to be mounted on the relevant rod 3, the two halves of the bearing element are first separated from one another by unscrewing the bolts 9 and are subsequently brought together again with the two parts of one of the grooves of the element engaging over the selected rib of the rod 3. The two halves of the bearing element are then screwed together by means of the bolts 9 so that the walls of the two parts of the relevant groove grip the respective rib. The bearing element 26 has a central aperture 28 surrounded by a ball-bearing 29 (Figure 2a) in which the shaft 25 is supported. If desired, a number of bearing elements of the above construction can be included in the framework shown in Figure 5.

The coupling elements 24 are of similar construction to the bearing element 26 except that they do not have a central aperture surrounded by a ball-bearing. Each coupling element consists of two separate halves 11 and 12 (Figure 3a) connected together by four bolts 13, and each of the four sides of each coupling element is formed with a groove 14 of dovetail crosssection which can receive a rib of one of the rods 3. In the arrangement shown in Figure 5, a vertical rod and two horizontal rods extending at right angles to one another are coupled together by the three coupling elements 24, each coupling element receiving in each of two adjoining grooves one of the ribs 6 of each of two of the rods.

The provision of the convexly curved outwardly facing surfaces 6a of the ribs 6 of the rods permits the use of a coupling element in the form of a clamping block having the construction shown in Figures 4a and b in a framework built from rods of the form shown in any of Figures la to le. Such a clamping block is shown at 30 in Figure 5.

The block consists of three separate sections 16, 17 and 18 which are clamped together by bolts 19. The block is formed with four cylindrical through-bores 20, 21, 22 and 23. The bores 20 and 21 have a diameter corresponding to the diameter of the circumscribing cylinders of rods of one size; the bores 22 and 23 have a diameter corresponding to the diameter of the circumscribing cylinders of rods of a larger size. The bore 20 intersects the bore 23 at right angles and extends parallel to the bore 22: the bore 21 intersects the bore 22 at right angles and extends parallel to the bore 23.

The bores 20 and 23 are each divided into two semi-cylindrical halves by the separation between the sections 17 and 18 of the clamping block, and the bores 21 and 22 are each divided into two semi-cylindrical halves by the separation between the sections 16 and 17 of the block. The wall of each half of each bore forms a semicylindrical clamping surface for engagement with the curved surface or surfaces 6a of one or more of the ribs 6 of one of the rods. Figure 5 shows two rods clamped in the larger-sized bores 22 and 23 of the block.

WHAT WE CLAIM IS: 1. A system for building a framework for supporting a machien or mechanism having a rotatable shaft, the system comprising a plurality or rods and a plurality of elements of which some form coupling elements for coupling the rods to one another and at least one is constructed as a bearing element for supporting said shaft, each rod comprising a plurality of ribs which extend parallel to each other longitudinally of the rod, and each of the coupling and bearing elements being formed with grooves each of which is capable of receiving a rib of one of the rods, the ribs and grooves having crosssectional shapes such that when a rib is received in a groove the rib and the groove interlock with each other in directions transverse to their longitudinal axes, and each of the coupling and bearing elements being divided into two separate sections such that each groove in each element is divided along a plane extending longitudinally of the groove into two parts lying one part in each section of the element, screw-threaded connections being provided for connecting the two sections of each element together, wherein each rib of each rod has a convexly curved surface facing outwardly away from the longitudinal axis of the rod, said surfaces of all the ribs of each rod lying on an imaginary circumscribing cylinder whose axis coincides with the longitudinal axis of the rod.

2. A system as claimed in Claim I, wherein the ribs and the grooves each have a dovetail cross-section.

3. A system as claimed in Claim 1 or 2, comprising a further clamping element which comprises separate sections each having a part-cylindrical clamping surface for engagement with the convexly curved surface or surfaces of one or more of the ribs of one of the rods.

4. A system as claimed in Claim 1, 2 or 3, wherein the ribs of all the rods have cross sections of identical shape and size.

5. A system as claimed in Claim 3, wherein the circumscribing cylinder of each rod has a diameter of 6, 10, 15, 25 or 40 mm or a multiple thereof.

6. A system as claimed in Claims 2 and 5, comprising a rod which has a circumscribing cylinder with a diameter of 6 mm and which consists of two ribs disposed diametrically opposite one another with respect to the longitudinal axis of the rod and adjoining one another at their bases, and a plurality of rods each of which comprises four ribs spaced evenly about the longitudinal axis of the respective rod, and wherein the coupling and bearing elements are of rectangular shape and are each formed with one of said grooves in each of the four sides of the respective element, each groove extending along the entire length of the respective side and the lengths

**WARNING** end of DESC field may overlap start of CLMS **.

Claims (7)

**WARNING** start of CLMS field may overlap end of DESC **. desired, a number of bearing elements of the above construction can be included in the framework shown in Figure 5. The coupling elements 24 are of similar construction to the bearing element 26 except that they do not have a central aperture surrounded by a ball-bearing. Each coupling element consists of two separate halves 11 and 12 (Figure 3a) connected together by four bolts 13, and each of the four sides of each coupling element is formed with a groove 14 of dovetail crosssection which can receive a rib of one of the rods 3. In the arrangement shown in Figure 5, a vertical rod and two horizontal rods extending at right angles to one another are coupled together by the three coupling elements 24, each coupling element receiving in each of two adjoining grooves one of the ribs 6 of each of two of the rods. The provision of the convexly curved outwardly facing surfaces 6a of the ribs 6 of the rods permits the use of a coupling element in the form of a clamping block having the construction shown in Figures 4a and b in a framework built from rods of the form shown in any of Figures la to le. Such a clamping block is shown at 30 in Figure 5. The block consists of three separate sections 16, 17 and 18 which are clamped together by bolts 19. The block is formed with four cylindrical through-bores 20, 21, 22 and 23. The bores 20 and 21 have a diameter corresponding to the diameter of the circumscribing cylinders of rods of one size; the bores 22 and 23 have a diameter corresponding to the diameter of the circumscribing cylinders of rods of a larger size. The bore 20 intersects the bore 23 at right angles and extends parallel to the bore 22: the bore 21 intersects the bore 22 at right angles and extends parallel to the bore 23. The bores 20 and 23 are each divided into two semi-cylindrical halves by the separation between the sections 17 and 18 of the clamping block, and the bores 21 and 22 are each divided into two semi-cylindrical halves by the separation between the sections 16 and 17 of the block. The wall of each half of each bore forms a semicylindrical clamping surface for engagement with the curved surface or surfaces 6a of one or more of the ribs 6 of one of the rods. Figure 5 shows two rods clamped in the larger-sized bores 22 and 23 of the block. WHAT WE CLAIM IS:

1. A system for building a framework for supporting a machien or mechanism having a rotatable shaft, the system comprising a plurality or rods and a plurality of elements of which some form coupling elements for coupling the rods to one another and at least one is constructed as a bearing element for supporting said shaft, each rod comprising a plurality of ribs which extend parallel to each other longitudinally of the rod, and each of the coupling and bearing elements being formed with grooves each of which is capable of receiving a rib of one of the rods, the ribs and grooves having crosssectional shapes such that when a rib is received in a groove the rib and the groove interlock with each other in directions transverse to their longitudinal axes, and each of the coupling and bearing elements being divided into two separate sections such that each groove in each element is divided along a plane extending longitudinally of the groove into two parts lying one part in each section of the element, screw-threaded connections being provided for connecting the two sections of each element together, wherein each rib of each rod has a convexly curved surface facing outwardly away from the longitudinal axis of the rod, said surfaces of all the ribs of each rod lying on an imaginary circumscribing cylinder whose axis coincides with the longitudinal axis of the rod.

2. A system as claimed in Claim I, wherein the ribs and the grooves each have a dovetail cross-section.

3. A system as claimed in Claim 1 or 2, comprising a further clamping element which comprises separate sections each having a part-cylindrical clamping surface for engagement with the convexly curved surface or surfaces of one or more of the ribs of one of the rods.

4. A system as claimed in Claim 1, 2 or 3, wherein the ribs of all the rods have cross sections of identical shape and size.

5. A system as claimed in Claim 3, wherein the circumscribing cylinder of each rod has a diameter of 6, 10, 15, 25 or 40 mm or a multiple thereof.

6. A system as claimed in Claims 2 and 5, comprising a rod which has a circumscribing cylinder with a diameter of 6 mm and which consists of two ribs disposed diametrically opposite one another with respect to the longitudinal axis of the rod and adjoining one another at their bases, and a plurality of rods each of which comprises four ribs spaced evenly about the longitudinal axis of the respective rod, and wherein the coupling and bearing elements are of rectangular shape and are each formed with one of said grooves in each of the four sides of the respective element, each groove extending along the entire length of the respective side and the lengths

of the sides of each element being multiples of 5 mm.

7. A system for building a framework for supporting a machine or mechanism having a rotatable member, the system substantially as herein described with reference to the accompanying drawings.