Abstract:
A support beam for elevator sheaves is disclosed. The support beam includes telescopic arms which are retracted for positioning the beam in the elevator shaft and, when positioned, are extended into recesses defined by the shaft walls to mount the beam in the desired position.

Description:
DESCRIPTION 
     1. Technical Field 
     The invention relates to a support beam for elevator sheaves and in particular, a beam which may readily be mounted in the upper structure of buildings having elevators wherein the elevator machinery is located other than above the hoistway. 
     2. Background of the Invention 
     Support beams for elevator sheaves have previously been of fixed length and must be mounted by insertion of their ends into open recesses provided at the top of the elevator shaft. Such mounting requires masonry work after mounting of the beam to secure the beam in the recesses. Such an operation may impair the beam isolation arrangement relative to the building by inadvertently securing the beam directly to the building thereby preventing isolating cushions supporting the beam ends from performing their function. 
     DISCLOSURE OF INVENTION 
     The invention aims to overcome these drawbacks with a new beam of the above-mentioned kind which includes at each of its ends a telescopic arm. The telescopic arm may slide outwardly from a retracted position facilitating insertion and handling of the beam in the elevator shaft, to an extended position in which it is adapted to be mounted by its end portions in the corresponding shaft recesses provided for receiving the end portions of the beam. 
     The advantage of such an arrangement is that it no longer requires open recesses to be provided in the thickness of the shaft wall on construction of the building. Consequently, masons are not required to cement around the beam once it has been positioned. 
     The recesses may in fact be formed by simple supports for the beam arms which are mounted in the shaft wall. Preferably, they consist of masonry recesses suitably dimensioned and positioned, formed in the shaft wall. The mounting of the beam in these recesses only requires the simple operation of opening the telescopic arms of the beam outwardly to extend into these recesses. The isolating cushions between the telescopic arms and the recesses remain fully functional without the danger of being made inoperative by being embedded in cement through subsequent masonry work, as with traditional beams. 
     Furthermore, the inward folding of the telescopic arms of the beam in particular facilitates raising of the beam in the shaft to its top fitting position, notwithstanding that the landing doors may have already been mounted with the sills or thresholds projecting inside the shaft. 
     Moreover, the maximum extension of the telescopic arms, which depends on the forces acting on and the permissible flexion of the beam structure, may be locked in a limit position indicated by a label affixed to each arm at this extension level. In this way it is possible to make sure that the permissible stress limits are not exceeded. 
     One embodiment of the invention is described hereafter by way of non-limiting example and with reference to the accompanying drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a longitudinal elevational view with parts cut away of one of the arms of a support beam in accordance with the invention, the telescopic arms being in the retracted position; 
     FIG. 2 is a longitudinal elevational view similar to FIG. 1 of the beam mounted in the elevator shaft with the arms extended; 
     FIG. 3 is a sectional view through line A--A of FIG. 2; and 
     FIG. 4 is a top view with parts cut away of the beam. 
    
    
     BEST MODE FOR CARRYING OUT THE INVENTION 
     As shown in these figures, the elevator beam of the invention is formed essentially of an upper tubular body 1 housing at each of its ends a telescopic arm 3 and including lower skirt 5 fastened to body 1 and carrying the sheaves 7 for the ropes of the elevator. The width of skirt 5 is equal to that of sheaves 7 plus an operating clearance. Body 1 is open longitudinally at its upper part by this same skirt width. Each of the lateral parts 9 forming the body and the skirt is formed from the same suitably profiled shape, the two profiled shapes being opposite each other with symmetry with respect to the median longitudinal plane. The upper part 11 of each profiled shape 9 is in the form of an inwardly turned U and the lower part 13 is flat. The flat portions 13 are braced and receive the sheave shafts 15 suitably keyed at their ends. The telescopic arms 3 are each formed of two opposite U-shaped bars 17 reinforced by gussets 38. These bars have a profile complementary, except for the clearance, to that of the U-shaped flanges 11 of the beam body so that each is housed thereinside and may slide freely. They are spaced apart substantially by the width of skirt 5 so as to slidingly pass around the rims of sheaves 7. Arms 3 may slide from a retracted position (FIG. 1) in which their internal opposite ends extend inwardly to substantially the center of the beam, to an extended position, such as shown in FIG. 2, in which their external ends are each fitted into the support defined by shaft recesses 18. The arms are each locked in position with the body 1 of the beam by four thru-bolts 19 disposed vertically in pairs as shown in FIG. 4. Longitudinal apertures 21 are provided for allowing free movement for adjusting the position of the arms within the support defined by the recesses. The lower end of each arm is provided with a support plate which engages a rubber shoe 23 isolating the beam from the building. 
     The foregoing clearly shows the convenience in positioning such a beam. In the retracted position of the arms, its length is substantially less than the width of the elevator shaft so that it may be readily winched into position at the top of the elevator shaft. In this position, the arms may be extended into the shaft recesses and locked in position and the beam is thus supported with the arms resting on the isolating shoes. Labels 25 on the travel path of the arms indicate the permissible stress level at varying distances of arm extension. 
     It will be noted that other equipment may be mounted on the beam other than that described, such as a counterweight fixed point plate 27, to which end eyelet rods of the cables are secured and tools for fixing the guides in their final position, e.g. a string of cabin guides 29 and two strings of counterweight guides 31.