CH671757A5 - - Google Patents

Description

DESCRIPTION

The present invention relates to an elevator for transporting people, comprising a vertical sheath, a cabin arranged to circulate inside the sheath, means for guiding the cabin in the sheath, and a motor device installed in the sheath for circulate the cabin.

According to conventional techniques, elevators are installed in buildings inside a vertical shaft which is part of the structure of the building or which is rigidly linked to this structure so as to cooperate with it. Whether the sheath is made of concrete or of metal construction, it therefore constitutes a particularly heavy and expensive element. These disadvantages are particularly noticeable in relatively small buildings, such as family houses, and they lead the project manager to abandon most of the time the installation of an elevator. For similar reasons, the installation of an after-the-fact elevator in an existing building requires, in addition to the openings which must be made in the floors or slabs of the floors, the construction of a vertical shaft which, in its classic form , requires reinforcements of existing structures because of its weight. In addition, the connections between this sheath and the different floors or slabs of the floors are often difficult to achieve and costly.

Patent application FR-A-2187 663 describes for this purpose a rectangular metallic support sheath comprising angle posts 5 made of folded sheet metal, filling panels made of sheet metal and internal crosspieces fixed to the posts to support vertical guides for the cabin and counterweights. However, this construction remains relatively heavy and the presence of the crosspieces, which are essential for the stability of this structure, determines an excessive bulk of the sheath.

Consequently, the object of the present invention is to provide an elevator which makes it possible to remedy the abovementioned drawbacks and constructed in a manner light enough to allow its installation, in an existing building or under construction without requiring any reinforcement of the building structure.

For this purpose, the elevator according to the invention is characterized as indicated in claim 1. The dependent claims relate to advantageous embodiments of the invention.

Other characteristics of the invention and its advantages will emerge better from the description of various exemplary embodiments, given below with reference to the appended drawings, in which:

FIG. 1 is a view in vertical section of a first embodiment of an elevator according to the invention,

Figure 2 is a horizontal sectional view along line II-II of FIG. 1,

FIG. 3 is a detailed view of part of FIG. 2, on an enlarged scale.

FIG. 4 is a detail view showing another part of FIG. 2, on an enlarged scale.

Figure 5 is a horizontal sectional view along the line Y-V of FIG. 1,

Figure 6 is a vertical sectional view showing a locking mechanism of the elevator illustrated in FIG. 1,

FIGS. 7 and 8 are partial views in vertical section of another embodiment,

Figure 9 is a partial vertical sectional view of another embodiment, and Figure 10 is a horizontal sectional view along the line X-X of FIG. 9.

40 In the embodiment which is illustrated by FIGS. 1 to 6, this is an elevator connecting only two floors of a building, for example of a family house, the slab of ground floor 1, the slab of the first floor 2 and the ceiling of the first floor 3. The elevator has a vertical cylindrical-45 casing 4 which, for example, has an internal diameter of the order of 1 m and inside which an equally cylindrical cabin 5 circulates, provided for two people in the present case. An upper structure 6 of the sheath 4 contains a winch 7 with an electric motor 8, as well as an electric panel 9 (fig. 5) which is accessible from the outside and 50 which is mounted on hinges to allow access to the winch compartment.

The sheath 4 constitutes a self-supporting metal structure which rests on the slab of the ground floor 1 and which comprises several superimposed sections-4a, 4b and 4c, in addition to its upper structure 55 6. As shown more particularly in FIGS. 2 and 3, the walls of these sections are formed by sheet metal elements, preferably of light metal, which each cover a horizontal angle substantially equal to 90 °. In the case of fig. 2, these elements include a rear element 11 and two lateral elements 12 and 13 which 60 are bolted to each other, while the front quadrant is formed by a sliding door 14 mounted on rollers and rails (not shown) fixed to the elements 12 and 13, this door 14 having a cylindrical shape which allows it to be inserted between the sheath 4 and the cabin 5. The two longitudinal edges of the rear element 11, ss as well as the two rear longitudinal edges of the lateral elements 12 and 13, are bent at right angles inwards to be bolted to each other along two vertical joints 15 and 16, while the respective front edges of the side elements 12 and

3

671757

13 are folded outwards so as to define, on each side of the door 14, vertical boxes 17 and 18 reinforcing the stability of the sheath and also serving as housing for various equipment which will be described later. It is noted that the elements 11 to 14 can be easily shaped by rolling and folding and are therefore relatively inexpensive. In addition, their assembly is particularly easy, especially thanks to their low weight.

Fig. 3 shows the area of the vertical joint 15 on an enlarged scale. A vertical guide 20 formed by a straight plate of drawn steel is inserted between the folded longitudinal edges of the sheath elements 11 and 12, and the assembly is rigidly assembled by bolts 21. An identical guide 22 is fixed in the same way in the joint

16 and is arranged in a plane perpendicular to that of the guide 20. These two guides can be formed of several sections, but they extend in a substantially continuous manner over the entire height of the sections 4a, 4b and 4c of the sheath, in order to '' guiding the cabin. To this end, the cabin 5 comprises opposite each guide 20 and 22 a pair of slides 23 which are housed in a vertical joint of the structure of the cabin. This structure is made similar to that of the sheath, by means of three wall elements 24, 25 and 26 made of light metal sheet, the longitudinal edges of which are folded inwards. Those of them which are located opposite the joints 15 and 16 of the sheath are folded at right angles, while the respective front edges of the lateral elements 24 and 26 are folded so as to define inside the cabin of the vertical boxes 27 and 28 framing a cabin door 29. This cabin door is produced in a similar manner to that of door 14 of the sheath; it also opens by sliding between the cabin and the sheath.

As shown in fig. 3, the folded edges of the wall elements 24 and 25 of the cabin are assembled, for example by means of bolts 31, against a metal profile 32 which defines between them sufficient space to accommodate the slides 23. These slides are formed by pairs of elastic pads 33 which are applied against the opposite faces of the guide 20 with a certain prestressing force, for example 50 N per slide. Such a pad can be constituted for example by a plate of anti-friction material, mounted on a leaf spring fixed to the corresponding wall element 24, 25. This guide system comprising the two flat guides 20 and 22 perpendicular to one another. the other is particularly simple and inexpensive and provides precise, vibration-free guidance. In addition, the guides 20 and 22 are rigid enough to be used as support elements for a parachute device 34 (fig. 1) mounted on the cabin. For this purpose, they extend downwards to the element of the building which supports the lower part of the sheath, for example the slab 1 of the ground floor or a foundation of the building. As these steel sections are much more rigid in compression than the light metal wall elements, they absorb most of the emergency braking forces. According to a variant not shown, the flat guides 20, 22 can be replaced by T-profiles which are usually used for guiding elevator cars. The core of the profile then fulfills the same function as the flat guide, while its wings are bolted in an adjustable position on brackets fixed by the assembly bolts of the sheath elements 11, 12 and 13.

The intermediate section 4b of the sheath 4 is constituted substantially in the same way as the section 4a, except that the door is replaced by a fixed element bolted to the vertical boxes

17 and 18 of the adjacent elements. Of course, the length of the section 4b is determined as a function of the difference in level between the upper faces of the slabs 1 and 2, while the sections 4a and 4c have a standard length. Along its lower edge, the section 4b is provided with a flange 35 which is fitted onto the section 4a and which can be fixed thereto. In the example shown, the section 4c is mounted in the same way on the section 4b, a closure profile 36 being mounted on the slab 2 around the sheath 4, but without being integral with this sheath in the vertical direction. Thus, the weight of the elevator is absolutely not transmitted to slab 2 of the first floor.

Of course, if one wishes to support the slab 2 of the first stage the weight of the upper parts 4c and 6 of the sheath,

as well as the weight of the cabin 5 supported by the structure 6, the section 4c of the sheath can be fixed to the profile 36 and be slidably connected to the intermediate section 4b. The solution to be adopted can be chosen according to the resistance of the existing structures of the building. In any case, the total weight of the lift is relatively low, in particular thanks to the light construction of the shaft 4, so that it can be installed in an existing building without the need for reinforcements. On the other hand, we note that in the example shown, the only transformation to operate in the structure of the building, to install the elevator afterwards, consists in providing an opening 39 of relatively small dimension in the slab 2.

The electromechanical equipment of the elevator according to the invention is largely of known type. The cabin 5 is suspended from two roller chains 40 which are wound symmetrically on the winch drum 7. The chains 40 are connected to the cabin 5 by means of a spring device 41 associated with an overload switch and a reduced load switch, these switches having the effect of cutting off the power to the motor 8 respectively in the event of excessive extension of the spring due to exceeding the limit load in the cabin, or in the event of insufficient extension resulting from a load shedding of the cabin, for example in the event of its blockage. The control means for setting the cabin in motion and for stopping it on the desired floor are of the conventional type and need not be described here.

Fig. 4 illustrates means for driving and locking the respective doors 14 and 29 of the sheath and of the cabin. The light metal sheet panel constituting the door is folded at right angles along a vertical edge, to form a respective wing 44, 45 on which is fixed a handle 46, 47 to allow the manual action of the door. Two vertical tabs 57 are fixed on the inside face of the door 14 of the sheath, to cooperate with a similar tab 58 which is fixed on the outside face of the door 29 of the cabin, so as to engage between the two tabs 57 when the cabin stops on the corresponding floor. Thanks to the coupling thus produced between the two doors, they can be made to slide together by acting on the handle of a single door. On the wing 44, 45 of the door, for example in its upper part, is fixed a respective locking shoe 48, which is provided with an orifice 49 intended to receive the lock of a conventional electromagnetic device, serving to block the door in the closed position and to release it only on the floor where the cabin is stopped. This device is housed in the respective vertical boxes 18 and 28 of the sheath and of the cabin. It further comprises an electrical end-of-travel contact of the door, actuated by the shoe 48. FIG. 4 also shows that the boxes 17, 18, 27 and 28 can be used to accommodate equipment such as electric cables 52 and boxes 53 and 54 containing the elevator control buttons. For maintenance, these boxes can be opened by dismantling a respective cover 55, 56 fixed by screws.

To allow maintenance personnel to work in complete safety, it is compulsory to provide in each lift, at each end of the shaft or the cage, a space always remaining free between the extreme position of the cabin and the fixed obstacles. closer, to prevent a worker in the sheath from being crushed by an unwanted movement of the cabin. In general, the safety regulations require, for this free space, a minimum height A, for example equal to 700 mm. In conventional elevators, this requirement is met by raising the upper structure of the elevator relative to the upper position of the car, and the creation of a pit below the extreme lower position of the car. In order to avoid these relatively expensive and cumbersome constructions, the elevator shown in FIGS. 1 to 6 is equipped with a car blocking system in order to guarantee the maintenance of a free space of height A at each end of the shaft when the elevator is in service or repair

5

10

15

20

25

30

35

40

45

50

55

60

65

671,757

tion. This system essentially comprises a main switch 60 (fig. 1), housed in the upper structure 6, and four locking devices 61 arranged in pairs in the vertical boxes 17 and 18 of the sheath, respectively at distances A from fixed obstacles located at the top and bottom of the sheath 4. The main switch 60 has three positions, namely: de-energized; in service; in Review. This last position makes it possible to operate the elevator, but only after the locking devices 61 have been engaged.

Fig. 6 shows by way of example an embodiment of a locking device 61, housed in a vertical box 17 or 18 of the lower section 4a of the sheath 4. A pivoting pawl 62 is mounted on a horizontal axis 63 fixed to the wall of the sheath, opposite an opening 64 formed in this wall. In the figure, the pawl 62 is shown in solid lines in its locking position, in which it abuts against the lower edge 65 of the cabin 5, thereby stopping this cabin at a distance A from the bottom of the sheath. The pawl is fitted with a stop 66 pressing against the wall of the sheath 4. This position corresponds to the “overhaul” position of the main switch 60. The other position 62a of the pawl 62 has been shown in broken lines, corresponding to the “in service” position of the main switch 60. In this position, the pawl 62 is fully retracted inside the box 17, 18. The pivoting of the pawl 62 from one position to the other and its maintenance are ensured by an electromagnetic jack 63 which is also housed in this box and which is provided with appropriate limit switches giving receipt of the correct position of the pawl 62.

In cases where the safety regulations do not allow the use of a blocking system of the type described above, the elevator shaft can be extended up and down according to an embodiment illustrated by fig. 7 and 8, so as to respect a free space of height A, between the fixed obstacles existing in the ends of the sheath and the normal extreme positions of the cabin 5, respectively opposite the lower floor and the upper floor . For this purpose, fig. 7 shows that an additional intermediate section 4d is interposed between the upper section 4c and the upper structure 6, in order to maintain the latter at a height A above the upper position 5b of the cabin. In the present case, an additional opening 70 had to be provided in the ceiling 3 of the first floor of the building. The structure of the intermediate section 4d and its fixing means are similar to those of the intermediate section 4b.

With reference to fig. 8, the sheath is extended downward, through an opening 71 made in the slab 1 of the ground floor, by a section 4e provided with a bottom 72 located at a vertical distance A from the extreme lower position of the floor from the cabin. Preferably, the section 4e is suspended from the section 4a of the sheath, which rests on the slab by means of a metal section 73 fixed on its periphery. From the point of view of electromechanical equipment, the solution illustrated in FIGS. 7 and 8 is simpler than the solution described above. However, it is more expensive when installing the elevator in an existing building.

Figures 9 and 10 show an alternative embodiment of an elevator according to the invention, in which the motor device is hydraulic. The elevator shaft 4 is substantially identical to that which has been described above, except that it does not have an upper structure 6. In this case, the car 75 is supported and driven by a hydraulic cylinder 76 of known type, mounted on a base 77 housed in a lower section 4f of the sheath 4. In the example shown, this section 4f is supported by a flange 78 integral with the sheath 4 and resting on the slab 1 of the ground - floor. It should however be noted that, if this slab was not able to support the weight of the elevator, the bottom of the sheath 4 could also rest on the ground by means of an appropriate support 79.

Unlike the previous example, the cabin 75 has a rear wall 81 which is substantially planar, while its side walls 82 and 83 are arcuate. This provides sufficient space for the cylinder 76 inside the sheath. The top of the cabin 75 is provided with a console structure 84 to be supported by the jack 76. Of course, the motor device also includes a group formed by a hydraulic pump driven by an electric motor (not shown), this group can be placed at a certain distance from the elevator, for example in a room in the basement. The control members are of the conventional type and are therefore not described here. It should also be noted that the hydraulic motor device can be of direct action, according to FIG. 9, or indirectly, by driving the cabin through chains or cables passing over pulleys secured to the jack.

Compared to the winch-driven elevator described above, this hydraulic-driven embodiment has certain advantages in addition to the conventional advantages of hydraulic elevators, in particular an easy speed adjustment. In the elevator according to the invention, the main advantage is that the weight of the motor device, of the car and of the payload is entirely supported by the base of the sheath 4. This can thus avoid overloading the structures of the floors building superiors. On the other hand, the height necessary for the base 77 of the jack automatically ensures sufficient safety space between the cabin and the bottom of the sheath. Finally, the fact that the electric motor can be arranged remotely ensures quieter operation.

The example shown in Figures 9 and 10 further includes doors with two leaves, which offers greater width for access to the cabin. For this purpose, the sheath 4 has at each landing a door having two symmetrical elements 86 and 87 which are driven symmetrically by a common pinion acting on respective racks, to move according to the double arrows by sliding between the walls of the sheath 4 and the cabin 75. The latter has a double door formed of similar symmetrical elements 88 and 89 operating in the same way.

It can also be noted that the slides 23 described above are replaced in the present case by guide members 90 each comprising a pair of rollers mounted outside of the cabin 75, to bear against two opposite faces of the vertical guides 20 attached to the sheath. This device saves space inside the cabin.

Of course, the embodiments described above by way of example are not limiting and various modifications or variants obvious to a person skilled in the art can be carried out without departing from the scope of the invention. In particular, an elevator according to the invention can be provided to serve more than two floors.

4

5

10

15

20

25

30

35

40

45

50

55

R

3 sheets of drawings

Claims (9)

671,757 2 1. Elevator for transporting people, comprising a vertical sheath, a cabin arranged to circulate inside the sheath, means for guiding the cabin in the sheath, and a motor device installed in the sheath to circulate the cabin, characterized in that the sheath (4) has a cylindrical shape, in that this sheath is formed of successive longitudinal sections (4a to 4e) in metal construction, in that each of these sheath sections (4a to 4e) consists of bent sheet metal elements (11,12,13) which are rigidly assembled to each other along their longitudinal edges bent at right angles, and in that the guide means comprise at least two vertical guides (20 ) consisting of steel profiles fixed to the folded longitudinal edges of the sheath elements. 2. Elevator according to claim 1, characterized in that said elements of the sheath extend over a horizontal angle substantially equal to 90 °. 3. Elevator according to claim 2, characterized in that the vertical guides (20) are disposed respectively in perpendicular radial planes and in that guide members (23) disposed on the car are applied against two opposite faces of each guide (20). 4. Elevator according to claim 3, characterized in that said guide members are slides comprising elastic pads (33) which exert a prestressing force against said opposite faces of each guide (20). 5. Elevator according to any one of claims 1 to 4, characterized in that said sheet metal elements (4a to 4e) are made of light metal. 6. Elevator according to claim 1, characterized in that the sheath comprises on each floor at least one sliding door (14) of arcuate shape, this door being arranged to slide between the sheath (4) and the cabin (5), and in that the edges of the sheath elements arranged on either side of this door are folded outwards so as to define a vertical box (17,18). 7. Elevator according to claim 6, characterized in that the cabin (5) has a substantially cylindrical shape. 8. Elevator according to claim 7, characterized in that the walls of the car are formed of elements (24 to 26) made of light metal sheet, the vertical edges of which are folded to be assembled with the edges of the adjacent elements. 9. Elevator according to claim 7, characterized in that the cabin is equipped with at least one sliding door (29) of arcuate shape, arranged to slide between the sheath and the cabin.