MEDICAL SUSPENSION DEVICE COMPRISING AN OFFSET ARM

Abstract

A suspension device making it possible to suspend items of equipment (7, 7) under a support structure comprises an anchor bracket (2) designed to be anchored axially to the support structure, two distribution arms (9, 10, 9, 10) that are adjustable up and down and that are designed to carry the items of equipment (7, 7), and that are connected to the anchor bracket (2) via pivot articulations (11, 11), each of which is offset from the anchor bracket (2) via a stationary offsetting arm (8, 8; 8).

Claims

1. A suspension device making it possible to suspend items of equipment under a support structure, said suspension device comprising an anchor bracket configured to be anchored axially to said support structure, two distribution arms that are adjustable up and down and that are configured to carry said items of equipment, each distribution arm comprising a suspension arm having one end articulated to said anchor bracket via a pivot articulation making it possible for said suspension arm (9, 9) to move in rotation in a horizontal plane, and a spring arm articulated to the other end of said suspension arm so as to be inclinable vertically relative to said suspension arm, the other end of said spring arm carrying a respective item of equipment, wherein each pivot articulation of a suspension arm is disposed at the end of an offsetting arm so as to be offset horizontally by a certain offset distance relative to said axis of said anchor bracket, which length is greater than a length of said suspension arm, and in that it further comprises connection means that secure said offsetting arm in stationary manner relative to said axis of said anchor bracket in such a manner that it remains stationary relative to said anchor bracket while said distribution arm is pivoting in said horizontal plane.

2. The suspension device according to claim 1, wherein the suspension device comprises two offsetting arms that are in mutual alignment on either side of a central point of said anchor bracket.

3. The suspension device according to claim 2, wherein said equipment is medical equipment.

4. The suspension device according to claim 1, wherein said equipment is medical equipment.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] The present invention can be better understood and other advantages appear on reading the following detailed description of embodiments given by way of non-limiting example and with reference to the accompanying drawings, in which:

[0016] FIG. 1 is a diagrammatic view of a prior art suspension device in an operating theater;

[0017] FIG. 2 is a diagrammatic view of a suspension device of the invention in an operating theater;

[0018] FIGS. 3A and 3B are diagrammatic views respectively showing first and second configurations of the suspension device of the invention;

[0019] FIG. 4 is a diagrammatic perspective view of the suspension device of the invention in an operating theater; and

[0020] FIG. 5 is a diagrammatic perspective view of another embodiment of the suspension device of the invention in an operating theater.

DESCRIPTION OF AN EMBODIMENT

[0021] FIG. 1 shows a prior art suspension device in an operating theater 1 with an anchor bracket 2 anchored to a support structure 3 or ceiling of the operating theater, above an operating table 4.

[0022] During a medical operation, the medical staff usually align the center of the operating table 4 so that it is vertically in register with the anchor bracket 2.

[0023] FIG. 1 shows two adjustable distribution arms, each of which is articulated relative to the anchor bracket 2, and each of which carries medical equipment 7, 7, namely medical lighting in this example, at its free end.

[0024] Instead of medical lighting 7, 7, any other electronic system could be carried, e.g. a monitoring and control system including a screen and a camera. The equipment could also be a fluid dispensing system, e.g. an intravenous drip, etc.

[0025] Conventionally, each distribution arm comprises a suspension arm 5, 5 connected at one end to the anchor bracket 2 via a pivot articulation 5A, 5A and at the other end to a spring arm 6, 6 that, in this example, carries, at its free end, a lighting dome 7, 7 designed to form an illumination spot on a zone of an operative field that, in this example, is on the operating table 4.

[0026] The vertical axis XX is used to represent the central axis of the anchor bracket 2, which central axis is also the axis of the pivot articulations 5A, 5A at the ends of the suspensions arms 5, 5.

[0027] As indicated above, with that type of suspension device, collisions can take place between the two spring arms 6, 6 of the two distribution arms or between a spring arm 6, 6 and a suspension arm 5, 5 of the same distribution arm, or of the other distribution arm.

[0028] In FIG. 1, circles in dashed lines indicate the collision zones in which collisions are most frequent.

[0029] From FIG. 1, it can be understood, for example, that the spring arm 6 interferes with the suspension arm 5 of the same distribution arm because the highest point of the spring arm 6 is higher than the lowest point of the suspension arm 5. The lighting dome 7 can thus also collide with the suspension arm 5.

[0030] FIG. 2 shows the suspension device of the invention in place in the operating theater 1 with the operating table 4 aligned vertically with the anchor bracket 2 on its central axis XX.

[0031] In the suspension device of the invention, a pivot articulation 11, 11 of a distribution arm is offset from the anchor bracket 2 (from its central axis XX) via a stationary offsetting arm 8, 8 that is interposed between the anchor bracket 2 and the articulation in question. A first end of the offsetting arm 8, 8 is connected to the anchor bracket 2, while the other end is connected to the suspension arm 9, 9 via the pivot articulation 11, 11.

[0032] FIG. 2 shows two offsetting arms 8, 8 in mutual alignment on either side of a central point of the anchor bracket 2.

[0033] During the medical operation, each offsetting arm such as 8 or 8 is held stationary relative to the anchor bracket 2 while the distribution arm is pivoting.

[0034] As shown in FIG. 2, each distribution arm includes a suspension arm 9, 9 connected to the anchor bracket 2/offsetting arm 8, 8 via the pivot articulation 11, 11, and a spring arm 10, 10 mounted to pivot at one end of a suspension arm 9, 9 and having its other end free and carrying equipment, namely, in this example shown in FIG. 2, a medical lighting dome 7, 7.

[0035] The stationary connection between an offsetting arm 8, 8 and the anchor bracket 2 may be of the sleeve/collar type, with disassembly and heightwise adjustment being possible before and after a medical operation. This stationary connection holds the offsetting arm 8, 8 in a position in which it is stationary relative to the anchor bracket 2 while the distribution arm is moving.

[0036] Such an offsetting arm 8, 8 is entirely suitable for being installed on an existing anchor bracket 2, in place of a suspension arm.

[0037] Instead of having two offsetting arms 8, 8 in mutual alignment, said two offsetting arms 8, 8 could be disposed in a V-shaped configuration at a fixed angle. In either configuration, they could also be superposed relative to each other.

[0038] The invention thus extends to configurations in which the suspension device has more than two distribution arms having pivot articulations 11, 11 offset from the anchor bracket 2.

[0039] In FIG. 3A, the two suspensions arms 9, 9 having the two spring arms 10, 10 are deployed in a 9 o'clock 3 o'clock configuration under the offsetting arms 8, 8.

[0040] The two lighting domes 7, 7 face each other under the offsetting arms 8, 8.

[0041] As can be seen in FIG. 3A and also in FIG. 2, each suspension arm 9, 9 is shorter than an offsetting arm 8, 8.

[0042] In this situation, there is no risk of collision between the two suspension arms 9, 9, and, in addition, it is possible to move the lighting dome 7, 7 over a larger zone than with a conventional suspension device while leaving fewer zones of singularities over the operative field.

[0043] In addition, each distribution arm (suspension arm 9, 9 with spring arm 10, 10) is shorter than an offsetting arm 8, 8, and therefore the spring arms 10, 10 cannot collide with each other because each spring arm 10, 10 with a lighting dome 7, 7 has its own zone of movement above the operative field.

[0044] There is therefore no risk of collision between a spring arm 10, 10 and a suspension arm 9, 9 or between the lighting domes 7, 7.

[0045] FIG. 3B shows a suspension device of the invention having two distribution arms, with two offsetting arms 8, 8 in mutual alignment, each offsetting arm 8, 8 being longer than a suspension arm 9, 9. However, as can be seen in FIG. 3B, the spring arms 10, 10 cross over and face each other.

[0046] With this arrangement, each lighting dome 7, 7 can be positioned on either side of the operating table 4, or at the feet or at the head of a patient lying on the table.

[0047] FIG. 4 is a diagrammatic perspective view of the suspension device of the invention having two offsetting arms 8, 8.

[0048] As indicated above, each offsetting arm 8, 8 is connected in stationary manner to the anchor bracket 2. The connection may be disassemblable or adjustable, e.g. adjustable heightwise along the axis XX. FIG. 4 shows two connections offset from the centre of the bracket 2 and of the sleeve/collar type.

[0049] Each pivot articulation 11, 11 that connects a suspension arm 9, 9 to an offsetting arm 8, 8 may also be of the sleeve/collar type or of the hub type with it being possible to adjust the connection vertically along the axis XX.

[0050] The articulation 12, 12 between a suspension arm 9, 9 and a spring arm 10, 10 makes it possible to incline the suspension arm 9, 9 upwards or downwards, and thus to move the dome 7, 7 further away from or closer to the operating table 4. Said articulation 12, 12 may also be a pivot articulation having a horizontal pivot axis.

[0051] Preferably, in order to avoid the risks of collision between the two suspension arms 9, 9, said suspension arms 9, 9 should not be able to reach the central axis XX of the anchor bracket 2. Thus, each suspension arm 9, 9 is shorter than an offsetting arm 8, 8.

[0052] In this example, the equipment is a lighting dome 7, 7 with a lighting axis arranged at the center of the lighting dome 7, 7. In order to cover the entire zone of use of the operative field, the lighting axis of the lighting dome 7, 7 should preferably be able to be spaced apart from the axis XX of the anchor bracket 2 by about 800 millimeters (mm)300 mm.

[0053] The offsetting arm 8, 8 preferably has a length equivalent to at least the sum of the length of the spring arm 10, 10 and of the lighting dome up to its lighting axis.

[0054] It should be noted that the axis XX of the anchor bracket 2 of FIG. 4 is free to receive other equipment to be suspended.

[0055] It can be understood that, in accordance with the invention, adding an offsetting arm 8, 8 to the suspension device artificially offsets the equipment 7, 7 in an operating theater 1.

[0056] This artificial offsetting of the equipment 7, 7 is compatible with the anchoring system that is centralized in an operating theater 1.

[0057] This artificial offsetting makes it easy and inexpensive to configure an operating theater 1 with suspension devices as if they were in a position of the 9 o'clock 3 o'clock type: a single anchoring point is necessary, and rotary articulations are omitted.

[0058] This arrangement with artificial offsetting offers all of the advantages procured with a 9 o'clock 3 o'clock installation. These known advantages are that collisions are limited, the items of equipment 7, 7 are moved into positions that cannot be reached by prior art suspension devices centered on the operating table 4, thereby limiting the singularities around the zone of use.

[0059] This artificial offsetting of the equipment 7, 7 in an operating theater 1 is compatible with laminar flows initially designed for centralized anchoring.

[0060] The suspension device of the invention makes it possible to reduce the forces related to manipulating the items of equipment 7, 7 fastened to the spring arms 10, 10 as is known with suspension devices in the 9 o'clock 3 o'clock position.

[0061] Naturally, the present invention is in no way limited to the above description of one of its embodiments, which can undergo modifications without going beyond the ambit of the invention.

[0062] For example, in another embodiment, the offsetting arms 8, 8 in mutual alignment on either side of a central point of an anchor bracket 2 as shown in FIG. 2 could be replaced with a single offsetting arm 8 fastened in its middle via a single connection to a central point of the anchor bracket 2 as shown in FIG. 5. The fastening may be of the sleeve/collar type so that it is also possible to mount, to remove, and to adjust the height of the single offsetting arm 8 before and after a medical operation.