The present application claims priority of German Patent Application No. 10 2006 004 126.7, filed on Jan. 25, 2006.
The invention generally relates to surgical armrests.
A surgical armrest is used to support the arm of a surgeon or of a surgical assistant during an operation, in order to increase the precision of the surgeon's hand movements and to reduce fatigue. In view of the fact that a surgical intervention can last several hours and that the surgical personnel perform such an operation standing up, an armrest can contribute to ensuring that the precision of the manoeuvres performed by the operating surgeon does not decrease over time.
An armrest known from document U.S. Pat. No. 5,074,501 comprises an arm support which is secured on a carrying structure for the arm support. The arm support comprises a base and two pivot arms which together form a parallelogram. The two pivot arms are secured on the base in each case about a horizontally extending pivot axis, the two pivot axes of the two pivot arms being spaced apart from one another in the vertical direction.
The arm support is connected to the two pivot arms at their ends remote from the base. The height of the arm support is changed by the pivot arms being pivoted up or down.
The two pivot arms of the known armrest are assigned a control mechanism which makes it possible to pivot the pivot arms up or down and thus change the height of the arm support and to fix the pivot arms in a defined pivoting position and thus fix the arm support at a defined height. The control mechanism comprises a bar which moves at least in its longitudinal direction during pivoting of the two pivot arms.
On the upper and lower pivot arm, the bar is assigned securing clamps with which the movement of the bar can be blocked by tightening of the clamps, as a result of which the pivoting of the two pivot arms is blocked and the arm support can thus be secured at a defined height.
Such a control mechanism for lifting and lowering and for securing the arm support has the disadvantage that the securing clamps cannot be actuated by the hand of that arm resting in the arm support. For surgical applications in which the height of the arm support has to be adjusted frequently during an operation, this known armrest is only suitable to a limited degree because it is awkward to handles. In addition, it does not permit a controlled lowering of the arm support. Instead, there is a danger of the arm support dropping in an uncontrolled manner after the securing clamps have been released.
By contrast, the document EP-A-1 486 178 discloses a surgical armrest which, compared to the known armrest described above, has the advantage that the lifting, lowering and fixing of the armrest can be carried out using the arm that is received in the arm support. The control mechanism of this known surgical armrest comprises a force switch which, by means of different forces applied by the arm received in the arm support, switches an electric motor on and off, the electric motor driving a bar which allows the pivot arm to be pivoted up or down as a result of the bar being driven in or out.
The disadvantage of an electromechanical control mechanism of this kind is that a power supply is needed via a power cable. However, power cables constitute an obstacle in an operating theatre. In addition, in the event of a defect of the electric motor, for example due to overloading of the electric motor, the control mechanism does not function. If such a defect occurs during an operation, the operation has to be continued without an armrest.
In addition to drive mechanisms comprising electric motors, it has also been proposed, for example in document U.S. Pat. No. 6,102,344, to use hydraulic or pneumatic control mechanisms for adjusting the height of the arm support for surgical armrests. Like control mechanisms with electric motors, hydraulic or pneumatic control mechanisms have the disadvantage that they are not suitable for sterilization in an autoclave. Surgical instruments and appliances have to satisfy particularly stringent demands concerning their cleaning and sterilization in particular. A safe method of sterilization is the sterilization of instruments and appliances in an autoclave in which temperatures of over 120° C. and high steam pressures prevail. Electromotive, hydraulic or pneumatic parts cannot withstand these conditions.
A surgical armrest whose control mechanism operates mechanically is therefore desirable.
However, the armrest known from the document mentioned at the outset, and having a mechanically operating control mechanism, is, as has already been described, disadvantageous in terms of the lifting, lowering and fixing functions of the arm support.
The object of the invention is therefore to provide a surgical armrest having a control mechanism that is improved in terms of the aforementioned functions.
According to the invention, a surgical armrest is provided comprising an arm support and a carrying structure for carrying the arm support. The carrying structure has a base and at least one pivot arm having a first end articulated on the base so as to pivot about an at least approximately horizontal pivot axis, and a second end connected to the arm support, such that a pivoting of the at least one pivot arm about the pivot axis causes a height adjustment of the arm support. A control mechanism is provided for controlling the at least one pivot arm for alternately permitting a fixing and a pivoting of the at least one pivot arm in downward direction and in upward direction. The control mechanism has at least one bar which is movable, at least in a longitudinal direction of the bar, upon pivoting of the at least one pivot arm. The control mechanism further has a freewheel coupling having a first coupling element and a second coupling element, the first coupling element being driven by the bar and being freely movable relative to the second coupling element upon an upward movement of the at least one pivot arm, and, upon a downward movement of the at least one pivot arm, driving the second coupling element, and the second coupling element being braked by means of at least one brake element.
Accordingly, the control mechanism of the surgical armrest according to the invention is provided with a freewheel coupling that interacts with the bar in such a way that it ensures a different speed of the at least one pivot arm in the downward direction and in the upward direction. For this purpose, the freewheel coupling comprises a first coupling element which is driven by the bar during each downward and upward movement of the at least one pivot arm. During an upward movement of the at least one pivot arm, the first coupling element is freely movable relative to the second coupling element, such that the pivot arm and, consequently, the arm support can move smoothly. By contrast, during a downward movement of the at least one pivot arm for lowering the arm support, the first coupling element drives the second coupling element, and, because the latter is braked by means of a brake element, the downward movement of the at least one pivot arm is slower compared to the upward movement. This prevents the arm support from dropping in an uncontrolled manner, since the downward movement is attenuated by the brake element.
Such a freewheel coupling according to the invention can advantageously be composed of parts that withstand treatment in an autoclave, while permitting improved operating safety and maneuvring compared to the known armrest with mechanical control mechanism.
In a preferred embodiment, the first coupling element and the second coupling element are in connection with one another via a form-fit engagement during the downward movement of the at least one pivot arm, whereas, during an upward movement of the at least one pivot arm, the form-fit engagement is cancelled by the second coupling element being spaced away from the first coupling element.
The advantage of this measure is that the different running characteristics of the pivoting of the at least one pivot arm in the upward and downward direction is effected simply by a spacing of the second coupling element from the first coupling element, by means of which the form-fit engagement between the first coupling element and second coupling element is cancelled. The form-fit engagement between the first coupling element and second coupling element during the downward movement of the at least one pivot arm ensures that no slip occurs between the first coupling element and second coupling element during this movement and thus ensures the braking action of the second coupling element for a controlled downward movement of the at least one pivot arm.
In another preferred embodiment, the first coupling element and the second coupling element are rotatable about a common rotation axis and, on their end faces directed toward one another, have a complementary oblique toothing which, in one direction of rotation of the first coupling element, causes a pushing-away of the second coupling element and, in the opposite direction of the first coupling element, causes a rotational movement of the second coupling element.
In this embodiment, the first coupling element and the second coupling element are accordingly arranged one after the other in respect of the common rotation axis, which reduces the overall space of the freewheel coupling. The complementary oblique toothing on the end faces constitutes a structurally advantageous and simple measure for creating the form-fit engagement with the second coupling element in one direction of rotation of the coupling element, whereas, in the reverse direction of rotation of the first coupling element, its oblique toothing automatically pushes away the second coupling element without the need for manual intervention, in order to ensure the free-running of the first coupling element relative to the second coupling element.
It is also preferable if the second coupling element is axially movable in the direction of the rotation axis and is pretensioned in the direction toward the first coupling element.
This measure has the advantage that after each upward movement of the at least one pivot arm, the second coupling element automatically comes into form-fit engagement again with the first coupling element, as a result of which the brake is activated again on completion of each lifting of the arm support.
In another preferred embodiment, the common rotation axis extends at least approximately perpendicular to the axial direction of movement of the bar.
The advantage of this measure lies in the space-saving construction, because the freewheel coupling in this arrangement is arranged transverse to the at least one pivot arm.
In another preferred embodiment, the bar drives the first coupling element via a gear arrangement.
The advantage of this measure is that, with a suitable configuration, a gear arrangement can provide a force transmission necessary and adapted for the driving of the freewheel coupling via the bar.
It is also preferable if the gear arrangement has at least one toothed wheel that meshes with a toothing of the bar.
The configuration of the gear arrangement with at least one toothed wheel is advantageous in terms of the ability to autoclave the control mechanism and thus the whole armrest.
It is also preferable if the gear arrangement comprises at least two toothed wheels that mesh with one another and preferably have a different diameter.
The use of at least two meshing toothed wheels, of which one meshes with the toothed bar and the other is connected to the first coupling element, has the advantage that a suitable speed of rotation transmission ratio can be selected by virtue of the different diameters of the two toothed wheels. For example, one toothed wheel with a greater diameter can mesh with the toothing of the bar, and the second toothed wheel, which for example sits on the shaft of the first coupling element, has by contrast a smaller diameter.
In another preferred embodiment, the braking action brought about by the brake element is adjustable.
This measure has the advantage that the braking action can be adapted to the particular requirements of the person using the armrest. In particular, in the event that the downward movement of the arm support is effected or assisted by the force of a spring, the braking action can be adapted to the spring force in order to set a desired speed of lowering of the arm support.
In another preferred embodiment, the brake element is made from an elastic material, and a clamping device is operatively connected to the brake element in order to vary the contact pressure of the brake element on the second coupling element.
This measure constitutes a structurally advantageous and simple possibility of adapting the braking action of the brake element to the second coupling element. For example, the clamping device can preferably have a clamping jaw and an adjustment member for the clamping jaw. The elastic material used for the brake element is preferably an autoclavable material, for example silicone.
In another preferred embodiment, the bar is assigned at least one spring which is tensioned during an upward movement of the at least one pivot arm and is relaxed during a downward movement.
The advantage of this measure is that the bar is pretensioned in the downward direction of the pivoting movement of the at least one pivot arm. The force of the spring is therefore counteracted in the upwardly directed pivoting movement of the at least one pivot arm and, thus, for the lifting of the arm support. However, the pretensioning of the bar should not be so great that the upward movement is slow. The pretensioning of the bar by means of a spring in the downward direction has the advantage that, after a catch for the bar is released, the arm support lowers automatically, but in a manner controlled by the braking action of the freewheel coupling.
For this purpose, it is also preferable if the at least one spring is configured such that the at least one pivot arm is pivoted in the downward direction by the force of the spring counter to the braking action generated by the brake element.
The pretensioning of the spring is preferably adjustable.
In a preferred embodiment, provision is also made that the carrying structure comprises at least one second pivot arm which extends at least approximately parallel to the first pivot arm and at one end is articulated on the base about a pivot axis spaced vertically apart from the pivot axis of the first pivot arm and at the other end is connected to the arm support, and that the bar is partially received in a cylinder so as to be movable relative to the latter, the cylinder being secured on the second pivot arm.
In this embodiment, the carrying structure of the surgical armrest according to similarly to the known armrest mentioned at the outset. Such a parallelogram structure of the pivot arms increases the overall stability of the armrest, particularly when the control mechanism, which includes the bar and cylinder, is disposed directly between the two pivot arms. In the context of the invention, however, it is also conceivable to use just one pivot arm, and to secure the bar on the base via the cylinder.
In another preferred embodiment, the bar is provided with a releasable catch which blocks the bar so that it is axially immovable and then frees it after release.
This measure advantageously increases the operating safety of the surgical armrest, since the catch ensures that undesired lowering of the arm support is avoided, by means of the catch blocking the axial mobility of the bar and thus the pivotability of the at least one pivot arm. In this way, the person operating the armrest can support himself safely on the arm support without any risk of the arm support dropping. In this embodiment, the arm support can be lowered only after the catch has been released.
It is also preferable if the catch is formed by a bolt which has a passage for the bar, the bolt being able to be moved about a tilt axis into a first tilt position, in which the bar extends obliquely through the passage and is thus clamped on the passage, and into a second tilt position in which the bar extends substantially perpendicularly through the passage and is thus axially movable.
The advantage of this embodiment of the releasable catch is that the bar can be blocked steplessly relative to the adopted height of the arm support. In this way, the arm support can also be arrested at any intermediate height between a lowermost position and a highest position.
It is also preferable here if the arm support is movable relative to the at least one support arm, and if the catch is connected to the arm support in such a way that, by slight lifting of the arm support relative to the at least one pivot arm, the catch is transferred from its blocked position into the release position, and, by slight lowering of the arm support relative to the at least one pivot arm, is transferred into the blocked position.
The advantage of this measure is that the catch can be released by simple maneuvring, namely by the arm support being raised slightly. The catch is activated simply by slight lowering of the arm support relative to the at least one pivot arm, which is already done largely automatically by the force of gravity of the arm support. Preferably, the catch can additionally be pretensioned into the blocked position.
In another preferred embodiment, the arm support is designed in such a way that it allows the arm support to be lifted by the same arm that is resting on the arm support.
The advantage of this measure is that the catch can also advantageously be released using the arm that is resting in the arm support. In this way, complete use of all the degrees of freedom of the arm support is possible using the arm that is resting on the arm support, without the user needing the hand of this arm or of the other arm to actuate the surgical armrest. It is therefore possible to control all movements of the arm support using the arm received in the arm support.
In a structurally simple embodiment of the arm support, the latter is designed as a substantially C-shaped shell, such that even the top face of the arm received in the arm support is at least partially enclosed by the arm support. The C-shaped design also has the advantage that the arm can be inserted from the side into the arm support.
Further advantages and features will become apparent from the following description and from the attached drawing.
It will be appreciated that the aforementioned features and those still to be explained below can be used not only in the respectively cited combination, but also in other combinations or singly, without departing from the scope of the present invention.
An illustrative embodiment of the invention is shown in the drawing and is described in more detail below with reference to said drawing, in which:
a) and b) each show two coupling elements of a freewheel coupling of the armrest in
a) and b) show longitudinal sections of the freewheel coupling of the armrest in
a) and b) show further details of the surgical armrest in
a) and b) show the surgical armrest in
a) and b) show the surgical armrest, with some parts being omitted compared to
a) and b) show further details of the surgical armrest in
In
The armrest 10 comprises generally an arm support 12 and a carrying structure 14 for the arm support 12.
The carrying structure 14 has a base 16 which, in the illustrative embodiment shown, has a stem 18 which is used for mounting the armrest 10 on a stand (not shown) or on an operating table (not shown). At the top of the stem 18, the latter is connected to a carrying block 20 which in turn carries at least one carrying arm or, in the illustrative embodiment shown, four carrying arms 22, 24, 26 and 28. In the illustrative embodiment shown, the carrying arms 22 to 28 are immovable relative to the carrying block 20, but they could also be mounted on the carrying block 20 so as to pivot about substantially horizontal pivot axes, so as to permit a rough preliminary setting of the height of the arm support 12.
The base 16 can in particular be rotatable about a substantially vertical axis 30, such that the arm support 12 can be pivoted in a substantially horizontal plane according to the set height.
At the ends of the carrying arms 22 to 28 remote from the carrying block 20, the base comprises a strut 32 which extends substantially vertically and on which the four carrying arms 22 to 28 are secured.
The carrying structure 14 additionally comprises at least one pivot arm or, in the illustrative embodiment shown, four pivot arms 34, 36, 38, 40, which together form a parallelogram structure.
With their ends directed toward the carrying arms 22 to 28, the pivot arms 34 to 40 are articulated so as to pivot in each case about an at least approximately horizontal pivot axis, specifically on the strut 32 of the base 16. the pivot arms 34 and 38 extend in this case parallel to one another and are articulated on the base 16 so as to pivot about a common pivot axis 42, and the pivot arms 36 and 40, which also extend parallel to one another, are pivotable about a pivot axis 44 that is vertically spaced apart from the pivot axis 42.
At their end remote from the pivot axes 42 and 44, respectively, the pivot arms 34, 38 and 36, 40 are connected to the arm support 12. In the illustrative embodiment shown, the arm support 12 is secured, by means of a substantially vertically disposed bearing element 46, on a likewise substantially vertically disposed strut 48, to which the ends of the pivot arms 34 to 40 remote from the pivot axes 42 and 44 are also connected in an articulated manner at axes 50 and 52.
The arm support 12 can be rotated about an axis 53, preferably through 360 degrees.
The arm support 12 is adjusted upward or downward by a pivoting of the pivot arms 34 to 40 about the pivot axes 42 and 44 in the upward or downward direction. To ensure a lifting of the arm support 12, a controlled lowering of the arm support 12 and a fixing of the arm support 12 in a selected height position, a control mechanism 54 is provided, which will be described below.
Referring first to
According to
At least one spring 66 is also arranged in the cylinder 64. The pretensioning of the spring 66 can be adjusted and set by means of an abutment 67 which is connected to one end 69 of the bar 56, preferably via a thread arrangement.
During a pivoting of the pivot arms 34 to 40 about the pivot axes 42 and 44, the bar 56 executes (in addition to a tilting movement) an axial movement, oriented in its longitudinal direction, relative to the cylinder 64. This longitudinal movement is depicted in
The cylinder 64 is connected to the carrying arms 36 and 40, specifically via a bow-shaped element 70 (see
According to
The control mechanism 54 also comprises a freewheel coupling 80 with which the bar 56 interacts in order to effect a different running characteristics of the pivoting movements of the pivot arms 34 to 40 in the upward and downward directions and, consequently, of the height adjustment of the arm support 12.
The freewheel coupling 80 is shown on its own in
The freewheel coupling 80 comprises a first coupling element 82 and a second coupling element 84, which are shown on their own in
The coupling elements 82 and 84 are designed in the form of wheels which are rotatable about a common rotation axis 86 and are arranged concentrically with respect to this rotation axis 86 and one behind the other.
The first coupling element 82 and the second coupling element 84 have, on their end faces, and with respect to the rotation axis 86, a complementary oblique toothing 88 (coupling element 82) and 90 (coupling element 84). The shape of the oblique toothings 88 and 90 is shown in
Upon a rotation of the first coupling element 82 about the rotation axis 86 in the direction of an arrow 92, the oblique toothing has the effect that the end face of the coupling element 82 slides on the coupling element 84, such that the second coupling element 84 is not moved in rotation during such a rotation of the first coupling element 82. The shape of the oblique toothing 88 and 90 means that, during a rotation of the coupling element 82 in the direction of the arrow 92, the second coupling element 84 is also pushed away in the direction of an arrow 94 in
According to
During a rotation of the first coupling element 82 about the rotation axis 86 in the direction of an arrow 96, that is to say in the opposite direction of rotation from the one in
a) accordingly represents the freewheel state of the freewheel coupling 80, whereas
The operating state in
Referring again to
The brake element 100 is arranged on a shaft extension 102 of the second coupling element 84, which shaft extension 102 is rotatable relative to the nonrotatable brake element 100.
The braking action of the brake element 100 can be adjusted by adjusting the contact pressure of the brake element 100 on the shaft extension 102 of the second coupling element 84. For this purpose, a clamping device is provided which comprises a clamping jaw 104 and an axial adjustment mechanism in the form of an adjustment sleeve 106, the clamping jaw cooperating with a counter-holder 108 which has a narrowing ramp 110, such that, when the clamping jaw 104 is pushed forward via the adjustment sleeve 106, the clamping jaw 104 presses the brake element 100 with increasing pressure onto the shaft extension 102. According to the enlarged detail in
The freewheel coupling 80 also comprises a housing part 114 which, via a guide slit or a guide groove 116, additionally permits the axial guiding of the second coupling element 84 together with the brake element 100 and the above-described clamping device. As has already been described, the axial mobility of the aforementioned parts is needed to ensure that the first coupling element 82 in the rotation direction according to arrow 92 in
To ensure that the oblique toothing 90 of the second coupling element 84 can again automatically come into a form-fit engagement with the oblique toothing 88 of the first coupling element 82 in the event of a downward movement of the pivot arms 34 to 40, the second coupling element 84 is pretensioned in the direction of the first coupling element 82 by means of a spring 118. As has already been mentioned, the brake element 100 and the clamping device for the brake element 100 also move axially with the second coupling element 84.
The operative connection between the bar 56 and the freewheel coupling 80 will now be described.
In its longitudinal movement in the directions according to the double arrow 68 in
The gear arrangement 120 comprises a first toothed wheel 122 which meshes with a toothing 124 on a partial section of the bar 56. The toothed wheel 122 in turn meshes with a second toothed wheel 126 which is arranged on a shaft extension 128 of the first coupling element 82 and is connected in a rotationally fixed manner to the first coupling element 82. The first toothed wheel 122 has a greater diameter than the second toothed wheel 126, with the result that there is a speed of rotation transmission ratio of greater than 1.
As will be seen from
The gear arrangement 120 together with the freewheel coupling 80 is accommodated in a main housing 130, which is shown in isolation in the enlarged detail in
The drive of the freewheel coupling 80 by the bar 56 is described with reference to
In the event of an opposite movement of the bar 56 for downward pivoting of the pivot arms 34 to 40, the direction of rotation of the toothed wheels 122 to 126 is exactly the reverse, such that the first coupling element 82 turns in the direction of the arrow 96 according to
In this way, the arm support 12 of the armrest 10 can be moved up and down between two end positions, the upward movement of the arm support 12 running smoothly, while the downward movement of the arm support 12 runs more slowly, and therefore in a controlled way, because of the braking action and depending on how the braking action is set. The upward movement of the arm support 12 is counteracted only by the force of the spring 66, which tensions more and more during the upward movement of the arm support 12 (see
The spring 66 is preferably designed in such a way that it permits a controlled lowering of the arm support 12 counter to the braking force of the brake element, without additional force being applied by the user.
a) shows an operating state of the armrest 10 which represents the lowermost position of the arm support 12, in which position the pivot arms 34 to 40 are pivoted downward and the bar 56 is driven into the cylinder 64.
b) shows, by contrast, an operating state of the armrest 10 in which the arm support 12 is raised relative to the position in
To ensure that the arm support 12, in the position shown in
The catch 132 is designed in such a way that it blocks the longitudinally directed movement of the bar 56 when the catch is in its blocking position, whereas the catch can be released in order to enable the longitudinally directed movement of the bar 56. In the illustrative embodiment shown, the catch 132 is designed such that it can block the movement of the bar 56 relative to the cylinder 64.
The catch 132 comprises a bolt 134, one end of which is articulated on the main housing 130, fixed to the cylinder, so as to be pivotable about a tilt axis 136.
The bolt 134 comprises a passage 138 through which the bar 56 extends. Depending on the state of tilting of the bolt 134 about the tilt axis 136, the bar 56 extends either perpendicularly or obliquely through the passage 138.
a) shows the catch 132 and the bar 56 on their own, on an enlarged scale. The position of the bolt 134 of the catch 132 in
By contrast,
Referring to
An end 140 of the bolt 134 remote from the tilt axis 136 is connected to a lever part 144 via a pull/push element 142, for example a bar or strut, the connection of the pull/push element 142 to the end 140 of the bolt 134 and to the lever part 144 being an articulated one.
As has already been described above, the arm support 12 is connected via the bearing element 46 to the strut 48, which is connected to the pivot arms 34 to 40. However, the connection of the bearing element 46 to the strut 48 is not rigid, and instead is effected via two further struts 146 and 148 which are connected in an articulated manner to the strut 48, such that the bearing element 46, and consequently the arm support 12, can move slightly relative to the pivot arms 34 to 40. This mobility is directed substantially vertically corresponding to an articulation of the struts 146 and 148 via substantially horizontal pivot axes 150, 152.
The above-described lever part 144 forms an L-shaped lever, such that a pivoting of the strut 148 about the pivot axis 152 at the same time effects a pivoting of the lever part 144, as a result of which the pull/push element 142 is in turn moved in its longitudinal direction.
a) shows a state in which the arm support 12, and consequently the bearing element 46, is located, relative to the pivot arms 34 to 40, in the maximally downwardly pivoted position about the pivot axes 150 and 152. The arm support 12 automatically adopts this position because of its force of gravity, and also when an operator rests his arm on the arm support 12. In this state, the lever part 144 presses the push/pull element 142 in the direction of an arrow 154, as a result of which the bolt 134 of the catch 132, as shown in
In order to free the catch 132 now, so that the bar 56 can move relative to the cylinder 64, for example in order to lower the arm support 12 starting from
Releasing the catch 132 requires only a slight lifting of the arm support 12, and this can be done with the same arm that is resting in the arm support. To ensure that the arm support 12 can be lifted with this arm, the arm support 12 is designed in the form of a shell 160 having substantially the shape of a C, such that a section 162 reaches at least as far as the top face of the arm received in the shell 160.
As will be seen from
Moreover, the lower end 140 of the bolt 134 is connected via a further pull element 164 to a tensioning spring (not shown) in the pivot arm 40, in order to ensure that the bolt 134 is pretensioned into the locking position according to
Number | Date | Country | Kind |
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10 2006 004 126.7 | Jan 2006 | DE | national |