NL2026223B1 - Telescopic Shaft Assembly and Rescue Tools - Google Patents

Abstract

A telescopic shaft assembly comprises a housing with a body cavity (1) extending along an operating axis (W), wherein at least a first shaft body (11) and a second shaft body (12) are received coaxially in the cavity and are operatively coupled, at least connectable with energizable drive means (6,7,8) with which the shaft bodies are displaceable along the working axis (W) between a fully retracted initial position and a fully extended final position. The drive means comprise a screw spindle (10) common to both shaft bodies and extending coaxially within both shaft bodies (11,12). The first shaft body (11) comprises a first screw nut arrangement (21) and is capable and adapted to operatively engage on the screw spindle (10). The second shaft body (12) includes a second screw nut arrangement (22) and is capable and arranged to operatively engage the screw spindle (10) therewith. The second shaft body (12) abuts the first shaft body (11) to reach its fully extruded end state thereof and is able and arranged to carry the first shaft body (11) to its fully extruded end state and thereby the first screw nut arrangement ( 21) into engaging engagement with the screw spindle (10).

Description

The present invention relates to a telescopic shaft assembly comprising a housing with a skirt part in which a body cavity extends along an operating axis, wherein at least a first shaft body is received coaxially in the cavity and is operatively coupled, at least connectable, to energizable drive means with which the first shaft body is displaceable along the working axis between a fully retracted initial position and a fully extended end position of the first shaft body. The invention herein particularly relates to a rescue tool provided with such a telescopic shaft assembly.

A rescue tool comprising a telescopic shaft assembly is known, for example, from International Patent Application WO 2018/156018. Therein is described a so-called rescue prop or ram which serves to force a space in an emergency in order to be able to free a victim from a plight. For example, the victim is trapped under an at least partially collapsed building or in a car wreck after a collision. In order to create sufficient space for an evacuation of the victim, the rescue tool is placed along the working axis between a part of the wreck or building and a solid ground, after which the drive means of the shaft body are energized. The shaft body thereby extends out of the housing and thus extends the effective length of the tool so as to lift the engaged part of the building or wreckage and thus force it out of the way. Rescue workers then have the opportunity to free the victim from his plight.

In the known rescue tool, the housing comprises a hydraulic cylinder and the extendable shaft body starts from a piston body which is axially movable in the cylinder cavity. The piston body and thus the shaft body can be driven out by means of a hydraulic pump and liquid so as to extend the effective length of the tool maximally over the deflection of the shaft body, i.e. the piston.

Such rescue tools are almost standard equipment of many rescuers such as firefighters and rescue workers. For this it is important that the tool is lightweight and compact, while nevertheless a large deflection can be made. The known tool has the disadvantage in this respect that it is hydraulic

-2- powered and therefore, in addition to its own weight, also entails a reservoir of hydraulic fluid and hydraulic pump as a load. Moreover, the stroke of the known tool is limited to the distance over which the piston body can extend from the cylinder and is thus limited to a maximum of the own length of the tool in the retracted position. A larger deflection inevitably leads to a less compact tool. The present invention has for its object, inter alia, to provide a telescopic shaft assembly that meets these drawbacks, at least to a large extent.

To this end, a telescopic shaft assembly of the type described in the preamble according to the invention is characterized in that at least a second shaft body extends coaxially within the first shaft body and is operatively coupled, or at least can be coupled, to the drive means with which the second shaft body is displaceable along the working axis. is between a fully retracted initial state and a fully extended final state of the second shaft body, that the drive means comprises a screw spindle common to both shaft bodies and extending coaxially within both shaft bodies, that the first shaft body comprises a first screw nut arrangement and is capable and arranged to operatively engaged with the screw spindle, that the second shaft body includes a second screw nut arrangement and is capable and arranged to operatively engage the screw spindle therewith, that the second shaft body for reaching the full The extruded end state thereof abuts the first shaft body, and that the second shaft body is capable and arranged to entrain the first shaft body to the fully extruded end state of the second shaft body, thereby bringing the first screw nut arrangement into engaging engagement with the screw spindle. Because at least a second shaft body here extends telescopically from the first shaft body, the maximum deflection of the shaft assembly can be significantly greater than the minimum inherent length in the retracted position. A larger clearance does not therefore have to be at the expense of a compact construction. In addition, the drive is provided by a common screw spindle. An ingenious cooperation between the first and second shaft body has hereby achieved that first of all the second shaft body extends almost completely, before it is

-3- first shaft body is extruded by the screw spindle.

It has been found that a significant weight reduction can thus be achieved with respect to hydraulic actuation in an assembly filled with hydraulic fluid, while moreover a significantly greater deflection is possible with the same length of the housing.

Optionally, within the second shank body, one or more further shank bodies can be accommodated coaxially in a similar manner and successively engaged with the spindle so as to allow a further extension of the working length.

Preferably, the screw spindle does not or hardly extends beyond both shaft bodies.

Because the second shaft body after reaching its fully extruded end state of the spindle! will run, it is important that the second shaft body is locked in axial direction.

To this end, a special embodiment of the shaft assembly according to the invention is characterized in that the first shaft body is provided at one end thereof with locking means which are capable and designed to engage on the second shaft body so as to form a releasable connection therewith, which is released upon retraction of the second shaft body.

The intended locking means thus effect an immovable connection between the second shaft body and the first shaft body which is currently carried by the spindle.

An axial unity is thus created between the two shaft bodies, which unit is released when the shaft assembly is pushed in.

Such locking means can be designed in many ways.

To this end, in a further special embodiment, the shaft assembly according to the invention is characterized in that the locking means comprise a resilient slide which can move axially against a spring tension in a guide and is capable of and adapted to fit onto the second shaft body via the intermediary of at least one fixing body. that the at least one slide, in an incompletely extruded state of the second shaft body, abuts a stop of the housing and is lifted out of a seat against the spring tension, wherein the at least one fixation body is released, and that the slide is in a position fully extruded end state of the second shaft body is freed by the first shaft body from the stop of the housing and forced into the seat under the spring tension, wherein the at least one fixation body maintains a fixing co-action with the second shaft body.

4- In this case, the resilient sliding body is lifted out of its seat by the stop of the housing when the first and second shaft bodies are fully retracted. The at least one fixation body is thereby released and now lies free on an outer wall of the second shaft body. An axial displacement of the second shaft body is not hindered in this key position.

Because the slide is freed from the stop when the maximum stroke of the second shaft body is reached and is forced into its seat by the spring tension, the at least one fixation body becomes locked between the two shaft bodies so that both shaft bodies are axial! fixed relative to each other. The second shaft body now forms one at least substantially immovable whole with the first shaft body. When the first shaft body is retracted, the slide is moved out of the seat and the at least one fixation body, and thus the second shaft body, is released again.

With a view to an increased axial load-bearing capacity, a further preferred embodiment has the feature here that the second shaft body comprises at least one recess for close accommodation of a fixation body that can be accommodated therein. The at least one fixation body falls into a corresponding recess, an edge of which provides an additional axial bearing capacity. With a view to a particularly high load capacity, which lends itself, for example, to being used for a high load such as, for example, required for a rescue tool, a further preferred embodiment of the shaft assembly according to the invention is characterized in that the slide comprises a resilient washer and at least one fixation body a number of fixation bodies which are jointly forced or released by the washer into one or more corresponding recesses, and more in particular that the at least one fixation body comprises a series of balls and that the second shaft body has a base thereof externally of a corresponding number of recesses are provided, which are in particular regularly distributed around a periphery thereof. If desired, such a fixation ring can be designed in multiple ways and it has been found to be able to withstand a particularly high axial load of the order of a few to a few tens of tons.

In order to ensure that both shank bodies can make a maximum deflection, it is important that the first shank body is first extruded after the second

-5- shaft body abuts against the stop with the first shaft body. To this end, a further preferred embodiment of the shaft assembly according to the invention is characterized in that the first shaft body, in its fully retracted initial position, is received while engaged in a chamber of the housing. The engaging action on the first shaft body, which thus emanates from the housing, prevents the first shaft body from prematurely running along with the second shaft body. Only after the second shank body abuts against the stop and carries the first shank body along is this engagement overcome and the first shank body with the first nut is placed on the spindle.

According to the invention, a special embodiment of the shaft assembly is characterized in that the chamber is provided in a wall thereof with a seat which provides space for a pressure body, in particular a resilient ring, and that the pressure body is in the fully retracted initial position of the the first shaft body clampingly engages the first shaft body. Due to an adequate dimensioning and fit of the pressure body, the mutual clamping between the housing and the first shaft body can thus be accurately tuned and adjusted. A further preferred embodiment of the shaft assembly according to the invention is characterized in that the first shaft body comprises a recess in a circumferential wall thereof in which the pressure body is received. The recess in the outer wall of the first shaft body ensures a defined starting position, which also keeps the screw thread of the first nut accurately in line with the screw thread on a spindle, so that both are optimally adjusted to each other when the first nut is received by the screw spindle. . A rescue tool according to the invention in particular comprises a delay device (ram) and is characterized for this purpose in that a shaft assembly as described above is provided therein. In a special embodiment, such a rescue tool according to the invention is characterized in that the drive means comprise an electric motor in the housing with a motor shaft driven thereby, which is operatively coupled to the screw spindle, in particular by means of a torque-converting transmission, and more in in particular that the electric motor must be operated by at least one

-6- rechargeable battery is supplied, which at least one battery is accommodated in or on the housing and in particular is removable or removable.

Such a battery powered configuration provides a completely wireless, portable system, although the tool may optionally or additionally be configured for mains or generator supplied power.

The invention will now be further elucidated on the basis of an exemplary embodiment and an associated drawing.

In the drawing: Figure 1 shows in perspective and half cut-away an example of a rescue tool with a shank assembly according to the invention; Figure 2A is a longitudinal section of the rescue tool of Figure 1 in a fully retracted position; Figure 2B is a distal detail of the rescue tool of Figure 1 in the state of Figure 24; Figure 2C is a proximal detail of the rescue tool of Figure 1 in the state of Figure 2A; Figure 3A is a longitudinal section of the rescue tool of Figure 1 in a substantially fully extruded condition from the second shaft body; Figure 3B is a distal detail of the rescue tool of Figure 1 in the state of Figure 3A; Figure 3C is a proximal detail of the rescue tool of Figure 1 in the state of Figure 3A; Figure 3D is a distal detail of the rescue tool of Figure 1 in a fully extruded condition from the second shaft body; Figure 3E is a proximal detail of the rescue tool of Figure 1 in a fully extruded condition from the second shaft body; Figure 3D is a distal detail of the rescue tool of Figure 1 in a partially extruded condition from the first shaft body; Figure 3E is a proximal detail of the rescue tool of Figure 1 in a partially extruded condition from the first shaft body; Figure ZA is a longitudinal section of the rescue tool of Figure 1 in a fully extruded state of the first shaft body;

Figure 4B is a distal detail of the rescue tool of Figure 1 in the state of Figure 4A; and Figure 4C shows a proximal detail of the rescue tool of figure 1 in the state of figure 4A. It should also be noted that the figures may be schematic and not always drawn on the same scale. In particular, for the sake of clarity, some dimensions may be exaggerated to a greater or lesser extent. Corresponding parts are indicated in the figures with the same reference numerals.

Figure shows an exemplary embodiment of a rescue tool in which a telescopic shaft assembly according to the present invention is applied. In this case, it is a powered and extendable strut with which, for example, parts of a car wreck can be driven apart or a load can be lifted and stabilized. The tools start from a housing between opposite support members 2,3, wherein the tool can be placed according to a working axis between positions to be dispersed from one another. To this end, the housing provides practical handles 4,5 and offers space for an electric motor 5, an output motor shaft of which is coupled to a screw spindle 10 via a torque-converting transmission 6 and bearing 7 . The electric motor is powered by a rechargeable battery pack which in the shown position has been removed from an insertion cavity 9 provided for this purpose. One of the two handles 4 also comprises an ergonomic control in the form of a rotary switch with which the electric motor 6 can be put into operation, wherein a direction of rotation of the electric motor 6 is imposed by a corresponding rotation of the handle 4 . The tool shown here is capable and equipped to provide a load capacity of the order of a few tons to a few tens of tons.

To this end, the tool includes a telescopic shank assembly formed by a casing portion 13 of the housing together with a first shaft body 11 and a second shaft body 12. The casing portion 13 encloses an axial body cavity 1 in which the first shaft body 11 is axially movable. The first shaft body 11, in turn, is also hollow and encloses the second shaft body 12 which is axially co-fitted within the first shaft body. At a distal end, the body cavity 1 opens so that both shaft bodies can be telescoped in and out along a working axis W.

-8- In the situation shown in figure 1, the first shaft body 11 operatively engages the screw spindle 10 with a first nut device 21, hereinafter referred to simply as a nut. The same applies to the second shaft body 12, which is provided internally at its base with a second nut device 22, hereinafter referred to simply as a nut, which is operatively engaged with the screw spindle 10. Both shaft parts 11,12 comprise one or more cams 26 in keyways provided for this purpose in longitudinal direction, which are not shown in more detail, and which protect the shaft parts 11,12 from rotation. A rotation of the spindle 10 thus ensures a rectilinear movement of the nuts 21,22 engaging thereon and therewith of the shaft bodies 11,12 connected thereto.

Figure 2A shows the rescue tool of Figure 1 in a longitudinal section along the working axis W, with Figures 2B and 2C showing distal detail and proximal detail, respectively, roughly according to circles B, C in Figure 2A. Distally, see Figure 2C, the second nut 22 lies on the spindle 10 so that the associated second shaft body 12 is in transmission engagement with the spindle, but the first nut 21 of the first shaft body 11 lies just behind the spindle 10. The first shaft body 11 therefore lies stationary in the housing 13 and is held in this position in that the first shaft body 11 is received clampingly at a base with the nut 21 in a chamber 23 provided for this purpose in the housing. In an inner wall thereof, the chamber 23 comprises a seat in the housing. the shape of a circumferential groove in which a pressure body in the form of a resilient ring 24 is enclosed. The resilient ring 24 clampsly engages an outer wall of the base of the first shaft body 11 and thus resists a (premature) axial displacement of the first shaft body 11 due to the friction generated thereby. a corresponding recess (groove) is provided in which the resilient ring 24 slides, the first nut 21 has an accurately defined position which is determined by the position of both grooves. In this example! the resilient ring comprises a hollow, flattened spiral spring, but a solid ring, for example a flexible polymer, can be used instead. The pressure body can also be formed by a rib which extends integrally from the wall of the chamber and in that case will be formed from (stainless) steel or aluminum. If desired, the first shaft body can be provided with a coating or top layer at the base that provides extra grip. Also

The semi-permanent fixation of the first shaft body can be provided electromagnetically, electromechanically or permanently magnetically.

By energizing the electric motor 6, the spindle 10 is set in rotation.

The second shank body 12 with the second nut is now carried along and the second shank body 12 deflects until the substantially fully extruded key tooth shown in Figures 3A-3C is reached.

The second nut 22 is now just on the spindle 10; the first nut is still clamped in chamber 23 just outside the reach of spindle 10, see also figure 3B and

3C.

The second shaft body now abuts with a widened base 15 thereof on a collar 14, or otherwise a stop, at the distal end of the first shaft body 11. Because the second nut 22 is still engaged with the spindle 10, a further rotation causes of the spindle 10 that the second shank body 12 is further driven out until it has reached its fully extruded end state, thereby carrying the first shank body 11 along with it.

Hereby, the clamping of the first shaft body 11 in the chamber 23 of the housing 13 is overcome and the second nut 22 slides on the spindle! 10, see Figure 3D and 3E.

At the distal end, the first shaft body 11 comprises locking means in the form of a resilient slide 31 which extend from a washer 30, see also figure 1, and which is actuated by a head 16 of the housing.

In the situation shown in figure 3D the slide 31 is lifted from its seat against a spring pressure of springs 32 acting thereon and is thereby expelled from a fixing cavity 33, because the slide 31 abuts on a collar 14 at the head of the housing.

Once entrained by the second shaft body 12, the first shaft body 11 will move away from the housing head, freeing the slide 31 from the head and releasing it.

The slide 31 now shoots under the spring tension of the spring package 32 into the cavities 33 and thereby forces a number of fixation bodies in the form of steel balls 34 into corresponding recesses 35 in an outer wall near the base 15 of the first shaft body 11, see figure 3D. and 3F.

This confinement of the balls 34 in the cavities 35 provides for an axial locking and fixation of the second shaft body 12 with respect to the first shaft body 11, whereby they as a whole are able to absorb a load acting thereon.

-10- On further rotation of the spindle, the first nut 21 is fully received thereon, see figure 3G, while the second nut 22 just slides off the spindle, see figure 3F. The first shank body 11 coupled to the first nut 21 is now pushed out further until the first nut 21 reaches the end of the spindle 10 and thus the first shank body 11 is fully extruded in its final state, see figure 4. The second nut 22 is now completely free and away from the spindle 10, see also figure 4A, and the second shank portion 12 is fully supported by the first shank body 11 which in turn transmits any axial load to the spindle 10 via the first nut 21 . To this end, the spindle 10 is journalled in a housing through the intermediary of a flat pivot bearing 7 and is able to withstand a load of the order of a few tons to, with a corresponding dimensioning of the components, several tens of tons. When the spindle 10 rotates in the opposite direction, the above-described stages repeat in reverse order. When the first shaft part 11 is fully retracted, the second nut 22 slides onto the spindle 10 and the clamping on the second shaft body 12 is released by the locking means 30-35. Subsequently, the first nut 21 slides off the spindle 10 to be clamped in the chamber 23 in a defined position and orientation. Finally, the second treasure body 12 slides completely into the housing 13 until the initial state of Fig. 2A is reached.

Thus, the invention provides a two-stage telescopic shaft assembly which can be extended to more stages by means of a third or even further shaft body similarly or similarly provided therein. Although the invention has been further elucidated on the basis of only a single exemplary embodiment, it will be apparent that the invention will in no way be limited thereto. On the contrary, many variations and embodiments are still possible for an average skilled person within the scope of the invention. For example, instead of a simple nut/spindle assembly, one or both shaft bodies of a ball screw or roller screw/spindle can also be used! assembly are assumed to limit mutual friction losses. The telescopic shaft assembly according to the invention can also be used in applications other than the rescue tool shown. It can be advantageous

-11- shaft assembly, for example, can also be used for a strut with which a load is stabilized for a shorter or longer period.

And also outside the field of rescue tools there are many applications in which the shaft assembly can be used to advantage.

Claims (12)

Claims: A telescopic shaft assembly comprising a housing with a sheath portion (13) in which a distal open body cavity {1} extends along a working axis (W), wherein at least a first shaft body (11) is received coaxially in the cavity and is operatively coupled, or at least can be coupled, to energizable drive means {6,7,8) with which the first shaft body can be moved along the working axis (W} between a fully retracted initial position and a fully extended end position of the first shaft body {11}, with the characterized in that at least a second shaft body (12) extends coaxially within the first shaft body (11) and is operatively coupled, or at least can be coupled, to the drive means {6,7,8) with which the second shaft body {12) according to the working axis ( W) is movable between a fully retracted initial position and a fully extended final position of the second shaft body (12), that the drive means shift one for both. eight bodies comprise a common screw spindle (10) extending coaxially within both shaft bodies (11,12), the first shaft body {11} comprises a first screw nut arrangement (21) and is capable and arranged to operatively engage the screw spindle { 10}, that the second shaft body (12) includes a second screw nut arrangement (22) and is capable and arranged therewith to operatively engage the screw spindle {10}, that the second shaft body {12} to achieve the fully extruded end state thereof abuts the first shaft body (11), and that the second shaft body (12) is able and arranged to carry the first shaft body (11} along to the fully extruded end state of the second shaft body and thereby the first screw nut arrangement (21 ) into engaging engagement with the screw spindle (10). Shaft assembly according to claim 1, characterized in that the first shaft body {11} is provided at one end thereof with locking means (30-35) which are able and arranged to, upon reaching the fully extruded end state of the second shaft body, to engage the second shaft body {12} in order to enter therewith into a releasable connection, which is lifted upon retraction of the second shaft body (12). -13- Shaft assembly as claimed in claim 2, characterized in that the locking means comprise a resilient slide which is axially movable against a spring tension in a guide and is able and adapted to engage the second shaft body via at least one fixation body, which the at least one slide in an incompletely extruded state of the second shaft body abuts a stop of the housing and is lifted out of a seat against the spring tension, wherein the at least one fixation body is released, and that the slide is in a fully extruded end position of the second shaft body is freed from the stop of the housing by the first shaft body and forced into the seat under the spring tension, wherein the at least one fixation body maintains a fixing co-action with the second shaft body. 4. Shaft assembly as claimed in claim 3, characterized in that the second shaft body comprises at least one recess for close accommodation of a fixation body that can be accommodated therein. Shaft assembly according to claim 4, characterized in that the slide comprises a resilient washer and the at least one fixation body comprises a number of fixation bodies which are jointly forced or released by the washer into one or more corresponding recesses. A shaft assembly according to claim 5, characterized in that the at least one fixation body comprises a series of balls and in that the second shaft body is externally provided at a base thereof with a corresponding number of recesses, which are in particular regularly distributed around a circumference thereof. Shaft assembly according to one or more of the preceding claims, characterized in that the first shaft body, in its fully retracted initial position, is received while engaged in a chamber of the housing. 8. Shaft assembly according to claim 7, characterized in that a chamber in a wall thereof is provided with a seat which can accommodate a pressure body, in particular a resilient ring, and that the pressure body is fully retracted in the -14- initial condition of the first shaft body clampingly engages the first shaft body. 9. Shaft assembly as claimed in claim 8, characterized in that the first shaft body comprises in a circumferential wall thereof a recess in which the pressure body is received. A rescue tool, in particular a delay device (ram), comprising a shaft assembly according to one or more of the preceding claims. A rescue tool according to claim 10, characterized in that the drive means comprise an electric motor in the housing with a motor shaft driven thereby, which is operatively coupled to the screw spindle, in particular via a torque-converting transmission. Rescue tool according to claim 11, characterized in that the electric motor is powered by at least one rechargeable battery, which at least one battery is accommodated in or on the housing and is in particular removable or removable.