EP0677662A1 - Muscle-like actuating device - Google Patents

Abstract

A force generating element which operates in a similar way to the muscular tissue of the body is made up from a fluidtight inner envelope of elastic material surrounded by an outer sheath which is inelastic in the direction in which it is required to work against a load. By injecting a fluid under pressure eg water or air into the inner envelope the resulting change of shape causes a contraction (delta L) along a central axis which includes the point of application (alpha) of the load. <IMAGE>

Description

Muscle-like power elements are components that are based on the mode of action of natural muscles.

A natural muscle is stimulated to "contract" by resonance, in which the living being couples itself arbitrarily (in contrast to "consciously") with an external source of excitation. The longitudinal muscle fibers, which are fixed in their length, start to oscillate (wavy line), which shortens the muscle under transverse thickening.

The invention makes it possible to produce force elements which are simple in construction, inexpensive to produce, lightweight, insensitive to misalignments, are environmentally friendly in operation and, in comparison with known force elements, offer a higher tapped force with comparable characteristic values.

Cross-streaked arbitrary muscles allow a powerful movement of the body parts and thereby the physical work. This development of force is associated with very short distances, which is why a force element modeled on this type of muscle is suitable for large translations with high reaction speeds and can be used where a short and extremely light construction is advantageous. There is also the great advantage of being able to work with low pressure of the operating medium, for example air or water, and small amounts of it due to the favorable internal transmission ratio adhering to this force element. This results in the favorable weight ratio of the force element to the load, with a Ratio of less than 1 ‰ is quite attainable, and best environmental compatibility when using air or water as a driving substance.

Such a force element can be divided into several communicating chambers by means of intermediate bundles, the common inner shell of which enables pressure equalization.

The advantages resulting from this are manifold: The amount of operating equipment is smaller because of the smaller volume of the inner shell, and thus the space requirement transversely to the longitudinal axis of the force element. Because of the wave-like outer line, several such force elements can be combined side by side in a light and space-saving manner, which additionally increases the force that can be tapped linearly. In addition, this multi-chamber force element can be used excellently for the production of tubular muscle-like force elements. Another decisive advantage is that the inner shell is stretched considerably less, which leads to an increase in tool life.

In conventional hydraulic or pneumatic force elements, e.g. in bellows, pneumatic or hydraulic cylinders, inflatable hoists, etc., it is characteristic that the load locations (the load locations here are the areas on the longitudinal axis of the force element that delimit the same and to which, with the shortest construction, a load is just attached) could) separate from each other as soon as the internal pressure of the force element is increased, ie that its length, measured in the longitudinal axis, increases.

With muscle-like force elements according to the invention, just like with natural muscle, this is exactly the other way round. In the case of force elements according to the invention, the load locations approach one another when the internal pressure increases while the force element is shortened. It is also characteristic of this type of force element that the force / travel characteristic is clearly non-linear and self-locking occurs at the end point (ideally with a spherical shape of the muscle-like force element).

A force element according to the invention consists of two individual parts, namely an inner shell and an outer shell, the outer shell being connected at two opposite ends to a fixed point and to the load.

The inner envelope is elastically extensible on all sides, expediently a balloon envelope made of an elastomer, rubber or the like. The equipment, be it a gas or a liquid, is introduced into it with pressure. It is sealed to the outside of the equipment and expands more and more as the internal pressure increases.

• Man nimmt nur längsgehende Fäden, welche in Fadenrichtung im wesentlichen nicht dehnbar sind und nebeneinander und übereinander liegen können;
• man nimmt ein netzartiges Gewebe, wobei darauf zu achten ist, das Netz im lastfreien Zustand derartig vorzuspannen, daß die Netzknoten in Richtung Längsachse des Kraftelementes möglichst weit voneinander entfernt sind und quer dazu möglichst eng beieinanderliegen;
• man nimmt einen in Richtung Längsachse des Kraftelementes stark bevorzugten Kreuzschlag von Fädern, die wiederum in Fadenrichtung unelastisch sind;
• man nimmt einen Stoff, welcher sich in Längsrichtung unelastisch verhält und in Querrichtung elastisch. Ist er dazu noch gasdicht, erfüllt er die Aufgaben der inneren Hülle mit. Erfüllt er noch dazu die Forderungen nach Festigkeit, Dichtheit und Beständigkeit, ist er ideal.

The outer shell consists of an inelastic fabric with a structure such that an expansion in the direction of the longitudinal axis of the muscle-like force element is effectively prevented. At the same time, however, the outer shell allows the circumference of the inner shell to extend transversely to the longitudinal axis. There are several ways to combine these two properties, in particular:

• One only takes longitudinal threads, which are essentially not stretchable in the thread direction and can lie side by side and one above the other;
• one takes a net-like tissue, whereby care must be taken to pretension the net in the load-free state in such a way that the net nodes are as far apart as possible in the direction of the longitudinal axis of the force element and are as closely as possible transverse to one another;
• one takes a cross stitch of threads which is strongly preferred in the direction of the longitudinal axis of the force element and which in turn is inelastic in the thread direction;
• one takes a fabric that is inelastic in the longitudinal direction and elastic in the transverse direction. If it is also gas-tight, it also fulfills the functions of the inner shell. If it also meets the requirements for strength, tightness and durability, it is ideal.

• Sie nimmt die Last in Längsrichtung auf,
• bewirkt eine steuerbare Aufdehnung des Kraftelementumfangs,
• ermöglicht eine gezielte Verformung der inneren Hülle und stützt sie,
• ermöglicht die entsprechende Steuerung des Innendruckes,
• bewirkt im Verein mit der inneren Hülle die Längsachsenverkürzung des Kraftelementes, da bei Erhöhung des Innendruckes in der Innenhülle sich diese nicht in Längsrichtung ausdehnen kann, wohl aber radial und im Umfang.

The outer shell does the following:

• It takes the load in the longitudinal direction,
• causes a controllable expansion of the circumference of the force element,
• enables targeted deformation of the inner shell and supports it,
• enables the appropriate control of the internal pressure,
• causes in conjunction with the inner shell, the longitudinal axis shortening of the force element, since when the internal pressure in the inner shell increases, it cannot expand in the longitudinal direction, but it can do so radially and in circumference.

Since the arc length of the threads cannot change between the load locations (hence the requirement for inelastic material), the length of the force element is shortened with increasing internal pressure of the inner cover. A shortening also results when using a mesh-like fabric. The bundling of the shell components at the load locations of the force element is absolutely necessary for the force element to be effective; see picture I.

Due to the internal transmission ratio of a muscle-like force element (on average over 1: 7), it can be seen that with the same load bearing capacity and comparable parameters (e.g. cross-section to piston diameter), the operating pressure compared to force elements of a known type only has to be one-seventh, or even at the same pressure seven times the load can be absorbed. Depending on The operating point on the force / displacement characteristic is also easily 20 times the force with a correspondingly shorter path.

To simulate so-called longitudinally streaked, involuntary muscles, several of the force elements described are arranged in a circle or arc and connected to one another at their load locations (see Figure II), and the force elements formed in this way are either permanently connected to one another or loosely placed against one another, always doing this The next multi-chamber force element is rotated about the longitudinal axis of the force element in such a way that a location with the greatest thickening of a chamber always plunges into the depression of a load location of the adjacent muscle ring and the desired tube shape is achieved in total.

This can also be achieved by a spiral arrangement of a very long, also multi-chambered force element, whereby it should be noted that the force element then rotates the longitudinal axis of the support element radially.

Claims (7)

Muscle-like force element for moving loads, characterized in that it consists of two shells, namely an inner and an outer shell, the inner shell being made of a stretchable material and in the manner of a balloon with a fluid, e.g. a gas or a liquid, is inflatable, and the outer shell consists of a non-elastic material in the longitudinal direction of the force element, but allows the inner shell to expand in the radial and circumferential directions. Force element according to claim 1, characterized in that the outer casing consists of a plurality of longitudinal, inelastic threads which lie side by side and one above the other and are combined on opposite sides of the force element. Power element according to claim 1 or 2, characterized in that the outer and inner casing are combined to form a common casing. Force element according to one of the preceding claims, characterized in that the force element is divided into several communicating chambers by means of intermediate bundles, the common inner sleeve of which enables pressure equalization between the chambers. Force element according to one of the preceding claims, characterized in that a plurality of such force elements are connected in series and arranged in a spiral, ring or arc shape. Force element according to claim 4, characterized in that the inner shells communicate with at least some successive force elements. Force element according to claim 4 or 5, characterized in that in the case of a spiral, ring or arc-shaped arrangement of force elements, several of them are laterally connected to one another.

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