RU36620U1 - ARTIFICIAL KNEE JOINT WITH REGULATION OF BRAKING FORCES SEPARATELY WHEN BENDING AND RIBBING - Google Patents

Description

ARTIFICIAL KNEE JOINT WITH REGULATION OF BRAKING FORCES SEPARATELY THREE BENDING

The utility model relates to medical equipment, namely to artificial knee joints and can be used for prosthetics of the lower extremities.

The actual problem of improving the biomechanical characteristics of walking on the prosthesis. It comes down, in particular, to approximating the dynamics of the movements of the lower leg during flexion and extension of the artificial knee joint (ICS) in the phase of transfer to normal (i.e., to the dynamics of similar movements in a healthy leg). After the back push, the prosthesis heel rises higher than that of a healthy leg, which lengthens the transfer time of the prosthetic limb and aggravates the asymmetry of movements. In addition, at the end of the transfer phase, there is a strong collision of the recurrence elements of the ICS, leading to a tendency for the receiving sleeve to fall from the stump and to a poorly dynamic shock, which, after prolonged use, has a negative effect on the health of the disabled person (see, for example, R. Baumgartner, P. Botta “Amputation and prosthetics of the lower extremities, trans. With German., M.,“ Medicine, 2002).

One of the ways to solve the problem is the introduction of an ICS braking mechanism with regulation of the braking force. It is advisable to take into account that the magnitude of the braking force during bending can significantly differ both in a larger and smaller direction from the braking force during bending. The difference in braking forces depends on the pace and individual characteristics of the disabled person’s walking, as well as on the technical characteristics of the prosthesis itself: the rigidity of the foot and toe of the foot, the presence of a pull and ankle device and other parameters. The presence in the ICS of the mechanism of braking of the lower leg eliminates excessive bending of the prosthesis in the transfer phase and reduces the impact on the elements of the ICS from the inertial forces of the lower leg and foot at the time of complete extension of the prosthesis. This allows you to improve biomechanical characteristics, reduce dynamic asymmetry and discomfort when walking, reduce the energy consumption of a disabled person (B. S. Farber et al. “Theoretical Foundations of the Construction of Lower Limb Prostheses and Motion Correction, edited by B. S. Farber, book 2, M., TsNIIPP, 1994).

-2 O O 31 54 4 1 6

AND RIBBING

MIK7: A61F 2/64

647G72-3000-05.00-MD) the braking mechanisms are combined with the rotation mechanism on the basis of split conical bushings pulled together by a screw. In this case, the magnitude of the stopping force set during regulation remains constant both during bending and unbending.

In the well-known ICS (RU 2084209 C1, JSC West Ukrainian Business Center, 07.20.1997), the braking is performed by crimping the overrunning clutch with a sleeve with a nrorez. In another design (DE 3923056 A1, Kunne, 01.24.1991), the braking means includes an overrunning clutch, a brake element and means for controlling the braking force.

The closest in technical essence is the ICS with the use of an overrunning clutch and a braking sleeve with a slot for braking, the design of which provides braking in one direction and free rotation in the other direction (US 6355071 B1, Cheng, 03/12/2002).

The lack of independent (separate) control

retarding both during flexion and extension of the lower leg limits the possibility of the dynamics of the movement of the lower leg of the prosthesis approaching normal, which is the main disadvantage of both the closest analogue and the above technical solutions. Another drawback of the closest analogue is that with each step, at the time of the transition of the IKS from the rest state to the state of rotation, there is a “breakdown felt by the disabled person as discomfort when walking, which is associated with dry friction, in which, as you know, the coefficient of rest friction significantly higher than the coefficient of sliding friction.

The objective of the present invention is to provide a mechanism to eliminate these disadvantages, namely: to provide the ability to independently control the braking and bending, and during extension of the lower leg, as well as to ensure a smooth — without “stalling” transition of the ICS from rest to rotational motion.

The technical result - increasing comfort and reducing the energy consumption of a disabled person when walking on the prosthesis - is achieved by the fact that the artificial knee joint contains the femoral and lower leg parts, interconnected by a limited rotation mechanism having at least one axis and bearings, a braking mechanism including an overrunning clutch, mounted on an axis and covered by a sleeve with a slot, and a screw for adjusting the compression force of the coupling by the sleeve. The joint further comprises an identical overrunning clutch, a slotted sleeve, a screw for adjusting the compression force of the sleeve by the sleeve, and a lubrication assembly,

both mentioned couplings are mounted on the axis but are allowed in the opposite direction of rotation, the bushings have a length shorter than the length of the couplings. Each screw controlling the compression force of the sleeve by the sleeve is placed in a groove formed on its outer surface, the groove is perpendicular to the axis of the sleeve and intersects the slot, and the threaded holes for the said screws are made in the body of one of the parts of the joint. Between the screw head and the sleeve there is an elastic element covering the screw, and the lubrication unit covers the bushings and contacts the outer surfaces of the couplings. On the outer surfaces of the split sleeve perpendicular to the axis of the groove, support pads are located symmetrically on both sides of the groove, and the distance from the axis of the sleeve to the plane passing through the middle of all the support pads is equal to the distance between the axis of the said bearings and the axis of the threaded hole for the screw, and the width of the pads is less than the width of the groove.

The joint can be characterized by the fact that the elastic element is made in the form of a set of Belleville springs, as well as the fact that the threaded holes for the screws are made in the femoral part.

The joint can also be characterized by the fact that the lubrication unit has an oil-containing element in the casing and wicks in the form of washers mounted on the couplings.

The joint can also be characterized by the fact that the slot of the sleeve is made at an angle to its longitudinal axis.

The invention is illustrated in the figures, where:

in FIG. 1 shows the design of the ICS with a braking mechanism;

in FIG. 2 is the same as in FIG. 1, a section along AA;

in FIG. 3 - the mechanism of braking in a disassembled state;

in FIG. 4 - split sleeve;

in FIG. 5 is the same as in FIG. 4, view from the side of the slot.

The principles of the invention are disclosed in the following example of a four-axis IKS and can be applied both in mono-and in polycentric IKS of various modifications.

IKS contains two main components: the femoral part 10, which in the manufacture of the prosthesis is connected to the receiving sleeve of the thigh, and the lower part 12, connected to the artificial lower leg. Parts 10 and 12 are interconnected by a rotation mechanism 13 including an axis 14 and links 16. The axis 14 is mounted in the housing 18 of the femoral part 10 on bearings 20 and is fixedly connected to the links 16.

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direction of rotation and covered by bushings 26 (hereinafter 261, 262) with a slot. Adjusting screws 30 (301,302) pass through the grooves 28 of the bushings 26, which are screwed into the housing 18 and, through the elastic elements 32 and washers 34, push the bushings 26 to the surface 36 of the housing 18. At the same time, the bushings 26 compress the couplings 24, creating a braking force.

On the outer surfaces of the bushings 26, perpendicular to the axis of the screw 30, there are support pads 38, 39 for contact with the surface 36 and the washer 34. The pads 38, 39 are located symmetrically on both sides of the groove 28. The width of the pads 38, 39 is less than the diameter of the screw 30. This design prevents the occurrence of bending moment acting on the screw 30, and also contributes to the stability of the adjusting characteristics in serial production.

The sleeve 26 has a slot 42 located at an angle a to the longitudinal axis of the sleeve, which reduces the effect of deviations from the cylindricality of the outer surface of the sleeve 24 on the change in the magnitude of the friction force between this surface and the sleeve. The angle a is 10-30 °. If the slot is parallel to the axis of the sleeve, then possible roughness due to the non-cylindrical surface of the coupling, mixing in the zone of the slot, can cause a change in the friction force. Therefore, the cylindrical surface of the coupling 24 does not require superior manufacturing quality.

The braking mechanism 22 has a lubrication unit consisting of an oil-containing element 44 and two wicks-washers 46, pressed against the split sleeves 26 by means of a casing 48 and washers 50, respectively.

The mechanism works as follows.

When walking on the prosthesis, the axis 14 with the links 16 fixed on it rotates cyclically in the housing 18 on the bearings 20. When the ICS is bent, the axis 14 rotates freely in one of the couplings 24, for example, in the coupling 241, while the coupling 242 is fixed on the axis 14 and rotates together with the axis in the sleeve 262, overcoming the friction between the contacting surfaces of the sleeve 242 and the sleeve 262. When the ICS is unbent, the axis 14 rotates freely in the sleeve 242, and the sleeve 241 rotates with the axis 14, overcoming the friction between the contacting surfaces of the sleeve 241 and sleeve 261. Forces sub rmazhivaniya independently adjustable: while bending the adjusting screw 302, in extension - screw 301.

To reduce wear and ensure smooth operation of the mechanism, the friction surfaces are lubricated with wicks-washers 46 from the oil-containing element 44.

artificial tibia, which is provided by the possibility of separate regulation of the forces of braking and nib bending, and nib extension of the ICS.

Claims (5)

1. An artificial knee joint containing the femoral and lower leg parts interconnected by a limited rotation mechanism having at least one axis and bearings, a braking mechanism including an overrunning clutch mounted on an axis and covered by a slot with a slot, and a force adjustment screw clutch compression sleeve, characterized in that it further comprises an identical overrunning clutch, a sleeve with a slot, a screw for adjusting the compression force of the sleeve by the sleeve, as well as a lubrication unit, both of which are said mouth couplings counter-mounted on the axis in the opposite direction of rotation, the bushings have a length shorter than the length of the couplings, each screw controlling the compression force of the coupling by the sleeve is placed in a groove formed on its outer surface, the groove is perpendicular to the axis of the sleeve and intersects the slot, the threaded holes for the said screws are made in the body of one of the parts of the joint, between the screw head and the sleeve there is an elastic element covering the screw, the lubrication unit covers the bushings and is in contact with the outer surfaces of the couplings, while on the outer surfaces of a spacer sleeve perpendicular to the axis of the groove, support pads are arranged symmetrically on both sides of the groove, and the distance from the axis of the sleeve to the plane passing through the middle of all the support pads is equal to the distance between the axis of the said bearings and the axis of the threaded hole for the screw, and the width of the pads is less groove width. 2. The joint according to claim 1, characterized in that the elastic element is made in the form of a set of Belleville springs. 3. The joint according to claim 1 or 2, characterized in that the threaded holes for the screws are made in the femoral part. 4. The joint according to claim 3, characterized in that the lubrication unit contains an oil-containing element in the casing and wicks in the form of washers mounted on the couplings. 5. The joint according to claim 4, characterized in that the slot of the sleeve is made at an angle to its longitudinal axis.