阅读说明：本技术 矫形技术装置和用于其的导体 (Orthopedic device and conductor therefor ) 是由 M·科佩 于 2018-10-16 设计创作，主要内容包括：本发明涉及一种矫形技术装置,其具有由电绝缘材料构成的基体和至少一个电导体,所述至少一个电导体布置在所述基体中或上。根据本发明设置,所述至少一个导体具有由能导电的弹性体构成的芯和电绝缘涂层。(The invention relates to an orthopedic device having a base body made of an electrically insulating material and having at least one electrical conductor which is arranged in or on the base body. According to the invention, the at least one conductor has a core made of an electrically conductive elastomer and an electrically insulating coating.)

1. Orthopedic device having a base body (12) made of an electrically insulating material and at least one electrical conductor (2) which is arranged in or on the base body (12),

it is characterized in that the preparation method is characterized in that,

the at least one conductor (2) has a core (4) made of an electrically conductive elastomer and an electrically insulating coating (6).

2. The orthopedic device according to claim 1, wherein the elastomer is silicone, thermoplastic elastomer, or polyurethane, and graphite particles, carbon black particles, and/or metal particles and/or carbon nanotubes are in the elastomer.

3. The orthopedic technical device according to claim 1 or 2, characterized in that the electrically insulating coating (6) has or consists of parylene.

4. The orthopedic device according to one of the preceding claims, characterized in that the material of the base body (12) has or consists of silicone, thermoplastic elastomer or polyurethane.

5. The orthopedic technical device according to one of the preceding claims, characterized in that the device has at least one electrode (14) and/or at least one sensor, wherein the electrode (14) and/or the sensor is electrically connected with the at least one conductor (2) and is preferably arranged such that it is in contact with a body part in a state in which the device is placed on the body part.

6. The orthopedic technical device according to one of the preceding claims, characterized in that the at least one conductor (2) has a screen (8) of an electrically conductive, elastic material, preferably an elastomer, which is arranged on the side of the insulating coating (6) facing away from the core (4).

7. The orthopedic technical device according to claim 6, characterized in that the screen (8) is of the same material as the core (4) or consists of the same material as the core.

8. A conductor for use in the orthopedic device according to any of the preceding claims.

9. A method for manufacturing the conductor according to claim 8, characterized in that the coating is manufactured by a CVD method.

Technical Field

The invention relates to an orthopedic device having a base body made of an electrically insulating material and having at least one electrical conductor which is arranged in or on the base body. The invention further relates to a conductor for the orthopedic device and to a method for producing the conductor.

Background

Within the framework of the invention, orthopedic devices are in particular orthoses, prostheses, in particular prosthetic sockets and prosthetic sleeves or other rehabilitation devices. Orthopedic devices are nowadays equipped in many cases with electrodes in order to receive electromyographic signals and transmit them onwards to a data processing device or in order to transmit electrical stimulation signals to the skin and/or the muscles below the skin of the patient of the orthopedic device, i.e. the wearer. This is advantageous in particular in the case of prosthesis sleeves, since they are in direct contact with the skin of the wearer and are therefore particularly suitable for the respective electrode for the wearer. The invention is of course not limited to prosthetic liners.

From the prior art, a series of different electrodes are known, which are in contact with the skin of the orthopedic device. The electrodes can be arranged, for example, on the inner side of an orthopedic device, for example a prosthesis socket, i.e. directly in contact with the skin, or positioned on the outer side of the socket, for example on the inner side of a prosthesis shaft surrounding the socket. In this case, the bushing usually has an electrically conductive conduction means, for example in the form of a metal rivet, or an electrically conductive silicone region, so that the orthopedic device can conduct electricity in the region of the electrode.

However, it is disadvantageous that in this case the electrodes must be arranged precisely at the location at which the conducting device is also arranged in orthopedic devices, and furthermore the electrodes must be arranged directly at the location on the wearer, for example on the amputation stump. The electrodes, which are usually space-intensive, are therefore usually not arranged in an optimal position.

A number of different possibilities for arranging electrical conductors in or on a substrate made of an electrically insulating material are therefore known from the prior art. It is known, for example, to use silver fabrics in order to conduct electrical signals through the base body of an orthopedic device to a site for further processing, for example an electronic data processing device. However, the use of silver is disadvantageous in that it is highly corrosive and also insufficiently resilient, in particular when the conductor produced in this way is arranged in an orthopedic device which itself consists of a resilient material.

A method is known from DE 102014106070 a1, in which a prosthesis sleeve is equipped with an electrically conductive conductor. In this case, the base body is first of all made of an electrically insulating elastomer material. The electrically insulating elastomeric material is crosslinked. The structure is then processed into a shaped first elastomeric material that is used as a mold for the electrical leads. A second elastomeric material is then added to the structure, the second elastomeric material being electrically conductive and then crosslinked. The electrical conductor is produced in the manner described from an electrically conductive elastomer material, which is arranged in a recess in the base body.

However, disadvantageously, the method described only allows the arrangement of electrically conductive structures on the surface of the base body and is furthermore complex and therefore time-consuming and costly.

Disclosure of Invention

The object of the present invention is therefore to further develop an orthopedic device according to the preamble of claim 1 in such a way that the electrical conductors can be arranged in or on the main body in a particularly simple manner and that, in addition, the spring properties of the main body are not negatively influenced.

The invention solves the stated object by means of an orthopedic device according to the preamble of claim 1, which is characterized in that at least one conductor comprises a core of an electrically conductive elastomer and an electrically insulating coating.

The conductor may be in the form of a cable or wire, for example. The elastomer of the core can be made electrically conductive, for example by adding particulate electricity. A coating of an electrically insulating material is applied to the core of such a shaped conductor or cable, for example as already mentioned. The coating advantageously does not negatively influence the elastic and flexible properties of the core, so that the elastic and flexible properties correspond to the elastic and flexible properties of the electrical conductor. The conductor can then be easily arranged in or on the base body of the orthopedic device, for example, injected into the elastomer material of the prosthesis sleeve. Since in this case both the core of the electrical conductor and the electrically insulating material of the base body are elastomers, the elastic properties of the orthopedic device are not negatively influenced.

Advantageously, the elastomer of the core is a silicone, a thermoplastic elastomer or a polyurethane, the graphite particles, carbon black particles and/or metal particles and/or carbon nanotubes being in the elastomer. Alternatively or additionally, electrically conductive fibers may also be used.

Preferably, the electrically insulating coating has or consists of parylene. The use of parylene as an insulating coating is furthermore advantageous, in particular, if both the electrically insulating material of the base body and the electrically conductive elastomer of the conductor thus do not only achieve an electrical insulating effect, but also ensure good adhesion between the material of the base body of the orthopedic device and the electrical conductor.

Preferably, the material of the base body has or consists of silicone, thermoplastic elastomer or polyurethane.

Advantageously, the orthopedic device has at least one electrode and/or at least one sensor, wherein the electrode and/or the sensor is electrically connected to at least one conductor and is preferably arranged such that the electrode and/or the sensor is in contact with the body part in the state of the device resting on the body part. In this way, particularly good contact is achieved for the transmission of electrical signals and pulses and at the same time ensures that reliable continuation of the transmission of signals is ensured also under strong mechanical and/or thermal loading of the orthopedic device. The at least one sensor preferably has a pressure sensor, a temperature sensor and/or a humidity sensor, a pulse measurement sensor and/or a blood flow measurement sensor (NIRS) and/or a sensor for measuring blood pressure levels.

Instead of arranging the electrodes and/or sensors on the skin of the wearer of the orthopedic technical device, the electrodes and/or sensors can also be held at a distance from the skin when they operate capacitively or inductively.

Preferably, at least one conductor has a shield made of an electrically conductive elastomer, which is arranged on the side of the insulating coating facing away from the core. The electrical conductor is thus constructed in three layers from the radially inner to the radially outer part and has, firstly, on the inside a core of an electrically conductive material, preferably an elastomer, which is covered by an electrically insulating coating, on the outside of which the shielding is located. In this way, it is possible to produce an electrical conductor of a shielded coaxial cable which does not negatively influence the elastic and flexible properties of the prosthesis sleeve in particular.

Preferably, the shield is of the same material as or consists of the same material as the core of the electrical conductor.

The invention also solves the stated object by means of a conductor for an orthopedic device described herein. The invention also solves the stated object by means of a method for producing the conductor, which is characterized in that the coating is produced by means of a CVD method. The abbreviation CVD stands for "Chemical vapor deposition" and is referred to as a Chemical coating process, which is known to the person skilled in the art from the prior art.

Drawings

Embodiments of the invention are explained in detail below with the aid of the figures.

In the drawings:

fig. 1 shows a schematic cross-sectional view of a cut through a conductor for an orthopedic device according to a first embodiment of the invention, an

Fig. 2 to 6 show different orthopedic devices according to further exemplary embodiments of the present invention.

Detailed Description

Fig. 1 shows a sectional view through an electrical conductor 2 for an orthopedic technical device according to a first exemplary embodiment of the present invention in a left-hand view. The electrical conductor 2 has a core 4 made of an electrically conductive elastomer, for example silicone provided with graphite particles. The core 4 is surrounded by a coating 6 consisting of an electrically insulating material, for example parylene.

In the middle view of fig. 1, an electrical conductor 2 is shown, in which a core 4 with a coating 6 surrounding it is surrounded by a shield 8, which is likewise composed of an electrically conductive elastomer and is arranged on the side of the insulating coating 6 facing away from the core 4. In this way, an electrical conductor 2 can be produced which has the properties of a coaxial cable with an electrical shield 8.

In the right-hand view of fig. 1, an electrical conductor 2 is shown, which, as in the middle view, has a shield 8, which is, however, surrounded by a second coating 10. Like coating 6, second coating 10 is an electrically insulating coating, which advantageously consists of the same material as coating 6.

Fig. 2 shows an orthopedic device in the form of a knee bandage. The orthopedic device has a base body 12, which can be made of, for example, an elastic fabric and can have a thickening, a cushion or an inserted or added cushion element. In the exemplary embodiment shown, six electrodes 14 are incorporated into the base body 12, which are each connected to an electrical conductor 2. The electrical conductor 2 connects the electrode 14 with an electrical control device 16, which is schematically shown in fig. 2. The electronic control device 16 is provided for further processing of the electrical signals, which are transmitted from the electrodes 14 to the electronic control device 16 via the electrical conductor 2 and, if necessary, are transmitted to an electronic data processing device. This can be achieved, for example, by means of cables, which are not shown in fig. 2, which is particularly advantageous if the electronic data processing device is arranged in the electronic control device 14 or at least on the base body 12 of the orthopedic technical device. It may therefore be expedient, for example, to further process the electrical signals transmitted by the electrodes 14 in the form of electronic data in the electronic control unit 16 in such a way that they can be stored in an electronic data memory, which is advantageously part of the orthopedic device, until they can be read and evaluated. Alternatively or in addition, it can be advantageous to enable wireless transmission of electronic data from the electronic control device 16 to the electronic data processing device.

Fig. 3 shows an orthopedic device in the form of a lower leg prosthesis according to a further embodiment of the invention. The base body 12 is designed in the form of a prosthesis shaft, on which the electrodes 14 are arranged and which is connected to an electrical control device, not shown, via electrical conductors 2. A lower leg member 18 and an artificial foot 20 are located on the base 12. Via the electrodes 14, for example, an electromyographic signal can be received from an amputation end arranged in the base body 12. The electromyographic signals are conducted via the electrical conductor 2 to the electrical control device and are used to control the artificial foot 18.

Fig. 4 shows a further embodiment of an orthopedic device according to an exemplary embodiment of the invention, which is likewise designed as a prosthesis, however here as a hand prosthesis and a forearm prosthesis. The base body 12 also forms a prosthesis shaft, on which the electrodes 14 are arranged and which are connected to the electrical control device 16 via the electrical conductors 2. The electric control device 16 is provided for generating a control signal for the prosthetic hand 22 from the electric signal received from the electrode 14 and thereby controlling the function of the prosthetic hand 22. The orthopedic device shown in fig. 4 also has a power supply 24, by means of which the electrical control device 16 can be supplied with electrical current.

Fig. 5 shows an embodiment of an orthopedic device configured as a shoulder prosthesis. Base 12 extends over the shoulder area of wearer 26 and extends along the arms of wearer 26 until past the elbows. Base 12 has a strap 28 that wraps around the torso of wearer 24. The electrodes 14 are arranged not only on the fastening strips 28, which are part of the base body 2, but also on other parts of the base body 12, for example an upper arm element 30 and a forearm element 32, which are connected to the electrical control device 16 via the electrical conductor 2.

Fig. 6 shows an orthopaedic device in the form of a T-shirt, which itself forms the base body 12. Electrodes 14 are arranged both on the sleeves 34 and on the remaining part of the base body 12, which are in turn connected to the electrical control device 16 via the electrical conductor 2. The difficulty in this configuration of the orthopedic device is to establish the best possible contact between the electrodes 14 and the skin region of the wearer 24. This may be achieved, for example, by cutting out of a T-shirt, elastic material or adding straps.

List of reference numerals

2 electric conductor

4 core

6 coating

8 shield part

10 second coating

12 base body

14 electrodes

16 electric control device

18 lower leg element

20 Artificial foot

22 artificial hand

24 power supply

26 to a wearer

28 fixing belt

30 upper arm element

32 forearm component

34 sleeves