DE29901542U1 - Battery operated micromotor for medical applications - Google Patents

Description

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Dr. Rainer E. Sachse

Lerchenstr.53
90425 Nuremberg

Battery-powered micromotor for medical applications

Description

The use of motor systems is firmly established in the field of medicine for driving drills, milling machines, saws and dermatomes, etc. There are essentially three different systems that are currently used clinically:

1.) Drives powered by pressurized gases, 2.) Electric drives where the energy is transferred to the desired handpiece via a shaft,

3.Electrical micromotor drives in which the motor unit of a micromotor is attached directly to the handpiece, with the electrical connecting cables being led to an external control unit which supplies the micromotor with a suitable voltage.

The main problem with these three systems is the fact that setting up these sterile devices takes a relatively long time, as the work has to be carried out under sterile conditions and the connecting cables have to be brought from the sterile to the non-sterile area. In addition, the cables are often a nuisance in clinical operations, as they often lie or hang around uncontrolled and, apart from looking untidy, also pose a sterility risk.
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The aim of the invention was therefore to design a motor system in such a way that battery-powered operation with the simplest possible operation and maximum safety for the patient is possible.

This object was achieved according to claim 1 in that the motor and the (unsterile) batteries that supply it are located in a sterilizable and sealed housing, which is provided with a connection mechanism for commercially available handpieces and a switch. At the start of the operation, the non-sterile batteries and possibly also the drive motor are inserted into the housing and then screwed in sterilely. An external switch can then be plugged in and the handpiece suitable for the planned procedure (e.g. drilling, sawing or tattooing handpiece) can be plugged in. All of this requires minimal effort and time, while at the same time minimizing the risk of contamination.

Two preferred embodiments are shown in longitudinal section in Fig. 1 and 2:

Showing:

Fig 1 the arrangement with batteries stored behind the engine and Fig.2 the arrangement with a circular battery arrangement,

The drive unit consists of a drive motor 1, which is located in a handle casing 2. On the output side, the motor is provided with a driver 3 for connecting commercially available handpieces 4, and on the handle casing there is a suitable plug connection 5 (preferably INTRA standard) for attaching a handpiece 4. On the side of the motor opposite the driver 3 there is an electrical carrier plate 6, to which the motor 1 is electrically connected, and which is electrically connected to the battery insert with electrical contact points 7 via springs 8 that are attached to the battery insert. A seal 9 eliminates the transport of germs from the unsterile battery insert 10 to the sterile motor 1. The battery insert 10, in which several batteries 11 are located, can be easily pulled out of the handle casing 2. On the side of the unit opposite the plug connection 5 there is a cover 12 which, together with a seal 13, ensures germ-tight closure of the handle sleeve 2.

In this cover 12, in addition to the locking mechanism 14, there is also a rotary knob 15 and a plug sleeve 16, which is integrated into it and into which an external switch 17 can be plugged using a (sterile) plug 18 and a cable 19. The external switch 17 can be designed so that it can be plugged onto the handpiece 4, or it can be constructed as a regular foot switch. The rotary knob 15 is connected to an internal electrical rotary switch 20, which is connected to the battery slot 10 via electrical contacts 21 and supplies the motor 1 with power. The rotary switch 20 is provided with a seal 22.

The version shown in Fig. 2 with a circular arrangement of the batteries is slightly thicker for mechanical reasons, but has the significant advantage that the center of gravity is closer to the handpiece, which is more ergonomic for precise work.

List of reference symbols

1 Drive motor 2 Grip sleeve 3 Driver 4 Handpiece 5 Plug connection 6 Electrical carrier plate 7 Electrical contact points 8th feathers 9 poetry 10 Battery slot 11 Batteries 12 End cap 13 poetry 14 Locking mechanism 15 Rotary knob 16 Plug sleeve 17 Switch 18 Plug 19 Cable 20 Rotary switch 21 Electrical contacts 22 poetry

Claims (8)

Dr.Dr. Rainer E. Sachse Lerchenstr.53
90425 Nuremberg Expectations: 1. Battery-operated micromotor for medical applications, characterized in that it is located together with batteries in a sterilizable housing which is provided with a connection mechanism for commercially available handpieces (preferably INTRA standard) and a switch. 2. Device according to claim 1, characterized in that the batteries surround the motor. 3. Device according to claim 1 and 2, characterized in that the batteries are arranged behind the motor. 4. Device according to claims 1 -3, characterized in that the device is additionally provided with a plug connection for an external switch or an external variable resistor. 5. Device according to claims 1 - 4, characterized in that the device is provided with a device (e.g. switch, potentiometer) with which the speed of the motor can be adjusted. 6. Device according to claims 1 - 4, characterized in that the device is connected to an internal control electronics with which the motor can be controlled. 7. Device according to claims 1-6, characterized in that the battery can be removed from the device as a unit together with the electrical control 8. Device according to claims 1-7, characterized in that the motor together with the batteries and the electrical control can be removed from the device as a unit and is connected to a drive shaft remaining in the housing with a driver.