DE8701668U1 - Laser device for medical applications - Google Patents

Description

HOEGER, STELLRECHT & PARTNER

PATENT ATTORNEYS UHLANDSTRASSE Hc-D 7OOC1 .STUTTGART 1

A 47 282 u Note: AESCULAP-WERKE AG

12 January 1987 formerly Jetter & Scheerer

^U ~ ²²⁰ 7200 Tuttlingen

LASER DEVICE FOR MEDICAL APPLICATIONS

The innovation concerns a laser device for medical applications with a plug connection to which glass fibers acting as light guides can be connected via a connector, and with a decailing device in ^the laser device for detecting different connectors connected to the plug connection.

Special glass fibers acting as light guides can be connected to medical laser devices with appropriate handpieces for different applications. After a specific fiber is plugged into the laser device, an electrical control circuit should automatically recognize the fiber type and set the required operating parameters of the laser device.

The aim of the innovation is to design a laser device of this type in such a way that the type of fiber connected to the laser device can be recognized using the simplest means, while at the same time ensuring that the recognition circuit in the laser device is galvanically separated from the connector for safety reasons. This task is solved in a laser device of the type described above by integrating an electrical resistor in the connector (iiti) which, when the connector is connected to the stepper connection, is

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January 12, 1987

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two electrical contacts in the plug connection are connected to the two ends of a secondary coil of a transformer of a detector circuit in the laser device, that the primary coil is connected in series with a fixed resistor in a primary current circuit of the detector circuit and that a voltage tap is provided between the primary coil and the fixed resistor.

The use of a transformer in the detection circuit ensures galvanic isolation of the ■resistance in the connector from the detection circuit in the laser device. With the circuit described, it is possible to determine the magnitude of the resistance in the connector, because this resistance to be measured appears multiplied by the square of the transformation ratio of the transformer in series with the fixed resistance of the detector circuit. The voltage tap between the transformer and the fixed resistance thus determines the partial voltage that drops across the fixed resistance, for example; this voltage depends on the magnitude of the resistance to be measured in the connector. The voltage taken at the voltage tap can either be displayed on a measuring device so that the operator can set the appropriate parameters required for this connector, or this voltage can be used directly to control a control circuit that automatically sets the appropriate operating parameters of the laser device.

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January 12, 1987

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If different types of glass fibers and handpieces are used, each type is assigned a specific value of resistance in the connector so that the circuit in the laser device automatically adapts its operating parameters to the type of fiber and handpiece used.

It is particularly advantageous if a capacitor is connected in parallel to the primary coil of the transformer to compensate for the inductance of the transformer. The detector circuit is usually operated at a constant frequency. Transformers that can be used in the detector circuits usually have different inductance values; the spread can be +/- 30%, for example. In order to compensate for these different inductance values, it is advantageous to connect a capacitor with the appropriate capacitance in parallel to each transformer, with the capacitance being matched to the actual inductance of the respective transformer. This means that the circuit can continue to be operated at a constant frequency in all devices, even if the transformers used have different inductance values. It has also been found that a significant improvement in the temperature behavior of the detector circuit can be achieved by connecting the capacitor in parallel.

The following description of a preferred embodiment of the innovation serves to explain in more detail in conjunction with the drawing. They show:

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January 12, 1987

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Figure 1 is a schematic diagram of the detector circuit of a laser device with a connected measuring resistor

Figure 2 shows a circuit similar to Fig. 1/ in which instead of the transformer, a resistor and an inductance are connected in parallel as an equivalent circuit

Figure 3 shows a circuit similar to Fig. 1 with a capacitor connected in parallel to the transformer.

The innovation concerns a laser device for medical applications of a known design in which laser radiation is generated by means of a laser, which is introduced into a glass fiber at a plug connection, which transmits the radiation to the application site. At the application site, the radiation either emerges directly from the glass fiber or it is emitted via an optical system, which is preferably integrated in a handpiece. Such arrangements are known and therefore not shown in the drawing.

In order to connect the glass fiber to the laser device, a plug connection is used in these known devices, whereby the glass fiber end is assigned a plug that can be plugged into the laser device.

According to the innovation, a measuring resistor 1 is integrated, for example cast, in the connector assigned to the end of the fiber optic cable. This resistor is

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January 12, 1987

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on both sides with electrical contacts 2/3 on the connector. These contacts 2 and 3 are connected to corresponding contacts on the plug connection of the laser device when the connector is plugged into the plug connection. These contacts of the laser device are connected via electrical lines 4 and 5 to the two ends of a secondary coil 6 of a transformer 7, which is part of a detector circuit 8 arranged in the laser device. When plugged in, the secondary coil 6 and the measuring resistor 1 form a closed secondary circuit of the transformer 7.

The primary coil 9 of the transformer 7 is connected in series with a fixed resistor 10 in a primary circuit. In the primary circuit, an alternating voltage with a fixed frequency is applied between two terminals 11 and 12. In addition, there is a voltage tap 13 between the primary coil 9 and the fixed resistor 10, from which a measuring voltage Uy can be tapped.

In the embodiment according to Figure 3, in addition to the transformer 7, a capacitor 14 of capacitance C is connected in parallel.

In operation, the value R of the measuring resistor 1 multiplied by the square of the transformation ratio of the transformer appears in series with the fixed resistor 10, whose value is indicated in the drawing as R _Q. In the equivalent circuit diagram of Figure 2, the value R multiplied by the square of the transformation ratio is

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Value of the measuring resistor 1 indicated with R ¹ - Parallel

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The inductance L _T of the transformer 7 is given in the equivalent circuit diagram of Figure 2 for this resistor which is connected in series with the fixed resistor 10. According to the embodiment of Figure 3, this is compensated by the capacitor 14 connected in parallel with the size CL.

The ratio of the effective measuring resistance R ¹ and the fixed resistance

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Stand 10 with the size R” is determined. This ratio depends on the size of the measuring resistor 1 with the size R, so that the voltage at the voltage tap 13

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certain voltage U is a measure for the size R of the

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measuring resistor 1. This voltage is used either to activate a corresponding display on the laser device or, preferably, directly to control a control circuit that sets the parameters of the laser device according to the respective connected fiber type.

In this way, it is possible to create an electrical detection circuit in a laser device using the simplest of means, which detects the different resistances in the various connected glass fibers and, if necessary, makes corresponding automatic adjustments to the laser operating parameters. Nevertheless, the galvanic isolation ¹ required for safety reasons between the detector circuit in the laser device on the one hand and the connector and the measuring resistor 1 integrated therein on the other hand is guaranteed.

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Claims (2)

PROTECTION CLAIMS: 1. Laser device for medical applications with a plug connection to which glass fibers acting as light guides can be connected via a connector, and with a decoding device in the laser device for detecting different connectors connected to the plug connection, characterized in that an electrical resistor (1) is integrated in the plug connector, which, when the plug connector is connected to the plug connection, is connected via two electrical contacts (2, 3) in the plug connection to the two ends of a secondary coil (6) of a transformer (7) of a detector circuit (8) 121 laser device, that the primary coil (9) is connected in series with a fixed resistor (10) in a primary circuit of the detector circuit (8) and that a voltage tap (13) is provided between the primary coil (9) and the fixed resistor (10). 2. Laser device according to claim 1, characterized in that a capacitor (14) is connected in parallel to the primary coil (9) of the transformer (7) to compensate for the inductance of the transformer (7),