DE19741824A1 - Monitoring siliconization mist inside pharmaceutical container - Google Patents

Abstract

A light beam is directed through the container, measuring the scattered light from its interior. Mist is reliably detected within, by evaluating the output of a photoelectric detector. An Independent claim is included for the corresponding apparatus. The light source (8) passes a beam through the container. The photoelectric detector (10) is placed to intercept scattered light. The measurement circuitry (13) evaluates the signal, establishing presence of mist. Preferred features: In the apparatus, the source is a laser, preferably a semiconductor laser diode. The receiver is a photo diode with integral pre-amplifier (10, 12). The photodiode includes an optical line filter (11), transparent to the waveband of the source, to reject scattered ambient light. The photodiode circuit includes an electronic filter, preferably a lock-in amplifier, to reject effects of ambient light. The evaluation circuitry (13) includes an analogue-to-digital (ADC) converter followed by a digital computer. The digital computer is a microprocessor or a PC. In evaluation, the photodiode output is integrated and compared with a threshold value. On exceeding this, an alarm and/or control signal are generated. Where the beam leaves the container, a second photoelectric detector (14), preferably a photodiode, has its own evaluation circuitry. The container is a pharmaceutical packing container.

Description

The invention relates to a method for monitoring the application of a Internal siliconization in a transparent container by means of an in the Inside of the container sprayed silicone spray. Specifically relates the internal siliconization of a transparent pharmaceutical Packaging container.

The invention further relates to a device for carrying out a such procedure.

For example, in the field of pharmaceutical packaging Packaging containers, e.g. B. pharmaceutical vials, which predominantly from one transparent material such as plastic or glass are made for certain Provide uses with an inner siliconization. Applying this Internal siliconization is usually done by using a silicone spray is generated and sprayed into the interior of the pharmaceutical packaging container becomes. Compressed air, which can be operated via a valve, turns one Storage vessel with silicone emulsion sucked in and by means of a spray nozzle nebulized.

If there is an error in the spray system, e.g. B. a malfunction of the valve, a Compressed air fluctuation, a missing silicone emulsion, then experience the Packaging containers no or only an insufficient silicone coating.  

So far, the silicone nebulizer has only been checked randomly, so that if a malfunction was discovered too late, a large number of pharmaceutical packaging containers was either unusable (Committee) or reworked.

A comparable is the case for other containers for other uses Given problems.

The invention is based, based on the task designated method or the associated device, a 100% Kon trolle the internal siliconization to provide when applying, since in usually, a later one especially for the field of pharmaceutical packaging 100% control of the siliconization is omitted for cost reasons.

This problem is solved for the process with the steps:

• Directing a light beam through the container,
• - Detect the inside of the pharmaceutical packaging container outgoing stray light through a photoelectric receiver, and
• - Evaluation of the output signal of the photoelectric receiver reliable detection of the presence of a spray mist inside of the container.

With regard to the associated device for monitoring the application of an internal siliconization to a transparent container by means of a silicone spray mist sprayed into the interior of the container, the object is achieved with:

• - A light source which is arranged in relation to the container that she shines through this,  
• - a photoelectric receiver which is so related to the Container is arranged so that it from the inside of the container outgoing stray light is detected, and
• - An evaluation circuit for the output signal of the photoelectric Receiver for the reliable detection of the presence of a Spray mist inside the container.

Due to the presence of a silicon spray inside the The stray light is changed significantly so that a reliable detection of the presence of spray mist inside the Container is possible. From the scattered light signal, the amount of Silicon spray mist can be recognized and thus a 100% check of the correct one Siliconization of the respective container can be made.

According to a first embodiment of the invention, a is used as the light source Laser, preferably a semiconductor laser diode used. Such Light source creates a sharply focused beam of light in a narrow Wavelength range that produces a particularly pronounced stray light.

According to a further embodiment of the invention, the Photoelectric receiver from a photodiode, preferably with a Integrated preamplifier that works on the wavelength of the laser light is coordinated.

Such a photoelectric receiver arrangement is particularly inexpensive and yet very sensitive.

According to a development of the invention, the photodiode is preferably a optical, transmissive in the wavelength range of the light source used Line filter to suppress ambient light  Scattered light upstream. Such an optical line filter enables hence a particularly distinctive useful signal.

It is also conceivable for the photodiode to be an electrical filter, preferably an Assign lock-in amplifier to suppress ambient light also not to falsify the useful signal by the ambient light.

A number of are available to the person skilled in the art for the evaluation circuit Options available. The evaluation circuit preferably contains an analog / digital converter with a downstream digital Computing unit, which according to a development of the invention Microprocessor or a PC can be.

Preferably, the evaluation circuit is constructed so that it Output signal of the photodiode integrated and a threshold with a Comparison level specifies that an alarm and / or if the threshold value is exceeded generates a control signal.

According to a further embodiment of the invention, in the area in which the Beam of the light source emerges from the container, a second photoelectric Receiver arrangement, preferably provided a photodiode, which Functionality of the light source, especially the laser, can be seen.

Further design features and advantages of the invention result based on the description of one shown in the drawings Embodiment using the example of a pharmaceutical packaging container.

Show it:  

Fig. 1 is a schematic block diagram representation of an apparatus for monitoring the application of a Innensilikonisierung according to the invention,

Fig. 2 in a diagram the course of the intensity of the scattered light over time, depending on the spraying of a silicone spray into the packaging container.

Fig. 1 shows in a schematic block diagram representation of an apparatus for monitoring the application of a Innensilikonisierung in a transparent pharmaceutical packaging container, in the present example of a bottle 1 by means of a silicone spray 2, which is introduced into the interior of the vial 1.

To produce the spray mist 2 , a storage vessel 3 is provided with a silicone emulsion 4 , from which the silicone emulsion is sucked in by means of compressed air, which is supplied to a hose system 5 with a valve 6 , and atomized into the vial 1 via a spray nozzle 7 .

By a malfunction of the valve 6 , or by compressed air fluctuations, but also, for. B. by a lack of silicone emulsion 4 in the storage container 3 , the internal siliconization of the vial 1 can be omitted or can only be insufficient.

To monitor the siliconization, the invention provides for optical monitoring via the scattered light from the spray mist 2 . For this purpose, a light source 8 , which is preferably formed by a laser diode, is provided, which is arranged in relation to the vial 1 in such a way that it shines through it in the transverse direction. The light beam generates scattered light due to the spray 2 , which is detected in the cone 9 by a photodiode 10 . An optical line filter 11 is located in front of the photodiode 10 and is only transparent to the wavelength range of the light from the light source 8 and thus suppresses the stray light emitted by the ambient light. A preamplifier 12 is preferably integrated with the photodiode 10 .

The device according to FIG. 1 also has an evaluation circuit 13 for the output signal of the preamplifier 12 connected downstream of the photodiode 10 , represented symbolically as a digital computing unit. This computing unit 13 can be implemented by a microprocessor or by a PC. It is programmed in such a way that it preferably integrates the output signal of the photodiode and specifies a threshold value with a comparison stage which, when the threshold value is exceeded, generates an alarm and / or control signal, e.g. B. to turn off the valve, as shown, releases.

The output signal of the photodiode 10 or of the downstream preamplifier 12 expressing the light intensity of the scattered light over time is shown in the diagram according to FIG. 2. At the beginning of the spraying in of a silicon mist, an easily detectable typical drop in the optical scatter in the spray jet and thus the light intensity I of the scattered light can be seen. This electrical signal can easily be converted into a digital signal via an A / D converter and processed in the evaluation stage 13 .

The quantity of the spray can also be recognized from the scattered light signal and a reliable 100% control of the siliconization of the vial 1 can be provided.

In addition to the integral evaluation of the output signal of the preamplifier 12 , other algorithms, e.g. B. the evaluation of the peak value, a value at time X, or the like, application.

Instead of the optical line filter 11 , an electrical filter, for. B. find a lock-in amplifier application that ensures the suppression of ambient light.

It is expedient to use a second photodiode 14 , which detects the light emanating from the light source 8 and shining through the vial 1 in order to document the function of the laser 8 .

Claims (11)

1. A method for monitoring the application of an internal siliconization to a transparent container by means of a silicone spray sprayed into the interior of the container, with the steps:

• Directing a light beam through the container,
• Detection of the scattered light emanating from the inside of the container by a photoelectric receiver,
• - Evaluation of the output signal of the photoelectric receiver for reliable detection of the presence of a spray in the interior of the container.

2. Device for monitoring the application of an internal siliconization to a transparent container by means of a silicone spray sprayed into the interior of the container, with:

• - a light source ( 8 ) which is arranged in relation to the container ( 1 ) in such a way that it passes through it,
• - A photoelectric receiver ( 10 ) which is arranged with respect to the container ( 1 ) that it detects the scattered light emanating from the inside of the container ( 1 ), and
• - An evaluation circuit ( 13 ) for the output signal of the photoelectric receiver ( 10 ) for the reliable detection of the presence of a spray in the interior of the container ( 1 ).

3. Apparatus according to claim 2, characterized in that the light source ( 8 ) is a laser, preferably a semiconductor laser diode. 4. Apparatus according to claim 2 or 3, characterized in that the photoelectric receiver ( 10 ) is a photodiode, preferably with an integrated preamplifier ( 12 ). 5. The device according to claim 4, characterized in that the photodiode ( 10 ) is assigned an optical, in the wavelength range of the light source used ( 8 ) transparent line filter ( 11 ) for suppressing the stray light emanating from ambient light. 6. The device according to claim 4, characterized in that the photodiode ( 10 ) is associated with an electrical filter, preferably a lock-in amplifier for suppressing the ambient light. 7. Device according to one of claims 2 to 6, characterized in that the evaluation circuit ( 13 ) has an analog / digital converter and a digital arithmetic unit connected downstream. 8. The device according to claim 7, characterized in that the digital Computing unit is a microprocessor or a PC. 9. The device according to claim 7 or 8, characterized in that the evaluation circuit ( 13 ) is constructed so that it integrates the output signal of the photodiode ( 10 ) and specifies a threshold value and a comparison stage which, when the threshold value is exceeded, an alarm and / or generates a control signal. 10. Device according to one of claims 2 to 9, characterized in that in the area in which the beam of the light source ( 8 ) emerges from the container ( 1 ), a second photoelectric receiver ( 14 ), preferably a photodiode, with an associated Evaluation circuit is provided. 11. The device according to any one of claims 1-10, characterized in that the container ( 1 ) is a pharmaceutical packaging container.