DE19815927A1 - Infrared radiation thermometer with otoscope function - Google Patents

Abstract

The infrared radiation thermometer has an observation device (30,32) for visual observation of the temperature measurement spot region, a housing (10) with a radiation inlet opening (14), an i.r. sensor (26) and at least one optical system (20,24) deflecting the i.r. radiation incident at the inlet opening to the sensor and/or the visible light incident at the opening to the observation device.

Description

The present invention relates to an infrared radiation thermometer, in particular a Ear clinical thermometer.

Infrared radiation thermometers of the type mentioned are used both for domestic purposes need as well as in the medical / medical field increasingly fast and precise determination of the body temperature of a human being used, whereby Usually simply a measuring tip of the Thermometer is inserted into the ear canal to measure the radiation emitted by the eardrum Measure infrared radiation. Because the eardrum is connected to the same bloodstream is like the temperature center in the brain, the eardrum temperature is a more accurate Indicator of the core body temperature of humans and reflects their changes much faster, better and more accurately than with oral, rectal or axilla measurements. In contrast to oral or rectal measurements using a conventional mercury thermometer there is also no danger mutual infection through contact with the mucous membranes. Further there is also no risk of perforation in the intestine, which occurs with rectal temperature measurements not to be compared with conventional mercury thermometers in babies and children is negligent.

With infrared ear thermometers, however, there is a risk that the measurement result by Geometry of the respective ear canal is noticeably influenced. Usually there is namely a difference between the temperature of the eardrum and the temperature of the surrounding ear canal tissue. Because of the different natural strengths Curvature of the auditory canal as well as frequently existing bumps (exostoses) is with a conventional infrared ear thermometer does not always ensure that the Measuring tip is aligned to the eardrum and not at least partially to the surrounding tissues with its lower temperature. Also a subjectively correct fit The measuring tip is not a guarantee of correct alignment with the drum fur, since in the worst case a partial coverage of the radiation entry opening through a skin fold to a strong directional dependence of the measured  Temperature and thus lead to incorrect measurements with poor reproducibility can.

In practice, different methods are used to solve this problem turns. So z. B. the shape of the front measuring tip area so chosen that the Measuring tip fits into as many ear canal shapes and sizes as possible. In addition positioning instructions are given in the operating instructions for this purpose Help users find the optimal position. Because of the very under however, different ear canal sizes and shapes result for each selected one Tip shape always with some of the user positioning disadvantages. It can also the alignment of the measuring tip to the eardrum cannot be checked and it takes place no feedback about the quality of the positioning.

Another possibility is that one built into the ear clinical thermometer The acoustic signal generator emits a signal tone each time the measured Temperature value increased by swiveling the measuring tip in the ear. The evaluation of the Areas rated according to temperature, however, are highly random and it gives no control over whether the eardrum is the warmest area overall was also included in the evaluation. It is also due to the acoustic Signal tones hardly possible to measure on sleeping people without disturbing them.

According to the teaching of PCT application WO 95/14913, several sensors can also be used be used to multiply the infrared radiation at different angles areas of the ear. This increases the overall coverage area so that the risk of incorrect positioning is reduced. The larger number infrared sensors, however, involve a much higher technical outlay the one that naturally translates into higher costs.

WO 97/06419 describes a device for non-contact temperature measurement known that a sighting device to identify the location and size of the Has measuring spots by means of visible light, the temperature of which is measured. For Temperature measurement is the heat radiation emanating from the measuring spot  optical system imaged on an infrared detector. However, this device is for use as an ear fever thermometer is unsuitable because it is used for a temperature measurement the ear canal is completely filled by the measuring tip of the thermometer, and therefore the light marking characterizing the measuring spot cannot be observed.

An infrared thermometer with an eyepiece is known from WO 97/42474 Function is not described. In any case, this thermometer is not suitable as Otoscope, since it has no lighting device with which to illuminate the inside of the ear can be tet. For the same reason, it cannot align the measurement tip can be used within the ear canal.

The object of the present invention is therefore to create an infrared Radiation thermometer, avoiding temperature measurement in the ear of the above-mentioned disadvantages of the prior art, an optimal alignment of the Measuring tip to the eardrum guaranteed.

This task is invented in a generic infrared radiation thermometer in accordance with an observation device for visual observation of the Temperature measuring area solved.

The observation device enables an optimal alignment of the measuring tip to Eardrum so that the above-mentioned error possibilities at one temperature measurement using a conventional ear fever thermometer is not only a thing of the past with a higher measuring accuracy but also with a higher measuring certainty and a better reproducibility of a measurement than in the prior art is. In addition, the observation device enables during a temperature measurement or independent of such a measurement to a third party, such as B. a doctor, in to see the ear, d. H. to carry out an ear examination like with an otoscope, so that the ear fever thermometer according to the invention in contrast to conventional Thermometers can be used not only as a thermometer but also as an otoscope. This eliminates the usual use of two single devices for through Conducting a temperature measurement or an ear examination, which naturally also includes  higher acquisition costs as well as more maintenance and Care and a larger consumption of auxiliary materials, such as. B. Hygiene protective sleeve len, is connected. When using two single devices, the sub are also search times correspondingly longer.

The radiation thermometer according to the invention has a radiation entry opening housing, an infrared sensor and at least one optical system stem that the infrared radiation incident in the radiation inlet opening to the In infrared sensor and / or the visible light entering the radiation entrance opening leads to the observation facility.

In a preferred embodiment, the optical system has a beam splitter, which is reflective for infrared radiation and transparent to visible light and between the radiation inlet opening on the one hand and the observation device and the infrared sensor is arranged on the other hand. The through the radiation entrance opening Incident infrared radiation is transmitted through the beam splitter in the direction of the infrared sensor reflected and advantageously by means of a converging lens on the infrared sensor focused. The evaluation of a temperature signal supplied by the infrared sensor by means of an associated evaluation electronics takes place in a manner known per se.

In an alternative embodiment, the infrared radiation according to the invention has thermometer a curved beam splitter that is reflective for infrared radiation and for visible light is permeable and so between the radiation inlet and the Infrared sensor is arranged that the incident through the radiation entrance opening Infrared radiation is focused on the infrared sensor.

In the two above-mentioned versions of an infrared beam according to the invention lung thermometer results in a particularly simple construction if the observation device is arranged opposite the radiation inlet opening.

In a further embodiment for an infrared radiation according to the invention This thermometer contains a light guide that passes through the radiation entry opening  incident infrared radiation leads to the infrared sensor, cf. for example the older one Application DE 197 13 608. In this embodiment, the optical system preferably a beam splitter that is transparent to infrared radiation and visible bare light is reflective and between the radiation inlet opening on the one hand and the observation device and the infrared sensor is arranged on the other hand.

An infrared radiation according to the invention contains for illuminating the measurement spot thermometer a light source for visible light that passes through the radiation entry opening voltage can illuminate the temperature measuring area. With this arrangement If necessary, infrared radiation emanating from the light source may not be able to infrared sor, and therefore do not falsify the temperature measurement. Instead of a light source, a mirror or the like can also be provided, with the ambient light into the Inside the ear. In addition, the light can also be used to optically mark the respective spot area can be used. A correspondingly designed one Infrared radiation thermometer then has a suitable marking device, preferably with diffractive optical elements.

It is particularly advantageous for ear examinations if the observation device instead of an eyepiece, an image recording device, for example a CCD camera, contains so that the image of the measurement spot area is viewed on an external monitor can be.

A device for automatic maximum can be used in the evaluation electronics evaluation of all recorded temperature values should be provided, so that even with one not optimal alignment of the measuring tip automatically that of the body core temperature at Appropriate maximum temperature is displayed and thus the risk of Incorrect measurement is greatly reduced.

Further features and advantages of the present invention result from the following lowing description of a preferred embodiment of an inventive Infrared radiation thermometer with otoscope function, which is shown in the single figure is shown mathematically.  

The radiation thermometer shown comprises a housing 10 with a measuring tip 12 which tapers conically towards a radiation inlet opening 14 , and is completed by a radiation inlet window 16 in order to protect the interior of the housing against contamination. The radiation entrance window 16 is covered in a manner known per se for measurement with an interchangeable measuring cap (not shown) which is permeable to infrared radiation, in particular to prevent the transmission of diseases by contaminated measuring tips. The measuring tip 12 , which is usually provided with a thin polyethylene film or a copolymer, is inserted into a person's ear canal for temperature measurement.

The measuring tip 12 is part of a measuring head 18 with a beam splitter 20 which is reflective for infrared radiation but is transparent to visible light. The beam splitter is arranged opposite the radiation entry opening 14 in such a way that the infrared radiation entering the radiation entry opening from the eardrum is reflected in a lower housing section 22 serving as a handle. In the lower housing section 22 , which extends substantially at right angles to the measuring tip 12 , there is a converging lens 24 through which the infrared radiation is focused on an infrared sensor 26 , which is preferably formed as a pyroelectric sensor or as a thermopile sensor. This is connected to evaluation electronics 28 , from which the detected infrared radiation can be converted into a temperature indication and displayed by means of a display device (not shown). Due to the special beam path of the optical system, only the temperature of a measuring spot corresponding to the typical size of the eardrum is determined.

In other embodiments according to the invention, the lower housing section 22 can also be angled at a different angle from 90 with respect to the measuring tip 12 , as can be seen, for example, from WO 97/19322. In addition, the optical system of planar beam splitter 20 and converging lens 24 can be replaced by a curved steel splitter which is designed to reflect infrared rays and is arranged such that the incident infrared radiation is focused on the infrared sensor 26 .

The beam splitter 20 is transparent to visible light in both directions, so that visible light falling from the eardrum into the radiation entry opening can reach an observation device which is located behind the beam splitter 20 and has an eyepiece 32 . Between the eyepiece 32 and the beam splitter 20 , a light source 30 for visible light is arranged, which can fall through the beam splitter 20 onto the radiation inlet opening 14 - be it directly or via a light-conducting element - and thus illuminate the respective measurement spot in the ear. The observation device makes it possible to look into the ear illuminated by the light source through the radiation inlet opening 14 during the temperature measurement, to align the measuring tip optimally with respect to the eardrum and only then to initiate the temperature measurement.

Since the alignment of the measuring tip 14 can be checked and appropriately corrected with the aid of the observation device before or during a temperature measurement, it can be avoided that the average temperature of a measuring spot area, which only comprises part of the eardrum and otherwise the surrounding ear canal tissue, is determined , which would naturally lead to much less precise measurement results. Since the sources of error mentioned at the beginning do not apply to a temperature measurement using conventional ear thermometers, the infrared radiation thermometer according to the invention not only offers a much greater measurement accuracy than conventional radiation thermometers, but also greater measurement reliability and reproducibility of the measurement results.

In the construction of the measuring head shown, the outer shape of the measuring tip may be due to the visual control possibility of the alignment in the ear can be designed more freely, which allows better adaptation to different ear shapes and sizes (such as Children's ears) is possible.

In addition, the infrared radiation thermometer according to the invention can also independent of a temperature measurement for ear examination, d. H. as an otoscope use.

Claims (10)

1. infrared radiation thermometer, in particular ear fever thermometer, characterized by an observation device ( 30 , 32 ) for visual observation of the temperature measuring area. 2. Infrared radiation thermometer according to claim 1, characterized in that it further comprises a radiation entry opening ( 14 ) having a housing ( 10 ), an infrared sensor ( 26 ) and at least one optical system ( 20 , 24 ) which in the radiation entry opening ( 14 ) incident infrared radiation to the infrared sensor ( 26 ) and / or in the radiation entry opening ( 14 ) incident visible light on the observation device ( 30 , 32 ). 3. Infrared radiation thermometer according to claim 2, characterized in that the optical system has a beam splitter (20?, Which is reflective for infrared radiation and transparent to visible light and between the radiation inlet opening ( 14 ) on the one hand and the observation device ( 30 , 32nd ) and the infrared sensor ( 26 ) on the other hand. 4. Infrared radiation thermometer according to claim 2 or 3, characterized in that the optical system further comprises a converging lens ( 24 ) for focusing the infrared radiation on the infrared sensor ( 26 ). 5. Infrared radiation thermometer according to claim 2, characterized in that the optical system comprises a curved beam splitter which is reflective for infrared radiation and transparent to visible light and is arranged between the radiation inlet opening ( 14 ) and the infrared sensor ( 26 ) that the infrared radiation incident through the radiation inlet opening ( 14 ) is focused on the infrared sensor ( 26 ). 6. Infrared radiation thermometer according to one of claims 2 to 5, characterized in that the observation device ( 30 , 32 ) is arranged opposite the radiation inlet opening ( 14 ). 7. Infrared radiation thermometer according to claim 2, characterized in that it has a light guide which directs the incident infrared radiation through the radiation inlet opening ( 14 ) to the infrared sensor ( 26 ). 8. Infrared radiation thermometer according to claim 2 or 7, characterized in that the optical system has a beam splitter ( 20 ) which is transparent to infrared radiation and reflective to visible light and between the radiation inlet opening ( 14 ) on the one hand and the Observation device ( 30 , 32 ) and the infrared sensor ( 26 ) on the other hand. 9. Infrared radiation thermometer according to one of the preceding claims, characterized in that the observation device has a light source ( 30 ) for visible light, an eyepiece ( 32 ) and / or an image recording device, for example a CCD camera. 10. Infrared radiation thermometer according to one of the preceding claims, characterized, that there is a marking device for optically marking the tempe ratur-measuring spot area.