DE202008014926U1 - Measuring device for physiological parameters - Google Patents

Abstract

Measuring device for attachment to body organs, such as fingers or toes for determining physiological parameters, in particular oxygen saturation in the blood, consisting of transmitting unit, receiving unit, display unit, supply unit, evaluation, spring element and connecting element and housing elements, characterized in that the upper housing element (8) and lower housing element (9) of the measuring device (1) via at least one connecting element (7) are inextricably and flexibly interconnected.

Description

The The invention relates to a measuring device according to the preamble of Claim 1. Devices are known for measuring blood, tissue and or skin parameters in medical technology in those over at least one transmitting and receiving unit measures by means of electromagnetic waves take place.

These Measurements can be made on different organs or body parts of the human being. As a particularly advantageous have proven medical measuring devices in which the Measurements can be made by finger or toe.

So revealed the US 5,490,523 A (Nonin) a Fingerclip Pulse Oximeter for measuring the blood oxygen saturation which consists of several separate individual elements, such as upper and lower housing part, which frictionally applies to the top and bottom of the finger, a spring which connects these housing parts together and the ends lie in slot-like depressions and electrical connection elements.

adversely in this measuring device is in particular that the many contact points the individual elements to be connected and the breakthroughs in the housing parts for fixing the spring and connecting elements as well as the breakthroughs of the electrical supply lines offer the possibility of bacterial contamination and can not be reliably disinfected.

In order to is the entire measuring device described above and all finger clip oximeters on the market in principle not reliable disinfectable.

In the WO 2008/018050 A2 (SPO) is a device for measuring and recording the blood saturation beschrienen, consisting of a separate finger sensor, which is either wrapped around the finger or in a finger well, as well as an attached around the wrist evaluation unit and associated display unit. A separate electrical supply line connects the sensor on the finger with the evaluation unit and display unit on the wrist.

All known technical solutions in the field of pulse oximeters Sensor or finger clip pulse oximeter with movable or height-pivoting connected Housing parts are made with individual separate elements, such as B. spring element and retaining element mechanically interconnected. By the type of fixation of the spring and holding elements to obtain the Agility arise breakthroughs in the housing parts and hard-to-reach areas that are classified as biological or bacterial contamination is no longer reliable be cleaned or disinfected.

task The invention is to disclose a measuring device, in particular is designed according to hygienic aspects and thus on the one hand lowest possible attack surfaces for the accumulation of bacteria and dangerous for humans Microorganisms on the other hand offers a fast and reliable Decontamination by common disinfection methods, such as wipe disinfection and in particular allows diving disinfection. In a special design, the measuring device can also hot steam be sterilized.

According to the invention This object by the features of claim 1, as well as for different forms of the invention by in the Subclaims mentioned features realized. The measuring device is formed in a preferred embodiment so that in it all functional elements, such as transmitting unit, receiving unit, Display unit, supply unit and evaluation unit in one Device are integrated and the overall structure of the measuring device, in particular, the surfaces in contact with the body organs hygienic design.

It demonstrate:

1 a measuring device with integrated spring element and connecting element made of the same material

2 a measuring device with combined spring element and connecting element of preferably the same material with different elasticity and flexibility

3 a measuring device with an inseparable from the upper housing member and lower housing member spring element, with spatial separation of the spring element from the connecting element

4 a measuring device with spatial separation of the spring element from the connecting element wherein the spring element is separable

5 a measuring device with external display unit

6 a measuring device with external evaluation unit and display unit

7 a measuring device with a plurality of integrated in a spring functional elements and in terner display unit

8th an electrical block diagram for 1 ; 2 ; 3 ; 4 ; 7

9 an electrical block diagram for 5

10 an electrical block diagram for 6

In 1 is a measuring device according to the invention ( 1 ), in the upper housing element ( 8th ) with lower housing element ( 9 ) by a flexible connecting element ( 7 ) with integrated spring element ( 7.1 ) is inseparably connected. This with a spring element ( 7.1 ) integrated connection element ( 7 ) consists of the same material. In a preferred embodiment, transmission unit ( 2 ) in the upper housing element ( 8th ) and receiving unit ( 3 ) in the lower housing element ( 9 ) arranged. The material for connecting element ( 7 ) and spring element ( 7.1 ) here preferably consists of silicone rubber. Furthermore, it can be seen that in a preferred embodiment in the upper housing element ( 8th ) above the transmitting unit ( 2 ), Evaluation unit ( 6 ) with display unit ( 4 ) and in the lower housing element ( 9 ), below the receiving unit ( 3 ), Supply unit ( 5 ) are arranged.

2 shows measuring device ( 1 ) at the connecting element ( 7 ) with a spring element ( 7.1 ) and in the connecting element ( 7 ) is included. Connecting element ( 7 ) and spring element ( 7.1 ) consist here preferably of the same materials with different elasticity and flexibility. Again, in the upper housing element ( 8th ) Transmitting unit ( 2 ), Evaluation unit ( 6 ) with display unit ( 4 ) and in the lower housing element ( 9 ) Receiving unit ( 3 ) and supply unit ( 5 ) arranged opposite each other. Upper housing element ( 8th ) and lower housing element ( 9 ) are by the connecting element ( 7 ) and spring element ( 7.1 ) and flexibly connected, so that upper housing element ( 8th ) and lower housing element ( 9 ) with transmitting unit ( 2 ) and receiving unit ( 3 ), put on toes or fingers positively and positively. The material for connecting element ( 7 ) and spring element ( 7.1 ) here preferably consists of silicone rubber, wherein the connecting element ( 7 ) one to spring element ( 7.1 ) has different Shore hardness. In a further embodiment, the connecting element ( 7 ) z. B. of silicone rubber and the enclosed spring element ( 7.1 ) made of a plastic material with restoring properties such. B. polyamide.

3 shows measuring device ( 1 ) at the spring element ( 7.1 ) of the connecting element ( 7 ) arranged spatially separated from each other and inseparable from the upper housing element ( 8th ) and the lower housing element ( 9 ) are connected. Connecting element ( 7 ) and spring element ( 7.1 ) consist here preferably of the same materials with different elasticity and flexibility. The material for connecting element ( 7 ) and spring element ( 7.1 ) here preferably consists of silicone rubber, wherein the connecting element ( 7 ) one to spring element ( 7.1 ) has different Shore hardness. In a further embodiment, the connecting element ( 7 ) z. B. of silicone rubber and the separately arranged spring element ( 7.1 ) made of a plastic material with restoring properties such. B. polyamide. Again, in the upper housing element ( 8th ) above the transmitting unit ( 2 ), Evaluation unit ( 6 ) with display unit ( 4 ) and in the lower housing element ( 9 ), below the receiving unit ( 3 ), Supply unit ( 5 ) arranged.

4 shows measuring device ( 1 ) at the spring element ( 7.1 ) of the connecting element ( 7 ) is spatially separated from each other and from the upper housing element ( 8th ) and / or the lower housing element ( 9 ) is separable in compliance with hygiene aspects. Here are spring element ( 7.1 ) and connecting element ( 7 ) preferably made of different materials. The material for connecting element ( 7 ) here preferably consists of silicone rubber and spring element ( 7.1 ) here is preferably a plastic material with restoring properties such. B. polyamide. Again, in the upper housing element ( 8th ) above the transmitting unit ( 2 ), Evaluation unit ( 6 ) with display unit ( 4 ) and in the lower housing element ( 9 ), below the receiving unit ( 3 ), Supply unit ( 5 ) arranged.

In 5 is the in the upper housing element ( 8th ) advantageous arrangement of the evaluation unit ( 6 ) and in the lower housing element ( 9 ) arranged supply unit ( 5 ). Furthermore, it is shown that the evaluation unit ( 6 ) with an external receiving unit ( 13 ) and external display unit ( 14 ). The connection of the evaluation unit ( 6 ) to the external receiving unit ( 13 ) and external display unit ( 14 ) takes place contactlessly via data transmission unit ( 12 ), ie without physical connections through electrical lines.

6 essentially gives 5 again only with the difference that both receiving unit ( 13 ), Display unit ( 14 ) and evaluation unit ( 6 ) are arranged externally and thus the essential requirements of a hot steam sterilization of the measuring device ( 1 ) given are. In this case, data acquisition unit ( 11 ) as well as data transmission unit ( 12 ) preferably in the upper housing lement ( 8th ) arranged.

7 shows measuring device ( 1 ) in the self-resetting spring ( 10 ), the upper housing element ( 8th ), lower housing element ( 9 ) and its connecting element ( 7 ) are integrated. In an advantageous embodiment, further functional elements, such as supply unit ( 5 ) of the evaluation unit ( 6 ) with the internal display unit ( 4 ) and the arrangement of the transmitting unit ( 2 ) and receiving unit ( 3 ), in the upper housing element ( 8th ) arranged. Feather ( 10 ) with its integrated functional elements, upper housing element ( 8th ), lower housing element ( 9 ) and connecting element ( 7 ), is preferably made of the same material. A suitable material for housing element ( 8th ), Feather ( 10 ), Housing element ( 9 ) and connecting element ( 7 ) is z. B polyamide which also has restoring properties.

8th shows the electrical block diagram for the 1 ; 2 ; 3 ; 4 and 7 , The block diagram shows transmission unit ( 2 ), Receiving unit ( 3 ), Evaluation unit ( 6 ), Display unit ( 4 ), as well as supply unit ( 5 ). At the transmitting unit ( 2 ) are usually encapsulated LED's with different wavelengths. Here, a red LED with 660 nm emitted wavelength and a second LED with typically 880-940 nm emitted wavelength are usually used. At the receiving unit ( 3 ) are usually encapsulated photodetectors on a semiconductor basis such. B. silicon. The evaluation unit ( 6 ) evaluates the signals of the receiving unit with the aid of a microprocessor ( 3 ) and executes the evaluated measured values of the display unit ( 4 ) to bring this to the display. In the display unit ( 4 ) is preferably a graphic LCD to represent the pulse course curve. The power supply for the evaluation unit ( 6 ); Transmitting unit ( 2 ) as well as display unit ( 4 ) via the supply unit ( 5 ) which preferably consists of disposable or rechargeable batteries, such. B. Li-ion batteries. All function blocks are electrically connected to each other.

9 shows the electrical block diagram for the 5 , The block diagram shows transmission unit ( 2 ), Receiving unit ( 3 ), Evaluation unit ( 6 ), Data transmission unit ( 12 ), Data receiving unit ( 13 ), external display unit ( 14 ), as well as supply unit ( 5 ). At the transmitting unit ( 2 ) are usually encapsulated LED's with different wavelengths. Here, a red LED with 660 nm emitted wavelength and a second LED with typically 880-940 nm emitted wavelength are usually used. At the receiving unit ( 3 ) are usually encapsulated photodetectors on a semiconductor basis such. B. silicon. The evaluation unit ( 6 ) evaluates the signals of the receiving unit with the aid of a microprocessor ( 3 ) and executes the evaluated measured values of the data transmission unit ( 12 ) too. The data transmission unit ( 12 ) physically transmits contactless the evaluated data, preferably encrypted and digital to the data receiving unit ( 13 ) which the evaluated data to the external display unit ( 14 ) to bring the data to the display. For the external display unit ( 14 ) is preferably a graphics-capable display to represent the pulse course curve. The power supply for the evaluation unit ( 6 ); Transmitting unit ( 2 ) as well as data transmission unit ( 12 ) via the supply unit ( 5 ) which preferably consists of disposable or rechargeable batteries, such. B. Li-ion batteries. In the data transmission unit ( 12 ) is preferably constructed on commercial solutions such. B. Bluetooth modules. At the data receiving unit ( 13 ) is also preferably built on commercial solutions based on Bluetooth.

10 shows the electrical block diagram for the 6 , The block diagram shows transmission unit ( 2 ), Receiving unit ( 3 ), Data acquisition unit ( 11 ) Data transmission unit ( 12 ), Data receiving unit ( 13 ), Evaluation unit ( 6 ), external display unit ( 14 ), as well as supply unit ( 5 ). At the transmitting unit ( 2 ) are usually encapsulated LED's with different wavelengths. Here, a red LED with 660 nm emitted wavelength and a second LED with typically 880-940 nm emitted wavelength are usually used. At the receiving unit ( 3 ) are usually encapsulated photodetectors on a semiconductor basis such. B. silicon. The data acquisition unit ( 11 ) transmits the acquired unevaluated raw data to the data transmission unit ( 12 ). The data transmission unit ( 12 ) physically non-contactly transmits the unexamined raw data, preferably encrypted and digital, to the data receiving unit ( 13 ) which the evaluated data to the evaluation unit ( 6 ). The evaluation unit ( 6 ) evaluates the raw data and forwards the evaluated data to the external display unit ( 14 ) continue where they are displayed. In the display unit ( 14 ) is preferably a graphics-capable display to represent the pulse course curve. The power supply for the evaluation unit ( 6 ); Transmitting unit ( 2 ) as well as data transmission unit ( 12 ) via the supply unit ( 5 ) which preferably consists of disposable or rechargeable batteries, such. B. Li-ion batteries. In the data transmission unit ( 12 ) is preferably constructed on commercial solutions such. B. Bluetooth modules. At the data receiving unit ( 13 ) is also preferably built on commercial solutions based on Bluetooth.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - US 5490523 A [0003]
• WO 2008/018050 A2 [0006]

Claims (30)

Measuring device for attachment to body organs, such as fingers or toes for the determination of physiological parameters, in particular oxygen saturation in the blood, consisting of transmitting unit, receiving unit, display unit, supply unit, evaluation unit, spring element and connecting element and housing elements, characterized in that upper housing element ( 8th ) and lower housing element ( 9 ) of the measuring device ( 1 ) via at least one connecting element ( 7 ) are inseparable and flexibly interconnected. Measuring device according to claim 1, characterized in that in the connecting element ( 7 ) the function of a spring element ( 7.1 ) is integrated and preferably made of the same material. Measuring device according to claim 1 and 2, characterized in that the connecting element ( 7 ) with spring element ( 7.1 ) is combined and preferably made of the same material with different elasticity and flexibility. Measuring device according to one or more of claims 1 to 3, characterized in that the spring element ( 7.1 ) of the connecting element ( 7 ) spatially separated from each other and inseparable with upper housing element ( 8th ) and lower housing element ( 9 ) connected is. Measuring device according to one or more of claims 1 to 4, characterized in that the spring element ( 7.1 ) of the connecting element ( 7 ) spatially separated from each other and from the upper housing element ( 8th ) and / or lower housing element ( 9 ) is separable. Measuring device according to one or more of claims 1 to 5, characterized in that the upper housing element ( 8th ) and lower housing element ( 9 ) are preferably formed form-fitting and höhenschwenkbar and self-resetting connected. Measuring device according to one or more of claims 1 to 6, characterized in that preferably transmitting unit ( 2 ) in the upper housing element ( 8th ) and receiving unit ( 3 ) in the lower housing element ( 9 ) are arranged. Measuring device according to one or more of claims 1 to 7, characterized in that the charging of the supply unit ( 5 ) is physically contactless. Measuring device according to one or more of claims 1 to 8, characterized in that measuring device ( 1 ) is designed to be disinfectable by dipping. Measuring device for attachment to body organs, such as fingers or toes for the determination of physiological parameters, in particular oxygen saturation in the blood, consisting of transmitting unit, receiving unit, evaluation unit, display unit, supply unit, spring element and connecting element and housing elements, characterized in that upper housing element ( 8th ) and lower housing element ( 9 ) of the measuring device ( 1 ) via at least one connecting element ( 7 ) are inseparably and flexibly connected to each other and in the upper housing element ( 8th ) or lower housing element ( 9 ) integrated evaluation unit ( 6 ) spatially from external display unit ( 14 ) is disconnected. Measuring device according to claim 10, characterized in that in the connecting element ( 7 ) the function of a spring element ( 7.1 ) is integrated and preferably made of the same material. Measuring device according to claim 10 and 11, characterized in that the connecting element ( 7 ) with spring element ( 7.1 ) is combined and preferably made of the same material with different elasticity and flexibility. Measuring device according to one or more of claims 10 to 12, characterized in that the spring element ( 7.1 ) of the connecting element ( 7 ) spatially separated from each other and inseparable with upper housing element ( 8th ) and lower housing element ( 9 ) connected is. Measuring device according to one or more of claims 10 to 13, characterized in that the spring element ( 7.1 ) of the connecting element ( 7 ) spatially separated from each other and from the upper housing element ( 8th ) and / or lower housing element ( 9 ) is separable. Measuring device according to one or more of claims 10 to 14, characterized in that the upper housing element ( 8th ) and lower housing element ( 9 ) form-fitting manner and are height-adjustable and self-resetting connected. Measuring device according to one or more of claims 10 to 15, characterized in that preferably transmitting unit ( 2 ) in the upper housing element ( 8th ) and receiving unit ( 3 ) in the lower housing element ( 9 ) are arranged. Measuring device according to one or more of claims 10 to 16, characterized in that the charging of the supply unit ( 5 ) is physically contactless. Measuring device according to one or more of claims 10 to 17, characterized in that measuring device ( 1 ) is designed to be disinfectable by dipping. Measuring device according to one or more of claims 10 to 18, characterized in that measuring device ( 1 ) is formed steam sterilizable. Measuring device for attachment to body organs, such as fingers or toes for the determination of physiological parameters, in particular oxygen saturation in the blood, consisting of transmitting unit, receiving unit, data acquisition unit, data transmission unit, evaluation unit, display unit, supply unit, spring element and connecting element and housing elements, characterized in that upper housing element ( 8th ) and lower housing element ( 9 ) of the measuring device ( 1 ) via at least one connecting element ( 7 ) are inseparably and flexibly connected to each other and in the upper housing element ( 8th ) and / or lower housing element ( 9 ) integrated data acquisition unit ( 11 ) as well as data transmission unit ( 12 ) spatially from the receiving unit ( 13 ), Evaluation unit ( 6 ) and external display unit ( 14 ) are separated. Measuring device according to claim 20, characterized in that in the connecting element ( 7 ) the function of a spring element ( 7.1 ) is integrated and preferably made of the same material. Measuring device according to claim 20 and 21, characterized in that the connecting element ( 7 ) with spring element ( 7.1 ) is combined and preferably made of the same material with different elasticity and flexibility. Measuring device according to one or more of claims 20 to 22, characterized in that the spring element ( 7.1 ) of the connecting element ( 7 ) spatially separated from each other and inseparable with upper housing element ( 8th ) and lower housing element ( 9 ) connected is. Measuring device according to one or more of claims 20 to 23, characterized in that the spring element ( 7.1 ) of the connecting element ( 7 ) spatially separated from each other and from the upper housing element ( 8th ) and / or lower housing element ( 9 ) is separable. Measuring device according to one or more of Claims 20 to 24, characterized in that the upper housing element ( 8th ) and lower housing element ( 9 ) form-fitting manner and are height-adjustable and self-resetting connected. Measuring device according to one or more of claims 20 to 25, characterized in that preferably transmitting unit ( 2 ) in the upper housing element ( 8th ) and receiving unit ( 3 ) in the lower housing element ( 9 ) are arranged. Measuring device according to one or more of claims 20 to 26, characterized in that the charging of the supply unit ( 5 ) is physically contactless. Measuring device according to one or more of claims 20 to 27, characterized in that measuring device ( 1 ) is designed to be disinfectable by dipping. Measuring device according to one or more of claims 20 to 28, characterized in that measuring device ( 1 ) is formed steam sterilizable. Measuring device for attachment to body organs, such as fingers or toes for the determination of physiological parameters, in particular oxygen saturation in the blood, characterized in that in a self-restoring spring ( 10 ) of the measuring device ( 1 ), upper housing element ( 8th ), lower housing element ( 9 ) and its connecting element ( 7 ) are integrated and preferably in the upper housing element ( 8th ), Transmitting unit ( 2 ), Receiving unit ( 3 ), Display unit ( 4 ), Supply unit ( 5 ) as well as evaluation unit ( 6 ) are arranged.